KR20010033564A - Use of macrolides in pest control - Google Patents

Abstract

Control of pests by macrolide compounds; More particularly, macrolides, characterized by the application of a pesticidal composition comprising a macrolide compound in the free form or in the form of an agrochemically useful salt and at least one adjuvant to the pest or its habitat, in particular the crop itself. Methods of controlling pests on and in the transgenic crops of useful plants such as corn, cereals, soybeans, tomatoes, cotton, potatoes, rice and mustard by the compounds; B) Insecticidal active compounds, characterized in that a pesticide comprising at least one macrolide compound and at least one adjuvant as an active ingredient is used as a planting or sowing site in close proximity or spatially with the planting or application of the propagation material. A method of protecting plant organs and plant propagation material subsequently formed from attack by pests; C) A macrolide compound, which is applied to a pest or habitat thereof as a pesticidal active compound, an insecticidal active amount of an insecticide comprising one or more macrolides in the free form or in the form of an agrochemically useful salt as an active ingredient and at least one auxiliary Control of tree pests and molluscs by Corresponding uses of these compounds, corresponding pesticides in which the active ingredient is selected from these compounds, methods of making and using these compositions, and plant propagation materials are described which are protected in this way from attack by pests.

Description

Use of macrolides in pest control

The present invention relates to a pest control method using a macrolide compound, more particularly

(A) novel pest control methods in transgenic crops of useful plants using macrolide compounds;

(B) a method of protecting plant propagation material and plant organs subsequently formed from attack by pests using macrolide compounds, and

(C) A method for controlling tree pests and mollusks by macrolide compounds.

Specific pest control methods are given in the literature. However, these methods are not entirely satisfactory in the field of pest control, because there is a need to also provide methods for controlling and controlling pests, in particular insects and representative mite, or for protecting plants, in particular crops. This object is achieved according to the invention by providing a method of the invention.

(A) Accordingly, a first aspect of the invention relates to a pesticidal composition comprising amacectin, in free form or in agrochemically useful salt form, in particular to pests or their habitats, in particular to the crops themselves. Control of pests in transgenic useful crops, such as corn, cereals, soybeans, tomatoes, cotton, potatoes, rice and mustard, characterized by application; A use of the composition and a propagation material of a transgenic plant treated with the composition.

Surprisingly, in today's useful plants that contain one or more genes that express pesticidal, in particular pesticidal, acaricidal, nematicidal or bactericidally active components or which are resistant to herbicides The use of macrolide compounds for the control of pests has been shown to have a synergistic effect. The use of macrolide compounds with transgenic plants primarily exceeds the expected additive effects on the pests to be controlled, thereby extending the range of action of macrolide compounds and, in particular, the active body expressed by the transgenic plants in both aspects. It is quite surprising:

In particular, surprisingly, within the scope of the present invention (A), the pesticidal activity of the macrolide compound together with the effect expressed by the transgenic useful plant is generally predictable of the macrolide compound alone and the transgenic crop alone. In addition to the pesticidal activity of, it was found that there is a synergistic effect as well. However, the term "synergistic" is not to be understood as limiting to pesticidal activity in this regard, which refers to other useful properties of the method according to the invention as compared to macrolide compounds alone and to transgenic useful plants alone. Examples of such useful properties that may be mentioned include expansion of the insecticidal spectrum for other pests, for example resistant strains; Even if the application rate of the macrolide compound alone and the transgenic useful plant alone is entirely ineffective, sufficient control of the pests using the composition according to the invention or reduction in the application rate of the macrolide compound; Improved crop safety; Agricultural products such as higher nutrient or oil content, better fiber quality, improved shelf life, reduced content of toxic products (such as mycotoxins), reduced content of certain types or better digestibility residues, or less useful ingredients. Improved quality; Improved resistance to salt content of undesirable temperatures, ventilation or moisture; Improved rates of assimilation such as nutrient uptake, water uptake and photosynthesis; Altered leaf area, reduced plant growth, increased yields, useful seed morphology / seed thickness or germination properties, altered colonization by by-product or plant plants, reduced aging, improved phytoalexin production, improved stimulation Useful crop properties such as increased ignition, reduced dropping and degranulation, better attraction to worms and predators, increased moisture, reduced algae, or other benefits known to those skilled in the art.

Macrolide compounds used according to the present invention parts (A), (B) and (C) are known to those skilled in the art. These are described, for example, in Milvemycin and Arber in US-P 4 310 519, US-P 5 077 298, JP 2 717 040 or US-P 4 427 663. It is a class of substances described as mectin. These macrolides should also be understood according to the invention to mean derivatives of these substances, for example milbamycin oxime, moxidecin, ivermectin, abamectin, emamectin and doramectin, and spinosyn of formula III do.

In the above formula,

R ₁ , R ₂ , R ₃ , R ₄ , R ₅ and R ₆ are independently of each other hydrogen or substituted or unsubstituted alkyl, alkenyl, alkynyl, cycloalkyl, aryl or heterocyclyl groups,

Substructures A and B are, independently of each other, two carbon atoms bonded to each of these substructures in free form by a single bond, a double bond or a single bond and an epoxy bridge, or in some cases, in the form of an agrochemically useful salt. Coupled.

Within the scope of the present invention (A), abamectin is preferred. Abamectin is a mixture of Avermectin B _1a and Avermectin B _1b and is described, for example, in The Pesticide Manual, 10 ^th ED. (1994), The British Crop Protection Council, London, page 3 Described.

Within the scope of the present invention (A), it is known from US Pat. No. 4,874,749 and described in Journal of Organic Chemistry, Vol. 59 (1994), pages 7704-7708, also preferred are emamectins, 4 "-deoxy-4" -epi-N-methylamino avermectin B _1b / B _1a , known as MK-244. Particularly useful salts of emamectins are described in US Pat. No. 5,288,710.

Within the scope of the present invention (A), a group of compounds consisting of spinosine and derivatives thereof; Preference is also given to a group of compounds consisting of spinosine present in nature or to a group consisting of derivatives of spinosine present in nature. Preferably, the active ingredient is within the scope of the object of the invention (A), spinosyn A; Spinosin D or a mixture consisting of spinosine A and spinosine D, with spinosads being particularly preferred, spinosads being described in "The Pesticide Manual", 11 ^th Ed. (1997), The British Crop Protection Council, London, United Kingdom, pages 1272-1273.

Agrochemically compatible salts of macrolide compounds are, for example, inorganic and organic acids, in particular hydrochloric acid, hydrobromic acid, sulfuric acid, nitric acid, perchloric acid, phosphoric acid, formic acid, acetic acid, trifluoroacetic acid, oxalic acid, malonic acid, toluene Acid addition salts of sulfonic acid or benzoic acid. Within the scope of the present invention, a composition known per se comprising abamectin or spinosad in free form as the active ingredient and emamtin as the benzoate salt is preferred.

The transgenic plants to be used according to the invention (A) are known from toxin-producing invertebrates of Maddival animal portals, from which they can be obtained, for example, in particular from Bacillus thuringiensis strains, A plant or propagation material thereof known from (e.g., lectins), or transformed with recombinant DNA technology which enables the synthesis of selectively acting toxins which are herbicidal or others capable of expressing bactericidal resistance. Examples of such toxins or transgenic plants capable of synthesizing toxins are, for example, EP-A-0 374 753, WO 93/07278, WO 95/34656, EP-A 0 427 529 And EP-A 451 878, which are incorporated herein by reference.

Methods for producing such transgenic plants are widely known to those skilled in the art and are described, for example, in the documents mentioned above.

Toxins that can be expressed by such transgenic plants include, for example, proteins that have insecticidal properties and are expressed by transgenic plants, such as Bacillus cereus protein or Bacillus popli protein. popliae protein); Or Bacillus thuringiensis endotoxin (B.t.) (eg, CryIA (a), CryIA (b), CryIA (c), CryIIA, CryIIIA, CryIIIB2 or CytA); VIP1; VIP2; VIP3; Nematodes, such as Photorhabdus spp or Xenorhabdus spp (e.g. Photorhabdus luminescens, Xenorhabdus nematophilus, etc.) Insecticidal proteins that colonize the bacteria; Proteolytic enzyme inhibitors such as trypsin inhibitors, serine protease inhibitors, patatin, cystatin, papain inhibitors; Ribosome-inactivated protein (RIP) (eg, lysine, corn RIP, abrin, lupine, saporin or briodine); Plant lectins such as pea lectins, barley lectins or anemone lectins; Or agglomerate; Toxins produced by animals (eg, scorpion toxins, spider poisons, wasp venoms and other insect specific neurotoxins); Steroid metabolases (e.g. 3-hydroxysteroid oxidase, ecsteroids UDP-glycosyl transferase, cholesterol oxidase), ecdysone inhibitors, HMG-COA reductase, ion channel blockers (e.g. sodium and calcium), larvae Toxins such as hormone esterases, diuretic hormone receptors, stilbene synthase, bibenzyl synthase, chitinase and glucanase.

Examples of known transgenic plants that include one or more genes that encode pesticidal resistance and express one or more toxins include KnockOut ^R (corn), YieldGard ^R (corn), NuCOTN 33B ^R (cotton), Bollgard ^R (cotton), NewLeaf ^R (potato), NatureGard ^R and Protecta ^R.

The following table further shows examples of targets and bodies and crop phenotypes of transgenic crops that exhibit resistance to pests, mainly insects, mites, nematodes, viruses, bacteria and diseases, and are resistant to certain herbicides or herbicide groups. .

Crop: Corn Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (eg P450 SU1) Dimboa biosynthesis (Bx1 gene) CMIII (small basic corn seed peptide) Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas) Helmintosporium tursicum, lopaloside mydis, diplodia mydis, austrian nubilalis, lepi Aerodactyl kinds of plant pathogens (eg, Fusarium, altereuna Leah, Klee's as Tina)

Target or expression body (s) performed Crop Phenotype / Resistence Against Maize-SAFP (zeamate) Hm1 gene chitinase glucanase coating protein Bacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus and xenorharvus toxin 3-hydroxysteroid oxidase oxidase peroxidase Plant pathogens (e.g., fusarium, alternaria, sclerotina, lysatonia, caetium, picomas) coccilobium plant pathogens pathogens viruses (e.g. corn dwarf mosaic virus, corn chlorotic dwarf virus) Dofterra, cholopterra, diphthera, nematodes (e.g. Australia nubilaris, heliotis zea), moth moths (e.g. Spodoptera prugiferda), corn root beetle, sesame species, roundup semis, Asian Lighted Moth, Bagumirepidofera, Koleoptera, Diphthera, Nematode (e.g. Australia Nubiliris, Heliotis Zea), Sterling Moth (e.g. Spodoptera fruitiferda), Corn Root Beetle, Sesame Subspecies, Roundup Semi, Asian Illuminated Moth, Bagumirepidoftera, Choleoptera, Diphthera, Nematode (e.g. Australia Nubiliris, Heliotis Zea), Mole Moth (e.g. Garda), corn root worms, sesame ah species, semi arrested, Asian borer, weevils

Target or expression body (s) performed Crop Phenotype / Resistence Against Aminopeptidase inhibitors (e.g. leucine aminopeptidase inhibitors (LAPI)) limonene synthagelectin protease inhibitors (e.g. cystatin, patatin, viriferin, CPTI) ribosomal inactivated protein corn 5C9 polypeptide Lepidofera, coleopterra, diphthera, nematodes (e.g. Australia nubiliris, heliotis zea), moth moths (e.g. Spodoptera prugiferda), corn rootworm, sesame species, black spots , Asian lighting moth, weevil corn root beetle lepidopterra, cholopterra, diphthera, nematode (e.g. Australia nubiliris, heliotis zea), extinct moth (e.g. Spodoptera fruitiferda), corn Root beetle, Sesameia species, rounded semi-semi, Asian light moth, weevil weevil, root beetle reedopterra, coleoptera, diphthera, nematode (e.g. Austrian Nubiliris, Heliotis zea), moth moth (e.g. Spodoptera fruitgiferda), corn rootworm, sesame species, rounded snails, Asian lit moth, Bagumi lepidoptera, cholopterra, diphthera, nematodes (e.g. Austrian Nubiliris, Heliotis zea) , Extinct (Eg Spodoptera frugiperda), corn root worms, sesame ah species, semi arrested, Asian borer, weevils HMG-CoA Reductase Lepidofera, coleopterra, diphthera, nematodes (e.g. Australia nubiliris, heliotis zea), moth moths (e.g. Spodoptera prugiferda), corn rootworm, sesame species, black spots , Asian Spotted Moth, Weevil

Crop: Wheat Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), phenophylates, oxadiazoles

Target or expression body (s) performed Crop Phenotype / Resistence Against Antifungal Polypeptide AlyAFP Glucose Oxidasepyrronitrin Synthesis Gene Serine / Threonine Kinase Polypeptides Systemic Acquired Resistance (SAR) Gene Chitinase Glucanase Double Strand Ribonuclease Coat Protein Bacillus Thuringiensis Toxin, VIP 3 , Bacillus cereus toxin, photorabdus and xenorhavudose toxin 3-hydroxysteroid oxidase peroxidase aminopeptidase inhibitors (e.g. leucine aminopeptidase inhibitors) lectin protease inhibitors (e.g. cystatin, pata Chitin, viriferin, CPTI) Plant pathogens (e.g. Ceftoria and Fusarium) Plant pathogens (e.g. Fusarium, Ceftoria) Plant pathogens (e.g. Fusarium, Ceftoria) Plant pathogens (e.g. Fusarium, Ceftoria) and other disease plant pathogens ( Examples: Fusarium, Ceftoria) and other diseases Viral, bacterial, fungal, nematode pathogens Pathogens Pathogens Viruses (e.g. BYDV and MSMV) Viruses (e.g. BYDV and MSMV) Lepidoptera, choloptera, deep Terra, nematode redodotera, coleopera, diphthera, nematode redodotera, coleopera, diphthera, nematode redopethera, coleopera, diphthera, nematode redodotera, coleopera, diphthera, Nematodes, aphids lepidopterra, choloptera, diphthera, nematodes, aphids Ribosome Inactivating Protein HMG-CoA Reductase Lepidoptera, coleopterra, diphthera, nematode, aphid lepidopterra, cholopterra, diphthera, nematode (e.g. Austrian Nubiliris, Heliotis zea), moth moth (e.g. Spodoptera prugi) Perda), Corn Root Beetle, Sesame Species, Roundup Semi, Asian Light Moth, Weevil

Crop: Barley Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), phenophylates, oxadiazoles

Target or expression body (s) performed Crop Phenotype / Resistence Against Antifungal Polypeptide AlyAFP Glucose Oxidasepyrronitrin Synthesis Gene Serine / Threonine Kinase Polypeptides Systemic Acquired Resistance (SAR) Gene Chitinase Glucanase Double Strand Ribonuclease Coat Protein Bacillus Thuringiensis Toxin, VIP 3 , Bacillus cereus toxin, photorabdus and xenorhavudose toxin 3-hydroxysteroid oxidase peroxidase aminopeptidase inhibitors (e.g. leucine aminopeptidase inhibitors) lectin protease inhibitors (e.g. cystatin, pata Chitin, viriferin, CPTI) Plant pathogens (e.g. Ceftoria and Fusarium) Plant pathogens (e.g. Fusarium, Ceftoria) Plant pathogens (e.g. Fusarium, Ceftoria) Plant pathogens (e.g. Fusarium, Ceftoria) and other disease plant pathogens ( Examples: Fusarium, Ceftoria) and other diseases Viral, bacterial, fungal, nematode pathogens Pathogens Pathogens Viruses (e.g. BYDV and MSMV) Viruses (e.g. BYDV and MSMV) Lepidoptera, choloptera, deep Terra, nematode redodotera, coleopera, diphthera, nematode redodotera, coleopera, diphthera, nematode redopethera, coleopera, diphthera, nematode redodotera, coleopera, diphthera, Nematodes, aphids lepidopterra, choloptera, diphthera, nematodes, aphids Ribosome Inactivating Protein HMG-CoA Reductase Lepidoptera, cholopterra, diphthera, nematodes, aphidsLepidoptera, cholopterra, diphthera, nematodes, aphids

Crop: Rice Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (eg P450 SU1) Antifungal Polypeptide AlyAFP Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas)

Target or expression body (s) performed Crop Phenotype / Resistence Against Glucose Oxidasepyrrolenitrin Synthetic Gene Serine / Threonine Kinase Phenylalanine Ammonia Lyase (PAL) PhytoAlexin B-1,3-Glucanase Antisense Receptor Kinase Polypeptides Systemic Acquired Resistance (SAR) Gene Chitinase Glucana Double-stranded ribonuclease-coated protein Bacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus and xenorhavudose toxin 3-hydroxysteroid oxididazeperoxidase Plant pathogens Plant pathogens Plant pathogens Plant pathogens (e.g. white plaques and blasts) Plant pathogens (e.g. white plaques and blasts) Plant pathogens (e.g. white plaques and blasts) Plant pathogens (e.g. white plaques and plaques) Plant Pathogens Viral, Bacterial, Fungal, Nematode Pathogens Plant Pathogens (e.g. White Blots and Blasts) Plant Pathogen Viruses (e.g. BYDVs and MSMVs) Viruses (e.g. BYDVs and MSMVs) , Coleopterra (e.g. rice weevil), diphthera, grasshopper (e.g. brown grasshopper), lepidoptera (e.g. stemborough), coleopera (e.g. rice water weevil), diphthera, grasshopper (e.g. Brown grasshoppers) Lepidoptera (e.g. Stemborough), coleopera (e.g. rice weevil), Diphthera, grasshoppers (e.g. brown grasshopper)

Target or expression body (s) performed Aminopeptidase inhibitors (eg, leucine aminopeptidase inhibitors) lectin protease inhibitors ribosomal inactivating protein HMG-CoA reductase Lepidoptera (e.g. Stemborough), coleopera (e.g. rice weevil), Diphthera, Grasshopper (e.g. brown locust) Lepidofera (e.g. Stembore), coleopera (e.g. rice weevil) ), Diphthera, locusts (e.g. brown grasshopper), lepidoptera (e.g. stems), coleopera (e.g. rice weevil), diphthera, grasshoppers (e.g. brown grasshopper), lepidoptera (e.g. stems) See), choloptera (e.g. rice water weevil), diphthera, grasshopper (e.g. brown grasshopper), lepidoptera (e.g. stemborough), coleopera (e.g. rice water weevil), diphthera, grasshopper ( Example: Brown Grasshopper)

Crop: Soybean Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or selective antifungal polypeptide AlyAFP Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), bacterial and fungal pathogens (e.g., fusarium, sclerotinia, stemlot)

Target or expression body (s) performed Crop Phenotype / Resistence Against Oxalate Oxidase Glucose Oxidase Pyrolnitrin Synthetic Gene Serine / Threonine Kinase Phenylalanine Ammonia Lyase (PAL) PhytoAlexins B-1,3-Glucanase Antisense Receptor Kinase Polypeptide Systemic Acquired Resistance (SAR) Gene Kitinazeglucanase Bacterial and Fungal Pathogens (e.g. Fusarium, Sclerotinia, Stemlot) Bacteria and Fungal Pathogens (e.g. Fusarium, Sclerotinia, Stemlot) Bacteria and Fungal Pathogens (e.g. Fusarium, Bacterial and fungal pathogens (e.g. Fusarium, sclerotinia, Stemlot) Bacteria and fungal pathogens (e.g. Fusarium, Sclerotinia, Stemlot) Bacterial and fungal pathogens (e.g., fusarium, sclerotinia, stemlot), plant pathogens (e.g., white and disease), plant pathogens, viral, bacterial, fungal, nematode pathogens, and Fungal Pathogens (e.g. Fusarium, Sclerotinia, Stemlot) Bacteria and Fungal Pathogens (e.g. Fusarium, Sclerotinia, Stemlot)

Target or expression body (s) performed Crop Phenotype / Resistence Against Dual stranded ribonuclease-coated protein Bacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus and xenorhavudose toxin 3-hydroxysteroid oxidase zeperoxidase aminopeptidase inhibitors (e.g., leucine Aminopeptidase Inhibitors) Lectin Protease Inhibitors (e.g. Birgiferrin) Ribosome Inactivating Proteins HMG-CoA Reductase Varase Encapsulation Nematode Hatching Anti-feeding principles Viruses (e.g. BPMV and SbMV) Viruses (e.g. BYDV and MSMV) Lepidoptera, cholopterra, aphid lepidoptera, coleoptera, aphid lepidopterra, cholopterra, aphid lepidopterra, cholopterra , Aphid lepidoptera, choloptera, aphid lepidoptera, choloptera, aphid lepidoptera, choloptera, aphid lepidoptera, choloptera, aphid nematodes (e.g., root-knot nematodes and cyst nematodes) Nematodes (such as root-knot nematodes and cyst nematodes)

Crop: Potato Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or optional Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), phenophylates, oxadiazoles

Target or expression body (s) performed Crop Phenotype / Resistence Against Polyphenol Oxidase or Polyphenol Oxidase Antisense Metallothioneine Ribonuclease Antifungal Polypeptide AlyAFP Oxalate Oxidase Glucose Oxidase Pyrronitrin Synthetic Gene Serine / Threonine Kinase Secropin Bphenylalanine Ammonia Lyase (PAL) Phyto Alexin B-1,3-glucanase antisense receptor kinase Erythema and fungal pathogens (e.g. phytophthora) Phytophthora, verticillium, lipotonia bacteria and fungal pathogens (e.g. phytophthora) Bacteria and fungal pathogens (e.g. phytophthora, vertisilium) , Fungi and fungal pathogens (e.g. phytophthora, verticilium, lizatonia) fungi and fungal pathogens (e.g. phytophthora, vertisilium, lizatoninia) fungi and fungal pathogens (e.g. Bacteria (e.g. Corynebacterium, Ceddonicum, Erwinia Carotovora) Bacteria and fungal pathogens (e.g. Phytophthora, Bertisilium, Lizatonia) And fungal pathogens (e.g. phytophthora, verticilium, lizatoninia) bacteria and fungal pathogens (e.g. phytophthora, vertisilium, lizatoninia) bacteria and fungal pathogens (e.g. phytophthora, bergitoria) Tisilium, lizhatonia)

Target or expression body (s) performed Crop Phenotype / Resistence Against Polypeptide Systemic Acquired Resistance (SAR) Gene Chitinase Varnase Disease Responsiveness Gene 49 Pseudobiquitin replicazebacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, Photorabdus and Xenorhavudus toxin Bacterial and fungal pathogens (e.g. phytophthora, vertisilium, lysatonia) Viral, bacterial, fungal, nematode pathogens and fungal pathogens (e.g. phytophthora, vertisilium, lysatonia) Fungal Pathogens (e.g. Phytophthora, Bertisilium, Lizatonia) Bacteria and Fungal Pathogens (e.g. Phytophthora, Bertisilium, Lizatoninia) Sclerosis Bacteria and Fungal Pathogens (e.g. Viruses (e.g. PLRA, PVY and TRV) Viruses (e.g. PLRA, PVY and TRV) Viruses (e.g. PLRA, PVY and TRV) Viruses (e.g. PLRA, PVY and TRV) PLRA, PVY and TRV) viruses (e.g. PLRA, PVY and TRV) choloteera (e.g. Colorado potato beetle), aphids

Target or expression body (s) performed Crop Phenotype / Resistence Against 3-hydroxysteroid oxidase oxidase peroxidase aminopeptidase inhibitors (e.g. leucine aminopeptidase inhibitors) steelbene synthagelectin protease inhibitors (e.g. cystatin, patatin) ribosomal inactivating protein HMG-CoA reductase Nematode hatching irritant varnaze antifeeding principles Coleoptera (e.g. Colorado potato beetle), aphid coleopera (e.g. Colorado potato beetle), aphid coleopera (e.g. Colorado potato beetle), aphid coleopera (e.g. Colorado potato beetle), aphid coleoff Terra (e.g. Colorado potato beetle), Aphid coleopera (e.g. Colorado potato beetle), Aphid coleopera (e.g. Colorado potato beetle), Aphid coleopera (e.g. Colorado potato beetle), Aphid cyst nematode ( E.g. root-knot nematodes and cyst nematodes)

Crop: Tomato Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or optional polyphenol oxidase or polyphenol oxidase antisense Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas)

Target or expression body (s) performed Crop Phenotype / Resistence Against Metallothioneinribonuclease Antifungal Polypeptides AlyAFP Oxalate Oxidase Glucose Oxidase Pyrrolenitrin Synthetic Gene Serine / Threonine Kinase Secropin Bphenylalanine Ammonia Lyase (PAL) Cf Gene (e.g. Cf9 Cf5 Cf4 Cf2) Mortinalpha-Hordonionine Cystemine Polygalacturonase Inhibitor Bacterial and fungal pathogens (e.g. phytophthora) Phytophthora, verticilium, lizatonia Bacterial and fungal pathogens (e.g., bacterial spots, fusarium, purpura, powdery mildew, myocardium rot, foliar, etc.) Pathogens (e.g., bacterial spots, Fusarium, follicles, powdery mildew, root rot, foliage, etc.) Bacterial and fungal pathogens (e.g., bacterial spots, Fusarium, purine, powdery mildew, root rot, foliate, etc.) Bacterial and fungal pathogens (e.g. Examples: Bacterial spots, Fusarium, Atmospheric disease, Powdery mildew, Root head rot, Hardy soil, etc. Bacterial and fungal pathogens (e.g. Bacterial spots, Fusarium, Purine, Powdery mildew, Root head rot, Hardy soil, etc.) Bacterial and fungal pathogens (e.g. Bacterial and fungal pathogens (e.g., bacterial spots, Fusarium, purpura, powdery mildew, myocardium rot, foliar soil, etc.) Asolani Bacterial and fungal pathogens (e.g. bacterial spots, fusarium, softwood, powdery mildew, myocardium rot, foliar soil, etc.) Bacterial and fungal pathogens (e.g. bacterial spots, fusarium, purine, powdery mildew, myocardium rot, foliar soil) Etc)

Target or expression body (s) performed Crop Phenotype / Resistence Against Prf Regulatory Gene I2 Fusarium Resistant Site PhytoAlexin B-1,3-Glucanase Antisense Receptor Kinase Polypeptide Systemically Acquired Resistance (SAR) Gene Chitinase Varnaze Glucanase Double Strand Ribonuclease Coat Protein 17kDa or 60kDa protein-containing protein (eg a or b) or nucleic acid protein Bacterial and fungal pathogens (e.g. bacterial spots, fusarium, infertility, powdery mildew, myocardium rot, lobules, etc.) Fusarium fungal and fungal pathogens (e.g. bacterial spots, fussium, soft rot, powdery mildew, myoclonic rot, foliar, etc.) Bacterial and fungal pathogens (e.g. bacterial spots, fusarium, incurable diseases, powdery mildew, myocardium rot, foliage, etc.) Bacterial and fungal pathogens (e.g. bacterial spots, fussium, erosion, powdery mildew, myocardium rot, foliate, etc.) Fungal pathogens (e.g. bacterial spots, Fusarium, purifying disease, powdery mildew, myocardium rot, foliar soil, etc.) Viral, bacterial, fungal, nematode pathogens Fungal and fungal pathogens (e.g. bacterial spots, Fusarium, purpura, powdery mildew, Mycelial and fungal pathogens (e.g. bacterial spots, Fusarium, purifying disease, powdery mildew, myocardium rot, foliage, etc.) Bacterial and fungal pathogens (e.g. bacterial spots, Viruses (e.g. PLRV, PVY and ToMoV) Viruses (e.g. PLRV, PVY and ToMoV) Viruses (e.g. PLRV, PVY) Viruses (e.g. PLRV, PVY and ToMoV) Viruses (e.g. PLRV, PVY and ToMoV) And ToMoV) TRV

Target or expression body (s) performed Crop Phenotype / Resistence Against Pseudobiquitin replicazebacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus and xenorhavudose toxin 3-hydroxysteroid oxidase zeperoxidase aminopeptidase inhibitors such as leucine aminopeptida Inhibitors) Lectin protease inhibitors (e.g. cystatin, patatin) Ribosome inactivating proteinStilbene synthase HMG-CoA reductase cyst nematode Viruses (e.g. PLRV, PVY and ToMoV) Viruses (e.g. PLRV, PVY and ToMoV) Lepidoptera (e.g. Heliotis), Garyi aphid Lepidopera (e.g. Heliotis), Garyi aphid lepidopera (e.g. Heliotis), Garuy aphid lepidoptera (e.g. Heliotis), Garyi aphid lepidoptera (e.g. Heliotis), Garyi aphid lepidoptera (e.g. Heliotis), Garyi aphid lepidoptera (e.g. Heliotis) ), Garyi aphid lepidoptera (e.g. Heliotis), Garyi aphid lepidoptera (e.g. Heliotis), Garyi aphid cyst nematode nematodes (e.g. root-knot nematodes and cyst nematodes) nematodes (e.g. root-knot nematodes and cyst nematodes)

Crop: Pepper Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or optional polyphenol oxidase or polyphenol oxidase antisense Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), phenophylates, oxadiazoles, etc.Bacterial and fungal pathogens

Target or expression body (s) performed Crop Phenotype / Resistence Against Metallothioneinribonuclease Antifungal Polypeptides AlyAFP Oxalate Oxidase Glucose Oxidase Pyrrolenitrin Synthetic Gene Serine / Threonine Kinase Secropin Bphenylalanine Ammonia Lyase (PAL) Cf Gene (e.g. Cf9 Cf5 Cf4 Cf2) Morphinealpha-Hordonionine Cystemin Polygalacturonase Inhibitor Prf Regulatory Gene I2 Fusarium Resistant Sites PhytoAlexin B-1,3-Glucanase Antisense Receptor Kinase Polypeptide Systemic Acquired Resistance (SAR) Gene chitinase varnaze glucanase Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Rotting, fungal pathogens etc. Bacterial and fungal pathogens And fungal pathogens and fungal pathogens fungal and fungal pathogens fungal and fungal pathogens fungal and fungal pathogens fungal and fungal pathogens fungal and fungal pathogens fungal and fungal pathogens fungal and fungal pathogens Viral, Bacterial, Fungal, Nematode Pathogenic Bacterial and Fungal Pathogens Bacterial and Fungal Pathogens Bacterial and Fungal Pathogens

Target or expression body (s) performed Crop Phenotype / Resistence Against Double stranded ribonuclease coated protein 17 kDa or 60 kDa protein nucleus containing protein (e.g. a or b) or nucleic acid protein Pseudobiquitin replicaze Bacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus and xenor Hadoops toxin 3-hydroxysteroid oxidase peroxidase aminopeptidase inhibitor (e.g. leucine aminopeptidase inhibitor) lectin protease inhibitors (e.g. cystatin, patatin) Ribosome Inactivating Proteinstilbene Synthase HMG-CoA Reductase cyst nematode hatching irritation varnase Virus (eg CMV, TEV) Virus (eg CMV, TEV) Virus (eg CMV, TEV) Virus (eg CMV, TEV) Virus (eg CMV, TEV) Virus (eg CMV, TEV) Terra, Aphid aphid Lepidoptera, Arachid aphid Lepidoptera, Arachid aphid Lepidoptera, Arachid aphid Lepidoptera, Aleumid aphid lepidoptera, Aleumid aphid lepidopterra, Aleumid aphid lepidopterra, Aleumid aphid lepidoptera, Nematode aphid nematode nematodes (e.g. root-knot nematodes and cyst nematodes) nematodes (e.g. root-knot nematodes and cyst nematodes)

Crop: Grape Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or optional polyphenol oxidase or polyphenol oxidase antisense Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), bacterial and fungal pathogens (e.g. filamentous fungus and powdery mildew)

Target or expression body (s) performed Crop Phenotype / Resistence Against Metallothioneinribonuclease Antifungal Polypeptides AlyAFP Oxalate Oxidase Glucose Oxidase Pyrrolenitrin Synthetic Gene Serine / Threonine Kinase Secropin Bphenylalanine Ammonia Lyase (PAL) Cf Gene (e.g. Cf9 Cf5 Cf4 Cf2) Mortin Bacterial and fungal pathogens (eg filamentous and powdery mildew) Bacterial and fungal pathogens (eg filamentous and powdery mildew) Bacterial and fungal pathogens (eg filamentous and powdery mildew) Bacterial and fungal pathogens (eg filamentous and powdery mildew) Fungal pathogens (eg filamentous and powdery mildew) Bacterial and fungal pathogens (eg filamentous and powdery mildew) Bacterial and fungal pathogens (eg filamentous and powdery mildew) Bacterial and fungal pathogens (eg filamentous and powdery mildew) Bacterial and fungal Pathogens (eg filamentous and powdery mildew) Bacterial and fungal pathogens (eg filamentous and powdery mildew) Bacterial and fungal pathogens (eg filamentous and powdery mildew)

Target or expression body (s) performed Crop Phenotype / Resistence Against Alpha-Hordonionine Cystemin Polygalacturonase Inhibitor Prf Regulatory Gene PhytoAlexin B-1,3-Glucanase Antisense Receptor Kinase Polypeptide System Acquired Hypersensitivity Reaction (SAR) Gene Chitinazevarnazeglu Double stranded ribonuclease Bacterial and fungal pathogens (eg filamentous and powdery mildew) Bacterial and fungal pathogens (eg filamentous and powdery mildew) Bacterial and fungal pathogens (eg filamentous and powdery mildew) Bacterial and fungal pathogens (eg filamentous and powdery mildew) Fungal pathogens (eg filamentous and powdery mildew) Bacterial and fungal pathogens (eg filamentous and powdery mildew) Bacterial and fungal pathogens (eg filamentous and powdery mildew bacterial and fungal pathogens (eg filamentous fungus and powdery mildew) Fungal and nematode pathogens and fungal pathogens (e.g. filamentous and powdery mildew) fungal and fungal pathogens (e.g. filamentous and powdery mildew and fungal pathogens (e.g. filamentous and powdery mildew)

Target or expression body (s) performed Crop Phenotype / Resistence Against Covered protein 17 kDa or 60 kDa protein nucleus containing protein (e.g. a or b) or nucleic acid protein Pseudobiquitin replicazebacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus and xenorhabudus toxin 3-hydr Oxysteroid oxidase oxidase peroxidase aminopeptidase inhibitors (e.g. leucine aminopeptidase inhibitors) lectin protease inhibitors (e.g. cystatin, patatin) ribosomal inactivated proteinStilbene synthase HMG-CoA reductase cyst nematode hatching stimulation Varnaze CBI feed prevention body Virus Virus Virus Virus Virus Repidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid, Aphid, Disease , Aphid cyst nematodes (e.g., root-knot nematodes and cyst nematodes) or common diseases

Crops: Oil Seed Rape Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or optional polyphenol oxidase or polyphenol oxidase antisense Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), bacterial and fungal pathogens, e.g., phenophylates, oxadiazoles (e.g. cylindrosporium, poma, sclerotini)

Target or expression body (s) performed Crop Phenotype / Resistence Against Metallothioneinribonuclease Antifungal Polypeptides AlyAFP Oxalate Oxidase Glucose Oxidase Pyrrolenitrin Synthetic Gene Serine / Threonine Kinase Secropin Bphenylalanine Ammonia Lyase (PAL) Cf Gene (e.g. Cf9 Cf5 Cf4 Cf2) Mortin Bacterial and fungal pathogens (e.g. Cylindrosporium, Forma, Sclerotinia) Bacterial and fungal pathogens (e.g. Cylindrosporium, Poma, Sclerotinia) Bacterial and fungal pathogens (e.g. Cylindro) Sporium, Forma, Sclerotinia) Bacterial and Fungal Pathogens (e.g. Cylindrosporium, Forma, Sclerotinia) Bacterial and Fungal Pathogens (e.g. Cylindrosporium, Forma, Sclerotinia) Bacterial and fungal pathogens (e.g. Cylindrosporium, Forma, Sclerotinia) Bacterial and fungal pathogens (e.g. Cylindrosporium, Poma, Sclerotinia) Bacterial and fungal pathogens (e.g. Cylindro) Sporium, Forma, Sclerotinia) Bacterial and Fungal Pathogens (e.g. Cylindrosporium, Forma, Sclerotinia) Bacterial and Fungal Pathogens (e.g. Cylindrosporium, Forma, Sclerotinia) Bacterial and fungal pathogens (e.g. cylindersporium, poma, sclera) Tea Catania)

Target or expression body (s) performed Crop Phenotype / Resistence Against Alpha-HordothionecysteinePolygalacturonase InhibitorPrf Regulatory Gene PhytoAlexinsB-1,3-Glucanase Antisense Receptor Kinase Polypeptide Systemic Acquired Resistance (SAR) Gene Chitinazevarnazeglu Double stranded ribonuclease Bacterial and fungal pathogens (e.g. Cylindrosporium, Forma, Sclerotinia) Bacterial and fungal pathogens (e.g. Cylindrosporium, Poma, Sclerotinia) Bacterial and fungal pathogens (e.g. Cylindro) Sporium, Forma, Sclerotinia) Bacterial and Fungal Pathogens (e.g. Cylindrosporium, Forma, Sclerotinia) Bacterial and Fungal Pathogens (e.g. Cylindrosporium, Forma, Sclerotinia) Bacterial and fungal pathogens (e.g. Cylindrosporium, Forma, Sclerotinia) Bacterial and fungal pathogens (e.g. Cylindrosporium, Poma, Sclerotinia) Bacterial and fungal pathogens (e.g. Cylindro) (Sporium, poma, sclerotinia) Viral, bacterial, fungal, nematode pathogens Fungal and fungal pathogens (e.g. cylindersporium, poma, sclerotinia) Bacterial and fungal pathogens (e.g. cylinders) (Sporium, Forma, Sclerotinia) Bacterial and Fungal Won Kyun (eg cylinder volume draw Spokane, poma, Loti's Clemente California) virus

Target or expression body (s) performed Crop Phenotype / Resistence Against Covered protein 17 kDa or 60 kDa protein nucleus containing protein (e.g. a or b) or nucleic acid protein Pseudobiquitin replicazebacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus and xenorhabudus toxin 3-hydr Oxysteroid oxidase peroxidase aminopeptidase inhibitors (e.g. leucine aminopeptidase inhibitors) Lectin protease inhibitors (e.g. cystatin, patatin, CPTI) Ribosome inactivating proteinStilbene synthase HMG-CoA reductase cyst nematode Hatching Stimulation Varnase CBI Nematode Prevented Feeding Virus Virus Virus Virus Virus Repidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid, Aphid, Disease , Aphid cyst nematodes (eg root-knot nematodes and cyst nematodes) root-knot nematodes (eg root-knot nematodes or root cyst nematodes)

Crops: Brassica plants (cabbage, Brussels sprouts, broccoli, etc.) Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or optional polyphenol oxidase or polyphenol oxidase antisense Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), phenophylates, oxadiazoles, etc.Bacterial and fungal pathogens

Target or expression body (s) performed Crop Phenotype / Resistence Against Metallothioneinribonuclease Antifungal Polypeptides AlyAFP Oxalate Oxidase Glucose Oxidase Pyrrolenitrin Synthetic Gene Serine / Threonine Kinase Secropin Bphenylalanine Ammonia Lyase (PAL) Cf Gene (e.g. Cf9 Cf5 Cf4 Cf2) Motinalpha hordonthioninecysteminpolygalacturonase inhibitorPrf regulatory genePitolexins B-1,3-glucanase Antisense Receptor Kinase Polypeptide Systemic Acquired Resistance (ARS) Gene Chitinazevarnazeglu Canaz Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Bacterial and fungal pathogens Viral, bacterial, fungal Fungal, nematode pathogens and fungal pathogens fungal and fungal pathogens fungal and fungal pathogens

Target or expression body (s) performed Crop Phenotype / Resistence Against Double stranded ribonuclease coated protein 17 kDa or 60 kDa protein nucleus containing protein (e.g. a or b) or nucleic acid protein Pseudobiquitin replicaze Bacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus and xenor Hadoops toxin 3-hydroxysteroid oxidase peroxidase aminopeptidase inhibitors (e.g. leucine aminopeptidase inhibitors) lectin protease inhibitors (e.g. cystatin, patatin, CPTI) Ribosome Inactivating Proteinstilbene synthase HMG -CoA reductase cyst nematode hatching stimulation Varnase CBI nematode-induced feeding prevention body Virus VirusVirus VirusVirus VirusRepydoftera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid Lepidoptera, Aphid, Aphid Terra, aphid cyst nematodes (e.g. root-knot nematodes and cyst nematodes) root-knot nematodes (e.g. root-knot nematodes or root cyst nematodes)

Crops: Fruits (e.g. apples, pears) Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or optional polyphenol oxidase or polyphenol oxidase antisense Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas) Bacterial and fungal pathogens (e.g. apple spot or ovulation)

Target or expression body (s) performed Crop Phenotype / Resistence Against Metallothioneinribonuclease Antifungal Polypeptides AlyAFP Oxalate Oxidase Glucose Oxidase Pyrrolenitrin Synthetic Gene Serine / Threonine Kinase Secropin Bphenylalanine Ammonia Lyase (PAL) Cf Gene (e.g. Cf9 Cf5 Cf4 Cf2) Mortin Bacterial and fungal pathogens (e.g. apple spot or ovule) Bacterial and fungal pathogens (e.g. apple spot or ovule) Bacterial and fungal pathogens (e.g. apple spot or ovule) Bacterial and fungal pathogens (e.g. apple spot or Bacterial and fungal pathogens (e.g. apple spot or ovule) Bacterial and fungal pathogens (e.g. apple spot or ovulation) Bacterial and fungal pathogens (e.g. apple spot or ovulation) Bacterial and fungal pathogens (e.g. apple Bacterial and fungal pathogens (e.g. apple spot or ovule) Bacterial and fungal pathogens (e.g. apple spot or ovule) Bacterial and fungal pathogens (e.g. apple spot or ovule)

Target or expression body (s) performed Crop Phenotype / Resistence Against Alpha-hordothionecysteinepolygalacturonase inhibitorPrf regulatory gene PhytoAlexinB-1,3-glucanase Antisense Receptor Kinase Polypeptide System Acquired Resistance (SAR) Gene Lysing Protein Lysozyme Kinase Bacterial and fungal pathogens (e.g. apple spot or ovule) Bacterial and fungal pathogens (e.g. apple spot or ovule) Bacterial and fungal pathogens (e.g. apple spot or ovule) Bacterial and fungal pathogens (e.g. apple spot or Bacterial and fungal pathogens (e.g. apple spot or ovule) Bacterial and fungal pathogens (e.g. apple spot or ovulation) Bacterial and fungal pathogens (e.g. apple spot or ovulation) Bacterial and fungal pathogens (e.g. apple Spots or ovulation) Viral, bacterial, fungal, nematode pathogens Fungal and fungal pathogens (e.g. apple spot or ovule) Bacterial and fungal pathogens (e.g. apple spot or ovule) Bacterial and fungal pathogens (e.g. apple spot) Or ovulation)

Target or expression body (s) performed Crop Phenotype / Resistence Against GlucanaseDouble strand ribonuclease coat protein 17 kDa or 60 kDa protein nucleus containing protein (e.g. a or b) or nucleic acid protein Pseudobiquitin replicazebacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus And xenorharvus toxin 3-hydroxysteroid oxidase peroxidase aminopeptidase inhibitors (eg leucine aminopeptidase inhibitors) lectin protease inhibitors (eg cystatin, patatin, CPTI) ribosomal inactivated protein Synthase HMG-CoA reductase cyst nematode hatching stimulation varase Bacterial and fungal pathogens (e.g., apple spot or ovule) virus virus virus virus virus virus lepidoptera, aphid, mite lepidoptera, aphid, mite lepidoptera, aphid, mite lepidoptera, aphid, mite lepidoptera , Aphids, mite-lepidoptera, aphids, mite-lepidoptera, aphids, mite-lepidoptera, aphids, diseases, mite-lepidoptera, aphids, mite cyst nematodes (e.g., root-knot nematodes and cyst nematodes) Feed-resistant body caused by CBI nematode feeding site Root-knot nematodes (e.g., root-knot nematodes or root cyst nematodes)

Crop: Melon Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or optional polyphenol oxidase or polyphenol oxidase antisense Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), bacterial or fungal pathogens (e.g. phytophthora), phenophylates, oxadiazoles

Target or expression body (s) performed Crop Phenotype / Resistence Against Metallothioneinribonuclease Antifungal Polypeptides AlyAFP Oxalate Oxidase Glucose Oxidase Pyrrolenitrin Synthetic Gene Serine / Threonine Kinase Secropin Bphenylalanine Ammonia Lyase (PAL) Cf Gene (e.g. Cf9 Cf5 Cf4 Cf2) Morphine Alpha Hordothione Cysteine Polygalacturonase Inhibitor Prf Regulatory Gene PhytoAlexins B-1,3-Glucanase Antisense Receptor Kinase Polypeptide Systemic Acquired Resistance (SAR) Gene Lysing Protein Lysozyme Kinase Varnaze Bacterial or fungal pathogens (eg phytophthora) Bacterial or fungal pathogens (eg phytophthora) Bacterial or fungal pathogens (eg phytophthora) Bacterial or fungal pathogens (eg phytophthora) Bacterial or Fungal pathogens (e.g. phytophthora) Bacterial or fungal pathogens (e.g. phytophthora) Bacterial or fungal pathogens (e.g. phytophthora) Bacterial or fungal pathogens (e.g. phytophthora) Bacterial or fungal Pathogens (e.g. phytophthora) Bacterial or fungal pathogens (e.g. phytophthora) Bacterial or fungal pathogens (e.g. phytophthora) Bacterial or fungal pathogens (e.g. phytophthora) Bacterial or fungal pathogens ( Examples: Phytophthora Bacterial or fungal pathogens (eg phytophthora) Bacterial or fungal pathogens (eg phytophthora) Bacterial or fungal pathogens (eg phytophthora) Bacterial or fungal pathogens (eg Phytophthora) bacteria Fungal pathogens (e.g. phytophthora) Bacterial or fungal pathogens (e.g. phytophthora) Viral, bacterial, fungal, nematode pathogenic fungi or fungal pathogens (e.g. phytophthora) Bacterial or fungal pathogens ( Example: phytophthora) Bacterial or fungal pathogens (eg phytophthora) Bacterial or fungal pathogens (eg phytophthora)

Target or expression body (s) performed Crop Phenotype / Resistence Against GlucanaseDouble strand ribonuclease coat protein 17 kDa or 60 kDa protein nucleus containing protein (e.g. a or b) or nucleic acid protein Pseudobiquitin replicazebacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus And xenorharvus toxin 3-hydroxysteroid oxidase peroxidase aminopeptidase inhibitors (eg leucine aminopeptidase inhibitors) lectin protease inhibitors (eg cystatin, patatin, CPTI, viriferin) ribosomes Inactivated proteinStilbene synthase HMG-CoA reductase cyst nematode hatching stimulation varase Bacterial or fungal pathogens (e.g. phytophthora) viruses (e.g. CMV, PRSV, WMV2, SMV, ZYMV) viruses (e.g. CMV, PRSV, WMV2, SMV, ZYMV) viruses (e.g. CMV, PRSV, WMV2, SMV, ZYMV) Virus (e.g. CMV, PRSV, WMV2, SMV, ZYMV) Virus (e.g. CMV, PRSV, WMV2, SMV, ZYMV) Virus (e.g. CMV, PRSV, WMV2, SMV, ZYMV) Aphids, mites, aphids, mites, mallows, mites, aphids, mites, mallows, mallows, aphids, mites, mallows, mites, mallows, mites, mallows, mites, mites , Powdery lepidoptera, aphids, mites, powdery lepidoptera, aphids, mites, powdery lepidoptera, aphids, mites, nematode nematodes (e.g., root-knot nematodes and cyst nematodes) Feed-resistant body caused by CBI nematode feeding site Root-knot nematodes (e.g., root-knot nematodes or root cyst nematodes)

Crop: Banana Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or optional polyphenol oxidase or polyphenol oxidase antisense Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), phenophylates, oxadiazoles, etc.Bacterial or fungal pathogens

Target or expression body (s) performed Crop Phenotype / Resistence Against Metallothioneinribonuclease Antifungal Polypeptides AlyAFP Oxalate Oxidase Glucose Oxidase Pyrrolenitrin Synthetic Gene Serine / Threonine Kinase Secropin Bphenylalanine Ammonia Lyase (PAL) Cf Gene (e.g. Cf9 Cf5 Cf4 Cf2) Morphine Alpha Hordothione Cysteine Polygalacturonase Inhibitor Prf Regulatory Gene PhytoAlexins B-1,3-Glucanase Antisense Receptor Kinase Polypeptide Systemic Acquired Resistance (SAR) Gene Lysing Protein Lysozyme Kinase Varnaze Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens Viral, bacterial, fungal Fungal, nematode pathogenic bacteria or fungal pathogen bacterial or fungal pathogen bacterial or fungal pathogen bacterial or fungal pathogen

Target or expression body (s) performed Crop Phenotype / Resistence Against GlucanaseDouble strand ribonuclease coat protein 17 kDa or 60 kDa protein nucleus containing protein (e.g. a or b) or nucleic acid protein Pseudobiquitin replicazebacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus And xenorharvus toxin 3-hydroxysteroid oxidase peroxidase aminopeptidase inhibitors (eg leucine aminopeptidase inhibitors) lectin protease inhibitors (eg cystatin, patatin, CPTI, viriferin) ribosomes Inactivated Proteinstilbene Synthase HMG-CoA Reductase Encapsulation Nematode Incubation Stimulation Varnase CBI Nematodes Bacterial or fungal pathogen viruses (e.g. banana bunch top virus (BBTV)) viruses (e.g. banana bunch top virus (BBTV)) viruses (e.g. banana bunch top virus (BBTV)) viruses (e.g. banana bunch top virus (BBTV)) BBTV)) Viruses (e.g. Banana Bunch Upper Virus (BBTV)) Viruses (e.g. Banana Bunch Upper Virus (BBTV) Lepidoptera, Aphids, Mites, Nematode Lepidoptera, Aphids, Mites, Nematode Lepidoptera, Aphids, Mites, nematode repidotera, aphids, mites, nematode redodotera, aphids, mites, nematode reedoftera, aphids, mites, nematode reedofedera, aphids, mites, nematode reedopterra, aphids, mites, nematode reefdorf Terra, aphid, mite, nematode nematode nematodes (e.g., root-knot nematodes and cyst nematodes) root-knot nematodes (e.g., root-knot nematodes or root cyst nematodes)

Crop: Cotton Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or optional polyphenol oxidase or polyphenol oxidase antisense Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), phenophylates, oxadiazoles, etc.Bacterial or fungal pathogens

Target or expression body (s) performed Crop Phenotype / Resistence Against Metallothioneinribonuclease Antifungal Polypeptides AlyAFP Oxalate Oxidase Glucose Oxidase Pyrrolenitrin Synthetic Gene Serine / Threonine Kinase Secropin Bphenylalanine Ammonia Lyase (PAL) Cf Gene (e.g. Cf9 Cf5 Cf4 Cf2) Morphine Alpha Hordothione Cysteine Polygalacturonase Inhibitor Prf Regulatory Gene PhytoAlexins B-1,3-Glucanase Antisense Receptor Kinase Polypeptide Systemic Acquired Resistance (SAR) Gene Lysing Protein Lysozyme Kinase Varnaze Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens Viral, bacterial, fungal Fungal, nematode pathogenic bacteria or fungal pathogen bacterial or fungal pathogen bacterial or fungal pathogen bacterial or fungal pathogen

Target or expression body (s) performed Crop Phenotype / Resistence Against GlucanaseDouble strand ribonuclease coat protein 17 kDa or 60 kDa protein nucleus containing protein (e.g. a or b) or nucleic acid protein Pseudobiquitin replicazebacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus And xenorharvus toxin 3-hydroxysteroid oxidase peroxidase aminopeptidase inhibitors (eg leucine aminopeptidase inhibitors) lectin protease inhibitors (eg cystatin, patatin, CPTI, viriferin) ribosomes Inactivated proteinStilbene synthase HMG-CoA reductase cyst nematode hatching stimulation varase Bacterial or fungal pathogen viruses (eg wound tumor virus (WTV)) viruses (eg wound tumor virus (WTV)) viruses (eg wound tumor virus (WTV)) viruses (eg wound tumor virus (WTV)) viruses (E.g., wound tumor virus (WTV)) viruses (e.g., wound tumor virus (WTV) repidotera, aphids, mites, nematodes, nacreifidoptera, aphids, mites, nematodes, nacrepidopera, aphids, Mites, nematodes, M. lepidofera, aphids, mites, nematodes, M. lepidofera, aphids, mites, nematodes, M. lepidoptera, aphids, mites, nematodes, m. Lepidofera, aphids, mites, Nematodes, nacrepidopera, aphids, mites, nematodes, arachnidopido, aphids, mites, nematodes, sauropod nematode nematodes (e.g., root-knot nematodes and cyst nematodes) Feed-resistant body caused by CBI nematode feeding site Root-knot nematodes (e.g., root-knot nematodes or root cyst nematodes)

Crop: Sugar Cane Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or optional polyphenol oxidase or polyphenol oxidase antisense Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), phenophylates, oxadiazoles, etc.Bacterial or fungal pathogens

Target or expression body (s) performed Crop Phenotype / Resistence Against Metallothioneinribonuclease Antifungal Polypeptides AlyAFP Oxalate Oxidase Glucose Oxidase Pyrrolenitrin Synthetic Gene Serine / Threonine Kinase Secropin Bphenylalanine Ammonia Lyase (PAL) Cf Gene (e.g. Cf9 Cf5 Cf4 Cf2) Morphine Alpha Hordothione Cysteine Polygalacturonase Inhibitor Prf Regulatory Gene PhytoAlexins B-1,3-Glucanase Antisense Receptor Kinase Polypeptide Systemic Acquired Resistance (SAR) Gene Lysing Protein Lysozyme Kinase Varnaze Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens Fungal or fungal pathogens Viral, bacterial, fungal Fungal, nematode pathogenic fungi or fungal pathogens fungal or fungal pathogens (eg clavibacter) fungal or fungal pathogens fungal or fungal pathogens

Target or expression body (s) performed Crop Phenotype / Resistence Against GlucanaseDouble strand ribonuclease coat protein 17 kDa or 60 kDa protein nucleus containing protein (e.g. a or b) or nucleic acid protein Pseudobiquitin replicazebacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus And xenorharvus toxin 3-hydroxysteroid oxidase peroxidase aminopeptidase inhibitors (eg leucine aminopeptidase inhibitors) lectin protease inhibitors (eg cystatin, patatin, CPTI, viriferin) ribosomes Inactivated protein Bacterial or fungal pathogen viruses (eg SCMV, SrMV) Viruses (eg SCMV, SrMV) Viruses (eg SCMV, SrMV) Viruses (eg SCMV, SrMV) Viruses (eg SCMV, SrMV) Viruses (eg SCMV (SrMV) Repidoptera, aphid, mite, nematode, Garui, beetle (e.g. Mexican rice worm) Repidotera, aphid, mite, nematode, Garui, beetle (e.g. Mexican rice worm) , Mites, nematodes, powdery, beetles (e.g. mexican rice worms) repidoptera, aphids, mites, nematodes, garii, beetles (e.g. mexican rice worms) (E.g. mexican rice worms) lepidoptera, aphids, mites, nematodes, floury, beetles (e.g. mexican rice worms) lepidoptera, aphids, mites, nematodes, floury, beetles

Target or expression body (s) performed Crop Phenotype / Resistence Against Stilbene synthase HMG-CoA reductase cyst nematode hatching stimulation Lepidoptera, aphids, mites, nematodes, floury, beetles (e.g. Mexican rice worms) Lepidoptera, aphids, mites, nematodes, powdery, beetles (e.g. Mexican rice nectarines) And cyst nematodes) root-knot nematodes (eg root-knot nematodes or root cyst nematodes)

Crop: Sunflower Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or optional polyphenol oxidase or polyphenol oxidase antisense Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), phenophylates, oxadiazoles, etc.Bacterial or fungal pathogens

Target or expression body (s) performed Crop Phenotype / Resistence Against Metallothioneinribonuclease Antifungal Polypeptides AlyAFP Oxalate Oxidase Glucose Oxidase Pyrrolenitrin Synthetic Gene Serine / Threonine Kinase Secropin Bphenylalanine Ammonia Lyase (PAL) Cf Gene (e.g. Cf9 Cf5 Cf4 Cf2) Morphine Alpha Hordothione Cysteine Polygalacturonase Inhibitor Prf Regulatory Gene PhytoAlexins B-1,3-Glucanase Antisense Receptor Kinase Polypeptide Systemic Acquired Resistance (SAR) Gene Lysing Protein Lysozyme Kinase Varnaze Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens (eg sclerotinia) Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens or Fungal pathogens or fungal pathogens fungal or fungal pathogens fungal or fungal pathogens fungal or fungal pathogens fungal or fungal pathogens fungal or fungal pathogens fungal or fungal pathogens fungal or fungal pathogens fungal or fungal pathogens or fungal pathogens Fungal Pathogens Viral, bacterial, fungal, nematode pathogenic or fungal pathogens or fungal pathogens or fungal pathogens or fungal pathogens

Target or expression body (s) performed Crop Phenotype / Resistence Against GlucanaseDouble strand ribonuclease coat protein 17 kDa or 60 kDa protein nucleus containing protein (e.g. a or b) or nucleic acid protein Pseudobiquitin replicazebacillus thuringiensis toxin, VIP 3, Bacillus cereus toxin, photorabdus And xenorharvus toxin 3-hydroxysteroid oxidase peroxidase aminopeptidase inhibitors (eg leucine aminopeptidase inhibitors) lectin protease inhibitors (eg cystatin, patatin, CPTI, viriferin) ribosomes Inactivated protein Bacterial or fungal pathogen viruses (eg CMV, TMV) Viruses (eg CMV, TMV) Viruses (eg CMV, TMV) Viruses (eg CMV, TMV) Viruses (eg CMV, TMV) Viruses (eg CMV) , TMV) Lepidofera, aphid, mite, nematode, Garui, beetle Lepidoptera, aphid, mite, nematode, Garui, beetle Lepidoptera, aphid, mite, nematode, Garui, beetle Lepidopera, aphid, mite, Nematodes, muleid, beetle lepidoptera, aphids, mites, nematodes, muleids, beetle lepidoptera, aphids, mite, nematodes, muleids, beetle lepidoptera, aphids, mites, nematodes, muleids, beetles

Target or expression body (s) performed Crop Phenotype / Resistence Against Stilbene synthase HMG-CoA reductase cyst nematode hatching stimulation Lepidoptera, aphids, mites, nematodes, gourds, beetles lepidoptera, aphids, mites, nematodes, gourds, beetles nematodes nematodes (e.g. root-knot nematodes and cyst nematodes) )

Crops: Beetroot, Beetroot Target or expression body (s) performed Crop Phenotype / Resistence Against Acetolactate synthase (ALS) acetyl CoA carboxylase (ACCase) hydroxyphenylpyruvate deoxygenase (HPPD) phosphinothricin acetyl transferase O-methyl transferase glutamine synthetase adenylosuccinate lyase (ADSL) Adenilosuccinate synthase anthranilate synthase nitriase 5-enolpyrubil-3-phosphosikimate synthase (EPSPS) glyphosate oxidoreductase protoporpyrinogen oxidase (PROTOX) Cytochrome P450 (e.g. P450 SU1) or optional polyphenol oxidase or polyphenol oxidase antisense Sulfonylureas, imidazolinones, triazolopyrimidines, pyrimidyloxybenzoates, phthalidearyloxyphenoxyalkanecarboxylic acids, cyclohexanedione isoxazoles (e.g. isoxaflutol or isoxacoltol), tri Inhibitors of on (eg mesotrione or sulcotrione) phosphinothricin altered lignin level glufosinate, bialaphos IMP and AMP synthesis inhibitors of adenilosuccinate synthesis inhibitors of tryptophan synthesis and catabolism3, 5-dihalo-4-hydroxy-benzonitrile (eg bromocinyl and oxynyl) glyphosate or sulfosateglyphosate or sulfosatediphenylether, cyclic imide, phenylpyrazole, pyridine derivative Xenobiotics and herbicides (e.g. sulfonylureas), phenophylates, oxadiazoles, etc.Bacterial or fungal pathogens

Target or expression body (s) performed Crop Phenotype / Resistence Against Metallothioneinribonuclease Antifungal Polypeptides AlyAFP Oxalate Oxidase Glucose Oxidase Pyrrolenitrin Synthetic Gene Serine / Threonine Kinase Secropin Bphenylalanine Ammonia Lyase (PAL) Cf Gene (e.g. Cf9 Cf5 Cf4 Cf2) Motinalpha hordonthionine cystemine polygalacturonase inhibitor Prf regulatory gene Phytoalexins B-1,3-glucanase antisense AX + WIN protein receptor kinase A polypeptide-systemic acquired resistance (SAR) gene with a hypersensitivity response Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens (eg sclerotinia) Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens or Fungal pathogens or fungal pathogens fungal or fungal pathogens fungal or fungal pathogens or fungal pathogens fungal or fungal pathogens fungal or fungal pathogens or fungal pathogens fungal or fungal pathogens or fungal pathogens (eg : Sercospora beticola) Bacterial or fungal pathogens Bacterial or fungal pathogens Viral, bacterial, fungal, nematode pathogens

Target or expression body (s) performed Crop Phenotype / Resistence Against Lysed protein lysozyme chitinazevarnaze glucanase double stranded ribonuclease coat protein 17kDa or 60kDa protein nucleus containing protein (e.g. a or b) or nucleic acid protein Cereus toxin, photorabdus and xenorhavudus toxin 3-hydroxysteroid oxidase peroxidase aminopeptidase inhibitors (e.g. leucine aminopeptidase inhibitors) Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogens Bacterial or fungal pathogenic viruses (eg BNYVV) viruses (eg BMYVV) viruses (eg BNYVV) viruses (eg BMYVV) viruses (E.g., BNYVV) virus (e.g., BNYVV), Repidoptera, aphid, mite, nematode, Garui, beetle, root fly Lepidotera, aphid, mite, nematode, Garui, beetle, root fly lepidotera, aphid, mite , Nematodes, gourds, beetles, root fly lepidoptera, aphids, mites, nematodes, gourds, beetles, root fly

Target or expression body (s) performed Crop Phenotype / Resistence Against Lectin Protease Inhibitors (e.g. Cystatin, Patatin, CPTI, Birgiferrin) Ribosome Inactivating Proteinstilbene Synthase HMG-CoA Reductase Encapsulation Nematode Incubation main body Lepidoptera, aphids, mites, nematodes, Garui, beetle, root fly Lepidoptera, aphids, mites, nematodes, Garui, beetle, root fly Lepidofera, aphids, mites, nematodes, Garui, beetle, root fly lepidorf Terra, aphid, mite, nematode, kaleid, beetle, root fly lepidoptera, aphid, mite, nematode, kaleid, beetle, root fly cyst nematode (e.g. root-knot nematode and cyst nematode) Root-knot nematodes or root cyst nematodes)

The abovementioned animal pests which can be controlled by the method according to the invention (A) include, for example, insects, representative mite and representative nematodes:

Lepidoptera Acleris spp., Adoxophyes spp., In particular Adoxophyes reticulana; Aegeria spp., Agrotis spp., In particular Agrotis spinifera; Alabama argilaceae, Amylois spp., Anticarsia gemmatalis, Archips spp., Argyrotaenia spp., Autograph Sowing (Autographa spp.), Busseola fusca, Cadra cautella, Carposina nipponensis, Chilo spp., Coristoneura species (Choristoneura spp.), Clysia ambiguella, Cnaphalocrocis spp., Cnephasia spp., Cochylis spp., Coleophora species spp.), Crosidolomia binotalis, Cryptophlebia leucotreta, Cydia spp., in particular Cydia pomonella; Diatraea spp., Diparopsis castanea, Earias spp., Ephestia spp., In particular E. coli. Quinilla (E. Khuniella); Eucosma spp., Eupoecilia ambiguella, Euprotis spp., Euxos spp., Grapolita spp., Heco Hedya nubiferana, Heliothis spp., Especially H. H. virescenes and H. Zea (H. zea); Hellula undalis, Hyphantria cunea, Keiferia lycopersicella, Leucoptera scitella, Lithocollethis spp., Lobesia spp., Lymanthria spp., Lyonetia spp., Malacosoma spp., Mamestra brassicae, Manduca sex Manduca sexta, Operophtera spp., Ostrinia nubilalis, Pammene spp., Pandemis spp., Panolis flammea flammea, Pectinophora spp., Phthorimaea operculella, Pieris rapae, Pieris spp., Plutella xylostellala ), Price species (Prays spp.), Shirpophaga spp., Sesameia species (Sesamia spp.), Sparganothis spp., Spodopteralittoralis, Synanthedon spp., Thaumetopoea spp., Tortrix spp. , Tricoflucia ni and Iponomeuta spp. (Trichoplusia ni and Yponomeuta spp.);

From the order of Coleoptera, for example, Agriotes spp., Antonomus spp., Atomaria linearis, Catokonema tibialis, Cosmopolites spp., Curculio spp., Dermestes spp., Diabrotica spp., Epilachna spp., Erem Ernus spp., Leptinotarsa decemlineata, Lysorhoptrus spp., Melolota spp., Oryzaephilus spp. ), Otiorhynchus spp., Plicyctinus spp., Popillia spp., Psylliodes spp., Rhizopertha spp. ), Scarabeidae, Sitophilus spp., Sitotroga spp., Tenebrio spp. , Tribolium spp. And Trogoderma spp .;

Orthoptera, for example Blata spp. Blatella spp., Gryllotalpa spp., Leucophaea maderae, Locusta spp., Periplaneta spp. And Sisto Kerka species (Schistocerca spp.);

The order of Isoptera, for example Reticulitermes spp .;

From the order of Psocoptera, for example, Liposcelis spp .;

Anoplura, for example, Haematopinus spp., Linognathus spp., Pediculus spp., Pemphigus spp. ) And Phyloxera spp .;

The order Malallophaga, for example Damalinea spp. And Trichodextes spp .;

Thysanoptera, for example, Frankliniella spp., Hercinothrips spp., Taeniothrips spp., Tripps Palmi palmi), Tripps tabaci, and Cirtothrips aurantii;

From the order of Heteroptera, for example Cimex spp., Distantiella theobroma, Dysdercus spp., Euchistus spp. , Eurygaster spp., Leptocorisa spp., Nezara spp., Piesma spp., Rhodnius spp., Salber Sahlbergella singularis, Scotinophara spp. And Triatoma spp .;

Homooptera necks, for example Aleurothrixus floccosus, Aleyrodes brassicae, Aonidiella aurantii, Apididae Aphididae, Aphiscraccivora, A. A. fabae, a. A. gosypii, Aspidiotus spp., Bemisia tabaci, Ceroplaster spp., Chrysomphalus aonidium, Cresom Chalsomphalus dictyospermi, Cocus hesperidum, Empoasca spp., Eriosoma lanigerum, Erythroneura spp., Gaskar Diaspore (Gascardia spp.), Laodelphax spp., Lecanium corni, Lepidosaphes spp., Macrosiphus spp., Myuces species (Myzus spp.), Especially M. M. persicae; Nephotettix spp., In particular N. N. cincticeps; Nilaparvata spp., In particular N. N. lugens; Paratoria spp., Pemphigus spp., Planococcus spp., Pseudaulacaspis spp., Pseudococcus spp., Especially bloody. P. Fragilis, P. C. citriculus and P. P. comstocki; Psylla spp., In particular P. P. pyri; Pulvinaria aethiopica, Quadraspidiotus spp., Rhopalosiphum spp., Saissetia spp., Scaphoideus spp. ., Schizaphis spp., Sitobion spp., Trialeurodes vaporariorum, Trioza erytreae and Unaspis citri. citri);

The tree of Hymenoptera, for example Acromyrmex, Atta spp., Cephus spp., Diprion spp., Diprionidae Diprionidae, Gilpinia polytoma, Hoplocampa spp., Lasius spp., Monomorium pharaonis, Neodiprion spp., Solenopsis spp. And Vespa spp .;

Diptera, for example, Aedes spp., Antherigona soccata, Bibio hortulanus, Califora erythrocephala, Ceratitis spp., Chrysomyia spp., Culex spp., Cuterebra spp., Dacus spp., Dro Drosophila melanogaster, Fannia spp., Gastrophilus spp., Glossina spp., Hypoderma spp. Hippobos Hypobosca spp., Liriomyza spp., Lucilia spp., Melanagromyza spp., Musca spp., Oestrus species ( Oestrus spp., Orseolia spp., Oscinella frit, Pegomia hyoscyami, Phorbia spp., Lagore Rhagoletis pomonella, Sciara spp., Stomoxys spp., Tabanus spp., Tannia spp., And Tipula spp. .);

Siphonaptera, for example, Ceratophyllus spp. And Xenopsylla cheopis;

Thysanura necks such as Lepisma saccharina and

The tree of Acarina, for example Acarus siro, Aceria sheldoni; Aculus spp., In particular A. A. schlechtendali; Amblyomma spp., Argas spp., Boophilus spp., Brevipalpus spp., In particular B. spp. B. californicus and B. B. phoenicis; Bryobia praetiosa, Calipitrimerus spp., Chorioptes spp., Dermanyssus gallinae, Eotetranicus species spp.), especially this. Carpini and E. carpini. Orientalis (E. orientalis); Eriophyes spp., In particular E. E. vitis; Hyalomma spp., Ixodes spp., Oligonichus pratensis, Ornithodoros spp., Panonicus spp., In particular Bloody. P. ulmi and P. Citri (P. citri); Phylolocoptruta spp., In particular P. pylori. P. oleivora; Polyphagotarsonemus spp., In particular P. P. latus; Psoroptes spp., Lipicephalus spp., Rhizoglyphus spp., Sarcoptes spp., Tarsonemus spp. And Tetranychus spp., In particular T. T. urticae, tee. T. cinnabarinus and tee. Kanzawai;

Representative Nematodes:

(1) a nematode selected from the group consisting of root-knot nematodes, cyst forming nematodes, stem nematodes and leaf nematodes;

(2) Anguina spp .; Aphelenchoides spp .; Ditylenchus spp .; Globoderra spp., For example, Globodera rostochiensis; Heterodera spp. Such as Heterodera avenae, Heterodera glycines, Heterodera schachtii or Heterodera trifolii; Longidorus spp .; Meloidogyne spp., For example Meloidogyne incognita or Meloidogyne javanica; Pratylenkus, for example Pratylenkus neglectans or Pratylenkus penetrans; Radopholus spp., For example Radopholus similis; Trichodorus spp .; Tylenchulus, for example Tylenchulus semipenetrans; And nematodes selected from the group consisting of Xiphinema spp. Or

(3) Heterodera spp., For example, a nematode selected from the group consisting of heterodera glycine and Meloidogyne spp., For example Meloidogine incogita .

The method according to the present invention (A) is particularly useful for transgenic plants, mainly plants and ornamental plants useful for agriculture, horticulture and forests, or in parts such as fruits, flowers, leaves, stems, tubers or roots of such plants. Pests of the mentioned types can be controlled, ie controlled or destroyed, and in some cases even extended to the plant parts which are subsequently formed to protect against these pests.

The process according to the invention (A) comprises rice, cereals (eg corn or sorghum); Fruits, such as poultry, nucleus, and nectars (eg apples, pears, plums, peaches, almonds, cherries, strawberries, such as strawberry, raspberry and blackberry); Leguminous plants (eg, kidney beans, lentils, peas, soybeans); Fruit plants (eg, rape, mustard, poppy, olives, sunflowers, coconut, castor oil plants, cacao seeds, peanuts); Gourds (eg pumpkins, cucumbers, melons); Fibrous plants (eg cotton, flax, hemp, jute); Citrus plants (eg oranges, lemons, grapefruits, tangerines); Vegetables (eg, spinach, lettuce, asparagus, cabbage, carrots, onions, tomatoes, potatoes, beets or peppers); Laurel (eg avocados, cinnamon, camphor); Or tobacco, nuts, coffee, eggplant, sugarcane, tea, vines, hops, bananas and latex plants or flavours, mainly corn, rice, cereals, soybeans, tomatoes, cotton, potatoes, beets, rice and mustard, especially cotton It can be usefully used to control pests of rice, soybeans, potatoes and corn.

It can be seen that the method according to the invention (A) is prophylactically and / or therapeutically useful in the field of pest control, even at low concentrations of use of the pesticidal composition, and a very useful biocidal spectrum is thereby achieved. Combining useful miscible compositions for use in warm-blooded animals, fish and plants, the method according to the invention is not only sensitive to, but usually resistant to, depending on the type of transgenic crop to be protected from attack by pests. It can be used for each or all of the growth stages of animal pests such as insects and representative mite. The insecticidal and / or acaricide effects of the process according to the invention are directly, ie immediately induced or after a short time, for example, by destruction of the pest during infestation, or indirectly, for example, reduced scattering and / or Or it can be clearly seen as the hatching rate, the preferred action corresponding to the rate of destruction (lethality) is at least 40 to 50%.

Depending on the intended purpose and the environment to be overcome, pesticides which fall within the scope of the invention (A) which are known per se include emulsifiable concentrates, suspension concentrates, directly sprayable or dilutable solutions, macrophages comprising macrolide compounds, There are, for example, pastes, dilute emulsions, wettable powders, soluble powders, dispersible powders, wettable powders, powders, granules or capsules in polymeric materials.

The active ingredient is used in combination with one or more adjuvants, such as extenders (such as solvents or solid carriers) or surface active compounds (surfactants) commonly used in the field of formulations in these compositions.

Formulation aids used include, for example, solid carriers, solvents, stabilizers, "sustained release" auxiliaries, colorants and, optionally, surface active substances (surfactants). Suitable carriers and auxiliaries are all materials commonly used in crop protection products. Suitable auxiliaries such as solvents, solid carriers, surface active compounds, nonionic surfactants, cationic surfactants, anionic surfactants and other auxiliaries in the compositions used according to the invention are described, for example, in EP-A 736. It is described in 252.

These compositions for controlling pests can be formulated, for example, as wettable powders, powders, granules, solutions, emulsifiable concentrates, emulsions, suspension concentrates or aerosols. For example, the composition is of the type described in EP-A 736 252.

The action of the composition within the scope of the present invention (A) comprising a macrolide compound can be substantially extended and applied to the environment to be overcome by adding other pesticidal, acaricide and / or bactericidal active ingredients. Suitable examples of active ingredients to be added are the active ingredients of the following groups: organophosphorus compounds, nitrophenols and derivatives, formamidine, urea, carbamate, pyrethroids, chlorinated hydrocarbons, and particularly preferred components in the mixture are, for example, , Thiamethoxam, pymetrozine, phenoxycarb, imidacloprid, Ti-435, fipronil, pyriproxyfen, emamectin, diazinon or diapentthiuron.

Indeed, the composition of the present invention (A) comprises from 0.1 to 99% of macrolide compounds, in particular from 0.1 to 95% and from 1 to 99.9%, in particular from 5 to 99.9%, of at least one solid or liquid adjuvant, 0-25%, in particular 0.1-20%, may be a surfactant (in each case% means by weight). While concentrated compositions are more preferred as commercial products, end users use diluent compositions with active ingredients that are actually quite low in concentration.

The composition according to the present invention (A) also contains other solid or liquid auxiliaries, for example stabilizers (such as epoxidized or non-epoxidized vegetable oils such as epoxidized coconut oil, rapeseed oil or soybean oil), antifoams. (E.g. silicone oils, preservatives, viscosity modifiers, binders and / or tackifiers), and also fertilizers or other active ingredients (e.g. fungicides, nematicides, molluscicides) to achieve a particular effect. Or herbicides).

The composition according to the invention (A) is prepared in a known manner, for example by grinding, screening and / or compressing the active ingredient, for example to a particular particle size, prior to mixing with the adjuvant / adjuvant and Prepared by thoroughly mixing and / or grinding with the adjuvant / adjuvant.

The method according to the invention for controlling pests of the abovementioned forms depends on the intended purpose and the situation to be overcome, in a manner known per se to the person skilled in the art, ie spraying, wetting, spraying, spraying, brushing the composition. , Seed dressing, spawning or swelling. Typical use concentrations are from 0.1 to 1000 ppm, preferably from 0.1 to 500 ppm of active ingredient. Application rates can vary widely and include soil composition, type of application (leaf application; seed dressing; application to sows), transgenic crops, pests to be controlled, climatic environment to be overcome in each case, application form, application time and target It depends on other factors that are determined by the crop. The application rate per hectare is generally from 1 to 2000 g / ha of macrolides, in particular from 10 to 1000 g / ha, preferably from 10 to 500 g / ha, particularly preferably from 10 to 200 g / ha.

A preferred application form in the field of crop protection within the scope of the present invention (A) is the application to the leaves of plants (leaving applications), and the frequency and application rate can be selected for the risk of invasion by the pest. However, the active ingredient can also be planted throughout the root system by drenching the plant parts into the liquid composition or by incorporating (soil application) the active ingredient in solid form into the plant parts, for example into the soil in the form of granules. Can be introduced (system action). In the case of rice crops, granules can be weighed in freshwater.

The composition according to the invention (A) is also suitable for protecting the propagation material of the transgenic plant, for example seeds, fruit, tubers or grains, or plant cuts from animal pests, in particular insects and representative mite. The propagation material can be treated with the composition before application, for example the seed can be dressed before sowing. The active ingredient may also be applied (coated) to seed grains by immersing the grains in a liquid composition or by coating them with a solid composition. The composition can also be applied to the site of application when the propagation material is applied, for example, as a blister during sowing. These treatments for plant propagation material and the plant propagation material so treated are also objects of the present invention.

Examples of formulations of macrolide compounds that can be used in the process according to the invention (A) (e.g. solutions, granules, powders, sprayable powders, emulsion concentrates, coated granules and suspension concentrates) are, for example, In the form as described in EP-A 580 553, Examples F1 to F10.

TABLE B

The following abbreviations are used in the table:

Active Body of Transgenic Plants: AP

Porto Havuduus Luminesense: PL

Xenorhavudus Nematophilus: XN

Protease inhibitors: PInh.

Plant Lectin: Plec

Agglutinins: Aggl.

3-hydroxysteroid oxidase: HO

Cholesterol Oxidase: CO

Kitinases: CH

Glucanase: GL

Stilbencinase: SS

AP Control AP Control B.1 Cryl (A) a AdoxoPiece species B.5 Cryl (A) a Chilo bell B.2 Cryl (A) a Agrotis species B.6 Cryl (A) a Clicia Ambiguela B.3 Cryl (A) a Alabama Argyllaea B.7 Cryl (A) a Crosidolomia Vinotalis B.4 Cryl (A) a Anticarsia B.8 Cryl (A) Sitia Bell Gematalis B.9 Cryl (A) a Deeparossis Castanea

AP Control AP Control B.10 CrylA (a) Earias species B.38 CrylA (a) Aleirodes species B.11 CrylA (a) Ephesian species B.39 CrylA (a) Aonidiaella Bell B.12 CrylA (a) Heliotis species B.40 CrylA (a) Bell on Apidida B.13 CrylA (a) Hellula Undalis B.41 CrylA (a) Apis Bell B.14 CrylA (a) Kferia Ricopercicela B.42 CrylA (a) Bemisia Tabaki B.15 CrylA (a) Leukofterra Citella B.43 CrylA (a) Empoasca species B.16 CrylA (a) Litocholete species B.44 CrylA (a) Mycus species B.17 CrylA (a) Lovesia Boatana B.45 CrylA (a) Nepotetics species B.18 CrylA (a) Austrian Nubilis B.46 CrylA (a) Nilaparvata species B.19 CrylA (a) Pandemis species B.47 CrylA (a) Pseudococcus species B.20 CrylA (a) Pectinophora gossip. B.48 CrylA (a) Squill B.21 CrylA (a) Phyloxtis citella B.49 CrylA (a) Quadraspidiotus species B.22 CrylA (a) Fiery species B.50 CrylA (a) Sizapis Bell B.23 CrylA (a) Flutella xyllstella B.51 CrylA (a) Trialeurodes species B.24 CrylA (a) Sirpopaga species B.52 CrylA (a) Liriomyza species B.25 CrylA (a) Sesame B.53 CrylA (a) Osinella species B.26 CrylA (a) Spartanotis species B.54 CrylA (a) Forvia species B.27 CrylA (a) Spodovterra species B.55 CrylA (a) Franklinela Bell B.28 CrylA (a) Tortrix species B.56 CrylA (a) Tryps species B.29 CrylA (a) Tricofluciani B.57 CrylA (a) Sirtotrips Auranti B.30 CrylA (a) Agrites species B.58 CrylA (a) Acerian species B.31 CrylA (a) Antonomus Grandis B.59 CrylA (a) Aculus species B.32 CrylA (a) Curculio species B.60 CrylA (a) Brevipalpus species B.33 CrylA (a) Diabrotica Balteata B.61 CrylA (a) Panonicus Species B.34 CrylA (a) Leptinotarsa species B.62 CrylA (a) Philocoroot root species B.35 CrylA (a) Lysoloft species B.63 CrylA (a) Tetranicus species B.36 CrylA (a) Otorhinhinkus species B.64 CrylA (a) Heterodera species B.37 CrylA (a) Aleutrotrix species B.65 CrylA (b) Meloidogine species B.66 CrylA (b) AdoxoPiece species B.67 CrylA (b) Agrotis species B.68 CrylA (b) Alabama Argyllaea

AP Control AP Control B.69 CrylA (b) Anticarsia Gemmamatlis B.95 CrylA (b) Agrites species B.70 CrylA (b) Chilo bell B.96 CrylA (b) Antonomus Grandis B.71 CrylA (b) Clicia Ambiguela B.97 CrylA (b) Gourculo species B.72 CrylA (b) Crosidolomia Vinotalis B.98 CrylA (b) Diabrotica Balteata B.73 CrylA (b) Sidi A Species B.99 CrylA (b) Leptinotarsa species B.74 CrylA (b) Deeparossis Castanea B.100 CrylA (b) Lysoloft species B.75 CrylA (b) Earias species B.101 CrylA (b) Of Otorhinhinkusu B.76 CrylA (b) Efestia B.102 CrylA (b) Aleutrotrix species B.77 CrylA (b) Heliotis species B.103 CrylA (b) Aleirodes species B.78 CrylA (b) Hellula Undalis B.104 CrylA (b) Aonidiaella Bell B.79 CrylA (b) Kferia Ricopercicela B.105 CrylA (b) Bell on Apidida B.80 CrylA (b) Leukofterra Citella B.106 CrylA (b) Apis Bell B.81 CrylA (b) Litocholete species B.107 CrylA (b) Bemisia Tabaki B.82 CrylA (b) Lovesia Boatana B.108 CrylA (b) Empoasca species B.83 CrylA (b) Austrian Nubilis B.109 CrylA (b) Mycus species B.84 CrylA (b) Pandemis species B.110 CrylA (b) Nepotetics species B.85 CrylA (b) Pectinophora gossip. B.111 CrylA (b) Nilaparvata species B.86 CrylA (b) Phyloxtis citella B.112 CrylA (b) Pseudococcus species B.87 CrylA (b) Fiery species B.113 CrylA (b) Squill B.88 CrylA (b) Flutella xyllstella B.114 CrylA (b) Quadraspidiotus species B.89 CrylA (b) Sirpopaga species B.90 CrylA (b) Sesame B.115 CrylA (b) Sizapis Bell B.91 CrylA (b) Spartanotis species B.116 CrylA (b) Trialeurodes species B.92 CrylA (b) Spodovterra species B.117 CrylA (b) Liriomyza species B.93 CrylA (b) Tortrix species B.118 CrylA (b) Osinella species B.94 CrylA (b) Tricofluciani B.119 CrylA (b) Forvia species B.120 CrylA (b) Franklinela Bell B.121 CrylA (b) Tryps species B.122 CrylA (b) Sirtotrips Auranti B.123 CrylA (b) Acerian species B.124 CrylA (b) Aculus species

AP Control AP Control B.125 CrylA (b) Brevipalpus species B.151 CrylA (c) Phyloxtis citella B.126 CrylA (b) Panonicus Species B.152 CrylA (c) Fiery species B.127 CrylA (b) Philocoroot root species B.153 CrylA (c) Flutella xyllstella B.128 CrylA (b) Tetranicus species B.154 CrylA (c) Sirpopaga species B.129 CrylA (b) Heterodera species B.155 CrylA (c) Sesame B.130 CrylA (b) Meloidogine species B.156 CrylA (c) Spartanotis species B.131 CrylA (c) AdoxoPiece species B.157 CrylA (c) Spodovterra species B.132 CrylA (c) Agrotis species B.158 CrylA (c) Tortrix species B.133 CrylA (c) Alabama Argyllaea B.159 CrylA (c) Tricofluciani B.134 CrylA (c) Anticarsia Gemmamatlis B.160 CrylA (c) Agrites species B.135 CrylA (c) Chilo bell B.161 CrylA (c) Antonomus Grandis B.136 CrylA (c) Clicia Ambiguela B.162 CrylA (c) Curculio species B.137 CrylA (c) Crosidolomia Vinotalis B.163 CrylA (c) Diabrotica Balteata B.138 CrylA (c) Sidi A Species B.164 CrylA (c) Leptinotarsa species B.139 CrylA (c) Deeparossis Castanea B.165 CrylA (c) Lysoloft species B.140 CrylA (c) Earias species B.166 CrylA (c) Otorhinhinkus species B.141 CrylA (c) Efestia B.167 CrylA (c) Aleutrotrix species B.142 CrylA (c) Heliotis species B.168 CrylA (c) Aleirodes species B.143 CrylA (c) Hellula Undalis B.169 CrylA (c) Aonidiaella Bell B.144 CrylA (c) Kferia Ricopercicela B.170 CrylA (c) Bell on Apidida B.145 CrylA (c) Leukofterra Citella B.171 CrylA (c) Apis Bell B.146 CrylA (c) Litocholete species B.172 CrylA (c) Bemisia Tabaki B.147 CrylA (c) Lovesia Boatana B.173 CrylA (c) Empoasca species B.148 CrylA (c) Austrian Nubilis B.174 CrylA (c) Mycus species B.149 CrylA (c) Pandemis species B.175 CrylA (c) Nepotetics species B.150 CrylA (c) Pectinophora Gosipela B.176 CrylA (c) Nilaparvata species B.177 CrylA (c) Pseudococcus species B.178 CrylA (c) Squill B.179 CrylA (c) Quadraspidiotus species B.180 CrylA (c) Sizapis Bell

AP Control AP Control B.181 CrylA (c) Trialeurodes species B.209 Cryla Kferia Ricopercicela B.182 CrylA (c) Liriomyza species B.210 Cryla Leukofterra Citella B.183 CrylA (c) Osinella species B.211 Cryla Litocholete species B.184 CrylA (c) Forvia species B.212 Cryla Lovesia Boatana B.185 CrylA (c) Franklinela Bell B.213 Cryla Austrian Nubilis B.186 CrylA (c) Tryps species B.214 Cryla Pandemis species B.187 CrylA (c) Sirtotrips Auranti B.215 Cryla Pectinophora gossip. B.188 CrylA (c) Acerian species B.216 Cryla Phyloxtis citella B.189 CrylA (c) Aculus species B.217 Cryla Fiery species B.190 CrylA (c) Brevipalpus species B.218 Cryla Flutella xyllstella B.191 CrylA (c) Panonicus Species B.219 Cryla Sirpopaga species B.192 CrylA (c) Philocoroot root species B.220 Cryla Sesame B.193 CrylA (c) Terranicus species B.221 Cryla Spartanotis species B.194 CrylA (c) Heterodera species B.222 Cryla Spodovterra species B.195 CrylA (c) Meloidogine species B.223 Cryla Tortrix species B.196 CrylA (c) AdoxoPiece species B.224 Cryla Tricofluciani B.197 Cryla Agrotis species B.225 Cryla Agrites species B.198 Cryla Alabama Argyllaea B.226 Cryla Antonomus Grandis B.199 Cryla Anticarsia Gemmamatlis B.227 Cryla Curculio species B.200 Cryla Chilo bell B.228 Cryla Diabrotica Balteata B.201 Cryla Clicia Ambiguela B.229 Cryla Leptinotarsa species B.202 Cryla Crosidolomia Vinotalis B.230 Cryla Resorhofus species B.203 Cryla Sidi A Species B.231 Cryla Otorhinhinkus species B.204 Cryla Deeparossis Castanea B.232 Cryla Aleutrotrix species B.205 Cryla Earias species B.233 Cryla Aleirodes species B.206 Cryla Efestia B.234 Cryla Aonidiaella Bell B.207 Cryla Heliotis species B.235 Cryla Bell on Apidida B.208 Cryla Hellula Undalis B.236 Cryla Apis Bell B.237 Cryla Bemisia Tabaki

AP Control AP Control B.238 CryIIA Empoasca species B.267 CryIIIA Crosidolomia Vinotalis B.239 CryIIA Mycus species B.268 CryIIIA Sidi A Species B.240 CryIIA Nepotetics species B.269 CryIIIA Deeparossis Castanea B.241 CryIIA Nilaparvata species B.270 CryIIIA Earias species B.242 CryIIA Pseudococcus species B.271 CryIIIA Efestia B.243 CryIIA Squill B.272 CryIIIA Heliotis species B.244 CryIIA Quadraspidiotus species B.273 CryIIIA Hellula Undalis B.245 CryIIA Sizapis Bell B.274 CryIIIA Kferia Ricopercicela B.246 CryIIA Trialeurodes species B.275 CryIIIA Leukofterra Citella B.247 CryIIA Liriomyza species B.276 CryIIIA Litocholete species B.248 CryIIA Osinella species B.277 CryIIIA Lovesia Boatana B.249 CryIIA Forvia species B.278 CryIIIA Austrian Nubilis B.250 CryIIA Franklinela Bell B.279 CryIIIA Pandemis species B.251 CryIIA Tryps species B.280 CryIIIA Pectinophora gossip. B.252 CryIIA Sirtotrips Auranti B.281 CryIIIA Phyloxtis citella B.253 CryIIA Acerian species B.282 CryIIIA Fiery species B.254 CryIIA Aculus species B.283 CryIIIA Flutella xyllstella B.255 CryIIA Brevipalpus species B.284 CryIIIA Sirpopaga species B.256 CryIIA Panonicus Species B.285 CryIIIA Sesame B.257 CryIIA Philocoroot root species B.286 CryIIIA Spartanotis species B.258 CryIIA Tetranicus species B.287 CryIIIA Spodovterra species B.259 CryIIA Heterodera species B.288 CryIIIA Tortrix species B.260 CryIIA Meloidogine species B.289 CryIIIA Tricofluciani B.261 CryIIIA AdoxoPiece species B.290 CryIIIA Agrites species B.262 CryIIIA Agrotis species B.291 CryIIIA Antonomus Grandis B.263 CryIIIA Alabama Argyllaea B.292 CryIIIA Curculio species B.264 CryIIIA Anticarsia Gemmamatlis B.293 CryIIIA Diabrotica Balteata B.265 CryIIIA Chilo bell B.266 CryIIIA Clicia Ambiguela

AP Control AP Control B.294 CryIIIA Leftinotarsa species B.325 CryIIIA Meloidogine species B.295 CryIIIA Resorhofus species B.326 CryIIIB2 AdoxoPiece species B.296 CryIIIA Otorhinhinkus species B.327 CryIIIB2 Agrotis species B.297 CryIIIA Aleutrotrix species B.328 CryIIIB2 Alabama Argyllaea B.298 CryIIIA Aleirodes species B.329 CryIIIB2 Anticarsia Gemmamatlis B.299 CryIIIA Aonidiaella Bell B.330 CryIIIB2 Chilo bell B.300 CryIIIA Bell on Apidida B.331 CryIIIB2 Clicia Ambiguela B.301 CryIIIA Apis Bell B.332 CryIIIB2 Crosidolomia Vinotalis B.302 CryIIIA Bemisia Tabaki B.333 CryIIIB2 Cydia B.303 CryIIIA Empoasca species B.334 CryIIIB2 Deeparossis Castanea B.304 CryIIIA Mycus species B.335 CryIIIB2 Earias species B.305 CryIIIA Nepotetics species B.336 CryIIIB2 Efestia B.306 CryIIIA Nilaparvata species B.337 CryIIIB2 Heliotis species B.307 CryIIIA Pseudococcus species B.338 CryIIIB2 Hellula Undalis B.308 CryIIIA Squill B.339 CryIIIB2 Kferia Ricopercicela B.309 CryIIIA Quadraspidiotus species B.340 CryIIIB2 Leukofterra Citella B.310 CryIIIA Sizapis Bell B.341 CryIIIB2 Litocholete species B.311 CryIIIA Trialeurodes species B.342 CryIIIB2 Lovesia Boatana B.312 CryIIIA Liriomyza species B.343 CryIIIB2 Austrian Nubilis B.313 CryIIIA Osinella species B.344 CryIIIB2 Pandemis species B.314 CryIIIA Forvia species B.345 CryIIIB2 Pectinophora gossip. B.315 CryIIIA Franklinela Bell B.346 CryIIIB2 Phyloxtis citella B.316 CryIIIA Tryps species B.347 CryIIIB2 Fiery species B.317 CryIIIA Sirtotrips Auranti B.348 CryIIIB2 Flutella xyllstella B.318 CryIIIA Acerian species B.349 CryIIIB2 Sirpopaga species B.319 CryIIIA Aculus species B.350 CryIIIB2 Sesame B.320 CryIIIA Brevipalpus species B.321 CryIIIA Panonicus Species B.322 CryIIIA Philocoroot root species B.323 CryIIIA Tetranicus species B.324 CryIIIA Heterodera species

AP Control AP Control B.351 CryIIIB2 Spartanotis species B.381 CryIIIB2 Tryps species B.352 CryIIIB2 Spodovterra species B.382 CryIIIB2 Sirtotrips Auranti B.353 CryIIIB2 Tortrix species B.383 CryIIIB2 Acerian species B.354 CryIIIB2 Tricofluciani B.384 CryIIIB2 Aculus species B.355 CryIIIB2 Agrites species B.385 CryIIIB2 Brevipalus species B.356 CryIIIB2 Antonomus Grandis B.386 CryIIIB2 Panonicus Species B.357 CryIIIB2 Curculio species B.387 CryIIIB2 Philocoroot root species B.358 CryIIIB2 Diabrotica Balteata B.388 CryIIIB2 Tetranicus species B.359 CryIIIB2 Leptinotarsa species B.389 CryIIIB2 Heterodera species B.360 CryIIIB2 Resorhofus species B.390 CryIIIB2 Meloidogine species B.361 CryIIIB2 Otorhinhinkus species B.391 CytA AdoxoPiece species B.362 CryIIIB2 Aleutrotrix species B.392 CytA Agrotis species B.363 CryIIIB2 Aleirodes species B.393 CytA Alabama Argyllaea B.364 CryIIIB2 Aonidiaella Bell B.394 CytA Anticarsia Gemmamatlis B.365 CryIIIB2 Bell on Apidida B.395 CytA Chilo bell B.366 CryIIIB2 Apis Bell B.396 CytA Clicia Ambiguela B.367 CryIIIB2 Bemisia Tabaki B.397 CytA Crosidolomia Vinotalis B.368 CryIIIB2 Empoasca species B.398 CytA Sidi A Species B.369 CryIIIB2 Mycus species B.399 CytA Deeparossis Castanea B.370 CryIIIB2 Nepotetics species B.400 CytA Earias species B.371 CryIIIB2 Nilaparvata species B.401 CytA Efestia B.372 CryIIIB2 Pseudococcus species B.402 CytA Heliotis species B.373 CryIIIB2 Squill B.403 CytA Hellula Undalis B.374 CryIIIB2 Quadraspidiotus species B.404 CytA Kferia Ricopercicela B.375 CryIIIB2 Sizapis Bell B.405 CytA Leukofterra Citella B.376 CryIIIB2 Trialeurodes species B.406 CytA Litocholete species B.377 CryIIIB2 Liriomyza species B.407 CytA Lovesia Boatana B.378 CryIIIB2 Osinella species B.379 CryIIIB2 Forvia species B.380 CryIIIB2 Franklinela Bell

AP Control AP Control B.408 CytA Austrian Nubilis B.438 CytA Squill B.409 CytA Pandemis species B.439 CytA Quadraspidiotus species B.410 CytA Pectinophora gossip. B.440 CytA Sizapis Bell B.411 CytA Phyloxtis citella B.441 CytA Trialeurodes species B.412 CytA Fiery species B.442 CytA Liriomyza species B.413 CytA Flutella xyllstella B.443 CytA Osinella species B.414 CytA Sirpopaga species B.444 CytA Forvia species B.415 CytA Sesame B.445 CytA Franklinela Bell B.416 CytA Spartanotis species B.446 CytA Tryps species B.417 CytA Spodovterra species B.447 CytA Sirtotrips Auranti B.418 CytA Tortrix species B.448 CytA Acerian species B.419 CytA Tricofluciani B.449 CytA Aculus species B.420 CytA Agrites species B.450 CytA Brevipalpus species B.421 CytA Atonomus Grandis B.451 CytA Panonicus Species B.422 CytA Curculio species B.452 CytA Philocoroot root species B.423 CytA Diabrotica Balteata B.453 CytA Tetranicus species B.424 CytA Leptinotarsa species B.454 CytA Heterodera species B.425 CytA Resorhofus species B.455 CytA Meloidogine species B.426 CytA Otorhinhinkus species B.456 VIP3 AdoxoPiece species B.427 CytA Aleutrotrix species B.457 VIP3 Agrotis species B.428 CytA Aleirodes species B.458 VIP3 Alabama Argyllaea B.429 CytA Aonidiaella Bell B, 459 VIP3 Anticarsia Gemmamatlis B.430 CytA Bell on Apidida B.460 VIP3 Chilo bell B.431 CytA Apis Bell B.461 VIP3 Clicia Ambiguela B.432 CytA Bemisia Tabaki B.462 VIP3 Crosidolomia Vinotalis B.433 CytA Empoasca species B.463 VIP3 Sidi A Species B.434 CytA Mycus species B.464 VIP3 Deeparossis Castanea B.435 CytA Nepotetics species B.436 CytA Nilaparvata species B.437 CytA Pseudococcus species

AP Control AP Control B.465 VIP3 Earias species B.494 VIP3 Aonidiaella Bell B.466 VIP3 Efestia B.495 VIP3 Bell on Apidida B.467 VIP3 Heliotis species B.496 VIP3 Apis Bell B.468 VIP3 Hellula Undalis B.497 VIP3 Bemisia Tabaki B.469 VIP3 Kferia Ricopercicela B.498 VIP3 Empoasca species B.470 VIP3 Leukofterra Citella B.499 VIP3 Mycus species B.471 VIP3 Litocholete species B.500 VIP3 Nepotetics species B.472 VIP3 Lovesia Boatana B.501 VIP3 Nilaparvata species B.473 VIP3 Austrian Nubilis B.502 VIP3 Pseudococcus species B.474 VIP3 Pandemis species B.503 VIP3 Squill B.475 VIP3 Pectinophora gossip. B.504 VIP3 Quadraspidiotus species B.476 VIP3 Phyloxtis citella B.505 VIP3 Sizapis Bell B.477 VIP3 Fiery species B.506 VIP3 Trialeurodes species B.478 VIP3 Flutella xyllstella B.507 VIP3 Liriomyza species B.479 VIP3 Sirpopaga species B.508 VIP3 Osinella species B.480 VIP3 Sesame B.509 VIP3 Forvia species B.481 VIP3 Spartanotis species B.510 VIP3 Franklinela Bell B.482 VIP3 Spodovterra species B.511 VIP3 Tryps species B.483 VIP3 Tortrix species B.512 VIP3 Sirtotrips Auranti B.484 VIP3 Tricofluciani B.513 VIP3 Acerian species B.485 VIP3 Agrites species B.514 VIP3 Aculus species B.486 VIP3 Antonomus Grandis B.515 VIP3 Brevipalpus species B.487 VIP3 Curculio species B.516 VIP3 Panonicus Species B.488 VIP3 Diabrotica Balteata B.517 VIP3 Philocoroot root species B.489 VIP3 Leptinotarsa species B.518 VIP3 Tetranicus species B.490 VIP3 Resorhofus species B.519 VIP3 Heterodera species B.491 VIP3 Otorhinhinkus species B.520 VIP3 Meloidogine species B.492 VIP3 Aleutrotrix species B.521 GL AdoxoPiece species B.493 VIP3 Aleirodes species B.522 GL Agrotis species B.523 GL Alabama Argyllaea

AP Control AP Control B.524 GL Anticarsia Gemmamatlis B.551 GL Antonomus Grandis B.525 GL Chilo bell B.552 GL Curculio species B.526 GL Clicia Ambiguela B.553 GL Diabrotica Balteata B.527 GL Crosidolomia Vinotalis B.554 GL Leptinotarsa species B.528 GL Sidi A Species B.555 GL Resorhofus species B.529 GL Deeparossis Castanea B.556 GL Otorhinhinkus species B.530 GL Earias species B.557 GL Aleutrotrix species B.531 GL Efestia B.558 GL Aleirodes species B.532 GL Heliotis species B.559 GL Aonidiaella Bell B.533 GL Hellula Undalis B.560 GL Bell on Apidida B.534 GL Kferia Ricopercicela B.561 GL Apis Bell B.535 GL Leukofterra Citella B.562 GL Bemisia Tabaki B.536 GL Litocholete species B.563 GL Empoasca species B.537 GL Lovesia Boatana B.564 GL Mycus species B.538 GL Austrian Nubilis B.565 GL Nepotetics species B.539 GL Pandemis species B.566 GL Nilaparvata species B.540 GL Pectinophora gossip. B.567 GL Pseudococcus species B.541 GL Phyloxtis citella B.568 GL Squill B.542 GL Fiery species B.569 GL Quadraspidiotus species B.543 GL Flutella xyllstella B.570 GL Sizapis Bell B.544 GL Sirpopaga species B.571 GL Trialeurodes species B.545 GL Sesame B.572 GL Liriomyza species B.546 GL Spartanotis species B.573 GL Osinella species B.547 GL Spodovterra species B.574 GL Forvia species B.548 GL Tortrix species B.575 GL Franklinela Bell B.549 GL Tricofluciani B.576 GL Tryps species B.550 GL Agrites species B.577 GL Sirtotrips Auranti B.578 GL Acerian species B.579 GL Aculus species B.580 GL Brevipalpus species

AP Control AP Control B.581 GL Panonicus Species B.607 PL Fiery species B.582 GL Philocoroot root species B.608 PL Flutella xyllstella B.583 GL Tetranicus species B.609 PL Sirpopaga species B.584 GL Heterodera species B.610 PL Sesame B.585 GL Meloidogine species B.611 PL Spartanotis species B.586 PL AdoxoPiece species B.612 PL Spodovterra species B.587 PL Agrotis species B.613 PL Tortrix species B.588 PL Alabama Argyllaea B.614 PL Tricofluciani B.589 PL Anticarsia Gemmamatlis B.615 PL Agrites species B.590 PL Chilo bell B.616 PL Antonomus Grandis B.591 PL Clicia Ambiguela B.617 PL Curculio species B.592 PL Crosidolomia Vinotalis B.618 PL Diabrotica Balteata B.593 PL Sidi A Species B.619 PL Leptinotarsa species B.594 PL Deeparossis Castanea B.620 PL Resorhofus species B.595 PL Earias species B.621 PL Othioh Hintus species B.596 PL Efestia B.622 PL Aleutrotrix species B.597 PL Heliotis species B.623 PL Aleirodes species B.598 PL Hellula Undalis B.624 PL Aonidiaella Bell B.599 PL Kferia Ricopercicela B.625 PL Bell on Apidida B.600 PL Leukofterra Citella B.626 PL Apis Bell B.601 PL Litocholete species B.627 PL Bemisia Tabaki B.602 PL Lovesia Boatana B.628 PL Empoasca species B.603 PL Austrian Nubilis B.629 PL Mycus species B.604 PL Pandemis species B.630 PL Nepotetics species B.605 PL Pectinophora gossip. B.631 PL Nilaparvata species B.606 PL Phyloxtis citella B.632 PL Pseudococcus species B.633 PL Squill B.634 PL Quadraspidiotus species B.635 PL Sizapis Bell B.636 PL Trialeurodes species

AP Control AP Control B.637 PL Liriomyza species B.665 XN Leukofterra Citella B.638 PL Osinella species B.666 XN Litocholete species B.639 PL Forvia species B.667 XN Lovesia Boatana B.640 PL Franklinela Bell B.668 XN Austrian Nubilis B.641 PL Tryps species B.669 XN Pandemis species B.642 PL Sirtotrips Auranti B.670 XN Pectinophora gossip. B.643 PL Acerian species B.671 XN Phyloxtis citella B.644 PL Aculus species B.672 XN Fiery species B.645 PL Brevipalpus species B.673 XN Flutella xyllstella B.646 PL Panonicus Species B.674 XN Sirpopaga species B.647 PL Philocoroot root species B.675 XN Sesame B.648 PL Tetranicus species B.676 XN Spartanotis species B.649 PL Heterodera species B.677 XN Spodovterra species B.650 PL Meloidogine species B.678 XN Tortrix species B.651 XN AdoxoPiece species B.679 XN Tricofluciani B.652 XN Agrotis species B.680 XN Agrites species B.653 XN Alabama Argyllaea B.681 XN Antonomus Grandis B.654 XN Anticarsia Gemmamatlis B.682 XN Curculio species B.655 XN Chilo bell B.683 XN Diabrotica Balteata B.656 XN Clicia Ambiguela B.684 XN Leptinotarsa species B.657 XN Crosidolomia Vinotalis B.685 XN Resorhofus species B.658 XN Sidi A Species B.686 XN Otorhinhinkus species B.659 XN Deeparossis Castanea B.687 XN Aleutrotrix species B.660 XN Earias species B.688 XN Aleirodes species B.661 XN Efestia B.689 XN Aonidiaella Bell B.662 XN Heliotis species B.690 XN Bell on Apidida B.663 XN Hellula Undalis B.691 XN Apis Bell B.664 XN Kferia Ricopercicela B.692 XN Bemisia Tabaki B.693 XN Empoasca species

AP Control AP Control B.694 XN Mycus species B.723 Plnh. Sidi A Species B.695 XN Nepotetics species B.724 Plnh. Deeparossis Castanea B.696 XN Nilaparvata species B.725 Plnh. Earias species B.697 XN Pseudococcus species B.726 Plnh. Efestia B.698 XN Squill B.727 Plnh. Heliotis species B.699 XN Quadraspidiotus species B.728 Plnh. Hellula Undalis B.700 XN Sizapis Bell B.729 Plnh. Kferia Ricopercicela B.701 XN Trialeurodes species B.730 Plnh. Leukofterra Citella B.702 XN Liriomyza species B.731 Plnh. Litocholete species B.703 XN Osinella species B.732 Plnh. Lovesia Boatana B.704 XN Forvia species B.733 Plnh. Austrian Nubilis B.705 XN Franklinela Bell B.734 Plnh. Pandemis species B.706 XN Tryps species B.735 Plnh. Pectinophora gossip. B.707 XN Sirtotrips Aruranti B.736 Plnh. Phyloxtis citella B.708 XN Acerian species B.737 Plnh. Fiery species B.709 XN Aculus species B.738 Plnh. Flutella xyllstella B.710 XN Brevipalpus species B.739 Plnh. Sirpopaga species B.711 XN Panonicus Species B.740 Plnh. Sesame B.712 XN Philocoroot root species B.741 Plnh. Spartanotis species B.713 XN Tetranicus species B.742 Plnh. Spodovterra species B.714 XN Heterodera species B.743 Plnh. Tortrix species B.715 XN Meloidogine species B.744 Plnh. Tricofluciani B.716 Plnh. AdoxoPiece species B.745 Plnh. Agrites species B.717 Plnh. Agrotis species B.746 Plnh. Antonomus Grandis B.718 Plnh. Alabama Argyllaea B.747 Plnh. Curculio species B.719 Plnh. Anticarsia Gemmamatlis B.748 Plnh. Diabrotica Balteata B.720 Plnh. Chilo bell B.749 Plnh. Leptinotarsa species B.721 Plnh. Clicia Ambiguela B.722 Plnh. Crosidolomia Vinotalis

AP Control AP Control B.750 Plnh. Lysorhofturus B.781 Plec AdoxoPiece species B.751 Plnh. Otorhinhinkus species B.782 Plec Agrotis species B.752 Plnh. Aleutrotrix species B.783 Plec Alabama Argyllaea B.753 Plnh. Aleirodes species B.784 Plec Anticarsia Gemmamatlis B.754 Plnh. Aonidiaella Bell B.785 Plec Chilo bell B.755 Plnh. Bell on Apidida B.786 Plec Clicia Ambiguela B.756 Plnh. Apis Bell B.787 Plec Crosidolomia Vinotalis B.757 Plnh. Bemisia Tabaki B.788 Plec Sidi A Species B.758 Plnh. Empoasca species B.789 Plec Deeparossis Castanea B.759 Plnh. Mycus species B.790 Plec Earias species B.760 Plnh. Nepotetics species B.791 Plec Efestia B.761 Plnh. Nilaparvata species B.792 Plec Heliotis species B.762 Plnh. Pseudococcus species B.793 Plec Hellula Undalis B.763 Plnh. Squill B.794 Plec Kferia Ricopercicela B.764 Plnh. Quadraspidiotus species B.795 Plec Leukofterra Citella B.765 Plnh. Sizapis Bell B.796 Plec Litocholete species B.766 Plnh. Trialeurodes species B.797 Plec Lovesia Boatana B.767 Plnh. Liriomyza species B.798 Plec Austrian Nubilis B.768 Plnh. Osinella species B.799 Plec Pandemis species B.769 Plnh. Forvia species B.800 Plec Pectinophora gossip. B.770 Plnh. Franklinela Bell B.801 Plec Phyloxtis citella B.771 Plnh. Tryps species B.802 Plec Fiery species B.772 Plnh. Sirtotrips Auranti B.803 Plec Flutella xyllstella B.773 Plnh. Acerian species B.804 Plec Sirpopaga species B.774 Plnh. Aculus species B.805 Plec Sesame B.775 Plnh. Brevipalpus species B.806 Plec Spartanotis species B.776 Plnh. Panonicus Species B.777 Plnh. Philocoroot root species B.778 Plnh. Tetranicus species B.779 Plnh. Heterodera species B.780 Plnh. Meloidogine species

AP Control AP Control B.807 Plec Spodovterra species B.837 Plec Sirtotrips Auranti B.808 Plec Tortrix species B.838 Plec Acerian species B.809 Plec Tricofluciani B.839 Plec Aculus species B.810 Plec Agrites species B.840 Plec Brevipalpus species B.811 Plec Antonomus Grandis B.841 Plec Panonicus Species B.812 Plec Curculio species B.842 Plec Philocoroot root species B.813 Plec Diabrotica Balteata B.843 Plec Tetranicus species B.814 Plec Leptinotarsa species B.844 Plec Heterodera species B.815 Plec Resorhofus species B.845 Plec Meloidogine species B.816 Plec Otorhinhinkus species B.846 Aggl. AdoxoPiece species B.817 Plec Aleutrotrix species B.847 Aggl. Agrotis species B.818 Plec Aleirodes species B.848 Aggl. Alabama Argyllaea B.819 Plec Aonidiaella Bell B.849 Aggl. Anticarsia Gemmamatlis B.820 Plec Bell on Apidida B.850 Aggl. Chilo bell B.821 Plec Apis Bell B.581 Aggl. Clicia Ambiguela B.822 Plec Bemisia Tabaki B.852 Aggl. Crosidolomia Vinotalis B.823 Plec Empoasca species B.853 Aggl. Sidi A Species B.824 Plec Mycus species B.854 Aggl. Deeparossis Castanea B.825 Plec Nepotetics species B.855 Aggl. Earias species B.826 Plec Nilaparvata species B.856 Aggl. Efestia B.827 Plec Pseudococcus species B.857 Aggl. Heliotis species B.828 Plec Squill B.858 Aggl. Hellula Undalis B.829 Plec Quadraspidiotus species B.859 Aggl. Kferia Ricopercicela B.830 Plec Sizapis Bell B.860 Aggl. Leukofterra Citella B.831 Plec Trialeurodes species B.861 Aggl. Litocholete species B.832 Plec Liriomyza species B.862 Aggl. Lovesia Boatana B.833 Plec Osinella species B.863 Aggl. Austrian Nubilis B.834 Plec Forvia species B.835 Plec Franklinela Bell B.836 Tryps species

AP Control AP Control B.864 Aggl. Pandemis species B.894 Aggl. Quadraspidiotus species B.865 Aggl. Pectinophora gossip. B.895 Aggl. Sizapis Bell B.866 Aggl. Phyloxtis citella B.896 Aggl. Trialeurodes species B.867 Aggl. Fiery species B.897 Aggl. Liriomyza species B.868 Aggl. Flutella xyllstella B.898 Aggl. Osinella species B.869 Aggl. Sirpopaga species B.899 Aggl. Forvia species B.870 Aggl. Sesame B.900 Aggl. Franklinela Bell B.871 Aggl. Spartanotis species B.901 Aggl. Tryps species B.872 Aggl. Spodovterra species B.902 Aggl. Sirtotrips Auranti B.873 Aggl. Tortrix species B.903 Aggl. Acerian species B.874 Aggl. Tricofluciani B.904 Aggl. Aculus species B.875 Aggl. Agrites species B.905 Aggl. Brevipalpus species B.876 Aggl. Antonomus Grandis B.906 Aggl. Panonicus Species B.877 Aggl. Curculio species B.907 Aggl. Philocoroot root species B.878 Aggl. Diabrotica Balteata B.908 Aggl. Tetranicus species B.879 Aggl. Leptinotarsa species B.909 Aggl. Heterodera species B.880 Aggl. Resorhofus species B.910 Aggl. Meloidogine species B.881 Aggl. Otorhinhinkus species B.911 CO AdoxoPiece species B.882 Aggl. Aleutrotrix species B.912 CO Agrotis species B.883 Aggl. Aleirodes species B.913 CO Alabama Argyllaea B.884 Aggl. Aonidiaella Bell B.914 CO Anticarsia Gemmamatlis B.885 Aggl. Bell on Apidida B.915 CO Chilo bell B.886 Aggl. Apis Bell B.916 CO Clicia Ambiguela B.887 Aggl. Bemisia Tabaki B.917 CO Crosidolomia Vinotalis B.888 Aggl. Empoasca species B.918 CO Sidi A Species B.889 Aggl. Mycus species B.919 CO Deeparossis Castanea B.890 Aggl. Nepotetics species B.920 CO Earias species B.891 Aggl. Nilaparvata species B.892 Aggl. Pseudococcus species B.893 Aggl. Squill

AP Control AP Control B.921 CO Efestia B.950 CO Bell on Apidida B.922 CO Heliotis species B.951 CO Apis Bell B.923 CO Hellula Undalis B.952 CO Bemisia Tabaki B.924 CO Kferia Ricopercicela B.953 CO Empoasca species B.925 CO Leukofterra Citella B.954 CO Mycus species B.926 CO Litocholete species B.955 CO Nepotetics species B.927 CO Lovesia Boatana B.956 CO Nilaparvata species B.928 CO Austrian Nubilis B.957 CO Pseudococcus species B.929 CO Pandemis species B.958 CO Squill B.930 CO Pectinophora gossip. B.959 CO Quadraspidiotus species B.931 CO Phyloxtis citella B.960 CO Sizapis Bell B.932 CO Fiery species B.961 CO Trialeurodes species B.933 CO Flutella xyllstella B.962 CO Liriomyza species B.934 CO Sirpopaga species B.963 CO Osinella species B.935 CO Sesame B.964 CO Forvia species B.936 CO Spartanotis species B.965 CO Franklinela Bell B.937 CO Spodovterra species B.966 CO Tryps species B.938 CO Tortrix species B.967 CO Sirtotrips Auranti B.939 CO Tricofluciani B.968 CO Acerian species B.940 CO Agrites species B.969 CO Aculus species B.941 CO Antonomus Grandis B.970 CO Brevipalpus species B.942 CO Curculio species B.971 CO Panonicus Species B.943 CO Diabrotica Balteata B.972 CO Philocoroot root species B.944 CO Leptinotarsa species B.973 CO Tetranicus species B.945 CO Resorhofus species B.974 CO Heterodera species B.946 CO Otorhinhinkus species B.975 CO Meloidogine species B.947 CO Aleutrotrix species B.976 CH AdoxoPiece species B.948 CO Aleirodes species B.977 CH Agrotis species B.949 CO Aonidiaella Bell B.978 CH Alabama Argyllaea B.979 CH Anticarsia Gemmamatlis

AP Control AP Control B.980 CH Chilo bell B.1007 CH Curculio species B.981 CH Clicia Ambiguela B.1008 CH Diabrotica Balteata B.982 CH Crosidolomia Vinotalis B.1009 CH Leptinotarsa species B.983 CH Sidi A Species B.1010 CH Resorhofus species B.984 CH Deeparossis Castanea B.1011 CH Otorhinhinkus species B.985 CH Earias species B.1012 CH Aleutrotrix species B.986 CH Efestia B.1013 CH Aleirodes species B.987 CH Heliotis species B.1014 CH Aonidiaella Bell B.988 CH Hellula Undalis B.1015 CH Bell on Apidida B.989 CH Kferia Ricopercicela B.1016 CH Apis Bell B.990 CH Leukofterra Citella B.1017 CH Bemisia Tabaki B.991 CH Litocholete species B.1018 CH Empoasca species B.992 CH Lovesia Boatana B.1019 CH Mycus species B.993 CH Austrian Nubilis B.1020 CH Nepotetics species B.994 CH Pandemis species B.1021 CH Nilaparvata species B.995 CH Pectinophora gossip. B.1022 CH Pseudococcus species B.996 CH Phyloxtis citella B.1023 CH Squill B.997 CH Fiery species B.1024 CH Quadraspidiotus species B.998 CH Flutella xyllstella B.1025 CH Sizapis Bell B.999 CH Sirpopaga species B.1026 CH Trialeurodes species B.1000 CH Sesame B.1027 CH Liriomyza species B.1001 CH Spartanotis species B.1028 CH Osinella species B.1002 CH Spodovterra species B.1029 CH Forvia species B.1003 CH Tortrix species B.1030 CH Franklinela Bell B.1004 CH Tricofluciani B.1031 CH Tryps species B.1005 CH Agrites species B.1032 CH Sirtotrips Auranti B.1006 CH Antonomus Grandis B.1033 CH Acerian species B.1034 CH Aculus species B.1035 CH Brevipalpus species B.1036 CH Panonicus Species

AP Control AP Control B.1037 CH Philocoroot root species B.1063 SS Flutella xyllstella B.1038 CH Tetranicus species B.1064 SS Sirpopaga species B.1039 CH Heterodera species B.1065 SS Sesame B.1040 CH Meloidogine species B.1066 SS Spartanotis species B.1041 SS AdoxoPiece species B.1067 SS Spodovterra species B.1042 SS Agrotis species B.1068 SS Tortrix species B.1043 SS Alabama Argyllaea B.1069 SS Tricofluciani B.1044 SS Anticarsia Gemmamatlis B.1070 SS Agrites species B.1045 SS Chilo bell B.1071 SS Antonomus Grandis B.1046 SS Clicia Ambiguela B.1072 SS Curculio species B.1047 SS Crosidolomia Vinotalis B.1073 SS Diabrotica Balteata B.1048 SS Sidi A Species B.1074 SS Leptinotarsa species B.1049 SS Deeparossis Castanea B.1075 SS Resorhofus species B.1050 SS Earias species B.1076 SS Otorhinhinkus species B.1051 SS Efestia B.1077 SS Aleutrotrix species B.1052 SS Heliotis species B.1078 SS Aleirodes species B.1053 SS Hellula Undalis B.1079 SS Aonidiaella Bell B.1054 SS Kferia Ricopercicela B.1080 SS Bell on Apidida B.1055 SS Leukofterra Citella B.1081 SS Apis Bell B.1056 SS Litocholete species B.1082 SS Bemisia Tabaki B.1057 SS Lovesia Boatana B.1083 SS Empoasca species B.1058 SS Austrian Nubilis B.1084 SS Mycus species B.1059 SS Pandemis species B.1085 SS Nepotetics species B.1060 SS Pectinophora gossip. B.1086 SS Nilaparvata species B.1061 SS Phyloxtis citella B.1087 SS Pseudococcus species B.1062 SS Fiery species B.1088 SS Squill B.1089 SS Quadraspidiotus species B.1090 SS Sizapis Bell B.1091 SS Trialeurodes species B.1092 SS Liriomyza species

AP Control AP Control B.1093 SS Osinella species B.1120 HO Leukofterra Citella B.1094 SS Forvia species B.1121 HO Litocholete species B.1095 SS Franklinela Bell B.1122 HO Lovesia Boatana B.1096 SS Tryps species B.1123 HO Austrian Nubilis B.1097 SS Sirtotrips Auranti B.1124 HO Pandemis species B.1098 SS Acerian species B.1125 HO Pectinophora Gosipela B.1099 SS Aculus species B.1126 HO Phyloxtis citella B.1100 SS Brevipalpus species B.1127 HO Fiery species B.1101 SS Panonicus Species B.1128 HO Flutella xyllstella B.1102 SS Philocoroot root species B.1129 HO Sirpopaga species B.1103 SS Tetranicus species B.1130 HO Sesame B.1104 SS Heterodera species B.1131 HO Spartanotis species B.1105 SS Meloidogine species B.1132 HO Spodovterra species B.1106 HO AdoxoPiece species B.1133 HO Tortrix species B.1107 HO Agrotis species B.1134 HO Tricofluciani B.1108 HO Alabama Argyllaea B.1135 HO Agrites species B.1109 HO Anticarsia Gemmamatlis B.1136 HO Antonomus Grandis B.1110 HO Chilo bell B.1137 HO Curculio species B.1111 HO Clicia Ambiguela B.1138 HO Diabrotica Balteata B.1112 HO Crosidolomia Vinotalis B.1139 HO Leptinotarsa species B.1113 HO Sidi A Species B.1140 HO Resorhofus species B.1114 HO Deeparossis Castanea B.1141 HO Othioh Hintus species B.1115 HO Earias species B.1142 HO Aleutrotrix species B.1116 HO Efestia B.1143 HO Aleirodes species B.1117 HO Heliotis species B.1144 HO Aonidiaella Bell B.1118 HO Hellula Undalis B.1145 HO Bell on Apidida B.1119 HO Kferia Ricopercicela B.1146 HO Apis Bell B.1147 HO Bemisia Tabaki B 1148 HO Empoasca species B.1149 HO Mycus species

B.1150 HO Nepotetics species B.1160 HO Franklinela Bell B.1151 HO Nilaparvata species B.1161 HO Tryps species B.1152 HO Pseudococcus species B.1162 HO Sirtotrips Auranti B.1153 HO Squill B.1163 HO Acerian species B.1154 HO Quadraspidiotus species B.1164 HO Aculus species B.1155 HO Sizapis Bell B.1165 HO Brevipalpus species B.1156 HO Trialeurodes species B.1166 HO Panonicus Species B.1157 HO Liriomyza species B.1167 HO Philocoroot root species B.1158 HO Osinella species B.1168 HO Tetranicus species B.1159 HO Forvia species B.1169 HO Heterodera species B.1170 HO Meloidogine species

Biological Example

Table 1: Pest control comprising the application of abamectin to transgenic cotton, wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 2: Pest control comprising the application of abamectin to transgenic rice, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 3: Pest control comprising the application of abamectin to transgenic potatoes, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 4: Pest control comprising the application of abamectin to transgenic brassica, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 5: Pest control comprising the application of abamectin to transgenic tomatoes, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 6: Pest control comprising the application of abamectin to transgenic gourds and plants, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 7: Pest control comprising the application of abamectin to transgenic soybeans, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 8: Pest control comprising the application of abamectin to transgenic maize, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 9: Pest control comprising the application of abamectin to transgenic wheat, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 10: Pest control comprising the application of abamectin to transgenic bananas where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 11: Pest control comprising the application of abamectin to transgenic citrus plants, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 12: Pest control comprising the application of abamectin to a transgenic tree, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 13: Pest control method comprising the application of emamectin-benzoate to the transgenic cotton, wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 14: Pest control method comprising the application of emamectin-benzoate to transgenic rice, wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 15: Pest control comprising the application of emamectin-benzoate to transgenic potatoes, wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 16: Pest control comprising the application of emamectin-benzoate to transgenic tomatoes, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 17: Pest control comprising the application of emamectin-benzoate to transgenic gourds and plants in which the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 18: Pest control comprising the application of emamectin-benzoate to transgenic soybeans, wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 19: Pest control method comprising the application of emamectin-benzoate to transgenic maize, wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 20: Pest control comprising the application of emamectin-benzoate to transgenic wheat, wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 21: Pest control comprising the application of emamectin-benzoate to transgenic bananas where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

TABLE 22 Pest control comprising the application of emamectin-benzoate to a transgenic orange tree where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 23: Pest control comprising the application of emamectin-benzoate to a transgenic tree, wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 24: Pest control comprising the application of emamectin-benzoate to transgenic gourds and plants, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 25: Pest control method comprising the application of spinosad to transgenic cotton, wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 26: Pest control method comprising the application of spinosad to transgenic rice, wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 27: Pest control comprising the application of spinosad to transgenic potatoes wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 28: Pest control comprising the application of spinosad to transgenic brassica where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 29: Pest control comprising the application of spinosad to transgenic tomatoes, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 30: Pest control comprising the application of spinosad to transgenic gourds and plants, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 31: Pest control comprising the application of spinosad to transgenic soybeans, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 32: Pest control method comprising the application of spinosad to transgenic maize, wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 33: Pest control comprising the application of spinosad to transgenic wheat, wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 34: Pest control comprising the application of spinosad to transgenic bananas where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 35: Pest control comprising the application of spinosad to a transgenic citrus plant, wherein the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table 36: Pest control comprising the application of spinosad to a transgenic tree, where the combination of the active body expressed by the transgenic plant and the pest to be controlled corresponds to that of Table B.

Table C

Abbreviation:

Acetyl-COA Carboxylase: ACCase

Acetolactate synthase: ALS

Hydroxyphenylpyruvate deoxygenase: HPPD

Inhibitors of Protein Synthesis: IPS

Hormone Mimics: HO

Glutamine Synthetase: GS

Protoporpyrenogen oxidase: PROTOX

5-enolpyruvill-3-phosphosikimate synthase: EPSPS

main body Resistance to crops C.1 ALS Sulfonylurea etc ^*** Cotton C.2 ALS Sulfonylurea etc ^*** rice plant C.3 ALS Sulfonylurea etc ^*** Brassica C.4 ALS Sulfonylurea etc ^*** potato C.5 ALS Sulfonylurea etc ^*** tomato C.6 ALS Sulfonylurea etc ^*** Green plant C.7 ALS Sulfonylurea etc ^*** Big head C.8 ALS Sulfonylurea etc ^*** corn C.9 ALS Sulfonylurea etc ^*** wheat C.10 ALS Sulfonylurea etc ^*** Science C.11 ALS Sulfonylurea etc ^*** drupe C.12 ALS Sulfonylurea etc ^*** Citrus C.13 ACCase +++ Cotton C.14 ACCase +++ rice plant C.15 ACCase +++ Brassica C.16 ACCase +++ potato C.17 ACCase +++ tomato

main body Resistance to crops C.18 ACCase +++ Green plant C.19 ACCase +++ Big head C.20 ACCase +++ corn C.21 ACCase +++ wheat C.22 ACCase +++ Science C.23 ACCase +++ drupe C.24 ACCase +++ Citrus C.25 HPPD Isoxaplutol, Isoxaclotol, Sulkotlion, Mesotrione Cotton C.26 HPPD Isoxaplutol, Isoxaclotol, Sulkotlion, Mesotrione rice plant C.27 HPPD Isoxaplutol, Isoxaclotol, Sulkotlion, Mesotrione Brassica C.28 HPPD Isoxaplutol, Isoxaclotol, Sulkotlion, Mesotrione potato C.29 HPPD Isoxaplutol, Isoxaclotol, Sulkotlion, Mesotrione tomato C.30 HPPD Isoxaplutol, Isoxaclotol, Sulkotlion, Mesotrione Green plant C.31 HPPD Isoxaplutol, Isoxaclotol, Sulkotlion, Mesotrione Big head C.32 HPPD Isoxaplutol, Isoxaclotol, Sulkotlion, Mesotrione corn C.33 HPPD Isoxaplutol, Isoxaclotol, Sulkotlion, Mesotrione wheat C.34 HPPD Isoxaplutol, Isoxaclotol, Sulkotlion, Mesotrione Science C.35 HPPD Isoxaplutol, Isoxaclotol, Sulkotlion, Mesotrione drupe C.36 HPPD Isoxaplutol, Isoxaclotol, Sulkotlion, Mesotrione Citrus C.37 Nitrilease Bromoxynil, oxynil Cotton C.38 Nitrilease Bromoxynil, oxynil rice plant C.39 Nitrilease Bromoxynil, oxynil Brassica C.40 Nitrilease Bromoxynil, oxynil potato C.41 Nitrilease Bromoxynil, oxynil tomato C.42 Nitrilease Bromoxynil, oxynil Green plant C.43 Nitrilease Bromoxynil, oxynil Big head C.44 Nitrilease Bromoxynil, oxynil corn C.45 Nitrilease Bromoxynil, oxynil wheat C.46 Nitrilease Bromoxynil, oxynil Science C.47 Nitrilease Bromoxynil, oxynil drupe C.48 Nitrilease Bromoxynil, oxynil Citrus C.49 IPS Chloroactanilide && Cotton

main body Resistance to crops C.50 IPS Chloroactanilide && rice plant C.51 IPS Chloroactanilide && Brassica C.52 IPS Chloroactanilide && potato C.53 IPS Chloroactanilide && tomato C.54 IPS Chloroactanilide && Green plant C.55 IPS Chloroactanilide && Big head C.56 IPS Chloroactanilide && corn C.57 IPS Chloroactanilide && wheat C.58 IPS Chloroactanilide && Science C.59 IPS Chloroactanilide && drupe C.60 IPS Chloroactanilide && Citrus C.61 HOM 2,4-D, mecoprop-P Cotton C.62 HOM 2,4-D, mecoprop-P rice plant C.63 HOM 2,4-D, mecoprop-P Brassica C.64 HOM 2,4-D, mecoprop-P potato C.65 HOM 2,4-D, mecoprop-P tomato C.66 HOM 2,4-D, mecoprop-P Green plant C.67 HOM 2,4-D, mecoprop-P Big head C.68 HOM 2,4-D, mecoprop-P corn C.69 HOM 2,4-D, mecoprop-P wheat C.70 HOM 2,4-D, mecoprop-P Science C.71 HOM 2,4-D, mecoprop-P drupe C.72 HOM 2,4-D, mecoprop-P Citrus C.73 PROTOX Protox Inhibitor /// Cotton C.74 PROTOX Protox Inhibitor /// rice plant C.75 PROTOX Protox Inhibitor /// Brassica C.76 PROTOX Protox Inhibitor /// potato C.77 PROTOX Protox Inhibitor /// tomato C.78 PROTOX Protox Inhibitor /// Green plant C.79 PROTOX Protox Inhibitor /// Big head C.80 PROTOX Protox Inhibitor /// corn C.81 PROTOX Protox Inhibitor /// wheat

main body Resistance to crops C.82 PROTOX Protox Inhibitor /// Science C.83 PROTOX Protox Inhibitor /// drupe C.84 PROTOX Protox Inhibitor /// Citrus C.85 EPSPS Glyphosate and / or sulfosate Cotton C.86 EPSPS Glyphosate and / or sulfosate rice plant C.87 EPSPS Glyphosate and / or sulfosate Brassica C.88 EPSPS Glyphosate and / or sulfosate potato C.89 EPSPS Glyphosate and / or sulfosate tomato C.90 EPSPS Glyphosate and / or sulfosate Green plant C.91 EPSPS Glyphosate and / or sulfosate Big head C.92 EPSPE Glyphosate and / or sulfosate corn C.93 EPSPS Glyphosate and / or sulfosate wheat C.94 EPSPS Glyphosate and / or sulfosate Science C.95 EPSPS Glyphosate and / or sulfosate drupe C.96 EPSPS Glyphosate and / or sulfosate Citrus C.97 GS Glyphosinate and / or bialaphos Cotton C.98 GS Glyphosinate and / or bialaphos rice plant C.99 GS Glyphosinate and / or bialaphos Brassica C.100 GS Glyphosinate and / or bialaphos potato C.101 GS Glyphosinate and / or bialaphos tomato C.102 GS Glyphosinate and / or bialaphos Green plant C.103 GS Glyphosinate and / or bialaphos Big head C.104 GS Glyphosinate and / or bialaphos corn C.105 GS Glyphosinate and / or bialaphos wheat C.106 GS Glyphosinate and / or bialaphos Science C.107 GS Glyphosinate and / or bialaphos drupe C.108 GS Glyphosinate and / or bialaphos Citrus

***: include sulfonylureas, imidazolinones, triazolopyrimidines, dimethoxypyrimidines and N-acylsulfonamides as follows;

Sulfonylureas (e.g. chlorsulfuron, chlorimuron, etametsulfuron, metsulfuron, prisulfuron, prosulfuron, triasulfuron, cynosulfuron, tripricsulfuron, oxasulfuron, bensulfuron, Tribenuron, ACC 322140, fluzasulfuron, ethoxysulfuron, fluzasulfuron, nicosulfuron, rimsulfuron, thifensulfuron, pyrazosulfuron, clopyrasulfuron, NC 330, azisulsulfuron, imazosulfuron, Sulfosulfuron, amidosulfuron, flupysulfuron, CGA 362622);

Imidazolinones (eg, imazamethabenz, imazaquin, imazamethicyr, imazetapyr, imazapyr and imazamox);

Triazolopyrimidine (eg DE511, flumetsulam and chloransulam);

Dimethoxypyrimidines such as pyrithiobac, pyriminobac, bispyribac and pyribenzoxime.

+++: Diclopov-Methyl, Fluazifop-P-Butyl, Haloxypop-P-Methyl, Haloxypop-P-Ethyl, Quizaalpop-P-Ethyl, Clodinapop Propargyl, Phe Resistance to Noxaprop-ethyl, -tepraloxydim, alkoxydim, cetoxydim, cycloxydim, cloproxidim, tralcoxydim, butoxydim, carloxidim, clepoxydim, cletodim .

&&&: Chloroacetanilide (eg alachlor acetochlor, dimethenamid).

/// protox inhibitors: for example, diphenylethers (e.g., acifluorfen, acloniphene, biphenox, chlornitrofen, ethoxyphene, fluoroglycopene, pomessafen, lactofen, oxyfluorfen ); Imides (e.g. azaphenidine, carfentrazone-ethyl, cinidon-ethyl, flumiclolac-pentyl, fluminoxazine, fluthiacet-methyl, oxadiargyl, oxadione, pentoxazone, sulfide Pentrazone, imide) and others (e.g. flumipropine, flupropacyl, nipyraclofen and thidiazimine) and additional fluazolates and pyoflufen-ethyl.

Biological Example

Table 39: Representative Adotoxins, in which the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control in the PS.

Table 40: Representative agrotis, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 41: Alabama Argilla, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. SeAH control method.

Table 42: Anticarcia, including the application of abamectin to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Gemma Matalis's recipe.

Table 43: Representative genus of genus Chilo, comprising the application of abamectin to herbicide tolerant transgenic crops, where the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control method.

Table 44: Cleacia cancer, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Bigguela's control.

Table 45: Representative Nepal, where the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops, corresponding to those of Table C. Control in crosses.

Table 46: Crocidol, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests comprises the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Romea Vinotalis Control.

Table 47: Representative media, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 48: Diparopsis, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. How to control castanea.

Table 49: Representative arias, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 50: Representative Efestia, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 51: Representative heliotis, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 52: Hulalouun, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops, corresponding to those of Table C. How to control Dallas.

Table 53: Caperia rico, including the application of abamectin to herbicide-tolerant transgenic crops, where the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to those of Table C. Control of Percicella.

Table 54: Leukopetera, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Cytella's control.

Table 55: Representative littocholes, including the application of abamectin to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control in the Teeth.

Table 56: Robecia bot, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops, corresponding to those of Table C. How to control Lana.

Table 57: Austrian Nubil, including the application of abamectin to herbicidally resistant transgenic crops, wherein the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Rally's Control.

Table 58: Representative Pandemis, where the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 59: Pectinophora, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests comprises the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Gosipela's control.

Table 60: Phloxtis, the combination of active body expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Cetella control.

Table 61: Representative phyris, including the application of abamectin to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. Control of the genus.

Table 62: Flutelas, including the application of abamectin to herbicidally resistant transgenic crops, wherein the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to those of Table C. How to control Silostella.

Table 63: Representative skirpo, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus par.

Table 64: Representative Sesameia, including the application of abamectin to herbicide tolerant transgenic crops, where the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control of the genus.

Table 65: Representative Sparto, including the application of abamectin to herbicide tolerant transgenic crops, where the combination of active bodies expressed by transgenic plants and crops to be protected against pests corresponds to that of Table C. Control in the genus Ganotis.

Table 66: Representative spordorf, where the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus Terra.

Table 67: Representative tortrix, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 68: Tricoflucia, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Your control.

Table 69: Representative Agrio, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control in Tess.

Table 70: Antonomomus, comprising the application of abamectin to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. Grandis's control method.

Table 71: Representative kurkul, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. How to control Rio.

Table 72: Diabrotica, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Valteata's control.

Table 73: Representative leptino, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. How to control in tarsa.

Table 74: Representative litshor, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control in the Hoofruth.

Table 75: Representative thiors, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. How to control in Hincus.

Table 76: Representative allurouro, comprising the application of abamectin to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. How to control in the trickus.

Table 77: Representative alayo, including the application of abamectin to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. How to control in death.

Table 78: Representative Aoni, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control in Diella.

Table 79: Representative avidida, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. In the control method.

Table 80: Representative Apis genus, including the application of abamectin to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control method.

Table 81: Bemisciata, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Barki's control.

Table 82: Representative Empoasca, the combination of active body expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 83: Representative mycus, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 84: Representative nepotes, where the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control in ticks.

Table 85: Representative Nilapar, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. How to control in bata.

Table 86: Representative Pseudoco, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control in Couse.

Table 87: Representative genera of the genus Sila, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control method.

Table 88: Representative Quadra, including the application of abamectin to herbicide tolerant transgenic crops, where the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to those of Table C. How to control in Speediotus.

Table 89: Representative siphypis, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 90: Representative trials, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control in Urodes.

Table 91: Representative Lyriomy, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. How to control yourself.

Table 92: Representative Ossinella, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 93: Representative Forvia, including the application of abamectin to herbicidally resistant transgenic crops, wherein the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control of the genus.

Table 94: Representative Franklin, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control in Niella.

Table 95: Representative Tripps, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 96: Sirtotripps, comprising the application of abamectin to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. How to control Auranti.

Table 97: Representative genus of the genus Acer, including the application of abamectin to herbicide tolerant transgenic crops, where the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control method.

Table 98: Representative aculus, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 99: Representative Brevipal, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. How to control in fever.

Table 100: Representative panoni, where the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control in Couse.

Table 101: Representative pilokov, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control in Truta.

Table 102: Representative tetrani, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control in Couse.

Table 103: Representative heteroderas, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of abamectin to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 104: Representative meloido, comprising the application of abamectin to herbicide tolerant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. Control in Guinea.

Table 105: Mamestra bra, including application of abamectin to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Shika control method.

Table 106: The combination of the active body expressed by the transgenic plant and the crop to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative AdoxoPOS genus control method.

Table 107: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests comprises the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative Agrotis control.

Table 108: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. How to control Alabama Argillacea.

Table 109: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. How to control anticarsia gummatalis.

Table 110: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative chiropractic control.

Table 111: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Clichy Ambiguela's control method.

Table 112: The active body expressed by transgenic plants and the combination of crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative Nepalese crocrosis control.

Table 113: Active body expressed by transgenic plants and the combination of crops to be protected against pests include the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Control of Crosidolomia vinotalis.

Table 114: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests comprises the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative methods of control in the media.

Table 115: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. How to control Difalopsis Castanea.

Table 116: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative Arias control.

Table 117: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative Efestia control.

Table 118: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative Heliotis genus control.

Table 119: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. How to get rid of Hellah Undalis.

Table 120: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Control of Keperia Ricofericella.

Table 121: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Leukofthera citella control.

Table 122: The active body expressed by the transgenic plants and the combination of crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative Litocholestis control.

Table 123: The combination of the active body expressed by the transgenic plant and the crop to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. How to control Rhodesia Botlana.

Table 124: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. How to control Austrian Nubilales.

Table 125: Active body expressed by transgenic plants and the combination of crops to be protected against pests include the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative pandemis control method.

Table 126: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Pectinophora Gosipella's control method.

Table 127: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. How to control phloxtis citella.

Table 128: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative Pieris control method.

Table 129: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. How to control flutella xyllstella.

Table 130: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative Skirpopa genus control method.

Table 131: The combination of the active body expressed by the transgenic plant and the crop to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative sesamia control method.

Table 132: The active body expressed by transgenic plants and the combination of crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative Sparganotis control.

Table 133: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests comprises the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative control method in sporofera.

Table 134: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Typical tortrix control method.

Table 135: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Trichofluciani's control.

Table 136: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative aggregate control method.

Table 137: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. How to control Antonomus Grandis.

Table 138: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative curculio control.

Table 139: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. How to control Diabrotica Valteata.

Table 140: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus Reptino tarsa.

Table 141: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus Resorkhoftrus.

Table 142: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Control method in typical Otorihinkusu.

Table 143: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests comprises the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Control method in the typical alluretricus.

Table 144: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests comprises the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative methods of controlling in Aleirodes.

Table 145: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative method in Aonidiaella.

Table 146: The combination of the active body expressed by the transgenic plant and the crop to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative apididae control method.

Table 147: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative apis control.

Table 148: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. How to control Bemisia Tabaki.

Table 149: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Typical empoasca in the control method.

Table 150: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative mycose control method.

Table 151: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Typical nepotetics control method.

Table 152: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Control method in the representative nilaparvata.

Table 153: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative method in the typical Sudokucus.

Table 154: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative methods of control in Silla.

Table 155: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative quadrapidosis treatment.

Table 156: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative method of controlling in Sizapis.

Table 157: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus Trialeurodes.

Table 158: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Relioma is a representative method.

Table 159: The combination of the active body expressed by the transgenic plant and the crop to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative Ossinella.

Table 160: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative methods of control in Forvia.

Table 161: The combination of the active body expressed by the transgenic plant and the crop to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative control method in Francinela.

Table 162: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative TRIP control method.

Table 163: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. How to control sirtotrips auranti.

Table 164: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative control method in aceria.

Table 165: The combination of the active body expressed by the transgenic plant and the crop to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative Aquilus control.

Table 166: The combination of the active body expressed by the transgenic plant and the crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative Brevipalpus genus control method.

Table 167: The combination of the active body expressed by the transgenic plants and the crops to be protected against pests comprises the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative panonicus control.

Table 168: The combination of the active body expressed by transgenic plants and crops to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative method in the genophytococcus ruta.

Table 169: The combination of the active body expressed by the transgenic plant and the crop to be protected against pests comprises the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative tetranikus genus control method.

Table 170: The combination of the active body expressed by the transgenic plant and the crop to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative heterodera control.

Table 171: The combination of the active body expressed by the transgenic plant and the crop to be protected against pests includes the application of emamectin-benzoate to herbicidally resistant transgenic crops corresponding to those of Table C. Representative Meloidogine genus control method.

Table 172: Representative Adotoxins, in which the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Control in the PS.

Table 173: Representative agrotis, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 174: Alabama Argilla, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. SeAH control method.

Table 175: Anticarsia, comprising the application of spinosad to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. Gemma Matalis's recipe.

Table 176: Representative genus of genus Chilo, comprising the application of spinosad to herbicidally resistant transgenic crops, where the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control method.

Table 177: Cleacia cancer, comprising application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C Bigguela's control.

Table 178: Crocidol, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests comprises the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Romea Vinotalis Control.

Table 179: Representative media, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control of the genus.

Table 180: Difaropsis, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. How to control castanea.

Table 181: Representative arias, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control of the genus.

Table 182: Representative Efestia, including the application of spinosad to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. Control of the genus.

Table 183: Representative heliotis, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 184: Hulaloune, where the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. How to control Dallas.

Table 185: Capperia rico, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to those of Table C. Control of Percicella.

Table 186: Leukoftera, the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Cytella's control.

Table 187: Representative littocholes, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control in the Teeth.

Table 188: Robecia bot, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests corresponds to those of Table C. How to control Lana.

Table 189: Austrian Nubil, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests corresponds to those of Table C. Rally's Control.

Table 190: Representative Pandemis, where the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 191: Pectinophora, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests comprises the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Gosipela's control.

Table 192: Phloxtis, including the application of spinosad to herbicidally resistant transgenic crops, where the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Cetella control.

Table 193: Representative pieris, including the application of spinosad to herbicidally resistant transgenic crops, where the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control of the genus.

Table 194: Flutelas, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to that of Table C. How to control Silostella.

Table 195: Representative skirpo, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control of the genus par.

Table 196: Representative Sesameia, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control of the genus.

Table 197: Representative Spartans, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control in the genus Ganotis.

Table 198: Representative Spordorf, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus Terra.

Table 199: Representative tortrix, including the application of spinosad to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. Control of the genus.

Table 200: Tricoflucia, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Your control.

Table 201: Representative Agrio, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Control in Tess.

Table 202: Antonomomus, comprising application of spinosad to herbicidally resistant transgenic crops, wherein the combination of active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. Grandis's control method.

Table 203: Representative kurkul, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. How to control Rio.

Table 204: Diabrotica, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Valteata's control.

Table 205: Representative leptino, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. How to control in tarsa.

Table 206: Representative litshor, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control in the Hoofruth.

Table 207: Representative Othior, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. How to control in Hincus.

Table 208: Representative allurouro, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. How to control in the trickus.

Table 209: Representative alayo, including the application of spinosad to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. How to control in death.

Table 210: Representative Aoni, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Control in Diella.

Table 211: Representative avidida, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. In the control method.

Table 212: Representative Apis genus, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. Control method.

Table 213: Bemisciata, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests corresponds to those of Table C. Barki's control.

Table 214: Representative Empoasca, including the application of spinosad to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. Control of the genus.

Table 215: Representative mycus, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 216: Representative nepotes, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Control in ticks.

Table 217: Representative Nilapar, including the application of spinosad to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. How to control in bata.

Table 218: Representative Pseudoco, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Control in Couse.

Table 219: Representative genus Sila, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to those of Table C. Control method.

Table 220: Representative quadra, including combinations of spinosad against herbicidally resistant transgenic crops, where the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to that of Table C. How to control in Speediotus.

Table 221: Representative Siepices, comprising the application of spinosad to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. Control of the genus.

Table 222: Representative trials, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control in Urodes.

Table 223: Representative Lyriomy, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. How to control yourself.

Table 224: Representative Ossinella, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control of the genus.

Table 225: Representative Forvia, including the application of spinosad to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. Control of the genus.

Table 226: Representative Franklin, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Control in Niella.

Table 227: Representative Tripps, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 228: Sirtotripps, comprising the application of spinosad to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. How to control Auranti.

Table 229: Representative genus of the genus Acer, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control method.

Table 230: Representative aculus, including the application of spinosad to herbicidally resistant transgenic crops, where the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control of the genus.

Table 231: Representative Brevipal, including the application of spinosad to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. How to control in fever.

Table 232: Representative Panony, including the application of spinosad to herbicidally resistant transgenic crops, where the combination of the active body expressed by the transgenic plant and the crop to be protected against pests corresponds to that of Table C. Control in Couse.

Table 233: Representative phylloff, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control in Truta.

Table 234: Representative tetrani, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to be protected against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control in Couse.

Table 235: Representative heteroderas, wherein the combination of active bodies expressed by transgenic plants and crops to be protected against pests includes the application of spinosad to herbicidally resistant transgenic crops corresponding to those of Table C. Control of the genus.

Table 236: Exemplary meloido, comprising the application of spinosad to herbicidally resistant transgenic crops, where the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Control in Guinea.

Table 237: Mamestra bra, including the application of spinosad to herbicidally resistant transgenic crops, wherein the combination of crops to protect against pests and active bodies expressed by transgenic plants corresponds to that of Table C. Shika control method.

Example B1: Actions on Antonomomus Grandis Adult, Spodoptera litoralis or Heliotis nonresense

Young transgenic cotton plants expressing δ-endotoxin CryIIIA are sprayed with an aqueous emulsion spray mixture containing 100, 50, 10, 5, 1 ppm of emamectin-benzoate, respectively. After the spray coating is dried, 10 adult Anthonomus grandis, 10 Spodoptera littoralis larvae or 10 heliotis-nonresense larvae are added to the cotton plants and introduced into a plastic container. Evaluate after 3 to 10 days. The rate of reduction of the population or the percentage of feeding damage (% action) is determined by the number of dead beetles and the rate of feeding damage to transgenic cotton plants in each case at concentrations of 100, 50, 10, 5, and 1 ppm of emamectin-benzoate and Non-genetic transitions treated with emulsion spray mixtures containing conventional CryIIIA-toxins are determined in comparison to those of cotton plants.

In this test, the control of the tested insects in the transgenic plants was good, while in the non-transgenic plants it was insufficient.

Example B2 Action against Antonomomus Grandis Adult, Spodoptera litoralis or Heliotis nonresense

Young transgenic cotton plants expressing δ-endotoxin CryIIIA are sprayed with an aqueous emulsion spray mixture containing 100, 50, 10, 5, 1 ppm of abamectin, respectively. After the spray coating is dried, 10 adult Anthonomus grandis, 10 Spodoptera littoralis larvae or 10 heliotis-nonresense larvae are added to the cotton plants and introduced into a plastic container. Evaluate after 3 to 10 days. The rate of reduction of the population or the percentage of food damage (% action) is determined by the number of dead beetles and the rate of food damage to transgenic cotton plants in each case at concentrations of 100, 50, 10, 5 and 1 ppm of abamectin and conventional CryIIIA. Non-genetic transitions treated with emulsion spray mixtures containing toxins are determined in comparison to those of cotton plants.

In this test, the control of the tested insects in the transgenic plants was good, while in the non-transgenic plants it was insufficient.

Example B3: Actions on Antonomus Grandis Adults, Spodoftera litoralis or Heliotis Viresense

Young transgenic cotton plants expressing δ-endotoxin CryIIIA are sprayed with an aqueous emulsion spray mixture containing 100, 50, 10, 5, 1 ppm of spinosad, respectively. After the spray coating is dried, 10 adult Anthonomus grandis, 10 Spodoptera littoralis larvae or 10 heliotis-nonresense larvae are added to the cotton plants and introduced into a plastic container. Evaluate after 3 to 10 days. The rate of reduction of the population or the percentage of feeding damage (% action) is the number of dead beetles and the rate of feeding damage to transgenic cotton plants in each case at concentrations of 100, 50, 10, 5 and 1 ppm of spinosad and conventional CryIIIA. Non-genetic transitions treated with emulsion spray mixtures containing toxins are determined in comparison to those of cotton plants.

In this test, the control of the tested insects in the transgenic plants was good, while in the non-transgenic plants it was insufficient.

Example B4: Actions on Antonomus Grandis Adult, Spodoptera litoralis or Heliotis Viresense

A young transgenic cotton plant expressing δ-endotoxin Cryla (c) is sprayed with an aqueous emulsion spray mixture containing 100, 50, 10, 5, 1 ppm of spinosad, respectively. After the spray coating is dried, 10 adult Anthonomus grandis, 10 Spodoptera littoralis larvae or 10 heliotis-nonresense larvae are added to the cotton plants and introduced into a plastic container. Evaluate after 3 to 10 days. The rate of reduction of the population or the percentage of feeding damage (% action) is the number of dead beetles and the rate of feeding damage to transgenic cotton plants in each case at concentrations of 100, 50, 10, 5 and 1 ppm of spinosad and conventional CryIIIA. Non-genetic transitions treated with emulsion spray mixtures containing toxins are determined in comparison to those of cotton plants.

In this test, the control of the tested insects in the transgenic plants was good, while in the non-transgenic plants it was insufficient.

Example B5: Actions on Antonomus Grandis Adult, Spodoptera litoralis or Heliotis Viresense

Young transgenic cotton plants expressing δ-endotoxin Cryla (c) are sprayed with an aqueous emulsion spray mixture containing 100, 50, 10, 5, 1 ppm of avamethine, respectively. After the spray coating is dried, 10 adult Anthonomus grandis, 10 Spodoptera littoralis larvae or 10 heliotis-nonresense larvae are added to the cotton plants and introduced into a plastic container. Evaluate after 3 to 10 days. The rate of reduction of the population or the percentage of food damage (% action) is determined by the number of dead beetles and the rate of food damage to transgenic cotton plants in each case at concentrations of 100, 50, 10, 5 and 1 ppm of abamectin and conventional CryIIIA. Non-genetic transitions treated with emulsion spray mixtures containing toxins are determined in comparison to those of cotton plants.

In this test, the control of the tested insects in the transgenic plants was good, while in the non-transgenic plants it was insufficient.

Example B6: Actions on Antonomus Grandis Adult, Spodoptera litoralis or Heliotis Viresense

Young transgenic cotton plants expressing δ-endotoxin Cryla (c) are sprayed with an aqueous emulsion spray mixture containing 100, 50, 10, 5, 1 ppm of emamectin-benzoate, respectively. After the spray coating is dried, 10 adult Anthonomus grandis, 10 Spodoptera littoralis larvae or 10 heliotis-nonresense larvae are added to the cotton plants and introduced into a plastic container. Evaluate after 3 to 10 days. The rate of reduction of the population or the percentage of feeding damage (% action) is determined by the number of dead beetles and the rate of feeding damage to transgenic cotton plants in each case at concentrations of 100, 50, 10, 5, and 1 ppm of emamectin-benzoate and Non-genetic transitions treated with emulsion spray mixtures containing conventional CryIIIA-toxins are determined in comparison to those of cotton plants.

In this test, the control of the tested insects in the transgenic plants was good, while in the non-transgenic plants it was insufficient.

Example B7: Action against Austrian Nubililis, Spodofterra species or Heliotis species

Corn cv. All invaded naturally with Austrian bilivilis, Spodopterra spp. Or heliotis. Plot (a) planted KnockOut ^R and adjacent plots (b) of the same size planted conventional corn are sprayed with an aqueous emulsion spray mixture comprising 200, 100, 50, 10, 5, 1 ppm of spinosad. Immediately thereafter, plot (b) is treated with an emulsion spray mixture comprising endotoxins 200, 100, 50, 10, 5, 1 ppm expressed by KnockOut ^R. Evaluate after 6 days. The percentage reduction of the population is determined by comparing the number of dead pests for plants in plot (a) with the number of dead pests for plants in plot (b).

An improved control of Austrian Nubilalis, Spodofterra species or Heliotis is observed in the plants of plot (a), while plot (b) shows control levels not exceeding 80%.

Example B8: Action against Austrian Nubililis, Spodofterra species or Heliotis species

Corn cv. All invaded naturally with Austrian bilivilis, Spodopterra spp. Or heliotis. Plot (a) planted KnockOut ^R and adjacent plots (b) of the same size planted conventional corn are sprayed with an aqueous emulsion spray mixture comprising 200, 100, 50, 10, 5, 1 ppm of abamectin. Immediately thereafter, plot (b) is treated with an emulsion spray mixture comprising endotoxins 200, 100, 50, 10, 5, 1 ppm expressed by KnockOut ^R. Evaluate after 6 days. The percentage reduction of the population is determined by comparing the number of dead pests for plants in plot (a) with the number of dead pests for plants in plot (b).

An improved control of Austrian Nubilalis, Spodofterra species or Heliotis is observed in the plants of plot (a), while plot (b) shows control levels not exceeding 80%.

Example B9: Action against Austrian Nubililis, Spodofterra species or Heliotis species

Corn cv. All invaded naturally with Austrian bilivilis, Spodopterra spp. Or heliotis. Plot (a) planted KnockOut ^R and adjacent plots (b) of the same size planted conventional corn are sprayed with an aqueous emulsion spray mixture comprising 200, 100, 50, 10, 5, 1 ppm of emamectin benzoate. Immediately thereafter, plot (b) is treated with an emulsion spray mixture comprising endotoxins 200, 100, 50, 10, 5, 1 ppm expressed by KnockOut ^R. Evaluate after 6 days. The percentage reduction of the population is determined by comparing the number of dead pests for plants in plot (a) with the number of dead pests for plants in plot (b).

An improved control of Austrian Nubilalis, Spodofterra species or Heliotis is observed in the plants of plot (a), while plot (b) shows control levels not exceeding 80%.

The present invention also provides

(B) Reorganization of propagation material as a pesticidal active compound with pesticides comprising at least one macrolide compound, especially abamectin, emamectin or spinosad, and one or more auxiliaries, in free form or in agrochemically useful salt form as active ingredient Or a method of protecting plant propagation material and plant organs subsequently formed from attack by pests, characterized in that they are used at the site of planting or sowing in close proximity or spatially together with the application; Corresponding uses of these compounds, corresponding pesticides, wherein the active ingredients are selected from these compounds, methods of making and using these compositions, and plant propagation materials which are thus protected from attack by pests.

Macrolides used in accordance with the present invention are known to those skilled in the art. These are groups of substances mentioned under part (A) of the present invention. Abamectin and emamectin are preferred.

Agrochemically useful salts of macrolides according to the invention are, for example, the same as those mentioned under part (A) of the invention.

In the case of abamectin, the free form is preferred in part (B) of the invention. Particularly preferred in the scope of part (B) of the present invention is that emamectin is in free form or agrochemically acceptable salt, in particular as salt, in particular benzoate, substituted benzoate, benzenesulfonate, citrate, phosphate, tartrate Or maleate, preferably as benzoate or benzenesulfonate, particularly preferably as benzoate.

The scope of the object of the present invention (B) extends in particular to representative insects, mites and nematodes.

These are mainly Lepidoptera species, such as, for example, Acleris species, Adoxophytes species, Aegean species, Agrotis species, Alabama Argillacea, Amylois species, Anticarsia gummatalis, Archipes species, Argyrotania species, Astilus atromaculus, Autographa species, Buseola pusca, Cadra caoutella, Carposina niponensis, Chilo species, Coristoneura species, Clycia ambiguella , Napalocrosis species, nepasia species, coquilis species, choleophora species, crocidolomia vinotalis, Cryptoflavia leukotreta, sidia species, diateaea species, dipalophesis castanea, aerias Species, Efestia species, Eucosma species, Eupoecilia ambiuela, Euprotis species, Yukzoa species, Grapolita species, Hedia nubiferana, Heliotis species, Hellula Undalis, Heteronicus Aator, Haipan Lia Kunea, Keperia Lycopericissella, Leukofterra Citella, Litocholtis species, Rhodesia Botlana, Rimantria species, Lionetia species, Malakosoma species, Mamestra brassica, Manduca sexta, Operofera species, Austrian Nubilis, Palmmene species, Pandemis species, Panolis flammea, Pectinophora gosipiella, Petriomia opulculella, Pieris lafa, Pieris species, flutella crocus Cilostella, price species, siropaga species, sesamia species, spartanotis species, sporofera species, sinantone species, taumetopoea species, tortrix species, tricofluciani and ifonomeuta species ;

Choloptera species, for example, Agriotes species, Antonomomus species, Atomaria linarias, Catoknema tivialis, Cosmopolites species, Curculio species, Dermestes species, Diabrotica species, Epila Kna, Eremnus, Reptinotarsa dessimetaata, Lisorthophlus, Melolota, Orcaephyllus, Othiorhinkus, Flictinus, Popilia, Ciliodes , Risperta species, Scarabidae, Sitophyllus species, Sitotroga species, Tenebrio species, Trivolume species and Trogoderma species;

Ortoperra throat, for example, Blata species. Blatella species, grrotopafa species, leukopea madeeraes, rocusta species, periplaneta species and cystokerca species;

Socothetera, for example, lipocellis species;

Anoflura necks, such as haematotopus species, linognathus species, pediculus species, fempigus species and phloxera species;

Malopaga necks such as damalione species and tricodexate species;

Thisanophthera necks, such as Francliniella spp., Hercinonotps spp., Taniotripps spp., Tryps palmi, tryps tabaki, and sirtotripps auranti;

Heterophthera species, for example, Simex species, Distantiella theobroma, Disdercus species, Yuquistus species, Yurigaster species, Leptocori species, Nezara species, Piesma species, Rodnius species , Salbergela singgularis, Scottinopara species and Triatoma species;

Homotera necks, for example, Aureurotrixus phlocosus, Aleirodes brassica, Aonidiaella spp., Apididae, Apis spp., Aspidiotus spp., Bemisia tabaki, Seuplaster spp. , Crysompalus Aonidium, Crysompalus Dictiospermi, Cocus Hesperidum, Empoasca Species, Eriosoma Lanigerum, Eritroneneura Species, Gaskardia Species, Lao Delfax Species, Lekanium Corni , Lepidodosapes species, Macrocypus species, Mai juice species, Nepotetics species, Nilaparvata species, Paratoria species, Pempigus species, Planococcus species, Schudaulacaspis species, Pseudococcus species, Silas, Fulvinaria aeopicica, Quadraspidiotus, Ropalolos, Cycetia, Scapoides, Sisapis, Sitobion, Trialeurodes Baphorario, Trio Chairs Eritrea and Unaspies Citri;

Himenophthera species, for example, Acromirmex, Ata species, Sepus species, Diprion species, Diprionidae, Gilfinia polytomas, Hoflocampa species, Lassius species, Monomorium pharaonics, Neody Prion species, solenopsis species and Vespa species;

Diphthera species, such as, for example, Aedes species, Anterigona sokata, Vibio hortulanus, Califora erythrocephala, Ceratitis species, Chrysomia species, Coolex species, Kuterrebra species, Doucus species, drosophila melanogasster, pannian species, gastrophilus species, glossina species, hippoderma species, hippoboska species, liriomyza species, ruquilia species, melanagromaiza species, Musca species, Oestrus species, Orceolia species, Ossinella frit, Pegomia thiosiami, Forvia species, Lagoretis pomonella, Skiara species, Stomachsis species, Tabanus species, Tania species and Tipula species ;

Siponapactera, for example, Seratophyll sp. And xenopsila keopis or

Tissanuura neck, for example Lepisma sakarina.

Among the Arachnida groups, these are preferably representative Acarina necks, such as, for example, Acarus Siro, Akeria Seldony, Aculus Schletschtendaly, Amblyomoma species, Argas species, Bupillius species, Brevipalpus species, Briobia praetoiosa, Caliphytrimerus species, Coryotethes species, Dermanisus galinae, Eoteranicus carpini, Eriopis species, Hyaloma species, Ixodes species, Oligos Nikus pratensis, Ornitodorus species, Panonicus species, Filocoptuta oleivora, Polypagotarsonemus latus, Sorofthes species, Lipispalus species, Rizoglyphs species, Sarcoptes species , Tarsonemus species, and tetranicus species.

Particularly preferred are insects of coleoptera and lepidoptera; In the choloptera species, in particular the Agrithes species, Antonomomus species, Atomaria linarias, Caetonic nema tivialis, Diabrotica species and Leptinotarsa dessumerneata genus and species; In the order of Lepidofera, in particular, AdoxoPies species, Agrotis species, Alabama Argillacea, Anticarsia gemmatalis, Chilo species, Sidia species, Efestia species, Heliotis species, Keperia ricospercisella, Mame Stra brassicae, Pectinophora gosipella, flutella xycilella, sesamia spp., Spodoptera spp., Tortrix spp. And tricoflucia genus and insects of the species.

Another preferred object according to the invention (B) is the control of representative nematodes, such as root-knot nematodes, stem nematodes and leaf nematodes; In particular, heterodera species such as heterodera sharkti, heterodera avenae and heterodera tripoly; Globodera species, such as, for example, globodera rostokiensis; Meloidogine species, such as meloidogine incoginita and meloidogine javanica; Radopolus species, for example Radopolus simillis; Pratylenkus such as pratylenkus neglexanthus and pratylenkus penetrance; Styrene coolers, for example, styrene coolers semiphenetrance; Longidorus, Trichodorus, Cipinema, Ditylencus, Apelencoides and Angena, in particular Meloidogine, for example Meloidogine incogita and heterodera, for example, heterodera glycine It is control of s.

Macrolides used according to the invention (B) are active ingredients prophylactically and / or therapeutically useful in the field of insect control, even at low application rates, while being well tolerated by warm-blooded animals, fish, worms and plants. The active ingredients used according to the invention are not only commonly sensitive, but also effective for each or all of the stages of development of the resistant pest. The action of the active ingredient used according to the invention is directly, ie immediately induced or after a short time, for example in the form of destruction of the pest during infestation, or indirectly, for example, reduced scattering and / or It can be clearly seen as the hatching rate, and a good action corresponding to the rate of destruction (lethality) is at least 50 to 60%.

Using the active ingredients used according to part (B) of the present invention, it is possible to control, i.e. control or destroy pests caused by plant propagation substances, mainly plants and ornamental substances which are useful for agriculture, horticulture and forests. And even later growing plant organs, i.e., until resistant mature plants grow, so that breeding substances or plants grown therefrom are not only pests that attack parasitic plant organs, but also soil-resident pests. Protected from

Suitable plant propagation substances in the present invention (B), ie seedlings, for example, seedlings, rhizomes, seedlings, cuttings or, in particular, seeds (seeds) such as fruits, tubers, kernels or bulbs, in particular, grains (eg wheat). , Barley, rye, oats, rice, corn or sorghum); Beet (eg sugar or feed beet); Fruits, such as poultry, nucleus, and lead (eg apples, pears, plums, peaches, almonds, cherries or strawberries, such as raspberries and blackberries); Leguminous plants (eg, kidney beans, lentils, peas, soybeans); Fruit plants (eg, rape, mustard, poppy, olives, sunflowers, coconut, castor oil plants, cacao seeds, peanuts); Gourds (eg pumpkins, cucumbers, melons); Fibrous plants (eg cotton, flax, hemp, jute); Citrus plants (eg oranges, lemons, grapefruits, tangerines); Vegetables (eg, spinach, lettuce, asparagus, cabbage, carrots, onions, tomatoes, potatoes or peppers); Lauraceae (eg avocados, cinnamon, camphor); Or tobacco, nuts, coffee, eggplant, sugarcane, tea, pepper, vine, hops, Musaceae and latex plants or flavours, especially cereals, rice, cotton, corn, soybeans, rape, vegetables, potatoes It is a breeding substance of sunflower, beet and sorghum.

Genetically modified propagation material is preferably a propagation material, in particular a seed containing one or more genes expressing insecticidal resistance, in particular insecticidal or acaricide, as well as bactericidal or nematicidal resistance, which makes plant resistance to herbicides, Induces increased resistance to plant disease or introduces other agriculturally useful properties into the plant. Such plants or their propagation material, in particular, contain genes derived from Bacillus thuringiensis and encode or contain pesticidally active proteins. These are, in particular, potatoes, alfalfa, cereals (eg wheat, barley, rye, oats, rice, corn or sorghum); Leguminous plants (eg, kidney beans, lentils, peas, soybeans); Beet (eg sugar or feed beet); Fruit plants (eg, rape, mustard, poppy, olives, sunflowers, coconut, castor oil plants, cacao seeds, peanuts); Gourds (eg pumpkins, cucumbers, melons); Fibrous plants (eg cotton, flax, hemp, jute); Citrus plants (eg oranges, lemons, grapefruits, tangerines); It is a genetically modified plant propagation material of vegetables (eg spinach, lettuce, asparagus, cabbage, carrots, onions or tomatoes).

Examples of genetically modified plant propagation materials mentioned are, for example, commercially available Maximizer ^R (KnockOut ^R ), Yieldgard ^R , Roundup Ready Soybeans ^R , TC Blend ^R or NuCOTN 33B ^R , all of which are It is known to the skilled person.

Another field of application of the active ingredients used in accordance with part (B) of the present invention is, for example, the protection of stored products or articles or the sanitary sector, in particular the protection of livestock or fertility livestock from pests.

Accordingly, the present invention (B) is emulsifiable concentrate, suspension concentrate comprising a corresponding pesticide, for example one or more active ingredients used according to the invention, for use according to the intended purpose and the environment to be overcome. Encapsulating agents in water, directly sprayable or dilutable solutions, fusible pastes, dilute emulsions, sprayable powders, soluble powders, dispersible powders, wet powders, powders, granules or polymeric materials and for use in the method It relates to the use of these pesticidal compositions. Preference is given to compositions comprising only one macrolide compound, in particular emamectin or a salt thereof.

In these compositions, the active ingredient is in pure form, for example, as a solid active ingredient in particulate size, or preferably one or more adjuvants, such as extenders (e.g. solvents or solid carriers), which are commonly used in the formulation art. Or surface-active compounds (surfactants).

Suitable auxiliaries such as solvents, solid carriers, surface active compounds, nonionic surfactants, cationic surfactants and anionic surfactants in the compositions used according to the invention are described, for example, in EP-A 736 252. It is described.

Liquid formulations for the treatment of plant propagation material, in particular seed according to part (B) of the invention, are for example surface active substances (1 to 15% by weight) [e.g. ethoxylated tristyrenephenol and salts thereof, alkyl Polyglycol ether ethoxylates, polyoxypropylene / polyoxyethylene copolymers, sodium salts of lignosulfonic acid, salts of polynaphthalenesulfonic acid and alkylbenzenesulfonic acid triethanolamine salts; Cryoprotectants (5-15%) [eg, DL-propane-1,2-diol or propane-1,2,3-triol]; Colorants (1 to 10%) such as pigments or water soluble dyes; Antifoam (0.05-1%) [eg polydimethylsiloxane]; Coatings (1 to 10%) [eg polyethylene glycol, polyvinyl acetate, polyvinylpyrrolidone, polyacrylate]; Preservatives (0.1-1%) [eg 1,2-benzoisothiazol-3-one]; Thickening agents (0.1 to 1%) such as heteropolysaccharides and solvents such as water.

Solid formulations for the treatment of plant propagation materials, in particular seeds, are for example surface active materials (1 to 10% by weight) [e.g. alkyl polyglycol ether ethoxylates, polyoxypropylene / polyoxyethylene copolymers, lig Sodium salt of nosulfonic acid, salt of polynaphthalenesulfonic acid]; Colorants (1 to 10%) such as pigments or water soluble dyes; Antifoam (0.05-1%) [eg polydimethylsiloxane]; Coatings (1 to 10%) (eg polyethylene glycol or cellulose) and carriers (up to 100%, w / w) such as silica powder, talc powder and clay, and the like.

Indeed, the composition comprises from 0.1 to 99% of the active ingredient, in particular from 0.1 to 95% and from 1 to 99.9%, in particular from 5 to 99.9%, of at least one solid or liquid adjuvant, and in practice from 0 to 25%, in particular from 0.1 to 20% may be a surfactant (in each case% means% by weight). While concentrated compositions are more preferred as commercial products, end users actually use dilute compositions with much lower concentrations of active ingredient.

Preferred compositions such as emulsifiable concentrates, powders, suspension concentrates, wettable powders and granules are for example the compositions described in EP-A 736 252.

The composition according to part (B) of the present invention may also contain stabilizers (e.g., non-epoxidized or epoxidized vegetable oils (e.g. epoxidized coconut oil, rapeseed oil or soybean oil)), defoamers (e.g. silicone oils, preservatives, viscosity Modifiers, binders and / or thickening agents) and also other solids or liquids, such as fertilizers or other active ingredients (such as fungicides, nematicides, molluscicides or optional herbicides) for achieving a particular effect. Adjuvants may be included.

The action of the composition according to the invention (B) is significantly extended by adding other pesticidal, acaricide and / or bactericidal active ingredients and can be applied to the environment to be overcome. Suitable adducts of pesticidal and acaricide active ingredients are, for example, representative of the following active ingredient groups: organophosphorus compounds, nitrophenols and derivatives, formamidine, triazine derivatives, nitroenamin derivatives, nitro- and cya Noguanidine derivatives, urea, benzoylurea, carbamate, pyrethroid, chlorinated hydrocarbons and Bacillus thuringiensis products. Particularly preferred components in the mixture are NI-25, TI-304, TI-435, MTI-446, fipronil, lufenuron, pyripoxyphene, tiacloprid, fluxofenime; Imidacloprid, thiamethoxam, phenoxycarb, diafenthiuron, pymetrozine, diazinon, disulfotone; Propenofoss, furathiocarb, cyromazine, cipermethrin, tau-fluvalinate, tefluthrin or Bacillus thuringiensis, NI-25, TI-304, TI-435, MTI-446, blood Very particular preference is given to furonyl, tiacloprid, imidacloprid, thiamethoxam and tefluthrin.

Examples of suitable adducts of bactericidal active ingredients are the following compounds: azoxystrobin, vitertanol, carboxycin, Cu ₂ O, cymoxanyl, ciproconazole, ciprodinyl, diclofluamide, diphenoconazole, Diconazole, epoxyconazole, fenpiclonyl, fludioxonil, fluquiconazole, flusilazole, flutriafol, furalacyl, guaztine, hexaconazole, hymexazole, imazilyl, already Benconazole, Ifconazole, Creoxime-Methyl, Mancozeb, Metallaxyl, R-Metalaxyl, Metconazole, Oxadixyl, Pepurazoate, Penconazole, Pensicuron, Prochloraz, Propiconazole, Pyroquilon, SSF-109, spiroxamine, tebuconazole, tefluthrin, thiabendazole, tolifluamide, triazoside, triadimefon, triadimenol, triflumizol, triticazole and unico Nasol.

The composition to be used according to part (B) of the present invention is prepared in a known manner, for example in the absence of an adjuvant, for example by grinding and / or screening to a particulate size or by compacting a solid active ingredient, one or more adjuvant In the presence of, for example, the active ingredient is prepared by thorough mixing and / or polishing with the adjuvant / adjuvant. These methods of making the compositions according to the invention and the use of macrolides for preparing these compositions are also an object of the invention.

According to the present invention, for example, planting of seedlings, rhizomes, seedlings, cruciforms or, in particular, seeding (seeds) (e.g. fruits, tubers, kernels or bulbs) to attack or attack by pests. Or an application method according to part (B) of the present invention for the protection of all plant propagation material which is a plant material capable of growing into a complete plant after sowing, for example, by replanting or propagating the propagation material to the site of reproduction or sowing. It is characterized by the application in such a way that it is applied in close proximity or spatially with the sowing. The application of these compositions in close proximity to the sowing or replanting or propagation of the propagation material to the seeding site is, according to the invention, preferably according to the invention, before the propagation material is replanted or sown before sowing the composition, for example, preferably by sowing. It is carried out prior to planting or sowing of the propagation material by direct soil application to the sown or grown site or to a site set proximate around the planting or sowing site of the propagation material. The application of such compositions carried out spatially with planting or applying propagation material to the planting or sowing site should be understood as planting or sowing propagation material to the planting or sowing site previously treated with these compositions, and intended purpose and overcome Depending on the circumstances, the pretreatment of the propagation material is carried out, for example, by spraying, spraying, spraying or scattering the propagation material, by brushing or pouring the composition onto the propagation material, or in the case of seeds. In particular, it can be carried out by dressing the seed. When carrying out preferred seed dressings according to the invention, ie dry seed-dressing, wet seed-dressing, liquid seed-dressing or slurry dressings, suitable pesticides are added to the seed prior to sowing in the seed-dressing device and the composition is For example, the contents of the seed-dressing device are agitated and / or the entire seed-dressing device is rotated and / or stirred so as to distribute evenly on the seed. A particular embodiment of this seed-dressing treatment is, for example, immersion of the seed in a liquid composition, a method of coating the seed with a solid composition (seed coating) or by adding the composition to water used for the preliminary immersion of the seed to add the active ingredient to the seed. Permeation (seed immersion). Typical application rates for the compositions used for seed-dressing treatments according to the invention are, for example, from 0.1 to 100 g, in particular from 1 to 60 g, preferably from 4 to 40 g, of active ingredient per 100 kg of seed.

Seed-dressing treatments according to the invention (B) are particularly well suited to the low toxicity of the active ingredients used, which makes them a good resistance to birds by dressing seeds, e.g. Bunting, crows, birds, crows, ducks, pheasants, finch, geese, red tits, chickens, crows, larks, tits, gulls, wandering crows, quails, mountain pigeons, yellow catalysts, pigeons or black-tailed birds) Observed in the case, including the tendency to obtain seeds from freshly sown fields. The seed dressing treatment according to the invention also extends to the dressing of stored seeds.

Commercially available plant propagation material pretreated according to part (B) of the present invention is another object of the present invention.

Examples of formulations of macrolide compounds that can be used in the process according to the invention (B), ie solutions, granules, powders, sprayable powders, emulsion concentrates, coated granules and suspension concentrates, for example, EP- A of the type described in Examples F1 to F10 of heading 580 553.

Example F1: General Method for Liquid Seed Dressing

The required amount of liquid formulation is added to the Erlenmeyer flask. The flask is stirred so that the liquid is distributed over the entire bottom of the vessel. The required amount of seed is introduced immediately into the flask. The flask is vigorously stirred for approximately 1 minute by hand to ensure that all seeds are covered with liquid. The contents of the flask are drained over a drying rack and dried in an oven.

Example F2: General Method for Dry Seed Dressing

The same number of seed kernels are placed in variously wide mouth flasks and each flask is charged with an amount of wettable powder such that the desired amount of active ingredient (eg, 0.03, 0.1 or 0.3 mg of kernel) is obtained per seed grain. Place the flask on the roller and spin for 3 minutes at 80 revolutions / minute. The seed grain adhering to the flask wall is then shaken off by hand and the flask is rotated in the opposite direction for 3 minutes.

Biological Example (% =% by weight unless otherwise indicated)

Example B4: Seed-dressing Action on the First Larva Larva of Spodofterra litolilis in Corn Leaves

The seeded corn seeds are sown as described in Method F1. 12, 19, 26, 33, 40, and 47 days after sowing, the portion of the uppermost leaf of the plant, 5-8 cm in length, is transferred to a glass beaker and a suspension of newly hatched L1 larvae of Spodoptera littoralis. Invade in a predetermined amount. The beaker is sealed with a lid and maintained at 25 ° C., 60% relative atmospheric humidity and 16 hours of daylight cycle. Evaluate 3 to 5 days after invasion. The percentage reduction of the population is determined by comparing the survival of larvae on plants grown from the dressed seeds with the survival of larvae on plants grown from untreated seeds.

Example B5 Seed-dressing Action on Adult Diabrotica Valteata in Beet Leaves

Seeds of beet seeded as described in Method F1 are sown. 33, 40, 47, 54 and 61 days after sowing, in each case three of the five plants are transferred to a glass beaker and infested with a predetermined number of young adult diabrotica batatas. The beaker is sealed with a lid and maintained at 25 ° C., 60% relative atmospheric humidity and 16 hours of daylight cycle. Evaluate 3 to 5 days after invasion. The percentage reduction of the population is determined by comparing the survival of diabrotica adults on plants grown from dressed seeds with the survival of adults on plants grown from untreated seeds.

Example B6: Seed-dressing Action on the Third Larvae Larva of Diabrotica Valteata in Corn Roots

Corn seeds treated as described in Method F1 are sown. After 14, 21 and 28 days of sowing, in each case five third larvae of Diabrotica valteata are placed in the bottom of each plant pot. Evaluate 6 days after invasion. The data recorded is the number of surviving insects (larva and pupa) on the soil surface and plant stems of the soil. The percentage reduction of the population is determined by comparing the survival of larvae and pupa on plants grown from the dressed seeds with the survival of larvae and pupa on plants grown from untreated seeds and their environment.

Example B7: Seed-dressing Action on Apis fabae

A glass flask or plastic container is charged with 100 g of soybean seed and a formulation amount of active ingredient such that a ratio of 0.1, 1 or 10 g of active ingredient per kg of seed is achieved. The active ingredient is evenly distributed on the seed surface by rotating and / or stirring the vessel. Seeds dressed in this way are sown in pots (three seeds per pot). Seedlings are grown in greenhouses at 25-30 ° C. until they reach the two-leaf stage, and then seeded with Apis Pava. Six days after inoculation, the test is evaluated. The percentage reduction of the population is determined by comparing the survival of the individual on the plant grown from the dressed seed and the survival of the individual on the plant grown from the untreated seed.

In this test, good action is observed with abamectin, emamectin and spinosad.

Example B8 Seed-dressing Action on Mai Juice Persica

Fill a glass flask or plastic container with a paste formulation of 100 g of beet seed and the active ingredient prepared from a sprayable powder and a small amount of water in an amount such that a ratio of 0.1, 1 or 10 g of active ingredient per kg of seed is achieved. Let's do it. The sealed seed-dressing vessel is stirred on the roller until the paste is evenly distributed on the seed surface. In this way, the seeded dressings are dried and sown in Lois soil in a plastic pot. The hairs are allowed to grow in a greenhouse for 14 hours of daylight at 24-26 ° C., 50-60% relative atmospheric humidity. Four weeks after germination, plants with a height of 10 cm were inoculated with a mixed inoculation of Mai juice persica. Evaluate 2-7 days after plant inoculation. The percentage reduction of the population is determined by comparing the survival of the individual on the plant grown from the dressed seed and the survival of the individual on the plant grown from the untreated seed.

In this test, good action is observed with abamectin, emamectin and spinosad.

The present invention also provides

(C) Pesticides as pesticidally active compounds with an insecticidal active amount of an insecticide comprising at least one macrolide, in particular abamectin, emamectin or spinosad, and at least one adjuvant, in free or agrochemically useful salt form as the active ingredient. Or control of tree pests and molluscs, characterized by application to their habitat; Corresponding uses of these compounds, corresponding pesticides, wherein the active ingredients are selected from these compounds, methods of making and using these compositions, and plant propagation materials which are thus protected from attack by pests.

The macrolides used according to the invention are the same as mentioned in aspect (A) of the invention. In addition, salts are as mentioned under part (A) of the present invention. In the case of abamectin, the free form is preferred according to the invention. Particularly preferred for the purposes of the present invention are only pesticidal active ingredients in free form or as agrochemically acceptable salts, in particular as salts, more particularly as benzoates, substituted benzoates, benzenesulfonates, citrate, phosphates, tarts It is a composition which comprises emamectin as a rate or maleate, preferably as benzoate or benzenesulfonate, particularly preferably as benzoate.

A number of different active ingredient groups are mentioned in the literature as active ingredients that act on arthropods for controlling gastropods and termites. Surprisingly, it has been found that compounds known under the general term macrolide also exhibit significant killing and termite activity, especially against gastropods (eg slugs and snails) and tree pests, particularly representative Isofera.

Molluscs include, for example, Ampulariidae; Arion [A. A. ater, A. A. circumscriptus, A. A. hortensis, A. A. rufus; Bradybaenidae (Bradibaena Fruitycum); Cepaea [Si. C. hortensis, C.i. C. Nemoralis]; Cochlodina; Deroceras [D. D. agrestis, Dee. D. empiricorum, Dee. D. laeve, Dee. Reticulatum; Discus [D. Rotundatus; Euromphalia; Galba [GE. Trunculata; Helicella [H. Itala, H. H. obvia; Helicidae (Helicigona arbustorum); Helicodiscus; Helix [H. H. aperta]; Limax [L. L. cinereoniger, L. L. flavus, L. L. marginatus, L. Maximus, L. L. tenellus]; Lymnaea; Milax [M. M. gagates, M. M. marginatus, M. M. sowerbyi]; Opeas; Pomacea [P. P. canaticulata]; Valonia and Zanitoides are included.

Termites include, in particular, the Hodotermitidae, Kalotermitidae, Rinotermitidae, and Termitidae families. Other pests that use it as a substrate to damage the tree by feeding on or by regeneration of the tree are, for example, tree boring insects such as the representative Lyctidae family, (Eg, xylocopa birginica) and anobida (eg, anobium punctatum).

Slugs and snails as pests are a growing problem in horticulture and agriculture. They cause severe plant damage by feeding, and can also cause undesirable contamination by slugs and snail mucus and feces. New changes in crop management have increased the number of various plant species that are susceptible to slugs and snails, eliminating burned, stump-based fields-based on an ecological approach, and existing mollusk problems, especially slugs. Instead of a suggestion that it gets worse, it induces the responsibility of changing straw.

Termites can inflict substantial damage, in particular, on ancillary structures at geographic latitudes between 42 ° N and 42 ° S. Mainly, two types of termites can be distinguished:

The subterranean termites, the most widely distributed form, require warm air and a humid environment. To ensure that the necessary moisture is always available, these termites must have direct access to wet soil. Damage caused by underground termites is actually always associated with damage to trees.

Termites, which use dry wood as their substrate, even less frequently, present a major problem because they do not need to contact wet soil. They penetrate through the gaps and vent holes to the attachment under the plank roof. Some penetrate into homes that have already invaded furniture. Pretreatment of wood is considered the most effective way to control these termites. Damage to termites that live on dry wood is slower than that of termites that live in wet environments, so damage caused by termites of the type mentioned earlier is found primarily in older appendages.

Damage caused by subterranean termites in a humid environment can be prevented by applying pesticides to termites or their habitats. Such compounds are commonly used mainly for application to the soil around the appendages.

Commercially available gastropods include metaldehyde and carbamates such as methiocarb. Carbamate is quite effective as a killing animal preparation, but presents a serious drawback that is quite toxic to mammals (eg cats, dogs and hedgehogs) and other organisms (eg harmless earthworms). While metaldehyde killing animal preparations exhibit lower toxicity, they immobilize pests by having an anesthetic or dehydrating effect, although not lethal to molluscs. Thus, for example, there is a need for useful mollusc preparations that are quite effective against slugs and snails, but have little or very low toxic effects on worms (eg earthworms) and mammals. This object is achieved by the macrolide of the present invention.

In addition, commercial termite control compositions are generally unsatisfactory in all respects because of the relatively large area around the appendage structure or because the adjunct itself must be treated with a large amount of pesticide. This can lead to a second problem at home, especially in the case of persistent pesticides. Therefore, there is another need for solutions that can be improved, in particular by applying active ingredients which can be used in small amounts and with low volatility.

Therefore, the inventive part (C) is selected to be suitable according to the intended purpose and the environment to be overcome, and comprises one or more active ingredients according to the invention, emulsifiable concentrates, suspension concentrates, directly sprayable or dilutable. It relates to pesticides such as solutions, expandable pastes, dilute emulsions, sprayable powders, soluble powders, dispersible powders, wet powders, powders, granules, pellets or encapsulating agents in polymeric materials.

In these compositions, the active ingredients are used in pure form, for example solid active ingredients of particulate size, or preferably in combination with one or more adjuvants or carriers commonly used in the formulation art.

Examples of formulation aids include solid carriers, solvents, stabilizers, sustained release aids, colorants and, optionally, surface active compounds (surfactants). Suitable carriers and auxiliaries are all materials commonly used in crop protection products, in particular in gastropods. Suitable auxiliaries such as solvents, solid carriers, surface active compounds, nonionic surfactants, cationic surfactants, anionic surfactants and the like in the compositions used according to the invention are described, for example, in EP-A 736 252. It is described in the heading.

Other suitable materials that can be used as carriers for arachnid preparations are phago-stimulants, i.e. physiologically used by handouts and / or foods (i.e. slugs and snails commonly contained in slug and snail feed formulations). Material). Mixtures of food stimulants with other suitable organic and / or inorganic carriers may also be used.

Suitable food stimulants for arachnid preparations are preferably ground grains such as flour, barley flour, rye flour and also rice starch, ground soybeans, fish meal, molasses and ground rapeseed. Only one food stimulant or a mixture of food stimulants may be used.

In order to make the food more flavorful to mollusks, one or more of the following substances can be used as additives for slug and snail feed:

a) vitamin B, in particular B1, B2, nicotinic acid or nicotinamide;

b) vitamin E;

c) animal or vegetable proteinaceous substances such as albumin and their hydrolysis products, in particular substances obtained by enzymatic hydrolysis with eg pepsin (eg meta proteins, proteases, peptone, Polypeptides, peptides, diketopiperazines and amino acids);

d) one or more amino acids or salts or amides thereof, which may be a synthetic product;

e) nucleic acids or their hydrolysis products (eg, nucleotides, nucleosides, adenine, guanine, cytosine, uracil or thymine);

f) urea, carbamic acid;

g) ammonium salts such as ammonium acetate;

h) amino sugars such as glucosamine or galactosamine;

i) sodium, potassium, calcium or magnesium compound, or a manganese, copper, iron, cobalt, zinc, trace amounts of compounds of aluminum, boron or molybdenum, in particular chelates of these (such as: Versene ^R);

j) phosphoric acid or glyceryl, but sugar phosphate;

k) water.

Stabilizers can be all known food stabilizers with bacteriostatic, fungicidal, bacteriostatic and / or bactericidal actions, such as sodium benzoate, methyl p-hydroxybenzoate, cetyltrimethylammonium bromide, citric acid , Tartaric acid, sorbic acid, phenol, alkylphenol or chlorinated phenol.

In addition to the substances mentioned as solid carriers, sustained release aids which may be used include resins such as urea / formaldehyde resins, soy flour, waxes, stearates and oils such as castor oil.

Substances which can be used as auxiliaries for arachnids according to part (C) of the present invention include, for example, binders such as methylcellosolve, polyvinylpyrrolidone, polyvinyl alcohol, polyacrylate, polymethacryl Latex, natural waxes, chemically modified waxes and synthetic waxes, sugars, starches, alginates, agar, lignosulfonates and gum arabic), humectants (e.g. polyalcohols such as sugars or glycerol), preservatives, Colorants, slugs and snails attractants, repellents for warm-blooded animals and / or other formulation aids. Mixtures with known killing animal active ingredients such as metaldehyde or mercaptodimethurr are also possible.

The formulation step can be completed by kneading, granulating (granules) and optionally pressing (pills, tablets, pellets).

In addition to the active ingredient, the killing animal composition, which preferably comprises other carriers and / or adjuvants, is preferably immediate, such as sprayable powders, trace powders, granules (the active ingredient is present as a mixture with the carrier material) or pellets. It exists in a usable form. Particularly preferred formulations are trace powders, granules or pellets.

Particularly suitable formulations for controlling molluscs according to part (C) of the present invention are actually 0 to 90%, preferably 0 to 70%, 0 to 10%, preferably 1 to 5%, of the active ingredient of the carrier material, 10 to 95%, preferably 25 to 90%, of binder, 0.5 to 25%, preferably 5 to 20%, and, optionally, 0 to 15% of other adjuvants (% in each case) Is a weight percent) granules or pellets.

The amount applied in each case as an applicator is not strict due to lack of toxicity or low toxicity to warm blooded animals, but depends on the degree of invasion, climatic conditions and the environment to be overcome such as the plants to be protected. The application rate of the food form according to the invention can vary within the practical range. In general, slugs and snails feed of 3-15 kg, preferably 5-10 kg, per hectare are used. For convenience, the gastropods are sprayed with an aqueous suspension or sprayed with powder, granules or pellets over the soil to distribute as evenly as possible among the crops. If the crop community is not dense, it may also be convenient to establish a "trapping strip" around the crop to be protected.

The gastropods preparations according to the invention are of great resistance to plants, and therefore there is no limitation in their application to the plants to be protected. Thus, all ornamental water and crops in all stages of agriculture, forestry and horticulture (also in greenhouses) can be protected from slug and snail damage.

The slug and snail feed according to the invention, the formulation of the composition for controlling tree pests and the use thereof can be seen from the following examples.

Compositions used according to the present invention part (C) for controlling gastropods and tree pests are known, for example in the absence of an adjuvant, for example, to obtain a particular particle size, for example by grinding and / or filtration. Or prepared by compacting the solid active ingredient and, in the presence of one or more adjuvants, for example by mixing and / or grinding the active ingredient thoroughly with the adjuvant / adjuvant. Methods of preparing the compositions according to the invention and the use of macrolides for preparing these compositions are also an object of the invention.

Indeed, the composition of part (C) of the present invention comprises from 0.1 to 99% of active ingredient, in particular from 0.1 to 95% and from 1 to 99.9%, in particular from 5 to 99.9% of one or more solid or liquid auxiliaries, From 25%, in particular from 0.1 to 20%, may be a surfactant (in each case% means by weight). Although concentrated compositions are more preferred as commercial products, the end consumer actually uses diluent compositions with much lower concentrations of active ingredient.

The activity of the compositions according to the invention can be significantly extended by addition of other ingredients, for example pesticidal, acaricide and / or bactericidal active ingredients, and can be chosen for the environment to be overcome. Examples of suitable additional active ingredients are the same as mentioned in part (B) of the present invention.

In a particularly preferred embodiment of the invention, the macrolide compound can be used to control termites and other tree destruction pests in the soil, thereby achieving indirect protection of the wood structure. The amount of macrolide sufficient to control the pest is preferably applied to the soil at an application rate of 1 to 2000 g, in particular 2 to 200 g, more particularly 5 to 100 g per hectare.

Working termites must work on pesticided soils to access trees. Inevitably, they ingest some pesticide and transfer it back to the termite colony to spread the active ingredient onto the termite colony.

The active ingredient (s) can be applied in the form of a feed, for example in the form of a tablet comprising the active ingredient as described in US Pat. No. 5,096,710. Particularly preferably, macrolides are applied to materials used by termites as food for the termite colony and as an accessory material. Examples of such materials are plates, paper, wood dust, cellulose powder or cotton. Useful concentrations for these materials are 0.01 to 10,000 ppm. This prey is particularly efficient, even when pheromones are used in addition, and are used on trees that have already been attacked by fungi. Such use is described, for example, in US Pat. No. 5,151,443.

Macrolides according to part (C) of the present invention are prophylactically and / or therapeutically useful active ingredients with a bactericidal spectrum which is very useful in the field of molluscs and tree pest control even at low use concentrations, Excellent resistance by The active ingredients according to the invention are not only sensitive, but also active against each or all of the growth stages of resistant mollusks and tree pests, especially termites. The action of the molluscs of the active ingredient according to the invention can be clearly seen in the form of destruction of the pests directly, ie immediately induced or shortly after, or indirectly, for example, with reduced scattering and / or hatching rates, Preferred action corresponding to the rate of destruction (lethality) is at least 50 to 60%.

The use of the active ingredients according to part (C) of the present invention can lead to the use of active ingredients, such as mollusc damage to plants, primarily agricultural, horticultural and forest plants, or organs of such plants (e.g. fruits, flowers, leaves, stems, Pests of the above-mentioned types occurring in tubers or roots can be controlled, i.e. destroyed or destroyed, and in some cases even plant organs which are subsequently formed are still protected from these pests.

Target crops suitable for mollusk control include, in particular, cereals (eg wheat, barley, rye, oats, rice, corn or sorghum); Beet (eg sugar or feed beet); Fruits, such as poultry, nucleus, and lead (eg apples, pears, plums, peaches, almonds, cherries or strawberries, such as raspberries and blackberries); Leguminous plants (eg, kidney beans, lentils, peas, soybeans); Fruit plants (eg, rape, mustard, poppy, olives, sunflowers, coconut, castor, cacao seeds, peanuts); Gourds (eg pumpkins, cucumbers, melons); Fibrous plants (eg cotton, flax, hemp, jute); Citrus plants (eg oranges, lemons, grapefruits, tangerines); Vegetables (eg, spinach, lettuce, asparagus, cabbage, carrots, onions, tomatoes, potatoes or peppers); Laurel family (eg avocados, cinnamon, camphor); Or tobacco, nuts, coffee, eggplant, sugarcane, tea, pepper, vines, hops, bananas and latex plants or flavours.

Another field of application for the active ingredient according to part (C) of the present invention is to protect the storage of stored products and materials from molluscs and tree pests.

The composition according to part (C) of the invention is also suitable for protecting plant propagation material, for example seeds (such as fruits, tubers or grains) or plant propagules from gastropods and termites, especially gastropods. The propagation material may be treated with the composition, for example, before planting the seed before sowing. Alternatively, the active ingredient according to the invention can be applied (coated) to seed grains by immersing the grains in a liquid composition or by coating them with a solid composition. In addition, the composition may be applied to the planting site when the propagation material is replanted, for example, during sowing during sowing. This method of treating plant propagation material and the plant propagation material so treated are also objects of the present invention.

The following examples are intended to describe part (C) of the present invention. They thereby do not place any restrictions.

Formulation Examples

Example F3: Preparation of Slug Pellets

40 kg crushed rapeseed (ratio of extracted / non-extracted crushed rapeseed = 65:35), 2.6 kg of a finely ground premix containing 2.1 kg of macrolide and 500 g of highly disperse silica, crosslinked corn starch 4.7 Kg, 540 g of urea / formaldehyde resin, 100 g of isopropanol, 3 kg of beet molasses and 140 g of a blue colorant (1,4-di (isobutylamino) anthraquinone) are sequentially introduced into the mixer and mixed thoroughly. It is compression molded. The product is cooled to dry and a fine 0.5 mm screen is used to remove fine material. This results in ready-to-use slug and snail feed formulations.

Instead of the compression molding method mentioned above, conventional densification methods can also be used to prepare slug and snail feed formulations.

Use Example

Example A1: Determination of efficacy of slug and snail pellets against Deroseras reticulum

The efficacy of slug and snail pellets against small snail species, for example Deroserasu species, is tested in a polycarbonate box with a 17 cm by 22 cm bottom. The bottom of the box is covered with a layer of cellulose paper that is sufficiently moistened. Slugs and snail pellets are evenly spread over half of the test area with an application rate of 20 particles, leaving the other half untreated. To avoid unreasonable behaviour, provide additional raw food to slugs, with two potato halves arranged in diagonally opposite corners of the box. Ten adult reticulated field slugs (Derocers reticulatum) are introduced into the untreated area of each box. Each test is repeated three times. Temperature and atmospheric humidity are kept substantially constant throughout the entire test period: 19 ° C. and relative atmospheric humidity of 90 to 95%. Check the status of the slug and keep a daily record for seven days. When evaluating efficacy, consider the number of animals exhibiting lethality and injury symptoms.

In this test, macrolides according to the invention are very effective.

Example A2: Determination of efficacy of slug and snail pellets against arion lupus

The efficacy of slugs and pellets for snails on larger snail species is tested in plastic test boxes equipped with wire mesh. Each box has a bottom of 0.25 m 2. The bottom of the box is applied with a compost layer for pots with a depth of 2-3 cm. Pot compost is sufficiently wetted before starting the experiment. The slug and snail pellets are evenly sprayed on the left half of the test area at an application rate of 3.1 g and the right half is left untreated. To avoid unreasonable behaviour, provide additional raw food to slugs, with two potato halves arranged in diagonally opposite corners of the box. Ten adult red slugs (Arion rugus) are introduced into the untreated area of each box. Each test is repeated four times. Temperature and atmospheric humidity are kept substantially constant throughout the entire test period: 19 ° C. and relative atmospheric humidity of 90 to 95%. Check the status of the slug and keep a daily record for seven days. When evaluating efficacy, consider the number of animals exhibiting lethality and injury symptoms.

In this test, macrolides according to the invention are very effective.

Example A3 Test of Determination of System Efficacy on Deroseras Reticulum

a) lettuce plant

The test solution is prepared by dissolving the macrolide sample in 1 ml of acetone and filling the solution with up to 50 ml of water. Roots, already washed with fresh water, of young lettuce plants 6 cm in height are immersed in this solution for at least 2 days. For each test, individual leaves are cut from these lettuce plants and placed on a 9 cm Petri dish paper filter. Pipette 1 ml of water onto each paper filter to keep the leaves wet during the experiment. Two medium size slugs are then introduced into each Petri dish and the amount and lethality of the leaves consumed are measured for 2 days.

In this test, macrolides according to the invention exhibit good action.

b) seeds

Ten slug batches are introduced into five sealed boxes containing compost and having a bottom of 35 cm x 20 cm. In each case, 100 treated winter wheat grains are evenly spread in four boxes. In the fifth box, 50 treated winter wheat grains are distributed on one side of the box and 50 untreated winter wheat kernels are distributed on the other side of the box to test for repelling action.

In this test, macrolides according to the invention are very effective.

Example A4: Action on Termites

Tree foods are treated with different amounts of macrolides and their effects on the hatching and survival of termites. Solutions with concentrations of test substance in acetone 0, 0.1, 100 and 1000 ppm are used. Water is used for control studies. Feeding consists of pine, which has been kept in its natural environment for four months.

Termites are collected from invasive pieces of open wood. To conduct tree feeding studies, the trees are maintained for 48 hours in an oven at 80 ° C. The dried wood is then weighed and the pieces left for 18 hours in a solution of the active ingredient at the desired concentration. The piece of wood is then removed from the solution, dried in air and weighed again. To assess the action of prey on termites, this treated piece of wood is placed on a thin layer of untreated soil in Petri dishes.

Termites (50 workers and 2 soldiers) are introduced into Petri dishes, respectively. The dish is examined three times per week for eight weeks. Record insect incidence, abnormality and lethality. After 8 weeks, the logs are washed with water and again dried in an oven at 80 ° C. for 48 hours. Subsequently, the weight of each piece of wood is measured in turn. The weight difference corresponds to the amount of wood consumed by termites.

In this test, macrolides according to the invention are very effective.

Claims (21)

A pest control method of crops of genetically useful useful plants, characterized by applying a pesticidal composition comprising a macrolide compound in the free form or in the form of an agrochemically useful salt as an active ingredient and one or more adjuvants to the pest or its habitat. . The method of claim 1 wherein abamectin is used. The method of claim 1, wherein emamectin is used. The method of claim 1, wherein the transgenic plant is treated. The method according to any one of claims 1 to 4, wherein the transgenic crop of the useful plant is corn. The method according to any one of claims 1 to 4, wherein the transgenic crop of useful plants is soybean. 5. A method according to claim 4, characterized by treating the propagation material of the genetically useful plant. Insecticides comprising one or more macrolide compounds in the free form or in the form of agrochemically useful salts as active ingredients and one or more auxiliaries are used in close proximity or spatially together with replanting or applying the propagation material to a planting or planting site. A method of protection against pest attack by subsequently growing plant organs and plant propagation material. The method of claim 8 wherein the active ingredient is abamectin in free form. The method according to claim 1, wherein the active ingredient used is emamectin in free form or in the form of a salt. The method according to any one of claims 8 to 10, wherein the propagation material is wool, rhizomes, seedlings, cuttings or seeds. 12. The method of claim 11, wherein the plant propagation material is seed. The method according to any one of claims 8 to 12, characterized in that the pest is a representative Redodotera neck. The method according to any one of claims 8 to 13, wherein the composition is used in such a way that the propagation material pretreated with the composition is planted or sown to a planting or planting site. The method according to any one of claims 8 to 14, wherein the pretreatment of the propagation material is seed dressing. A tree pest characterized by the application of a pesticidal active amount of pesticide comprising at least one macrolide and at least one adjuvant in free form or in an agrochemically useful salt as an active ingredient to the pest or its habitat as the pesticidal active compound. And control of molluscs. 17. The method of claim 16, wherein the active ingredient used is abamectin, emamectin or spinosad in free form or in the form of an agrochemically useful salt. 18. The method according to claim 17, wherein the active ingredient used is emamectin as the benzoate salt. The method of claim 16, wherein the gastropod is controlled. 19. The method of any one of claims 16-18, wherein the termites are controlled. A composition for controlling molluscs and tree pests, characterized in that it comprises at least one macrolide and at least one adjuvant as an insecticidal active compound.