EA046116B1 - NEW METHODS FOR DILUTATION AND CONTROLLED RELEASE OF BIOLOGICAL CONTROL AGENTS - Google Patents

Description

BACKGROUND OF THE INVENTION

Field of technology to which the invention relates

The invention relates to the field of biological control agents for the protection of agricultural crops and, more specifically, to new means and methods for breeding biological control agents directed against plant pests.

State of the art

The use of arthropods (insects and mites) as biological control agents (BCAs) is an expanding field of technology with many advantages over chemical pest control. BCA arthropods can naturally control other arthropod species that are crop pests.

Phytoseiulus is a genus of mites in the family Phytoseiidae. This predatory mite is most often used to control common spider mites in greenhouses and on crops grown outdoors in temperate environmental conditions. Mites of the genus Phytoseiulus can eat up to seven adult spider mites or several dozen of their eggs per day. A well-fed female lays approximately 50 eggs in her lifetime. The genus Phytoseiulus contains four known species, namely P. persimilis, P. longipes, P. macropilis and P. fragariae (Chant and McMurtry 2006). All species of the genus Phytoseiulus are considered type 1 predators, i.e. highly specific to a diet consisting of spider mites, preferably the genus Tetranychus (McMurtry and Croft 1997). The most commonly used species of this genus for biological control of spider mites is Phytoseiulus persimilis.

Adults of Phytoseiulus persimilis (P. persimilis) have a bright reddish-orange coloration, long legs and pear-shaped bodies (approximately 0.5 mm long).

P. persimilis is considered a specialist predator of spider mites (mites from the family Tetranychidae), which are phytophagous mites (Helle and Sabelis 1985, Gerson et al. 2003). Gerson et al., 2003 specifically stated that members of the genus Phytoseiulus live and lay their eggs almost exclusively within the spider colonies of Tetranychidae spp. Gerson et al., 2003 further noted that the specificity of P. persimilis for spider mite prey may be a disadvantage if other predators are present on the same plants.

It was found that P. persimilis can develop and possibly reproduce on another mite phytophage (herbivore), Steneotarsonemus pallidus from the family Tarsonemidae (Simmonds, S.P., 1970).

From a commercial point of view, a significant disadvantage of producing a predatory mite that feeds exclusively on phytophagous mites such as spider mites is that it requires rearing the prey mites on plants, which is expensive.

Walzer and Schausberger, 1999, examined intra- and interspecific predatory behavior of adult females and immature stages of the generalist predator Neoseiulus californicus and the specialist predator Phytoseiulus persimilis. Adult females and immature stages of both predators were reported to have higher rates of consuming larvae than eggs and protonymphs. It was found that the predatory behavior of N. californicus directed towards P. persimilis was stronger than vice versa. P. persimilis was reported to have a higher rate of predation on conspecifics than on heterospecifics and was more prone to cannibalism than N. californicus. Additionally, when provided with prey from the family Phytoseiidae, P. persimilis was reported to experience greater mortality than N. californicus.

Walzer and Schausberger, 1999 further indicate that P. persimilis females are unable to support oviposition, regardless of con- or heterospecific prey. In addition, mortality of immature P. persimilis individuals was lower when feeding on conspecific larvae compared to feeding on heterospecific larvae. These authors concluded that for P. persimilis, neither hetero- nor conspecific prey provides sufficient levels of nutrients for sustained reproduction. This is supported by Yao and Chant (1989), who reported that P. persimilis did not produce eggs when it either engaged in cannibalism or preyed on immature Iphyseius degenerans. In this study, only two females were observed, which laid one egg each during cannibalism on conspecific individuals.

Finally, it was found that P. persimilis can develop by feeding on juvenile predatory mites Neoseiulus californicus and Iphyseius degenerans from the family Phytoseiidae. However, it did not lay eggs when feeding on these mites, which served as prey. On the other hand, when the predatory mites N. californicus and I. degenerans fed on P. persimilis, they laid eggs (Yao and Chant, 1989). This shows the narrow dietary range of P. persimilis in contrast to other mites of the same family.

P. persimilis may also develop as a cannibal, feeding on the younger stages of its own species. Oviposition was rare when feeding in this manner (Walzer and Schausberger, 1999; Yao and Chant, 1989). In all cases where mites of the family Phytoseiidae were used as prey, they were fed spider mites, which are grown on plants and therefore involve high costs.

It was additionally found that P. persimilis thrives by feeding on thrips larvae (phytophagous insects) but does not lay eggs on this diet (Walzer 2004). This is in contrast to the predatory mite N. califonicus, which could reproduce by feeding on this prey (Walzer 2004). It should be emphasized that this study reported a high mortality rate during juvenile development.

US Patent No. 9,781,937 and EP Patent No. 2,612,551 disclose a mite composition comprising a species of predatory mite selected from a species of mesostigmatoid mite or a species of prostigmatoid mite, and a food source for the species of predatory mite selected from a species of astigmatoid mite. In addition, these publications disclose that at least a portion of the astigmatosis mites are immobilized, and that the immobilized astigmatosis mites are brought into contact with a fungal growth reducing agent comprising a fungal growth reducing mite population selected from a species of mycophagous mites or a type of mite that produces antifungal substances.

US Pat. No. 7,947,269 discloses a mite composition comprising a breeding population consisting of a species of predatory mites of the family Phytoseiidae and an artificial host population comprising at least one species selected from the family Carpoglyphidae.

US Pat. No. 8,097,248 discloses a mite composition comprising a breeding population consisting of a species of predatory mite of the family Phytoseiidae, Amblyseius swirskii, an artificial host population comprising at least one species of astigmatic mite selected from the group consisting of: i) Carpoglyphidae , ii) Pyroglyphidae and iii) Glyciophagidae.

US Pat. No. 8,733,283 discloses a method for breeding predatory mites by providing a food source for the prey mites that includes dextrose; breeding Thyreophagus entomophagus mites as prey on said food source; providing predatory mites that feed on Thyreophagus entomophagus, with an initial ratio of predatory mites to prey mites from 1:10 to 1:100, and breeding predatory mites on said prey mites to create a breeding population.

US Patent No. 8,733,283 and EP No. 2,048,941 state that Phytoseiulus persimilis can only be grown on a diet consisting of spider mites. The authors report that P. persimilis is a predator that feeds only on spider mites and cannot survive on alternative food sources such as pollen. These publications highlight that there is a tendency for survival to decrease when there is a shortage of prey.

EP Patent No. 2,380,436 discloses a mite composition comprising a breeding population of a species of predatory mites of the family Phytoseiidae and a population of at least one species of the order Astigmata, characterized in that the individuals in the population of the species of the order Astigmata are non-living.

WO2007075081 discloses a mite composition comprising a breeding population consisting of a species of predatory mites of the family Phytoseiidae, and an artificial host population, characterized in that the artificial host population includes at least one species selected from the family Glyciphagidae. Regarding the mite family Phytoseiidae, Phytoseiulus persimilis, spider mites (Tetranychus urticae) are indicated as the best prey.

None of the above patent documents disclose or indicate the successful rearing of the important predatory mite Phytoseiulus persimilis on mites of the order Astigmata in any form or at any stage of development. In contrast, all of the above patent documents and scientific publications report that P. persimilis is a predator that feeds only on spider mites and cannot survive on alternative food sources. Therefore, an entomologist/acarologist would not consider P. persimilis as a typical generalist predator species of the family Phytoseiidae or subfamily Amblyseiinae, but rather as a highly specialized species.

In view of the above, there is a long overdue need for effective and economically viable mass rearing of Phytoseiulus persimilis for biological control of crop pests.

Brief description of the invention

The present invention relates to the field of insect control and more particularly to a system and method for diluting biological control agents against plant pests.

One object of the present invention is to disclose a combination for breeding Phytoseiulus predatory mites, comprising a population of predatory mites comprising at least one species of mites from the genus Phytoseiulus, and a population of prey mites containing at least one species from the order Astigmata, wherein said population of predatory mites mites is a population selected to lay eggs for at least 2 generations on said prey mites of the order Astigmata, wherein further said mites of the order Astigmata prey belong to a family selected from Glycyphagidae, Pyroglyphidae and Carpoglyphidae, and selected from a group consisting of non-viable eggs or a combination of non-viable eggs

- 2,046,116 eggs and non-viable mites.

It is a further object of the present invention to disclose a breeding combination according to any of the above definitions, wherein said predatory mite is capable of laying eggs for at least 10 generations, bred on said prey mites of the order Astigmata.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein said population of predatory mites is characterized by a trait of increased reproduction rate compared to a control population of predatory mites without the trait.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein said population of predatory mites is characterized by a beige-white coloration.

It is a further object of the present invention to provide a propagation combination according to any of the above definitions, wherein said combination does not contain a fungal growth reducing agent.

It is a further object of the present invention to disclose a breeding combination according to any of the above definitions, wherein said predatory mite species is selected from the group consisting of Phytoseiulus fragariae, Phytoseiulus longipes, Phytoseiulus macropilis, Phytoseiulus persimilis and Phytoseiulus robertsi.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein said predatory mite species is Phytoseiulus persimilis.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein the species from the order Astigmata belongs to a family selected from the group consisting of Carpoglyphidae, Pyroglyphidae, Acaridae and Glycyphagidae.

It is a further object of the present invention to disclose a breeding combination according to any of the above definitions, wherein a species from the order Astigmata includes members of the family Carpoglyphidae, such as the genus Carpoglyphus, such as Carpoglyphus lactis, Carpoglyphus munroi, from the family Glycyphagidae, such as the genus Glycyphagus, for example Glycyphagus domesticus, from the genus Lepidoglyphus, for example Lepidoglyphus destructor, from the family Pyroglyphidae, such as the genus Dermatophagoides, for example Dermatophagoides farinae, Dermatophagoides pteronisinus, from the family Acaridae, such as the genus Tyrophagus, for example Tyrophagus putrescentiae.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein said prey population of mites of the order Astigmata is in frozen form.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein said prey population of mites of the order Astigmata comprises a mixture containing non-viable frozen juvenile mites at various stages of development.

It is a further object of the present invention to disclose a breeding combination as defined above, wherein the combination comprises at least one species of mites of the genus Phytoseiulus and a mixture containing non-viable frozen juvenile C. lactis mites at various stages of development and sawdust or other material. carrier.

It is a further object of the present invention to provide a propagation combination as defined above, wherein the combination comprises P. persimilis and a mixture containing non-viable frozen juvenile C. lactis ticks at various stages of development and sawdust or other carrier material.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein said prey population of mites of the order Astigmata comprises non-viable eggs of C. lactis.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein said prey population of mites of the order Astigmata comprises non-viable eggs and non-viable juvenile mites in a 1:1 (w/w) ratio.

It is a further object of the present invention to provide a reconstitution combination according to any of the above definitions, wherein said combination further comprises a carrier such as sawdust, bran or other carrier material.

It is a further object of the present invention to disclose a breeding combination according to any of the above definitions, wherein said population of predators reared on said mite species of the order Astigmata reproduces at an average rate of at least about 15% per day, particularly in the range of 15 % up to 25% per day.

It is a further object of the present invention to provide a combination for diluting

- 3 046116 according to any of the above definitions, wherein said individuals of astigmatoid mites are treated with a treatment selected from the group consisting of thermal treatment such as freezing, heating, cold shock treatment or heat shock treatment; chemical treatment such as gas or smoke treatment; radiation treatments such as UV, microwave, gamma or x-ray treatments; mechanical processing such as vigorous shaking or stirring, shearing, impact; processing by changing gas pressure, such as ultrasonic treatment, pressure changes, pressure drops; electrical treatment such as electric shock; immobilization with adhesive; immobilization due to fasting, such as induced by water or food deprivation; immobilization by treatment causing asphyxiation or oxygen deprivation, such as temporary removal of oxygen from the atmosphere or replacement of oxygen with another gas, and any combination thereof.

It is a further object of the present invention to provide a breeding combination as defined above, wherein the combination comprises P. persimilis and a mixture containing non-viable C. lactis eggs and sawdust or other carrier material.

It is a further object of the present invention to provide a breeding combination as defined above, wherein said combination comprises P. persimilis and a mixture containing non-viable C. lactis mites and sawdust or other carrier material.

It is a further object of the present invention to disclose a breeding combination according to any of the above definitions, wherein said combination comprises a population of the predatory mites Phytoseiulus persimilis and dead individuals of at least one species belonging to the order Astigmata selected from the group consisting of Carpoglyphus lactis, Lepidoglyphus destructor, Glycifagus domestics, Dermatophagoides farinae and Dermatophagoides pteronisinus.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein said prey mite population further includes a species of mite from the family Phytoseiidae.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions wherein said prey species of mites of the family Phytoseiidae is nonviable.

It is a further object of the present invention to provide a propagation combination according to any of the above definitions, wherein said combination is capable of controlling a crop pest.

It is a further object of the present invention to disclose a breeding combination according to any of the above definitions, wherein said crop pest is selected from the group of mites, in particular members of the family Tetranychidae subclass Acari, such as the common spider mite, more particularly a species of spider mite, in particular Tetranychus , Panonychus and various other species of mites.

It is a further object of the present invention to provide a propagation combination according to any of the above definitions, wherein said combination is capable of reducing said crop pest by at least 50%.

It is a further object of the present invention to provide a propagation combination according to any of the above definitions, formulated for the controlled release of said predatory mites onto a crop plant.

It is a further object of the present invention to provide a propagation combination according to any of the above definitions contained in a container configured to release said predatory mites on a crop plant in a controlled manner.

It is a further object of the present invention to provide a breeding combination as defined above, wherein said predatory mites are capable of being slowly and continuously released from said container onto said crop over a period of approximately three weeks.

A further object of the present invention is to disclose a method for breeding a population of predatory mites containing at least one species of mites from the genus Phytoseiulus, the method comprising: (a) providing a Phytoseiulus breeding combination according to any one of claims 1 to 24; and (b) allowing individuals from the predatory mite population to prey on individuals from the astigmatosis mite population for at least 2 generations.

It is a further object of the present invention to provide a method for propagating a population of predatory mites containing at least one species of mites from the genus Phytoseiulus, the method comprising: (a) providing a combination comprising a population of predatory mites containing at least one species of mites from the genus Phytoseiulus, and a population of prey mites comprising individuals of at least one species of mite from the order Astigmata, wherein said population of prey

- 4,046,116 mites are selected to lay eggs for at least 2 generations on said prey mites of the order Astigmata; (b) allowing individuals from the predatory mite population to prey on individuals from the astigmatosis mite population for at least 2 generations; wherein said prey mites of the order Astigmata belong to a family selected from Glycyphagidae, Pyroglyphidae and Carpoglyphidae, and said prey mites of the order Astigmata are selected from the group consisting of non-viable eggs or a combination of non-viable eggs and non-viable mites.

A further object of the present invention is to disclose a method according to any of the above definitions, wherein the breeding population is maintained in a temperature range of 18-30°C, in particular at approximately 22°C.

It is a further object of the present invention to disclose a method according to any of the above definitions, wherein the breeding population is maintained at a relative humidity of 70-90%, in particular approximately 85%.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein said predatory mite is capable of laying eggs for at least 2 generations, preferably for at least 10 generations, reared on said prey mites of the order Astigmata.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein said population of predatory mites is characterized by a beige-white coloration.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein said combination does not contain a fungal growth reducing agent.

It is a further object of the present invention to disclose a method according to any of the above definitions, wherein said predatory mite species is selected from the group consisting of Phytoseiulus fragariae, Phytoseiulus longipes, Phytoseiulus macropilis, Phytoseiulus persimilis and Phytoseiulus robertsi.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein said predatory mite species is Phytoseiulus persimilis.

It is a further object of the present invention to disclose a method according to any of the above definitions, wherein the species from the order Astigmata belongs to a family selected from the group consisting of Carpoglyphidae, Pyroglyphidae, Acaridae and Glycyphagidae.

It is a further object of the present invention to disclose a method according to any of the above definitions, wherein a species of the order Astigmata includes members of the family Carpoglyphidae, such as the genus Carpoglyphus, such as Carpoglyphus lactis, Carpoglyphus munroi, the family Glycyphagidae, such as the genus Glycyphagus, for example Glycyphagus domesticus, from the genus Lepidoglyphus, for example Lepidoglyphus destructor; from the family Pyroglyphidae, such as the genus Dermatophagoides, for example Dermatophagoides farinae, Dermatophagoides pteronisinus, from the family Acaridae, such as the genus Tyrophagus, for example Tyrophagus putrescentiae.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein said prey population of mites of the order Astigmata is in frozen form.

It is a further object of the present invention to provide a method as defined in any of the above, wherein said prey population of mites of the order Astigmata comprises a mixture containing non-viable frozen juvenile mites at various stages of development.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the combination comprises at least one species of mites of the genus Phytoseiulus and a mixture containing non-viable frozen juvenile C. lactis mites at various stages of development and sawdust or other carrier material.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the combination comprises P. persimilis and a mixture containing non-viable frozen juvenile C. lactis ticks at various stages of development and sawdust or other carrier material.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein said prey population of mites of the order Astigmata comprises non-viable eggs of C. lactis.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein said prey population of mites of the order Astigmata comprises non-viable eggs and non-viable juvenile mites in a 1:1 (w/w) ratio.

- 5 046116

It is a further object of the present invention to provide a method according to any of the above definitions, wherein said combination further comprises a carrier such as sawdust, bran or other carrier material.

It is a further object of the present invention to disclose a method according to any of the above definitions, wherein said population of predators reared on said mite species of the order Astigmata reproduces at an average rate of at least about 15% per day, in particular in the range of 15% to 25 % per day.

It is a further object of the present invention to disclose a method according to any of the above definitions, wherein said astigmatite mites are treated with a treatment selected from the group consisting of heat treatment such as freezing, heating, cold shock treatment or heat shock treatment; chemical treatment such as gas or smoke treatment; radiation treatments such as UV, microwave, gamma or x-ray treatments; mechanical processing such as vigorous shaking or stirring, shearing, impact; processing by changing gas pressure, such as ultrasonic treatment, pressure changes, pressure drops; electrical treatment such as electric shock; immobilization with adhesive; immobilization due to fasting, such as induced by water or food deprivation; immobilization by treatment causing asphyxiation or oxygen deprivation, such as temporary removal of oxygen from the atmosphere or replacement of oxygen with another gas, and any combination thereof.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein said combination comprises P. persimilis and a mixture containing non-viable C. lactis eggs and sawdust or other carrier material.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein said combination comprises P. persimilis and a mixture containing non-viable C. lactis mites and sawdust or other carrier material.

It is a further object of the present invention to disclose a method according to any of the above definitions, wherein said combination comprises a population of predatory mites Phytoseiulus persimilis and dead individuals of at least one species belonging to the order Astigmata selected from the group consisting of Carpoglyphus lactis, Lepidoglyphus destructor, Glycifagus domestics , Dermatophagoides farinae and Dermatophagoides pteronisinus.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein said prey mite population further comprises a species of mite from the family Phytoseiidae.

It is a further object of the present invention to provide a method according to any of the above definitions wherein said prey species of mites of the family Phytoseiidae is nonviable.

It is a further object of the present invention to provide a method for controlling a crop pest, the method comprising using a combination for propagating Phytoseiulus as defined above in relation to a crop grown in soil.

It is a further object of the present invention to disclose a method according to any of the above definitions, wherein said crop pest is selected from the group of mites, in particular members of the family Tetranychidae subclass Acari, such as the common spider mite, more particularly a species of spider mite, in particular Tetranychus, Panonychus and various other species of mites.

It is a further object of the present invention to disclose the use of a combination for propagating Phytoseiulus according to any of the above definitions for the control of a crop pest.

It is a further object of the present invention to disclose a use according to any of the above definitions, wherein the crop pest is selected from the range of mites, in particular members of the family Tetranychidae subclass Acari, such as the common spider mite, more particularly spider mite species, especially Tetranychus, Panonychus and various other types of ticks.

It is a further object of the present invention to disclose a use according to any of the above definitions, wherein the crop is selected from the group consisting of greenhouse crops, outdoor crops, vegetables, ornamental plants, fruit trees, hop varieties, cotton and varieties of strawberries.

It is a further object of the present invention to disclose a biological control agent (BCA) for the control of crop pests comprising a mixture of: (a) at least one species of predatory mites from the genus Phytoseiulus, wherein said species of predatory mites is attacked by

- 6 046116 is a population of Phytoseiulus selected to lay eggs for at least 2 generations on specified prey mites of the order Astigmata, (b) individuals of prey mites comprising at least one species of the order Astigmata, said individuals of the order Astigmata belong to a family selected from Glycyphagidae, Pyroglyphidae and Carpoglyphidae, and are selected from the group consisting of lifeless eggs or a combination of lifeless eggs and lifeless mites; and (c) carrier material.

It is a further object of the present invention to provide a BCA according to any of the above definitions, wherein said population of predatory mites is characterized by a beige-white coloration.

A further object of the present invention is to disclose a pest control container containing a Phytoseiulus propagation combination according to any one of claims 1 to 29, wherein said container is configured to be attached to a crop plant, wherein said container contains an outlet from which said predatory mites released slowly and continuously onto the designated crop over a period of approximately three weeks.

It is a further object of the present invention to provide a container according to any of the above definitions, wherein said container is selected from the group consisting of sachet, pouch, chamber, pouch, pouch, bottle and bag.

It is a further object of the present invention to disclose a container according to any of the above definitions, wherein said prey mites are in frozen form.

It is a further object of the present invention to disclose a container according to any of the above definitions, wherein said prey mites are frozen astigmatoid mite eggs.

It is a further object of the present invention to disclose a container as defined above, wherein said prey mites are frozen eggs of Carpoglyphus lactis.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein the prey population of Astigmata mites is at least partially immobilized.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein the prey population of mites of the order Astigmata is immobilized.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein the prey population of mites of the order Astigmata comprises dead eggs and at least partially immobilized mites.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein the prey population of mites of the order Astigmata includes eggs and dead mites.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein the prey population of mites of the order Astigmata comprises eggs and immobilized juvenile mites in a 1:1 (w/w) ratio.

It is a further object of the present invention to disclose a breeding combination according to any of the above definitions, wherein the mites are immobilized by an immobilizing treatment selected from the group consisting of thermal treatment such as freezing, heating, cold shock treatment or heat shock treatment; chemical treatment such as gas or smoke treatment; radiation treatments such as UV, microwave, gamma or x-ray treatments; mechanical processing such as vigorous shaking or stirring, shearing, impact; processing by changing gas pressure, such as ultrasonic treatment, pressure changes, pressure drops; electrical treatment such as electric shock; immobilization with adhesive; immobilization due to fasting, such as induced by water or food deprivation; immobilization by treatment causing asphyxiation or oxygen deprivation, such as temporary removal of oxygen from the atmosphere or replacement of oxygen with another gas, and any combination thereof.

It is a further object of the present invention to provide a propagation combination as defined above, wherein the combination comprises P. persimilis and a mixture containing immobilized C. lactis mites and sawdust or other carrier material.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein the immobilized C. lactis ticks are dead ticks.

It is a further object of the present invention to provide a combination for diluting

- 7 046116 according to any of the above definitions, wherein the combination contains a population of predatory mites Phytoseiulus persimilis and dead individuals of C. lactis as a population of mites serving as prey, wherein additionally in the population of predatory mites Phytoseiulus persimilis they are capable of laying eggs for at least 2 generations, preferably over at least 10 generations.

It is a further object of the present invention to disclose a breeding combination according to any of the above definitions, wherein the combination comprises a population of predatory mites Phytoseiulus persimilis and dead individuals of at least one species belonging to the order Astigmata selected from the group consisting of Carpoglyphus lactis, Lepidoglyphus destructor, Glycifagus domestics, Dermatophagoides farinae and Dermatophagoides pteronisinus.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein the prey mite population further includes a species of mite from the family Phytoseiidae.

It is a further object of the present invention to disclose a breeding combination according to any of the above definitions, wherein the prey species of mites of the family Phytoseiidae belongs to the genus Amblyseius, for example Amblyseius swirskii.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein the prey species of mite is Amblyseius swirskii.

It is a further object of the present invention to disclose a breeding combination according to any of the above definitions, wherein the combination comprises a population of predatory mites Phytoseiulus persimilis and a population of prey mites comprising mites of the species Amblyseius swirskii.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein Amblyseius swirskii mites are at least partially immobilized.

It is a further object of the present invention to disclose a breeding combination comprising a predatory mite population comprising at least one species of mites from the genus Phytoseiulus and a prey mite population comprising at least one species from the family Phytoseiidae.

It is a further object of the present invention to disclose a breeding combination according to any of the above definitions, wherein the prey species of mite is of the genus Amblyseius, for example Amblyseius swirskii.

It is a further object of the present invention to provide a breeding combination according to any of the above definitions, wherein the prey tick is immobilized.

It is a further object of the present invention to provide a method according to any of the above definitions wherein the prey population of mites of the order Astigmata is at least partially immobilized.

It is a further object of the present invention to disclose a method according to any of the above definitions, wherein the prey population of mites of the order Astigmata is immobilized.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the prey population of ticks of the order Astigmata comprises a mixture containing dead frozen juvenile ticks at various stages of development.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the combination comprises P. persimilis and a mixture containing dead frozen juvenile C. lactis ticks at various stages of development and sawdust or other carrier material.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the prey population of mites of the order Astigmata comprises eggs and at least partially immobilized mites.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the prey population of mites of the order Astigmata includes eggs and dead mites.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the prey population of mites of the order Astigmata comprises eggs and immobilized juvenile mites in a 1:1 (w/w) ratio.

It is a further object of the present invention to disclose a method according to any of the above definitions, wherein ticks are immobilized by an immobilizing treatment selected from the group consisting of thermal treatment such as freezing, heating, cold shock treatment or heat shock treatment; chemical treatment such as treatment

- 8 046116 gas or smoke; radiation treatments such as UV, microwave, gamma or x-ray treatments; mechanical processing such as vigorous shaking or stirring, shearing, impact; processing by changing gas pressure, such as ultrasonic treatment, pressure changes, pressure drops; electrical treatment such as electric shock; immobilization with adhesive; immobilization due to fasting, such as induced by water or food deprivation; immobilization by treatment causing asphyxiation or oxygen deprivation, such as temporary removal of oxygen from the atmosphere or replacement of oxygen with another gas, and any combination thereof.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein said combination comprises P. persimilis and a mixture containing immobilized C. lactis mites and sawdust or other carrier material.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the immobilized C. lactis ticks are dead ticks.

It is a further object of the present invention to disclose a method according to any of the above definitions, wherein the combination contains a population of predatory mites Phytoseiulus persimilis and dead individuals of C. lactis as a population of mites serving as prey, wherein additionally in the population of predatory mites Phytoseiulus persimilis they are capable of laying eggs for at least 2 generations, preferably over at least 10 generations.

It is a further object of the present invention to disclose a method according to any of the above definitions, wherein the combination comprises a population of predatory mites Phytoseiulus persimilis and dead individuals of at least one species belonging to the order Astigmata selected from the group consisting of Carpoglyphus lactis, Lepidoglyphus destructor, Glycifagus domestics, Dermatophagoides farinae and Dermatophagoides pteronisinus.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the prey mite population further includes a species of mite from the family Phytoseiidae.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the prey species of mite is of the genus Amblyseius, for example Amblyseius swirskii.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the prey species of mite is Amblyseius swirskii.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the combination comprises a population of predatory mites Phytoseiulus persimilis and a population of prey mites comprising mites of the species Amblyseius swirskii.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein Amblyseius swirskii mites are at least partially immobilized.

A further object of the present invention is to disclose a method for breeding a population of predatory mites including at least one species of mites from the genus Phytoseiulus, the method comprising: (a) providing the combination of claim 26; and (b) allowing members of the predatory mite population to prey on members of the Phytoseiidae mite population.

It is a further object of the present invention to disclose a method according to any of the above definitions, wherein the predatory mite species is selected from the group consisting of Phytoseiulus fragariae, Phytoseiulus longipes, Phytoseiulus macropilis, Phytoseiulus persimilis and Phytoseiulus robertsi.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the predatory mite species is Phytoseiulus persimilis.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the prey species of mite is of the genus Amblyseius, for example Amblyseius swirskii.

It is a further object of the present invention to provide a method according to any of the above definitions, wherein the prey tick is immobilized.

It is a further object of the present invention to disclose a biological control product for the control of crop pests comprising a mixture of (a) Phytoseiulus persimilis predatory mites grown in a combination according to any of the above definitions, (b) prey mites including at least one species from the order Astigmata, and (c) optionally a carrier material.

It is a further object of the present invention to provide a biological control product as defined above, wherein a species of the order Astigmata includes members of the family Carpoglyphidae, such as the genus Carpoglyphus, such as Carpoglyphus lactis, Carpoglyphus munroi, of the family Glycyphagidae, such as the genus Glycyphagus , for example Glycyphagus domesticus, from the genus

- 9 046116

Lepidoglyphus, for example Lepidoglyphus destructor; from the family Pyroglyphidae, such as the genus Dermatophagoides, for example Dermatophagoides farinae, Dermatophagoides pteronisinus, from the family Acaridae, such as the genus Tyrophagus, for example Tyrophagus putrescentiae.

It is a further object of the present invention to disclose a biological control product for the control of crop pests comprising a mixture of (a) Phytoseiulus persimilis predatory mites grown in a combination according to any of the above definitions, (b) prey mites including: at least one species from the family Phytoseiidae, and (c) optionally a carrier material.

It is a further object of the present invention to provide a biological control product for the control of crop pests, including members of the genus Phytoseiulus, grown using a combination according to any of the above definitions.

It is a further object of the present invention to provide a combination according to any of the above definitions, formulated for the controlled release of predatory mites on a crop plant.

It is a further object of the present invention to disclose a container containing a combination according to any of the above definitions, wherein the container is configured to be attached to a crop plant, the container comprising an outlet from which predatory mites are slowly and continuously released onto the crop over a period of approximately three weeks.

It is a further object of the present invention to disclose a container as defined above, wherein the container is selected from the group consisting of sachet, pouch, chamber, pouch, pouch and bag.

It is a further object of the present invention to disclose a container according to any of the above definitions, wherein the prey mites are frozen astigmatosis mite eggs.

It is a further object of the present invention to disclose a container according to any of the above definitions, wherein the prey mites are frozen Carpoglyphus lactis eggs.

Brief description of graphic materials

To provide an understanding of the present invention and an idea of how it may be put into practice, a number of embodiments have been adapted at this time, intended to be described by way of non-limiting example only with reference to the accompanying drawings; this implies the following:

in fig. Figure 1 shows a photograph of different stages of development of P. persimilis reared on dead or immobilized ticks Carpoglyphus lactis (C. lactis);

in fig. 2 is a photograph of P. persimilis reared on dead or immobilized Carpoglyphus lactis (C. lactis) ticks, as an embodiment of the present invention;

in fig. 3 is a graph describing the daily reproduction rate of a population of P. persimilis when fed a mixture of dead C. lactis eggs and dead motile stages over a 14-week period;

in fig. Figure 4 is a graph of the percentage of P. persimilis showing signs of feeding, as indicated by their body shape and coloration;

in fig. Figure 5 graphically illustrates the dependence of the rate of mite release on the number of days after the start of the experiment;

in fig. Figure 6 graphically illustrates the differences between the daily reproduction rate of the original population of P. persimilis (P+ and P-) reared on C. lactis as prey; whereby the P+ population was propagated and selected for improved adaptation to C. lactis as prey; The P population is a commercially available control population of P. persimilis; and in fig. 7 graphically illustrates the number of P. persimilis (Pp) and spider mites on plants treated with the slow release system of the present invention compared to control plants.

Detailed Description of the Invention

The common spider mite, Tetranychus urticae Koch, is a major spider mite pest of ornamental plants and vegetable crops grown in greenhouses. In addition, this ubiquitous spider mite is a serious pest of numerous ornamental plants in home gardens and is of great importance as a pest of food and fiber crops throughout the world (van de Vrie et al., 1972). The predatory mite Phytoseiulus persimilis of the family Phytoseiidae is the main species used to control common spider mites in greenhouses as well as outdoor crops.

Phytoseiulus persimilis is a predatory mite whose specialized diet

- 10 046116 are spider mites. Spider mites are herbivorous mites (phytophagous mites) and therefore require rearing on plants, which is undesirable as it involves complex operations and high rearing costs.

The present invention provides for the first time an alternative method for breeding P. persimilis and other species of mites from the genus Phytoseiulus. Contrary to conventional wisdom, the present invention demonstrates that the diet range of a tick species of the genus Phytoseiulus, such as P. persimilis, can be expanded and can be cultured on other types of prey that are cheaper to obtain and therefore much more preferable. Alternative prey mites are predominantly astigmatoid mites, which feed on stored food and are therefore significantly less expensive to obtain.

In accordance with one embodiment of the present invention, a system and method is provided for using mites (specifically dead mites) of the species Carpoglyphus lactis (C1) or other astigmatoid mites as an alternative food source for a mite species of the genus Phytoseiulus, such as Phytoseiulus persimilis.

The present invention shows that a species of mite from the genus Phytoseiulus, in particular Phytoseiulus persimilis, can complete its life cycle and reproduce by feeding on dead mites belonging to the order Astigmata (within the class Arachnida).

The present invention is directed to the development of a system for producing a species of mite from the genus Phytoseiulus, for example Phytoseiulus persimilis, by feeding a diet containing astigmatite mites. The system is based on the following components:

1. Predator - specifically Phytoseiulus persimilis and, in a broader sense, mites from the genus Phytoseiulus.

2. Prey - a species of mite, possibly Carpoglyphus lactis, Glyciphagus domesticus, Lepidoglyphus destructor, Dermatophagoides farinae, Dermatophagoides pteronisinus, or another astigmatoid mite, or another species of mite such as Amblyseius swirskii.

3. Rearing system - a specific installation in which ticks are reared, containing a rearing medium, that is, the manner in which the prey tick is presented to the predator, the developmental stage of the prey, and other factors.

The following dilution methods are within the scope of the present invention.

1. The predator is bred on a mixture of live ticks that serve as prey.

2. The predator is provided with a mixture of prey mites that are immobilized by freezing or other means such as irradiation.

3. A prey tick is removed from a population of prey ticks at a certain stage of development, and then, alive or dead, it serves as food for the predator.

It should be noted that in all of the above-mentioned optional breeding methods, the prey mite may be either one of the above mentioned astigmatoid mites or another species.

In view of the end product for biological control, the following is within the scope of the present invention.

1. A mixture that contains both a predator and prey mites, or a predator and prey mites, at specific stages that are used to feed the predator.

2. An additional option is to extract only the predators, resulting in the final product containing only predators.

In accordance with one embodiment of the present invention, there is provided a breeding composition comprising a population of predatory mites comprising at least one species of mites from the genus Phytoseiulus, and a population of prey mites comprising individuals of at least one species of mites from the order Astigmata, wherein of said population of predatory mites, they are capable of laying eggs for at least 2 generations, wherein additionally said mite of the order Astigmata serving as prey is selected from the group consisting of non-viable mites, non-viable eggs and a combination thereof.

It is within the scope of the present invention that the predatory mite is capable of laying eggs for at least 10 generations and preferably more with members of the order Astigmata as prey.

It is further within the scope of the present invention that a population of predatory mites is characterized by the trait of increased reproduction rate compared to a control population of predatory mites of the same species without the above trait.

It is further within the scope of the present invention that the population of predatory mites of the present invention has a daily reproduction rate in the range of approximately 1.15-1.2.

It is further within the scope of the present invention that the population of predatory mites is characterized by a beige-white coloration when said predatory mite of the genus Phytoseiulus is bred on said mites of the order Astigmata serving as prey as a food source.

It is within the scope of the present invention that predators will have a different appearance

- 11 046116 a species that distinguishes them from a conventional product containing P. persimilis mites bred on spider mites (in the case of the present invention, white mites instead of the usual orange mites).

In accordance with a further embodiment of the present invention, it was demonstrated for the first time that a population of P. persimilis successfully developed and reproduced when feeding on dead Carpoglyphus lactis for at least six months (approximately 25 generations).

It is emphasized that this paper unexpectedly reports that P. persimilis completes its life cycle and reproduces by feeding on either nonphytophagous prey (prey that does not require feeding on living plants) or prey that does not consume phytophagous mites.

The present invention provides a mite composition that contains a population of Phytoseiulus persimilis mites for breeding and a population of artificial host mites including at least one species from the order Astigmata or from the family Phytoseiidae. Until now, mite species of the genus Phytoseiulus, such as the important predatory mite Phytoseiulus persimilis, have been bred on their natural diet of phytophagous mites, which involves high costs and resources (such as providing suitable plants in sufficient quantities in a greenhouse environment ).

The present invention solves the serious problem of breeding the main predator controlling spider mites, Phytoseiulus persimilis, by breeding it in a cost effective and economically feasible manner using an alternative diet based on non-phytophagous mites.

Accordingly, the present invention provides a mite composition comprising a breeding population consisting of a species of mites from the genus Phytoseiulus, for example, the species of predatory mites Phytoseiulus persimilis, a population consisting of at least one species from the order Astigmata or from the family Phytoseiidae, and not necessarily the carrier.

In accordance with one embodiment of the present invention, there is provided a breeding composition comprising a population of predatory mites comprising at least one species of mites from the genus Phytoseiulus, and a population of prey mites including at least one species from the order Astigmata.

In accordance with a further embodiment of the present invention, there is provided a method of propagating a population of predatory mites including at least one species of mites from the genus Phytoseiulus, the method comprising: (a) providing a composition containing a population of predatory mites including at least one species of mites from the genus Phytoseiulus, and a population of prey mites including at least one species from the order Astigmata; and (b) allowing individuals from the predatory mite population to prey on individuals from the astigmatosis mite population.

In accordance with a further embodiment of the present invention, there is provided a breeding composition comprising a population of predatory mites including at least one species of mites from the genus Phytoseiulus and a population of prey mites including at least one species from the family Phytoseiidae.

In accordance with a further embodiment of the present invention, there is provided a method of propagating a population of predatory mites including at least one species of mites from the genus Phytoseiulus, the method comprising: (a) providing a composition containing a population of predatory mites including at least one species of mites from the genus Phytoseiulus, and a population of prey mites comprising at least one species from the family Phytoseiidae; and (b) allowing members of the predatory mite population to prey on members of the Phytoseiidae mite population.

In some embodiments, individuals in the prey tick population, i.e., a species in the order Astigmata or a species in the family Phytoseiidae, are immobilized and/or non-living.

It is further within the scope of the present invention that the predatory mite Phytoseiulus persimilis is capable of reproducing for at least 2 generations, preferably at least 10 generations, more preferably for at least 15 generations or more generations while feeding on said population of mites order Astigmata.

The composition of the present invention provides a significant number of advantages over previous combinations. In one aspect, the food material used to feed the prey during predator production will no longer be plants or mites, but mites that live on the stored food, hence a significant cost savings.

In another aspect of the present invention, there is provided a breeding composition comprising a population of predatory mites comprising at least one species of mites from the genus Phytoseiulus and a population of prey mites including at least one species from the family Phyto

- 12 046116 seiidae.

In accordance with some further embodiments of the present invention, the predatory mite species is selected from the group consisting of Phytoseiulus fragariae, Phytoseiulus longipes, Phytoseiulus macropilis, Phytoseiulus persimilis and Phytoseiulus robertsi.

In accordance with further embodiments of the present invention, the predatory mite species is Phytoseiulus persimilis.

In yet further embodiments of the present invention, the prey species of mite is a member of the genus Amblyseius, for example Amblyseius swirskii.

In accordance with additional embodiments of the present invention, the propagation composition contains immobilized prey ticks.

In accordance with additional aspects of the present invention, the prey ticks are immobilized or dead ticks.

In accordance with additional aspects of the present invention, there is provided a method for controlling a crop pest, the method comprising applying a composition as defined above to a crop grown in soil.

In accordance with additional aspects of the present invention, the use of a composition according to any of the above definitions for the control of a crop pest is provided.

In accordance with further aspects of the present invention, there is provided a biological control product for the control of crop pests, comprising a mixture of (a) Phytoseiulus persimilis predatory mites reared using a composition as defined above, (b) prey mites, comprising at least one species from the order Astigmata, and (c) optionally a carrier material.

In accordance with further aspects of the present invention, there is provided a biological control product for the control of crop pests, comprising a mixture of (a) individuals of the predatory mite Phytoseiulus persimilis bred using the composition according to any one of claims 26 to 31, and (b) individuals of mites prey species comprising at least one species from the family Phytoseiidae, and (c) optionally a carrier material.

The present invention further provides a slow release system (eg, sachets) for mites, especially for a mite species of the genus Phytoseiulus, in particular Phytoseiulus persimilis (P. persimilis), suitable for use on an agricultural crop.

The main aspect of the innovative solution is that predatory mites can reproduce within a system over several generations, with a certain proportion of predatory mites continuously leaving the system and moving onto the crop for pest control. This provides a continuous supply of mites to the crop without the need for the farmer to reapply them.

The slow release system embodiments of the present invention are based on the following features.

1. Individuals of predatory mites - P. persimilis or another species of mites from the genus Phytoseiulus.

2. The food source for predatory mites is artificial prey or host, such as frozen eggs of Carpoglyphus lactis (C. lactis) or other astigmatosis mites.

3. Predatory mites are combined with their artificial host in one actual location. This is accomplished through the following alternative approaches:

a. providing the predatory mites with their artificial host in a container, such as a sachet, pouch, chamber, pouch, sack or pouch, configured to be attached to a crop plant, from which the mites will be slowly and continuously released onto the crop over a period of approximately three weeks;

b. applying a mixture containing predatory mites, a carrier and an artificial host as a food source directly to the leaves of a crop. From this mixture, predatory mites will be slowly released onto the crop over a period of approximately three weeks.

It should be noted that such slow release systems for predatory mites have been highly favored in the case of P. persimilis up to the present time, with P. persimilis known to be a specialist predator (natural enemy) of spider mites and hence it has been bred on a diet representing are spider mites. However, spider mites are not suitable for use in this type of mite release system intended for crop protection for the following reasons:

spider mites themselves are pests and if used alive, they can damage crops;

- 13 046116 spider mites cannot reproduce without the provision of plant material, therefore they cannot reproduce in sachets;

without providing a food source, living spider mites quickly die and dry out (for example, within a few days);

when kept dead, spider mites quickly dry out and lose their nutritional value;

Spider mites are expensive to obtain.

The present invention provides an unexpected technological solution to the above problem, which has not been shown to be successful to date. The solution is based on the use of frozen eggs of C. lactis or another species of astigmatosis mites as an artificial host for P. persimilis. Unlike spider mites, frozen C. lactis eggs retain their nutritional value for approximately three weeks. This innovative solution allows for the sustained release of the predatory mite P. persimilis from a container or mixture combining the predatory mite with its artificial host, applied directly to the crop plant for pest control.

As used herein, the term approximately means ± 10% of a specified amount or rate or value.

The term controlled release as used herein refers to slow release, sustained release, rapid release, which are designed to be released in a sustained controlled manner or manner. In the context of the present invention, it refers to the gradual release of predatory mites onto a crop plant over a specified period of time, for example, over the course of a day or a week.

The term slow release system or container refers herein to a sachet-type release system, for example, a sachet, pouch, chamber, pouch, pouch or pouch, which contains a composition or formulation of the present invention consisting of predatory mites of the genus Phytoseiulus, an artificial host (dead astigmatic mites) and not necessarily a carrier. It is further included within the scope of the present invention that such a system or container refers to an apparatus, unit, device, compartment, compartment, panel or room for the slow release of beneficial insects or predatory mites available or known in the art.

It is also within the scope of the present invention that the Phytoseiulus mite release system may be of any suitable type. In general, the mite release system may comprise a container suitable for containing specimens of predatory mites of the genus Phytoseiulus (eg, P. persimilis) and specimens of artificial host mites (eg, dead eggs of C. lactis). The container contains an opening and/or means for providing an exit opening for mobile stages of predatory mites of the genus Phytoseiulus. Release systems of this type are known to one skilled in the art and various products are commercially available in the market, for example, sachet type release systems and other suitable types of release systems which are included within the scope of the present invention.

As used herein, the term propagation composition generally refers to a composition suitable for propagating, feeding, rearing, nurturing or reproducing a species of mites. More specifically, it relates to a composition suitable for commercial breeding of ticks. This paper recognizes that mass rearing systems for predatory mites are highly dependent on the availability of suitable prey for predators. Consequently, there continues to be a need for improved systems for rearing both predatory mites and ticks suitable as breeding prey. To solve this problem, the present invention provides a composition or system specifically adapted for the efficient and economical propagation of a species of mites from the genus Phytoseiulus, in particular Phytoseiulus persimilis, a very important predatory mite used for the biological control of crop pests (spider mites). It is demonstrated for the first time that Phytoseiulus persimilis completes its life cycle and reproduces, i.e., over at least 2 generations, by breeding on astigmatoid mites or prey mites of the family Phytoseiidae, such as Amblyseius swirskii.

The term carrier refers herein to an inactive or inert substance, or particles, or carrier medium. In a preferred embodiment, the propagation composition of the present invention contains a carrier for individuals of the tick species. The carrier may be any solid material that is suitable for providing a carrier surface for the mite specimens. Examples of suitable carriers are plant materials such as bran (eg wheat), sawdust (eg fine sawdust), cornmeal, vermiculite, etc.

As used herein, the term Phytoseiulus refers to a genus of mites in the family Phytoseiidae. This genus of predatory mites is most often used to control common spider mites in greenhouses and on crops grown outdoors.

- 14 046116 spirit. It is within the scope of the present invention that the genus Phytoseiulus contains the following species: Phytoseiulus fragariae, Phytoseiulus longipes, Phytoseiulus macropilis, Phytoseiulus persimilis and Phytoseiulus robertsi. Phytoseiulus mites are known as specialized predators of spider mites (mites from the family Tetranychidae), which are phytophagous mites.

As used hereinafter, the term Phytoseiulus persimilis or P. persimilis refers to the population of predatory mites including Phytoseiulus persimilis (P. persimilis). Phytoseiulus is a genus of mites in the family Phytoseiidae. This predatory mite is the predatory mite most commonly used to control common spider mites in greenhouses and on crops grown outdoors in temperate environmental conditions.

P. persimilis is commonly used for the control and control of spider mites. They are voracious predators of most pests, which are spider mites (Tetranychus spp). Some of the species they affect include the common tick Tetranychus urticae, the red tick T. cinnabarinus and the Pacific tick T. pacificus. Unlike Neoseiulus californicus (order: Mesostigmata, family: Phytoseiidae, subfamily: Amblyseiinae), which can go without food for relatively long periods, Phytoseiulus persimilis must feed on fresh food. Additionally, Phytoseiulus persimilis are not flexible in terms of their diet like other available predatory mite species for spider mite control, as they are only known to feed on a specific species of Tetranychus and not all species of the genus.

In the present invention, these problems are solved for the first time by a composition for mass propagation of P. persimilis, which contains a species of mites from the order Astigmata. The breeding system of the present invention is much more cost effective than breeding P. persimilis based on its traditional diet, which consists of phytophagous mites.

The term artificial host generally herein refers to a non-natural host or a host other than the target host for a predatory mite, one that can be more easily reared by biocontrol practitioners in the laboratory than the target host. In the context of the present invention, artificial host or prey refers to organisms that are unlikely to be attacked by a natural enemy or predatory mite in its natural habitat, but which are used artificially to support its development and/or reproduction. This is usually a species that is easier and cheaper to breed. Examples within the scope of the present invention include barn mites (such as astigmatoid mites) for predatory mites (such as the Phytoseiulus species), mite eggs for predatory insects, and mites. In further aspects, the term artificial host is used when the biological control agent is forced to feed on an insect or mite that it would not feed on in nature. This may allow for higher production levels. The present invention demonstrates for the first time that a species of commercially available mites of the genus Phytoseiulus can be mass reared using astigmata mites (Acari: Astigmata) as artificial prey.

The term juvenile tick or juvenile ticks hereinafter refers to the life stages of ticks, or tick developmental phases, or instars, including egg, larva, protonymph, and deutonymph (third instar).

The term individual or individuals or individuals of ticks in the context of the present invention refers to the developmental stages of the tick, including, but not limited to, egg, juvenile stages of ticks such as larva, protonymph and deutonymph (third instar).

The term mobile stages hereinafter refers to the developmental stages of ticks, including the larva, protonymph, deutonymph (third instar), and adult stage.

As used hereinafter, the term nonviable generally means the absence of the capacity to live, grow, develop, or function. In accordance with the main aspects of the present invention, it relates to dead or inanimate or lifeless or immobilized ticks (ie, any stages or phases of tick development) or tick eggs. In a specific embodiment of the present invention, non-viable mites and/or eggs of mites of the order Astigmata are used as prey for predatory mites of the genus Phytoseiulus.

In accordance with some embodiments of the present invention, non-viable mites or eggs are obtained by or subjected to processing, including, but not limited to, thermal treatment, such as freezing, lyophilization, heating, cold shock or heat shock treatment; chemical treatment such as gas or smoke treatment; radiation treatment such as UV, microwave, gamma or x-ray treatment; mechanical processing such as vigorous shaking or stirring, shearing, impact; processing by changing gas pressure, such as ultrasonic treatment, pressure changes, pressure drops; electrical treatment such as electric shock; immobilization with adhesive; immobility due to fasting, such as that induced by water or food deprivation; immobilize

- 15 046116 living by treatment causing asphyxiation or oxygen deprivation, such as temporary removal of oxygen from the atmosphere or replacement of oxygen with another gas, and any combination thereof.

In accordance with a specific embodiment, the composition of the present invention contains dead frozen eggs of C. lactis used as prey for predatory mites of the genus Phytoseiulus. As used herein, the term Astigmata or Astigmata refers to the order of mites within the subclass: Acari. Astigmatina is a cohort of mites. Astigmatina belongs to the Sarcoptiformes, which includes the biting Acariformes. The order Astigmata contains superfamilies with more than a thousand genera. Within the scope of the present invention, non-limiting examples of such superfamilies and families may include the following.

Suborder: Acaridia

Superfamilies:

Schizoglyphoidea: Examples of families include: Schizoglyphidae;

Histiostomatoidea: Example families include: Histiostomatidae, Guanolichidae;

Canestrinioidea: Example families include: Chetochelacaridae, Lophonotacaridae, Canestriniidae, Heterocoptidae;

Hemisarcoptoidea: Example families include: Chaetodactylidae, Hyadesiidae, Carpoglyphidae, Algophagidae, Hemisarcoptidae, Winterschmidtiidae;

Glycyphagoidea: Example families include: Euglycyphagidae, Chortoglyphidae, Pedetropodidae, Echimyopodidae, Aeroglyphidae, Rosensteiniidae, Glycyphagidae;

Acaroidea: Example families include: Sapracaridae, Suidasiidae, Lardoglyphidae, Glycacaridae, Gaudiellidae;

Acaridae: Example families include: Hypoderoidea, Hypoderidae Suborder: Psoroptidia;

Superfamilies:

Pterolichoidea: Example families include: Oconnoriidae, Ptiloxenidae;

Pterolichidae: Example families include: Cheylabididae, Ochrolichidae, Gabuciniidae, Falculiferidae, Eustathiidae, Crypturoptidae, Thoracosathesidae, Rectijanuidae, Ascouracaridae, Syringobiidae, Kiwilichidae, Kramerellidae;

Freyanoidea: Example families include: Freyanidae, Vexillariidae, Caudiferidae;

Analgoidea: Example families include: Heteropsoridae, Analgidae, Xolalgidae, Avenzoariidae, Pteronyssidae, Proctophyllodidae, Psoroptoididae, Trouessartiidae, Alloptidae, Thysanocercidae, Dermationidae, Epidermoptidae, Apionacaridae, Dermoglyphidae, Laminosioptidae, Knemidokoptidae, Cytoditidae;

Pyroglyphoidea: Example families include: Pyroglyphidae, Turbinoptidae;

Psoroptoidea: Example families include: Psoroptidae, Galagalgidae, Lobalgidae, Myocoptidae, Rhyncoptidae, Audycoptidae, Listrophoridae, Chirodiscidae, Atopomelidae, Chirorhynchobiidae, Gastronyssidae, Lemurnyssidae, Pneumocoptidae, Sarcoptidae.

A preferred astigmatoid mite species used in the biological control system of the present invention as an artificial host population for the predatory mite of the genus Phytoseiulus, for example P. persimilis, is a mite species from the family Carpoglyphidae, more preferably Carpoglyphus lactis (C. lactis).

Carpoglyphidae is a family of mites in the order Astigmatina, comprising four genera: Carpoglyphus, Coproglyphus, Dichotomiopus and Pullea.

Carpoglyphus lactis (Acarus lactis), preferably used in the present invention as a diet for breeding P. persimilis, belongs to the genus Carpoglyphus. This document recognizes that Carpoglyphus lactis is a mite that feeds on stored foods and infects saccharide-rich stored foods, including dried fruit, wine, beer, dairy products, marmalades and honey. Since C. lactis is capable of feeding on stored food, it is highly advantageous and cost effective to grow P. persimilis on this mite species, as demonstrated for the first time in the present invention.

In a further embodiment of the present invention, a predatory mite of the genus Phytoseiulus, such as P. persimilis, can complete its life cycle and reproduce by feeding on dead mites of the species Carpoglyphus lactis and/or Dermatophagoides farinae, both of which belong to the order Astigmata.

The term trait as used herein refers to a characteristic or phenotype. A phenotypic trait may refer to the appearance or other detectable characteristic of an individual resulting from the interaction of the genome, proteome and/or metabolome that determines it with the environment. For example, in the context of the present invention, increased reproduction rate, as described herein, is a phenotypic characteristic characterizing the composition based on predatory mites of the present invention. According to a further embodiment of the present invention, the symptom may also arise from interactions between the mite and its associated microorganisms. The trait can be inherited in a dominant or recessive manner, or in a partially dominant or incompletely dominant manner.

- 16 046116 at once. A trait may be monogenic (that is, determined by a single locus), or polygenic (that is, determined by more than one locus), or may also arise from the interaction of one or more genes with the environment. A dominant trait leads to full phenotypic expression in a heterozygous or homozygous state; a recessive trait usually manifests itself only if it is in a homozygous state.

Within the scope of the present invention, the term genetic linkage is understood as the association of hereditary characteristics due to the proximity of genes on the same chromosome, measured by the percentage of recombination between loci (centimorganide, cM).

As used herein, the term population refers to a genetically heterogeneous collection of mites that share a common genetic ancestry.

As used herein, the phrase genetic marker or molecular marker or biomarker refers to a component in the genome of an individual, for example, a nucleotide or polynucleotide sequence, that is associated with one or more loci or traits of interest. In some embodiments, depending on the context, the genetic marker is polymorphic in the population of interest or the locus is in a polymorphic state. Genetic markers or molecular markers include, for example, single nucleotide polymorphisms (SNPs), insertions/deletions (i.e., insertions or deletions), simple sequence repeats (SSRs), restriction fragment length polymorphisms (RFLPs), randomly amplified polymorphic DNAs (RAFDs) , restriction amplified sequence polymorphism (CAPS) markers, diversity chip technology (DArT) markers, and amplified fragment length polymorphisms (AFLP) or combinations thereof, among many other examples, such as DNA sequence per se. For example, genetic markers can be used to determine the chromosomal location of genetic loci containing alleles that contribute to variation in phenotypic traits. The phrase genetic marker or molecular marker or biomarker can also refer to a polynucleotide sequence complementary to or corresponding to a genomic sequence, such as a nucleic acid sequence used as a probe or primer.

Physically, a genetic marker may be located on a chromosome at a position that is within or outside the genetic locus with which it is associated (ie, intragenic or extragenic, respectively).

As used herein, the term germplasm refers to the totality of genotypes of a population or other group of individuals (eg, a species).

As used herein, the terms hybrid and hybrid offspring refer to an individual that is descended from genetically different parents (eg, a genetically heterozygous or predominantly heterozygous individual).

As used herein, the term allele(s) means any of one or more alternative or variant forms of a gene or genetic unit at a particular locus, all of the alleles at a particular locus being associated with a single trait or characteristic. In a diploid cell of an organism, the alleles of a given gene are located at a specific location or locus (plural loci) on the chromosome. One allele is present on each chromosome of a pair of homologous chromosomes. A diploid plant species may contain a large number of different alleles at a particular locus. Such alternative or variant forms of alleles may result from single nucleotide polymorphisms, insertions, insertions/deletions, inversions, translocations or deletions, or from gene regulation due to, for example, chemical or structural modification, transcriptional regulation or post-translational modification/regulation.

An allele associated with a qualitative trait may include alternative or variant forms of various genetic units, including those that are identical to or associated with one gene, or several genes or their products, or even a gene that is disrupted or controlled by a genetic factor, causing the development of the phenotype represented by locus. As used herein, the term locus (plural loci) means a specific location or locations or region or site on a chromosome at which, for example, a gene or genetic marker element or factor is located. In certain embodiments, such a genetic element enables the development of the trait.

As used herein, the term reproduction and its grammatical variants refer to any method that produces offspring. Reproduction can be sexual or asexual, or any combination of the two. Exemplary non-limiting types of propagation include crossing, introgression, self-fertilization, backcrossing, haploid duplication, and combinations thereof.

As used herein, the term genetic determinant refers to genetic determinants such as genes, alleles, QTLs or traits.

Introgression of a genetic determinant means the introduction of genes, alleles, QTLs or traits into a line, in addition to the genetically introgressed determinant, virtually all of

- 17 046116 the required morphological and physiological characteristics of the line have been restored. This method is often used in variety development in which one or more genetic determinants are transferred into the desired genetic background, preferably through the use of backcrossing.

The term genotype refers to the genetic structure of a cell or organism. An individual's genotype includes specific alleles for one or more genetic marker loci present in the individual's haplotype. As is known in the art, a genotype can be associated with a single locus or with multiple loci, regardless of whether the loci are linked or unlinked and/or linked or unlinked. In some embodiments, an individual's genotype refers to one or more genes that are linked such that the one or more genes are involved in expression causing the phenotype of interest. Thus, in some embodiments, a genotype includes the totality of one or more alleles present in an individual at one or more genetic loci. In some embodiments, the genotype is expressed based on the haplotype.

In accordance with a further embodiment of the present invention, a predatory mite of the genus Phytoseiulus, such as P. persimilis, can complete its life cycle and reproduce (i.e., including development and oviposition) for at least 3 generations by feeding on live juvenile mites of the species Amblyseius swirskii, which belongs to the family Phytoseiidae.

It is further within the scope of the present invention to disclose a population of predatory mites of the genus Phytoseiulus, for example the mite species P. persimilis, reared by feeding on dead or immobilized mites belonging to a species selected from the group consisting of Carpoglyphus lactis, Dermatophagoides farinae, Lepidogyphus destructor, Glyciphagus domesticus, Dermatophagoides pteronisinus, Amblyseius swirskii and any combination thereof.

According to a further embodiment, the predatory mite feeds on the above prey mites, developing and reproducing over at least two generations.

In accordance with a further embodiment of the present invention, P. persimilis or other predatory mite of the genus Phytoseiulus can develop by feeding on dead individuals of the following species belonging to the order Astigmata: Carpoglyphus lactis, Lepidoglyphus destructor, Glycifagus domesticus and Dermatophagoides pteronisinus.

It is further within the scope that the mites used as prey are immobilized by an immobilizing treatment selected from the group consisting of thermal treatment such as freezing, heating, cold shock treatment or heat shock treatment; chemical treatment such as gas or smoke treatment; radiation treatments such as gamma, UV, microwave or x-ray treatments; mechanical processing such as vigorous shaking or stirring, shearing, impact; processing by changing gas pressure, such as ultrasonic treatment, pressure changes, pressure drops; electrical treatment such as electric shock; immobilization with adhesive; immobilization due to fasting, such as induced by water or food deprivation; immobilization through treatment that causes asphyxiation or oxygen deprivation, such as temporarily removing oxygen from the atmosphere or replacing oxygen with another gas.

One skilled in the art will appreciate how such treatments can result in the immobilization of astigmatoid mites or other mites of the family Phytoseiidae and that the immobilization treatment must be such that the mites remain suitable prey (food source) for the predatory mites.

Also within the scope of the present invention is the term immobilized ticks, which can also mean dead or lifeless ticks.

Let us now turn to FIG. 1, which photographs show different stages of development of P. persimilis reared on dead or immobilized C. lactis. The figure shows an adult female (Fig. 1A) and a juvenile that has just hatched from an egg (Fig. 1B). As can be seen in this figure, all stages are characterized by the pale whitish coloration typical of this diet, in contrast to the normal orange coloration observed when P. persimilis feeds on spider mites, their traditional diet. In other words, the predators of the present invention that feed on C. lactis acquire a beige-white coloration instead of the typical orange coloration. In addition, the dorsal scute of the predator is darker than the cuticle around it. This figure demonstrates that P. persimilis can develop and reproduce when feeding on dead or immobilized C. lactis ticks. As explained above, the production of C. lactis (Acari: Astigmata) is significantly more cost-effective than the traditional diet of P. persimilis, which is a phytophagous spider mite.

Let us now turn to FIG. 2, which photographically shows P. persimilis reared on dead or immobilized C. lactis. As you can see, the predator is characterized by a unique appearance, while it turns beige-white instead of the typical orange coloration (when feeding

- 18 046116 nii traditional diet, which is spider mites), and the dorsal scute of the predator is darker than the cuticle around it.

This document recognizes that common spider mites feed on many plant species and are a major pest of vegetables, ornamental plants, fruit trees, hop varieties, cotton and strawberry varieties (van de Vrie et al., 1972). At this time, it can be assumed that most problems in greenhouses where spider mites are the main cause will be associated with the common spider mite. The larva, protonymph, deutonymph and adult feed primarily on the underside of leaves.

It is within the scope of the present invention to provide a composition for the control of mite pests, in particular members of the class Acari, the family Tetranychidae, such as the common spider mite, more particularly species of spider mites, in particular the genera Tetranychus, Panonychus and various other mite species.

In accordance with some embodiments of the present invention, the crop is selected from the group consisting of greenhouse crops and outdoor crops. Non-limiting examples of crop types within the scope of the present invention include vegetables, ornamental plants, fruit trees, hop varieties, cotton and strawberry varieties.

Specific examples of plant species that serve as hosts for mite pests within the scope of the present invention include the following.

Acanthaceae: Acanthus mollis; Justicia adhatoda.

Actinidiaceae: Actinidia chinensis; Actinidia deliciosa; Actinidia sp.

Adoxaceae: Sambucus canadensis; Sambucus chinensis; Sambucus edulus; Sambucus nigra;

Sambucus sieboldiana; Sambucus sp.; Viburnum lantana; Viburnum opulus; Viburnum rhytidophyllum; Viburnum sp.; Viburnum tinus.

Aizoaceae: Mesembryanthemum crystallinum.

Alstroemeriaceae: Alstroemeria sp.

Amaranthaceae: Alternanthera sp.; Amaranthus blitum; Amaranthus caudatus; Amaranthus graecizans; Amaranthus hybridus; Amaranthus mangostanus; Amaranthus palmeri;

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Amaranthus retroflexus; Amaranthus sp.; Amaranthus spinosus; Amaranthus viridis; Atriplex canescens; Atriplex lentiformis; Atriplex semibaccata; Beta vulgaris; Celosia argentea; Chenopodium album; Chenopodium murale; Chenopodium sp.; Dysphania ambrosioides; Haloxylon ammodendron; Iresine herbstii; Salsola vermiculata; Spinacia oleracea.

Amaryllidaceae: Allium ampeloprasum; Allium sulfur; Allium fistulosum; Allium sativum; Allium sp.; Narcissus sp.

Anacardiaceae: Mangifera indica; Pistacia terebinthus; Pistacia vera.

Annonaceae: Annona muricata; Annona reticulata; Annona squamosa.

Apiaceae: Aegopodium podagraria; Ammi majus; Apium graveolens; Apium nodiflorum; Arracacia xanthorrhiza; Athamanta macedonica; Bupleurum lancifolium; Coriandrum sativum; Cryptotaenia canadensis; Daucus carota; Eryngium sp.; Foeniculum vulgare; Pastinaca sativa; Petroselinum crispum; Peucedanum japonicum; Phelolophium madagascariense; Spananthe sp.

Apocynaceae: Ampelamus laevis; Apocynum cannabinum; Asclepias sp.; Catharanthus roseus; Mandevilla sp.; Matelea carolinensis; Nerium oleander; Plumeria sp.; Raphionacme sp.; Rauvolfia serpentina; Vinca major; Vinca sp.

Aquifoliaceae: Ilex crenata.

Araceae: Alocasia macrorrhizos; Alocasia sp.; Anthurium sp.; Arum italicum; Arum sp.; Caladium bicolor; Caladium sp.; Calla sp.; Colocasia esculenta; Colocasia sp.; Dieffenbachia sp.; Epipremnum pinnatum; Philodendron sp.; Symplocarpus foetidus; Xanthosoma sp.; Zantedeschia aethiopica.

Araliaceae: Aralia sp.; Hedera canariensis; Hedera helix; Hedera sp.; Hydrocotyle umbellata; Polyscias balfouriana; Schefflera actinophylla; Schefflera elegantissima; Schefflera sp.; Tetrapanax papyrifer.

Araucariaceae: Agathis sp.; Araucaria sp.

Arecaceae: Dypsis sp.; Phoenix dactylifera; Phoenix sp.; Veitchia sp.

Aristolochiaceae: Aristolochia clematitis.

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Asparagaceae: Asparagus laricimis; Asparagus officinalis; Asparagus setaceus; Asparagus sp.; Aspidistra elatior; Cordyline fruticosa; Cordyline sp.; Dracaena braunii; Dracaena fragrans; Dracaena goldieana; Dracaena sp.; Hyacinthus orientalis; Lachenalia ensifolia; Maianthemum racemosum; Ornithogalum sp.; Polygonatum odoratum; Ruscus aculeatus; Yucca sp.

Balsaminaceae: Impatiens balsamina; Impatiens sp.; Impatiens walleriana.

Berberidaceae: Berberis cretica; Berberis thunbergii; Berberis vulgaris; Berberis wilsoniae; Nandina domestica.

Betulaceae: Alnus incana; Betula maximowicziana; Betula papyrifera; Betula pendula; Carpinus sp.; Corylus avellana.

Bignoniaceae: Campsis radicans; Pyrostegia venusta; Tecoma capensis; Tecoma stans.

Boraginaceae: Borago officinalis; Cynoglossum columnae; Heliotropium arborescens; Heliotropium eichwaldii; Heliotropium europaeum; Nama hispidum; Omphalodes verna.

Brassicaceae: Aethionema saxatile; Brassica juncea; Brassica napus; Brassica oleracea; Brassica rapa; Brassica sp.; Capsella bursa-pastoris; Diplotaxis erucoides; Diplotaxis viminea; Eruca vesicaria; Erysimum graecum; Erysimum sp.; Erysimum x cheiri; Hirschfeldia incana; Lepidium didymum; Malcolmia sp.; Matthiola fruticulosa; Matthiola incana; Matthiola odoratissima; Nasturtium sp.; Raphanus raphanistrum; Raphanus sp.; Rapistrum rugosum; Rorippa indica; Sinapis arvensis; Zilla spinosa.

Bromeliaceae: Tillandsia sp.

Buxaceae: Buxus sempervirens.

Calophyllaceae: Mammea americana.

Campanulaceae: Campanula erinus; Lobelia sp.; Platycodon grandiflorus.

Cannabaceae: Cannabis sativa; Celtis australis; Celtis occidentalis; Humulus lupulus; Humulus scandens; Trema micrantha.

Cannaceae: Canna indica.

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Capparaceae: Capparis nummularia.

Caprifoliaceae: Cephalaria gigantea; Diervilla sp.; Leycesteria formosa; Lonicera etrusca; Lonicera nigra; Lonicera periclymenum; Lonicera sp.; Lonicera tatarica; Lonicera xylosteum; Pterocephalus plumosus; Scabiosa sicula; Symphoria racemosa; Symphoricarpos albus; Symphoricarpos orbiculatus; Weigela hortensis.

Caricaceae: Carica papaya.

Caryophyllaceae: Dianthus armeria; Dianthus barbatus; Dianthus caryophyllus; Dianthus chinensis; Dianthus sp.; Dianthus tenuiflorus; Drymaria cordata; Gypsophila paniculata; Myosoton aquaticum; Silene chalcedonica; Silene vulgaris; Stellaria media.

Celastraceae: Celastrus orbiculatus; Celastrus scandens; Euonymus europaeus; Euonymus japonicus; Euonymus sp.

Cistaceae: Helianthemum salicifolium.

Cleomaceae: Cleome sp.; Cleome viscosa.

Clethraceae: Clethra arborea.

Combretaceae: Terminalia catappa.

Commelinaceae: Commelina benghalensis; Commelina communis; Commelina diffusa.

Compositae: Acanthospermum hispidum; Achillea filipendulina; Achillea fraasii; Ageratum conyzoides; Ageratum houstonianum; Ambrosia trifida; Anthemis chia; Arctium lappa; Arctium minus; Arctotheca calendula; Arctotis sp.; Artemisia dracunculus; Bellis annua; Bidens bipinnata; Bidens biternata; Bidenspilosa; Bidens sp.; Boltonia sp.; Brachyscome sp.; Calendula arvensis; Calendula officinalis; Calendula sp.; Callistephus chinensis; Carduus crispus; Carthamus tinctorius; Centaurea cyanus; Centaurea hyalolepis; Centaurea iberica; Centaurea imperialis; Centaurea montana; Chaenactis stevioides; Chrysanthemum coronarium; Chrysanthemum indicum; Chrysanthemum morifolium; Chrysanthemum segetum; Chrysanthemum sp.; Chrysothamnus viscidflorus; Cichorium endivia; Cichorium intybus; Cichorium pumilum; Cichorium spinosum; Conyza bonariensis; Conyza canadensis; Conyza sp.; Cosmos bipinnatus; Cosmos sp.; Crassocephalum crepidioides; Crepis neglecta; Crepis rubra; Cynara cardunculus; Cynara sp.; Dahlia coccinea; Dahlia sp.; Dahlia

- 22 046116 variabilis; Elephantopus mollis; Erigeron annuus; Erigeron sp.; Euryops sp.; Euthamia graminifolia; Galinsoga caracasana; Galinsoga ciliata; Galinsoga parviflora; Gerbera jamesonii; Gerbera sp.; Helianthella quinquenervis; Helianthus annuus; Helichrysum luteoalbum; Helichrysum tenax; Helichrysum thianschanicum; Heliopsis sp.; Helminthotheca echioides; Lactuca saligna; Lactuca sativa; Lactuca serriola; Lapsana communis; Leontodon autumnalis; Leucanthemum vulgare; Melampodium perfoliatum; Melanthera aspera; Mikania micrantha; Montanoa bipinnatifida; Notobasis syriaca; Osteospermum sp.; Parthenium sp.; Pentzia globosa; Pieris pauciflora; Pieris sprengeriana; Pseudognaphalium obtusifolium; Rudbeckia amplexicaulis; Rudbeckia sp.; Schkuhria pinnata; Scolymus maculatus; Scorzonera sp.; Senecio lividus; Senecio sp.; Senecio vulgaris; Solidago gigantea; Sonchus arvensis; Sonchus asper; Sonchus oleraceus; Sonchus sp.; Tagetes erecta; Tagetes microglossa; Tagetes minuta; Tagetespatula; Tagetes sp.; Taraxacum officinale; Tithonia rotundifolia; Tragopogon dubius; Tragopogon pratensis; Tridax procumbens; Urospermum dalechampii; Vernonia sp. ; Xanthium strumarium; Zinnia elegans; Zinnia sp.

Convolvulaceae: Calystegia hederacea; Calystegia sepium; Convolvulaceae sp.; Convolvulus arvensis; Convolvulus hirsutus; Convolvulus scammonia; Convolvulus siculus; Convolvulus sp.; Convolvulus tricolor; Dinetus racemosus; Ipomoea aquatica; Ipomoea arachnosperma; Ipomoea batatas; Ipomoea biflora; Ipomoea cairica; Ipomoea hochstetteri; Ipomoea indica; Ipomoea lacunosa; Ipomoea lobata; Ipomoea nil; Ipomoea purpurea; Ipomoea sp.; Ipomoea tricolor; Ipomoea triloba.

Cornaceae: Cornus alba; Cornus canadensis; Cornus nuttalii; Cornus sp.

Cucurbitaceae: Benincasa hispida; Bryonia alba; Citrullus colocynthis; Citrullus lanatus; Cucumis melo; Cucumis sativus; Cucumis sp.; Cucurbita ficifolia; Cucurbita maxima; Cucurbita moschata; Cucurbita pepo; Cucurbita sp.; Cucurbitaceae sp.; Diplocyclos palmatus; Ecballium elaterium; Lagenaria siceraria; Luffa acutangula; Luffa cylindrica; Momordica charantia; Praecitrullus fistulosus; Sechium edule.

Cupressaceae: Chamaecyparis thyoides; Cupressus sp.; Juniperus arizonica; Juniperus virginiana; Platycladus orientalis.

Cyperaceae: Cyperus esculentus; Cyperus rotundus; Cyperus schimperianus. Dipterocarpaceae: Shorea robusta.

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Ebenaceae: Diospyros kaki; Diospyros scabrida.

Elaeagnaceae: Elaeagnus angustifolia; Elaeagnus umbellata.

Equisetaceae: Equisetum palustre.

Ericaceae: Azalea nudiflora; Azalea sp.; Rhododendron sp.; Siphonandra sp.

Euphorbiaceae: Acalypha australis; Acalypha havanensis; Acalypha sp.; Acalypha wilkesiana; Codiaeum sp.; Codiaeum variegatum; Croton niveus; Croton sp.; Euphorbia amygdaloides; Euphorbia burmanni; Euphorbia helenae; Euphorbia helioscopia; Euphorbia hirta; Euphorbia hypericifolia; Euphorbia parviflora; Euphorbia pulcherrima; Euphorbia sp.; Hevea brasiliensis; Hura crepitans; Jatropha gossypiifolia; Jatropha hastata; Jatropha multifida; Jatropha sp.; Manihot esculenta; Manihot sp.; Mercurialis annua; Mercurialis sp. ; Ricinus communis.

Fagaceae: Quercus alba; Quercus robur; Quercus sp.

Garryaceae: Aucuba japonica.

Gentianaceae: Eustoma grandiflorum; Gentiana sp.

Geraniaceae: Er odium alnifolium; Geranium carolinianum; Geranium dissectum; Geranium lucidum; Geranium molle; Geranium rotundifolium; Geranium sp.; Pelargonium inquinans; Pelargonium sp.

Gesneriaceae: Saintpaulia ionantha.

Goodeniaceae: Goodenia sp.; Scaevola sp.

Grossulariaceae: Ribes americanum; Ribes nigrum; Ribes rubrum.

Heliconiaceae: Heliconia bihai; Heliconia latispatha.

Hydrangeaceae: Deutzia sp.; Hydrangea macrophylla; Hydrangea paniculata; Hydrangea sp.; Philadelphus coronarius; Philadelphus sericanthus.

Iridaceae: Crocosmia x crocosmiiflora; Gladiolus hortulanus; Gladiolus italicus; Gladiolus sp.; Iris sanguinea; Iris x germanica; Ixia flexuosa.

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Juglandaceae: Carya illinoinensis; Juglans regia; Juglans sp.

Lamiaceae: Ajuga sp.; Ballota africana; Clerodendrum chinense; Clerodendrum thomsoniae; Galeopsis speciosa; Galeopsis tetrahit; Glechoma hederacea; Glechoma sp.; Holmskioldia sanguinea; Holmskioldia sp.; Lamium album; Lamium amplexicaule; Lamium purpureum; Lamium sp.; Lavandula sp.; Leonotis ocymifolia; Leucas martinicensis; Marrubium vulgare; Melissa officinalis; Mentha arvensis; Mentha sp.; Mentha spicata; Mentha x piperita; Moluccella laevis; Monarda fistulosa; Nepeta cataria; Ocimum basilicum; Ocimum tenurflorum; Perilla frutescens; Rosmarinus officinalis; Salvia argentea; Salvia officinalis; Salvia pratensis; Salvia sp.; Salvia splendens; Salvia verticillata; Salvia viridis; Stachys arvensis; Vitex negundo.

Lauraceae: Cassytha sp.; Endlicheria paniculata; Laurus nobilis; Per sea americana.

Leguminosae: Acacia greggii; Acacia horrida; Acacia huarango; Acacia karroo; Acacia robusta; Acacia sp.; Alysicarpus longifolius; Amphicarpaea bracteata; Anthyllis vulneraria; Arachis hypogaea; Arachis sp.; Astragalus sinicus; Bauhinia forficata; Bauhinia monandra; Bauhinia sp.; Bauhinia variegata; Bituminaria bituminosa; Canavalia ensiformis; Caragana arborescens; Cassia artemisioides; Ceratonia siliqua; Cercis siliquastrum; Cicer arietinum; Clianthus sp.; Clitoria ternatea; Coronilla valentina; Crotalaria juncea; Crotalaria micans; Crotalaria sp.; Dalbergia sissoo; Dalea mollis; Desmodium khasianum; Dolichos sp.; Erythrina corallodendron; Erythrinapoeppigiana; Erythrina sp.; Genista sp.; Gleditsia sp.; Glycine max; Indigofera arrecta; Indigofera holubii; Indigofera tinctoria; Inga sp.; Kennedia coccinea; Lablab purpureus; Laburnum anagyroides; Laburnum sp.; Lathyrus cicera; Lathyrus odoratus; Lathyrus sativus; Lens culinaris; Lespedeza maximowiczii; Lotus corniculatus; Lupinus arboreus; Lupinus argenteus; Lupinus sativus; Macroptilium atropurpureum; Macroptilium lathyroides; Medicago arabica; Medicago arborea; Medicago lupulina; Medicago orbicularis; Medicago polymorpha; Medicago sativa; Medicago sp.; Melilotus albus; Melilotus indicus; Melilotus sp.; Mucuna membranacea; Mucuna pruriens; Neonotonia wightii; Neorautanenia mitis; Onobrychis viciifolia; Ornithopus sp.; Phaseolus acutifolius; Phaseolus coccineus; Phaseolus lunatus; Phaseolus sp.; Phaseolus vulgaris; Pisum sativum; Psophocarpus tetragonolobus; Pueraria montana; Pueraria phaseoloides; Rhynchosia capitata; Rhynchosia caribaea; Robinia hispida; Robinia pseudoacacia; Sesbania cannabina; Sesbania herbacea; Spartium junceum; Styphnolobium japonicum; Teramnus uncinatus; Tipuana tipu; Trifolium alexandrinum; Trifolium aureum; Trifolium dasyurum;

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Trifolium dubium; Trifolium glomeratum; Trifolium hybridum; Trifolium incarnatum; Trifolium pratense; Trifolium purpureum; Trifolium repens; Trifolium sp.; Trifolium spumosum; Vicia angustifolia; Vicia faba; Vicia pulchella; Vicia sativa; Vicia sp.; Vicia villosa; Vigna aconitifolia; Vigna angularis; Vigna mungo; Vigna radiata; Vigna sp.; Vigna unguiculata; Wisteria floribunda; Wisteria polystachya; Wisteria sinensis.

Liliaceae: Lilium sp.

Linaceae: Reinwardtia tetragyna.

Lythraceae: Cuphea sp.; Lagerstroemia speciosa; Punica granatum.

Magnoliaceae: Magnolia lili flora; Magnolia sp.; Magnolia stellata.

Malvaceae: Abelmoschus esculentus; Abutilon pictum; Abutilon reflexum; Abutilon sp.; Abutilon theophrasti; Abutilon tubulosum; Alcea rosea; Althaea nudiflora; Byttneria australis; Ceiba pentandra; Corchorus capsularis; Corchorus olitorius; Gossypium barbadense; Gossypium herbaceum; Gossypium hirsutum; Gossypium sp.; Grewia asiatica; Grewia biloba; Helicteres guazumifolia; Hibiscus lunar ifolius; Hibiscus mutabilis; Hibiscus rosa-sinensis; Hibiscus sp.; Hibiscus syriacus; Hibiscus trionum; Malva aegyptia; Malva moschata; Malva neglecta; Malva nicaeensis; Malva parvflora; Malva sp.; Malva sylvestris; Malva trimestris; Malvella leprosa; Sida rhombifolia; Sida sp.; Sterculia murex; Tilia americana; Tilia cordata; Tilia platyphyllos; Tilia rubra; Tilia sp.; Tilia tomentosa; Tilia x euchlora; Triumfetta semitriloba; Waltheria indica.

Marantaceae: Calathea sp.; Mar anta sp.

Meliaceae: Azadirachta indica; Melia azedarach; Toona ciliata.

Menispermaceae: Tinosporafragosa.

Moraceae: Artocarpus altilis; Ficus carica; Ficus elastica; Ficus religiosa; Ficus sp.; Morus alba; Morus nigra; Morus rubra; Morus sp.

Moringaceae: Moringa oleifera.

Musaceae: Musa acuminata; Musa basjoo; Musa sp.; Musa xparadisiaca.

Myrtaceae: Eucalyptus grandis; Psidium cattleianum; Psidium guajava; Syzygium cumini.

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Nothofagaceae: Nothofagus alpina.

Nyctaginaceae: Bougainvillea spectabilis.

Olacaceae: Ximenia americana.

Oleaceae: Forsythia koreana; Forsythia suspensa; Forsythia x intermedia; Fraxinus angustifolia; Fraxinus excelsior; Fraxinus ornus; Fraxinus sp.; Jasminum humile; Jasminum nudiflorum; Jasminum officinale; Jasminum sambac; Jasminum sp.; Ligustrum lucidum; Ligustrum vulgare; Olea europaea; Osmanthus fragrans; Syringa oblata; Syringa vulgaris.

Onagraceae: Chylismia claviformis; Epilobium angustifolium; Fuchsia magellanica; Fuchsia sp.; Fuchsia x hybrida; Gaura sp.; Oenothera biennis; Oenothera laciniata; Oenothera sp. ; Oenothera tetraptera.

Orchidaceae: Catasetum sp.; Cymbidium sp.; Orchidaceae sp.; Papilionanthe teres.

Oxalidaceae: Oxalis corniculata; Oxalis debilis; Oxalis europaea; Oxalis floribunda; Oxalis sp.

Papaveraceae: Argemone mexicana; Bocconia frutescens; Chelidonium majus; Chelidonium sp.; Dicentra sp.; Eschscholzia sp.; Fumaria officinalis; Papaver aculeatum; Papaver nudicaule; Papaver orientale; Papaver rhoeas; Papaver somniferum.

Passifloraceae: Passiflora caerulea; Passiflora edulis; Passiflora foetida; Passiflora mollissima; Passiflora sp.

Paulowniaceae: Paulow niafortunei.

Pedaliaceae: Sesamum indicum.

Phyllanthaceae: Phyllanthus amarus; Phyllanthus sp.

Phytolaccaceae: Petiveria alliacea; Phytolacca americana; Phytolacca dioica; Phytolacca esculenta; Phytolacca icosandra.

Pinaceae: Pinus sylvestris; Tsuga canadensis.

Pittosporaceae: Pittosporum tobira.

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Plantaginaceae: Angelonia sp.; Antirrhinum majus; Digitalis purpurea; Hippuris vulgaris; Linaria genistifolia; Mecardonia procumbens; Plantago asiatica; Plantago lanceolata; Plantago major; Plantago sp.; Veronica persica; Veronica sp.; Veronica teucrium.

Platanaceae: Platanus orientalis; Platanus sp.

Plumbaginaceae: Limoniastru guyonianum; Limonium sinuatum; Plumbago auriculata; Plumbago sp.

Poaceae: Aegilops sp.; Agropyron desertorum; Aira sp.; Avenafatua; Avena sativa; Avena sp. ; Avena sterilis; Bambusa sp.; Bromus catharticus; Bromus sp.; Chondrosum barbatum; Cynodon dactylon; Dactyloctenium aegyptium; Digitaria argillacea; Digitaria ciliaris; Digitaria diversinervis; Digitaria sanguinalis; Eleusine coracana; Elymus hispidus; Elymus repens; Eragrostis sp.; Festuca arundinacea; Festuca sp.; Helictotrichon pratense; Hordeum sp.; Lolium multiflorum; Lolium sp.; Ophiuros exaltatus; Oryza glaberrima; Oryza sativa; Panicum miliaceum; Panicum sp.; Paspalum dilatatum; Pennisetum clandestinum; Pennisetum purpureum; Phleum pratense; Poa annua; Poa pratensis; Poa trivialis; Poaceae sp.; Rottboellia cochinchinensis; Saccharum officinarum; Setaria pumila; Setaria viridis; Sitanion hystrix; Sorghum bicolor; Sorghum halepense; Sorghum sp.; Stenotaphrum secundatum; Triticum sp.; Zea mays; Zeugites sp.

Polemoniaceae: Phlox Carolina; Phlox paniculata; Phlox sp.

Polygonaceae: Emex australis; Fallopia baldschuanica; Fallopia convolvulus; Persicaria hydropiper; Persicaria longiseta; Persicaria maculosa; Persicaria pensylvanica; Polygonum argyrocoleon; Polygonum aviculare; Rumex acetosa; Rumex acetosella; Rumex crispus; Rumex japonicus; Rumex obtusifolius; Rumex sp.

Pontederiaceae: Eichhornia crassipes.

Portulacaceae: Portulaca oleracea.

Primulaceae: Cyclamen graecum; Cyclamen hederifolium; Cyclamenpersicum; Cyclamen sp.; Primula denticulata; Primula polyantha; Primula sp.; Primula veris.

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Ranunculaceae: Adonis aestivalis; Anemone coronaria; Anemone hortensis; Aquilegia sp.; Clematis paniculata; Clematis sp.; Delphinium sp.; Helleborus sp.; Ranunculus asiaticus; Thalictrum fendleri.

Resedaceae: Reseda odorata.

Rhamnaceae: Frangula dodonei; Helinus integrifolius; Rhamnus alpina; Rhamnus imeretina; Ziziphus jujuba; Ziziphus spina-christi.

Rosaceae: Alchemilla vulgaris; Armeniaca mume; Cerasus lusitanica; Cerasus serrula; Cerasus vulgaris; Chaenomeles japonica; Chaenomeles sinensis; Cotoneaster horizontalis; Cotoneaster microphyllus; Cotoneaster tomentosa; Crataegus laevigata; Crataegus monogyna; Crataegus sanguinea; Cydonia oblonga; Eriobotrya japonica; Filipendula ulmaria; Fragaria moschata; Fragaria vesca; Fragaria virginiana; Fragaria x ananassa; Geum rivale; Malus domestica; Malus floribunda; Malus pumila; Malus sp.; Marcetella maderensis; Padus avium; Potentilla fragarioides; Potentilla fruticosa; Potentilla norvegica; Potentilla tanacetifolia; Prunus amygdalus; Prunus armeniaca; Prunus avium; Prunus cerasifera; Prunus cerasoides; Prunus cerasus; Prunus domestica; Prunus insititia; Prunus lusitanica; Prunus persica; Prunus salicina; Prunus serotina; Prunus sp.; Prunus spinosa; Pyracantha coccinea; Pyracantha koidzumii; Pyracantha sp.; Pyrus communis; Pyrus pyrifolia; Pyrus sp.; Rosa canina; Rosa cymosa; Rosa hybrida; Rosa multiflora; Rosa odorata; Rosa rugosa; Rosa sp.; Rosa x alba; Rosa x centifolia; Rosa x damascena; Rosa x rugosa; Rubus buergeri; Rubus chaerophyllus; Rubus chingii; Rubus fruticosus; Rubus idaeus; Rubus lloydianus; Rubus occidentalis; Rubus sp.; Rubus ulmifolius; Sorbus aucuparia; Sorbus sp.; Spiraea japonica.

Rubiaceae: Coffea arabica; Coffea sp.; Galium aparine; Galium stellatum; Gardenia jasminoides; Gardenia sp.

Rutaceae: Choisya ternata; Citrus aurantiifolia; Citrus aurantium; Citrus Clementina; Citrus limon; Citrus maxima; Citrus medica; Citrus paradisi; Citrus reticulata; Citrus sinensis; Citrus sp.; Citrus trifoliata; Ruta graveolens; Zanthoxylum rhoifolium.

Salicaceae: Dovyalis caffra; Populus alba; Populus nigra; Populus sp.; Populus tremula; Populus x canadensis; Salix aegyptiaca; Salix alba; Salix babylonica; Salix caprea; Salix chaenomeloides; Salix dephnoides; Salix fragilis; Salix sp.; Salix viminalis.

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Sapindaceae: Acer campestre; Acer negundo; Acer platanoides; Acer pseudoplatamis; Acer rubrum; Acer saccharum; Acer sp.; Aesculus glabra; Dodonaea viscosa; Koelreuteria paniculata; Litchi sinensis; Sapindus sp.

Saxifragaceae: Rodgersiapodophylla.

Scrophulariaceae: Buddleja davidii; Buddleja madagascariensis; Diascia sp.; Myoporum sp.; Nemesia sp.; Verbascum blattaria.

Simaroubaceae: Ailanthus altissima.

Solanaceae: Acnistus arborescens; Brugmansia arborea; Brugmansia suaveolens; Brugmansia x candida; Calibrachoa sp.; Capsicum annuum; Capsicum sp.; Cestrum cyaneum; Cestrum elegans; Cestrum strigillatum; Cyphomandra sp.; Datura snowstorm; Datura sp.; Datura stramonium; Lycium chinense; Nicandra physalodes; Nicotiana glauca; Nicotiana sp.; Nicotiana tabacum; Petunia sp.; Petunia x hybrid; Physalis acutifolia; Physalis alkekengi; Physalis angulata; Physalis lagascae; Physalis peruviana; Salpichroa origanifolia; Solanum aethiopicum; Solanum americanum; Solanum capsicoides; Solanum carolinense; Solanum delagoense; Solanum elaeagnifolium; Solanum grandiflorum; Solanum laciniatum; Solanum lycopersicum; Solanum macrocarpon; Solanum mammosum; Solanum melongena; Solanum muricatum; Solanum nigrum; Solanum panduraeforme; Solanum quitoense; Solanum sp.; Solanum tuberosum; Withania somnifera.

Strelitziaceae: Strelitzia reginae.

Theaceae: Camellia japonica; Camellia sinensis; Camellia sp.

Thymelaeaceae: Dais cotinifolia.

Tropaeolaceae: Tropaeolum majus; Tropaeolum sp.

Ulmaceae: Ulmus americana; Ulmus glabra; Ulmus laevis; Ulmus pumila; Ulmus rubra; Ulmus sp.

Urticaceae: Boehmeria nivea; Laportea aestuans; Parietaria judaica; Parietaria officinalis; Pipturus albidus; Urtica dioica; Urtica sp.; Urtica urens.

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Verbenaceae: Aloysia citriodora; Duranta erecta; Glandulariaphlogrflora; Lantana camara;

Lippia alba; Verbena bracteata; Verbena brasiliensis; Verbena hybrida; Verbena officinalis; Verbena sp.

Violaceae: Viola odor ata; Viola sp.; Viola tricolor; Viola x wittrockiana.

Vitaceae: Ampelopsis sp.; Parthenocissus quinquefolia; Parthenocissus tricuspidata; Vitis sp.;

Vitis vinifera.

Xanthorrhoeaceae: Hemerocallis fulva; Hemerocallis minor.

Zingiberaceae: Curcuma longa; Zingiber mioga.

Zygophyllaceae: Tribulus terrestris.

The term fungal growth reducing agent or fungal growth reducing agent as used herein refers to a chemical fungal growth reducing agent, such as a natural or synthetic fungicide, or a biological fungal growth reducing agent, such as a population of a mite species that produces antifungal secretions. substances, or a population of mycophagous mites.

It is within the scope of the present invention that the propagation composition according to any of the above definitions does not contain or does not contain an agent for reducing fungal growth. The claimed mites of the genus Phytoseiulus of the present invention are capable of completing their life cycle and reproducing for at least 2 generations when they are bred on lifeless individuals of the order Astigmata, including mites at any stage of development and/or eggs. It should be noted that nonviable mites of the order Astigmata at various stages of development are not capable of producing or secreting agents to reduce fungal growth.

To understand the present invention and provide an idea of how it may be put into practice, several preferred embodiments will now be described, given by way of non-limiting example only, with reference to the following examples.

Example 1

Breeding protocol for P. persimilis

In this example, rearing is accomplished by feeding P. persimilis a mixture containing dead frozen C. lactis mites at various stages of development and sawdust or other carrier material (eg bran). Prey ticks were immobilized by immobilizing treatment, such as freezing or gamma irradiation, before being used as food.

Illustrative growing conditions:

temperature: in the range of 18-30°C, in particular approximately 22°C;

Humidity: above 60%, in particular approximately 85%.

With the above nutritional regimen, the P. persimilis population increased by an average of approximately 15% per day.

In fig. Figure 3 graphically describes the daily reproduction rate of P. persimilis fed on a mixture of dead C. lactis eggs and motile stages (freeze-killed) over a 14-week period. As can be seen, an average increase in the reproduction rate of P. persimilis ranging from approximately 10% to approximately 20% per day was recorded.

Methods used in this experiment

A population of P. persimilis was reared using dead C. lactis as prey at 22 degrees Celsius and 85% relative humidity mixed with sawdust. Each week the mixture was weighed and four samples containing approximately 50 mg were taken, placed on black tape and the number of individuals counted. The total population size was calculated according to these calculations and 1500 individuals were kept for breeding each week. Reproduction rates were calculated by dividing the total number of individuals detected by 1500 to obtain the multiplier at which the population reproduced during a given week. To convert the daily reproduction rate into an indicator, the 7th root of this number was taken in accordance with the following formula:

- 31 046116 t N(t

N(0) where λ is the daily reproduction rate, N(0) is the number of mites left for breeding in the previous count (in this case 1500), N(t) is the number of mites found in this count, and t =7.

Example 2

Breeding P. persimilis on astigmatoid mites

In this experiment, different species of mites were tested as food for P. persimilis using the following protocol.

Thirty P. persimilis mites were isolated in modified Munger cells and fed frozen astigmatic mites of the species listed below. Food was replaced daily and ticks were checked for feeding signs. Characteristics used as indicators were a fully rounded body (as opposed to the flat body of mites that do not feed) and a whitish coloration, as opposed to the usual orange coloration when feeding on spider mites.

Let us now turn to FIG. 4, which graphically represents the percentage of P. persimilis showing signs of feeding, as indicated by the shape and color of their body, after feeding for 3 consecutive days on each of the following types of ticks that serve as prey:

GD = Glyciphagus domesticus (family Glycyphagidae)

LD = Lepidogyphus destructor (family Glycyphagidae)

DF = Dermatophagoides farinae (family Pyroglyphidae)

DP = Dermatophagoides pteronisinus (family Pyroglyphidae)

CL = Carpoglyphus lactis (family Carpoglyphidae)

It can be seen that P. persimilis can feed on all of the above astigmatoid mite prey species with varying efficiency.

Example 3

Use of Amblyseius swirskii as prey for P. persimilis

In this experiment, 50 predatory mites were fed frozen A. swirskii mites as food at 22°C, 85% RH and checked daily. The ticks showed signs of feeding based on their large bodies and whitish coloration. When oviposition began, eggs were collected from the population, isolated, and monitored for hatching. The hatching and then maturation of the resulting larvae were noted. When these mites reached maturity, two of them were isolated to test their ability to lay eggs. These females actually laid eggs, and the resulting eggs were observed to hatch. This demonstrates that P. persimilis can develop and reproduce on frozen A. swirskii as food for at least two generations, and that the third generation eggs laid are viable.

Example 4

Slow release system for P. persimilis

We now turn to a description of a controlled release system for P. persimilis in accordance with some embodiments of the present invention. A mixture containing approximately 200 P. persimilis mites was reared on dead C. lactis prey mites and sawdust as a vehicle was placed in a container (eg a sachet or small plastic bottle of approximately 100 ml) with an outlet hole in its lid. The container was placed on adhesive tape or a surface under controlled conditions (25°C, 75% humidity). The adhesive tape was replaced twice a week and the number of P. persimilis mites that appeared on it was counted to estimate the rate of release from the container.

Let us now turn to FIG. 5, which graphically illustrates the dependence of the rate of release of mites from the container on the number of days after the start of the experiment.

As can be seen in FIG. 5, mites are continuously released from the container over a period of 20 days, with peak release occurring around day 9 (between days 8 and 10). The release rate of predatory mites was approximately 2-25 mites per day. This example demonstrates that, based on the composition and reconstitution method of the present invention, a slow or controlled release system has been constructed to

P. persimilis (released over at least about 20 days).

Example 5

Phytoseiulus longipes raised on C. lactis as prey

Let us now take an example in which breeding is accomplished by feeding Phytoseiulus longipes (P. longipes), as a further illustrative example from the genus Phytoseiulus, a mixture containing dead C. lactis as prey.

Illustrative breeding protocol. A population of P. longipes was reared using dead C. lactis as prey at 22°C and 85% relative humidity mixed with sawdust. The mites showed signs of feeding, as determined by their color changing from the typical reddish to white, as shown above for P. persimilis feeding on C. lactis (see Figs. 1 and 2). In addition, all different life stages of P. longipes mites were observed, indicating that this species completed its developmental cycle on this alternative diet. Reproduction was maintained for three weeks, indicating that a population of P. longipes can be propagated on dead C. lactis for at least this period of time.

Example 6

Reproduction and selection of a population of P. persimilis with increased reproduction rates on C. lactis as prey

This experiment demonstrated the successful propagation and selection of a population of P. persimilis adapted to feed on C. lactis as prey. As shown in this example, the selected population of P. persimilis has the advantageous and desirable properties of significantly increased reproduction rates when reared on astigmatite mites.

Experimental protocol

P. persimilis was reared using dead C. lactis as prey at 22°C and 85% relative humidity mixed with sawdust. Each week the mixture was weighed and four samples containing approximately 50 mg each were taken, placed on black tape and the number of individuals counted. The total population size was calculated according to these calculations and 1500 individuals were kept for breeding each week. Reproduction rates were calculated by dividing the total number of individuals detected by 1500 to obtain the multiplier at which the population reproduced during a given week. To calculate the daily reproduction rate, the 7th root of this calculated number was taken in accordance with the following formula:

t N(t

N(0) where λ is the daily reproduction rate, N(0) is the initial number of mites retained for breeding (i.e. 1500 mites), N(t) is the total number of mites found after breeding during the period time of a week and t=7.

It should be noted that each population was maintained and measured over a period of 4-10 weeks. The entire procedure was repeated 3 times.

Let us now turn to FIG. 6, which demonstrates the observed differences in daily reproductive rate (represented as λ, terminal rate of increase) between a population of P. persimilis propagated and selected for adaptation to C. lactis as an artificial prey host (denoted as P+ in Fig. 6 ), compared with a conventional or commercially available population of P. persimilis (raised on their natural host, i.e., spider mites) used as a control (denoted as P- in Fig. 6). The figure presents the means and standard error found for the λ values during testing.

As can be seen in FIG. 6, a population of P. persimilis selected for improved adaptation to breeding on C. lactis individuals (P+) showed a significantly increased daily reproductive rate of approximately 3.6 (P+/P-: 0.18/0. 05), on C. lactis as prey, compared to a control population of P. persimilis not subjected to the breeding and selection process as specifically described (P-).

In conclusion, the present invention provides for the first time a population of P. persimilis that exhibits the trait of increased reproduction rate when reared on astigmatite mites, such as C. lactis individuals, as prey. This provides the possibility of a very preferable, revolutionary indoor production of improved predatory mites P. persimilis, characterized by increased fertility when bred on mites of the order Astigmata, in comparison with

- 33 046116 unselected, currently available P. persimilis mites that exhibit significantly reduced reproductive rates and yields when bred on the same species of mites of the order Astigmata serving as prey.

Example 7

Slow release of ticks in the field

This example demonstrates the performance of a slow release system of the present invention (eg, described in Example 4 above) under greenhouse conditions.

Sweet pepper plants were planted in a greenhouse and treated with three different treatments in 5 replicates:

Slow-release sachets containing 30 P. persimilis were applied to plants 13 days before plants were infested with spider mites.

Slow-release sachets containing 30 P. persimilis were applied to plants 6 days before plants were infested with spider mites.

Control plants were not treated with P. persimilis.

The sachets were placed on the lower parts of plants 1 m high. Infestation was carried out by attaching a leaf infected with spider mites with staples to one of the upper leaves of the plant. After 3 days of plant infestation, samples of the mite population on each plant were collected. Spider mites and P. persimilis mites found on or above the infested leaf were counted.

Let us now turn to FIG. 7, which graphically illustrates the number of P. persimilis (Pp) and spider mites on plants treated with the slow release system of the present invention compared to control plants. As can be seen, predatory mites were detected on plants treated with both P. persimilis-based treatments. In addition, spider mite counts on plants treated with P. persimilis decreased rapidly compared to control plants. More specifically, an inverse correlation was observed between the number of P. persimilis and the number of spider mites, namely, the more P. persimilis mites were on the plants, the lower the number of spider mites. This experiment clearly demonstrates that P. persimilis mites and, more specifically, the composition of the present invention are effective against spider mite infestations. The P. persimilis slow release system of the present invention reduced the spider mite population on the plant despite the relatively long time (approximately 6-13 days) elapsed between the application of P. persimilis and the transfer of the spider mites to the plant. This demonstrates the effectiveness of the P. persimilis based composition and slow release system described herein in controlling spider mite infestations.

Bibliography

Chant, D. A. & McMurtry, J. A. (2006). A review of the subfamily Amblyseiinae Muma (Acari: Phytoseiidae): part VIII. The tribes Macroseiini Chant, Denmark and Baker, Phytoseiulini n. tribe, Africoseiulini n. tribe and Indoseiulini Ehara and Amano. International Journal of Acarology 32, 13-25.

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Simmonds, S.P. (1970). The Possible Control of Steneotarsonemus pallidus on Strawberries by Phytoseiulus persimilis. Plant pathology 19, 106-107.

McMurtry, J.A. & Croft, B.A. (1997). Life-styles of phytoseiid mites and their roles in biological control. Annual Review of Entomology, 42, 291-321.

Helle, W. & Sabelis, M.W. (1985). Spider Mites. Their Biology, Natural Enemies and Control, Vol. I.B. Elsevier, Amstedam.

Gerson, U., Smiley, R.L. & Ochoa, R. (2003). Mites (Acari) for Pest Control; Blackwell Science Ltd.: Oxford, UK.

Walzer, A. & Schausberger, P. (1999). Cannibalism and interspecific predation in the phytoseiid mites Phytoseiulus persimilis and Neoseiulus californicus'. predation rates and effects on reproduction and juvenile development BioControl 43: 457-468.

Yao, D.S. & Chant, D.A. (1989). Population growth and predation interference between two species of predatory phytoseiid mites (Acarina: Phytoseiidae) in interactive systems. Oecologia 80: 443–455.

Walzer, A., Paulus, W. & Schausberger, P. (2004) Ontogenetic shifts in intraguild predation on thrips by phytoseiid mites: the relevance of body size and diet specialization. Bulletin of Entomological Research, 94, 577-584.

van de Vrie, M., McMurtry J. A. & Huffaker S. B. (1972) Ecology of tetranychid mites and their natural enemies: A review: III. Biology, ecology, and pest status, and host-plant relations of tetranychids. Hilgardia 41(13):343–432.

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Claims (56)

CLAIM 1. Combination for breeding predatory mites Phytoseiulus, containing: a population of predatory mites comprising at least one species of mites from the genus Phytoseiulus, and a population of prey mites comprising individuals of at least one species of mites from the order Astigmata, wherein said population of predatory mites is a population selected for laying eggs over at least 2 generations on said prey mites of the order Astigmata, wherein further said mites of the order Astigmata prey belong to a family selected from Glycyphagidae, Pyroglyphidae and Carpoglyphidae, and selected from the group consisting of non-viable eggs or a combination of non-viable eggs and non-viable mites. 2. The combination according to claim 1, wherein said predatory mite is capable of laying eggs for at least 10 generations, bred on said individuals of mites of the order Astigmata, serving as prey. 3. The combination according to claim 1, where the specified population of predatory mites is characterized by a trait of increased reproduction rate compared to the control population of predatory mites without the specified trait. 4. The combination according to claim 1, wherein said population of predatory mites is characterized by a beige-white color. 5. The combination according to claim 1, wherein said combination does not contain an agent for reducing fungal growth. 6. The combination according to claim 1, wherein said species of predatory mite is selected from the group consisting of Phytoseiulus fragariae, Phytoseiulus longipes, Phytoseiulus macropilis, Phytoseiulus persimilis and Phytoseiulus robertsi. 7. The combination according to claim 1, wherein said species of predatory mite is Phytoseiulus persimilis. 8. The combination of claim 1, wherein the species from the order Astigmata belongs to a family selected from the group consisting of Carpoglyphidae, Pyroglyphidae, Acaridae and Glycyphagidae. 9. The combination according to claim 1, where the species from the order Astigmata includes representatives from the family Carpoglyphidae, such as the genus Carpoglyphus, for example Carpoglyphus lactis, Carpoglyphus munroi; from the family Glycyphagidae, such as the genus Glycyphagus, for example Glycyphagus domesticus, from the genus Lepidoglyphus, for example Lepidoglyphus destructor, from the family Pyroglyphidae, such as the genus Dermatophagoides, for example Dermatophagoides farinae, Dermatophagoides pteronisinus, from the family Acaridae, such as of the genus Tyrophagus, for example Tyrophagus putrescentiae. 10. The combination according to claim 1, wherein said population of mites of the order Astigmata serving as prey is in frozen form. 11. The combination of claim 1, wherein said prey population of mites of the order Astigmata comprises a mixture containing non-viable frozen juvenile mites at various stages of development. 12. The combination according to claim 1, wherein the combination contains at least one species of mites from the genus Phytoseiulus and a mixture containing non-viable frozen juvenile C. lactis mites at various stages of development and sawdust or other carrier material. 13. The combination of claim 1, wherein said combination comprises P. persimilis and a mixture containing non-viable frozen juvenile C. lactis ticks at various stages of development and sawdust or other carrier material. 14. The combination of claim 1, wherein said prey population of mites of the order Astigmata comprises non-viable eggs of C. lactis. 15. The combination of claim 1, wherein said prey population of mites of the order Astigmata includes non-viable eggs and non-viable juvenile mites at a ratio of 1:1 (w/w). 16. The combination of claim 1, wherein said combination further comprises a carrier such as sawdust, bran or other carrier material. 17. The combination according to claim 1, wherein said population of predators bred on said species of mites from the order Astigmata reproduces at an average rate of at least about 15% per day, in particular in the range from 15% to 25% per day. 18. The combination of claim 1, wherein said astigmatoid mites are treated with a treatment selected from the group consisting of heat treatment such as freezing, heating, cold shock treatment or heat shock treatment; chemical treatment such as gas or smoke treatment; radiation treatments such as UV, microwave, gamma or x-ray treatments; mechanical processing such as vigorous shaking or stirring, shearing, impact; processing - 36 046116 by changing gas pressure, such as ultrasonic treatment, pressure changes, pressure differences; electrical treatment such as electric shock; immobilization with adhesive; immobilization due to fasting, such as induced by water or food deprivation; immobilization by treatment causing asphyxiation or oxygen deprivation, such as temporary removal of oxygen from the atmosphere or replacement of oxygen with another gas, and any combination thereof. 19. The combination of claim 1, wherein the combination comprises P. persimilis and a mixture containing non-viable C. lactis eggs and sawdust or other carrier material. 20. The combination of claim 1, wherein said combination comprises P. persimilis and a mixture containing non-viable C. lactis mites and sawdust or other carrier material. 21. The combination according to claim 1, wherein said combination contains a population of predatory mites Phytoseiulus persimilis and dead individuals of at least one species belonging to the order Astigmata, selected from the group consisting of Carpoglyphus lactis, Lepidoglyphus destructor, Glycifagus domestics, Dermatophagoides farinae and Dermatophagoides pteronisinus. 22. The combination of claim 1, wherein said prey mite population further comprises a species of mite from the family Phytoseiidae. 23. The combination according to claim 22, wherein said prey species of mites from the family Phytoseiidae is non-viable. 24. The combination according to claim 1, wherein said combination is capable of controlling a crop pest. 25. The combination of claim 24, wherein said crop pest is selected from the group of mites, in particular members of the family Tetranychidae subclass Acari, such as the common spider mite, more particularly a species of spider mite, especially Tetranychus, Panonychus and various other mite species. 26. The combination of claim 24, wherein said combination is capable of reducing said crop pest by at least 50%. 27. A combination according to any one of claims 1 to 26, formulated for the controlled release of said predatory mites onto a crop plant. 28. The combination according to any one of claims 1 to 27, contained in a container configured to release said predatory mites onto the crop plant in a controlled manner. 29. The combination of claim 28, wherein said predatory mites are capable of being slowly and continuously released from said container onto said crop over a period of approximately three weeks. 30. A method for breeding a population of predatory mites, including at least one species of mites from the genus Phytoseiulus, the method including: a. providing a combination for breeding Phytoseiulus according to any one of claims 1 to 22 and b. providing the opportunity for individuals from the predatory mite population to hunt individuals from the astigmatosis mite population for at least 2 generations. 31. A method for breeding a population of predatory mites, including at least one species of mites from the genus Phytoseiulus, the method including: a. providing a combination comprising a population of predatory mites comprising at least one species of mites from the genus Phytoseiulus, and a population of prey mites comprising individuals of at least one species of mites from the order Astigmata, wherein said population of predatory mites is selected for laying eggs over at least 2 generations on said mites of the order Astigmata serving as prey; b. allowing individuals from the predatory mite population to prey on individuals from the astigmatosis mite population for at least 2 generations; wherein said prey mites of the order Astigmata belong to a family selected from Glycyphagidae, Pyroglyphidae and Carpoglyphidae, and said prey mites of the order Astigmata are selected from the group consisting of non-viable eggs or a combination of non-viable eggs and non-viable mites. 32. Method according to any one of claims 30 and 31, wherein the breeding population is maintained in a temperature range of 18-30°C, in particular at approximately 22°C. 33. Method according to any one of claims 30 and 31, wherein the breeding population is maintained at a relative humidity of 70-90%, in particular at approximately 85%. 34. The method according to claim 31, wherein said predatory mite is capable of laying eggs for at least 2 generations, preferably for at least 10 generations, bred on said individuals of mites of the order Astigmata serving as prey. 35. The method according to claim 31, wherein said combination does not contain an agent for reducing fungal growth. 36. The method according to claim 31, where the specified species of predatory mites is selected from the group consisting of Phytoseiulus fragariae, Phytoseiulus longipes, Phytoseiulus macropilis, Phytoseiulus persimilis and Phytoseiulus robertsi. - 37 046116 37. The method according to claim 31, wherein said species of predatory mite is Phytoseiulus persimilis. 38. The method of claim 31, wherein the species from the order Astigmata belongs to a family selected from the group consisting of Carpoglyphidae, Pyroglyphidae, Acaridae and Glycyphagidae. 39. The method according to claim 31, where the species from the order Astigmata includes representatives from the family Carpoglyphidae, such as the genus Carpoglyphus, for example Carpoglyphus lactis, Carpoglyphus munroi; from the family Glycyphagidae, such as the genus Glycyphagus, for example Glycyphagus domesticus, from the genus Lepidoglyphus, for example Lepidoglyphus destructor, from the family Pyroglyphidae, such as the genus Dermatophagoides, for example Dermatophagoides farinae, Dermatophagoides pteronisinus, from the family Acaridae, such as the genus Tyrophagus, for example Tyrophagus putrescentiae. 40. The method according to claim 31, wherein said population of mites of the order Astigmata serving as prey is in frozen form. 41. The method of claim 31, wherein said prey population of mites of the order Astigmata comprises a mixture containing non-viable frozen juvenile mites at various stages of development. 42. The method according to claim 31, where the combination contains at least one species of mites from the genus Phytoseiulus and a mixture containing non-viable frozen juvenile C. lactis mites at various stages of development and sawdust or other carrier material. 43. The method of claim 31, wherein said combination comprises P. persimilis and a mixture containing non-viable frozen juvenile C. lactis ticks at various stages of development and sawdust or other carrier material. 44. The method of claim 31, wherein said prey population of mites of the order Astigmata comprises non-viable eggs of C. lactis. 45. The method of claim 31, wherein said prey population of mites of the order Astigmata comprises non-viable eggs and non-viable juvenile mites at a ratio of 1:1 (w/w). 46. The method of claim 31, wherein said combination further comprises a carrier such as sawdust, bran or other carrier material. 47. The method according to claim 31, wherein the specified population of predators bred on the specified species of mites from the order Astigmata reproduces at an average rate of at least about 15% per day, in particular in the range from 15% to 25% per day. 48. The method of claim 31, wherein said astigmatite mites are treated with a treatment selected from the group consisting of heat treatment such as freezing, heating, cold shock treatment or heat shock treatment; chemical treatment such as gas or smoke treatment; radiation treatments such as UV, microwave, gamma or x-ray treatments; mechanical processing such as vigorous shaking or stirring, shearing, impact; processing by changing gas pressure, such as ultrasonic treatment, pressure changes, pressure drops; electrical treatment such as electric shock; immobilization with adhesive; immobilization due to fasting, such as induced by water or food deprivation; immobilization by treatment causing asphyxiation or oxygen deprivation, such as temporary removal of oxygen from the atmosphere or replacement of oxygen with another gas, and any combination thereof. 49. The method of claim 31, wherein said combination comprises P. persimilis and a mixture containing non-viable C. lactis eggs and sawdust or other carrier material. 50. The method of claim 31, wherein said combination comprises P. persimilis and a mixture containing non-viable C. lactis mites and sawdust or other carrier material. 51. The method according to claim 31, wherein said combination contains a population of predatory mites Phytoseiulus persimilis and dead individuals of at least one species belonging to the order Astigmata, selected from the group consisting of Carpoglyphus lactis, Lepidoglyphus destructor, Glycifagus domestics, Dermatophagoides farinae and Dermatophagoides pteronisinus. 52. The method of claim 31, wherein said prey mite population further comprises a species of mite from the family Phytoseiidae. 53. The method according to claim 52, where the specified species of mites from the family Phytoseiidae, which serve as prey, is non-viable. 54. A method for controlling a pest of an agricultural crop, the method comprising using a Phytoseiulus breeding combination according to any one of claims 1 to 29 in relation to a crop grown in soil. 55. The method of claim 54, wherein said crop pest is selected from the group of mites, in particular members of the family Tetranychidae subclass Acari, such as the common spider mite, more particularly spider mite species, especially Tetranychus, Panonychus and various other mite species. 56. Use of the Phytoseiulus breeding combination according to any one of claims 1 to 29 for the control of a crop pest. -