WO2001029074A1

WO2001029074A1 - Chimeric gene coding for a myb30 transcription factor and expression in plants

Info

Publication number: WO2001029074A1
Application number: PCT/FR2000/002922
Authority: WO
Inventors: Xavier Daniel; Christophe Lacomme; Dominique Roby
Original assignee: Centre National De La Recherche Scientifique (Cnrs)
Priority date: 1999-10-21
Filing date: 2000-10-20
Publication date: 2001-04-26
Also published as: FR2800092A1

Abstract

The invention concerns a novel chimeric gene coding for a MYB30 transcription factor whereof the expression in plants modulates the response to pathogenic stresses, the plant cells comprising said chimeric gene stably integrated in their genome, and transformed plants comprising said stably integrated chimeric gene in their genome and/or comprising said plant cells.

Description

CHIMERIC GENE ENCODING A TRANSCRIPTION FACTOR MYB30 AND EXPRESSION IN PLANTS

The present invention relates to a new chimeric gene whose expression in plants modulates the response to pathogenic aggressions, plant cells comprising said chimeric gene integrated in a stable manner into their genome, and transformed plants comprising said chimeric gene integrated in a stable manner in their genome and / or comprising the above plant cells. In their natural environment, plants are constantly subjected to attack by pathogenic organisms. Before they can penetrate the plant, they must first cross the structural barriers represented by cutin and suberin deposits present on the surface of the leaves and stems, as well as the wall.

^" pectocellulosic of each cell. Often these structural barriers are sufficient and the plant resists infection. Otherwise, the aggressor enters via the action of lytic enzymes such as cutinases and cellulases, or via natural openings (stomata, hydathodes, roots) or accidental openings (wound), and the plant must develop defense mechanisms within its tissues. The ability of the plant to rapidly implement new defense strategies to fight against its invasion, as well as the pathogen's ability to divert them, are the determinants of the outcome of the interaction.

A given phytopathogenic microorganism (bacteria, virus, fungus) attacks a limited number of plant species, called "host" plants, all other species being called "non-host". The interaction is said to be "compatible" when a "sensitive" host plant interacts with a "virulent" pathogenic agent which develops within the plant, causing disease there. Conversely, the interaction is said to be "incompatible" when the "resistant" host plant develops defense reactions preventing the "avirulent" pathogen from multiplying. An interaction between a non-host plant and a virulent or avirulent pathogen is also described as incompatible. One of the plant's defense responses during an incompatible interaction the most spectacular is the Hypersensitive Response or HR. This strong and rapid response is characterized by the death of cells at the point of infection, and those immediately around. HR can be triggered in response to infection by a wide variety of pathogens and can occur only a few hours after contact between the plant and the pathogen causing rapid and limited necrosis. Cell death is genetically programmed, although the experimental data in this direction are still fragmentary. One of the best indications of the existence of such cell death programs is the identification of mutants of plants presenting spontaneous lesions (in the absence of any attack by a pathogenic agent) which can be of two types, necrotic or chlorotic. This suggests the involvement of different cell death programs during pathogenesis.

The triggering of HR is conditioned by the recognition by the plant of the pathogen. This initial recognition event, via the transduction of the perceived signal (s), leads to the execution of a cell death program. The so-called "gene-for-gene" theory defined by Flor in 1947 (Flor, 1947) describes the specificity of recognition between a host plant and a pathogenic agent. This recognition involves a gene for "resistance" or R gene generally dominant in the plant, and a dominant gene for "avirulence" or _4vr in the pathogen. An "elicitor / receiver" model was

- proposed to explain this theory. In this model, the Avr genes encode elicitors recognized directly or indirectly as ligands by the receptors encoded by the R genes (Keen, 1990). It should be noted that a plant can have many R genes, just as a pathogen can have many Avr genes. Thus, it would be possible to extend the gene-for-gene theory to non-host interactions, where the addition of several recognitions would lead to resistance. Following recognition events between the resistant plant and the avirulent pathogen, the signaling pathways leading to the hypersensitive response involve the phosphorylation / dephosphorylation of proteins, flows of electrolytes through the plasma membrane, the production of reactive oxygen species, and possibly other events as yet unknown. The role of each of these changes in plant cell metabolism is not always strictly demonstrated, but a bundle of experimental data highlights them. However, the sequence of these signaling events is not clearly determined, and may vary depending on the pathosystem.

Hypersensitive cell death is genetically programmed, as indicated by many recent works, and can be compared with other forms of programmed cell death (pcd) in plants and with apoptosis in animals. The components required for the regulation of hypersensitive cell death are currently identified genetically by the isolation of mutants "spontaneous lesions", as previously mentioned. These mutants show phenotypes which are characterized by the appearance of necrotic lesions similar to those observed during a hypersensitive response. These lesions can be delimited, or spread. An interpretation of these phenotypes has been proposed (Walbot et al, 1983), suggesting that cell death initiated by any stimulus is autocatalytic and controlled by a suppressor system. Mutations causing the spontaneous appearance of delimited lesions (initiation mutants) are thought to affect genes involved in the initiation of cell death, while mutants showing propagative lesions (propagation mutants), are thought to be affected in suppressants of cell death or genes involved in limiting cell death. Genes that are affected by these mutations are thought to play a role in resistance, with several of these mutants showing expression of histochemical, biochemical and molecular markers associated with plant resistance responses.

At present, there is little data concerning the actors of cell death occurring during plant / pathogenic microorganism interactions. The search for these components is therefore a particularly important area of investigation to explore. Various strategies can be developed for this purpose: one of them is the identification of genes whose expression is specifically induced during HR. This approach, developed in Arabidopsis thaliana, led to the isolation of the AtMYB30 gene, which codes for a MYB-type transcription factor (Lacomme, 1996). The MYB factors are proteins that regulate the transcription of other genes, present in almost all living things, particularly numerous in plants, and in particular in Arabidopsis, where their family has more than a hundred members. They are involved in many physiological processes, but none of them has yet been involved in the regulation of cell death.

The discovery of the existence of MYB factors comes from research carried out in the animal domain. The study of leukemia affecting myeloblasts in Chicken caused by the poultry myeloblastosis virus or AMN (for Avian Myeloblastic Virus) has indeed led to the identification of the viral nucleotide sequence of the gene responsible for oncogenic power (Duesberg and al, 1980). This sequence presented extremely strong homologies with a gene (PROTO-AMV) contained in the cellular ADΝ of the chicken (Souza et al, 1980). This gene was renamed C-MYB (for cellular myeloblastosis) and the sequence transduced into the genome of the virus, V-MYB (Klempnauer et al, 1982). The transition from C-MYB to V-MYB results from a rearrangement of cellular ADΝ involving deletions of a part of each of the 3 'and 5' ends of the C-MYB gene. Subsequently, genes strongly homologous to C-MYB were identified and cloned in all the animal species studied: humans have four MYB genes (HsMYB, A-MYB, B-MYB and HsMYBCDCS) (Bernstein and Coughlin, 1997 ; Majello et al, 1986; Νomura et al, 1988), one mouse (C-MYB) (Gonda et al, 1985), Drosophila at least two (D-MYB and DmMYBCDC5) (Katzen et al, 1985; Ohi et al, 1998).

These genes are also present in the yeasts Saccharomyces cerevisiae (ScMYBBASl, ScMYBREBl and ScMYBCDCS) (Ohi et al, 1998; Tice-Baldwin et al, 1989) and Schizosaccharomyces pombe (SpMYBCDCδ) (Ohi et ai, 1994), the ascomycete filamentous fungus Aspergillus nidulans (AnMYBFLBD) (Wieseτ and Adams, 1995), the nematode Caenorhabditis elegans (CeMYBCDC5) (Ohi et al, 1998), and the amoeba Dictyostelium discoideum (DdMYBl and DdMYB2) (Oisv a. And Van Haastert, 1998; - Grasser and α /., 1992). In plants, the first gene coding for a transcriptional factor of MYB type identified was the ZmMYBCl gene of Corn, corresponding to a locus studied since 1984

(Rhoades, 1984; Paz-Ares et a, 1987). Unlike their animal counterparts, plant MYB genes are represented in plants by much larger multigenic families: ten members in corn (Chopra et al, 1996; Hattori et al, 1992; Marocco et al, 1989; Paz - Ares et al, 1987; Timmermans et al, 1999), Barley (Gubler et al, 1995; Marocco et al, 1989; Wissenbach et ai, 1993) and Antirrhinum majus (Jackson et ai, 1991; Noda et ai, 1994; Waites et al, 1998). They have been identified in many other plant species: Tobacco (Yang and Klessig, 1996), Pea (Uimari and Strommer, 1997), Rice (Gubler et al, 1997; Magaraggia et al, 1997), Tomato ( Lin et al, 1996), Potato (Baranowskij et al, 1994), Craterostigma plantagineum (Iturriaga et al, 1996), Parsley (Feldbrugge et al, 1997) and Lolium temulentum (Gocal et ai, 1999), as well as Physcomitrella patens foam (Leech et ai, 1993). We can notably mention Petunia which would have 20 to 40 MYB genes (Avila et al, 1993), and especially Arabidopsis thaliana whose members of the MYB family are at least one hundred in number (Kranz et al, 1998; Romero et al , 1998), as previously mentioned.

Recent estimates of the total number of genes in Arabidopsis (16,000 to 25,000) indicate that the MYB genes represent 0.2 to 0.6% of this total, representing the largest proportion known to date for a family of regulatory genes in plants (Romero et al, 1998). There are other families of equal or greater size in eukaryotes, such as the family of genes encoding Zinc finger proteins, which is thought to represent approximately 1% of human genes (Hoovers et al, 1992). However, overall sequence conservation between genes is very low in this family (Klug and Schwabe, 1995), while plant MYB factors share very strong amino acid sequence similarities (Romero et al, 1998). To determine the overall regulation potential of MYB factors in plants, research into the function of all genes in this family was undertaken in Arabidopsis thaliana via the formation of a European consortium of fifteen laboratories. Kranz et al. (Kranz et al, 1998) published a study concerning 97 MYB genes, including more than 30 new ones. Their distribution in the Arabidopsis genome shows that they cover 92% of its surface: even if there are some rare loci comprising several genes (up to six out of 4 cM on chromosome V), this distribution seems homogeneous and random. (Kranz et al, 1998).

In view of the general knowledge set out above, a person skilled in the art would have considered that the overexpression of a gene involved in cell death would cause the formation of significant necrosis, implying a very retarded growth phenotype. ^' marked, a phenotype of the “spontaneous lesions” type or an altered phenotype for HR, incompatible with the development of transgenic plants susceptible to commercial development.

However, contrary to what might have been expected, the overexpression of the AtMYB30 gene in plants makes it possible to increase their tolerance to pathogenic aggressions, without causing phenotypic responses of the necrosis type.

The present invention therefore relates to a new chimeric gene (or expression cassette) comprising, in the direction of transcription, a promoter regulatory sequence which is functional in plant cells and plants, a nucleic acid sequence coding for a factor MYB30 and a functional terminator regulatory sequence in plant cells and plants, the above being operably linked to allow expression of the MYB gene in plant cells and plants.

According to a particular embodiment of the invention, the sequence coding for the factor MYB30 is a sequence of plant origin, in particular of Arabidopsis thaliana. Preferably, the sequence coding for a factor MYB30 is the sequence coding for the factor _4tMYB30 represented by SEQ ID NO 1.

The present invention also relates to the sequences capable of hybridizing selectively with the sequence SEQ ID NO 1 above, the sequences homologous to the above sequence, the fragments of said sequence, and the sequences which differ from the sequence. above but which due to the degeneracy of the genetic code, code for the same protein.

According to the present invention, the term “nucleic acid sequence” is intended to mean a nucleotide or polynucleotide sequence, which may be of the DNA type, in particular double strand, in particular of the cDNA type.

By "sequence capable of hybridizing selectively" is meant according to the invention the sequences which hybridize with the above sequence at a level significantly above the background noise. The background noise can be linked to the hybridization of other DNA sequences present, in particular other cDNAs present in a cDNA library. The level of the signal generated by the interaction between the sequence capable of selectively hybridize and the sequence defined by SEQ ID NO 1 above is generally 10 times, preferably 100 times more intense than that of the interaction of other DNA sequences generating background noise. The level of interaction can be measured, for example, by labeling the probe with radioactive elements, such as ³² P. Selective hybridization is generally obtained by using very ^" harsh ^" environmental conditions (for example 0.03 M NaCl and 0.03 M sodium citrate at approximately 50 ° C.-60 ° C. The hybridization can of course be carried out according to the usual methods of the prior art (in particular Sambrook & al., 1989, Molecular Cloning: A Labratory Manual).

By "homolog" is meant according to the invention a nucleic acid sequence having one or more sequence modifications compared to SEQ ID NO 1 and coding for the transcription factor AtMYB30. These modifications can be obtained according to the usual mutation techniques, or alternatively by choosing the synthetic oligonucleotides used in the preparation of said sequence by hybridization. In view of the multiple combinations of nucleic acids which can lead to the expression of the same amino acid, the differences between the reference sequence described by SEQ ED NO 1 and the corresponding homolog may be significant. Advantageously, the degree of homology will be at least 70% relative to the reference sequence, preferably at least 80%, more preferably at least 90%. These modifications are generally and preferably neutral, that is to say that they do not affect the primary sequence of the transcription factor AtMYB30.

The methods for measuring and identifying the homologies between the nucleic acid sequences are well known to those skilled in the art. One can use for example the programs PILEUP or BLAST (in particular Altschul & al., 1993, J. Mol. Evol. 36: 290-300; Altschul & al., 1990, J. Mol. Biol. 215: 403-10) . By “fragments” is meant according to the invention fragments of the DNA sequences defined by the ID sequences above, that is to say the above sequences for which parts have been deleted but which retain the function of said sequences, ie coding for a transcription factor with a function and activity similar and / or equivalent to that of the transcription factor AtMYB30. In the chimeric gene according to the invention, the promoter regulatory sequence functional in plant cells and plants, is advantageously heterologous with respect to the sequence coding for the factor MYB30. By “heterologous” is meant according to the invention a functional promoter region different from the functional promoter region native to the sequence coding for factor MYB 30. As promoter regulatory sequence in plants, any promoter sequence of a gene may be used. expressing itself naturally in plants, such as promoters known as constitutive of bacterial, viral or vegetable origin or also promoters called light dependent like that of a gene of the small subunit of ribulose-biscarboxylase / oxygenase (RuBisCO ) of a plant or any known suitable promoter which can be used. Among the promoters of plant origin, mention will be made of the histone promoters as described in application EP 0 507 698, or the rice actin promoter (US Pat. No. 5,641,876). Among the promoters of a plant virus gene, mention will be made of that of the cauliflower mosaic (CaMV 19S or 35 S).

It is also possible to use a promoter regulatory sequence specific for particular regions or tissues of plants.

It is also possible to use an inducible promoter advantageously chosen from the promoters of phenylalanine ammonia lyase (PAL), of HMG-CoA reductase (HMG), of chitinases, of glucanases, of proteinase inhibitors (PI), of genes of the family. PR1, nopaline synthase (nos) or the vspB gene (Table 3 US 5,670,349), the HMG2 promoter (US 5,670,349), the apple β-galactosidase (ABGl) promoter or the promoter of apple amino cyclopropane carboxylate synthase (ACC synthase) (WO 98/45445).

According to the invention, it is also possible to use, in combination with the above promoters, other regulatory sequences, which are located between the promoter and the coding sequence, such as transcription activators ("enhancer"), such as for example the transcription activator of the tobacco mosaic virus (VMT) described in application WO 87/07644, or of the tobacco etch virus (VET) described by Carrington & Freed.

In the chimeric gene according to the invention, the functional terminator regulatory sequence in plant cells and plants is also advantageously heterologous with respect to the sequence coding for the factor MYB30. As a terminating regulatory or polyadenylation sequence, it is possible to use any corresponding sequence of bacterial origin, such as for example the terminator nos of Agrobacterium tumefaciens, of viral origin, such as for example the terminator of

^' CaMV 35 S, or of vegetable origin, such as for example a histone terminator as described in application EP 0 633 317. The present invention also relates to a cloning or expression vector for the transformation of a host organism containing at least one chimeric gene as defined above. This vector comprises, in addition to the above chimeric gene, at least one origin of replication. This vector can consist of a plasmid, a cosmid, a bacteriophage or a virus, transformed by the introduction of the chimeric gene according to the invention. Such transformation vectors as a function of the host organism to be transformed are well known to those skilled in the art and widely described in the literature.

Preferably, the vector for transforming plant cells or plants according to the invention is a plasmid.

The subject of the invention is also a process for transforming plant cells or plants, by integration of at least one chimeric gene as defined above, a transformation which can be obtained by any suitable known means, amply described in the literature specialized and in particular the references cited in the present application, in particular by the vector according to the invention.

A series of methods involves bombarding cells, protoplasts or tissues with particles to which the DNA sequences are attached. Another series of methods consists in using as a means of transfer into the plant a chimeric gene inserted into a Ti plasmid of Agrobacterium tumefaciens or Ri of Agrobacterium rhi∑ogenes.

Other methods can be used such as micro-injection or electroporation, or even direct precipitation using PEG.

Those skilled in the art will choose the appropriate method depending on the plant cell or the plant to be transformed. These include patents and applications for

. following patent: US 4,459,355, US 4,536,475, US 5,464,763, US 5,177,010, US 5,187,073,

EP 267,159, EP 604,662, EP 672,752, US 4,945,050, US 5,036,006, US 5,100,792, US 5,371,014, US 5,478,744, US 5,179,022, US 5,565,346, US 5,484,956, US 5,508,468, US 5,538,877, US 5,554,798, US 5,489,520, US 5,510,318, US 5,204,253, US 5,405,765, EP 442 174, EP 486 233, EP 486 234, EP 539 563, EP 674 725, WO 91/02071 and WO 95/06128.

The present invention also relates to a plant cell or a transformed plant comprising a chimeric gene according to the invention defined above. According to a particular embodiment of the invention, the plant cell or the transformed plant comprises at least one other heterologous gene coding for a particular peptide or protein of interest. The chimeric gene according to the invention and the other heterologous gene (s) may have been introduced into the host organism simultaneously by means of the same vector comprising them, or by means of several vectors, or in a sequenced manner by means of several vectors , or by crossing several host organisms, plant cells or plants, each comprising a heterologous gene.

By "plant cell" is meant according to the invention any cell originating from a plant and which can constitute undifferentiated tissues such as calluses, differentiated tissues such as embryos, parts of plants, plants or seeds.

By heterologous gene is meant according to the invention any gene introduced artificially into the host organism, and more particularly artificially integrated into its genome, the methods allowing this introduction or integration possibly being those described above, the content of the references cited being incorporated herein by reference. The heterologous gene other than the chimeric gene according to the invention may be a gene comprising a coding sequence and the regulatory elements 5 'and 3' of said coding sequence not modified with respect to the natural gene, artificially reintroduced into the genome a host organism which may be of the same species as that from which the gene was isolated, or of a different species. The heterologous gene can also be a chimeric gene comprising a coding sequence of plant, bacterial, fungal, viral or animal origin, under the control of functional regulatory elements in the host organism, different from those naturally linked functionally to the sequence coding.

The coding sequence of the above heterologous gene can comprise any sequence coding for a protein of interest which it is desired to express in a cell plant or plant other than the transcription factor MYB30.

It may be a gene coding for a selection marker as well as a gene conferring on the transformed plant new agronomic properties, or a gene for improving the agronomic quality of the transformed plant. Selection Markers

Among the genes coding for selection markers, there may be mentioned antibiotic resistance genes, herbicide tolerance genes (bialaphos, glyphosate or isoxazoles), genes coding for easily identifiable reporter enzymes such as the enzyme GUS, genes coding for pigments or enzymes regulating the production of pigments in transformed cells. Such selection marker genes are described in particular in patent applications EP 242 236, EP 242 246, GB 2 197 653, WO 91/02071, WO 95/06128, WO 96/38567 or WO 97/04103. Genes of interest Among the genes conferring new agronomic properties on transformed plants, there may be mentioned the genes conferring tolerance to certain herbicides, those conferring resistance to certain insects, those conferring tolerance to certain diseases, etc. Such genes are described in particular in patent applications WO 91/02071 and WO 95/06128.

Herbicide tolerance Among the genes conferring tolerance to certain herbicides, mention may be made of the Bar gene conferring tolerance to bialaphos, the gene coding for an appropriate EPSPS conferring resistance to herbicides having EPSPS as target such as glyphosate and its salts (US 4,535,060, US 4,769,061, US 5,094,945, US 4,940,835, US 5,188,642, US 4,971,908, US 5,145,783, US 5,310,667, US 5,312,910, US 5,627,061, US 5,633,435, FR 2,736,926), the gene encoding glyphosate5, oxidized5,4 or a gene coding for a HPPD conferring tolerance to herbicides targeting HPPD such as isoxazoles, in particular isoxafutole (FR 95 06800, FR 95 13570), diketonitriles (EP 496 630, EP 496 631) or triketones, especially sulcotrione (EP 625 505, EP 625 508, US 5,506,195). Such genes coding for HPPD conferring tolerance to herbicides targeting HPPD are described in the patent application. Resistance to Insects Among the proteins of interest conferring new properties of resistance to insects, mention will be made more particularly of the Bt proteins widely described in the literature and well known to those skilled in the art. Mention will also be made of proteins extracted from bacteria such as Photorabdus (WO 97/17432 & WO 98/08932). Resistance to Diseases Among the proteins or peptides of interest which confer new disease resistance properties, mention will be made in particular of chitinases, glucanases, Poxalate oxidase, all these proteins and their coding sequences being widely described in the literature, or even antibacterial peptides. and / or antifungals, in particular peptides of less than 100 amino acids rich in cysteines such as thionines or plant defensins, or else fungal eliciting peptides, in particular elicitins (Kamoun & al., 1993; Panabières & al., 1995). Change in quality

One can also cite the genes modifying the constitution of the modified plants, in

- Particularly the content and quality of certain essential fatty acids (EP 666 918) or also the content and quality of proteins, in particular in the leaves and / or seeds of said plants. Mention will in particular be made of the genes coding for proteins enriched in sulfur amino acids (Korit, A.A. & al., Eur. J. Biochem. (1991) 195, 329-334; WO 98/20133;

WO 97/41239; WO 95/31554; WO 94/20828; WO 92/14822).

According to an advantageous embodiment of the invention, the heterologous gene other than the chimeric gene according to the invention is a gene coding for a protein or peptide of interest conferring new properties of resistance to diseases. The present invention also relates to plants containing transformed cells as defined above, in particular plants regenerated from the transformed cells and their progeny. The regeneration is obtained by any suitable process which depends on the nature of the species, as for example described in the references above. The present invention also relates to genetically transformed plants modified, in the genome of which the chimeric gene according to the invention is integrated in a stable manner and transmissible by sexual reproduction.

The present invention also relates to plants obtained by crossing the regenerated plants above with other plants. It also relates to the seeds of transformed plants.

The term "plant" according to the invention means any differentiated multicellular organism capable of photosynthesis, in particular monocotyledons or dicotyledons, more particularly crop plants intended or not for animal or human food, such as corn, wheat, rice, sugar cane, beet, tobacco, cotton, rapeseed, soybeans, etc., more particularly dicotyledonous plants, in particular cotton, rapeseed or soybeans, and preferably cruciferous plants such as rapeseed.

The present invention also relates to a method making it possible to improve the resistance of plants to pathogenic aggressions, in particular fungal, said method consisting in overexpressing in said plants a transcription factor MYB30. By "overexpressing" is meant according to the invention an expression of the factor MYB30 additional to the natural expression of the factor MYB30 found natively in plants.

Advantageously, the overexpression is ensured constitutively, or not induced in a given tissue of the plant, so as to ensure a constant overexpression of the factor MYB30 in the tissues likely to be infected by a pathogenic agent.

The overexpression is preferably ensured by the integration into the genome of the plant of a chimeric gene according to the invention as defined above, in particular a chimeric gene whose promoter regulatory sequence is chosen from constitutive promoters such as promoters histone as described in application EP 0 507 698, the rice actin promoter (US 5,641,876) the 19S or 35S promoter of the cauliflower mosaic virus (CaMV 19S or 35 S), and the specific promoters particular regions or tissues of plants.

Advantageously, the plant is a transformed plant according to the invention as defined above. The present invention also relates to a process for treating transformed plants according to the invention with an agrochemical composition comprising them.

The present invention also relates to a method for cultivating transformed plants according to the invention, the method consisting in planting the seeds of said transformed plants in an area of a field suitable for the cultivation of said plants, to be applied to said surface of the said field an agrochemical composition, without substantially affecting said seeds or said transformed plants, then harvesting the cultivated plants when they reach the desired maturity and optionally separating the seeds from the harvested plants. By agrochemical composition is meant according to the invention any agrochemical composition comprising at least one active product having one of the following activities, herbicide, fungicide, bactericide, virucide or insecticide.

According to a preferred embodiment of the process according to the invention, the agrochemical composition comprises at least one active product having at least one fungicidal and / or bactericidal activity, more preferably having an activity complementary to that of the product produced by the chimeric gene expressing the factor MYB30 in plants transformed according to the invention.

Preferably, the spectrum of activity of the fungicidal compounds is complementary to the spectrum of resistance to pathogenic agents conferred by the chimeric gene according to the invention.

By complementary spectrum is meant according to the invention an activity spectrum for the chimeric gene according to the invention distinct from the activity spectrum of the compounds, or an activity spectrum relating to identical infectious agents but allowing identical control or improved for lower doses of application of fungicidal compounds. The expression of the chimeric gene according to the invention in transformed plants has shown, in addition to improved resistance to fungal attack without phenotype of the “necrosis” type, “spontaneous lesions” or also altered for HR, the possibility of obtaining a slowing down the phenomenon of aging of certain tissues such as the leaves. This property is particularly important in a plant cultivation strategy involving the creation of a high biomass, in particular for animal feed or human, or in the case of plants genetically modified to produce proteins of high added value, such as enzymes of the food additive type, for example vitamins, of the vaccine type or for therapeutic purposes.

The use of specific promoters of certain tissues will delay the senescence of said tissues. For example, a light-dependent promoter, such as a promoter of the small subunit of the plant RuBisCo, will be able to direct this property of delaying senescence in only green tissues such as the leaves, allowing in particular the increase in the biomass.

It is understood that for the present invention, the expression of an antisense gene MYB30 making it possible to obtain the opposite effects, such as a reduction in resistance to pathogens or an acceleration of senescence.

The chimeric antisense genes corresponding to the sense genes defined above, that is to say for which the sequence coding for a factor MYB30 is replaced by the corresponding antisense sequence, like the corresponding plant cells or transformed plants also form part of the present invention. .

The examples below illustrate the invention, without however seeking to limit its scope.

All the methods or operations described below in these examples are given by way of examples and correspond to a choice made from among the different methods available to achieve the same result. This choice does not affect the quality of the result and therefore, any suitable method can be used by those skilled in the art to achieve the same result. Most of the methods for engineering DNA fragments are described in "Current Protocols in Molecular Biology" Volumes 1 and 2,

Ausubel F.M. et al or in Sambrook et al 1989. Abbreviations

ACO ACC Oxydase

DNA Deoxyribonucleic acid

T-DNA transfer DNA

AMV Avian Myeloblastosis Virus RNA Ribonucleic Acid AtMYB30 Gene ^ Arabidopsis thaliana "MYB30" AtMYB30 Protein from the AtMYB 30 bp gene base pair (base pairs) CaMV Cauliflower Mosaic Virus Cfu Colony Forming Unit

HR Hypersensitive Response kb kilo base pair Isd lesion simulating disease resistance PAL Phenylalanine-ammonia-lyase PCR Polymerase Chain Reaction

P.s.t. Pseudomonas syringae pv. tomato ROS Reactive Oxygen Species

X.c.c. Xanthomonas campestris pv. campestris

Material and methods

1. Plant material

The Col-0 (and transgenic lines derived therefrom), Sf-2 and Ws-0 ecotypes of Arabidopsis thaliana L. (Heynh) and the mutants lds3, lsd4 and lsd5 (Dietrich et al, 1994) are cultivated under conditions previously described (Lacomme and Roby, 1996). In general, 5-week-old plants are used in the experimental work. For Isdl, the plants are cultivated under the conditions described above (Jabs et al, 1996). The procedure used with the lsd5 mutant and the suppressor lines is slightly different. Seeds for sterile culture are surface sterilized in 12% bleach for 20 min, washed 5 times in sterile distilled water and sown on Murashige and Skoog medium (MS) containing 0.8% agar and 1% sucrose. The conditions during sterile growth are 16 hours a day in a culture chamber with a light intensity of 0.13 mE / s / m2. The conditions inducing the appearance of lesions correspond to a higher light intensity (1.52 mE / s / m2). Cell suspensions are cultured as previously described (Lacomme and Roby, 1996). The cultivar Bottom Special (BS) of Nicotiana tάbacum L. and the lines transgenic derivatives are cultivated as previously described (Pontier et al, 1994). 2 bacterial strains

2.1 Escherichia coli

The bacteria used for the generation of the various constructs are E. coli, strain DH5α. They are cultured at 37 ° C. on LB medium (Miller, 1972) in the absence or in the presence of antibiotics, as the case may be.

2.2 Agrobacterium tumefasciens

The strains of Agrobacterium tumefasciens used to transform are the strain

LBA4404 (Bevan, 1984) in the case of Tobacco, and the strain GV3101 (Koncz and Schell, 1986) in the case of Arabidopsis. They are cultured at 28 ° C. on a LB medium supplemented with antibiotics corresponding to the genome of bacteria, to "helper" plasmids and to the plasmids containing the genetic constructs as appropriate.

2.3 Ralstonia solanacearum

The wild avirulent GMI1000 and virulent K60 strains of R. solanacearum are respectively responsible for the development of an observable HR from 24 hours and of the disease from 3 days on the leaves of Tobacco variety Bottom Special (BS). These strains are cultivated for 3 days at 28 ° C. on a Petri dish containing BGT medium (Boucher et al,

1985), then 20 ml of liquid BGT medium are inoculated with a colony isolated from this dish. After a 12 h incubation at 28 ° C with shaking (200 rpm), this culture is centrifuged for 5 min at 6000 g at 28 ° C. The resulting pellet is washed with 10 ml of sterile water, and vigorous stirring resuspends the pellet. A new centrifugation, under the same conditions as before, allows the bacteria to be pelleted again. The new pellet is taken up in 5 ml of sterile water, and a reading of the optical density at 600 nm is carried out on a dilution to one tenth in sterile water. The ratio 1 DO ₆ oo = 1.10 ⁹ cfu / ml makes it possible to evaluate the concentration of bacteria. In order to inoculate the tobacco plants, the bacterial suspension is adjusted to 5.10 ⁶ , 1.10 ⁷ and 5.10 ⁷ cfu / ml for the strain GMI1000, and 5.10 ⁷ cfu ml for the strain K60.

2.4 Xanthomonas campestris pv. campestris

The strain 147 of Xanthomonas campestris pv. campestris (Xcc) is responsible for the development of an observable HR from 36 hours on the leaves of the ecotype Colombia-0 of Arabidopsis when the inoculum is 1.10 ⁸ cfu / ml. It is cultivated for 3 days at 28 ° C. on a Petri dish containing Kado medium (Kado and Heskett, 1970) supplemented with spectinomycin (100 μg / ml), then 20 ml of liquid Kado medium (spectinomycin 100 μg / ml) are sown with a colony isolated from this box. After a 12 h incubation at 28 ° C with shaking (200 rpm), this culture is centrifuged for 5 min at 6000 g. The resulting pellet is washed with 10 ml of sterile water, and vigorous stirring resuspends the pellet. A new centrifugation, under the same conditions as before, allows the bacteria to be pelleted again. The new pellet is taken up in 5 ml of sterile water, and a reading of the optical density at 600 nm is carried out on a dilution to one tenth in sterile water. The ratios 1 OD ₆₀ o = 1.1O ⁹ cfu / ml makes it possible to evaluate the concentration of bacteria, and to adjust the bacterial suspension to 1.10 ⁸ cfu / ml in order to inoculate the Arabidopsis plants.

3 Bacterial inoculations of plants

3.1 Inoculation of Tobacco by Ralstonia solanacearum Inoculations are carried out manually on the underside of the youngest leaves having reached their maximum size (approximately 30 cm long by 20 cm wide) on plants eight weeks old, using a sterile 1 ml syringe without needle, and this on an area of about 5 cm ² . The large area of the leaves used allows several inoculations on the same leaf. 3.1.1 Pathogenicity test of the avirulent strain GMI 1000

Inoculations using three inocula (5.10 ⁶ , 1.10 ⁷ and 5.10 ⁷ cfu / ml) are carried out on the two sides of the central rib of two leaves of two plants for each line tested. The inoculated areas are identified by delimiting them with a black marker. The appearance of symptoms over time is noted by visual appreciation of their severity and extent. A notation being essential, we established a hierarchy in the severity of the symptoms, according to the following scale:

1: Appearance of small groups of cells in "collapse" in the inoculated areas. 2: Appearance of larger areas in "collapse" in the inoculated areas. 3: The whole inoculated zones are in "collapse". The results are expressed on the basis of the sum obtained for each time and for each line. The maximum being 24 (index 3, 2 zones for 2 leaves of 2 plants), the results are finally expressed as a percentage of this maximum. Plotting this data on a time graph makes it possible to compare the speed of onset of symptoms, as well as their severity. 3.1.2 Virulent strain K60

The inoculations are carried out with an inoculum of 5.10 ⁷ cfu / ml under the same conditions as for the avirulent strain GMI1000. Symptoms are observed over time. These being very different between the wild BS line and certain transgenic lines, it was not possible to establish a gravity scale, as in the case of the GMI 1000 strain.

3.2 Inoculation of Arabidopsis by Xanthomonas campestris pv. campestris

Before inoculating Arabidopsis plants, these are placed in a high humidity atmosphere for 16 to 18 hours, so as to cause the opening of the stomata. Inoculation is carried out on the underside of the leaves, on either side of the central vein, on five adult leaves of plants four weeks old, and this over a total area equivalent to one third of the total area of the leaf . After inoculation, the plants are replaced in an atmosphere with high humidity for 48 h to promote infection.

3.3 Measurement of bacterial growth in planta (IGC) The measurement of bacterial growth in planta is based on the enumeration over time of bacteria present in tissue samples from inoculated plants. This type of measurement was carried out during inoculations of Tobacco by the bacteria R. solanacearum, with the avirulent strain GMI 1000 and the virulent strain K60 expressing resistance to rifampicin. For each line and each kinetic point, a 0.5 cm ² disc is taken from six different eight-week-old plants with a punch in the inoculated zone, as well as in the tissues immediately around in the case of the strain virulent K60. These six discs are ground in 1 ml of sterile water in a mortar using a pestle, and this material is rinsed in 1 ml of sterile water. This suspension is subjected to a series of dilutions in sterile water, so as to obtain, according to experiments, dilutions ranging from 10 to 100,000. One hundred microliters of these dilutions are spread on dishes Petri dish containing solid BGT medium (1.5% Agar) supplemented with rifampicin (50 μg / ml) in order to inhibit the growth of parasitic microorganisms, and the dishes are placed in an incubation chamber at 28 ° C. in order to allow growth of R. solanacearum bacteria. Two days later, colonies of R. solanacearum are counted. The results are expressed in log10 (cfu / cm ² ) (means and standard deviations). 4 Molecular biology methodologies

4.1 RNA extraction and Northern analysis

Total RNA extractions and Northern analyzes were performed as described in Lacomme and Roby (1996). The probes were obtained from a PstI fragment of the hsr203J gene from Tobacco in the case of hsr203J, from a PstI fragment of the str246C gene from Tobacco in the case of str246C, from an EcoRI / Xhol fragment from the ACC Oxydase gene Nt-ACOl of Tobacco in the case of ACO, and of a BglI / Xbal fragment of the plasmid pBEFl-a (gift from Bernard Lescure) containing the EFI-a gene of Arabidopsis in the case of EFI-a. Filters are hybridized at 42 ° C with the probes in a 6XSSC solution, 0.5%

SDS, 5X Denhardt's solution and 0.1 mg / ml denatured DNA from salmon sperm. The filters are then washed twice for 15 min with 2XSSC, 0.1% SDS at room temperature and twice for 20 min with 0.1XSSC, 0.1% SDS at 55 ° C. The DNA fragments corresponding to the full length cDNA clones were used as a probe, in the case of AtMYB30 and RaRI36; and a HindIII fragment of the PAL-1 gene (Dong et al, 1991) was used in the case of PAL.

4.2 Extraction of plant genomic DNA

A leaf sample (0.2 g) is ground in liquid nitrogen. The powder obtained is transferred to 1 ml of extraction buffer (containing, for 100 ml: 2 g of CTAB; 10 ml of Tris-HCl IM pH8; 28 ml of 5M NaCl; 4 ml of 0.5M EDTA pH8; 0.5 ml of β-mercaptoethanol added extemporaneously) and the suspension is incubated for 20 min in a water bath at 65 ° C. After which, 600 μl of chloroform are added, the samples are then vigorously stirred for 15 min at room temperature, then centrifuged at 10,000 g for 10 min. The aqueous phase is recovered, and added with 600 μl of isopropanol. Immediately afterwards they are centrifuged at 10,000 g for 20 seconds. The pellet is recovered and washed with 70% ethanol at room temperature. After centrifugation for 10 min at 10,000 g, the supernatant is removed and the pellet is resuspended in 50 μl of water. An aliquot of a tenth dilution in sterile water will be used during a PCR-type reaction for a final mixture of 25 μl. 4.3 Cloning and sequencing of the cDNA clone

The AtMYB30 cDNA was cloned as previously described (Lacomme and Roby, 1996). Its nucleotide sequence was determined on the two strands by the dideoxynucleotide termination method according to the Sequenase kit (USB, Amersham). The results were analyzed using GCG (University of Wisconsin) programs. '4.4 Southern analysis

The DNA extracted from plants according to the protocol described by Saghai-Maroof et ai (1984) is digested with restriction enzymes, separated on a 0.8% agarose gel and transferred to a Hybond N + membrane (Amersham). Hybridization is carried out as described above (Lacomme and Roby, 1996) with a _4t_VT_550-3'-specific probe labeled with ³² P and with a probe corresponding to the MYB domain. 4.5 RT-PCR

The RNA extracts are treated with DNAse I, RNAse-free (Boerhinger Manheim) and subjected to phenol / chloroform extraction. A control PCR is carried out to verify the absence of genomic DNA. A first strand of cDNA is synthesized from 2.5 to 20 μg of total RNA without DNA, using a reverse transcriptase Super script II RNAse H- (BRL), according to the instructions of the producer. Β-tubulin 4 (Marks et ai, 1987) is used as a constitutive internal control and the cDNAs of AtMYB30, or of β-tubulin 4 and of PR1 (Uknes et al, 1992) are amplified by using the specific probes mentioned below. below during the same PCR reaction: GCTTACGAAT CCGAGGGTGC C and

GTCCAGTGT CTGTGATATT GCACC for β-tubulin 4. GATTGGTATA ACTGAACAAA CATGG and GCCCAAGACA GTCCTCAAGA C for PRl.

All PCR reactions are carried out with a Robocycler gradient 96 (Stratagene). The work is carried out twice in two independent experiments. 4.6 Polymerase Chain Reaction (PCR)

The compositions and concentrations of the various components of the reaction are those indicated by the supplier of the enzyme Taq polymerase (BRL). The temperature and time conditions used for the PCR reactions are as follows:

Temperature Time Number of cycles

95 ° C 3 min

72 ° C 45 s 1

48 ° C 45s

95 ° C 1 min

48 ° C 45 s 32

72 ° C 45 s

72 ° C 10 min 1

4.7 Generation of constructions

Transformation experiments on E. coli bacteria are carried out using the thermal shock method (Sambrook et al, 1989). All the plasmids are extracted by mini-preparation according to the method of alkaline lysis (Sambrook et al, 1989) or by Maxiprep (Qiagen). The DNA digestion experiments are carried out with Promega restriction enzymes, and those for DNA purification on agarose gel (1%) use the Jetsorb kit (Genomed). The dephosphorylation of the ends of the DNA fragments is carried out by alkaline shrimp phosphatase (Pharmacia). All the bacteria described are E. coli of strain DH5α, and the transformed bacteria are selected on LB medium (Miller, 1972) supplemented with ampicillin (50 μg / ml) or kanamycin (50 μg / ml) as the case may be.

4.7.1 Control constructions (pBIl l l), direction (pBIM131) and antisense (pBIW13)

The plasmid extracted from the clone RaR015, containing the cDNA of the AtMYB30 gene (Lacomme, 1996), was prepared by mini-preparation and used during a PCR experiment using the oligonucleotides MYB5 and MYB6 (FIG. 1). The resulting 999 bp amplifier contains the entire coding region of the AtMYB30 gene, and the use of this pair of oligonucleotides made it possible to insert, by point mutagenesis, a Hpal restriction site at the two ends of the fragment. This fragment was purified and cloned into the vector pCRTMII (Invitrogen). The insertion was verified by digestion of the plasmid from isolated colonies using the enzymes Hpal, EcoRI, and SacII / Hpal. A colony was retained, and the corresponding plasmid baptized pCRM2_4 (FIG. 1). The sequence of the inserted fragment was completely read three times on both strands, and no mutation due to PCR was detected inside the coding region of the AtMYB30 gene. Hpal digestion of this plasmid, followed by its purification on agarose gel, resulted in the obtaining of a 935 bp fragment with blunt ends, and containing the entire coding region of the AtMYB30 gene. This fragment, called "ORF AtMYB30", was subsequently used in cloning experiments with a view to obtaining the constructs used during this work (FIG. 1).

The plasmid pBI221 (Clontech) was subjected to a double Sac1 / Smal digestion (FIG. 1). The sac-digested end was made blunt by the action of the Kleenow fragment of the DNA Polymerase I enzyme. In order to facilitate the purification of the 3.83 kb fragment and to avoid the co-purification of the fragment of 1, 87 kb (corresponding to the coding region of the GUS gene), the latter is digested into two new fragments by the enzyme SnaBI. Thereafter, the ends of the 3.83 kb fragment are dephosphorylated in order to avoid recircularization of the vector on itself during the ligation experiments. Thus, a 3.83 kb fragment (called "pBI221-GUS") is obtained corresponding to the linearized plasmid pBI221, devoid of the coding region of the GUS gene, and the blunt ends of which can accommodate the "ORF AtMYB30" fragment.

The ligation experiments using the vector "pBI221-GUS" and the fragment "ORF AtMYB30", then those of transformation of bacteria, led to obtaining several hundred colonies isolated by selection on ampicillin. 94 different colonies were subjected to a PCR experiment using the oligonucleotides Ml 3-20 and M13Rev, and 74 of them led to the amplification of a fragment of expected size (1995 bp). In order to verify the size and orientation of the "ORF AtMYB30" fragment, their plasmid DNA was subjected to two digestions (EcoRI / HindIII and PstI). Analysis of the results showed that one colony had a plasmid whose orientation was "sense", and that 25 colonies had a plasmid whose orientation was "antisense". The "sense" and "antisense" plasmids were named "pB__M231" and "pBIW23" respectively (FIG. 1). Their nature was verified by digestion (EcoRI / HindlII and PstI), and their sequencing on the two strands three times (oligonucleotides M13-20, M13Rev, MYB2_32, MYB2_5, MYB3_5) made it possible to verify that no mutation was appeared in the coding region of the AtMYB30 gene, and that it was correctly inserted in order to be transcribed in the plasmid pBIM231. In order to subclone these constructs into a binary vector, the plasmids pBI231 and pBIW23 were digested with the enzymes EcoRI and HindIII, and the fragments were purified on agarose gel.

The binary plasmid pBI121 (Clontech, (Jefferson et al, 1987)) was also subjected to digestion with the enzymes EcoRI and HindIII. The 10 kb fragment was purified and dephosphorylated, then used in ligation experiments with the 2.3 kb fragment originating from the plasmids pB_M231 or pBIW23. The binary plasmid containing the "sense" construct was named "pBIM131" and that containing the "antisense" construct, "pBIW13". Their sequencing on the two strands revealed no anomaly in the sequence of the coding region of the AtMYB30 gene, nor in the junctions created during the generation of these plasmids. Finally, in order to generate a control construct (not comprising the coding region of the AtMYB30 gene), the binary plasmid pBI121 was subjected to digestion with the enzymes Sac1 and SnaBI in the presence of the Kleenow fragment of the DNA Polymerase I enzyme, then digestion with the restriction enzyme Smal. The ligation of this fragment allowed its recircularization, and the new plasmid was named "pBIl ll". Its sequence between the 35S promoter and the NOS terminator, fully read three times, is identical to the sequence of pBI121 for these two elements. 4.7.2 Construction pGXM1 33 The plasmid pGEX-2T (Pharmacia), chosen for the production of the recombinant protein AtMYB30 in E. coli was subjected to digestion with the restriction enzyme Smal, and after dephosphorylation, was used during of a ligation experiment with the "ORF AtMYB30" fragment. A plasmid containing the coding region of the AtMYB30 gene in "sense" orientation was retained. Its restriction profile was checked, and the nucleotide sequence in and around the coding region of the AtMYB30 gene was read on the two strands three times (oligonucleotides MYB2_5, MYB2 32 and MYB3 5), demonstrating the absence of mutations vis-à-vis the original sequence. The corresponding plasmid was named "pGXM133".

5 Production, purification of the recombinant fusion protein GST-AtMYB30 in E. coli, and detection by Western analysis For the analysis of transgenic lines over or under expressing the gene

AtMYB30, we produced a recombinant protein in E. coli, which was purified, before being used for the immunization of rabbits. Analysis of their immune serum revealed that it contained antibodies to the recombinant fusion protein GST-AtMYB30. 5.1 Production and purification of the recombinant fusion protein GST-AtMYB30

The coding region of the AtMYB30 gene was cloned into the expression vector pGEX-2T (Pharmacia), and the resulting plasmid, pGXM133, was used to transform E. coli bacteria. Induction of the synthesis of the GST- fusion protein

AtMYB30, as well as its purification, were carried out according to the suppliers' instructions. However, it was not possible to produce this soluble fusion protein in sufficient quantities to purify the AtMYB30 protein by cleavage using thrombin or Factor Xa, despite our efforts to adapt. of the protocol under more favorable conditions (bacterial strain deficient in proteases, culture temperature lowered from 37 ° C to 23 ° C). This fusion protein being particularly reluctant to solubilization, we opted for its purification on acrylamide gel of SDS-PAGE type, after the elimination of the major part of the insoluble contaminating proteins by successive washings using added buffers. from SDS. The acrylamide gel fragments containing the fusion protein were used to obtain two batches of rabbit immune serum containing polyclonal antibodies (Eurogentech). 5.2 Western analysis

Western blot type experiments are carried out according to Sambrook et al. (1989). The analyzed samples correspond to extracts containing the soluble proteins of four week old plants (Tobacco and Arabidopsis) cultivated in compost. An anti-GST-AtMYB30 immune serum (from the final bleeding) diluted to 5000th, as well as anti-rabbit antibodies as secondary antibodies, were used. The revelation is performed using the alkaline phosphatase method, an enzyme coupled with secondary antibodies.

An immunodetection experiment of the recombinant proteins GST and GST-AtMYB30 made it possible to determine the titer of use of the antibodies. Indeed, a dilution to 5,000th makes it possible to specifically detect the protein GST-AtMYB30, while the recombinant protein GST, purified by affinity on the glutathione-sepharose column (Pharmacia) and supplied by Benoît Ranty (UMR UPS / CNRS 1456), n is no longer detected at this dilution, in a range from 0.002 μg to 2 μg. On the other hand, the GST-A.MYB30 fusion protein is detected as soon as its quantity deposited on the gel exceeds 0.2 μg. These are the conditions that were used to analyze the transgenic lines of Tobacco and Arabidopsis.

6 Generation and characterization of transgenic lines of Tobacco and Arabidopsis

6.1 Processing methods Arabidopsis thaliana is processed using the soaking method (derived from

(Bechtold et al, 1993)) flower stalks in a solution containing the Agrobacterium tumefasciens bacteria previously transformed by the plasmids pBIl l l, pBIM131 or pBIW13 by the thermal shock method. Agrobacteria are cultivated on a Petri dish on LB selective medium (containing the antibiotics specific to the agrobacterium and to the plasmid carrying the construct) at 28 ° C. After 3 days of culture, an isolated colony is placed for a few hours in preculture in 50 ml of selective LB medium with stirring at 28 ° C., and this preculture is used to seed a culture of 1 liter of selective LB medium with stirring at 28 ° vs. The agrobacteria are recovered by centrifugation and resuspended in 1 liter of MS solution containing sucrose (50 g / 1) and Silouet (50 μl 1), so that the optical density of the solution read at 600 nm is between 1 , 8 and 2. The Arabidopsis flower stalks are soaked for 30 seconds in this solution and the plants are placed in "aracons". When they reach maturity, the seeds are harvested.

Tobacco is transformed according to the leaf disc method described by Horsch et al. (1984). The transformed plants are selected on solid MS medium (0.8% Agar) supplemented with kanamycin (100 μg / ml) and carbenicillin (400 μg / ml). Tl transgenic plants are brought to flowering and their self-fertilization makes it possible to obtain several thousand seeds.

6.2 Genetic characterization of transforming lines The estimation of the number of T-DNA insertion events in transformed plants of Arabidopsis and Tobacco is carried out by a test of plant growth on an MS agar medium supplemented with kanamycin. (50 μg / ml for Arabidopsis, 400 μg / ml for Tobacco). In fact, T-DNA contains, in addition to the control, sense or antisense constructs, a gene responsible for the production of the protein Nopaline synthase II or NPT-II, responsible for the detoxification of kanamycin. The percentage of resistant plants in an individual seed population is determined from 10 days after sowing for Arabidopsis, and 15 days after sowing for Tobacco. This count makes it possible to estimate, according to the Mendelian laws of the segregation of dominant characters, the number of T-DNA insertion events in the genome of plants of generation Tl for each line. For this, 200 seeds from first generation plants (Tl) are sown individually, and plants resistant to kanamycin are counted. A test of κ ² is then carried out to test the validity of the estimate of the number of insertions.

6.2.1 Transforming Tobacco Lines Experiments with transforming Tobacco using the control (pBIl 11), sense (pBIM131) and antisense (pBIW13) constructs led to the production of 7, 19 and 14 independent lines, respectively.

The nomenclature used for the denomination of the different lines obtained is explained using the following example: the line "pBIM131-40A" comprises the construction meaning pBIM131, and represents the first plant (A) coming from the leaf disc number 40.

Their genetic analysis shows that most transgenic lines have undergone only one T-DNA insertion event: this is the case for 71% (5 of 7) of the control lines, 68% (13 out of 19) sense lines, and 57% (8 out of 14) of antisense lines. Two control lines (29%) presented two insertion events, as did three sense lines (16%) and four antisense lines (28%). Three T-DNA insertion events are estimated for an antisense line (7%), but for no sense line or any control line.

Among all the lines obtained, only one antisense line (pBIW13-15A) does not exhibit Mendelian segregation for resistance to kanamycin (55% of ^" resistant plants ^" ). However, a bias may have been insinuated in the counting of plants resistant to kanamycin since they are small and pale, and difficult to distinguish from sensitive plants An identical test with lower concentrations of kanamycin (100, 200 and 300 μg / ml) in the medium led to the same difficulties. It is therefore likely that the T-DNA was inserted in a part of the genome that is not easily accessible to the transcription machinery in this line, leading to a very reduced production of the transgene NPTII and to a difficult detoxification of kanamycin, origin of a resistance to kanamycin reaching the limit of the test used. On the other hand, the sense line pBIM131-15A has a very low germination rate, and it was necessary to sow very many seeds to be able to count plants resistant to kanamycin sensitive plants among 200 plants that have germinated. As a result, these last two lines were not used for the rest of the manipulations.

6.2.2 Transforming lines of Arabidopsis

The transformation experiments of Arabidopsis by the control (pBIl 11), sense (pB_M131) and antisense (pBIW13) constructs led respectively to obtaining 2, 3 and 7 independent lines.

The nomenclature used for the denomination of the different lines obtained is explained using the following example: the line "pBIM131-A2" has the construction meaning pBIM131, and represents the second plant (2) resulting from the first experiment (A ) transformation of Arabidopsis. No multiple T-DNA insertion events were detected for the Arabidopsis transgenic lines. Due to the small number of lines obtained, the generation of other lines has been undertaken, and they are being selected.

6.3 Molecular characterization of transforming lines

In order to verify the insertion of each of the constructs pBIl ll, pBIM131 and -pBIW13 into the genome of the transforming plants of Tobacco and Arabidopsis, a PCR test is done. It uses the genomic DNA of the line to be tested as a template, and a pair of oligonucleotides specific to each construct as primers. FIG. 2 shows the location of the oligonucleotides used for these tests on the control (pBI11), sense (pBIM131) and antisense (pBIW13) constructs. Thus the use of the pair FIN35S / NOS-TRev provides a 311 bp fragment only with the plasmid pBIl 1 or a plant transformed by the control construct, the use of the pair FIN35S / RTMYB3 provides a fragment of 550 bp only with the plasmid pBIM131 or a plant transformed by the sense construct, and the use of the pair FIN35S / RTMYB5 provides a fragment of 1050 bp only with the plasmid pBIW13 or a plant transformed by the antisense construct. All the other uses of these couples do not lead to any amplification.

The verification of the insertion of the T-DNAs for each transgenic line of Tobacco and Arabidopsis was carried out on their genomic DNA, using each of the three plasmids carrying the three constructs as positive controls, and the genomic DNA of the line. wild type BS or wild type Col-0 as negative controls. In Figure 3, the results obtained with some of the lines are reported. Thus the lines pBIl 11-9A and pBIl 11-23A from Tobacco and the lines pBIl 11-A1 and pBIl 11-A2 from Arabidopsis carry well the control construction pBIl ll, the lines pBIM131-27D, pBIM131-27F, pBIM131- 4C , pBIM131-13C, pBIM131-40A, pB_M131-47A and pBIM131-50A from Tobacco and the lines pBIM131-Al, pBIM131-A2 and pBIM131-A3 from Arabidopsis have the construction sense ρBIMIM1, and the lines pBW13-25C and pB13 44B of Tobacco and the lines pBW13-Al and pBW13-A7 are effectively transformed by the antisense construct pBIW13. On the other hand, the wild line of Tabac BS or the wild ecotype Col-0 of Arabidopsis do not show amplification with any of the three pairs of oligonucleotides. Similarly, none of the 40 Tobacco lines or the 12 Arabidopsis lines is at the origin of a non-specific amplification of the construction it possesses (results not shown).

7 Measuring the cell death rate

The method used (so-called "Evans Blue" method (Baker and Mock, 1994)), makes it possible to detect the death of plant cells. Indeed, the dye "Bleu Evans" is not not able to penetrate intact cells, and is not retained by dead cells. On the other hand, it is capable of crossing damaged membranes and is retained by dying cells. It is therefore possible to compare the cell death rate between two plant samples by the quantity of dye retained. This type of measurement was carried out during inoculations of Tobacco by the avirulent GMI 1000 and virulent K60 strains of R. solanacearum. For each line and each kinetic point, two 0.5 cm ² discs are taken from four different plants (i.e. eight discs) with a punch in the inoculated zone. These eight discs are immersed for 20 min in a Evans Blue solution (0.25%) with moderate circular stirring (80 rpm) at 25 ° C. The discs are then abundantly rinsed on sintered glass using sterile water (approximately 50 ml) so as to remove any unsuccessful Evans Blue. The discs are then placed in eppendorf tubes, frozen in liquid nitrogen, then stored at -80 ° C until extraction. This consists of grinding the discs in liquid nitrogen. The powder obtained is suspended in 1 ml of 0.5% SDS, then it is stirred vigorously for 1 min. After centrifugation for 3 min at 10,000 g, 250 μl of the supernatant obtained are diluted in 750 μl of water. A reading of the optical density at 600 nm is carried out for each sample, and the results are expressed in DOβoo unit (means and standard deviations) per cm ² of plant tissue. 8 Measurement of the level of chlorophylls a and b

The leaf samples (0.5 g) are ground in 5 ml of 80% acetone. The solution obtained is stirred vigorously for 5 min and filtered through glass wool. The residues fixed to the glass wool are washed with 80% acetone until all the pigments are extracted. The eluate is collected and adjusted to 20 ml with 80% acetone. The assay is carried out by spectrophotometry at 663 and 645 nm. The chlorophyll a and b concentrations are calculated from the formulas below. These concentrations are expressed in milligrams of chlorophylls a and b per gram of fresh weight of plant tissue.

Chl a ^≈ (12.7 X DO _{6 5} ) - (2.69 X DO ₆₆ _) Chl b = (22.9 X DO _{6 5} ) - (4.68 X DO ₆₆₃ ) Chl a + b = (( Chla + Chl b) X 20)) / (10 X fresh weight) The results are expressed in% of the amount of chlorophylls present in the wild line during the first extraction, for each leaf stage.

EXAMPLE 1 Isolation of the cDNA Coding for the Factor AtMYB30

In order to isolate genes specifically induced during the early stages of HR, a differential screening was undertaken in A. thaliana (ecotype Col-0) inoculated with the strain 147 of X.c.c, one hour after inoculation, in the presence of cycloheximide. Cell suspensions responding in the same way as whole plants to inoculations were used to obtain homogeneous and reproducible responses. The use of cycloheximide made it possible to focus on the very first stages of the hypersensitive response by isolating genes whose transcriptional activation is independent of de novo protein synthesis. The 27 independent cDNA clones isolated at the end of this differential screening can be divided into seven ATHSR families (for Arabidopsis thaliana hypersensitivity-related genes) on the basis of experiments of cross hybridizations between the clones and analysis of their similarities sequences by querying the databases. One of the cDNAs was completely sequenced for the ATHSR1 families (corresponding to the AtMYB30 gene), ATHSR2 (the clone RaRI2I), and ATHSR3 (the clone RaR105), and a partial sequence was carried out for the 5 'end for all the others. clones.

The clone corresponding to the ATHSR1 family has very strong sequence similarities with the transcriptional factors of the MYB type. The ATHSRI gene has been renamed AtMYB30 in order to comply with the international nomenclature for MYB factors. The nucleotide sequence of the AtMYB30 cDNA and the amino acid sequence of the deduced protein are shown in SEQ ID NO 1. The cDNA has a size of 1310 bp and the predicted ORF of 969 bp encodes a polypeptide of 323 residues with a molecular weight of 36 kDa. The N-terminal sequence of AtMYB30 contains the MYB repeats (R2, R3) generally present in plant MYB proteins. This motif is strongly similar to the MYB domain characteristic of this family of transcriptional factors (Martin and Paz-Ares, 1997). The highly conserved tryptophan residues in c-myb are present in AtMYB30. The first tryptophan residue from the R3 repeat is substituted by a phenylalanine residue, a substitution which is, in addition to isoleucine, commonly found at this position in vegetable MYB proteins. The amino acid sequence of AtMYB30 was then compared with that of other MYB proteins from A. thaliana, other plant and animal species. The degree of similarity among these sequences indicates that different subclasses of vegetable MYB proteins can be defined, beyond the group of animal MYB proteins. AtMYB30 belongs to a subgroup including AtMYB31 (formerly cY13), AmMYB306 and LeTHM6. AtMYB30 has the strongest similarities to the Snapdragon protein AmMYB306 (Jackson et al, 1991) (60% identity and 74% similarity), and to a lesser degree, to the protein AtMYB31 from A. thaliana (53% identity and 70% similarity) and the Tomato LeTHM6 protein (66% identity and 72% similarity). AtMYB30 also shares similarities with other MYB proteins, more specifically in the Myb field. No significant similarity was found in the C-terminal pertie between AtMYB30 and other MYB proteins. However, two sequence elements, GQWERxLQTDIHxxKxALxxALS and TxYASSTENIAxLLxxW, are kept between AtMYB30, AmMYB306, AtMYB31 and LeTHMό. A Southern analysis was carried out in order to study the genomic organization of the gene

AtMYB30. In order to avoid detecting other members of the MYB gene family, a 453 bp cDNA fragment specific for the C-terminal part of the protein was used as a probe. A single fragment could be detected for the four digests involving enzymes that do not cut the cDNA, indicating that AtMYB30 is a unique gene. By comparison, a fragment of 193 bp corresponding to the Myb domain was also used as a probe. Several fragments were detected in this case, confirming the existence of a MYB gene superfamily in A. thaliana (Kranz et al., 1998).

The question of the role of the AtMYB30 gene in HR was tackled by implementing three complementary strategies. The first strategy corresponds to the precise study of its expression profile during various interactions between Arabidopsis and pathogens, in order to provide possible data making it possible to establish a temporal correlation between the activation of the gene and the RH. The second strategy was undertaken by analyzing the regulation of the transcription of the AtMYB30 gene in Isd mutants of Arabidopsis affected in cell death programs (Dietrich et al, 1994), as well as in the corresponding phx suppressors (Morel and Dangl, 1999), with the aim to explore the hypothesis of the existence of a relationship between the mutant phenotypes observed and its expression. The third strategy is based on the generation and analysis of transgenic lines of plants over- or under-expressing the AtMYB30 gene, in order to have direct access to the possible phenotypic consequences of a deregulation of this gene.

Expression of AtMYB30 during development and in response to pathogens

In order to study the expression of the AtMYB30 gene, we analyzed developmental regulation as well as the effects of virulent and avirulent bacterial pathogens on the level of A ÏMYB3Q transcripts. In the plants of A. thaliana, it was not possible to detect AtMYB30 transcripts by Northern analysis, indicating that AtMYB30 is expressed at very low level, as previously mentioned for different MYB genes (Leech et al, 1993; Li and Parish, 1995). Therefore, we determined the level of AtMYB30 transcripts by RT-PCR using the β-tubulin 4 gene constitutively expressed as internal control. The messenger RNAs of AtMYB30 accumulate during the early stages of development, i.e. in seedlings two weeks old, but remain barely detectable during other developmental stages, throughout the plant. In order to study the expression of AtMYB30 in response to pathogens, an RNA preparation was carried out from cultured cells inoculated with Xcc, the original biological system for the isolation of the cDNA clone. PAL and RaR136 probes (a constitutively expressed clone in cells, unpublished results) served to control cell infection and cell viability, respectively. The AtMYB30 transcripts could not be detected during the compatible interaction, nor in response to the hcc-mutant of Xcc, incapable of causing symptoms in Arabidopsis (Arlat et al, 1991). On the contrary, the transcripts of AtMYB30 accumulate transiently one hour after inoculation with the avirulent bacterial isolate. By comparison, PAL transcripts accumulate during HR at a maximum rate 24 hours after inoculation. A similar accumulation of PAL transcripts is observed during the compatible interaction, but the levels are significantly lower. As expected, the constitutive expression of RaR136 was observed in all cases, except in infected cells for 24 hours. This exception can be explained by reduced cell viability late after infection. The accumulation of AtMYB30 transcripts was also evaluated in Arabidopsis plants infected with the same pathogen. It has been shown that AtMYB30 is expressed transiently between one and two hours, and specifically during the hypersensitive response (interaction between the avirulent isolate 147 and the resistant ecotype Col-0). No expression could be detected during the compatible interaction (interaction between isolate 147 and the sensitive Sf-2 ecotype) or in response to treatment with water. In response to another bacterial pathogen, Pseudomonas syringae pv. tomato (isolate DC3000 (Whalen et al, 1991)), containing (or not) the avRululence gene avrRpml (Debener et ai, 1991) or the avirulence gene avrB (Wanner et ai, 1993), AtMYB30 is transiently expressed and before the appearance of cell death, namely one hour after inoculation (hypersensitive cell death being observed 9 hours and 7 hours after inoculation, respectively), in our experimental conditions. During the compatible interaction, no expression of AtMYB30 could be detected.

The expression of AtMYB30 is induced in mutants affected in the initiation of programmed cell death, and suppressed in the corresponding suppressors

Mutants of Arabidopsis showing necrotic lesions mimicking the resistance response in the absence of pathogen have been characterized (Dietrich et al, 1994; Greenberg et al, 1993; Greenberg et al, 1994). They are believed to be affected in the control of hypersensitive cell death, and therefore offer the opportunity to explore the relationships between specific activation of AtMYB30 and programmed cell death. The expression of AtMYB30 was studied in three initiation mutants, lsd3, lsd4 and lsd5, whose "lesion" phenotype is dependent on light. The lesions are visible 24 hours, 4 days and 6 days after transfer of the plants under permissive conditions, respectively for lsd5, lsd3 and lsd4. In parallel, the expression of the PR1 gene, whose accumulation of transcripts is correlated with the appearance of lesions in these mutants, was also analyzed, as a control. While PR1 transcripts only accumulate when the three conditional mutants show lesions, AtMYB30 is also expressed in the absence of lesions: constitutively and strongly in the lsd5 and lsd4 mutants. On the contrary, AtMYB30 is not not expressed in the lsd3 mutant in the absence of lesions. No expression of AtMYB30 is detected in the wild Ws-0 ecotype from which the mutants lsd3, lsd4 and lsd5 are derived.

For a better understanding of the relationships between the lsd5 and lsd4 mutations, which lead to the constitutive expression of AtMYB30, and the expression of AtMYB30, different suppressor lines produced from the lsd5 mutant ((Morel and Dangl, 1999) , and unpublished results), were analyzed. According to our results, when transferring into permissive conditions, double mutant lines no longer show necrotic lesions (phxlllsd5, phx2llsd5, and phxll-lllsd5) or show lesions of much smaller size (phx3llsd5 and phxlOllsdδ). As previously described, AtMYB30 is expressed in lsd5 whatever the conditions. On the contrary, AtMYB30 transcripts are not detected in any of the suppressor lines, or in the wild-type Ws-0 ecotype. Similarly, the activation of the AtMYB30 gene, constitutive in the lsd4 mutant, is suppressed in the offspring of the phxlllsd4 cross. The phxl mutant has been shown to suppress cell death normally caused by the lsd4 mutation (Morel, unpublished results).

The expression of AtMYB30 is not altered in the mutant Isdl, affected in the propagation of cell death

The Isdl mutant of A. thaliana shows an alteration in the control of cell death in the absence of a pathogen: it is unable to control the extent of cell death once it has started (Dietrich et al, 1994; Jabs et al, 1996). This mutant represents an excellent tool for exploring the role of AtMYB30 in limiting cell death. For this purpose, the expression of AtMYB30 was analyzed in Isdl plants showing or not showing lesions, in comparison with wild plants under the same conditions. As before, the expression of the PR1 gene was also followed, as a control, it accompanies the formation and the propagation of the lesions. This defense marker has been shown to accumulate systematically in plants showing lesions. Surprisingly, the expression of AtMYB30 could not be detected in Isdl, whatever the phenotype observed. Similar data have been obtained with an Isdl mutation suppressor, phx21, or in the wild-type Ws-0 ecotype. Example 2 Constructions allowing the modulation of the expression of the AtMYB30 gene in transgenic plants

The plasmids pB_M131, pBIW13, and pBIl 11 (FIG. 4) are derived from the plasmids pBI221 (Clontech), pBI121 (Clontech, (Jefferson et al, 1987)) and from the plasmid corresponding to the clone RaR015 comprising the cDNA of the AtMYB30 gene (Lacomme, 1996). The plasmid pBIM131 is a binary plasmid whose T-DNA comprises a gene responsible for kanamycin resistance, and a construct in which the coding region of the AtMYB30 gene is placed under the dependence of the CaMV 35S promoter and the NOS terminator of Agrobacterium tumefasciens. This plasmid was used to transform Tobacco and Arabidopsis plants for the overproduction of the AtMYB30 protein in "sense" lines. Plasmid pBIW13 is a binary plasmid, the T-DNA of which comprises a gene responsible for kanamycin resistance, and a construct in which the coding region of the AtMYB30 gene is placed in antisense orientation under the dependence of the CaMV 35S promoter and the terminator NOS of Agrobacterium tumefasciens. This construct was used to transform Tobacco and Arabidopsis plants to inhibit the production of the AtMYB30 protein in Arabidopsis, and to inhibit the production of the orthologous protein in Tobacco in "antisense" lines. The plasmid pBI11 is a binary plasmid whose T-DNA comprises a gene responsible for resistance to kanamycin, and a fusion between the 35S promoter of CaMV and the NOS terminator of Agrobacterium tumefasciens. This plasmid was used to transform Tobacco and Arabidopsis plants, with the aim of obtaining “control” lines in both cases, so as not to impute the cause of the phenotypes of “sense” lines and “lines”. antisense "only to the differences between the constructions, and not to the transformation event or the insertional nature of the transformation. These three plasmids were subjected to verification of their nucleotide sequence three times, on the two strands of DNA. It did not reveal any mutation in the coding region of the AtMYB30 gene in the plasmids pB_M131 and pBIW13, and all the fusions created during the ligation experiments during the generation of the three plasmids (pBIl ll, pBIM131, and ρBIW13) were verified. . Example 3 Analysis of the Tobacco Sense Lines Eighteen transforming lines comprising the sense construction of the AtMYB30 gene dependent on the 35S promoter of the CaMV cauliflower mosaic virus were examined. In plants 2 months old, no phenotype seemed to differentiate them from the wild line BS (Bottom Special). However, the strong relationship between its expression and hypersensitive cell death established in Arabidopsis foreshadowed the obtaining of a phenotype of the "spontaneous lesions" type or of an altered phenotype for HR. No spontaneous lesion was observed on the transgenic lines obtained, and in order to test this hypothesis, a pathogenicity test was carried out on all of our "sense" lines (having the sense construction pB_M131). This test consists in inoculating the plants with the avirulent GMI 1000 and virulent K60 strains of R. solanacearum, necrotrophic bacteria which respectively cause HR in 24 hours and disease from three days on the wild line BS with inocula of 5.10 ⁷ cfu / ml.

3.1 Sense lines have altered phenotypes in response to bacterial inoculations Inoculation of eighteen sense lines, as well as the wild line BS, by the avirulent strain GMI 1000 and the virulent strain K60 of R. solanacearum has made it possible to '' observe a clear difference between the phenotypes of the wild line and some of the sense lines.

3.1.1 Sense lines show increased resistance to the avirulent GMI 1000 strain of R. solanacearum

Inoculation of the avirulent strain GMI1000 of R. solanacearum from the sense lines led to the observation of phenotypes different from that of the wild line BS. These differences in the speed of onset and the severity of the symptoms could be quantified, and made it possible to classify the eighteen sense lines tested in three classes, according to the phenotype observed (Table 1 below and Figure 7). Table 1 Classification of the different sense lines of Tobacco according to their phenotype compared to the wild line BS during inoculations with the avirulent strain

GMI 1000 from R. solanacearum.

3.1.2 Sense lines have an altered sensitivity towards the virulent strain K60 of R. solanacearum

Inoculations of the virulent strain K60 of R. solanacearum were carried out on the 18 sense lines and the wild line. Inoculation of this strain at a concentration of 5.10 ⁷ cfu / ml causes the appearance of tissue chlorosis (the color changes from deep green to light green) three days after inoculation which worsens (the tissues become yellow) and extends beyond the area inoculated in the wild line after five days. These observations are typical of a compatible interaction leading to the disease.

Observation of the symptoms after inoculation shows for the sense lines pBIM131-4D, pBIM131-13A, pBIM131-13C, pBIM131-40A, pBIM131-47A and pBIM131-50A a very different phenotype from the wild line. The inoculated areas do not exhibit evasive chlorosis, but appear necrotic spots which converge, and lead to the formation of brown necrotic lesions limited to the inoculated areas, and surrounded by a weak chlorotic halo. These lesions are reminiscent of those observed during an interaction leading to the hypersensitive response, but their color is darker, and their appearance is much less smooth. 3.1.3 The phenotypic classes identified are correlated with the quantity of AtMYB30 protein produced in transgenic plants

The hypothesis of a correlation between the phenotypes observed during inoculation by the avirulent GMI 1000 and virulent K60 strains of R. solanacearum and the rate of production of the protein AtMYB30 in the different sense lines was tested by. Western blot type. The soluble proteins of lines representing the different phenotypic classes observed were extracted and the production of the AtMYB30 protein was evaluated using polyclonal antibodies directed against a recombinant fusion protein GST-AtMYB30. The lines which have been used are the wild line BS, two lines behaving like the latter (pBIM131-27D and pBIM131-27F), four lines whose phenotype is particularly strong (pBIM131-13C, pBIM131-40A, pBIM131-47A and pBIM131-50A), and a line with an intermediate phenotype (pBIM131-4C). The results of this analysis show that the AtMYB30 protein could not be detected in the wild line BS or the two lines pBIM131-27D and pBIM131-27F, but that it is possible to clearly detect a protein band in the other lines. , with a molecular weight of approximately 36 kDa, molecular weight expected for the protein product of the AIMYB30 gene. The same Western blot analysis, carried out under the same conditions, did not allow the AtMYB30 protein to be detected in two control lines (pBl l l-9A and pBIl l l-23A) having the pBIl ll control construct (results not shown).

For the rest of the manipulations, we chose to use the pBIM131-40A line because it represents the category of sense lines whose phenotype is very clearly altered by comparison with that of the wild line, and that it only presents only T-DNA insertion event. The pBIM131-4C line has also been used during certain manipulations because of its intermediate phenotype and its unique T-DNA insertion event. The wild line BS, as well as the control line pBIl 11-23 A, served respectively as negative control, and as control line.

3.1.4 Measurement of bacterial growth in planta

Measuring bacterial growth in planta or IGC provides information on how bacteria multiply in plant tissue, and possibly deduce the effectiveness of plant defense reactions in limiting the growth of bacteria. In order to study the role of the AtMYB30 gene in this phenomenon of restriction of growth of R. solanacearum in tobacco tissues, IGC experiments were carried out after inoculation with the avirulent GMI 1000 and virulent K60 strains in the wild line BS, and the control lines pBI1 11-23 A and sense pB_M131-40A. The growth of the avirulent strain GMI 1000 of R. solanacearum is impaired in the senspBIM131-40A line

The first six days of observation do not make it possible to distinguish a difference in bacterial growth between the wild line BS, the control line pBIl 11-23 A and the sense line pB_M131-40A, although the concentration of bacteria in this latter line is lower than that detected in the wild line and the control line from the third day (72 hours). In fact, in all cases, a drop in the level of bacteria measured in the inoculated areas is first detected during the first 24 hours. Subsequently, the bacteria multiply (growth corresponding to one or two logarithmic units is observed between 24 and 48 hours) and their number remains relatively constant until six days after inoculation. Beyond this kinetic point, a disparity between the wild line and the control line on one side, and the direction line on the other, is detected: a sudden and strong decrease in bacteria between 6 and 14 days after inoculation characterizes the pBIM131-40A line, while this drop is much less brutal, and even less strong at the end of kinetics for the most concentrated inoculum, in the wild line BS and the control line pBIl 11-23 A.

The growth of the virulent strain K60 of R. solanacearum is impaired in the senspBIM131-40A line

The same IGC experiments were carried out using the virulent strain of R. solanacearum, K60. In this case, the growth of bacteria in the tissue immediately around the inoculated areas was also measured. Analysis of the results indicates that the number of bacteria present in the wild line and in the control line is comparable. In the inoculated areas, it appears that virulent bacteria are able to multiply within the tissues during the first six days. Their number is higher in the case of the sense line pBIM131-40A on the third day following inoculation. Subsequently, the importance of the drop in the number of bacteria beyond six days is really greater in this line than in the control line pBIl ll -23 A or the wild line BS: at ten and fourteen days after inoculation, the bacterial growth rate is ten times lower in the pBEM131-40A line. Bacterial growth was also assessed in the tissues immediately adjacent to the inoculated areas. The bacteria are detected as early as three days after inoculation, multiply and reach a maximum, then their number drops so that they are no longer detectable fourteen days after inoculation. If the three curves share the same profile, the growth peak of the bacteria appears clearly earlier (6 days) for the pB_M131-40A line than for the control line or the wild line (10 days). In all cases this growth is transient, this character being more marked for the sense line pBIM131-40 A.

FIG. 6 presents the results obtained on the in planta bacterial growth of R. solanacearum inoculated at 5.10 ⁷ CFU / ml in transgenic tobacco plants. A, Interaction incompatible with the avirulent bacterial strain GMI1000. B, Interaction compatible with the virulent strain K60. In both cases (A and B) the samples were taken from the infiltration area. The results present the means and standard deviations obtained over two series of samples. The results show that the bacterial population is maintained for up to 3 days after inoculation in the inoculated area. This phase is followed by a progressive decrease in the bacterial populations in the wild, control and antisense lines, which does not increase until after 9 days. However, after only 6 days, a very significant decrease in the bacterial population is observed in the sense line, with an almost total extinction of the GMI 1000 strain, 13 days after inoculation.

3.1.5 Measuring the rate of cell death after bacterial inoculation

The observation of symptoms and bacterial growth profiles in planta during inoculation with the avirulent GMI 1000 and virulent K60 strains of R. solanacearum made it possible to clearly highlight the mutant phenotype of certain sense lines (and in particular the pBIM131 line. -40A) in comparison with the wild line or the control line pBI1 l l-23A. In order to provide additional data to these results We investigated whether the kinetics of initiating and / or extending cell death were also altered in this line overproducing the AtMYB30 protein. For this, we carried out "Evans Blue" type tests according to the method described by Baker and Mock (1994). Experiments using the avirulent strain GMI 1000 of R. solanacearum were carried out. Laβgure 5 illustrates the results obtained on the measurement of cell death by ^• Evans Blue staining (Backer and Mock, 1994) on Tobacco after inoculation with this bacterial strain, in a weak inoculum (10 ⁷ cfu / ml). The kinetics presented show the appearance of a dye penetration peak in the case of the sense line, corresponding to the appearance of symptoms, 19 hours after inoculation. After the tissue collapse, the necrosis appears, and the dye is no longer retained. This peak representative of the establishment of the hypersensitive response appears earlier and is three times higher in the sense line than in the wild line where it is relatively low due to the poorly concentrated inoculum used during this experiment. Less retention of Evans Blue is also observed later in the antisense line.

The interaction between the virulent strain K60 of R. solanacearum and the wild line BS or the control line pBIl 1 l-23A leads to the disease. In this case, the in planta bacterial growth profiles presented by these two lines are identical: cell death is detected approximately 48 hours after the inoculation of the bacteria, and its rate drops to three days, to become undetectable from six days. The profile obtained with the plants of the sense line pBIM131-40A is very different. Cell death is detected earlier (as early as 24 hours after inoculation), its rate is higher two days after inoculation, and it is no longer detectable from three days. In addition, this rate is much higher than in the wild line or the control line, since it is possible to measure a difference reaching a factor of ten between these two lines and the sense line pBIM131-40 A.

3.1.6 The expression of genes linked to pathogenicity is altered in the sense line pBIM131-40A

The expression profile of the str246C and hsr203J genes of Tobacco was studied during inoculations with the avirulent GMI1000 and virulent K60 bacteria of R. solanacearum in the wild line BS, the control line pBI1 l l-23A, and the sense line pBIM131-40A. While these two genes show a similar expression in the first two lines, significant differences have been observed in the sense line pB_M131-40A. During these experiments, the Arabidopsis EF-la gene is used as a constitutive internal control. The expression of the str246C gene is altered in the sense line pBIMl 31-40 A While the str246C gene is not induced during inoculation with water in the wild line or in the control line pBIl ll -23 A, its expression is detected very early (from 6 hours) and up to 6 days after inoculation in the sense line pB_M131-40A. In addition, this expression is earlier and stronger in response to the avirulent GMI 1000 and virulent K60 strains of R. solanacearum. However, it is not detected in uninoculated plants, whatever the line: the expression of the str246C gene is therefore not constitutive in the sense line pB_M131-40A, but more quickly and more strongly induced during the three inoculations in this line. The expression of the hsr203J gene is altered in the senspBIM131-40A line

In the wild line BS or the control line pBI1 l l -23 A, the hsr203J gene is essentially expressed during the first stages of the interaction incompatible with the GMI 1000 strain, since it is detected 6 hours and 12 hours after inoculation. On the other hand, it is barely detectable during compatible interaction, and absent in plants not inoculated or inoculated with water. In contrast, the hsr203J gene has a different expression profile in the sense line pBIM131-40A. This expression is also detected 6 hours after inoculation with the GMI 1000 strain, but maintained longer than in the wild line. In addition, it is detected very clearly during the compatible interaction 12 hours after inoculation. Finally, this gene is not expressed in the absence of inoculation.

3.2 The senescence of the leaves of sense lines is delayed When studying the process of senescence of the tobacco leaves, the first eight adult leaves (starting from the base of the plant) or the first eight leaf stages of four different plants are taken into account for each line. Their color and degree of necrosis are estimated visually. Indeed, the leaves change color during this developmental process. The latter gradually changes from deep green to yellow, and the final stage of this evolution is characterized by necrosis of the leaves, which take a brownish hue, and gradually dry out. This sequence of events is dependent on the age of the leaves, and occurs first for the older leaves.

3.2.1. Observation of the phenotype of sense lines shows a delay in leaf senescence When studying the process of leaf senescence in sense lines, a difference in phenotype compared to the wild line was clearly observed. While the first leaf stages of the wild line BS and the control line pBIl l l-23A show advanced senescence (the first ten leaves are necrotic), the plants originating from the sense line pB_M131-40A only show the beginning of this process: only one or two necrotic leaves appear, and the color loss of the upper leaf stages is relatively low. It should be noted that the observation of this alteration of leaf senescence in the different sense lines resulted in the same classification established during the study of the response of the sense lines to inoculation with the avirulent strain GMI 1000 and the strain virulent K60 of R. solanacearum, and the detection of the protein AtMYB30. Generally, the leaves of plants from the senses ^• lines seemed to have a slightly larger than those of wild-type line. In order to quantify these observations, the number of green leaves and necrotic leaves among the first eight leaf stages, was determined in four plants of the sense lines pBIM131-40A and pBIM131-4C, of the control line pBIl ll -23 A, as well than the wild BS line. The results obtained perfectly reflect the visual impression felt during observations of sense lines in general, and show a delay in triggering and a slowing down of the process of leaf senescence in sense lines pB_M131-4C and pBIM131-40A. The delay observed is reflected, in particular for the pBIM131-40A line, by the delayed appearance of the first necrotic leaves: ninety days after sowing for this line, sixty days for the wild line. The slowing down of the senescence process can be evaluated by the importance of the slopes of the different curves: they are generally lower in the two sense lines than in the control line or the wild line.

3.2.2 The chlorophyll pigments are kept longer In order to confirm the differences observed visually during the leaf senescence, a measurement of the quantity of chlorophylls in the leaves over time was carried out. These experiments were carried out on the plants used to count the green or necrotic leaves. The first eight leaf stages were subjected to the extraction of chlorophyll pigments. The sense line analyzed, pBIM131-40A, shows a decrease in the quantity of chlorophylls much slower than the wild line or the control line pBIlll -23 A for the fourth and eighth leaf stages. This is true for the eight leaf stages for which this measurement was made (results not shown). It is particularly striking to see that the fourth leaf of the pBIM131-40A line still has 50% of the initial amount of chlorophylls ninety days after sowing, when it was not possible to detect these pigments in the wild line at that date. It should also be noted that the difference observed between the sense line on the one hand, and the wild line and the control line on the other, is clearly visible from the seventieth day of cultivation of the plants.

3.2.3 The expression of the ACC oxidase gene is reduced In order to confirm our phenotypic and biochemical observations during the process of senescence of the leaves of the sense lines pB_M131-4C and pBIM131-40A, we undertook a molecular study of this process, via the detection of the expression of the ACC Oxydase or ACO gene. ACC Oxydase (previously EFE for Ethylene-Forming Enzyme) catalyzes the last step of the biosynthetic pathway for ethylene (Adams and Yang, 1979), a plant hormone strongly involved in the ripening of fruits (Balagué et al, 1993) . and senescence of plant tissues (Nadeau and O'Neill, 1995), in particular leaves and flowers. This enzyme can be considered as a marker of senescence, and it makes it possible to estimate the implication of the biosynthetic pathway of ethylene in the process of senescence of the leaves of our transgenic lines of Tobacco. Samples from the seventh and eighth leaf stages were pooled for the different measurement times, and subjected to RNA extraction. Senescence being more advanced for the wild line and the control line pBIl ll -23 A, it was not possible to extract RNA in sufficient quantities beyond the seventieth day of cultivation of the plants, while these extractions were able to be carried out until the eighty-fourth day of culture for the sense lines pBEVÎ131-4C and pBIM131-40A. The obtained results show that the expression of the ACO gene is overall weaker in the sense lines than in the wild line or the control line, even if it is very strong at the seventieth day of culture in the line pB_M131-4C. This is particularly true for the pBIM131-40A line, since this expression is barely detectable at the sixtieth and seventieth days of culture, whereas it is strong in the wild line BS and the control line pBI1 l l-23A. Thereafter, that is to say at the eightieth and ninety-ninth days after sowing, the expression of the _4CO gene is more easily detected in the pB_M131-40A line, and presents a level comparable to that observed. on the sixtieth day of culture for the wild line.

Example 4 Impact of the modulation of ^expression, AtMYB30 on resistance to different pathogens Tobacco.

Virulent (Pseudomonas syringae pv. Tabaci), avirulent (Pseudomonas syringae pv. Pisi and Pseudomonas fluorescens constitutively expressing the hate gene) or symptomless (Pseudomonas fluorescens) strains were inoculated at two different concentrations. In response to the two avirulent strains, 25 hours after inoculation, necrotic lesions localized to the inoculation zone are observed on the line overexpressing AtMYB30; these same symptoms appear later (48 hours after inoculation) in the other lines. Surprisingly, more marked chloroses are observed in sense line plants inoculated with P. syringae pv. tabaci, in comparison with the other lines, therefore indicating a different behavior of this line towards two pathogenic bacteria R. solanacearum and P. syringae. In the case of P. fluorescens not containing the plasmid encoding a haine, no symptom is observed, and this on all the lines. In addition, pathogenic fungi have been tested on these transgenic lines in collaboration with the company Biogemma. Two fungal pathogens from Tobacco were selected because of their different invasion modes: Chalara elegans, root pathogen and Cercospora nicotianae, leaf pathogen. No significant difference in symptoms could be observed in response to root infection with Chalara elegans, regardless of the line. In contrast, leaf inoculation by the fungus Cercospora nicotianae made it possible to observe a clear difference between the lines. While the wild and control lines show marked symptoms, no symptoms are observed on the sense line. The antisense line shows symptoms similar to, or slightly inferior to, the controls.

Example 5 Analysis of Anti-sense Tobacco Lines

The phenotypes observed during inoculations of the pBIM131 sense lines (cell death, bacterial growth in planta) led us to carry out similar studies on eight of the available antisense lines. Their phenotype after inoculation with the avirulent GMI 1000 and virulent K60 strains of R. solanacearum was observed, as well as during senescence of the leaves and flowering.

4.1 Antisense lines show altered phenotypes in response to bacterial inoculations

The inoculation experiments of the antisense lines with the avirulent strain GMI 1000 and the virulent strain K60 of R. solanacearum led to the observation of altered phenotypes vis-à-vis the wild line BS.

Antisense lines have reduced resistance to the avirulent GMI 1000 strain of R. solanacearum

Inoculation of the leaves of antisense lines with the avirulent strain GMI 1000 of R. solanacearum made it possible to observe an alteration of the phenotype compared to the wild line BS. Indeed, the speed of appearance of symptoms characteristic of HR is often reduced, as well as their final severity. A quantification of these symptoms resulted in the classification of the tested antisense lines into four phenotypic classes. Observation of the phenotypes Although, during this experiment, the symptoms obtained with the wild line BS were stronger, and their appearance earlier than during all the other inoculations, the results obtained are extremely clear, and allow in particular to distinguish several types of behavior among the eight antisense lines tested against the avirulent strain GMI 1000. We also inoculated two control lines (pBIl 1 1-9A and pBIl 11-23 A, chosen for their unique event of insertion of T-DNA) in the same conditions, and these have the same phenotypes as the wild line (results not shown). The symptoms obtained four days after inoculation with the lines pBIW13-28A and pBIW13-28B are very specific: they do not resemble in any way those obtained with the wild line BS. For the three inocula tested (5.10 ⁶ , 1.10 ⁷ , and 5.10 ⁷ cfu / ml), the symptoms are characterized four days after inoculation by a dry and localized necrosis in the inoculated zones, just as for the wild line, but each d 'between them presents an original phenotype beyond the necrotic zone. It is a strong chlorosis around the necrotic lesions for the pBW13-28A line, while the necroses of the pBW13-28B line do not remain confined to the inoculated areas, but extend outside. The symptoms obtained with the other antisense lines analyzed also differ from the phenotype of the wild line, but in a less atypical way (results not shown). While most of the sense lines showed an acceleration of HR and a worsening of necrotic symptoms, antisense lines show a completely opposite phenotype: the symptoms appear later, and the necrotic lesions rarely extend to the whole inoculated areas. Apart from the lines pBIW13-28A and pBIW13-28B, the necrotic lesions due to the avirulent strain GMI 1000 of R. solanacearum never extend beyond the limits of the inoculated zones. The course of symptoms is completed 72 hours after inoculation. The quantification of the symptoms makes it possible to divide the antisense lines into four phenotypic classes

In the same way as for the sense lines, it was possible to quantify the symptoms observed. The symptoms observed in the wild line with the inoculum of 5.10 ⁶ cfu / ml are visible from 15 hours after inoculation with the appearance of large areas of tissue "collapse", which are limited to the surface of the tissues inoculated from 24 hours after inoculation. Symptoms are even earlier (12 hours after inoculation) and reach the maximum severity as early as 24 hours after inoculation for the other two inocula, 1.10 ⁷ and 5.10 ⁷ cfu / ml. Four days after inoculation, they are characterized by necrosis having invaded all of the areas inoculated for the three inocula. In the antisense lines tested, four phenotypic classes can be identified, based on the speed of onset and the severity of the symptoms, in comparison with the wild line. First, the lines ρBW13-3A, ρBW13-21A and pBW13-25D, and particularly for the two weakest inocula, develop the response much less quickly, and its final extent is much less. Then, the lines pBW13-41B and pBW13-4B are distinguished by an intermediate phenotype between the wild line and the three above-mentioned antisense lines: this distinction in the severity and the rapidity of onset of symptoms is only detectable at lower inoculum for the pBW13-41B line (5.10 ⁶ cfu / ml). Finally, the pBIW13-25C line has a phenotype very similar to that of the wild line, and this for the three inocula tested. These differences are all the stronger when the inoculum is small: they are difficult to detect for the strongest inoculum (5.10 ⁷ cfu ml), but they are very clear when the inoculum is 5.10 ⁶ cfu / ml. The fourth class comprises the two lines pBIW13-28A and pBIW13-28B which exhibit very remarkable phenotypes, because they are very different from the wild line. Antisense Lines Show Modified Susceptibility to Virulent Strain K60 of R. solanacearum Inoculation of Tobacco Antisense Lines with Virulent Strain K60 of R. solanacearum revealed that not all lines reacted as the line wild BS. While chlorosis of the inoculated tissues, characteristic of the disease, appears around the third day, and it then spreads outside this zone in the wild line, most of the eight antisense lines tested do not develop the same symptoms. Among these lines, it is possible to determine four groups, according to the importance and the rapidity of the symptoms caused by the strain K60. These groups correspond exactly to those identified by observations made for inoculations with the avirulent strain GMI1000. The pBW13-25C line is comparable to the wild line for the speed of appearance of the symptoms, even if they are a little weaker. Among the lines reacting faster (the appearance of chlorosis is visible from 48 hours after inoculation) than the wild line, it is possible to distinguish the lines pBIW13-3A, pBW13-21A, pBW13-25D, pBW13-41B and pBIW13 -44B on the one hand, and the lines pBW13-28A and pBW13-28B on the other hand. The former are distinguished by a slight worsening of the symptoms (chlorosis is more marked, and it extends over an area increased by approximately 50% compared to the wild line), and the latter are different by the speed of appearance of symptoms, which is much faster (they appear as early as 36 hours after inoculation), and by the very nature of these symptoms. The pBW13-28A line is characterized by a very strong chlorosis in the inoculated area, which quickly gives way to large necrotic lesions in this area, while a particularly strong chlorosis extends beyond the inoculated areas. The symptoms observed in the pBW13-28B line are very different, since they are clearly necrotic. These necroses are brown, covering about one tenth of the surface of the inoculated tissue, and do not spread thereafter. These necrotic zones correspond precisely to the place where the injection with the syringe was made, therefore where the bacteria were most numerous.

Example 6 Isolation of Transforming Lines of Arabidopsis thaliana

8.1. Selection of transformed plants

The constructs used for the transformation of Tobacco, comprising either the open reading phase of AtMYB30 in sense orientation, in antisense orientation, or without this orf (control construction), downstream of the CaMV 35S promoter, had been introduced into Arabidopsis thaliana Ws-0 ecotype. From the seeds from the transformed plants, the selection of the transformed lines was carried out. This step, carried out on MS medium supplemented with kanamycin (50 mg / l), made it possible to obtain 25, 15 and 6 transformants respectively for the sense, antisense, and control constructions. 8.2. Molecular and genetic analysis of transformants

The presence of the transgene has been validated in all sense lines, and in most of the transformed antisense and control plants. The use of a pair of primers specific to each construct made it possible to verify the correct orientation of the transgene in the sense and antisense lines. Furthermore, the number of T-DNA insertions containing each construct was evaluated. All transformed lines verified from a molecular point of view and having only one insertion locus were seeded. The phenotype of these lines during development was observed on 15 plants of each line and appeared in the majority of cases, similar to the wild line Ws-0. Only a few transformed lines show an altered development, characterized by a dwarf phenotype. At the end of this stage, we have 18 lines over-expressing potentially AtMYB30, 8 lines under-expressing it and 4 control lines. 8.3. Analysis of the phenotype in response to an avirulent pathogenic bacterium

The pathosystem selected is the interaction Arabidopsis thaliana I Xanthomonas campestris pv. campestris (X.c.c). 10 plants of each transformed line, as well as 10 wild plants Ws-0, were inoculated with the strain X.c.c. 147. Observation of the establishment and development of the hypersensitive response made it possible to classify the different lines transformed according to the intensity of the symptoms observed. In the wild line, the plants inoculated by X.cc. \ 47 present as early as 10 hours after infection the first symptoms of the hypersensitive response, namely a 'collapse' of plant cells in the inoculation zone. These first symptoms progress to constitute necrotic lesions localized to the inoculation zone 30 to 48 hours after inoculation. In addition to these reference kinetics, the results show that certain sense lines have clearly stronger necrosis than the wild line and that certain antisense lines develop less necrotic symptoms. The control lines do not differ phenotypically from the Ws-0 line. In order to confirm these visual observations, a measurement of the cell death rate by the Blue Evans technique was carried out on all the lines tested 30 hours after inoculation, time when the cell death rate is maximum in the ecotype. wild. The results show an interesting correlation between the intensity of the symptoms observed and the rate of cell death measured. For the rest of the experiments, 2 sense lines (131.17A and 131.20 A), 2 antisense lines (W13.1A and W13.19 A) as well as a control line (111.23 A) were selected.

8.4. Impact of the modulation of the expression of cell death AtMYB30 on ^{"hypersensitive} in Arabidopsis thaliana

The selected sense lines inoculated by Xcc 147 exhibit a particularly marked intensification of the hypersensitive response. In addition to an increase, cell death is detected earlier in one of the sense lines. These results show that the different lines selected are affected in resistance to this pathogenic bacteria and will constitute a tool of choice to validate the role of AtMYB30 in Arabidopsis thaliana in the regulation of the hypersensitive response. REFERENCES

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Claims

1. A chimeric gene comprising in the direction of transcription, a sequence ^• functional regulatory promoter in plant cells and plants, a nucleic acid sequence encoding a MYB factor 30 and a functional terminator regulatory sequence in plant cells and plants, the above elements being operably linked to allow expression of factor MYB 30 in plant cells and plants.

2. Chimera gene according to claim 1, characterized in that the sequence coding for the factor MYB30 is a sequence of plant origin, in particular Arabidopsis thaliana (AtMYB30).

3. Chimera gene according to one of claims 1 or 2, characterized in that the sequence coding for the factor MYB30 is the sequence represented by SEQ ID NO 1, the sequences capable of hybridizing selectively with SEQ ID NO 1, the sequences homologous to SEQ ED NO 1 and the fragments of said sequence.

4. Cloning or expression vector for the transformation of a host organism characterized in that it contains at least one chimeric gene according to one of claims 1 to 3.

5. Method for transforming plant cells or plants, characterized in that at least one chimeric gene according to one of claims 1 to 3 is integrated into the genome of plant cells or plants.

6. Method according to claim 5, characterized in that the chimeric gene is integrated by means of the vector according to claim 4.

7. Transformed plant cell characterized in that it comprises a chimeric gene according to one of claims 1 to 3.

8. transformed plant cell according to claim 7, characterized in that that it comprises at least one other heterologous gene coding for a particular peptide or protein of interest.

9. Transformed plant, characterized in that it comprises transformed cells according to one of claims 7 or 8.

10. Transformed plant according to claim 9, characterized in that it is regenerated from the transformed cells according to one of claims 7 or 8.

11. Transformed plant, characterized in that a chimeric gene according to one of claims 1 to 3 is stably integrated into its genome and transmissible by sexual reproduction.

12. Transformed plant according to one of claims 9 to 11, characterized in that it is chosen from monocotyledonous plants, such as corn, wheat, rice, sugar cane, or dicotyledons, such as beetroot, tobacco, cotton, rapeseed, soy.

13 Transformed plant according to one of claims 9 to 12, characterized in that it is chosen from dicotyledonous plants, in particular cotton, rapeseed or soybeans, and preferably cruciferous plants such as rapeseed.

14. Method for improving the resistance of plants to pathogenic aggressions, in particular fungal, characterized in that it consists in overexpressing in said plants a transcription factor MYB30.

15. Method according to claim 14, characterized in that the overexpression is ensured by the integration into the genome of the plant a chimeric gene according to one of claims 1 to 3.

16. The method of claim 15, characterized in that the promoter regulatory sequence of the chimeric gene is chosen from constitutive promoters such as histone promoters, rice actin promoter or the 19S or 35S promoter of the cauliflower mosaic (CAMV 19S or 35 S), and specific promoters of specific regions or tissues of plants.

17. Method for cultivating transformed plants according to one of claims 9 to 13, characterized in that it consists in planting the seeds of said transformed plants in an area of a field suitable for the cultivation of said plants, to apply to said surface of said field an agrochemical composition, without substantially affecting said seeds or said transformed plants, and then harvesting the cultivated plants when they reach the desired maturity and possibly separate the seeds from the harvested plants.

18. The method of claim 17, characterized in that the agrochemical composition comprises at least one active product having at least one fungicidal and / or bactericidal activity, more preferably having an activity complementary to that of the product produced by the chimeric gene expressing the factor MYB30 in transformed plants.