WO1999035269A2 - Method for controlling the division and/or elongation of eukariotic cells - Google Patents

Abstract

The invention concerns a method for controlling the division and/or elongation of eukariotic cells, and in particular plant cells, by modifying the expression and/or the activity of a TONNEAU1 protein in said cells. Said medhod enables in particular to act on the size of plants, or of their organs. The modification of the expression and/or the activity of the TONNEAU1 protein can for example, be carried out via a gene coding for said protein, or sequences controlling its expression, or by using said protein inhibitors of activators.

Description

 DIVISION AND / OR ELONGATION CONTROL METHOD

OF EUKARYOTIC CELLS.

The present invention relates to the cloning and expression of genes making it possible to act on the architecture, growth or fertility of plants.

The architecture of a higher plant is determined essentially by the control of cell divisions and elongation. The cells of the roots, leaves, stems, and flowers of the plant initially form in the meristems. The conversion of organ drafts to mature organs requires precise control of the elongation of these cells.

Mutations affecting the control of elongation lead to significant changes in the appearance of plants. Thus, in Arabidopsis thaliana, mutants called "barrel" have been observed, which have a phenotype very affected compared to the wild type. These plants are capable of generating root, leaf and floral primordia, without being able to make them grow and give them an appropriate mature form. They have a strong shortening of the roots, stems and leaf petioles, as well as floral and reproductive organs.

All the organs are present, but have a modified size and shape. The cotyledons, smaller in size than those of the wild type, have an increased thickness. The hypocotyle and the root, very short and of large diameter, elongate little during development. Numerous root hairs, secondary roots and small, scaly, fleshy leaves appear. After 8 to 10 weeks of cultivation in vi tro, a flower stalk develops with sterile flowers strongly modified, as well as secondary ramifications. Studies of embryo development carried out by the team of inventors on tonneaul (tonl) mutants of Arabidopsis thaliana, have shown that the zygote was affected from the first mitosis by a modification of the orientation of the division plan [ TRAAS et al., Nature, 375, 676-677, (1995)]. This alteration continues at later stages through a disruption of cell divisions resulting in a change in the shape and size of cells compared to the wild type.

It is generally accepted that the cytoskeleton is involved in cell elongation and the establishment of the division plane. During cell division, the microtubules organize themselves to form a structure called: "preprophase ring", which will precisely determine the location of the division plane, where the phragmoplast will be formed and the future wall constructed. Microtubule polymerization inhibitors also block cell lengthening processes, revealing their role in this process.

The inventors studied the organization of the cytoskeleton in wild seedlings of Arabidopsis thaliana and in seedlings of the tonl mutant. Thanks to immuno-archings performed using tubulin-specific antibodies, they have thus shown that at interphase, the cortical microtubules of wild plant cells are arranged perpendicular to the elongation axis of the cell, while they are distributed randomly in the mutant cells. In mutant cells, the achromatic spindle is correctly positioned but the preprophase ring is never present, which results in a random orientation of the division plane [TRAAS et al., Publication cited above]. The Inventors have now isolated at

Arabidopsis thaliana, a TONNEAUl gene (TON1) whose mutation is responsible for the “TONNEAU” phenotype described above. They also identified homologs of this gene in other plants, in particular rice, and found that it was very conserved in higher plants (we observe for example 77% identity between the TONNEAUl gene of Arabidopsis and that of rice, and 36 contiguous amino acids identical in the two proteins).

The sequence of a genone DNA clone of Arabidopsis thaliana containing 2 copies of the TONNEAUl gene, called TONla and TO-Vlb, is represented in the sequence list in the appendix under the number SEQ ID NO: 1. The sequences of the proteins TONla and TONlb are respectively represented under the numbers SEQ ID NO: 2 and SEQ ID NO: 3. The sequence coding for a TONNEAU1 protein from rice and the corresponding peptide sequence are respectively represented under the numbers SEQ ID NO: 4 and SEQ ID NO: 5.

The subject of the present invention is a method for controlling the process of division and / or elongation of eukaryotic cells, and in particular of plant cells, characterized in that the expression and / or activity of a TONNEAUl type protein in said cells. The present invention also relates to the use of a nucleic acid sequence derived from all or part of the sequence of a TONNEAUl type gene for obtaining a product making it possible to modify the expression and / or the activity of a TONNEAUl type protein in eukaryotic cells, and in particular plant cells.

For the purposes of the present invention, the expression “TONNEAUl type protein” means not only one of the proteins (SEQ ID NO: 2, SEQ ID NO: 3 or SEQ ID NO: 5) encoded by the TONNEAUl d genes. 'Arabidopsis or rice represented in figure 3, and in the list of sequences in the appendix, but also all the homologous proteins, which includes in particular the TONNEAUl proteins encoded by genes orthologous from other plants. Likewise, the term “sequence of a TONNEAUl gene” is understood to mean not only the sequence of any of the TONNEAUl genes from Arabidopsis or rice represented in FIG. 3 or in the sequence list in the appendix, but also the sequences of homologous genes, and in particular those of the orthologous genes of other organisms, and in particular of other higher plants. These genes can be easily identified and cloned on the basis of their homology with the TONNEAUl gene from Arabidopsis or its rice orthologue. "Nucleic acid sequences derived from all or part of the sequence of the TONNEAU1 gene" include in particular:

- the cDNA sequences of TONNEAU1 proteins or portions of these cDNA sequences, as well as their transcripts; it may for example be the whole of a sequence coding for a protein of TONNEAUl type, or a portion of this coding sequence, and / or all or part of the 5 'and 3' untranslated regions. These sequences can be used in sense or antisense orientation; - Nucleic acid sequences capable of being obtained by mutagenesis from the sequence of a gene of TONNEAUl type as defined above.

The modification of the expression and / or the activity of proteins of the TONNEAUl type in plant cells makes it possible, by acting on their development, to control the morphology and architecture of said plants, and in particular to change the size of the plant or that of some of these organs. For example, by totally or partially inhibiting the expression or activity of a TONNEAUl protein in a plant or in certain organs thereof, a reduction in the size of said plant or of said organs will be induced; on the contrary, if one overexpresses or activates the TONNEAUl protein, one will induce an increase in the size of the plant or organs concerned.

According to a preferred embodiment of the present invention, the expression and / or the activity of the TONNEAUl type protein is modified by mutagenesis of the gene coding for said protein.

This mutagenesis can be carried out by any suitable means, known in itself; it is possible, for example, to delete all or part of the TONNEAUl gene, and / or to insert an exogenous sequence; it is also possible to introduce one or more point mutations, to interrupt or shift the reading frame, or else to obtain a mutant TONNEAUl protein, more or less active than the wild-type protein; non-functional TONNEAU1 counterparts with a dominant antagonistic effect can also be produced.

The present invention also encompasses nucleic acid sequences capable of being obtained by mutagenesis from the sequence of a gene of TONNEAUl type as defined above, and in particular nucleic acid sequences capable of being obtained by introduction of a mutation capable of modifying the expression and / or the activity of the TONNEAUl protein. According to another embodiment of the present invention, the expression of the TONNEAUl protein is modified by associating a sequence derived from the sequence of a TONNEAUl gene with appropriate sequences for controlling transcription. For example, to regulate the expression level of a protein of the TONNEAUl type, it is possible to replace the natural promoter of this protein with a strong promoter, or on the contrary associate it with sequences of the silent type.

It is also possible to inhibit the expression of the TONNEAUl protein at the post-transcriptional level, by co-suppression or antisense suppression, by introducing into the cells recombinant DNA constructs producing in these cells sense or antisense transcripts derived from the cDNA. of this protein. The present invention also encompasses the recombinant DNA constructs making it possible to regulate the level of expression of a protein of TONNEAUl type, and containing at least one sequence derived from all or part of the sequence of a gene of TONNEAUl type, under transcriptional control of an appropriate promoter. Advantageously, it is possible, if desired, to use an inducible, and / or tissue-specific promoter.

The invention also encompasses recombinant vectors carrying the recombinant DNA constructs defined above, as well as cells and multicellular organisms transformed by these constructs; the present invention encompasses in particular plant cells or plants transformed by recombinant DNA constructs defined above.

According to yet another embodiment of the present invention, at least one product that inhibits or activates the TONNEAU1 protein is used.

One can for example, to inhibit the activity of TONNEAUl, use antibodies directed against this protein; they may in particular be recombinant antibodies produced in the plant concerned, or in certain tissues thereof.

TONNEAU1 inhibitor or activator products can also be selected on the basis of their selective affinity for this protein. These products can for example be screened on plant cells cultivated in vi tro, in which TONNEAUl is necessary for elongation, or on heterologous systems (bacteria, yeast) in which the TONNEAUl protein is expressed, or on acellular systems, by research of TONNEAUl interactions with various ligands.

Because of the essential role played by the TONNEAUl protein in the elongation process, the modification of its expression and / or of its activity finds numerous applications in the field of plant productions.

For example, to obtain a reduction in the size of a plant, it is possible, as indicated above, to inhibit the production of the TONNEAUl protein therein, by implementing conventional techniques such as antisense suppression, or co-suppression, or else inhibit the activity of TONNEAUl by the production of non-functional homologs of this protein with a dominant antagonist effect, or by the production of antibodies directed against TONNEAUl.

Advantageously, the expression or the activity of TONNEAUl can be blocked thanks to the use of an inducible promoter, in order to induce a phenomenon of dwarfism controlled over time, or else a selective inhibition can be obtained in the tissues. desired targets (eg stem, leaf petiole, floral organs) through the use of specific tissue-promoters. This makes it possible to selectively modify the architecture of the plant and to obtain, for example, a reduction in the size of the stem in cereals, in the lateral dimensions, and the height in hybrids, in particular hybrids of corn, rapeseed. and sunflower. This reduction in size allows for example to increase the harvest index, and / or to obtain better resistance to climatic hazards (lodging).

The modification of the expression and / or the activity of TONNEAUl can also make it possible to modify the floral architecture to induce a male sterility (by reduction of the size and blocking of the dehiscence of the anthers), to remove the petals (for example to produce apetal colza allowing better resistance to cryptogamic diseases, and better photosynthesis), or inducing female sterility of ornamental species in order to increase the flowering period.

The tissue-specific inhibition of the expression and / or activity of the TONNEAU1 gene can also relate to the root system, for example to control its development in pots in the case of ornamental plants.

In woody species, it is also possible to obtain an improvement in the quality of the fibers and the mechanical quality of the wood by reducing the elongation of the cells, or on the contrary by increasing it, by overexpression of TONNEAUl.

The activity of homologous proteins present in animal or plant eukaryotic cells can also be modified by means similar to those mentioned above for TONNEAUl. By acting on these proteins, it is thus possible, for example, to envisage controlling the multiplication of cells, their dispersion in the organism, and thus inhibiting, for example, the development of tumors.

The present invention will be better understood using the additional description which follows, which refers to nonlimiting examples illustrating the identification, cloning, and expression of TONNEAU1 genes. EXAMPLE 1: IDENTIFICATION OF THE TONNEAU GENE (S)

A tone-water phenotype mutant was identified during the screening of the collection of insertion mutants from INRA-Versailles. This mutant (ACL4) carries an insertion of a DNA fragment carrying a marker for resistance to anamycin. Out of 2256 seeds harvested from a heterozygous plant for the kanamycin resistance marker, 1710 descendants were normal, and 546 had the barrel phenotype. All mutants were resistant to kanamycin, indicating a close link between the tonneaul, nuclear recessive mutation and the inserted T-DNA fragment. Subsequently, a second T-DNA insertion, devoid of a functional kanamycin resistance marker, was identified.

In order to more precisely analyze the sites of T-DNA insertions, the inventors produced a genomic library of the mutant ACL4, because the sequences flanking the T-DNA could not be isolated by methods based on PCR. . The mapping of the sequences flanking the two insertions highlights the presence of chromosomal rearrangements: a reciprocal translocation involving the bottom of chromosomes 2 and 3 (bearing approximately on 20 centiMorgans) and an inversion bearing on 40 centiMorgans corresponding to the central part of chromosome 2 Furthermore, the results of mapping the mutation go in the same direction since markers of chromosome 2 and chromosome 3 are closely linked to the mutation, and recombinations are blocked on a large part of chromosome 2.

Molecular analyzes carried out on individual mutant seedlings revealed that 30% of the mutants had a translocated chromosome 2 and a wild type chromosome 2, and 70% 2 chromosomes 2 translocated. In addition, all the mutants tested have 2 copies translocated for chromosome 3.

These elements led the inventors to analyze the bottom region of chromosome 3, close to the markers cdc2B and BGLl [LISTER and DEAN Weeds World, 4 (i), 1-10 (1997)] involved in the insertion of DNA- T to identify the gene causing the tone phenotype. Two banks of artificial bacterial chromosomes (BAC = Bacterian Artificial Chromosome), the bank "TAMU" accessible at the address: http://aims.cps.msu.edu/aims/ and the bank "IGF" accessible at the address : http://www.rzpd.de/ were screened on the basis of the sequences flanking the T-DNA insertions of the mutant ACL4. Five BAC clones were isolated and a restriction map made it possible to position them in relation to each other. These clones and the corresponding restriction map are represented in FIG. 1. The clone BAC 2F19 from the TAMU library, and largely covering the region of the T-DNA insertion site was used for the various analyzes; and SalI lXhoI and Sall l PvuII fragments were subcloned, partially sequenced and used for functional complementation analyzes. Figure 1 legend:

The sequences flanking the isolated T-DNA insertions which were used as probes to screen the two genomic libraries of BAC type are represented by a black band. The five isolated BAC clones are represented by hatched bands. The position of the SalI lXhoI and Sall l PvuII fragments of the clone BAC 2F19 which have been isolated and used for the functional complementation analyzes of the mutants is indicated at the bottom of the figure. A 7.1 kbp portion of the SalI lXhoI fragment which has been subcloned and sequenced is represented by a double hatched arrow. The Southern type molecular hybridizations and PCR analyzes revealed a duplication of the TONNEAUl genes {cf. example 2 below). These 2 genes are represented by the black arrows. EXAMPLE 2: IDENTIFICATION OF TWO HOMOLOGOUS GENES PRESENT AT THE TONNEAU LOCUS

In order to detect possible rearrangements or deletions in the cloned fragment, the 7.1 kbp sequence isolated from BAC 2F19 (cf. FIG. 1) was compared with the sequences flanking the T-DNA insertions in the ton1 mutants. ACL4.

This comparison revealed, in the latter, a 1.4 kbp deletion at the insertion point of the T-DNA. PCR amplifications were then carried out using the genomic DNA of the tonl mutant ACL4, and the DNA of BAC 2F19, using different primers. The position of these primers is indicated in FIG. 2 and in FIG. 3. The first amplification was carried out with the primers P5 (located in the deletion in the ton1 mutants) and P6. No amplification was expected in the mutant type plants while the expected size of the amplified fragment was 430 bp in the wild type genomic sequences. Now, surprisingly, an amplification product of 330 bp was obtained in the mutant type plants, and two amplification products of 330 and 430 bp for the wild type sequences. The sequencing of these fragments of 330 and 430 bp shows that they have an identity of 95.1% and 93.5% at their terminal regions, while this identity decreases sharply in the central part. Analysis of other sequences obtained from this region (fragment amplified by the primers TIAf and T2Br) has shown that the two conserved regions correspond to two fragments of exons flanking an intron. These results indicate the presence, at the level of the affected sequence in the ton1 mutants, of a second gene having homology with the first. EXAMPLE 3 ISOLATION AND SEQUENCING OF TON1 GENES In order to analyze the regions affected by the deletion in tonl mutants, and to establish the degree of identity between the two homologous genes affected by this mutation, the wild type genomic region a been cloned and sequenced. Preliminary hybridization and amplification analyzes did not reveal any significant difference between the plant genomic DNA (type S) and the DNA extracted from the selected BACs (ColO), the 7.1 kb fragment DNA isolated from BAC 2F19 was used for cloning and sequencing. This fragment was subcloned into the plasmid pBSIISK (STRATAGÈNE) and sequenced. The DNA strands synthesized from PCR primers labeled “PRISM Ready Reaction Dye Primer Cycle Sequencing Kit” (APPLIED BIOSYSTEMS) are then separated on denaturing polyacrylamide gel and analyzed using an automatic sequencer (APPLIED BIOSYSTEMS; Model 373A DNA Sequencing System).

The sequence obtained was compared with banks of "EST" (Expressed Sequence Tag). This comparison made it possible to identify different ESTs having sequence similarities with the TON1 proteins, and in particular an EST isolated in rice (number identification: D39592) homolog of these sequences. The corresponding clone (S1091) supplied by MAFF DNA Bank (1-2, 2-chome, Kannondai, Tsukuba, Ibaraki 305, JAPON), was found after sequencing, to a complete cDNA of 1083 bp, coding for a protein of 261 amino acids.

The position of introns and exons was defined on the one hand using the NETPLANTGENE software [HEBSGAARD et al. , Nucleic Acids Res. , 24, 3439-3452 (1996)] and on the other hand thanks to comparisons with the cDNA sequences isolated from a library of Arabidopsis [QUAEDVLIEG et al. , Plan t Cel l, 7, (1), 117-129 (1995)] and the sequences of 3 'RACE PCR products isolated (see example 4 below) from primers P5 and P8 (Marathon cDNA amplification Kit ; CLONTECH).

The structure and the sequence of the TONNEAU1 genes of Arabidopsis are represented in FIGS. 2 and 3. Caption of FIG. 2:

Figure 2 shows schematically the structure of the 2 TONNEAUl genes; the 1.4 kbp deletion at the T-DNA insertion point in the tonl mutant is represented by a double black arrow. The two genes TONla and TONlb are represented by black arrows. These 2 genes are separated by 220 bp.

Exons are represented by black boxes. The hatched areas correspond to the untranslated transcribed sequences. The location and size of introns and exons is very conserved, except for the sixth intron of the TONla gene which is absent in the TONlb gene.

The positions of the donor and acceptor splice sites are represented by square brackets. The associated figures correspond to the probability that the detected sequence is a splicing site.

The arrowheads indicate the position of the different primers used during the characterization of the ton1 mutants. The black arrowheads correspond to the defined primers and the gray arrowheads correspond to the sequences homologous to the defined primers. The sizes of the corresponding amplification fragments are also indicated.

The sequence of the 7.1 kbp fragment isolated from BAC 2F19 is shown in the list of sequences in the appendix under the number SEQ ID NO: 1, as well as in Figure 3 (3a to 3k). Figure 3 legend:

The amino acids corresponding to the exons are shown in capitals.

The cDNA sequences isolated from the Arabidopsis library, the rice cDNA (S1091), and the 3 'RACE PCR product sequences isolated from the primers P5 and P8 are indicated in bold, respectively. characters highlighted in gray, and in italics.

The underlined sequences correspond to the different PCR primers. The primers whose name is shown in italics correspond to the sequences homologous to the primers defined from the sequence. The boxes correspond to the polyadenylation sites of the cDNAs. The hatched boxes correspond to the beginning and the end of the deletion induced by the insertion of T-DNA.

The results presented in FIGS. 2 and 3 show that the two genes TONla and TONlb are positioned in direct tandem and separated by 220 bp. The TONla gene consists of 8 exons with an average size of 98 nucleotides; the average size of the introns is 168 bp. The TOΝlb gene consists of 7 exons with an average size of 110 nucleotides; the average size of the introns is 214 bp.

The comparison of the wild type and mutant type sequences shows that the deletion induced by the insertion of ADΝ-T affects the two genes TOΝla and TO-Vlb. It induced the disappearance of the C-terminal part of the TOΝla protein (corresponding to the last 97 amino acids) and the Ν-terminal part of the TOΝlb protein (corresponding to the first 29 amino acids). Furthermore, the comparison between the sequences flanking the ADΝ-T insertions and the region containing the TONNEAU1 genes confirms that the insertion (and the associated chromosomal rearrangements) did not induce other changes in the nucleotide sequence.

EXAMPLE 4: EXPRESSION OF THE GENES TON1A AND TON1B

The genomic organization of the region affected by the insertion of T-DNA in tonneaul mutants is unique since it contains a gene duplicated in direct tandem. The question of the functionality and the simultaneous expression (or not) of these genes arises. Screening of a cDNA library (approximately 500,000 clones) made it possible to isolate four independent clones. After analysis and sequencing, all four were found to correspond to the TO lb gene.

In addition to screening this bank, RACE PCR reactions were carried out. This method makes it possible to isolate by PCR amplification the 3 ′ or 5 ′ parts of a transcript (even if weakly expressed) from a primer internal to the gene of interest and from a primer positioned on an adapter ligated at the ends. synthesized cDNA. The amplifications were carried out on cDNAs produced from messenger RNA isolated from seedlings of the S ecotype 5 days old. The 3 'RACE reactions were carried out using primers P5 and P8. The 3 'part of the two genes was thus obtained. The 3 'part of the TON 1a gene was isolated by amplification from the primer P8 while that of the TON1b gene was obtained from the primer P5. The amplifications thus obtained demonstrate that the two genes TO-vla and TONlb are expressed in seedlings 5 days old. The different sequences corresponding to RACE PCR products, to rice and Arabidopsis cDNAs, and the sequences deduced from the genomic sequence were compared. The results of these alignments are shown in Figure 4. The sequence alignment analyzes were performed using the Pileup function of the GCG software. (isconsin Package Version 9.0, Genetics Computer Group, Inc. (GCG) Madison Wisc, USA). The homology searches were established by SeqVu 1.1 software (The Garvan Institute of Medical Research, Sydney, Australia) using the GES method. The gray boxes represent the identical amino acids The white boxes inside the blocks represent the homologous amino acids.

The translated sequences correspond respectively to the cDNA isolated in rice (tonlriz .p), to the sequences deduced from the genomic sequence of ¹ Arabidopsis (tonla .p and tonlbg.p) and the cDNA isolated in the bank of 'Arabidopsis (tonlbc .p).

These results show that the sequences isolated by RACE PCR (WS ecotype) are perfectly identical to those deduced from the nucleotide sequence isolated from the BAC (ColO ecotype). The protein sequences corresponding to the TO-Vla and TOWlb genes have a high identity rate (80%). The level of identity reaches 96% on the first three exons. A high level of identity (67%) and homology (79%) is also obtained between the protein sequences corresponding to the TOItfla gene and to the cDNA isolated from rice. These levels of identity and homology are slightly lower in the case of the TONlb protein.

FIG. 5 represents the comparison of the protein sequences deduced from the TONNEAU1 genes, from the orthologous gene in rice, and from several ESTs homologous to mammals or parasites (identified as described in Example 3).

EXAMPLE 5: COMPLEMENTATION OF TON MUTANTS!

To confirm the direct relationship between the insertion of T-DNA and the tone mutant phenotype! the mutants were complemented by the introduction of a wild type copy of the TONNEAU1 gene. To do this, several constructions were carried out in using as vector the binary plasmid pZPHYG. This plasmid is derived from the vector PZP200 [HAJDUKIEWICZ et al. , Plant Mol. Biol. , 25, 989-994 (1994)] into which the gene coding for hygromycin B phosphotransferase (HPT) has been introduced. This gene, under the control of promoters and terminators of nopaline synthase derived from the plasmid pGDW32 [WING et al., Mol. Gen. Broom. , 219, 9-16, (1992)] gives plants resistance to hygromycin. These constructions are represented on the

Figure 6.

Constructions 1 and 2 contain the 12 kbp (Sall / Xhol) and 7.2 kbp (Sall PvuII) genomic fragments isolated from BAC 2F19 and corresponding respectively to the two TONla and TONlb genes or to the TONla gene. These TONNEAU1 genes are represented in Figure 6 by black arrows.

Construction 1 contains the two TONla and TONlb genes (Sall-Xhol fragment) while construction 2 contains only the TONla gene (Sali-PvuI I fragment).

Construction 3 was carried out from the cDNA of the full-length TONlb gene from the Arabidopsis library. This cDNA was cloned between the double promoter of the cauliflower mosaic virus (Prom70 CAMV) and the terminator of the cauliflower mosaic virus (Ter CAMV) derived from the plasmid pJIT60 [GUERINEAU et al., Plant Mol . Biol. 18 (4), 815-818 (1992)].

A negative complementation control (binary vector only) was also used to evaluate the effect of infiltration on the segregation frequencies of the TONNEAUl mutation and thus to obtain mutants carrying the gene for resistance to hygromycin.

These constructs were introduced into the Agrobacterium tumefaciens C58C1 strain, pMP90 [KONCZ and SCHELL, Mol. Gen. Genêt, 204, 383-396 (1986)] by electroporation. The recombinant strains were used to transform plants of Arabidopsis heterozygous for the ton1 mutation.

Two series of infiltrations (transformation in planta) [BECHTOLD et al .., C. R. Acad. Sci. Paris, 316, 1194-1200, (1993)] relating to 75 heterozygous plants for the tonneaul mutation and 50 wild type plants were produced for each of the constructions. The plants (TO) were harvested and the primary transformants (Tl) sown in vitro. The seeds from heterozygous plants for the TONNEAUl mutation were subjected to a double selection. Thus, the sowing was carried out on hygromycin (75 μg / ml), and after one week of culture, the resistant seedlings were transplanted onto medium containing kanamycin (100 μg / ml). The seedlings showing resistance to the two selection agents were transplanted in the greenhouse. The progeny of these plants (T2) were used for genetic complementation analyzes. At the same time, wild type plants (WS) were treated according to this same protocol (except for the selection of transformants which is done only on hygromycin).

The Tl seedlings selected in a fraction (1/8) of the progeny of infiltrated plants (heterozygous plants for the tonl mutation) are distributed as follows: 22 and 31 for constructions 1 and 2, 43 for construction 3, and 15 for the construction 4. The different seedlings transferred to the greenhouse had a wild phenotype during transplanting, except for one of them (obtained from construction 3).

After a few weeks of cultivation in a greenhouse, two plants showing a developmental defect were isolated among the plants having a wild phenotype during transplanting. These transformants obtained from construction 3, presented an increase in the diameter and a strong reduction in the elongation of the flower stalks as well as an "embossing" of the leaves. During flowering, the first flowers and the first pods placed seemed little affected; however, the flowers produced subsequently presented an increasingly affected phenotype, leading to flowers almost identical to barrel-type flowers (reduction in the size of the floral organs, deformation and shortening of the pods more and more important). Unlike the flowers, the floral peduncles were only slightly affected. After two months of cultivation, the flower stalks showed wounds (bursting of the stems) and an increase in diameter in the apical part. These developmentally impaired plants were isolated from the progeny of plants heterozygous for the tonl mutation and transformed with construct 3. No plants with a similar phenotype were observed among the transformants obtained with the other constructs or in the progeny wild type plants (even transformed with construction 3).

The allelic structure for the ton1 mutation was tested by PCR amplifications in these plants. Amplifications carried out using a specific primer located inside the deletion and a primer outside the deletion show that the seedlings are of mutant genotype.

The presence of T-DNA insertions carrying the TON1b cDNA was also tested by PCR amplification. The primers P5 and P10 amplify in these plants a fragment of 950 bp corresponding to the size expected for amplification from a TON1 cDNA. A fragment of identical size was also amplified from the DNA of the different transformants obtained by infiltration with the bacterial strain containing the construction 3. These plants with an intermediate phenotype therefore correspond to a partial restoration of the tone phenotype. Certain plants of wild phenotype have a homogeneous kanamycin-resistant progeny, they carry a T-DNA insertion at the TON locus in the homozygous state, however in their progeny plants of the ton phenotype are observed. These plants are mutants restored by the presence of a functional TON gene which confirms the nature of the two identified candidate genes, targets of the mutation.

Claims

1) Method for controlling the division and / or elongation of eukaryotic cells, and in particular of plant cells, characterized in that the expression and / or activity of a protein of the TONNEAUl type is modified in said cells.

2) Method according to claim 1, characterized in that one modifies the expression and / or the activity of said protein by mutagenesis of a gene of TONNEAUl type.

3) Nucleic acid sequence capable of being obtained by mutagenesis of the sequence of a TONNEAUl type gene.

4) Method according to claim 1, characterized in that the expression of said protein of type TONNEAUl is modified by expressing at least one sequence derived from all or part of the sequence of a gene of type TONNEAUl under transcriptional control of appropriate sequences. 5) Method according to claim 4, characterized in that said derived sequence is a sequence coding for a protein of type TONNEAUl.

6) Method according to claim 4, characterized in that said derived sequence is an antisense sequence.

7) Method according to claim 4, characterized in that said derived sequence is a mutant sequence according to claim 3.

8) Use of a nucleic acid sequence derived from all or part of the sequence of a TONNEAUl type gene for obtaining a product making it possible to modify the expression and / or the activity of a protein TONNEAUl type in eukaryotic cells. 9) Construction of recombinant DNA containing at least one nucleic acid sequence derived from any or part of the sequence of a TONNEAUl type gene under transcriptional control of an appropriate promoter.

10) Construction of recombinant DNA according to claim 9, characterized in that said promoter is an inducible promoter, and / or tissue-specific.

11) Cell transformed by a nucleic acid sequence derived from all or part of the sequence of a TONNEAUl type gene.

12) Cell according to claim 11, characterized in that it is a plant cell.

13) Transgenic plant, transformed by a nucleic acid sequence derived from all or part of the sequence of a gene of TONNEAUl type.

14) Process according to claim 1, characterized in that the expression of the TONNEAUl type protein is modified by using at least one inhibitor or activator product of said protein.

15) Method according to claim 1, characterized in that it is implemented to control the size of a plant, or at least one organ thereof.