The effects of aberrant chromosomes on variegation and crossing over in Drosophila melanogaster

Garland, Maureen Rosina

January 1966

It has been suggested (Suzuki, 1965a) that the extrinsic and intrinsic factors which increase crossing over in the centromere regions of Drosophila do so by inactivating these regions at the time of crossing over; the inactivation resulting in altered chromosome structure which permits the intimate synapsis necessary for crossing over. This hypothesis predicts that the 3L heterochromatic marker w⁺ carried in Dp(wm)264.58a, which exhibits position effect variegation, would tend to be inactivated by chromosome aberrations, known to increase crossing over. The reversed acrocentric (RA) compound X chromosome, the X chromosome inversions sc⁴sc⁸ and sc⁸, the autosomal inversions Cy, Sb, and Ubx, and the Minute mutants M(2) and M(3) were tested for their effects on the expression of w⁺ in various coisogenic stocks. The amount of pigment in each eye was visually scored into twelve classes. Crossover analyses of the centromere regions of chromosomes 2 and 3 were performed to confirm the effects of sc⁴sc⁸, Cy, Ubx, and Sb on crossing over. The RA, sc⁴sc⁸, Cy, and Ubx all increase crossing over and significantly depress the activity of w⁺. The degree of pigment reduction is correlated with the amount of increase in crossing over. Combination of these aberrations produces an effect on pigmentation and crossing over greater than that produced by either considered singly. Sb has a slight effect in increasing crossing over and decreasing pigmentation. M(3), known to increase crossing over, significantly decreases pigmentation whereas M(2) does not. The effect of the X chromosome inversion sc⁸ is doubtful. Expression of w⁺ is affected similarly in males and females, an observation suggesting that the chromosome physiology of both sexes is similar although the actual factor(s) mediating crossing over are absent in the males. These results lend support to the proposed hypothesis but, with fluctuating parental source effects and variations found within a stock testifying to the general lability of the system, further tests under stringently controlled conditions are necessary before such experiments can be considered critical. / Science, Faculty of / Zoology, Department of / Graduate

Drosophila melanogaster

Chromosomes

Crossing over (Genetics)

Influence of chromosomal aberrations on meiotic non-disjunction in Aspergillus.

Pollard, D. Russell (Donald Russell).

January 1966

No description available.

Crossing over (Genetics).

Chromosome abnormalities.

Genetics.

Aspergillus.

Role of recombinaison proteins in crossover formation, pairing and synapsis in Arabidopsis meiosis : Physiologie et génétique moléculaires / Rôle des protéines de recombinaison dans la formation crossing over, l'appariement et la synapse dans la méiose d'Arabidopsis

Singh, Gunjita

09 October 2017

Manifestation visible des cross-overs génétiques, les chiasmata lient les paires de chromosomes homologues afin de les orienter correctement sur le fuseau méiotique en Métaphase et Anaphase I. Ils résultent d'un processus complexe et étroitement régulé impliquant l'induction de cassures double-brins et de leur réparation par l'invasion d'un duplex d'ADN homologue faisant office de modèle. La recombinaison est ainsi essentielle pour le synapsis et la ségrégation correcte des chromosomes méiotiques à la première division méiotique, et pour la génération de la variabilité génétique. Bien que les processus permettant à un chromosome de s'apparier seulement à son homologue ne soient pas complètement élucidés, l'appariement des chromosomes homologues est étroitement lié à la recombinaison catalysée par les enzymes d'échange de brins d'ADN RAD51 et DMC1. Ces deux protéines ont des capacités très similaires in vitro, mais sont fonctionnellement distinctes in vivo.La première partie de ma thèse montre l'impact de l'élimination de l'activité d'échange de brins de RAD51 dans la méiose d'Arabidopsis, tout en conservant sa fonction de facteur accessoire pour l'action de DMC1. La recombinaison peut donner lieu à des cross-over (CO) et non-cross-over (NCO) et la recombinase spécifique de la méiose DMC1 a été jugée particulièrement importante dans la production de CO interhomologue. Des résultats récents suggèrent fortement toutefois que DMC1 est la seule recombinase active dans la méiose et doit donc être responsable des résultats de CO et NCO. Etant donné qu'environ 95% de la recombinaison méiotique homologue dans Arabidopsis n'entraîne pas de cross-overs interhomologues, Arabidopsis est un modèle particulièrement sensible pour tester l'importance relative des deux protéines - même des effets mineurs sur la population d'événements non-cross-over devraient produire des effets détectables sur les cross-overs. DMC1 catalyse la réparation de toutes les cassures d'ADN méiotiques en présence d'une protéine RAD51 catalytiquement inactive (fusion RAD51-GFP), et les résultats de mon travail montrent que cela n'a pas d'effet détectable sur les taux relatifs de recombinaison de CO et de NCO : à la fois localement, à l'échelle du chromosome et du génome. Et non plus sur la progression de la division méiotique. Ce travail a abouti à une publication dans le journal PLoS One (Singh G, Da Ines O, Gallego ME & White CI (2017) Analyse de l'impact de l'absence d'activité d'échange de brins de RAD51 dans la méiose d'Arabidopsis PLoS ONE 12: e0183006- 16).Des publications antérieures montrent une synapsis homologue partielle et incomplète en l'absence de rad51 et xrcc3 dans la méiose d'Arabidopsis. Cela s'accompagne de la présence de nombreuses fibres courtes ZYP1 dans ces noyaux, ce qui pourrait indiquer de faibles longueurs de complèxe synaptonémale (SC). Ce synapsis partielle dépend à la fois de SPO11 et de DMC1 et implique des péricentromères, montrant que DMC1 est capable (au moins partiellement) d'entraîner le synapsis dans les péricentromères en l'absence de RAD51. Afin de mieux caractériser ceci et pour tester l'hypothèse que les fibres ZYP1 courtes montrent la présence d'une initiation de SC à ces sites, j'ai méné des expériences d'immunofluorescence et d'imagerie SIM. Utilisant un coloration DAPI et les antiséra ASY1, ZYP1 et CENH3, j'ai conduite des analyses cytogénétiques de le synapsis dans les mutants rad51, xrcc3 et des plantes sauvages. Ces travaux faisaient l'objet de la deuxième partie de mes travaux de thèse. Dans les plantes mutantes, j'observe effectivement des fibres courtes ZYP1 comprenant des centromères, mais elles ne sont pas la règle, ce qui signifie que le synapsis ne commence pas nécessairement à des centromères ou des péricentromères. (...) / The visible manifestation of genetic crossing-over, chiasmata link homologous chromosome pairs to permit them to properly orient on the meiotic Anaphase I spindle. They are the result of an intricate and tightly regulated process involving induction of DNA double- strand breaks and their repair through invasion of a homologous template DNA duplex. Recombination is thus essential for the synapsis and accurate segregation of meiotic chromosomes at the first meiotic division, and in doing so, generates genetic variation. Although the processes permitting a chromosome to pair only with its homologue are not fully understood, successful pairing of homologous chromosomes is tightly linked to recombination catalysed by the DNA strand exchange enzymes RAD51 and DMC1. Both proteins share very similar capabilities in vitro, but are functionally distinct in vivo. The first part of my thesis shows the impact of eliminating the strand exchange activity of RAD51 in Arabidopsis meiosis, while retaining its function as an accessory factor for the action of DMC1. Recombination can give rise to both crossover (CO) and non-crossover (NCO) outcomes and the meiosis-specific recombinase DMC1 has been thought to be of particular importance in the production of inter-homolog CO. Recent results however suggest strongly that that DMC1 is the only active recombinase in wild-type meiosis and thus must be responsible for both CO and NCO outcomes. Approximately 95% of meiotic homologous recombination in Arabidopsis does not result in inter-homologue crossovers and Arabidopsis is thus a particularly sensitive model for testing the relative importance of the two proteins - even minor effects on the non-crossover event population should produce detectable effects on crossing-over. DMC1 catalyses repair of all meiotic DNA breaks in the presence of the catalytically inactive RAD51 (RAD51-GFP fusion) and the results of my work show that this has no detectable effect on the relative rates of CO and NCO recombination, both locally and chromosome- and genome-wide, nor on the progression of the meiotic division. This work has resulted in a publication in the journal PLoS One (Singh G, Da Ines O, Gallego ME & White CI (2017) Analysis of the impact of the absence of RAD51 strand exchange activity in Arabidopsis meiosis. PLoS ONE 12: e0183006–16).Previous publications show partial, incomplete homolog synapsis in the absence of rad51 and xrcc3 in Arabidopsis meiosis. This is accompanied by the presence of many short ZYP1 fibres in these nuclei, possibly indicating short stretches of Synaptonemal Complex (SC). The partial synapsis is both SPO11- and DMC1-dependent and involves peri-centromeres, showing that DMC1 is able to (at least partially) drive synapsis in peri-centromeres in the absence of RAD51. In an effort to better characterize this and to test the hypothesis that the short ZYP1 fibres show the presence of initiation of SC at these sites, immunofluorescence and SIM imaging with DAPI staining and ASY1, ZYP1 and CENH3 antisera were carried out for cytogenetic analyses of synapsis in rad51 and xrcc3 mutants and the WT in the second part of my thesis work. Although I do observe short ZYP1 fibres including centromeres in the mutants, these are not the rule, so synapsis does not necessarily begin at centromeres or peri-centromeres. The superresolution imaging does confirm the presence of stretches of 4-chromatid fibres in xrcc3 plants and this approach will be extended in future work of the group to probe the nature of the RAD51-independent partial meiotic chromosome synapsis.Finally, I have designed and built CRISPR/CAS9 constructs with the aim of creating meiotic DSB hotspots at specific genomic loci. Taking advantage of single nucleotide polymorphism data, these constructs were designed to specifically cleave sites in the Arabidopsis Col-0 ecotype, and not in Ler-0 plants. (...)

Crossing over

Recombinaison

Rad51

DMC1

Arabidopsis thaliana

Crossing over

Recombination

RAD51

DMC1

Arabidopsis thaliana

Towards a functional characterization of meiotic recombination in rapeseed : analysis of the meiotic transcriptome and hyper-recombinant mutants / Vers une caractérisation fonctionnelle de la recombinaison méiotique chez le colza : analyse du transcriptome méiotique et de mutants hyper-recombinants

Blary, Aurélien

20 December 2016

La recombinaison méiotique produite par les Crossing Overs (COs) est un facteur limitant pour l’efficacité de la sélection variétale. Une possibilité pour produire des plantes hyper-recombinantes serait d’exploiter la variabilité intraspécifique pour les fréquences de recombinaison. L’identification des polymorphismes causaux, liés à la séquence ou l’expression, représente un travail de longue haleine. Une approche alternative serait de produire des mutants pour des régulateurs négatifs des fréquences de recombinaison. Chez le colza, jeune allotétraploïde (AACC, 2n=38), il est possible de jouer sur ces 2 approches. Dans un premier temps j’ai cherché à vérifier dans quelle mesure pouvait varier le transcriptome méiotique entre 2 variétés ayant servi à cartographier un QTL pour le contrôle de la recombinaison entre chromosome homoéologues (hérités des génomes parentaux). Ce transcriptome méiotique s’est révélé de façon inattendue très variable ; les principales sources de cette variation étant notamment la nature du génome (A ou C) ainsi que l’effet variété. J’ai montré que les HEs (le remplacement d’une région chromosomique par la duplication de la région homoéologue) contribuent de façon importante aux différences d’expression observées à la fois entre variétés ou au sein d’un même génotype. Dans un second temps, j’ai vérifié que FANCM décrit chez Arabidopis thaliana comme un régulateur négatif pour les fréquences de recombinaison avait bien la même fonction chez les Brassica. Chez Brassica rapa j’ai vérifié qu’un mutant fancm complémente comme attendu un mutant déficient pour la voie majoritaire de formation des COs. Chez Brassica napus j’ai observé une faible augmentation à la fois des fréquences de recombinaison entre chromosomes homologues et homoéologues. Ce travail souligne l’importance de la caractérisation des HEs chez les allopolyploïdes. Au-delà de leurs impacts sur le contenu et l’expression génique, les HEs ont très certainement des conséquences phénotypiques. Cette étude présente aussi un exemple de biologie translationnelle pour un trait important en amélioration des plantes. / Meiotic recombination driven by Crossing-Over (CO) is a limiting factor for the efficiency of plant breeding. One way to produce hyper-recombinant plants is to use the existing interspecific variability for recombination frequencies. Identification of the causal polymorphisms, either link to gene sequence or expression, represents a long-term endeavour. Another possibility is to mutate anti-meiotic CO genes. In rapeseed, a young allotetraploid species (AACC, 2n=38), both of these approaches are possible. First I wanted to check how much varies the meiotic transcriptome between 2 varieties that differ in term of recombination between homoeologous chromosomes (inherited from parental genomes). Unexpectedly, the meiotic transcriptome turned out to be very variable, the main source of this variation being notably the origin of the genome (A or C) and the variety. I also showed that homoeologous exchanges (HEs; the replacement of one chromosomal region with a duplicate of the homeologous region) contributed to this variation and led to large changes in expression both between and within varieties. Then I assessed whether FANCM, an anti-CO protein identified in Arabidopis thaliana had the same function in the Brassica genus. In Brassica rapa, a fancm mutant complements as expected a meiosis mutant defective in the main formation pathway for the formation of meiotic COs. In Brassica napus, I observed a slight increase in both homologous and homoeologous recombination frequencies. This work emphasizes the importance of characterizing HEs in allopolyploids species. Beyond their impact on gene content and expression, HEs most have likely phenotypic consequences. This study also presents an example of translational biology for an important trait in crop breeding.

Méiose

Recombinaison

Crossing-Over

Brassica napus

Polyploïdie

Meiosis

Recombination

Crossing-Over

Brassica napus

Polyploidy

Fine scale recombination variation in Drosophila melanogaster

Adrian, Andrew B.

01 December 2015

The study of natural variation is a principle component of biology. One process that affects levels of natural variation is meiotic recombination—the process by which homologous chromosomes break and interchange genetic information with one another during the formation of gametes. Surprisingly, this factor that shapes levels of natural variation across the genome itself presents with a great deal of variation. That variation manifests itself at many levels: within genomes, between individual organisms, across populations, and among species. The factors and mechanisms responsible for the non-random patterning of recombination events across the genome remain particularly elusive in most cases. Herein, I utilize a combination of bioinformatic and molecular genetic approaches to better explain recombination patterning. I explore several factors that are now known to contribute to the distribution of recombination events across genomes. In particular, I demonstrate that transcriptional activity during meiosis is associated with, and partially predictive of crossing over events in Drosophila melanogaster. Additionally, I present a model which is capable of accounting for approximately 40% of the variation in crossover rates in Drosophila based on the localization of several previously identified DNA motifs. Lastly, I present preliminary data describing how recombination patterns are altered under naturally stressful conditions, a key insight that is necessary for uniting our findings at one level of variation with the many others. These findings support a multifactorial model for crossover distribution that includes both genetic and epigenetic factors and will further progress the field in developing a comprehensive understanding of recombination localization.

Crossing over

DNA

DSB

Linkage

Polymorphism

Transcription

Biology

Causes and Consequences of Recombination Rate Variation in Drosophila

Stevison, Laurie S.

January 2011

<p>Recombination occurs during meiosis to produce new allelic combinations in natural populations, and thus strongly affects evolutionary processes. The model system Drosophila has been crucial for understanding the mechanics underlying recombination and assessing the association between recombination rate and several evolutionary parameters. Drosophila was the first system in which genetic maps were developed using recombination frequencies between genes. Further, Drosophila has been used to determine genetic and environmental conditions that cause variation in recombination rate. Finally, Drosophila has been instrumental in elucidating associations between local recombination rate and nucleotide diversity, divergence and codon bias, as well as helping determine the causes of these associations.</p><p>Here I present a fine-scale map of recombination rates across two major chromosomes in Drosophila persimilis using 181 SNP markers spanning two of five major chromosome arms. Using this map, I report significant fine-scale heterogeneity of local recombination rates. However, I also observed "recombinational neighborhoods", where adjacent intervals had similar recombination rates after excluding regions near the centromere and telomere. I further found significant positive associations of fine-scale recombination rate with repetitive element abundance and a 13-bp sequence motif known to associate with human recombination rates. I noted strong crossover interference extending 5-7 Mb from the initial crossover event. Further, I observed that fine-scale recombination rates in D. persimilis are strongly correlated with those obtained from a comparable study of its sister species, D. pseudoobscura. I documented a significant relationship between recombination rates and intron nucleotide sequence diversity within species, but no relationship between recombination rate and intron divergence between species. These results are consistent with selection models (hitchhiking and background selection) rather than mutagenic recombination models for explaining the relationship of recombination with nucleotide diversity within species. Finally, I found significant correlations between recombination rate and GC content, supporting both GC-biased gene conversion (BGC) models and selection-driven codon bias models. </p><p>Next, I looked at the role of chromosomal inversions in species maintenance by examining the impact of inversions distinguishing species to disrupt recombination rates within inverted regions, at inversion boundaries and throughout the remainder of the genome. By screening nearly 10,000 offspring from females heterozygous for 3 major inversions, I observed recombination rates within an inverted region in hybrids between Drosophila pseudoobscura and D. persimilis to be ~10-4 (similar to rates of exchange for inversion heterozygotes within species). However, despite the apparent potential for exchange, I do not find empirical evidence of ongoing gene exchange within the largest of 3 major inversions in DNA sequence analyses of strains isolated from natural populations. Finally, I observe a strong 'interchromosomal effect' with up to 9-fold higher (>800% different) recombination rates along collinear segments of chromosome 2 in hybrids, revealing a significantly negative association between interchromosomal effect and recombination rate in homokaryotypes, and I show that interspecies nucleotide divergence is lower in regions with larger changes in recombination rates in hybrids, potentially resulting from greater interspecies exchange. This last result suggests an effect of chromosomal inversions on interspecies gene exchange not considered previously.</p><p>Finally, I experimentally tested for a novel male-mediated effect on female recombination rates by crossing males that differed by either induced treatment variation or standing genetic variation to genetically identical females. After assaying recombination frequency in the offspring of these genetic crosses, I fitted these data to a statistical model where I showed no effect of male temperature treatment or male genetic background on offspring recombination rate. However, I did observe a difference of recombination rates of offspring laid 5-8 days post-mating between males treated with Juvenile Hormone relative to control males. Environmental variation in male ability to affect recombination rate in their mates suggests the potential for sexual conflict on optimal proportion of recombinant offspring, perhaps leading to changes in population-level recombination rates with varying levels of sexual selection.</p><p>Overall, my map of fine-scale recombination rates allowed me to confirm findings of broader-scale studies and identify multiple novel features that merit further investigation. Furthermore, I have identified several similarities and differences between inversions segregating within vs. between species in their effects on recombination and divergence, and I have identified possible effects of inversions on interspecies gene exchange that had not been considered previously. Finally, I have provided some evidence that males may impact female recombination rates, although future work should attempt to explore the range of male differences that impact this trait and the mechanism through which males impact the outcome of female meiosis.</p> / Dissertation

Genetics

crossing over

Drosophila

interchromosomal effect

inversions

recombination

speciation

The genetic structure of related recombinant lines /

Anderson, Amy D.

January 2003

Thesis (Ph. D.)--University of Washington, 2003. / Vita. Includes bibliographical references (p. 142-144).

Effect of B chromosomes on recombination frequency in maize

Khanna, Anupama Q. Weber, David F.

January 1998

Thesis (Ph. D.)--Illinois State University, 1998. / Title from title page screen, viewed July 5, 2006. Dissertation Committee: David F. Weber (chair), Marjorie A. Jones, Anthony Otsuka, Derek McCracken, Radheshyam Jayaswal. Includes bibliographical references (leaves 85-91) and abstract. Also available in print.

Diversité et déterminisme génétique de la recombinaison méiotique chez Saccharomyces cerevisiae / Diversity and genetic determinsim of meiotic recombination rate in Saccharomyces cerevisiae

Raffoux, Xavier

06 November 2018

L’agriculture moderne doit assurer notre sécurité alimentaire dans le contexte d’un changement climatique qui entraîne une baisse des rendements. Une meilleure compréhension des facteurs contrôlant la recombinaison méiotique ouvrirait la voie à la modification du nombre et de la répartition des crossing-overs, ce qui permettrait une localisation plus précise des facteurs génétiques contrôlant les caractères d’intérêt agronomique et faciliterait le pyramidage d’allèles favorables au sein d’un même génotype élite. Pendant ma thèse, j’ai développé une méthode de mesure à haut débit de la recombinaison chez la levure Saccharomyces cerevisiae pour étudier la diversité de la recombinaison et de l’interférence au sein d’une collection de 24 souches représentatives de la diversité de l’espèce ainsi qu’au sein d’un dispositif di-allèle à cinq parents. Les résultats montrent un nombre moyen de crossing-overs par méiose compris entre 24 et 61, ce qui est plus élevé que chez la majorité des autres espèces. Plus particulièrement, les profils de recombinaison diffèrent entre souches, atteignant un écart d’un facteur 9 dans certaines régions. Les souches originaires d’habitats peu stables n’ont cependant pas un niveau de recombinaison plus élevé que les souches originaires d’environnements stables. En outre, la plupart des souches montrent de l’interférence dont la force est corrélée positivement avec le niveau de recombinaison. L’étude de la relation entre niveau de recombinaison et similarité de séquence entre homologues, à différentes échelles locales ou globales, indique que la recombinaison est contrôlée à la fois par des éléments cis et des facteurs trans. Par ailleurs, l’hétérozygotie chez les hybrides a un effet négatif sur le niveau de recombinaison, mais les homozygotes ont aussi un niveau de recombinaison réduit par un effet de dépression de consanguinité. Ce travail permettra maintenant d’étudier la réponse de la recombinaison à la sélection et de détecter les QTL de nombre de crossing-overs, afin d’identifier des gènes qui contrôlent la recombinaison. / Modern agriculture must ensure food security in a context of climate change that will lower yields. A better understanding of the factors controlling meiotic recombination could pave the way to modifying the number and distribution of crossing-over, which would allow a more precise localization of genetic factors controlling agronomic traits, and facilitate gene pyramiding in selection programs. During my thesis, I developed a method for high-throughput measurement of recombination rates in the yeast Saccharomyces cerevisiae. This allowed me to study the diversity of recombination and interference in a collection of 24 strains representing most of the diversity of the species, as well as within a five-parent di-allele design. The results show an average number of crossovers per meiosis ranging between 24 and 61, higher than in the majority of other species. Furthermore, recombination patterns differ between strains, and ratios of local recombination rates show 9-fold differences in some regions. Strains from unstable habitats, however, do not have a higher level of recombination than those from stable environments. In addition, most strains show interference whose strength is positively correlated with the level of recombination. The study of the relationship between recombination rate and sequence similarity between homologs at different scales (from local to global) indicates that recombination is controlled by both cis elements and trans factors. Lastly, heterozygosity in hybrids has a negative effect on crossing-over, but homozygotes also have a reduced level of recombination due to inbreeding depression. This work will now be used to study the response of recombination to selection and to detect QTL of crossover number in order to identify genes controlling recombination.

Taux de recombinaison méiotique

Selection récurrente

Crossing-Over

Interférence

Diversité

Meiotic recombination

Reccurent selection

Crossing-Over

Interference

Diversity

Stimulation et contrôle de la recombinaison homologue chez le maïs pour augmenter l'efficacité du ciblage de gène et le brassage génétique

Ayar, Ayhan

19 March 2013

La recombinaison homologue est un mécanisme de réparation de l’ADN extrêmement contrôlé et particulièrement chez les eucaryotes supérieurs. Dans les cellules méiotiques de ces derniers, où les cassures doubles brin de l’ADN sont programmées, les voies de crossing-over de la recombinaison homologue, qui génèrent de nouvelles combinaisons de gènes, sont restreintes. Dans les cellules somatiques, la recombinaison illégitime, qui assure majoritairement la réparation des cassures double brin de l’ADN, limite l’intégration ciblée du transgène par recombinaison homologue. Les entreprises de biotechnologie convoitent de maitriser la recombinaison homologue afin de contrôler d’une part le brassage génomique qui a lieu pendant la méiose, et d’autre part l’intégration du transgène dans le génome. Cette étude a porté sur le développement d’outils afin d’atteindre ces deux objectifs. Afin d’augmenter le brassage du génome, ayant lieu pendant la méiose, une version du promoteur OsDmc1b, active dans les cellules méiotiques, a été caractérisée chez le maïs. Des plantes sur-exprimant le gène ZmSpo11.1, sous contrôle de ce promoteur, ont ainsi été développées afin d’obtenir des lignées potentiellement hyper-recombinantes. Si la surexpression de ZmSpo11.1 permet effectivement d’augmenter le taux de crossing-over, il pourra être utilisé par les sélectionneurs afin d’accélérer l’introgression d’allèles d’intérêt dans des variétés élites. Concernant la mise en place d’une technique de ciblage de gène, deux stratégies, reposant sur l’utilisation de la méganucléase I-SceI, ont été testées. La démarche a nécessité trois éléments : un locus cible contenant le site de coupure I-SceI, une matrice de réparation et la séquence codant I-SceI (ou I-SceI::GR). La première stratégie, consistant à retransformer les lignées présentant le locus cible avec la matrice de réparation et I-SceI, ne semble pas exploitable car aucun évènement de ciblage de gène n’a été mis en évidence. La seconde stratégie, reposant sur l’assemblage des trois éléments par croisement, est beaucoup plus prometteuse. Malgré la faible activité d’I-SceI::GR, des évènements de recombinaison homologue ont été observés dans les tissus foliaires de certaines plantes. Du cal embryogène, développé à partir de ces dernières, a permis de régénérer des plantes présentant des évènements de ciblage de gène. Ces travaux ouvrent de nouvelles perspectives dans l’élaboration contrôlée d’OGM. / Homologous recombination is a DNA repair mechanism highly regulated in higher eukaryotes. In their meiotic cells, where DNA double-stranded breaks are programmed, the crossing-over pathway of homologous recombination, which generates new gene combinations, is limited in activity and genomic distribution. In somatic cells, illegitimate recombination, which mainly ensures DNA double-strand repair, limits the targeted integration of transgenes by homologous recombination. Biotechnology companies aim to master homologous recombination to control on the one hand the genomic mixing that occurs during meiosis, and on other hand, the integration of transgenes into the genome. This study focuses on the development of tools to achieve these two objectives.To increase genome mixing occurring during meiosis, a version of the OsDmc1b promoter active in maize meiotic cells was isolated. Then, plants over-expressing the ZmSpo11.1 gene under control of this promoter have been developed to obtain potentially hyper-recombinant lines. If ZmSPO11.1 overexpression increases the crossing over rate, it can be used by breeders to accelerate the introgression of alleles of interest into elite varieties. For the establishment of a gene targeting technique, two strategies based on the use of the I-SceI meganuclease were tested. These approaches involved the use of three elements which are: a target locus containing the cleavage site of I-SceI, a repair template and the sequence encoding I-SceI (or ISceI::GR). The first strategy, consisting of the retransformation of target locus lines with the repair template and I-SceI, does not seem workable because no gene targeting events were isolated. The second strategy, based on the assembly of the three components by crossing, is more promising. Despite the low activity of I-SceI::GR, homologous recombination events were observed in leaf tissues of certain plants. Embryogenic callus, developed from these plants, permitted the regeneration of plants with gene targeting events. This work opens new perspectives in the development of controlled GMO production.

Maïs

Recombinaison homologue

Cassure double brin

Crossing-over

Méganucléase I-Scel

Ciblage de gène

Maize

Homologous recombination

Double strand break

Crossing-over

I-SceI meganuclease

Gene targeting