Dissertations / Theses on the topic 'Translocation (Genetics) Genetic recombination. Molecular genetics'

Successful bacterial circular chromosome segregation requires that any dimeric chromosomes, which arise by crossing over during homologous recombination, are converted to monomers. Resolution of dimers to monomers requires the action of the XerCD site-specific recombinase at dif in the chromosome replication terminus region. This reaction requires the DNA translocase, FtsK(C), which activates dimer resolution by catalysing an ATP hydrolysis-dependent switch in the catalytic state of the nucleoprotein recombination complex. We show that a 62-amino-acid fragment of FtsK(C) interacts directly with the XerD C-terminus in order to stimulate the cleavage by XerD of BSN, a dif-DNA suicide substrate containing a nick in the 'bottom' strand. The resulting recombinase-DNA covalent complex can undergo strand exchange with intact duplex dif in the absence of ATP. FtsK(C)-mediated stimulation of BSN cleavage by XerD requires synaptic complex formation. Mutational impairment of the XerD-FtsK(C) interaction leads to reduction in the in vitro stimulation of BSN cleavage by XerD and a concomitant deficiency in the resolution of chromosomal dimers at dif in vivo, although other XerD functions are not affected.

Meiotic recombination is a fundamental biological process in sexually reproducing organisms, enabling offspring to inherit novel combinations of mutations, and ensuring even segregation of chromosomes into gametes. Recombination is initiated by programmed Double Strand Breaks (DSBs), the genomic locations of which are determined in most mammals by PRDM9, a rapidly evolving DNA-binding protein. In crosses between different mouse subspecies, certain Prdm9 alleles cause infertility in hybrid males, implying a critical role in fertility and speciation. Upon binding to DNA, PRDM9 deposits a histone modification (H3K4me3) typically found in the promoters of expressed genes, suggesting that binding might alter the expression of nearby genes. Many other questions have remained about how PRDM9 initiates recombination, how it causes speciation, and why it evolves so rapidly. This body of work investigates these questions using complementary experimental and analytical methodologies. By generating a map of human PRDM9 binding sites and applying novel sequence analysis methods, I uncovered new DNA-binding modalities of PRDM9 and identified sequence-independent factors that predict binding and recombination outcomes. I also confirmed that PRDM9 can affect gene expression by binding to promoters, identifying candidate regulatory targets in meiosis. Furthermore, I showed that PRDM9’s DNA-binding domain also mediates strong protein-protein interactions that produce PRDM9 multimers, which may play an important functional role. Finally, by generating high-resolution maps of PRDM9 binding in hybrid mice, I provide evidence for a mechanism to explain PRDM9-mediated speciation as a consequence of the joint evolution of PRDM9 and its binding targets. This work reveals that PRDM9 binding on one chromosome strongly impacts DSB formation and/or repair on the homologue, suggesting a novel role for PRDM9 in promoting efficient homology search and DSB repair, both critical for meiotic progression and fertility. One consequence is that PRDM9 may play a wider role in mammalian speciation.

Includes bibliographies.
{59} leaves : ill. ; 30 cm.
Title page, contents and abstract only. The complete thesis in print form is available from the University Library.
The Polycomblike gene of Drosophila melanogaster is required for the correct spatial expression of the homeotic genes of Antenapaedia and Bithorax Complexes. This thesis describes the isolation and molecular characterization of the Polycomblike gene.
Thesis (Ph.D.)--University of Adelaide, Dept. of Biochemistry, 1995

Translocation of a 17.1 kilobase region of the OCT plasmid encoding mercury resistance (mer) in Pseudomonas putida was shown to occur in a recombination-deficient host with plasmid PP1 serving as a recipient replicon. The frequency of transposition in Pseudomonas was estimated at 10^3 -10 -^2, but undetectable in Escherichia soli. ' DNA comprising all of mr as well as subregions there of were cloned and subjected to DNA sequence analysis. Like other transposons, mer was found to contain inverted repeat sequences at its termini. These were similar to, but not identical to the inverted repeat structures found in the prototypical mercury resistance transposon Tn501 from E. aeruginosa.

Thesis (MSc (Genetics))--University of Stellenbosch, 2009.
Gene transfer from wild gras species to wheat is complicated by the simultaneous integration of large amounts of alien chromatin. The alien chromatin containing the target gene is inherited as a linkage block and the phenomenon is known as linkage drag. The degree of linkage drag depends on whether, and how readily, recombination occurs between the foreign and wheat chromatin. The S13 translocation line was developed by the department of Genetics, US. A cross was made between Chinese Spring and a leaf rust resistant Aegilops speltoides accession. Resistant backcross F1 was backcrossed to Chinese Spring and W84-17. S13 was selected from the backcross progeny and found to carry three rust resistance genes temporarily named LrS13, SrS13 and YrS13. Unfortunately, the resistance genes were completely linked to gametocidal (Gc) genes that were co-transferred from the wild parent. In wheat Gc genes cause reduced fertility, poor plant phenotype and hybrid necrosis. In order to use employ the rust resistance genes commercially they need to be separated from the Gc genes. At the onset of this study four putative shortened forms of the S13 translocation were provided. The four lines were identified in a homoeologous paring induction experiment (involving the test cross 04M127). This study aimed to achieve the following: (i) characterize the four recombinants with the use of molecular markers, (ii) use the knowledge gained to identify further recombinants in the 04M127 cross, (iii) identify the shortest (most useful) recombinant, and (iv) attempt to shorten the shortest recombinant form still further and thereby remove as many of the Gc genes as possible. In total, seven recombinants of the S13 translocation (04M127-1, -2, -3, -4, -7, -11 and -12; referred to as recombinant group A) were identified and characterised with microsatellite and SCAR markers. These recombinants have exchanged different amounts of foreign chromatin for wheat chromatin, but were still associated with Gc genes, showing hybrid necrosis and seed shrivelling. Some of the recombinants have lost the undesirable „brittle rachis‟ phenotype which occurs in Ae. speltoides and the S13 translocation line. In plants VII having this trait, the rachis spontaneously disarticulates after the third spikelet upon ripening of the ear. Recombinant 3 appeared to be least affected by Gc genes and was therefore used in further attempts to shorten the translocation. Recombinant 3 was crossed with wheat (W84-17) and resistant F1 (heterozygous for the translocation) were test crossed with Chinese Spring nullisomic 3A tetrasomic 3B/D plants. Thirty five resistant testcross F1 plants were identified (named recombinant group B). The resistant group B recombinants as well as nine susceptible test cross F1 (which also appeared to be recombinant) were characterised making use of microsatellites and a SCAR marker. From the results it appeared that each of the 35 resistant plants exchanged substantial amounts of Ae. speltoides chromatin for wheat chromatin. The species chromatin that remained (and which contains LrS13) is probably located either close to the 3AS telomere or within the proximal regions of 3AS and 3AL. A SCAR marker that has been developed specifically for the S13 translocation provided useful confirmation of the presence of Ae. speltoides chromatin in the 35 recombinants. If the SCAR marker proves to be tightly linked to LrS13 it may eventually be used for marker assisted selection of the resistance or it may be employed in continued attempts to reduce the amount of foreign chromatin. Seedling rust resistance tests showed that the recombinants have lost SrS13 and YrS1 during recombination. An attempt was also made to develop additional markers that specifically detect the translocation in order to further characterise the group B recombinants. Published information on Ae. speltoides specific repeated and transposon sequences were obtained and used for primer design. Unfortunately, no suitable markers could be found and the primers that were designed tended to amplify the same fragments in both the wheat and species genomes. DArT markers were also employed in an attempt to characterise the 35 group B recombinants and controls. The DArT results provided an independent verification of the results obtained with the microsatellite markers. The DArT results confirmed that the group B recombinants exchanged large amounts of species chromatin for wheat chromatin. Even though the 35 resistant group B recombinants have undergone extensive recombination they still show signs of residual Gc effects. It is believed these effects can be removed by continued backcrossing to wheat accompanied by selection against Gc symptoms. While the effects of Gc genes per se were not studied, their properties were reminiscent of those of transposable elements. Indications were that complex interactions involving the Gc genes themselves as well as genetic factors in the wheat genome may have a drastic effect on the selective survival of recombinant gametes.

How life originated from physical and chemical processes is one of the great questions still unanswered today. Studies towards this effort have transitioned from the notion of a single self-replicating entity to the idea that a network of interacting molecules made this initial biological leap. In order to understand the chemical kinetic and thermodynamic mechanisms that could engender pre-life type networks we present an empirical characterization of a network of RNA recombinase molecules. We begin with 1-, 2-, and 3-molecular ensembles and provide a game theoretic analysis to describe the frequency dependent dynamics of competing and cooperating RNA genotypes. This is then extended to 4- and 5-membered networks where varying topologies are compared and mechanisms that could lead to preferential growth and selection of genotypes are described. At the core of these network connections is ribozyme catalysis initiated through a 3-nucleotide base-pairing interface. With the development of a fluorescence anisotropy method, we are able to illustrate a correlation between these binding thermodynamics and network outcomes. Finally, we consider how the heterogeneity of the environment could impact network dynamics and develop a spectrum of spatial inducing methods in which our chemical populations can be probed. These experiments illustrate simple chemical dynamics of RNA interactions, yet these very processes are the foundation for building complexity and ultimately from where selection and evolvability derive.

In eukaryotes, recombination plays a critical role in both the production of viable gametes and as a population genetic process. Here, we are interested in studying recombination as it provides insight into a process that has shaped variation. To this end, we study the evolution of cross-over rates in chimpanzees and humans through two experiments. Components of the recombination machinery are well described in yeast and C. elegans, but less so in other species. In humans, cross-over rates vary across physical scales and occur predominantly in narrow ∼2 kb regions called hotspots, where hotspot usage differs considerably between individuals. Differential hotspot usage is associated with specific DNA motifs, and DNA-contacting zinc finger array variants in the transacting PRDM9 H3K4 trimethyltransferase. The precise relationship between DNA motifs, PRDM9 and hotspot activity is not completely understood. Experiment 1. To investigate the importance of PRDM9 motif recognition, which is predicted be different between humans and chimpanzees, and the effect of PRDM9 on the evolution of fine-scale cross-over rates, we sequenced 10 unrelated Pan troglodytes verus (Western chimpanzee) genomes to moderate coverage (∼10×). I validate the approach by demonstrating that fine-scale maps estimated from 10 human genomes of each African and European ancestry recapitulate independently estimated maps. Then I characterise the error modes in sequencing data arising from errors in chemistry, alignment, variant calling, and genotyping. I identify several cryptic error modes missed by state-of-the-art filters and develop methods to counteract them. To guard against genotype error arising from stochastic variation in low to moderate coverage sequencing, I develop methods to incorporate the underlying statistical uncertainty into recombination analyses, evaluate the approaches through simulation (estimated 11% improvement) and empirical assessment (estimated 4% improvement), and discover that the reported genotype uncertainty is poorly calibrated, which limits the approaches. Consequently, a filtering approach was applied to the hard-called chimpanzee genotypes. I estimate recombination rates in chimpanzees through an existing LD-based method. In contrast to humans, there is no increased cross-over localisation around chimpanzee PRDM9 binding predictions, nor motifs consistently associated with activity. Hotspots do not overlap between the two species, indicating that rates evolved rapidly and consistent with PRDM9 localising all hotspots. In contrast, gene pro- moters and CpG islands are common attractors of recombination (2.7-fold increase in rate in chimpanzee, 1.5-fold increase in human), suggesting chromatin state influences hotspot placement but to varying degree in the species. I discuss the potential implications for PRDM9 mechanism. Experiment 2. To enable a more representative characterisation of the spectrum of genome changes occurring in chimpanzee genomes, I analyse data from an extended three generation Western chimpanzee pedigree sequenced at high coverage (∼30×). I use Mendel transmission to filter variants, infer haplotypes, and identify recombination events through a Hidden Markov Model approach. We detect 375 recombination events, of which 3 are double cross-over events. Sex-specific recombination rate estimates in chimpanzees mirror sex differences in humans (N♂/N♀ = 0.58) and have similar levels of total recombination. We resolve recombination events typically at ∼ 856 base-pair resolution. Additionally, analyses of Mendel inconsistencies suggest that extended pedigree sequencing opens the door on studying complex genome changes. These experiments demonstrate the power of comparative analyses, the utility of high throughput sequencing in enabling the study of recombination in almost any species of interest, the challenges in sifting signal from noise in these data, and the need for experimental and algorithmic methods to guard against error.

Homologous recombination represents a DNA repair pathway. Its role in a plant cell is not limited to double strand break repair. It also extends to genome evolution via rearranging of DNA sequences, and has an important application in foreign DNA integration in the plant genome. Our study demonstrated that effects exerted by stress on homologous recombination and genome stability are not restricted to the exposed generation. The progeny of plants exposed to stress exhibited elevated spontaneous homologous recombination, changes in DNA methylation and higher tolerance to stress. These heritable changes are mediated by an unknown stress-inducible epigenetic signal. Furthermore, we demonstrated that using factors that enhance homologous recombination can improve the efficiency of genetic transformation by Agrobacterium. We have developed and patented a plant growth medium enhancing homologous recombination and significantly increasing the transformation frequency. The role of several other chemicals for the improvement of transformation was also evaluated.
xxi, 246 leaves : ill. ; 29 cm. --

Mitotic genome instability can occur during the repair of double-strand breaks (DSBs) in DNA, which arise from endogenous and exogenous sources. Studying the mechanisms of DNA repair in the budding yeast, Saccharomyces cerevisiae has shown that Homologous Recombination (HR) is a vital repair mechanism for DSBs. HR can result in a crossover event, in which the broken molecule reciprocally exchanges information with a homologous repair template. The current model of double-strand break repair (DSBR) also allows for a tract of information to non-reciprocally transfer from the template molecule to the broken molecule. These “gene conversion” events can vary in size and can occur in conjunction with a crossover event or in isolation. The frequency and size of gene conversions in isolation and gene conversions associated with crossing over has been a source of debate due to the variation in systems used to detect gene conversions and the context in which the gene conversions are measured.

In Chapter 2, I use an unbiased system that measures the frequency and size of gene conversion events, as well as the association of gene conversion events with crossing over between homologs in diploid yeast. We show mitotic gene conversions occur at a rate of 1.3x10-6 per cell division, are either large (median 54.0kb) or small (median 6.4kb), and are associated with crossing over 43% of the time.

DSBs can arise from endogenous cellular processes such as replication and transcription. Two important RNA/DNA hybrids are involved in replication and transcription: R-loops, which form when an RNA transcript base pairs with the DNA template and displaces the non-template DNA strand, and ribonucleotides embedded into DNA (rNMPs), which arise when replicative polymerase errors insert ribonucleotide instead of deoxyribonucleotide triphosphates. RNaseH1 (encoded by RNH1) and RNaseH2 (whose catalytic subunit is encoded by RNH201) both recognize and degrade the RNA in within R-loops while RNaseH2 alone recognizes, nicks, and initiates removal of rNMPs embedded into DNA. Due to their redundant abilities to act on RNA:DNA hybrids, aberrant removal of rNMPs from DNA has been thought to lead to genome instability in an rnh201Δ background.

In Chapter 3, I characterize (1) non-selective genome-wide homologous recombination events and (2) crossing over on chromosome IV in mutants defective in RNaseH1, RNaseH2, or RNaseH1 and RNaseH2. Using a mutant DNA polymerase that incorporates 4-fold fewer rNMPs than wild type, I demonstrate that the primary recombinogenic lesion in the RNaseH2-defective genome is not rNMPs, but rather R-loops. This work suggests different in-vivo roles for RNaseH1 and RNaseH2 in resolving R-loops in yeast and is consistent with R-loops, not rNMPs, being the the likely source of pathology in Aicardi-Goutières Syndrome patients defective in RNaseH2.

Dissertation

Indiana University-Purdue University Indianapolis (IUPUI)
Break-induced replication (BIR) is a mechanism to repair double-strand breaks (DSBs) that possess only a single end that can find homology in the genome. This situation can result from the collapse of replication forks or telomere erosion. BIR frequently produces various genetic instabilities including mutations, loss of heterozygosity, deletions, duplications, and template switching that can result in copy-number variations (CNVs). An important type of genomic rearrangement specifically linked to BIR is half crossovers (HCs), which result from fusions between parts of recombining chromosomes. Because HC formation produces a fused molecule as well as a broken chromosome fragment, these events could be highly destabilizing. Here I demonstrate that HC formation results from the interruption of BIR caused by a defective replisome or premature onset of mitosis. Additionally, I document the existence of half crossover instability cascades (HCC) that resemble cycles of non-reciprocal translocations (NRTs) previously described in human tumors. I postulate that HCs represent a potent source of genetic destabilization with significant consequences that mimic those observed in human diseases, including cancer.

The aim of this study was to analyse testcross-material that was generated during a homoeologous pairing-induction experiment. Absence of the homoeologous pairing suppressor gene, Ph1, was employed to induce meiotic pairing between the Lr59 translocation (Aegilops peregrina) and 1AL of normal wheat. The study aimed to characterize the test-cross plants derived from this experiment and to identify recombinants which retained the least amount of species chromatin but which still contained the Lr59 gene. The test-cross F1 population, 07M5 (total 635 plants), was screened for Lr59 resistance by inoculating seedlings with the leaf rust pathotype, UVPrt8. The 168 resistant plants were characterized with molecular markers in order to identify recombinants. The data were used to construct a physical map which showed the relative sizes of the recombinants and which could be used to identify those recombinants which contained the least amount of residual species chromatin. Microsatellite (Xcfa2219, Xbarc83 and Xgwm164) and SCAR (S15T3) analysis was used for the initial identification of recombinants. The results showed that 152 of the 168 resistant plants were recombinants for the four loci; that eight of the remaining 16 plants represented non-recombinant, wild species-types and that the last eight plants represented the wheat parental-types which were resistant (and thus, also recombinants). This extremely high recombination frequency can largely be attributed to strong segregation distortion that was evident in the cross. It is also possible that the translocation segment could derive from the S genome rather than the U genome of Ae. peregrina. The S genome is closer related to the wheat genomes than the U genome and may be more prone to recombination. With the use of the microsatellite and SCAR data, a physical map was constructed which showed the relative location of the Lr59 gene on the translocation. It appeared that the eight shortest recombinants retained terminal species chromatin. In an attempt to characterize the eight recombinants, additional marker loci had to be identified within that region. RAPD, iv AFLP and DArT markers were investigated for this purpose. RAPD analyses did not produce any useful markers. AFLP and DArT analyses did identify useful markers with which the eight recombinants could be screened. The data showed which recombinants probably retained the least amount of species chromatin. Seeing that AFLP and DArT markers are anonymous and that the distances between marker loci are unknown, it is not possible to say which recombinant is the shortest and consequently it will be nessecary to also evaluate the group of eight recombinants agronomically in order to identify the most useful ones. The results showed that multiple cross-overs apparently occured on both sides of Lr59. Multiple cross-overs are higly unlikely in material of this nature, therefore it was speculated that the observation resulted from incomplete synteny between the telomeric areas of the translocation and 1AL. A structural difference between the two chromosome regions might have given rise to abnormal meiotic pairing structures and thus unexpected gamete genotypes. Each of the eight recombinants did express one or more of the Ae. peregrina derived AFLP loci which can in future be verified for use as a marker for marker assisted selection. The study succeeded in identifying a number of potentially useful recombinants which contain the Lr59 resistance. It would, however, be risky to select only one of the shortest recombinants for further development on the basis of the present knowledge as some recombinants may contain genetic abnormalities which resulted from reduced synteny in the Lr59 region. It would therefore be wise to further evaluate all eight recombinants before the best one is selected for agronomic use.

Les champignons mycorhiziens à arbuscules (CMA) sont des organismes microscopiques du sol qui jouent un rôle crucial dans les écosystèmes naturels et que l’on retrouve dans tous les habitats de la planète. Ils vivent en relation symbiotique avec la vaste majorité des plantes terrestres. Ils sont des biotrophes obligatoires, c'est-à-dire qu'ils ne peuvent croître qu'en présence d'une plante hôte. Cette symbiose permet entre autres à la plante d'acquérir des nutriments supplémentaires, en particulier du phosphore et du nitrate. Malgré le fait que cette symbiose apporte des services importants aux écosystèmes, la richesse des espèces, la structure des communautés, ainsi que la diversité fonctionnelle des CMA sont mal connues et l'approfondissement des connaissances dans ces domaines dépend d’outils de diagnostic moléculaire. Cependant, la présence de polymorphisme nucléaire intra-isolat combiné à un manque de données génomiques dans différents groupes phylogénétique de ces champignons complique le développement de marqueurs moléculaires et la détermination de l'affiliation évolutive à hauts niveaux de résolution (c.a.d. entre espèces génétiquement similaires et/ou isolats de la même espèce). . Pour ces raisons, il semble une bonne alternative d’utiliser un système génétique différent en ciblant le génome mitochondrial, qui a été démontré homogène au sein d'un même isolat de CMA. Cependant, étant donné le mode de vie particulier de ces organismes, une meilleure compréhension des processus évolutifs mitochondriaux est nécessaire afin de valoriser l'utilisation de tels marqueurs dans des études de diversité et en génétique des populations. En ce sens, mon projet de doctorat consistait à investiguerétudier: i) les vecteurs de divergences inter-isolats et -espèces génétiquement rapprochéesphylogénétiquement apparentées, ii) la plasticité des génomes mitochondriaux, iii) l'héritabilité mitochondriale et les mécanismes potentiels de ségrégation, ainsi que iv) la diversité mitochondriale intra-isolat in situ. À l'aide de la génomique mitochondriale comparative, en utilisant le séquençage nouvelle génération, on a démontré la présence de variation génétique substantielle inter-isolats et -espèces, engendrées par l'invasion d'éléments mobiles dans les génomes mitochondriaux des CMA, donnant lieu à une évolution moléculaire rapide des régions intergéniques. Cette variation permettait de développer des marqueurs spécifiques à des isolats de la même espèce. Ensuite, à l'aide d'une approche analytique par réseaux de gènes sur des éléments mobiles, on a été en mesure de démontrer des évènements de recombinaisons homologues entre des haplotypes mitochondriaux distincts, menant à des réarrangements génomiques. Cela a permis d'ouvrir les perspectives sur la dynamique mitochondriale et l'hétéroplasmie dans un même isolatsuggère une coexistence de différents haplotypes mitochondriaux dans les populations naturelles et que les cultures monosporales pourraient induirent une sous-estimation de la diversité allélique mitochondriale. Cette apparente contradiction avec l'homogénéité mitochondriale intra-isolat généralement observée, a amené à investiguer étudier les échanges génétiques à l'aide de croisements d'isolats génétiquement distincts. Malgré l'observation de quelques spores filles hétéroplasmiques, l'homoplasmie était le statut par défaut dans toutes les cultures monosporales, avec un biais en faveur de l'un des haplotypes parentaux. Ces résultats suggèrent que la ségrégation opère durant la formation de la spore et/ou le développement de la coloniedu mycélium. De plus, ils supportent la présence d'une machinerie protéique de ségrégation mitochondriale chez les CMAAMF, où l'ensemble des gènes impliqués dans ce mécanisme ont été retrouvé et sont orthologues aux autres champignons. Finalement, on est revenue aux sources avecon a étudié le polymorphisme mitochondrial intra-isolat à l'aide d'une approche conventionnelle de PCR en utilisant une Taq polymérase de haute fidélité, suivie de clonage et de séquençage Sanger, sur deux isolats de R. irregularis. Cela a permis l'observation d'hétéroplasmie in situ, ainsi que la co-expression de variantes de variantes de protéines'ARNm dans une souche in vitro. Les résultats suggèrent que d'autres études basées sur le séquençage nouvelle génération aurait potentiellement ignorée cette variation, offrant ainsi plusieurs nouveaux arguments permettant de considérer les CMA comme des organismes possédant une population de génomes mitochondriaux et nucléaires distincts.
The association between arbuscular mycorrhizal fungi (AMF) and plant roots is one of the most widespread symbioses involving plants, and thus has an important role in terrestrial ecosystems. In exchange for carbohydrates, AMF improve plant fitness by enhancing mineral nutrient uptake, especially in particular phosphate and nitrate. Although this symbiosisDespite the fact that these symbioses contribute provides to important services toin ecosystems, the species richness, community structure and functional diversity of AMF is not well understood due to a lack of reliable molecular tools. The intra-isolate genetic polymorphism of nuclear DNA observed in AMF, combined with a lack of genomic data in a broad range of phylogenetic groups, has made it difficult to develop molecular markers and to determine evolutionary relatedness at high levels of resolution (i.e. between genetically-similar species and/or isolates). For these reasons, it seems a good alternative to use a different genetic system by targeting the mitochondrial genome, which have been shown to be homogeneous within AMF isolates. However, given the peculiar lifestyle of these organisms, a better understanding of the mitochondrial evolutionary processes and dynamics were is necessary in order to validate the usefulness of such markers in diversity and population genetics studies. In that regard, the objectives of my PhD project were to investigate: i) the divergence between closely related species and isolates, ii) mitochondrial genomes plasticity, iii) mitochondrial heritability and potential segregation mechanisms and iv) in situ mitochondrial intra-isolate allelic diversity. With Using comparative mitochondrial genomics using and next generation sequencing (NGS) sequencing, we found substantial sequence variation in intergenic regions caused by the invasion of mobile genetic elements. This variation gives risecontributes to rapid mitochondrial genome evolution among closely related isolates and species, which makes it possible to design reliable intra- and inter-specific markers. Also, an extensive gene similarity network-based approach allowed us to provide strong evidence of inter-haplotype recombination in AMF, leading to a reshuffled mitochondrial genome. These findings suggest the coexistence of distinct mtDNA haplotypes in natural populations and raise questions as to whether AMF single spore cultivations artificially underestimates mitochondrial genetic diversity in natural population.. This apparent contradiction with the intra-isolate mtDNA homogeneity usually observed in these fungi, led to the investigation of mitochondrial heritability in the spore progeny resulting from crossed-cultures. Although an heteroplasmic state was observed in some daughter spores, we found that homoplasmy was the dominant state in all monosporal cultures, with an apparent bias towards one of the parental haplotypes. These results strongly support the presence of a putative mitochondrial segregation proteic machinery in AMF, whose complete set of genes were orthologous with those found in other fungi. Our findings suggest that segregation takes place either during spore formation or colony mycelium development. Finally, we performed a conventional PCR based approach with a high fidelity Taq polymerase, followed by downstream cloning and Sanger sequencing using the model organism Rhizophagus irregularis. We found in situ heteroplasmy along with substantial intra-isolate allelic variation within the mtDNA that persists in the transcriptome. Our study also suggest that genetic variation in Glomeromycota is higher than meets the eye and might be critically underestimated in most NGS based-AMF studies both in nuclei and mitochondria.