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Genomics and Transcriptomics of Hybrid Male Sterility Assessed in Multiple Interspecies Feline BreedsDavis, Brian W 03 October 2013 (has links)
Hybrid male sterility (HMS) is typically the first mechanism fortifying reproductive isolation resulting from genomic incompatibilities. Three interspecies feline breeds derived from domestic cat crosses to wild cat species (Asian leopard cat and African serval) manifest HMS through several generations of backcrossing before eventually regaining fertility. This work utilized 199 hybrid individuals with varying fertilities in a genome wide association study (GWAS) comprising 63,000 genome wide SNPs. Leveraging these results with whole-testis transcriptome sequencing and quantitative real-time PCR data facilitated the comparison of transcripts in sterile and fertile hybrids. This dissertation describes four loci with highly significant and fifty with moderately significant association to sterility within each individual hybrid domestic breed and combinations of breeds. These associations help identify epistatic targets for hybrid incompatibility contributing to sterility. Comparative QTL mapping between pairs of species provides a framework to describe the accumulation of clade-specific reproductive isolating loci. Detailed exploration of gene misregulation between domestic and hybrid individuals, as well as between littermate hybrids of varying fertilities outlines a pattern of expression consistent with a meiotic sex-chromosome inactivation failure in early generations and apoptotic failure in later hybrid generations. Combining comparative genomic association and transcriptomic characterization among hybrid felids of varying divergence, new insight is gained into the mechanisms of mammalian reproductive isolation.
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Isolamento de sequências repetitivas do genoma de espécies do gênero Ancistrus (Siluriformes: Loricariidae) / Isolation of repetitive sequences of the genome of species of the genus Ancistrus (Siluriformes: Loricariidae)Silva, Keteryne Rodrigues da [UNESP] 09 March 2016 (has links)
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Previous issue date: 2016-03-09 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / O DNA pode estar organizado no genoma em sequências de cópias únicas e em sequências que se repetem várias vezes, denominadas sequências repetitivas. Estas sequências são constituídas basicamente por repetições em tandem (satélites, minissatélites e microssatélites) ou dispersas (transposons ou retrotransposons), e parecem estar envolvidas em diversos eventos celulares importantes, como por exemplo nos processos de replicação do DNA, de recombinação, de expressão gênica e de evolução dos cromossomos, auxiliando na manutenção e propagação do material genético celular. Em nível cromossômico parecem ser responsáveis por proporções significativas das variações cariotípicas observadas em diversos grupos. O gênero Ancistrus (Siluriformes, Loricariidae) apresenta atualmente 68 espécies nominais, e uma enorme quantidade de espécies ainda não identificadas. Alguns trabalhos vêm utilizando sequências repetitivas também em análises citogenéticas e moleculares para identificação de cromossomos homólogos e marcadores cariotípicos interessantes que podem auxiliar os trabalhos de identificação de espécies. Apesar de serem amplamente estudadas em diversos organismos, há ainda muito a ser entendido sobre essas sequências e sua organização no genoma. Este trabalho teve como objetivo isolar sequências repetitivas no genoma de espécies de Ancistrus, afim de encontrar possíveis marcadores para o gênero, que pudessem contribuir para o entendimento da taxonomia deste grupo, bem como auxiliar no entendimento do processo de evolução dos cromossomos sexuais dessas espécies. Dentre as sequências isoladas está um transposon da família TC1/mariner que se mostrou presente em todos os cromossomos das espécies analisadas e dois DNAs satélites que se apresentam acumulados em regiões centroméricas de alguns cromossomos. Sendo assim, este estudo resultou em dados que poderão contribuir com o entendimento da evolução cariotípica do gênero Ancistrus bem como fornecer mais informações sobre características e evolução dos cromossomos sexuais em peixes. / DNA may be organized in the genome as single copy sequences and as sequences that are repeated several times, called repetitive sequences. These sequences are basically constituted by tandem repeats (satellites, minisatellites and microsatellites) or scattered (transposons and retrotransposons), and seem to be involved in important cellular events such as, DNA replication process, recombination, gene expression and chromosome evolution, assisting in maintenance and spread the genetic material of cells. At chromosome level, seems to be significant proportions of karyotypic variations observed in several groups. The genus Ancistrus (Siluriformes, Loricariidae) has, actually, 68 nominal species and several species not identified yet. Repetitive sequences have been used in molecular cytogenetic analysis for identification of homologous chromosomes and interesting karyotypic markers that can assist in species identification works. Despite being widely studied in several organisms, there is still much to be understood about these sequences and their organization in the genome. This study aimed to isolate repetitive sequences in the genome of Ancistrusspecies in order to find possible markers for the genus, which could contribute to the understanding of the taxonomy of this group and to the understanding of the process of evolution of sex chromosomes of these species. Among the isolated sequences, there is a family of TC1/mariner transposon that showed to be present in all the chromosomes of the analyzed species, and two satellites DNAs that have accumulated in centromeric regions. Thus, this study resulted in data that could be contribute to understanding the karyotype evolution of Ancistrus genus as well as providing more information on the characteristics and evolution of sex chromosomes in fish.
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Etudes de gènes des chromosomes sexuels au cours de la spermatogenèse chez l'homme et la souris et implication dans la fertilite masculineDecarpentrie, Fanny 08 July 2011 (has links)
Les chromosomes sexuels subissent pendant la spermatogenèse de multiples modifications qui entrainent d’importantes variations dans le niveau d’expression des gènes qu’ils portent. Notamment, ils sont inactivés au cours de la méiose et la majorité reste réprimé tout au long de la spermiogenèse. Cette étude met en évidence l’existence de transcrits alternatifs particuliers de gènes sur le chromosome X et Y, dont les profils d’expressions témoignent de leur rôle au cours de ces deux phases de la spermatogenèse. Sur le chromosome X nous avons isolé, chez l’homme et chez la souris, trois gènes ubiquitaires (Uba1x, Prdx4, Atp11c) réactivés dans les spermatides via un transcrit alternatif exprimé de façon majoritaire dans les testicules. Le gène Prdx4 code, pour deux isoformes de protéines différentes par leur domaine N-terminal. Nous avons mis au point des anticorps spécifiques de chaque isoforme et nous avons démontré que, chez la souris, le transcrit réactivé est traduit dans les spermatides et produit une protéine dans un compartiment cellulaire distinct de l’autre isofome ubiquitaire. Un total de cinq mutations, affectant ces transcrits exprimés dans les spermatides, ont été retrouvées dans les gènes UBA1X et PRDX4 chez des hommes infertiles. Sur le chromosome Y chez la souris, nous avons étudié les gènes Zfy1 et Zfy2, deux homologues testicules spécifiques codant pour des protéines à doigt de zinc avec un long domaine d’activation. Zfy2, mais pas Zfy1, promeut l’élimination apoptotique des spermatocytes contenant un chromosome X univalent. Nous avons identifié un transcrit alternatif du gène testicule spécifique Zfy1 exprimé dans les spermatocytes et les spermatides. La protéine putative issue de ce transcrit, possédant un domaine acidique réduit de moitié qui pourrait être à l’origine des différences fonctionnelles entre les gènes homologues Zfy1 et Zfy2 au cours de la méiose murine. Chez l’homme, l’orthologue de ces gènes ZFY est ubiquitaire et nous avons montré qu’il produisait un transcrit alternatif testicule spécifique, codant une protéine avec le même domaine acidique raccourci que Zfy1. Nos données indiquent que ce transcrit alternatif est prédominant dans les spermatocytes et les spermatides chez l’homme et chez la souris. Ces résultats apportent la première évidence d’une fonction du gène ZFY au cours de la spermatogenèse chez l’homme et de son implication possible dans la fertilité masculine. / Sex chromosomes undergo many modifications during spermatogenesis, leading to dramatic variations in the expression levels of their genes. In particular, they are inactivated during meiosis with most genes remain silent throughout spermiogenesis. Our study describes specific alternative transcripts produced by X and Y chromosome genes, whose expression indicates roles in early spermatocytes (meiosis) and in spermatids (spermiogenesis). On the X chromosome, we have shown that three widely transcribed genes, Uba1x, Prdx4, and Atp11c, are reactivated in mouse and human spermatids via an alternative transcript that is expressed mainly in the testis. The Prdx4 gene codes two isoforms of the peroxiredoxin 4 that differ in their N-terminal domain. We have raised antibodies specific for each PRDX4 isoform and demonstrate, in mouse, that the reactivated transcript is translated in spermatids, producing a protein in a distinct cellular compartment from the ubiquitous isoform. Altogether, five mutations, affecting the spermatid-reactivated transcripts uniquely, of UBA1x and PRDX4, have been found specifically in our group of infertile men. On the mouse Y chromosome, we have studied Zfy1 and Zfy2, nearly identical testis specific zinc finger genes with long acidic (activation) domains. Zfy2, but not Zfy1, promotes the apoptotic elimination of spermatocytes with an unpaired X chromosome. We have identified an alternatively spliced transcript of Zfy1 that lacks half the acidic domain, and could explain the functional difference between Zfy1 and Zfy2. In human, the ZFY gene is widely transcribed, but we show that ZFY produces a testis specific variant transcript, encoding the same short acidic domain as Zfy1. Our data indicate that the alternative transcripts predominate in spermatocytes and spermatids, in both human and mouse. This provides the first evidence that human ZFY may play a conserved role during spermatogenesis, and contribute to human male fertility.
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Le variant d'histone H3.3 dans la spermatogenèse : inactivation des chromosomes sexuels et régulation des piARN / The histone variant H3.3 in spermatogenesis : sexual chromosomes inactivation and piRNA regulationFontaine, Émeline 23 October 2018 (has links)
Durant ces dernières décennies, la fertilité masculine est en constante diminution à l’échelle mondiale. Même si les facteurs environnementaux ont une part de responsabilité indéniable, il n’en reste pas moins que les altérations génétiques mais également épigénétiques semblent aussi largement impliquées. La compréhension des mécanismes épigénétiques qui régulent la fertilité masculine est récente mais essentielle pour le développement de nouvelles approches thérapeutiques. Dans ce contexte, l’objectif de mes travaux de thèse s’est focalisé sur l’étude du rôle du variant d’histone H3.3 dans la spermatogenèse. H3.3 possède la capacité de remplacer l’histone canonique H3 dans la chromatine modifiant ainsi les propriétés épigénétiques de cette dernière. H3.3 est nécessaire à la spermatogenèse mais son rôle reste à élucider. Grace à plusieurs modèles murins, mes travaux de thèse ont montré que la forme H3.3B est essentielle à la reproduction masculine notamment pour la transition méiose/post-méiose. Lors de cette transition, on observe une forte régulation des piARN, des rétrotransposons et des chromosomes sexuels. Nos expériences révèlent pour la première fois que la perte de H3.3B provoque une chute de l’expression des piARN. À l’inverse, l’absence de H3.3B est aussi associée à une augmentation de l’expression de l’ensemble des gènes des chromosomes sexuels comme des rétrotransposons RLTR10B et RLTR10B2. Ces changements d’expression se traduisent par une spermatogenèse altérée et une infertilité. Par des expériences de ChIP-seq, nous avons observé que H3.3 est fortement enrichie sur les piRNA, les rétrotransposons RLTR10B et RLTR10B2 et l'ensemble des chromosomes sexuels. Toutes ces expériences ont permis de mieux caractériser la fonction régulatrice de l’histone H3.3B au cours de la spermatogenèse. En particulier, elles démontrent que H3.3B, en fonction de sa localisation sur la chromatine, intervient dans la régulation positive ou négative de l'expression de régions chromatiniennes définies. Ces résultats montrent l’importance des contrôles épigénétiques au cours de la spermatogenèse et ouvrent de nouvelles pistes dans la compréhension des causes d’infertilité masculine. / In last decades, male fertility has been steadily declining worldwide. Even if environmental factors have an undeniable responsibility, the fact remains that both genetic and epigenetic alterations also seem to be widely implicated. The understanding of the epigenetic mechanisms that regulate male fertility is recent but essential to develop a new therapeutic approaches. In this context, the objective of my thesis work focused on the study of the role of histone variant H3.3 in spermatogenesis. H3.3 has the ability to replace the H3 canonical histone in chromatin thus modifying the epigenetic properties of chromatin. H3.3 is necessary for spermatogenesis but its role remains unclear. Used to several mouse models, my thesis work has shown that the H3.3B form is essential for male reproduction and especially for the meiosis/post-meiosis transition. During this transition, there is a strong regulation of piRNAs, retrotransposons and sex chromosomes. Our experiments reveal at the first time that the loss of H3.3B resulted in down-regulation of the expression of piRNA. In contrast, the absence of H3.3B is also associated with increased expression of all sex chromosom genes as well as of both RLTR10B and RLTR10B2 retrotransposons. These expression changes result in altered spermatogenesis and infertility. By ChIP-seq experiments, we observed that H3.3 is markedly enriched on the piRNA clusters, RLTR10B and RLTR10B2 retrotransposons and the whole sexual chromosomes. All these experiments allowed bettering characterizing the regulatory function of histone H3.3B during spermatogenesis. In particular, he demonstrates that H3.3B, depending on its chromatin localization, is involved in either up-regulation or down-regulation of expression of defined chromatin regions. These results show the importance of epigenetic controls during spermatogenesis and open new tracks for understanding the causes of male infertility.
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Karyotypová evoluce u vybraných čeledí entelegynních pavouků / Karyotype evolution of selected families of entelegyne spidersKotz, Matěj January 2020 (has links)
The Araneoidea superfamily is a diverse clade of spiders with a great species diversity. The whole superfamily displays considerable conservativeness of observed karyotypes. Most likely ancestral karyotype in males is 24 acrocentric chromosomes with X1X2 sex determination system. The goal of this study is to explore the karyotype diversity of two araneoid families - Araneidae and Mimetidae. The majority of studied species exhibit the ancestral karyotype. In some species of the aformentioned families was observed sudden increase in chromosome numbers, up to 2n♂ = 52 in Araneidae and up to 2n♂ = 57 in Mimetidae. The latter number is the highest chromosome count observed in Entelegynae so far. Increase in 2n goes hand in hand with increase in sex chromosome numbers, leading up to X1X2X3X40 system in Araneidae and up to X1X2X3X4X5X6X70 in Mimetidae. I suggest polyploidy as a possible mechanism of the increase. To test this hypothesis, I measured the size of the genome using flow cytometry and used fluorescence in situ hybridization for the detection of 18S rRNA and 5S rRNA genes. For one species, probe for U2 snRNA gene was also optimized as part of this thesis. In many species studied, these techniques were used for the first time ever. In the case of the family Mimetidae, the largest genomes in...
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The evolutionary mechanisms promoting sex chromosome divergence within <i>Carica papaya</i>Brown, Jennifer Erin 04 December 2013 (has links)
No description available.
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The evolution, ecology and genetics of sex determination in Mercurialis annuaRussell, John R. W. January 2012 (has links)
The allocation of resources to male or female progeny, or to male or female reproductive function more generally, is one of the most important life history decisions a sexually reproducing individual must ever make. Sex determination is thus a fundamental process, yet the mechanisms which control it are surprisingly diverse. In this thesis, I examine sex determination in the plant species Mercurialis annua L. (Euphorbiaceae). I assess the mechanism of sex determination operating in dioecious and androdioecious populations of M. annua and also investigate the conservation and evolution of sex-determining mechanisms across the annual mercury clade, the lineages of which display exceptional variation in sexual system. First, using crosses, I establish that sex in dioecious M. annua is controlled by a single-locus genetic mechanism, consistent with recent work that identified a single male-linked DNA marker in the species. My search for new sex-linked genes revealed none, however, suggesting that M. annua possesses at most a small non-recombining region around sex-determining loci. Why many dioecious plants lack heteromorphic sex chromosomes is still poorly understood and I consider explanations for this. I extend my investigation by comparing genetic diversity between loci that differ in their linkage to the sex-determining locus. I find a single male-linked marker to possess significantly lower diversity than autosomal loci, but no difference in the diversity of partially sex-linked and non-sex-linked genes. I also assess the conservation of a sex-linked marker among annual mercury lineages and conduct crosses between lineages to examine the conservation of sex determination. My findings indicate a conserved mechanism of single-locus genetic sex determination and I consider the role polyploidisation and hybridisation have played in sexual system evolution and the modification of sex-determining mechanisms in the clade. Finally, I assess the presence of environmental sex determination in androdioecious M. annua, concluding that although male frequency is not influenced by growing density, a degree of sexual lability exists in the lineage.
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Genetika a genomika hybridní sterility / Genetics and Genomics of Hybrid SterilityBhattacharyya, Tanmoy January 2013 (has links)
Charles University in Prague Faculty of Science Ph.D. study program: Molecular and Cellular Biology, Genetics and Virology Abstract Genetics and genomics of hybrid sterility Mgr. Tanmoy Bhattacharyya Supervisor: Prof. MUDr. Jiří Forejt, DrSc. Praha 2013 Abstract Male-limited hybrid sterility restricts gene flow between the related species, an important pre- requisite of speciation. The F1 hybrid males of PWD/Ph female (Mus m. musculus subspecies) and C57BL/6J or B6 male (Mus m. domesticus) are azoospermic and sterile (PB6F1), while the hybrids from the reciprocal (B6PF1) cross are semi fertile. A disproportionately large effect of the X chromosome (Chr) on hybrid male sterility is a widespread phenomenon accompanying the origin of new species. In the present study, we mapped two phenotypically distinct hybrid sterility loci Hstx1 and Hstx2 to a common 4.7 Mb region on Chr. X. Analysis of meiotic prophase I of PB6F1 sterile males revealed meiotic block at mid-late pachynema and the TUNEL assay showed apoptosis of arrested spermatocytes. In sterile males over 95% of pachytene spermatocytes showed one or more unsynapsed autosomes visualized by anti SYCP1, HORMAD2 and SYCP3 antibodies. The phosphorylated form of H2AFX histone, normally restricted only to XY chromosome containing sex body decorated unsynapsed...
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Sex Chromosome Evolution in Blow FliesAnne Amarila Andere (9120365) 28 July 2020 (has links)
<div>Chromosomal mechanisms of sex determination vary greatly in phylogenetically closely related species, indicative of rapid evolutionary rates. Sex chromosome karyotypes are generally conserved within families; however, many species have derived sex chromosome configurations. Insects display a plethora of sex chromosome systems due to rapid diversification caused by changes in evolutionary processes within and between species. A good example of such a system are insects in the blow fly family Calliphoridae. While cytogenetic studies observe that the karyotype in blow flies is highly conserved (five pairs of autosomal chromosomes and one pair sex chromosome), there is variation in sex determining mechanisms and sex chromosome structure within closely related species in blow flies. The evolutionary history of sex chromosomes in blow fly species have not been fully explored. Therefore, the objective of this research was to characterize the sex chromosome structures in four species of blow flies and investigate the selective forces which have played a role in shaping the diverse sex chromosome system observed in blow flies. The blow fly species used in this study are Phormia regina, Lucilia cuprina, Chrysomya rufifacies and Chrysomya albiceps. Phormia regina,and Lucilia cuprina have a heteromorphic sex chromosome system and are amphogenic (females produce both male and female offspring in equal ratio). In contrast, Chrysomya rufifacies and Chrysomya albiceps, have a homomorphic sex chromosome system, are monogenic (females produce unisexual progeny), have two types of females (arrhenogenic females – male producers and thelygenic females – female producers), and sex of the offspring is determined by the maternal genotype. </div><div>To accomplish these tasks, a total of nine male and female individual draft genomes for each of the four species (including three individual draft genomes of Chrysomya rufifacies – male, and the two females) were sequenced and assembled providing genomic data to explore sex chromosome evolution in blow flies. Whole genome analysis was utilized to characterize and identify putative sex chromosomal sequences of the four blow fly species. Genomic evidence confirmed the presence of genetically differentiated sex chromosomes in P. regina and L. cuprina; and genetically undifferentiated sex chromosomes in C. rufifacies and C. albiceps. Furthermore, comparative analysis of the ancestral Dipteran sex chromosome (Muller element F in Drosophila) was determined to be X-linked in P. regina and L. cuprina contributing to sex chromosome differentiation but not sex-linked in C. rufifacies and C. albiceps. Evolutionary pressures are often quantified by the ratio of substitution rates at non-synonymous (dN) and synonymous (dS) sites. Substitution rate ratio analysis (dN/dS) of homologous genes indicated a weaker purifying selection may have contributed to the loss of sex-linked genes in Muller element F genes of the undifferentiated sex chromosome as compared to the differentiated sex chromosome system. Overall, the results presented herein greatly expands our knowledge in sex chromosome evolution within blow flies and will reinforce the study of sex chromosome evolution in other species with diverse sex chromosome systems.</div><div><br></div>
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Analýza pohlavných chromozómov a repetitívne usporiadaných génov u vybraných vtáčkarovitých a araneomorfných pavúkov / Analysis of sex chromosomes and gene clusters in selected mygalomorph and araneomorph spidersPappová, Michaela January 2019 (has links)
1 Abstract: The diploma thesis focuses on study of sex chromosomes evolution and repetitive organized genes of chosen mygalomorph and araneomorph spiders. Spiders are characterized by complexicity of sex chromosome systems, their karyotypes contain multiple sex chromosomes X. Besides multiple X chromosomes they also contain a pair or two pairs of nondiferentiated sex chromosomes X and Y. The used methods include methods of classical cytogenetics (preparation of chromosome slides, C-banding) and methods of molecular cytogenetics (fluorescent in situ hybridization and comparative genome hybridization). Complex sex systems were discovered in the studied Theraphosidae spiders. In Theraphosidae spiders Atropothele socotrana and Poecilotheria vittata neo-sex chromosomes were found. Analysis of molecular differentiation of sex chromosomes suggests low differentiation of Y chromosome in neo-sex chromosomes and pair of nondifferentiated sex chromosomes XY. In haplogyne spider Kukulcania aff. hibernalis (X1X2Y), the Y chromosome was significantly differentiated, male specific signal covered the whole chromosome. Detection of 18S rDNA showed that karyotypes of majority of analysed Theraphosidae spiders and haplogyne spiders contain low number (1 or 2) of nucleolar organizing regions localized terminally, which...
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