Global ETD Search

11	Function of the Mouse PIWI Proteins and Biogenesis of Their piRNAs in the Male Germline Beyret, Ergin January 2009 (has links) <p>PIWI proteins belong to an evolutionary conserved protein family as the sister sub-family of ARGONAUTE (AGO) proteins. While AGO proteins are functionally well-characterized and shown to mediate small-RNA guided gene regulation, the function of PIWI proteins remain elusive. Here we pursued functional characterization of PIWI proteins by studying MILI and MIWI, two PIWI proteins in the mouse.</p><p>We first show that both MIWI and MILI co-immunoprecipitate with a novel class of non-coding small RNAs from the post-natal mouse testis extract, which are named Piwi-interacting RNAs (piRNAs). Our cloning efforts identified thousands of different piRNA sequences, mostly derived from intergenic regions. Interestingly, both MILI and MIWI piRNAs correspond to the same regions on the genome and differ primarily in length. We propose piRNAs in the adult testis are produced by the processing of long, single stranded RNA precursors, based on the observation that piRNAs originate in clusters from a number of sites on the genome in a head-to-tail homology. In support, we bioinformatically predicted putative promoters, and yeast one hybrid analysis on two such regions found out that they interact with Krueppel C2H2 type zinc finger transcription factors. We did not observe the features of the "ping-pong" mechanism in their biogenesis: Both MILI and MIWI piRNAs are biased for 5` Uracil without an Adenine bias on the 10th nucleotide position, and do not significantly consist of sequences complementary to each other along their first 10nt. Moreover, MILI piRNAs are not down-regulated in Miwi-/- testis. These results indicate that the post-natal testicular piRNAs are produced independent of the ping-pong mechanism. </p><p>Although piRNAs are highly complex, PAGE and in situ analyses showed that piRNAs are germ cell-specific with predominant expression in spermatocytes and round spermatids, suggestive of a meiotic function. Correspondingly, we found that Miwi-/-; Mili-/- mice undergo only male infertility with terminal spermatogenic arrest during meiosis. piRNAs show a nucleo-cytoplasmic distribution, with enrichment in the chromatoid and dense bodies, two male germ cell-specific structures. The dense body has been implicated in synapsis and in the heterochromatinization of the sex chromosomes during male meiosis, a process known as meiotic sex chromosome inactivation (MSCI). Our histological analysis on Miwi-/-; Mili-/- testes showed that, while the overall synapsis is not affected, the sex chromosomes retain the euchromatin marker acetyl-H4K16 and lacks the heterochromatin marker H3K9-dimethyl. These observations indicate that murine PIWI proteins are necessary for MSCI. Moreover, we identified piRNA production from the X chromosome before MSCI, and propose PIWI proteins utilize piRNAs to target and silence unpaired chromosomal regions during meiosis.</p> / Dissertation Biology, Cell Meiotic sex chromosome inactivation Meiotic silencing of unpaired chromosome piRNA Piwi small RNA Spermatogenesis
12	Exploring the Sex Chromosome Evolution of Clam Shrimp Lang, Connor 11 November 2021 (has links) No description available. Biology hermaphrodite clam shrimp sex chromosome transposable element recombination suppression androdioecy
13	“Donating Our Bodies to Science”: A Discussion About Autopsy and Organ Donation in Turner Syndrome Prakash, Siddharth K., San Roman, Adrianna K., Crenshaw, Melissa, Flink, Barbara, Earle, Kimberly, Los, Evan, Bonnard, Åsa, Lin, Angela E. 01 March 2019 (has links) At the Third Turner Resource Network Symposium, a working group presented the results of collaborative discussions about the importance of autopsy in Turner syndrome (TS). Considerable gaps in understanding the causes of death in TS can only be closed by more frequent death investigations and autopsies. The presentation included an overview of autopsy methods, strategies for utilizing autopsy, and biobanking to address research questions about TS, and the role of palliative care in the context of autopsy. This review highlights strategies to promote autopsy and tissue donation, culminating with an action plan to increase autopsy rates in the TS community. autopsy molecular autopsy palliative care postmortem examination sex chromosome abnormality syndrome Turner syndrome Pediatrics
14	Bases génétiques et évolution du conflit génétique induit par la distorsion de ségrégation des chromosomes sexuels chez Drosophila simulans / Genetic bases and evolution of the genetic conflict caused by sex chromosome segregation distortion in Drosophila simulans Courret, Cécile 02 December 2019 (has links) La distorsion de ségrégation méiotique est une entorse à la loi de ségrégation équilibrée des allèles via les gamètes. Les gènes ou éléments génétiques causaux (distorteurs de ségrégation) empêchent, chez les hétérozygotes, la production de gamètes qui ne les contiennent pas. Ils peuvent ainsi se répandre dans les populations même s’ils sont délétères pour les individus porteurs.Parce qu'ils induisent un biais du sexe ratio, les distorteurs liés au sexe et s'exprimant dans le sexe hétérogamétique sont générateurs de conflits intragénomiques, caractérisés par l'évolution de suppresseurs qui tendent à rétablir l'équilibre des sexes. Ce processus peut conduire à l’émergence de nouvelles espèces, à l’évolution du comportement reproducteur ou du déterminisme du sexe.Dans l'espèce Drosophila simulans, des distorteurs liés au chromosome X, perturbent la ségrégation du chromosome Y lors de la méiose mâle. La descendance des mâles porteurs est alors très majoritairement femelle. Un de ces éléments distorteurs, le gène HP1D2, code une protéine qui se lie au chromosome Y avant la méiose. La distorsion est le fait d'allèles dysfonctionnels de HP1D2 (qui ont un faible niveau de transcrits testiculaires et/ou ont une délétion du domaine d’interaction protéine-protéine). Dans les populations naturelles envahies par les distorteurs, ceux-ci se trouvent neutralisés par des suppresseurs autosomaux et des chromosomes Y résistants.Le premier volet de ma thèse a été consacré au déterminisme génétique de la suppression autosomale. Par cartographie de QTL, utilisant des lignées recombinantes consanguines, j'ai révélé la complexité de ce déterminisme : 5 QTLs avec de nombreuses relation d’épistasie.Le deuxième volet est consacré au chromosome Y, qui présente, d’importante variations phénotypiques pour la résistance aux distorteurs. Nous avons étudié ses variations moléculaires et structurales et la dynamique des Y résistants dans les populations naturelles. Le séquençage de différents chromosomes Y, résistants ou sensibles, a permis de retracer l’histoire évolutive du chromosome Y en relation avec celle des distorteurs.Le dernier volet est une étude cytologique pour comparer le comportement des formes sauvages et distortrices de la protéine HP1D2 dans les spermatogonies.Dans l’ensemble ces travaux apportent un éclairage sur les bases génétiques et moléculaires du système Paris et sur son évolution. / Meiotic drive is an infringement of the law of allele segregation into the gametes. In heterozygote individuals, the causal genes or genetic elements (meiotic drivers), prevent the production of gamete which does not contain it. Thus, they can spread through populations even if they are deleterious for the carriers.Because they induce sex-ratio bias, sex-linked drivers that are expressed in the heterogametic sex, are an important source of genetic conflict, characterized by the evolution of suppressor which tends to restore a balanced sex ratio. This process can lead to the emergence of new species, evolution of reproductive behavior or sex determination.In Drosophila simulans, X-linked meiotic drivers disturb the segregation of the Y chromosome during male meiosis. The progeny of carrier male is mainly composed of females. One of the drivers is the HP1D2 gene, which encodes a protein that binds to the heterochromatic Y chromosome. The distortion is due to dysfunctional alleles of HP1D2 (low level of expression and/or a deletion of its protein-protein interaction domain). In natural populations where the drivers have spread, they are neutralized by autosomal suppressors and resistant Y chromosomes.The first part of my thesis was focus on the genetic determinism of autosomal suppression. I performed a QTL mapping using recombinant inbreed lines which highlighted the complexity of the genetic determinism of suppression: 5 QTLs and multiple epistatic interaction.The second part is about the Y chromosome, which show important phenotypic variation in the resistance of Y chromosomes to the driver. We studied its molecular and structural variation and the dynamic of resistant Y chromosomes in natural population. The sequencing of different Y chromosomes, sensitive and resistant, allowed us to retrace the evolutionary history of the Y chromosome related to the one of the driver.The last part is a cytological study to compare the localization of the functional and the driver form of HP1D2 in spermatogonia.Generally, results presented here give a better insight regarding the genetic bases and the evolution of the multiple actors of the Paris sex ratio system. Drosophile Distorteur de ségrégation Chromosome sexuel Conflit génétique Hétérochromatine Drosophila Meiotic drive Sex chromosome Genetic conflict Heterochromatin
15	Sex Chromosome Evolution in Blow Flies Andere, Anne Amarila 08 1900 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / 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. 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. Sex chromosome evolution blow flies homomorphic sex chromosomes undifferentiated sex chromosomes Muller element f Chrysomya rufifacies
16	The Evolution of Sex Chromosomes in Papaya (<i>Carica papaya</i>) Weingartner, Laura A. 09 August 2010 (has links) No description available. Botany Genetics papaya sex chromosome molecular evolution Y evolution population genetics
17	Evolutionary Genomics of Xenopus: Investigations Into Sex Chromosomes, Whole Genome Duplication, Speciation, and Hybridization Furman, Benjamin January 2018 (has links) African clawed frogs (Xenopus) have been scientific and medical model species for decades. These frogs present many curious features, and their genomic history is no exception. As such, a variety of evolutionary genomic questions can be addressed with these species in a comparative framework, owing to the great array of genetic tools available and a large number of abundant species. The sex chromosomes of this group are evolutionarily young, and this thesis establishes that there has been an additional change in what constitutes the sex chromosomes in one species of Xenopus. This allows us to compare the evolutionary trajectory of newly established sex chromosomes. By exploring the genetic content of these systems, profiling their recombinational activity, and assessing the extent of nucleotide divergence between the sex chromosomes, we find that sex chromosome evolution may be predictable in some aspects, and highly unpredictable in others. In addition, this genus is uncharacteristic for vertebrates in the frequency with which lineages undergo whole genome duplication. In this thesis, we explore the selective dynamics operating on duplicate genes over time, and the rate at which duplicate copies are purged from the genome from multiple Xenopus species. These investigations provide an animal perspective on the subject of biased subgenome evolution, characteristic of allopolyploids. The last two chapters of this thesis redefine the species boundaries for the most intensively studied Xenopus species (X. laevis), and explore the genetic extent of hybridization between the common X. laevis and the endangered X. gilli. Overall, this thesis provides a broad look at several aspects of Xenopus evolutionary genomics, providing novel contributions to the fields of sex chromosome research, whole genome duplication, and speciation and hybridization. / Thesis / Doctor of Philosophy (PhD) genome evolution sequencing sex chromosome turnover phylogenetics purifying selection pseudogenization endangered species
18	Characterization of the expression patterns of the retrogene-parental gene pairs in the African malaria vector Anopheles coluzzii Miller, Duncan Joseph 09 July 2020 (has links) Retrogenes are a group of functional genes produced by gene retroduplication events during evolution. It has been observed that many retrogenes have formed since the evolutionary divergence of Anopheles mosquitoes from the Aedes lineage as a result of developing heteromorphic sex chromosomes. It has been further observed that these retroduplications predominately occur from parent genes on the heteromorphic X chromosome to autosomes and have a predisposition to have enriched expression in testis. In order to investigate the nature of this male-biased expression in testis, we utilized bioinformatic techniques to identify retrotransposition events and assign them relative ages based on evolutionary branches of divergence. This list of parent genes and retrogenes were then analyzed and a total of twenty-five gene pairs were selected for further examination. Available gene expression data in the form of RNA-seq and DNA microarray were used in tandem with gene annotation data to computationally investigate gene pairs in An. coluzzii. These pairs were further investigated experimentally by means of RT-PCR conducted on dissected head, thorax, abdomen, and reproductive organs in both male and female Anopheles coluzzii Mopti strain. Testis and male accessory glands (MAGs) were also investigated by this method in An. coluzzii. Available expression data support previously observed testis enriched expression of retrogenes and provides evidence for the predominate expression of retrogenes occurring in postmeiotic cells suggesting retrogene involvement in sperm development. Experimental evidence revealed a small group of five retrogenes which exhibit the expected male-biased expression in male testis with little to no expression in female ovaries, although a shared expression in the heads of both sexes was observed. Of the five retrogenes, four carry out energy related functions involving mitochondria, suggesting contribution to energy requirements of developing sperm. Testis and MAG experiments in An. coluzzii revealed a predisposition for retrogenes to be expressed in testis while parent genes tended to have higher expression in MAGs, and this phenomenon is partially supported by DNA microarray expression data. Overall, these results suggest further investigation of retrogenes in An. coluzzii may reveal unique functions in male mosquito fertility that are exploitable in genetic approaches to mosquito control. / Master of Science in Life Sciences / Malaria is a potentially deadly disease which effects thousands of people every year. Malaria around the world is spread by multiple species of mosquitoes in a genus called Anopheles. Controlling the populations of these disease spreading mosquitoes is essential to preventing the spread of malaria. Current insecticide-based approaches used to stop mosquitoes are becoming less effective overtime as mosquitoes become resistant. A potential way to develop new techniques for mosquito control is through research involving mosquito reproductive genetics. Understanding the genes involved in how mosquitoes reproduce could improve future techniques designed to reduce or prevent mosquitos from reproducing. This research focuses on a group of genes called retrogenes which have formed over the evolution of these mosquitoes via the duplication from a separate parent gene. In mosquitoes these retrogenes are understood to be involved in male reproduction. The retrogenes involved in male mosquito reproduction could have important functions in male sexual reproduction and sterility. These important genes could be manipulated to interrupt whatever important functions these genes have in reproduction. In this research we first computationally identified retrogenes and their parent genes and categorized them by age. We then utilized available annotation and expression data to analyze the potential significance of retrogenes to male fertility and found that multiple retrogenes tended to be expressed during sperm development. Lastly, we conducted gene expression experiments using dissected head, thorax, abdomen, and reproductive organs in both male and female Anopheles mosquitoes. Results revealed unique patterns of expression that suggest male specific roles of five retrogenes in testes and head expression in both males and females suggesting a possible role in mating behavior. These results provide evidence that retrogenes do have functional roles in male fertility specifically related to the maturation and development of sperm. Retrogene Retrotransposition Male-biased expression Anopheles coluzzii Male accessory glands Meiotic sex chromosome activation Sexual antagonism
19	CHARACTERIZATION OF A LARGE VERTEBRATE GENOME AND HOMOMORPHIC SEX CHROMOSOMES IN THE AXOLOTL, <em>AMBYSTOMA MEXICANUM</em> Keinath, Melissa 01 January 2017 (has links) Changes in the structure, content and morphology of chromosomes accumulate over evolutionary time and contribute to cell, developmental and organismal biology. The axolotl (Ambystoma mexicanum) is an important model for studying these changes because: 1) it provides important phylogenetic perspective for reconstructing the evolution of vertebrate genomes and amphibian karyotypes, 2) its genome has evolved to a large size (~10X larger than human) but has maintained gene orders, and 3) it possesses potentially young sex chromosomes that have not undergone extensive differentiation in the structure that is typical of many other vertebrate sex chromosomes (e.g. mammalian XY chromosomes and avian ZW chromosomes). Early chromosomal studies were performed through cytogenetics, but more recent methods involving next generation sequencing and comparative genomics can reveal new information. Due to the large size and inherent complexity of the axolotl genome, multiple approaches are needed to cultivate the genomic and molecular resources essential for expanding its utility in modern scientific inquiries. This dissertation describes our efforts to improve the genomic and molecular resources for the axolotl and other salamanders, with the aim of better understanding the events that have driven the evolution of vertebrate (and amphibian) chromosomes. First, I review our current state of knowledge with respect to genome and karyotype evolution in the amphibians, present a case for studying sex chromosome evolution in the axolotl, and discuss solutions for performing analyses of large vertebrate genomes. In the second chapter, I present a study that resulted in the optimization of methods for the capture and sequencing of individual chromosomes and demonstrate the utility of the approach in improving the existing Ambystoma linkage map and generating targeted assemblies of individual chromosomes. In the third chapter, I present a published work that focuses on using this approach to characterize the two smallest chromosomes and provides an initial characterization of the huge axolotl genome. In the fourth chapter, I present another study that details the development of a dense linkage map for a newt, Notophthalmus viridescens, and its use in comparative analyses, including the discovery of a specific chromosomal fusion event in Ambystoma at the site of a major effect quantitative trait locus for metamorphic timing. I then describe the characterization of the relatively undifferentiated axolotl sex chromosomes, identification of a tiny sex-specific (W-linked) region, and a strong candidate for the axolotl sex-determining gene. Finally, I provide a brief discussion that recapitulates the main findings of each study, their utility in current studies, and future research directions. The research in this dissertation has enriched this important model with genomic and molecular resources that enhance its use in modern scientific research. The information provided from evolutionary studies in axolotl chromosomes shed critical light on vertebrate genome and chromosome evolution, specifically among amphibians, an underrepresented vertebrate clade in genomics, and in homomorphic sex chromosomes, which have been largely unstudied in amphibians. genomics large vertebrate genome sex chromosome evolution Ambystoma mexicanum amphibian Bioinformatics Biology Computational Biology Genomics Molecular Genetics
20	On the Evolution of the Avian Transcriptome Uebbing, Severin January 2015 (has links) Change in gene expression is a powerful tool for evolution, because seemingly small expression changes can contribute important steps towards adaptation without necessarily affecting the whole organism. There is still much to learn about how gene expression evolves on genome- and population-wide levels, especially in non-model organisms. This thesis addresses some important questions in gene expression evolution via the quantitative measurement of RNA and protein levels in birds. First, I confirmed the state of incomplete dosage compensation in birds by sequencing the transcriptome of collared flycatchers (Ficedula albicollis). I showed that pleiotropy governs the evolution of expression male-bias from the Z chromosome. Sex-linked genes in females were more highly expressed than half the male expression level, indicative of a partial up-regulation. A comparison with data from ostrich (Struthio camelus), a bird with non-degenerated sex chromosomes, showed that sex-linked expression male-bias evolved following sex chromosome degradation. Second, using a combination of RNA sequencing and proteome mass spectrometry in chicken (Gallus gallus), I asked whether complete dosage compensation was achieved through regulation at translation. I showed that this was not the case and that incomplete dosage compensation extends to the protein level in birds. In addition, sex-linked genes showed more often an increased amount of regulation at translational level than autosomal genes. Third, I investigated gene expression divergence between collared and pied flycatchers (Ficedula hypoleuca) using RNA sequencing in multiple tissues and individuals. Tissues differed in the degree of expression variance and in the number of divergent genes, which I identified using expression QST. Variance within species was negatively correlated with expression breadth and protein interactivity, indicating that evolutionary constraints act predominantly within interbreeding populations. Among genes unique to one of the species, I identified one gene, DPP7, falling into a large genomic deletion fixed in pied flycatchers. Fourth, I investigated allele-specific expression (ASE) in the two flycatcher populations. ASE was identified from genetic variants within transcripts using RNA sequencing reads. We developed a Bayesian negative binomial approach that gained statistical power by estimating expression variance from combined SNPs within a transcript and overdispersion from the whole dataset. evolution gene expression regulation RNA-seq transcriptomics proteomics sex chromosome dosage compensation divergence ASE birds Ficedula flycatcher chicken

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