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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
191

Small steps and grand leaps: a study of micro- and macroevolutionary processes

Tzika, Athanasia 14 March 2008 (has links)
Evolutionary biology is not a specialty, like genetics or development - it is an explanation of what is investigated by all biological specialties. Thus, the goal of this dissertation was to study both micro- and macroevolutionary processes in a multi-disciplinary framework.<p>Population genetics, conservation, and phylogeny inference. The Jamaican boa (Epicrates subflavus) is an endemic species, whose natural populations greatly and constantly declined since the late 19th century, mainly due to predation by introduced species, human persecution, and habitat destruction. Using species-specific nuclear microsatellite loci and mitochondrial sequences, we investigated the population structure of this endangered reptile. All analyses pinpointed to an Eastern versus (Western+Central) pattern of differentiation in agreement with geological data and patterns of differentiation uncovered in other vertebrate and invertebrate Jamaican species. The same molecular markers were employed on 80 Jamaican boas of the European captive breeding program. This approach allowed us to (i) clarify all ambiguities in the studbook, (ii) correct parental allocation errors and (iii) assess the genetic diversity and the level of inbreeding of the current captive population. These results provide important insights for guiding the development of proper ex-situ and in-situ species survival and habitat management plans for this vulnerable snake. In the same framework of classical evolutionary genetics, we performed preliminary analyses of cytochrome b-like sequences in representatives of all cetacean families (but one), and revealed the presence of at least four nuclear mitochondrial pseudogenes that were independently inserted into the nuclear genome. <p>Evo-Devo. The emergence of Evolutionary Developmental biology has caused a partial shift in the criteria for the selection of model species. Thus far, the main criterion was the relevance of a species for understanding human biology, whereas in the frame of the new discipline, it is the understanding of the generative mechanisms underlying biological diversity that is put forward. We discussed a few criteria and limitations of major relevance to the choice of model species for Evo-Devo studies, and applied a pragmatic approach to identify possible model species within Amniotes. <p>Moreover, we developed MANTiS, an application pipeline that aims at integrating genomic, functional and expression data with evolutionary concepts, thus constituting the missing link between multi-species genome comparisons and functional analyses. Using MANTiS, we proceeded in the analysis of 35 metazoan full genomes for identifying all lineage-specific gene gains and losses. These results were combined with functional and expression analyses, and we demonstrated the much higher performance of MANTiS against popular databases of ortholog clusters (InParanoid, OrthoMCL, RoundUp).<p>Finally, preliminary results of our attempt to adapt the new revolutionary technology of DNA sequencing in microfabricated high-density picoliter reactors (developed by 454/Roche) to the ultra-fast sequencing of brain full transcriptomes in multiple reptilian species are highly promising. As an example, the Crocodylus sample generated more than 72 Mbases (per run), which were successfully assembled in approximately 31,000 contigs. One third of the latter could be matched to known sequences in the transcriptome of related species. After fine-tuning of the in silico analyses, and incorporation of genomic sequence data, we expect our approach to provide important insights not only in the evolution of central nervous system novelties in vertebrates, but in transcriptomes in general as the brain transcriptome is one of the most complex among all organs.<p> / Doctorat en Sciences / info:eu-repo/semantics/nonPublished
192

Exploration of microbial diversity and evolution through cultivation independent phylogenomics

Martijn, Joran January 2017 (has links)
Our understanding of microbial evolution is largely dependent on available genomic data of diverse organisms. Yet, genome-sequencing efforts have mostly ignored the diverse uncultivable majority in favor of cultivable and sociologically relevant organisms. In this thesis, I have applied and developed cultivation independent methods to explore microbial diversity and obtain genomic data in an unbiased manner. The obtained genomes were then used to study the evolution of mitochondria, Rickettsiales and Haloarchaea. Metagenomic binning of oceanic samples recovered draft genomes for thirteen novel Alphaproteobacteria-related lineages. Phylogenomics analyses utilizing the improved taxon sample suggested that mitochondria are not related to Rickettsiales but rather evolved from a proteobacterial lineage closely related to all sampled alphaproteobacteria. Single-cell genomics and metagenomics of lake and oceanic samples, respectively, identified previously unobserved Rickettsiales-related lineages. They branched early relative to characterized Rickettsiales and encoded flagellar genes, a feature once thought absent in this order. Flagella are most likely an ancestral feature, and were independently lost during Rickettsiales diversification. In addition, preliminary analyses suggest that ATP/ADP translocase, the marker for energy parasitism, was acquired after the acquisition of type IV secretion systems during the emergence of the Rickettsiales. Further exploration of the oceanic samples yielded the first draft genomes of Marine Group IV archaea, the closest known relatives of the Haloarchaea. The halophilic and generally aerobic Haloarchaea are thought to have evolved from an anaerobic methanogenic ancestor. The MG-IV genomes allowed us to study this enigmatic evolutionary transition. Preliminary ancestral reconstruction analyses suggest a gradual loss of methanogenesis and adaptation to an aerobic lifestyle, respectively. The thesis further presents a new amplicon sequencing method that captures near full-length 16S and 23S rRNA genes of environmental prokaryotes. The method exploits PacBio's long read technology and the frequent proximity of these genes in prokaryotic genomes. Compared to traditional partial 16S amplicon sequencing, our method classifies environmental lineages that are distantly related to reference taxa more confidently. In conclusion, this thesis provides new insights into the origins of mitochondria, Rickettsiales and Haloarchaea and illustrates the power of cultivation independent methods with respect to the study of microbial evolution.
193

Taxano-genomics, a strategy incorporating genomic data into the taxonomic description of human bacteria / Taxono-génomique, une stratégie incorporant des données génomiques dans la description taxonomique des bactéries humaines

Padmanabhan, Babu roshan 08 December 2014 (has links)
Mon projet de doctorat était de créer un pipeline pour taxono-génomique pour la comparaison de plusieurs génomes bactériens. Deuxièmement, je automatisé le processus d'assemblage (NGS) et annotation à l'aide de divers logiciels open source ainsi que la création de scripts de maison pour le laboratoire. Enfin, nous avons intégré le pipeline dans la description de plusieurs espèces bactériennes de laboratoire sur. Cette thèse est divisée principalement en Taxono- génomique et Microbiogenomics. Les avis de la section taxono-génomique, décrit sur les avancées technologiques en génomique et métagénomique pertinentes dans le domaine de la microbiologie médicale et décrit la stratégie taxono-génomique en détail et comment la stratégie polyphasique avec des approches génomiques sont reformatage de la définition de la taxonomie bactérienne. Les articles décrivent les bactéries cliniquement importantes, leur séquençage complet du génome et les études génomiques comparatives, génomiques et taxono-génomique de ces bactéries. Dans cette thèse, j'ai inclus les articles décrivant ces organismes: Megasphaera massiliensis, Corynebacterium ihumii, Collinsella massiliensis, Clostridium dakarense. Bacillus dielmoensis, jeddahense, Occidentia Massiliensis, Necropsobacter rosorum et Pantoea septica. Oceanobacillus / My PhD project was to create a pipeline for taxono-genomics for the comparison of multiple bacterial genomes. Secondly I automated the process of assembly (NGS) and annotation using various open source softwares as well as creating in house scripts for the lab. Finally we incorporated the pipeline in describing several bacterial species from out lab. This thesis is subdivided mainly into Taxono-genomics and Microbiogenomics. The reviews in taxono-genomics section, describes about the technological advances in genomics and metagenomics relevant to the field of medical microbiology and describes the strategy taxono-genomics in detail and how polyphasic strategy along with genomic approaches are reformatting the definition of bacterial taxonomy. The articles describes clinically important bacteria, their whole genome sequencing and the genomic, comparative genomic and taxono-genomic studies of these bacteria.
194

Funkčně genomická a farmakogenomická analýza aspektů metabolického syndromu / Functional genomic and pharmacogenomic analysis of metabolic syndrome aspects

Krupková, Michaela January 2014 (has links)
Metabolic syndrome is a prevalent disease characterized by concurrent manifestation of insulin resistance, obesity, dyslipidemia, hypertension and other hemodynamic and metabolic disorders. It has multifactorial type of inheritance and its resultant phenotype is determined by both environmental and genetic factors as well as their interactions. That is the main reason why comprehensive analysis of the genetic component of this syndrome is complicated in human population. Genetically designed experimental animal models are significant tools for analysis of genetic architecture of human complex conditions including the metabolic syndrome. The aim of this Thesis is utilization of functional and comparative genomic tools to uncover pathogenesis of metabolic syndrome aspects and their genetic determinants. We also studied pharmacogenetic interactions of these genetic determinants with drugs affecting particular components of the metabolic syndrome. Establishing and utilizing several genetically designed congenic rat strains, we undertook four different research projects focusing on pharmacogenetic interaction of all-trans retinoic acid and ondansetron with differential segment of rat chromosome 8, pharmacogenetic interaction of differential segment of rat chromosome 4 and dexamethasone, determining Plzf...
195

Microbial endophytes and their interactions with cranberry plants

Bustamante Villalobos, Peniel 01 1900 (has links)
Virtuellement toutes les plantes hébergent des champignons et des bactéries endosymbiontes (endophytes). Ces microorganismes façonnent le développement de leur hôte et peuvent inhiber des phytopathogènes. Au niveau moléculaire, les interactions plante-endophyte sont médiées par des molécules secrétées y compris des protéines et métabolites secondaires. Au cours des dernières années, la recherche d’endophytes a augmenté chez nombreux plantes, cependant chez les Ericaceae les endophytes ne sont pas bien connus. Alors, on s’est mis à investiguer les endophytes racinaires de la canneberge, une plante membre d’Ericaceae native de l’Amérique du Nord. On a échantillonné quatre plants provenant d’une ferme commerciale organique. Au total, 30 souches fongiques et 25 bactériens ont été isolés. Les bactéries Pseudomonas sp. EB212, Bacillus sp. EB213 et EB214; et les champignons Hyaloscypha sp. EC200, Pezicula sp. EC205 et Phialocephala sp. EC208 ont supprimé la croissance de cinq pathogènes de la canneberge, incluant Godronia cassandrae, un champignon causant la pourriture des fruits de la canneberge au Québec. EB213 a été capable de promouvoir légèrement la croissance de plantules de la canneberge. En performant des techniques microscopiques, on a constaté l’habileté de EC200, EC205 et EC208 à coloniser internement les racines des plantules de la canneberge. De plus, les génomes de ces champignons ont été séquencés, assemblés et annotés. Les analyses génomiques se sont concentrées sur les protéines secrétées et les groupes des gènes impliqués dans la biosynthèse (GGB). On a trouvé un large répertoire de gènes codant pour des enzymes qui métabolisent les carbohydrates et d’autres codant pour des protéases. Les deux groupes d’enzymes seraient utiles à dégrader de la matière organique pour libérer des nutriments. Aussi bien, ces enzymes pourraient faciliter la colonisation des racines de la plante hôte. De plus, on a prédit des nombreuses protéines effectrices qui assisteraient les endophytes à éviter l’activation du système immunitaire des plants. A noter que parmi les GGB inférés dans les génomes de EC200, EC205 et EC208, environ 90% ne sont pas caractérisés. Finalement, on a performé des analyses transcriptomiques pour élucider la réponse de EC200, EC205 et EC208 envers la présence de leur hôte, simulée par l’addition d’un extrait de canneberge au milieu de culture. Les conclusions majeures sont que les racines des plantes de la canneberge qui ont été échantillonnées sont dominées par des microorganismes avec l’habileté d’inhiber des phytopathogènes ; et que les génomes de EC200, EC205 et EC208 codent pour un grand répertoire de protéines qui pourraient être liées aux interactions plante-endophyte. / Virtually all plants host fungal and bacterial endosymbionts (endophytes). These microbes shape plant development and may inhibit phytopathogens. At the molecular level, plant-endophyte interactions are mediated by secreted compounds, including proteins and secondary metabolites. While endophytes are increasingly studied in diverse plants, little is known about their presence in Ericaceae. Therefore, we set out to investigate the root endophytes of cranberry, an ericacean member native to North America. We sampled endophytes from four plants grown on an organic farm. In total, 30 fungal and 25 bacterial strains were isolated and identified. A subset of these, notably Pseudomonas sp. EB212, Bacillus sp. EB213 and EB214; and fungi Hyaloscypha sp. EC200, Pezicula sp. EC205, and Phialocephala sp. EC208, were tested for their ability to suppress phytopathogens. Altogether, they inhibited five cranberry pathogens, including Godronia cassandrae, an important cranberry fruit-rot agent in Quebec. EB213 was the only endophyte that increased the biomass of cranberry seedlings. Using microscopy techniques, we confirmed the ability of EC200, EC205, and EC208 to colonize cranberry roots internally. The genomes of these fungi were sequenced, assembled and annotated. Genomic analyses focused on secreted proteins and biosynthetic gene clusters (BGCs). We found an extensive repertoire of carbohydrate-active enzymes and proteases that could assist in recycling organic nutrients, rendering them accessible to plants; these enzymes may also facilitate root colonization. In addition, effector proteins were predicted; these molecules may assist endophytes to escape the plant immune system and favour colonization. We inferred 139 biosynthetic gene clusters (BGCs) across the three examined fungi. Remarkably, the product of around 90% of BGCs are unknown. Finally, transcriptomic analyses were performed to determine how EC200, EC205 and EC208 respond to the presence of cranberry, simulated by the addition of cranberry extract in the culture medium. The two major conclusions of this work are that the roots of the sampled cranberry plants are dominated by endophytes with biocontrol abilities, and that EC200, EC205 and EC208 encode a broad repertoire of proteins that could be involved in plant-endophyte interactions.
196

Phyletic Distribution and Diversification of the Phage Shock Protein Stress Response System in Bacteria and Archaea

Popp, Philipp F, Gumerov, Vadim M., Andrianova, Ekaterina P., Bewersdorf, Lisa, Mascher, Thorsten, Zhulin, Igor B., Wolf, Diana 19 March 2024 (has links)
Maintaining cell envelope integrity is of vital importance for all microorganisms. Not surprisingly, evolution has shaped conserved protein protection networks that connect stress perception, transmembrane signal transduction, and mediation of cellular responses upon cell envelope stress. The phage shock protein (Psp) stress response is one such conserved protection network. Most knowledge about the Psp response derives from studies in the Gram-negative model bacterium Escherichia coli, where the Psp system consists of several well-defined protein components. Homologous systems were identified in representatives of the Proteobacteria, Actinobacteria, and Firmicutes. However, the Psp system distribution in the microbial world remains largely unknown. By carrying out a large-scale, unbiased comparative genomics analysis, we found components of the Psp system in many bacterial and archaeal phyla and describe that the predicted Psp systems deviate dramatically from the known prototypes. The core proteins PspA and PspC have been integrated into various (often phylum-specifically) conserved protein networks during evolution. Based on protein domain-based and gene neighborhood analyses of pspA and pspC homologs, we built a natural classification system for Psp networks in bacteria and archaea. We validate our approach by performing a comprehensive in vivo protein interaction study of Psp domains identified in the Gram-positive model organism Bacillus subtilis and found a strong interconnected protein network. Our study highlights the diversity of Psp domain organizations and potentially diverse functions across the plethora of the microbial landscape, thus laying the ground for studies beyond known Psp functions in underrepresented organisms.
197

The Roles of Moron Genes in the Escherichia Coli Enterobacteria Phage Phi-80

Ivanov, Yury V. 23 October 2012 (has links)
No description available.
198

<b>Two Case Studies on the Use of Public Bioinformatics Data Toward Open-Access Research</b>

Daphne Rae Krutulis (18414876) 20 April 2024 (has links)
<p dir="ltr">Open-access bioinformatics data enables accessible public health research for a variety of stakeholders, including teachers and low-resourced researchers. This project outlines two case studies utilizing open-access bioinformatics data sets and analysis software as proofs of concept for the types of research projects that can be adapted for workforce development purposes. The first case study is a spatial temporal analysis of Lyme disease rates in the United States from 2008 to 2020 using freely available data from the United States Department of Agriculture and Centers for Disease Control and Prevention to determine how urbanization and other changes in land use have impacted Lyme disease rates over time. The second case study conducts a pangenome analysis using bacteriophage data from the Actinobacteriophage Database to determine conserved gene regions related to host specificity.</p>
199

Evolutionary usage and developmental roles of vertebrate non-methylated DNA

Long, Hannah Katherine January 2014 (has links)
Vertebrate genomes exhibit global methylation of cytosine residues where they occur in a cytosine-guanine dinucleotide (CpG) context and this epigenetic mark is generally thought to be repressive to transcription. Punctuating this pervasive DNA methylation landscape are short, contiguous regions of non-methylated DNA which are found at two thirds of mammalian gene promoters. These non-methylated regions exhibit CpG content close to expected levels as they escape the depletion of CpGs observed across the methylated fraction of the genome. The unique nucleotide properties of these CpG island (CGI) regions enable their identification by computational prediction in mammalian genomes. Owing to a lack of high-resolution genome-wide DNA methylation profiles in non-mammalian species, these CGI predictions have often been used as a proxy for non-methylated DNA in these organisms. In contrast to mammals, CGI predictions in cold-blooded vertebrates rarely coincide with gene promoters, leading to the belief that CGls are significantly divergent between vertebrate species, and that unique promoter-associated features may have been acquired during warmblooded vertebrate evolution. This thesis is primarily concerned with the location, establishment and biological function of non-methylated islands of DNA in vertebrate genomes. To experimentally determine genome-wide profiles of non-methylated DNA, a novel biochemical technique was established called biotinylated ZF-CxxC affinity purification (Bio-CAP), and development of this method is discussed in Chapter 3. Experimental analysis of non-methylated DNA profiles in this thesis initially addresses two main questions: (1) 'How does the non-methylated DNA landscape compare genome-wide for seven vertebrates considering distinct tissue types and developmental stages?' (2) 'How are vertebrate non-methylated regions of DNA defined and interpreted in the nuclear environment?' To address the first question, non-methylated DNA was profiled by Bio-CAP sequencing across the genomes of seven diverse vertebrate species, representing all major branch points of vertebrate evolution, and the results are discussed in Chapters 4 and S. Contrary to previously held dogma, experimentally determined nonmethylated islands of DNA (NMls) constitute an ancient epigenetic feature of vertebrate gene regulatory elements. However, despite having numerous high-resolution maps of vertebrate non-methylated DNA, the means by which NMls are identified and maintained in the nuclear environment remains poorly understood. To address the second question and identify features which determine the methylation state of DNA, exogenous DNA sequences were introduced into mouse embryonic stem (ES) c~.II~. Non-methylated DNA was profiled by Bio-CAP sequencing to investigate how different features, such as sequence-specific binding motifs, chromatin architecture and nucleotide composition of a given DNA sequence impact local DNA methylation patterns. Interestingly, the majority of exogenous promoters were appropriately non-methylated in mouse ES cells, germline and somatic cells suggesting that gene promoters have retained strong signals for the nonmethylated state across millions of years of evolution (discussed in Chapter 6). During mouse embryogenesis, genome-scale DNA demethylation and remethylation events occur to remodel the epigenetic landscape and loss of DNA methylation during this time leads to embryonic lethality. To investigate the biological function of non-methylated DNA, the third question addressed in this thesis is (3) 'What is the developmental importance of non-methylated islands of DNA during vertebrate embryogenesis?' To investigate this, members of the ZF-CxxC domain-containing family of chromatin modifiers were ablated in zebrafish embryos to perturb the chromatin landscape at NMls, and therefore interfere with their function during early development (Chapter 7). Early embryonic development and patterning was disrupted in knockdown embryos, suggesting that interpretation of non-methylated DNA and placement of chromatin modifications at NMls is essential for normal zebrafish embryogenesis. Together this work sheds light on the evolutionary origins of NMls, the mechanisms involved in the recognition and establishment of nonmethylated loci and provides an insight into the function of non-methylated DNA during early embryonic development.
200

Algorithmes pour la réconciliation d’un arbre de gènes avec un arbre d’espèces

Doyon, Jean-Philippe 04 1900 (has links)
Une réconciliation entre un arbre de gènes et un arbre d’espèces décrit une histoire d’évolution des gènes homologues en termes de duplications et pertes de gènes. Pour inférer une réconciliation pour un arbre de gènes et un arbre d’espèces, la parcimonie est généralement utilisée selon le nombre de duplications et/ou de pertes. Les modèles de réconciliation sont basés sur des critères probabilistes ou combinatoires. Le premier article définit un modèle combinatoire simple et général où les duplications et les pertes sont clairement identifiées et la réconciliation parcimonieuse n’est pas la seule considérée. Une architecture de toutes les réconciliations est définie et des algorithmes efficaces (soit de dénombrement, de génération aléatoire et d’exploration) sont développés pour étudier les propriétés combinatoires de l’espace de toutes les réconciliations ou seulement les plus parcimonieuses. Basée sur le processus classique nommé naissance-et-mort, un algorithme qui calcule la vraisemblance d’une réconciliation a récemment été proposé. Le deuxième article utilise cet algorithme avec les outils combinatoires décrits ci-haut pour calculer efficacement (soit approximativement ou exactement) les probabilités postérieures des réconciliations localisées dans le sous-espace considéré. Basé sur des taux réalistes (selon un modèle probabiliste) de duplication et de perte et sur des données réelles/simulées de familles de champignons, nos résultats suggèrent que la masse probabiliste de toute l’espace des réconciliations est principalement localisée autour des réconciliations parcimonieuses. Dans un contexte d’approximation de la probabilité d’une réconciliation, notre approche est une alternative intéressante face aux méthodes MCMC et peut être meilleure qu’une approche sophistiquée, efficace et exacte pour calculer la probabilité d’une réconciliation donnée. Le problème nommé Gene Tree Parsimony (GTP) est d’inférer un arbre d’espèces qui minimise le nombre de duplications et/ou de pertes pour un ensemble d’arbres de gènes. Basé sur une approche qui explore tout l’espace des arbres d’espèces pour les génomes considérés et un calcul efficace des coûts de réconciliation, le troisième article décrit un algorithme de Branch-and-Bound pour résoudre de façon exacte le problème GTP. Lorsque le nombre de taxa est trop grand, notre algorithme peut facilement considérer des relations prédéfinies entre ensembles de taxa. Nous avons testé notre algorithme sur des familles de gènes de 29 eucaryotes. / A reconciliation between a gene tree and a species tree depicts an evolutionary scenario of the homologous genes in terms of gene duplications and gene losses. To infer such a reconciliation given a gene tree and a species tree, parsimony is generally used according to the number of gene duplications and/or losses. The combinatorial models of reconciliation are based on probabilistic or combinatorial criteria. The first paper defines a simple and more general combinatorial model of reconciliation which clearly identifies duplication and loss events and does not only induce the most parsimonious reconciliation. An architecture of all possible reconciliations is developed together with efficient algorithms (that is counting, randomization, and exploration) to study combinatorial properties of the space of all reconciliations or only the most parsimonious ones. Based on the classical birth-death process, an algorithm that computes the likelihood of a reconciliation has recently been proposed. The second paper uses this algorithm together with the combinatorial tools described above to compute efficiently, either exactly or approximately, the posterior probability of the reconciliations located in the considered subspace. Based on realistic gene duplication and loss rates and on real/simulated datasets of fungal gene families, our results suggest that the probability mass of the whole space of reconciliations is mostly located around the most parsimonious ones. In the context of posterior probability approximation, our approach is a valuable alternative to a MCMC method and can competes against a sophisticated, efficient, and exact computation of the probability of a given reconciliation. The Gene Tree Parsimony (GTP) problem is to infer a species tree that minimizes the number of duplications and/or losses over a set of gene family trees. Based on a new approch that explores the whole species tree space for the considered taxa and an efficient computation of the reconciliation cost, the third paper describes a Branch-and- Bound algorithm that solves exactly the GTP problem. When the considered number of taxa is too large, our algorithm can naturally take into account predefined relationships between sets of taxa. We test our algorithm on a dataset of eukaryotic gene families spanning 29 taxa.

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