Global ETD Search

41	Genome Evolution of Neurospora tetrasperma Sun, Yu January 2013 (has links) In this thesis work, I have used a comparative genomics approach to study a fungal model organism, Neurospora tetrasperma. My specific focus has been on genomic introgression, intron evolution, chromosomal structural rearrangements and codon usage. All of the studies are based on large-scale dataset generated by next-generation sequencing technology (NGS), combined with other techniques, such as Optical Mapping. In the introgression study, we detected large-scale introgression tracts in three N. tetrasperma lineages, and the introgression showed allele-specific and chromosomal-specific pattern. In the study of introns, we found indications of mRNA mediated intron loss and non-homologous end joining (NHEJ) mediated intron gains in N. tetrasperma. We found that selection is involved in shaping intron gains and losses, and associated with intron position, intron phase and GC content. In the study of chromosomal structural rearrangements, we found a lineage specific chromosomal inversion pattern in N. tetrasperma, which indicates that inversions are unlikely to associate with the origin of the suppressed recombination and the mating system transition in N. tetrasperma. The result suggests inversions are the consequences, rather than the causes, of suppressed recombination on the mating-type chromosome of N. tetrasperma. In the final study, analyses of codon usage indicated that the region of suppressed recombination in N. tetrasperma is subjected to genomic degeneration, and selection efficiency has been much reduced in this region. Neurospora tetrasperma next-generation sequencing introgression intron chromosomal inversion codon usage
42	Évolution à fine échelle des sites d'épissage des introns dans les gènes des oomycètes Bocco, Steven Sêton 08 1900 (has links) Les introns sont des portions de gènes transcrites dans l’ARN messager, mais retirées pendant l’épissage avant la synthèse des produits du gène. Chez les eucaryotes, on rencontre les introns splicéosomaux, qui sont retirés de l’ARN messager par des splicéosomes. Les introns permettent plusieurs processus importants, tels que l'épissage alternatif, la dégradation des ARNs messagers non-sens, et l'encodage d'ARNs fonctionnels. Leurs rôles nous interrogent sur l'influence de la sélection naturelle sur leur évolution. Nous nous intéressons aux mutations qui peuvent modifier les produits d'un gène en changeant les sites d'épissage des introns. Ces mutations peuvent influencer le fonctionnement d'un organisme, et constituent donc un sujet d'étude intéressant, mais il n'existe actuellement pas de logiciels permettant de les étudier convenablement. Le but de notre projet était donc de concevoir une méthode pour détecter et analyser les changements des sites d'épissage des introns splicéosomaux. Nous avons finalement développé une méthode qui repère les évènements évolutifs qui affectent les introns splicéosomaux dans un jeu d'espèces données. La méthode a été exécutée sur un ensemble d'espèces d'oomycètes. Plusieurs évènements détectés ont changé les sites d’épissage et les protéines, mais de nombreux évènements trouvés ont modifié les introns sans affecter les produits des gènes. Il manque à notre méthode une étape finale d'analyse approfondie des données récoltées. Cependant, la méthode actuelle est facilement reproductible et automatise l'analyse des génomes pour la détection des évènements. Les fichiers produits peuvent ensuite être analysés dans chaque étude pour répondre à des questions spécifiques. / Introns are portions of genes transcribed into messenger RNA, but removed during RNA splicing. In eukaryotes, they are called spliceosomal introns as they are removed by spliceosomes. Introns allow many important processes such as alternative splicing, nonsense-mediated decay and functional-RNA coding. These roles leads to the question of the influence of natural selection on evolution of introns. We focus on mutations that are able to change gene products by modifing introns splice sites. These mutations seems to be an interesting topic as they can affect proteins, but there is currently no software to study them properly. The aim of our project was to design a method to detect and analyze changes in splice sites of spliceosomal introns. We finally developed a method that locates the evolutionary events on splice sites of spliceosomal introns in a given species set. The method was performed on a set of oomycetes. Several detected events change splice sites and proteins, but there is also many events that seems to modify introns without affecting gene products. Our method lacks a final step for thorough analysis of the collected events. However, the current method is easily reusable and automates genome analysis for the detection of events. The resulting files can then be analyzed in each study to answer specific questions. Intron Évolution Eucaryote Épissage Gène Eukaryote Splicing Gene Evolution
43	Phylogénie moléculaire et morphologique des Detarieae résinifères (Leguminosae : Caesalpinioideae) : contribution à l'étude de l'histoire biogéographique des légumineuses Fougère-Danezan, Marie January 2005 (has links) Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal. Phylogénie Biogéographie Leguminosae Caesalpinioideae Detarieae Intron du trnL Espaceur trnL-F Espaceurs transcrits internes ITS Morphologie
44	UNDERSTANDING EVOLUTIONARY RELATIONSHIPS IN THE ANGIOSPERM ORDER APIALES BASED ON ANALYSES OF ORGANELLAR DNA SEQUENCES AND NUCLEAR GENE DUPLICATIONS Nicolas, Antoine 29 April 2009 (has links) I studied evolutionary history in the angiosperm order Apiales, with a special emphasis on interactions between form, time, and space. Four broad categories of problems were addressed: interfamilial relationships in Apiales, the assignment of genera traditionally assigned to the Apiaceae subfamily Hydrocotyloideae, the estimation of divergence times of the major clades, and the reconstruction of the biogeographic history of Apiales. We used molecular markers with different evolutionary properties and rates derived from the plastid (trnD-trnT and rpl16), nuclear (RPB2), and mitochondrial (nad1 intron 2) genomes, from more than 250 species representing all major clades in the order. The nuclear RPB2 region exhibited evidence of at least six duplication events in Apiales and provided a rich source of information for understanding the origins of polyploid lineages, especially in Araliaceae. Sequence comparisons among the copies show that exon regions are highly conserved. All copies appear to be functional but may have undergone subfunctionalization. Phylogenetic analyses of the three genomes suggest that Hydrocotyloideae should be divided into as many as six evolutionary lineages, but that most taxa should be included in subfamilies Azorelloideae and Mackinlayoideae. Relationships among and within the major clades of Azorelloideae need further analyses since many genera appeared non-monophyletic (e.g., Azorella, Schizeilema, and Eremocharis). Mackinlayoideae appeared as the earliest diverging lineage of Apiaceae, but the plastid and nuclear trees were incongruent in the placement of the Platysace clade relative to Mackinlayoideae and the rest of Apiaceae. Among the remaining clades of suborder Apiineae, Myodocapaceae appeared sister to Apiaceae in both plastid and nuclear trees, preceded by the divergence of Araliaceae and then Pittosporaceae. At the base of the gene trees in Apiales, Griseliniaceae and Torricelliaceae formed successive sisters to Apiineae. The placement of Pennantiaceae as sister to the rest of Apiales was confirmed by plastid data, but was not found in the nuclear trees. The order appears to have originated in the Cretaceous, with Apiineae having an age of c. 100 Mya. Australasia appears to be the most likely center of origin for Apiineae and most of its major clades, except Azorelloideae (South America) and Apioideae-Saniculoideae (sub-Saharan Africa). Apiales Hydrocotyloideae RPB2 trnD-trnT rpl16 nad1 intron 2 Life Sciences
45	Molekulární fylogeografie lína obecného Tinca tinca (Linnaeus, 1758) / Molecular phylogeography of the tench Tinca tinca (Linnaeus, 1758) Lajbner, Zdeněk January 2011 (has links) The tench Tinca tinca (Linnaeus, 1758) is a valued table fish native to Europe and Asia, but which is now widely distributed in many temperate freshwater regions of the world as the result of human-mediated translocations. Spatial genetic analysis applied to sequence data from four unlinked loci (introns of three nuclear genes and mitochondrial DNA) defined two groups of populations that were little structured geographically but were significantly differentiated from each other, and it identified locations of major genetic breaks, which were concordant across genes and were driven by distributions of two major phylogroups. This pattern most reasonably reflects isolation in two principal glacial refugia and subsequent range expansions, with the Eastern and Western phylogroups remaining largely allopatric throughout the tench range. However, this phylogeographic variation was also present in European cultured breeds and some populations at the western edge of the native range contained the Eastern phylogroup. Thus, natural processes have played an important role in structuring tench populations, but human-aided dispersal have also contributed significantly, with the admixed genetic composition of cultured breeds most likely contributing to the introgression. I have then designed novel PCR-RFLP assays...
46	Structure and conformational rearrangements during splicing of the ribozyme component of group II introns Li, Cheng-Fang 27 June 2011 (has links) (PDF) Les introns de groupe II forment une classe d'ARN connus avant tout pour leur activité ribozymique, qui leur permet de catalyser leur propre réaction d'épissage. Sous certaines conditions, ces introns peuvent s'exciser des ARN précurseurs dont ils font partie et assurer la ligation des exons qui les bordent sans l'aide d'aucune protéine. Les introns de groupe II sont généralement excisés sous forme d'un lariat, semblable à celui formé par les introns des prémessagers nucléaires, dont l'épissage est assurée par le spliceosome. De telles similarités dans le mécanisme d'épissage suggèrent que les introns de groupe II et les introns des prémessagers nucléaires pourraient avoir un ancêtre évolutif commun.Malgré leurs séquences très diverses, les introns de groupe II peuvent être définis par une structure secondaire commune, hautement conservée. Celle-ci est formée de six domaines (domaine I à domaine VI ; D1-D6), émergeant d'une roue centrale. L'épissage des introns de groupe II comprend deux étapes, et autant de réactions de transestérification, qui produisent les exons liés et l'intron excisé sous forme lariat. Il est généralement admis que la structure du ribozyme subit des changements conformationnels entre les deux étapes de l'épissage et que le domaine VI est un acteur clé dans ce phénomène. Cependant, malgré l'identification d'un certain nombre d'interactions tertiaires entre domaines, ni la RMN, ni les études faisant appel à des modifications chimiques ne sont parvenues à déterminer l'environnement immédiat, au niveau du site actif du ribozyme, de l'adénosine qui sert de point de branchement de la structure en lariat, ainsi que des nucléotides qui entourent cette adénosine au sein du domaine VI. A l'aide d'analyses phylogénétiques et d'une modélisation moléculaire tridimensionnelle, nous avons identifié plusieurs sections du ribozyme susceptibles de constituer le site de fixation du domaine VI au cours de l'étape de branchement. Des mutations ont été introduites dans ces sites de fixation potentiels et la cinétique de réaction des ARN mutants résultants a été déterminée. Afin de démontrer formellement l'interaction du domaine VI avec le site récepteur le plus probable, une molécule de ribozyme dont la réaction de branchement est assurée par l'addition d'oligonucléotides ADN ou ARN qui positionnent correctement le domaine VI vis-à-vis de son partenaire a été construite. En combinant l'information apportée par différentes expériences de ce type, nous avons pu générer un modèle à résolution atomique du complexe formé par le domaine VI, son site de branchement et le reste de l'intron au moment où l'épissage est initié. Group II intron Ribozyme structure Conformational rearrangements Docking site of DVI
47	Alternativ splicing och hur den förhåller sig till växters alternativa splicing / Alternativ splicing in animals and how it relates to the alternative splicing in plants Gasparini, Isabella January 2010 (has links) <p>Alternativ splicing är en process som ger upphov till att olika mRNA-sekvenser bildas från en enda gen, vilket bidrar till en ökad proteindiversitet hos organismen. Olika mRNA-sekvenser kan uppstå eftersom att det förekommer olika varianter av alternativ splicing som även kan kombineras på flera olika sätt: cassette exon (inkludering/exkludering av exon), intron retention (intronet behålls), alternative 5´splice-site choice (olika 5´ splice sites kan väljas) och slutligen alternative 3´ splice-site choice (andra 3´ splice sites kan väljas). För att alternativ splicing ska äga rum i olika pre-mRNA måste den regleras av cis-reglerande element. De cis-reglerande elementen utgörs av fyra grupper: exonic splicing enhancers (ESE), exonic splicing silencers (ESS), intronic splicing enhancers (ISE) samt intronic splicing silencers (ISS). Som namnen förtäljer finns de antingen i exoner eller introner, där de interagerar med transagerande faktorer, SR-proteiner (aktiverare) eller hnRNPs (hämmare). Alternativ splicing förekommer både i djur och i växter. Hos <em>Homo sapiens </em>genomgår över 74 % av de 25,000 gener som finns hos organismen, alternativ splicing. Däremot i växten <em>Arabidopsis thaliana</em>, genomgår endast 22 %, av den totala mängden på cirka 26,000 gener, alternativ splicing. Eftersom att processen bidrar till en ökad proteindiversitet, kommer det medföra att olika processer i organismerna påverkas, exempelvis celltillväxt, celldöd samt utvecklingen av olika sjukdomar, såsom Parkinson och cystisk fibros. Många studier har gjorts som bekräftar dess betydelse för organismerna men på grund av processens komplexitet är det fortfarande ett ämne som ständigt måste utforskas.</p><p> </p> Alternativ splicing spliceosom exon intron splice sites SR-proteiner hnRNPs NATURAL SCIENCES NATURVETENSKAP
48	RNA and DNA Inactivation Strategies to Prevent or Inhibit HIV-1 Replication via Gene Therapy Nazari, Reza 20 January 2009 (has links) AIDS is caused by a lentivirus, HIV-1. In addition to antiretroviral drugs that are currently in use for HIV/AIDS therapy, a number of gene therapy strategies have been designed as alternative therapies. Most of these therapies target HIV RNA/proteins, which are subject to high rate of mutation, resulting in escape mutants. Viral entry is mediated by CCR5 co-receptor in most routes of transmission. To downregulate CCR5 as a gene therapy approach, we targeted seven unique sites within the CCR5 mRNA by a multimeric hammerhead ribozyme, Rz1-7. Hammerhead ribozyme is a small RNA that cleaves a target RNA upon binding to it. Expressing the Rz1-7 from HIV-1- and MSCV-based vectors in otherwise susceptible cells inhibited replication of a CCR5-tropic strain of HIV-1 by 99-100%. The Rz1-7 will be tested for inhibition of HIV-1 replication in the CD4+ T-lymphoid and myeloid progeny of transduced human CD34+ hematopoietic progenitor stem cells. It may be preferable to interfere HIV-1 life cycle at the DNA level since a one-time inactivation might suffice to confer a complete and permanent inhibition of virus replication in the gene modified cells and their progeny. This is what other strategies that target the HIV-1 RNA/protein can hardly offer. For this purpose, group II introns, which are able to splice out and get incorporated into a specific DNA sequence, can be designed/modified to gain novel DNA targeting specificities. As a novel approach, we have examined whether insertion of a modified intron into an infectious HIV-1 clone at two sites within the integrase domain of HIV-1 pol gene could inhibit virus replication. Intron insertion into the HIV-1 clone was induced and mammalian cells were transfected with intron-inserted HIV-1 clones. Although similar amounts of HIV-1 RNA, protein, and progeny virus were produced from the clones as from wild-type HIV-1 provirus DNA, in the absence of a functional integrase, the HIV-1 reverse-transcribed DNA failed to integrate and virus replication was aborted. These results demonstrate that modified group II introns can confer complete inhibition of virus replication at the level of second round of infection. We are now developing vectors to assess whether intron insertion can take place in mammalian cells. HIV-1 gene therapy Interfering RNA CCR5 co-receptor Integrase Hammerhead ribozyme Group II intron 0307
49	RNA and DNA Inactivation Strategies to Prevent or Inhibit HIV-1 Replication via Gene Therapy Nazari, Reza 20 January 2009 (has links) AIDS is caused by a lentivirus, HIV-1. In addition to antiretroviral drugs that are currently in use for HIV/AIDS therapy, a number of gene therapy strategies have been designed as alternative therapies. Most of these therapies target HIV RNA/proteins, which are subject to high rate of mutation, resulting in escape mutants. Viral entry is mediated by CCR5 co-receptor in most routes of transmission. To downregulate CCR5 as a gene therapy approach, we targeted seven unique sites within the CCR5 mRNA by a multimeric hammerhead ribozyme, Rz1-7. Hammerhead ribozyme is a small RNA that cleaves a target RNA upon binding to it. Expressing the Rz1-7 from HIV-1- and MSCV-based vectors in otherwise susceptible cells inhibited replication of a CCR5-tropic strain of HIV-1 by 99-100%. The Rz1-7 will be tested for inhibition of HIV-1 replication in the CD4+ T-lymphoid and myeloid progeny of transduced human CD34+ hematopoietic progenitor stem cells. It may be preferable to interfere HIV-1 life cycle at the DNA level since a one-time inactivation might suffice to confer a complete and permanent inhibition of virus replication in the gene modified cells and their progeny. This is what other strategies that target the HIV-1 RNA/protein can hardly offer. For this purpose, group II introns, which are able to splice out and get incorporated into a specific DNA sequence, can be designed/modified to gain novel DNA targeting specificities. As a novel approach, we have examined whether insertion of a modified intron into an infectious HIV-1 clone at two sites within the integrase domain of HIV-1 pol gene could inhibit virus replication. Intron insertion into the HIV-1 clone was induced and mammalian cells were transfected with intron-inserted HIV-1 clones. Although similar amounts of HIV-1 RNA, protein, and progeny virus were produced from the clones as from wild-type HIV-1 provirus DNA, in the absence of a functional integrase, the HIV-1 reverse-transcribed DNA failed to integrate and virus replication was aborted. These results demonstrate that modified group II introns can confer complete inhibition of virus replication at the level of second round of infection. We are now developing vectors to assess whether intron insertion can take place in mammalian cells. HIV-1 gene therapy Interfering RNA CCR5 co-receptor Integrase Hammerhead ribozyme Group II intron 0307
50	Alternativ splicing och hur den förhåller sig till växters alternativa splicing / Alternativ splicing in animals and how it relates to the alternative splicing in plants Gasparini, Isabella January 2010 (has links) Alternativ splicing är en process som ger upphov till att olika mRNA-sekvenser bildas från en enda gen, vilket bidrar till en ökad proteindiversitet hos organismen. Olika mRNA-sekvenser kan uppstå eftersom att det förekommer olika varianter av alternativ splicing som även kan kombineras på flera olika sätt: cassette exon (inkludering/exkludering av exon), intron retention (intronet behålls), alternative 5´splice-site choice (olika 5´ splice sites kan väljas) och slutligen alternative 3´ splice-site choice (andra 3´ splice sites kan väljas). För att alternativ splicing ska äga rum i olika pre-mRNA måste den regleras av cis-reglerande element. De cis-reglerande elementen utgörs av fyra grupper: exonic splicing enhancers (ESE), exonic splicing silencers (ESS), intronic splicing enhancers (ISE) samt intronic splicing silencers (ISS). Som namnen förtäljer finns de antingen i exoner eller introner, där de interagerar med transagerande faktorer, SR-proteiner (aktiverare) eller hnRNPs (hämmare). Alternativ splicing förekommer både i djur och i växter. Hos Homo sapiens genomgår över 74 % av de 25,000 gener som finns hos organismen, alternativ splicing. Däremot i växten Arabidopsis thaliana, genomgår endast 22 %, av den totala mängden på cirka 26,000 gener, alternativ splicing. Eftersom att processen bidrar till en ökad proteindiversitet, kommer det medföra att olika processer i organismerna påverkas, exempelvis celltillväxt, celldöd samt utvecklingen av olika sjukdomar, såsom Parkinson och cystisk fibros. Många studier har gjorts som bekräftar dess betydelse för organismerna men på grund av processens komplexitet är det fortfarande ett ämne som ständigt måste utforskas. Alternativ splicing spliceosom exon intron splice sites SR-proteiner hnRNPs NATURAL SCIENCES NATURVETENSKAP

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