Global ETD Search

71	Exploration du rôle de l'épissage mineur dans le développement embryonnaire : modèle du syndrome de Taybi-Linder) (TALS) / Exploration of minor splicing function during embryonic development with the Taybi-Linder Syndrome (TALS) model Cologne, Audric 10 October 2019 (has links) Le Syndrome de Taybi-Linder (TALS) est une maladie génétique rare affectant le développement embryonnaire, caractérisée par un nanisme microcéphalique sévère et un décès précoce des patients. Le gène muté dans ce syndrome est RNU4ATAC, qui encode un petit ARN nucléaire (snRNA) non-codant : U4atac. Ce snRNA est l’une des briques composant le spliceosome mineur, une machinerie nucléaire dédiée à l’épissage des introns U12, un groupe d’introns peu étudié car présent dans ~1 % des gènes seulement. Dans le TALS, ces introns sont fréquemment retenus dans les transcrits matures, l’épissage correct des introns U12 semble donc capital pour le développement embryonnaire. L’étude du profil transcriptomique des patients TALS permet ainsi d’établir les conséquences moléculaires d’un dysfonctionnement du spliceosome mineur, nous permettant d’en apprendre davantage sur les mécanismes d’épissage des introns U12 en condition physiologique ou pathologique, et sur le rôle de l’épissage mineur dans le développement embryonnaire. Cette thèse présente la première analyse approfondie du transcriptome de cellules provenant de patients TALS. Pour mener cette analyse, nous avons développé un pipeline bioinformatique qui, à partir de données RNA-seq de seconde génération, utilise différentes méthodes dédiées à l’étude différentielle de l’expression des gènes ou de la qualité d’épissage entre patients et contrôles. L’épissage étant particulièrement complexe à analyser à partir de reads courts, deux approches complémentaires ont été utilisées : l’une classique, basée sur l’alignement des reads, et l’autre plus originale, basée sur l’assemblage des reads et permettant de détecter plus d’événements d’épissage non-annotés (KisSplice). Une des conséquences attendue d’un dysfonctionnement du spliceosome mineur est une rétention massive des introns U12 dans les ARN matures. Cependant, la détection et la quantification de rétentions d’intron chez les mammifères constituent encore aujourd’hui un challenge bioinformatique. Nous avons donc utilisé une méthode récente dédiée à l’analyse des rétentions d’introns pour caractériser le plus précisément possible le profil transcriptomique des patients TALS. J’ai ainsi participé au développement de KisSplice et de notre outil d’analyse statistique des différentielles d’épissage, kissDE, et mis en évidence certaines caractéristiques de l’épissage mineur, que ce soit en condition physiologique ou pathologique / The Taybi-Linder Syndrome (TALS) is a rare genetic disorder of the embryonic development leading to a severe microcephaly, a primordial dwarfism and an early/unexpected death. The mutated gene in this syndrome is RNU4ATAC, which encode a non-coding small nuclear RNA (snRNA) named U4atac, involved in the minor spliceosome. This nuclear machinery is dedicated to the splicing of a small number of particular introns : the U12 introns. Because only about 1 % of the Human’s genes display at least one U12 intron, they have not been extensively study and little is known about their function. In TALS patients’ cells, most of the U12 introns are retained in mature transcripts ; hence, splicing of U12 introns seems important for the embryonic development. Studying TALS patients’ cells transcriptomes both in physiological and pathological conditions should enable us to precisely identify most of the molecular consequences of a minor splicing defect and could shed light on the mechanism linking minor splicing and embryonic development. This thesis is the first work to conduct an in depth analysis of TALS patients’ cells transcriptomes. In order to do a precise analysis, we developed a bioinformatic pipeline that uses multiple methods to detect differentially expressed or spliced genes between patients and controls and from second generation RNA-seq data. Splicing analysis is a very complex task complete with short reads ; hence, we used two complementary approaches. The first one is based on reads alignement to a reference genome, method conventionnally used to work on splicing, and the second one is based on reads assembly (KisSplice), a original method enabling to find more non-annotated splicing events. One of the expected consequences of a minor splicing malfunction is a global U12 introns retention in mature transcripts. However, intron retention detection and quantification in mammals is particulary difficult task in mammals, thus we used a new method dedicated to intron retentions analysis to study the transcriptomic profile of TALS patients. During my thesis, I was one of the developer of KisSplice and kissDE, our differential splicing analysis tool, and I identified important charcteristics of minor splicing either in physiological or pathological conditions TALS Épissage mineur Introns U12 RNU4ATAC Transcriptomique Bioinformatique TALS Minor splicing U12 introns RNU4ATAC Transcriptomic Bioinformatic 570
72	Small intron definition of MVM pre-mRNAs Haut, Donald David, January 1998 (has links) Thesis (Ph. D.)--University of Missouri--Columbia, 1998. / Typescript. Vita. Includes bibliographical references (leaves: 111-119). Also available on the Internet.
73	História evolutiva de exon shuffling em eucariotos / Evolutionary history of exon shuffling in eukaryotes Gustavo Starvaggi França 11 February 2010 (has links) Exon shuffling foi primeiramente proposto por Walter Gilbert em 1978 como um mecanismo em que exons de diferentes genes podem ser combinados, levando à formação de novos genes. O mecanismo de exon shuffling é favorecido por recombinações intrônicas e está correlacionado com a simetria de exons. Evidências deste mecanismo provém de análises de combinações de fases de introns, correlações entre bordas de exons e de domínios protéicos e da recorrência de domínios em diversas proteínas. Dessa forma, a evolução de proteínas formadas por exon shuffling pode ser inferida considerando a organização exon-intron dos genes, o padrão de combinações de fases de introns e a organização de domínios nas proteínas. Neste sentido, regiões protéicas que possivelmente foram originadas por eventos de exon shuffling foram identificadas através de análises em larga escala em diferentes espécies eucarióticas. A estratégia foi baseada no alinhamento entre todas as proteínas anotadas de uma determinada espécie e a verificação da presença de introns e suas respectivas fases em torno das regiões alinhadas. Nós verificamos que eventos de exon shuffling em eucariotos antigos, de origem anterior aos Metazoa, são predominantemente simétricos 0-0, enquanto nos metazoários a predominância é de unidades simétricas 1-1. Esses dados confirmam idéias anteriores de que a transição para a multicelularidade animal foi marcada pelo embaralhamento extensivo de exons e domínios 1-1. O metazoário basal Trichoplax adhaerens pode ser considerado um representante desta transição, evidenciada pelas freqüências balanceadas de regiões simétricas 0-0 e 1-1. O sinal de flanqueamento por introns em torno das bordas de domínios protéicos confirmou os resultados obtidos através dos alinhamentos, com a prevalência de domínios 0-0 em não metazoários e 1-1 em metazaoários. Um agrupamento hierárquico de domínios flanqueados por introns foi construído, permitindo identificar domínios ou grupos de domínios com evidência de expansões em períodos específicos, como nos vertebrados. Por fim, os genes envolvidos em eventos de exon shuffling foram analisados quanto ao enriquecimento em termos do Gene Ontology. Os resultados indicaram que este mecanismo contribuiu significativamente para a formação de genes relacionados com uma grande diversidade de termos, alguns dos quais envolvidos diretamente com características de metazoários e vertebrados, tais como matriz extracelular, adesão, coagulação sangüínea, processos do sistema imune e sistema nervoso / Exon shuffling was first proposed by Walter Gilbert in 1979 as a mechanism in which exons from different genes could be combined to lead the creation of new genes. The mechanism of exon shuffling is favored by intronic recombinations and it is correlated with symmetry of exons. Evidence of this mechanism come from analyses of intron phase combinations, correlations between the borders of exons and domains and domain recurrence in several proteins. Taking this into account, the evolution of proteins formed by exon shuffling can be inferred regarding the exonintron organization of the genes, the pattern of intron phase combinations and the protein domain organization. In this sense, protein regions that were probably arose by exon shuffling events were identified through a large scale analysis in several eukaryotic species. The strategy was based on alignments between all annotated proteins from a given species. Then, the aligned regions were verified in respect with intron phase combinations surrounding them. We have found that exon shuffling events in early eukaryotes are preferentially symmetric of phase 0, while in metazoans, the preference is for 1-1 symmetric units. These data confirms previous ideas that the transition to animal multicellularity was marked by extensive 1-1 exon shuffling. The basal metazoan Trichoplax adhaerens is a representative of this transition, evidenced by the balanced frequencies of 0-0 and 1-1 symmetric regions. The signal of intron flanking around the borders of protein domains corroborated previous analyses, showing that non metazoans have higher frequencies of 0-0 domains and metazoans have higher frequencies of 1-1 domains. A hierarchical clustering of domains flanked by introns was built, allowing us to identify domains or groups of domains with evidence of expansions during specific periods, such as in vertebrates. Finally, genes involved in exon shuffling events were analyzed regarding the Gene Ontology enriched terms. The results indicated that this mechanism significantly contributed to the creation of genes related with a large diversity of terms, some of them are directly involved with features of metazoans and vertebrates, such as extracellular matrix, cell adhesion, blood coagulation and immune and nervous system processes Domínios Evolução Exon shuffling Genoma Introns Matriz extracelular Metazoários Domains Evolution Exon shuffling Extracellular matrix Genome Introns Metazoans
74	Les singularités du génome de la paramécie : un bon révélateur des mécanismes évolutifs à l’œuvre chez les êtres vivants / The analysis of the paramecium genom reveals some general evolutionary constraints that shape the genomes of eukaryotes Goût, Jean-François 12 October 2009 (has links) La publication du génome de la paramécie (Aury, 2006) a révélé une séquence atypique particulièrement intéressante pour les études de génomique évolutive. Au cours de cette thèse, j’ai mené une analyse bioinformatique détaillée de ce génome en me concentrant particulièrement sur les trois points suivants : 1) Le rôle de deux classes distinctes de petits ARN fonctionnels non codants, l’une intervenant dans les processus de régulation de l’expression des gènes tandis que l’autre participe aux réarrangements génomiques (élimination de fragments d’ADN) associés au cycle sexuel de la paramécie. 2) L’évolution des paires de gènes après une duplication globale de génome (WGD). En effet, avec une WGD relativement récente précédée de deux autres WGDs plus anciennes encore bien visibles, la paramécie est un modèle de choix pour cette étude. Nous avons pu montrer que la rétention des deux copies d’un gène après une WGD est fortement corrélée au niveau d’expression des gènes. Nous proposons un modèle basé sur les coûts et bénéfices de l’expression des gènes pour expliquer cette observation. 3) L’analyse de contraintes sélectives sur les introns pour produire des messagers détectables par le Nonsense-Mediated mRNA Decay (NMD). Ces contraintes sélectives, mises en évidence initialement chez la paramécie, se sont avérées être présentes chez tous les eucaryotes que nous avons pu analyser, ce qui nous amène à questionner l’efficacité des mécanismes d’épissage chez les eucaryotes et le rôle du NMD dans la prévention des erreurs d’épissage. L’ensemble de ces analyses a permis de mieux comprendre un certain nombre de mécanismes évolutifs universels / This work presents a detailed analysis of the paramecium genome, with focusing more precisely on the 3 following topics : 1) The role of two distinct classes of small non-coding RNAs. The first one (siRNAs) being involved in post-transcriptional gene silencing while the other (scanRNAs) plays a crucial role during the massive genomic rearrangements that occur in ciliates after sexual reproduction (Lepère et al. 2009). 2) The evolution of duplicated genes following Whole-Genome Duplications (WGDs). Indeed, the paramecium genome contains evidences for 3 successive WGDs (Aury et al. 2006), which explains why this organisms is perfectly well suited for such an analysis. We show that retention of duplicated genes is strongly correlated to their expression level and we propose a model based on cost and benefit of gene expression to explain this pattern. 3) The analysis of the extremely tiny introns in paramecium (99% of introns are less than 20-33nt in length) revealed the presence of a translational control of splicing in eukaryotes. This work suggests that splicing errors are frequent and that eukaryotic cells rely on the Nonsense-mediated mRNA Decay to detect aberrant transcripts produced by splicing errors (Jaillon et al. 2008). These analyses provide new insights on several evolutionary mechanisms that shape the genomes of eukaryotes Évolution Cilie Génomique Paramecia Duplication Introns Gène expression Evolution Genomics Whole-genome duplication Duplication Paramecium Introns Ciliates Gene expression 571
75	Evolution and Function of Compositional Patterns in Mammalian Genomes Prakash, Ashwin January 2011 (has links) No description available. Bioinformatics Biomedical Research Genetics Medicine Molecular Biology Genomic Mid range inhomogeneity GMRI MRI introns ncRNA DNA conformations ZDNA HDNA RNA secondary structures miRNA Long non coding RNA piRNA siRNA snoRNA Orthologous introns
76	Functional Characterization Of The Saccharomyces Cerevisiae Splicing Factor, Prp17 In pre-mRNA Splicing And Cell Cycle Progression: An Analysis Through Global Expression Profiling, Protein Interactions And Spliceosomal Associations Katoch, Aparna 07 1900 (has links) The presence of introns in all the eukaryotic genomes identified so far underscores the fundamental and ubiquitous role of pre-mRNA splicing. The spliceosomal machinery, comprised of five small nuclear RNAs and several protein factors, catalyzes the two-transesterification reactions of splicing with precision and consistency. Through a complex network of protein-protein and RNA-protein interactions it ensures the removal of the intron and ligation of the flanking exons to yield the mature mRNA. Prpl7 is a splicing factor that functions at the second-step of splicing (Vijayraghavan et all, 1989). Null alleles of prpl7 are viable at 23°C but die at temperatures above 33°C (Jones et al.9 1995). Besides its functions in pre-mRNA splicing, mutants in PRP17ICDC40 were independently shown to affect cell-cycle progression, particularly the Gl/S and G2/M transitions (Chawla et a/., 2003). In this study, we have attempted a further characterization of Prpl7 to analyze both its role in pre-mRNA splicing and in cell-cycle progression with an aim to decipher underlying reasons for the interlinking of these two cellular processes. Different experimental approaches were adopted to achieve this goal. Global gene-expression profiling provided an overview of all the transcripts affected in a prpl 7 mutant and allowed its comparison with mutants of other splicing factors. This exercise aided in identification of both pre-mRNA splicing and cell-cycle related effects of Prpl7. Biochemical analysis of the Prpl7 spliceosomal associations have provided further clarity on the part played by Prpl7 in pre-mRNA splicing. A genome-wide two-Hybrid screen for interacting partners of Prpl7 was undertaken and uncovered two Likely interacting partners of Prpl7. Global expression profiling of splicing mutants Pleiotropic phenotypes observed in mutants of prpl 7 and few other splicing factors have been speculated to arise from either the multi functionality of the factor or more likely due to a specific requirement of the factor in splicing of a select subset of transcripts, that encode proteins essential to the affected cellular pathway. These observations raise questions about the ubiquitous requirement of factors in pre-mRNA splicing. To understand these aspects of splicing, we studied the effects of splicing factor mutants on a genome-wide scale. Using splicing-sensitive DNA microarrays imprinted with all yeast ORFs and in addition, independent spots for a majority of the intron sequences, we analyzed the global expression changes triggered by the inactivation of temperature-sensitive mutations in PRP17 or PRP22. Experiments with prp2-l mutant strain detect, as expected, an increase in pre-mRNA levels at the intron spots and further demonstrated that the ORF spots detect a decrease in mRNA levels in these DNA microarrays. These results established the DNA micro arrays as tools for the analysis of splicing on a global scale. The temporal alterations in transcript profiles in prpl 7 and prp22 mutants, as compared to the wild type, revealed both shared and unique effects of these factors on clusters of intron-containing transcripts. Such differential effects, on intron-containing transcripts, amongst the splicing mutants implicate specialized roles for each of these factors. Through analysis of the set of intron-containing transcripts affected in prpl7Δ cells, we infer those attributes of these pre-mRNA substrates, which predispose a need for Prpl 7. We find that splicing of introns longer than 200nts has a stronger dependence on Prpl7. The distance between consensus intron elements- the branch-nucleotide and the 3'splice-site (B), also imposes a requirement for Prpl7. Introns with a 13nts or lesser distance between these elements are spliced even in the absence of Prpl 7, both in vivo and in vitro. The 5'splice-site to branch-nucleotide distance (A) also influences the need for Prpl7. Most introns with a A/B ratio of less than 2 undergo Prpl7 independent splicing in vivo. Intron-containing genes that could be responsible for the pleiotropic phenotypes of prpl7 were also identified through the global splicing analysis. These included splicing targets that act at the Gl-S phase such as ANC1/TAF14, TMD4, PHO85 and those at the G2-M phase of the cell-cycle; TUB], TUB3, GIM5, MOBl UBC9. Recently, a different study implicates ANC1ITAF14 as the intron-containing gene responsible for the cell-cycle phenotype associated with prpl7 (Dahan and Kupiec, 2004). Our global analysis of all intron-containing transcripts with compromised expression in prpl7A cells identify, in addition, PHO85 as a possible regulator underlying cell-cycle effects in this mutant. Pho85 is a cyclin-dependent kinase that functions at both the Gl/S and M/Gl phases of the division cycle (Moffate* al., 2000). Synergistic growth defects in double mutants of prpl7 and pho85 have uncovered a novel role for Prpl7 in bud morphogenesis. Our micro array data also reveals compromised expression levels for several key intronless cell-cycle rregulatory genes indicating a possible splicing-independent role for Prpl7 in the cell-cycle. Examples of such transcripts are: the Gl cyclins CLN1, CLN2 and CLN3; CDC6, required for assembly of the pre-replication complex at sites of replication origin; and the cell-cycle regulatory transcription factors: SWI5 and ACE2. The global analysis has therefore enabled, for the first time, a characterization of the splicing substrate specificity of Prpl7 and has also uncovered the effects of this protein on gene expression during cell-cycle progression (Fig. V.I A). Spliceosomal interactions of Prpl7 To understand the function and associations of Prpl7 in the spliceosome, we have examined its snRNP interactions and determined the time point of its coalescence on assembling spliceosomes. A functional epitope tagged-Prpl7 was created using the polyoma middle T-antigen and the poly-HIS tags (Stevens et aln 1999). Through immunoprecipitation analyses performed with splicing extracts, from this strain, we find Prpl7 to associate with three spliceosomal snRNPs- U2, U5 and U6, implicating an interaction with active spliceosomes or post-splicing complexes. Specific biochemical depletion of any one of these snRNAs, through oligo-directed RNaseH cleavage, did not have a drastic effect on the association of Prpl7 with the other two snRNAs. To decipher the point at which Prp 17 joins the assembling spliceosomes, we examined the presence of Prp 17 in in vitro assembled complexes generated under various conditions. The conditions adopted were designed to stall and enrich for •assembly intermediates. A co-immunoprecipitation of the input precursor RNA and reaction intermediates revealed an early association of Prp 17 with the assembling Spliceosome prior to its catalytic activation. This association occurred in the A2-1 complex, which contains the U4/U6.U5 tri-snRNP along with the Ul and U2snRNPs. Prpl7 was found to associate with all subsequent complexes until the completion of catalytic transesterification reactions and possibly continue with the spliced-out introns complex (Fig. V.1B). Identification of two novel interacting partners of Prpl7 from a genome-wide two-hybrid screen Although several genetic interacting partners of PRP17 are known, none display a direct physical association with Prpl7. Knowledge of the proteins that Prpl7 interacts with can further the functional characterization of this protein and aid in deciphering its link to cell-cycle progression. A genome-wide screen for interacting partners using Prpl7 as bait was carried out in a two-hybrid system with a yeast genomic DNA-B42 activation-domain library (Gyuris et al., 1993). Through this screen we identified two interacting partners of Prpl 7- YOL078W, an essential gene and SGML The domain in the 1176 amino acid YOL078W protein responsible for interaction with Prpl7 was mapped to a 225 amino acid segment in the C-terminai region of this protein. The N-terminal region of the protein appears to exert a negative effect on the interaction with Prpl7. While YOL078w does not have any apparent role in pre-mRNA splicing, a majority of the cells arrest with small buds indicating a late Gl or early S phase arrest upon transcriptional shut-down of YOL078W. YOL078W has been independently characterized as AVOl, a component of the TOR complex, involved in nutrient sensing and cell size regulation (Loewith et al, 2002). Other reports show it tto be a component of a complex that interacts with Ceglp, a nuclear protein involved in mRNA capping (Gavin et al, 2002). We hypothesize that Prpl7 and Avol may exist in a dynamic nucleocytoplasmic complex possibly functioning in either cell-cycle regulation, RNA processing or both. Through this study we have Established the use of splicing-sensitive microarrays as tools for the characterization of pre-mRNA splicing factors. Simultaneous assessment of the effects on other cellular pathways was accomplished through expression profiling of all the intron-containing and intronless genes. Deciphered the differential dependence of pre-mRNA substrates on spliceosome factors at a global scale. Predicted the substrate-specificity of the second-step splicing factor, Prpl7, and verified some of these predictions in vitro. Gathered evidence for a possible splicing-independent effect of Prpl7 on the cell division cycle. Uncovered a novel function of Prpl7 in bud morphogenesis, as deduced from its synergistic genetic interaction with PHO85. Identified U2, U5 and U6 snRNPs as interacting partners of Prpl7 in both xtracts and in in vitro splicing reactions. Determined the point of coalescence of Prpl7 during spliceosome assembly to be at an early assembly stage soon after the entry of U4/U6.U5 tri-snRNP and prior to catalytic activation. Demonstrated continued Prpl7 association with the spliceosome beyond the completion of the splicing reactions. Identified Avolp and Sgmlp as novel interacting partners of Prpl7 through a genome-wide two-hybrid screen. Saccharomyces cerevisiae - Splicing pre-mRNA Splicing Protein Interactions Introns Spliceosomal Interactions Gene Expression Spliceosome Spliceosomal Associations pre-mRN Introns Prp17 Microbiology
77	An analysis of genetic determinants that govern exon definition and alternative splicing of minute virus of mice (MVM) pre-mRNAs Gersappe, Anand January 1998 (has links) Thesis (Ph. D.)--University of Missouri--Columbia, 1998. / Typescript. Vita. Includes bibliographical references (leaves: 215-225). Also available on the Internet.
78	Estudos de sistemática molecular e de biogeografia histórica do bagre de água doce Pseudoplatystoma Bleeker, 1862 (Pimelodidae) na América do Sul Costa, Luis Fernando Carvalho 26 March 2010 (has links) Made available in DSpace on 2016-06-02T19:29:23Z (GMT). No. of bitstreams: 1 3030.pdf: 2014938 bytes, checksum: b6d8f7597811d1909e335b6facc588b7 (MD5) Previous issue date: 2010-03-26 / Universidade Federal de Minas Gerais / The catfishes of the Pseudoplatystoma genus are carnivore pimelodids, migratory and important for fisheries in all major river basins from South America. Only three species were recognized for the genus (P. corruscans, P. fasciatum and P. tigrinum), but a new revision raised to eight the number of species (P. fasciatum, P. punctifer, P. orinocoense, P. magdaleniatum, P. reticulatum, P. tigrinum, P. metaense and P. corruscans). Recently, Pseudoplatystoma was the subject of a molecular phylogeny study based on mitochondrial markers, where monophyletic clades where found for P. tigrinum, P. corruscans, P. reticulatum+P. punctifer+P. fasciatum and P. magdaleniatum. Despite these advances on the knowledge of the evolutionary history and systematics of the group, there are still questions to be answered. Thus, this study aimed a molecular phylogenetic analysis on Pseudoplatystoma to try to answer pendant questions about the systematics and taxonomy of the group, and propose a scenario for its diversification history in the geographic area of South America. In order to do this, we employed the mitochondrial Cytochrome b gene and introns from Rag1 and S7 genes, whose phylogenies were estimated by Maximum Likelihood using TREEFINDER software. Nodes were dated on BEAST software. It was shown that some Pseudoplatystoma species, resulting from the last revision of the genus, do not correspond to monophyletic groups or they were not significantly supported clades in all trees. The only monophyletic species in all markers were P. magdaleniatum and P. corruscans. Pseudoplatystoma orinocoense was a monophyletic lineage only on Cytochrome b. In light of these results, it is suggested that the old terminology P. fasciatum to be revalidated for the taxa here defined as P. fasciatum clade: P. punctifer (Amazon, Maranhão, Tocantins-Araguaia), P. reticulatum (Paraná-Paraguay) and P. fasciatum (Guyanas). Under the same rationale, P. tigrinum should be revalidated for Orinoco, given the paraphyletism of P. metaense. However, some cases of nonmonophyletic species in one or more markers may be due to incomplete lineage sorting, although this possibility needs to be investigated using other markers. The history of diversification of Pseudoplatystoma was the result of millions of years of evolution and and it was strongly influenced by the evolution of the South America geographical matrix. The biogeographic study allowed us to identify and date the important diversification events for the genus and relate them to the historical geomorphological and/or climate changes reported for South America, which would be the primary diversification causes for other freshwater fishes from the continent. / Os bagres do gênero Pseudoplatystoma são pimelodídeos carnívoros, migradores e de importância pesqueira em todas as grandes bacias hidrográficas da América do Sul. Apenas três espécies eram reconhecidas para o gênero (P. corruscans, P. fasciatum e P. tigrinum), mas uma nova revisão elevou para oito o número de espécies (P. fasciatum, P. punctifer, P. orinocoense, P. magdaleniatum, P. reticulatum, P. tigrinum, P. metaense e P. corruscans). Recentemente, Pseudoplatystoma foi alvo de um de estudo de filogenia molecular com marcadores mitocondriais, onde foram encontrados clados monofiléticos para P. tigrinum, P. corruscans, P. reticulatum+P. punctifer+P. fasciatum e P. magdaleniatum. Apesar desses avanços no conhecimento da história evolutiva e da sistemática do grupo, ainda restam questões a serem respondidas. Dessa forma, o presente estudo objetivou uma análise filogenética molecular em Pseudoplatystoma para tentar responder questões pendentes sobre a sistemática e taxonomia do grupo, bem como propor um cenário para sua história de diversificação no espaço geográfico da América do Sul. Para isso, foram empregados o gene mitocondrial do Citocromo b e íntrons dos genes Rag1 e S7, cujas filogenias foram estimadas por Máxima Verossimilhança no programa TREEFINDER. Os nós das filogenias foram datados no programa BEAST. Foi demonstrado que algumas espécies de Pseudoplatystoma, resultantes da última revisão do gênero, não correspondem a grupos monofiléticos ou não tiveram clados significativamente sustentados em todas as árvores. As únicas espécies monofiléticas em todos os marcadores foram P. magdaleniatum e P. corruscans. Pseudoplatystoma orinocoense só foi uma linhagem monofilética no Citocromo b. À luz desses resultados, sugere-se que a antiga terminologia P. fasciatum seja revalidada para os táxons do clado aqui definido como clado P. fasciatum: P. punctifer (Amazonas, Maranhão, Tocantins-Araguaia), P. reticulatum (Paraná-Paraguai) e P. fasciatum (Guianas). Sob a mesma racionalidade, P. tigrinum deveria ser revalidado para o Orinoco, dado o parafiletismo de P. metaense. Entretanto, alguns dos casos de espécies não-monofiléticas em um ou mais marcadores podem ser devidos à separação incompleta de linhagens, embora essa possibilidade necessite ser investigada com o uso de outros marcadores. A história da diversificação de Pseudoplatystoma foi resultado de milhões de anos de evolução e fortemente influenciada pela evolução da matriz geográfica Sul-Americana. O estudo biogeográfico nos permitiu identificar e datar os eventos de diversificação importantes para o gênero e relacioná-los às mudanças geomorfológicas e/ou climáticas históricas conhecidas para a América dos Sul, que seriam as causas primárias de diversificação de outros peixes de água doce do continente. Genética animal Filogenia Biogeografia Sistemática Peixes Neotropical Bagres mtDNA nDNA Introns Neotropical Phylogeny Catfish mtDNA nDNA Introns Biogeography Molecular systematics CIENCIAS BIOLOGICAS::ECOLOGIA
79	Generation of recombinant influenza A virus without M2 ion channel protein by introducing a point mutation at the 5' end of viral intron Cheung, Kai-wing. January 2004 (has links) published_or_final_version / abstract / Microbiology / Master / Master of Philosophy Mutation (Biology) Influenza viruses. Membrane proteins - Genetics. Ion channels. Introns. Viral genetics.
80	The roles of CYT-18 in folding, misfolding and structural specificity of the Tetrahymena group I ribozyme Chadee, Amanda Barbara 22 March 2011 (has links) Group I introns are structured RNAs that have been used extensively as model systems for RNA folding because they are experimentally tractable, yet complex enough to have folding challenges associated with larger RNAs. The Tetrahymena group I intron consists of a set of conserved core helices and a set of peripheral elements. Peripheral elements surround the core helices and form long range tertiary contacts between each other and to the core. Interestingly, a long-lived misfolded state is populated that has the same long range tertiary contacts as the native state but differs locally within the core. Our lab showed that the intact periphery is necessary to specify the correct core structure, as mutating tertiary contacts or removing the P5abc peripheral element dramatically destabilized the native ribozyme relative to the misfolded form. However, we also showed that the thermodynamic benefit peripheral structure provided is accompanied by kinetic liability in folding, apparently because native tertiary contacts formed by peripheral elements around the misfolded core must come apart to allow refolding of the misfolded RNA to the native state. In addition to peripheral elements, proteins also play a role in stabilizing the native structures of many group I introns. The CYT-18 protein, which occupies the same binding site as P5abc, stabilizes the functional structures of certain group I introns by using a set of insertions that are absent in other related bacterial and mitochondrial aminoacyl tRNA synthetases. Using the P5abc deletion variant of the Tetrahymena ribozyme, I sought to further define CYT-18 roles in RNA folding by probing its thermodynamic and kinetic effects on the native state formation relative to the misfolded state. I demonstrated that CYT-18, like P5abc, provided thermodynamic stability to the native state. However, unlike P5abc, CYT-18 had no apparent effect on the refolding kinetics, suggesting that a protein co-factor can stabilize the functional structure without acquiring the associated costs in RNA folding kinetics. Furthermore, I found that the mechanism of CYT-18 action appears to be distinct from P5abc. Disruption of the long-range contact P14, which is formed between P5c and L2 and is part of the network of peripheral contacts, dramatically weakened P5abc binding to the native ribozyme core by ~10⁸ fold. Interestingly, CYT-18 maintained specific and tight binding to these mutants, which suggests that CYT-18 does not rely on a circular network of contacts to specifically stabilize the native state. Instead, the specificity may arise from a more direct and intimate contact of CYT-18 with the ribozyme core. This study gives insight into an evolutionary advantage of protein co-factors in RNA folding; proteins may offer thermodynamic assistance without inhibiting folding kinetics. / text Group I introns Structured RNAs RNA folding Tetrahymena Core helices Peripheral elements Tertiary contacts Ribozyme

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