Global ETD Search

11	Caractérisation de l'inactivation du chromosome X chez l'humain à la naissance : distribution et transmission des ratios d'inactivation Bolduc, Véronique January 2006 (has links) Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal. Inactivation du chromosome X Ratios d'inactivation Mosaïcisme biaisé HUMARA Corrélation inter-tissus Transmission XIST
12	Étude moléculaire et cytochimique des métalloendopeptidases PHEX et NEP dans le tissu osseux chez la souris grise Mus musculus et son mutant Hyp Ruchon, Andréa Araujo Frota January 2000 (has links) Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal. Ostéoblaste Ostéocyte Odontoblaste Neprilysin Peptidases
13	L'empreinte génomique : paradigmes du syndrome de Beckwith-Wiedemann et du syndrome de Turner Hamelin, Catherine January 2001 (has links) Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal. Épigénétique Méthylation Origine parentale Chromosome II Chromosome X Jumeaux monozygotiques Microsatellites GH IGF2 H19
14	Mise au point d'une nouvelle approche permettant la génération de délétions chevauchantes sur le chromosome X des cellules ES Fradet, Nadine January 2004 (has links) Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal. Cellules souches embryonnaires Corps embryoïdes LIF Hématopoïèse Développement embryonnaire Technologie Cre/loxP Délétions chevauchantes Chromosome X Locus BTK Rétrovirus
15	Architecture chromosomique du locus Xic : implications pour la régulation de l'inactivation du chromosome X / Chromosomal architecture of the Xic locus : implications for the regulation of X chromosome inactivation Nora, Elphège-Pierre 07 September 2011 (has links) Le développement embryonnaire précoce des mammifères femelles s’accompagne de l’inactivation transcriptionnelle d’un de leurs deux chromosomes X. Cet évènement est initié suite à l’expression mono-allélique de l’ARN non codant Xist, qui est contrôlée par de nombreux éléments cis-régulateurs présents dans le centre d’inactivation du chromosome X (Xic) – tel son anti-sens répresseur Tsix. Mon travail de thèse a consisté à développer des approches permettant d’appréhender le paysage structural dans lequel s’exerce cette régulation. La caractérisation de l’architecture tridimensionnelle du Xic, par des techniques basées sur la capture de conformation chromosomique (3C) et l’hybridation in situ en fluorescence (FISH), m’a permis de mettre en évidence que les promoteurs respectifs de Xist et Tsix sont engagés dans des interactions physiques intimes avec des loci distaux, localisés au sein du Xic, et de montrer qu’au moins certaines de ces régions exercent un effets régulateurs à longue-distance. Les éléments du Xic contactés par les régions promotrices de Xist et de Tsix sont en outre fondamentalement différents, chacune engageant des associations chromosomiques sur plusieurs centaines de kilobases dans leur direction 5’ respective.Ce travail a également permis de révéler des propriétés insoupçonnées de l’architecture chromosomiques. En effet, le Xic apparaît scindé en plusieurs sous-régions, couvrant chacune entre 200kb et 1Mb, à l’intérieur desquelles les interactions chromosomiques sont préférentiellement établies. L’existence de ces domaines d’interaction s’intègre avec d’autres propriétés structurales du génome, tels la composition de la chromatine sous-jacente et l’association à la lamine nucléaire, mais n’apparaît pas en dépendre directement. En étudiant la dynamique de la conformation chromosomique du Xic au cours de la différenciation cellulaire, j’ai pu constater la robustesse de cette organisation, sauf sur le chromosome X inactif, qui se distingue par la perte des contacts chromosomiques préférentiels détectables sur son homologue actif.Enfin, j’ai pu mettre en évidence que la variabilité du repliement général du chromosome X amène à un instant donné chaque allèle de Tsix à contacter physiquement des jeux de séquences distales différents, suggérant que l’environnement structural instantané de chacun de ces allèles à l’orée de l’activation mono-allélique de Xist est différent. Ce travail, combinant des approches à l’échelle de la population cellulaire d’une part et de la fibre de chromatine unique d’autre part, apporte une nouvelle vision du paysage structural et régulateur dans lequel s’inscrit le contrôle de l’activité transcriptionnelle de Xist, et fourni de nouvelles perspectives concernant les principes fondamentaux de l’organisation topologique des chromosomes chez les mammifères. / Early development of female mammals is accompanied by transcriptional inactivation of one of their two X chromosomes. This event is initiated following mono-allelic expression of the Xist non-coding RNA – what is achieved by the interplay of numerous cis-regulatory elements present within the X inactivation center (Xic), such as its repressive antisense Tsix. Our work aimed at throwing light on the structural landscape that underlies such long-range regulation. Characterization of the three-dimensional architecture of the Xic, by the means of Chromosome Conformation Capture (3C)-based techniques and in situ fluorescence hybridization (FISH), revealed that the respective promoters of Xist and Tsix contact many distal genomic elements within the Xic, and that at least one of such interacting region exerts long-range cis-transcriptional control. Noticeably, Xist and Tsix promoters associate with different sets of elements in their respective 5’ direction that are spread out over several hundreds of kilobases These experiments also revealed unforeseen properties of chromatin architecture. Indeed, the Xic appears to be partitioned in several sub-regions, each spanning between 200kb and 1Mb, inside which chromosomal interactions are preferentially established. The existence of these interaction domains integrates with other structural features of the genome, such as underlying chromatin composition and association with the nuclear lamina, but does not seem to directly depend on them. By analyzing chromosome conformation of the Xic during cell differentiation we document the robustness of this organizational principle, with the noticeable exception of the inactive X chromosome that assumes a folding pattern that is more random than its active homolog. Finally we also bring evidence that variability in the folding pattern of the two X chromosomes in the same cell brings each Tsix allele in association with different sets of chromosomal partners at a given moment, suggesting that the instantaneous structural environment of each allele at the onset of mono-allelic Xist up-regulation is different.By combining approaches at the scale of cell populations on the one hand, and at the single chromatin fiber level on the other, this study provides a first vision of the structural landscape in which Xist regulation takes place, and brings new insights concerning fundamental properties of chromosome organization in mammals. Inactivation du chromosome X Régulation transcriptionnelle Architecture nucléaire Interactions chromosomiques X-chromosome inactivation Transcriptional regulation Nuclear organization Chromosomal interactions
16	A Survey of Functional Retroposed Genes: H. sapiens, M. musculus, D. melanogaster, and C. elegans Mahmood, Sanaa 27 July 2010 (has links) Retrogenes are functional genes that are created through retroposition, whereby mature mRNA is reverse-transcribed and re-integrated into the genome. In this study, the following objectives were accomplished: (i) intrachromosomal- and interchromosomal-retroposed genes were located in H. sapiens, (ii) interchromosomal-retroposed genes were located in M. musculus, D. melanogaster, and C. elegans. To date, this is the first assay for intrachromosomal-retroposed genes in H. sapiens and interchromosomal-retroposed genes in C. elegans. Biases discovered include excess interchromosomal generation of retrogenes by chromosome X in H. sapiens, M. musculus, and D. melanogaster. Selection pressure created by the inactivation of the X chromosome during male meiosis appears to be at least partially responsible for this phenomenon. In addition, excess interchromosomal recruitment of retrogenes by chromosome X was observed in H. sapiens. The driving force appears to be an interplay between selection for female-beneficial genes and selection for male-beneficial genes. No other chromosome biases were discovered. Retrogene Chromosome X Homo sapiens Mus musculus Drosophila melanogaster Caenorhabditis elegans MSCI Selection Intrachromosomal Interchromosomal 0307 0369
17	A Survey of Functional Retroposed Genes: H. sapiens, M. musculus, D. melanogaster, and C. elegans Mahmood, Sanaa 27 July 2010 (has links) Retrogenes are functional genes that are created through retroposition, whereby mature mRNA is reverse-transcribed and re-integrated into the genome. In this study, the following objectives were accomplished: (i) intrachromosomal- and interchromosomal-retroposed genes were located in H. sapiens, (ii) interchromosomal-retroposed genes were located in M. musculus, D. melanogaster, and C. elegans. To date, this is the first assay for intrachromosomal-retroposed genes in H. sapiens and interchromosomal-retroposed genes in C. elegans. Biases discovered include excess interchromosomal generation of retrogenes by chromosome X in H. sapiens, M. musculus, and D. melanogaster. Selection pressure created by the inactivation of the X chromosome during male meiosis appears to be at least partially responsible for this phenomenon. In addition, excess interchromosomal recruitment of retrogenes by chromosome X was observed in H. sapiens. The driving force appears to be an interplay between selection for female-beneficial genes and selection for male-beneficial genes. No other chromosome biases were discovered. Retrogene Chromosome X Homo sapiens Mus musculus Drosophila melanogaster Caenorhabditis elegans MSCI Selection Intrachromosomal Interchromosomal 0307 0369
18	Investigação de alterações em genes de microRNAs expressos no cérebro como causa de deficiência intelectual ligada ao cromossomo X / Mutational screening of X-chromosomal brain-expressed microRNA genes in male patients with X-Linked Intellectual Disability Thainá Fernandez Gonçalves 28 January 2014 (has links) Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / A Deficiência Intelectual (DI) é uma condição definida como um funcionamento intelectual significativamente prejudicado, expresso juntamente com limitações em pelo menos duas áreas do comportamento adaptativo que se manifestam antes dos 18 anos de idade. A prevalência estimada da DI na população em geral é de 2-3% e um número expressivo de casos permanece sem um diagnóstico definitivo. Há um consenso geral de que a DI é mais comum em indivíduos do sexo masculino em relação aos do sexo feminino. Entre as explicações para este excesso está a concentração de genes específicos para a habilidade cognitiva no cromossomo X. MicroRNAs (miRNAs) são pequenas moléculas de RNA não codificador que modulam a expressão gênica pós-transcricional de RNAs mensageiros alvo. Recentemente, estudos têm demonstrado a importância essencial dos miRNAs para o desenvolvimento e funcionamento cerebrais e sabe-se que o cromossomo X tem uma alta densidade de genes de miRNAs. Neste contexto, os miRNAs são candidatos potenciais como fatores genéticos envolvidos na Deficiência Intelectual Ligada ao X (DILX). Neste estudo, foram analisadas as regiões genômicas de 17 genes de miRNAs expressos no cérebro localizados no cromossomo X, com o objetivo de investigar o possível envolvimento de variantes na sequência destes miRNAs na DILX. Para este fim, selecionamos amostras de DNA genômico (sangue periférico) de 135 indivíduos do sexo masculino portadores de DI sugestiva de DILX de um grupo de mais de 1.100 pacientes com DI encaminhados ao Serviço de Genética Humana da UERJ. O critério de inclusão para este estudo era de que os probandos apresentassem um ou mais parentes do sexo masculino afetados pela DI que fossem interligados por via materna. As amostras de DNA dos pacientes foram amplificadas utilizando a técnica de reação em cadeia da polimerase, seguida por purificação e sequenciamento direto pelo método de Sanger dos fragmentos amplificados. Para avaliar a conservação dos 17 miRNAs foi realizada uma análise filogenética in silico incluindo sequências dos miRNAs selecionados de humanos e de outras 8 espécies de primatas estreitamente relacionadas. Não foram encontradas alterações nas sequências nos genes de 17 miRNAs analisados, mesmo diante do padrão genético altamente heterogêneo da população brasileira. Adicionalmente, a análise filogenética destes miRNAs revelou uma alta conservação entre as espécies comparadas. Considerando o papel dos miRNAs como reguladores da expressão gênica, a ausência de alterações e a alta conservação entre primatas sugerem uma forte pressão seletiva sobre estas moléculas, reforçando a sua importância funcional para o organismo em geral. Apesar de não termos encontrado variantes de sequência nos miRNAs estudados, o envolvimento de miRNAs na DI não pode ser completamente descartado. Alterações fora da molécula de miRNA precursor, nos fatores de processamento, nos sítios alvo e variações no número de cópias de genes de miRNAs podem implicar em alteração na expressão dos miRNAs e, consequentemente, na funcionalidade do miRNA maduro. Sendo assim, uma análise sistemática da expressão de miRNAs em pacientes com DILX é urgentemente necessária, a fim de desvendar novos genes/mecanismos moleculares relacionados a esta condição. / Intellectual Disability (ID) is defined as a significantly impaired intellectual functioning, along with limitations in at least two areas of adaptive behavior appearing before 18 years of age. The estimated prevalence of ID in the general population is 2-3% and a significant number of cases remain without a definite diagnosis. There is a general consensus that ID is more common in males compared to females. Among the explanations for this excess it is the concentration of specific genes for cognitive ability on the chromosome X. MicroRNAs (miRNAs) are small non-coding RNA molecules that modulate post-transcriptional gene expression of target messenger RNAs. Recently, studies have demonstrated the essential importance of miRNAs for brain development and function and chromosome X has a high density of miRNA genes. In this context, miRNAs are potential candidates as genetic factors involved in X-Linked Intellectual Disability (XLID). In this study, the genomic regions of 17 brain-expressed miRNA genes located on the chromosome X were analyzed, aiming to investigate the possible involvement of sequence variants in these miRNAs in XLID. For this purpose, genomic DNA samples (peripheral blood) were obtained from 135 male patients with ID suggestive of XLID that were selected from a group of over 1,100 patients with ID referred to to the Human Genetics Laboratory of the State University of Rio de Janeiro. Inclusion criteria were at least two affected males in different generations related through maternal lineage. DNA samples from patients were amplified using the polymerase chain reaction technique, followed by purification and direct sequencing by Sanger method. To assess the conservation of the 17 miRNAs, in silico phylogenetic analysis was performed, including sequences of the chosen miRNAs from human and from other 8 closely related primate species. No sequence changes were found for the 17 miRNA genes analyzed, even in light of the highly heterogeneous genetic nature of the Brazilian population. Furthermore, phylogenetic analysis of the selected miRNAs revealed a high conservation among the compared species. Considering the role of miRNAs as regulators of gene expression, the absence of variations and the high conservation among primates suggest a strong selective pressure on these molecules, emphasizing their functional importance for the body in general. Although we have found no sequence variants in the miRNAs studied, the involvement of miRNAs in ID cannot be completely rejected. Alterations outside the precursor miRNA molecules, in the processing factors, in the target sites and changes in copy number of miRNA genes can result in abnormal expression of miRNAs and, consequently, in the functionality of the mature miRNA. Thus, a systematic analysis of miRNAs expression in patients with XLID is urgently needed in order to uncover new genes/molecular mechanisms related to this condition. Deficiência Intelectual Ligada ao X MicroRNA Cérebro Cromossomo X X-Linked Intellectual Disability MicroRNA Brain Chromosome X GENETICA HUMANA E MEDICA
19	Investigação de alterações em genes de microRNAs expressos no cérebro como causa de deficiência intelectual ligada ao cromossomo X / Mutational screening of X-chromosomal brain-expressed microRNA genes in male patients with X-Linked Intellectual Disability Thainá Fernandez Gonçalves 28 January 2014 (has links) Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / A Deficiência Intelectual (DI) é uma condição definida como um funcionamento intelectual significativamente prejudicado, expresso juntamente com limitações em pelo menos duas áreas do comportamento adaptativo que se manifestam antes dos 18 anos de idade. A prevalência estimada da DI na população em geral é de 2-3% e um número expressivo de casos permanece sem um diagnóstico definitivo. Há um consenso geral de que a DI é mais comum em indivíduos do sexo masculino em relação aos do sexo feminino. Entre as explicações para este excesso está a concentração de genes específicos para a habilidade cognitiva no cromossomo X. MicroRNAs (miRNAs) são pequenas moléculas de RNA não codificador que modulam a expressão gênica pós-transcricional de RNAs mensageiros alvo. Recentemente, estudos têm demonstrado a importância essencial dos miRNAs para o desenvolvimento e funcionamento cerebrais e sabe-se que o cromossomo X tem uma alta densidade de genes de miRNAs. Neste contexto, os miRNAs são candidatos potenciais como fatores genéticos envolvidos na Deficiência Intelectual Ligada ao X (DILX). Neste estudo, foram analisadas as regiões genômicas de 17 genes de miRNAs expressos no cérebro localizados no cromossomo X, com o objetivo de investigar o possível envolvimento de variantes na sequência destes miRNAs na DILX. Para este fim, selecionamos amostras de DNA genômico (sangue periférico) de 135 indivíduos do sexo masculino portadores de DI sugestiva de DILX de um grupo de mais de 1.100 pacientes com DI encaminhados ao Serviço de Genética Humana da UERJ. O critério de inclusão para este estudo era de que os probandos apresentassem um ou mais parentes do sexo masculino afetados pela DI que fossem interligados por via materna. As amostras de DNA dos pacientes foram amplificadas utilizando a técnica de reação em cadeia da polimerase, seguida por purificação e sequenciamento direto pelo método de Sanger dos fragmentos amplificados. Para avaliar a conservação dos 17 miRNAs foi realizada uma análise filogenética in silico incluindo sequências dos miRNAs selecionados de humanos e de outras 8 espécies de primatas estreitamente relacionadas. Não foram encontradas alterações nas sequências nos genes de 17 miRNAs analisados, mesmo diante do padrão genético altamente heterogêneo da população brasileira. Adicionalmente, a análise filogenética destes miRNAs revelou uma alta conservação entre as espécies comparadas. Considerando o papel dos miRNAs como reguladores da expressão gênica, a ausência de alterações e a alta conservação entre primatas sugerem uma forte pressão seletiva sobre estas moléculas, reforçando a sua importância funcional para o organismo em geral. Apesar de não termos encontrado variantes de sequência nos miRNAs estudados, o envolvimento de miRNAs na DI não pode ser completamente descartado. Alterações fora da molécula de miRNA precursor, nos fatores de processamento, nos sítios alvo e variações no número de cópias de genes de miRNAs podem implicar em alteração na expressão dos miRNAs e, consequentemente, na funcionalidade do miRNA maduro. Sendo assim, uma análise sistemática da expressão de miRNAs em pacientes com DILX é urgentemente necessária, a fim de desvendar novos genes/mecanismos moleculares relacionados a esta condição. / Intellectual Disability (ID) is defined as a significantly impaired intellectual functioning, along with limitations in at least two areas of adaptive behavior appearing before 18 years of age. The estimated prevalence of ID in the general population is 2-3% and a significant number of cases remain without a definite diagnosis. There is a general consensus that ID is more common in males compared to females. Among the explanations for this excess it is the concentration of specific genes for cognitive ability on the chromosome X. MicroRNAs (miRNAs) are small non-coding RNA molecules that modulate post-transcriptional gene expression of target messenger RNAs. Recently, studies have demonstrated the essential importance of miRNAs for brain development and function and chromosome X has a high density of miRNA genes. In this context, miRNAs are potential candidates as genetic factors involved in X-Linked Intellectual Disability (XLID). In this study, the genomic regions of 17 brain-expressed miRNA genes located on the chromosome X were analyzed, aiming to investigate the possible involvement of sequence variants in these miRNAs in XLID. For this purpose, genomic DNA samples (peripheral blood) were obtained from 135 male patients with ID suggestive of XLID that were selected from a group of over 1,100 patients with ID referred to to the Human Genetics Laboratory of the State University of Rio de Janeiro. Inclusion criteria were at least two affected males in different generations related through maternal lineage. DNA samples from patients were amplified using the polymerase chain reaction technique, followed by purification and direct sequencing by Sanger method. To assess the conservation of the 17 miRNAs, in silico phylogenetic analysis was performed, including sequences of the chosen miRNAs from human and from other 8 closely related primate species. No sequence changes were found for the 17 miRNA genes analyzed, even in light of the highly heterogeneous genetic nature of the Brazilian population. Furthermore, phylogenetic analysis of the selected miRNAs revealed a high conservation among the compared species. Considering the role of miRNAs as regulators of gene expression, the absence of variations and the high conservation among primates suggest a strong selective pressure on these molecules, emphasizing their functional importance for the body in general. Although we have found no sequence variants in the miRNAs studied, the involvement of miRNAs in ID cannot be completely rejected. Alterations outside the precursor miRNA molecules, in the processing factors, in the target sites and changes in copy number of miRNA genes can result in abnormal expression of miRNAs and, consequently, in the functionality of the mature miRNA. Thus, a systematic analysis of miRNAs expression in patients with XLID is urgently needed in order to uncover new genes/molecular mechanisms related to this condition. Deficiência Intelectual Ligada ao X MicroRNA Cérebro Cromossomo X X-Linked Intellectual Disability MicroRNA Brain Chromosome X GENETICA HUMANA E MEDICA
20	Využití metody paralelního sekvenování při stanovování zešikmení X inaktivace / Use of massive parallel sequencing in determination of skewed X inactivation Veselková, Tereza January 2016 (has links) Skewed X chromosome inactivation has been often studied as a possible factor that influences manifestation of X-linked diseases in heterozygous women. Yet the association between phenotype and degree of skewing stays unclear for most disorders. Current works rely mostly on methods that are based on methyl-sensitive restriction while determining the X inactivation pattern and mainly the HUMARA assay which investigates the methylation profile in the AR gene. However those methods have some known disadvantages and therefore we are still seeking new methodical approaches. We used DNA isolated from whole blood and in some cases also buccal swabs to asses X inactivation patterns in 54 women using methylation-based methods for loci AR, CNKSR2 and RP2. Transcription-based assay was utilized to evaluate skewing of X inactivation in 32 of those women, whose samples were available for RNA extraction, using massive parallel sequencing and polymorphisms LAMP2 c.156A>T, IDS c.438C>T and ABCD1 c.1548G>A. Partly thanks to almost no stuttering during PCR the RP2 locus was the most informative in our study (71 % of women) and approximately the same number of women (69 %) were informative for the HUMARA assay. However when comparing the results of those two methods we determined difference greater than 10 % in...

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