Global ETD Search

21	p53 activity during adenovirus infection / Die Aktivität des Tumorsuppressors p53 in Adenovirus-infizierten Zellen Savelyeva, Irina 30 October 2009 (has links) No description available. 570 Biowissenschaften, Biologie Mathematics and Computer Science p53 Adenovirus Azetylierung E1A Sp1 p53 acetylation adenovirus E1A Sp1 42.13 Molecular biology WF 200: Molekularbiologie
22	Transcriptional regulation of the Human Zfm1/Sf1 Gene / Transkriptionelle Regulation des humanen Zfm1/ Sf1-Gens Nogoy, Nicole Alberta 05 July 2006 (has links) No description available. 570 Biowissenschaften, Biologie Medicine Gefäßmuskelzellen Proliferation Zfm1 Sp1 Egr1 arteriorsklerose Zfm1/Sf1 atheroscleoris smooth muscle cells proliferation Sp1 Egr1 42 Biologie
23	Promotoranalyse und Expressionsstudien der murinen und humanen fork head homologen Gene Foxq1 und FOXQ1 / Promoter analysis and expression studies of the murine and human fork head homologous genes Foxq1 and FOXQ1 Pasche, Bastian 30 January 2002 (has links) No description available. 32 Biologie WJD 200 WK 000 Mathematics and Natural Science Transkriptionsfaktor fork head Magen Sp1 Sp3 transcription factor fork head stomach Sp1 Sp3 42.23 42.13
24	Unraveling molecular, cellular and cognitive defects in the mouse model for mental retardation caused by Rsk2 gene mutation / Identification des déficits moléculaires, cellulaires et cognitifs chez le modèle souris du retard mental causé par la mutation du gène Rsk2 Mehmood, Tahir 24 February 2012 (has links) Le syndrome de Coffin-Lowry (CLS), une déficience intellectuelle liée à l'X, est causée par des mutations du gène RPS6KA3 codant pour la kinase RSK2 régulée par les facteurs de croissance.Pour comprendre les conséquences du déficit en RSK2 dans l'hippocampe nous avons effectué une comparaison des profils d'expression génique d'hippocampes de souris Rsk2-KO et WT. Elle a révélé l'expression différentielle de 100 gènes, codant pour des protéines agissant dans divers processus biologiques. Nous avons analysé les conséquences de la dérégulation de l'un de ces gènes Gria2 codant pour GluR2, une sous-unité du récepteur glutamate AMPA. Un niveau d'expression doublé de GluR2 a été relevé dans l'hippocampe des souris Rsk2-KO et les études électrophysiologiques y ont révélé une réduction des transmissions AMPAR et NMDAR. L’activité de ERK1/2 était aussi anormalement augmentée dans l'hippocampe des souris Rsk2-KO, ainsi que le niveau de P-Sp1. Ensemble, mes résultats ont suggéré que la surexpression de GluR2 dans les neurones déficients en RSK2, était causée par une augmentation de l'activité transcriptionnelle de Sp1 sur le gène Gria2, qui, elle-même, est le résultat de l’augmentation anormale de l’activité de ERK1 / 2. / Coffin–Lowry Syndrome (CLS), an X-linked form of intellectual disability, is caused by mutations of the RPS6KA3 gene encoding the growth factor regulated kinase RSK2. To understand the consequences of RSK2 deficiency in the hippocampus we performed a comparison of the hippocampal gene expression profiles from Rsk2-KO and WT mice. It revealed differential expression of 100 genes, encoding proteins acting in various biological pathways. We further analyzed the consequences of deregulation of one of these genes, Gria2 encoding GluR2, a subunit of the glutamate AMPAR. An abnormal two-fold increased expression of GluR2 was found in the hippocampus of Rsk2-KO mice. Electrophysiology studies showed a reduction of basal AMPAR and NMDAR mediated transmission, in the hippocampus of Rsk2-KO mice. Activity of ERK1/2 was also abnormally increased in the adult hippocampus of Rsk2-KO mice. P-Sp1 level was also significantly higher in RSK2 deficient cells. Together, my results suggested that over expression of GluR2 in RSK2 deficient cells, is caused by increased Sp1 transcriptional activity on the Gria2 gene, which, itself, is the result of ERK1/2 increased signaling. Syndrome de Coffin-Lowry RSK2 Gria2 Récepteur glutamate AMPA ERK CREB PC12 Sp1 Coffin-Lowry Syndrome RSK2 Gria2 Glutamate receptor ERK CREB PC12 Sp1 572.8 572.6
25	Transcriptional activation by Sp1 and post-transcriptional repression by muscle-specific microRNA miR-133 of expression of human ERG1 and KCNQ1 genes and potential implication in arrhythmogenesis Luo, Xiaobin January 2007 (has links) Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal. HERG1 KCNQ1 Canaux potassiques Sp1 MicroARNs miR-1 miR-133 Arythmies Différences régionales Repolarisation
26	Implication des gènes de Salmonella enterica sérovar Typhi dans les différentes étapes d'infection Béland, Maxime January 2008 (has links) Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal. Salmonella enterica sérovar Typhi Fièvre typhoïde Humain spécifique Differential fluoresence induction GFP Macrophages humains Macrophages murins SP1-1 SP1-2 Salmonella enterica serovar Typhi Typhoid fever Human restricted pathogen Differential fluorescence induction GFP Human macrophages Murine macrophages SP1-1 SP1-2
27	Transcriptional regulation of SRC by the SP family of factors and histone deacetylase inhibitors Ellis, Danielle J. P. 05 July 2007 The SRC gene encodes pp60c-Src, a 60 kDa non-receptor tyrosine kinase that is frequently activated and/or overexpressed in many cancers including colon cancer. In a subset of colon cancer cell lines, it has been shown, that the overexpression of c-Src can be explained, in part, by the transcriptional activation of the SRC gene. As a result, the general goal of this thesis was to further characterize how SRC is transcriptionally regulated in human cancer cell lines. Two highly dissimilar promoters, the housekeeping-like SRC1A promoter, as well as the HIF-1Ñ regulated tissue-specific SRC1Ñ promoter, regulate SRC expression. hnRNP K and the Sp family of factors regulate the SRC1A promoter; however, the true impact of Sp3 on SRC1A activity was not understood. In this thesis, a comprehensive analysis of the effect of Sp3 on SRC1A activity was performed. Physiologically, Sp3 exists as four translational isoforms that, in part, dictate the activation potential of Sp3. In general, the longer forms of Sp3 were modest transcriptional activators of the SRC1A promoter whereas the shorter forms were unable to activate the SRC1A promoter. An analysis of all Sp3 isoforms identified that the shorter Sp3 isoforms could be converted into transcriptional activators of SRC1A if the SUMOylation of a critical lysine residue within the inhibitory domain was prevented. Conversely, SUMOylation of the same isoform had little effect on the activation potential of the longer Sp3 isoforms at the SRC1A promoter. These results suggest that transcriptional activation by Sp3 is promoter context-, isoform- and modification-dependent.<p>SRC is transcriptionally repressed by histone deacetylase inhibitors (HDIs) and despite unsuccessful studies attempting to identify HDI-responsive elements within the SRC promoter regions none could be identified. This finding also suggests that histone deacetylases (HDACs) may be required for SRC expression. Historically, it was believed that HDIs act at the histone level to alter chromatin dynamics through the inactivation of HDACs to result in histone hyperacetylation and increased transcriptional activation. As such, a systematic investigation of the changes in histone H3 and H4 acetylation status at the transcriptionally repressed SRC promoter regions and the transcriptionally activated p21WAF1 promoter region was performed. The p21WAF1 promoter was used as control in this study as p21WAF1 is a classical example of a gene transcriptionally activated by HDIs. Interestingly, similar changes in histone acetylation at the p21WAF1 promoter and both SRC promoter regions were observed. Upon closer examination of acetylation changes at discreet histone residues, it was observed that in the rare case that a particular residue was differentially acetylated upon treatment at the promoter regions analyzed, the SRC1Ñ and p21WAF1 promoter regions demonstrated more similar changes in acetylation as compared to SRC1A. Taken together, these results suggest that histone acetylation status is not an accurate indicator of transcriptional activity following HDI treatment. To further investigate HDI-mediated SRC repression, RNA Pol. II occupancy at the promoter and regions downstream of the promoter were assessed. Despite the continued occupancy of RNA Pol. II at the promoter regions, RNA Pol. II was lost from the 3¡¦ UTR upon treatment with HDIs. These findings suggest that RNA Pol. II . may be sequestered at the promoter regions upon treatment with HDIs possibly as a result of impeded transcription initiation and/or elongation. Further analysis of the phosphorylation status of RNA Pol. II identified that transcriptional initiation was indeed occurring despite HDI treatment; however, productive transcriptional elongation could not be confirmed thus suggesting a role for abrogated elongation in HDI mediated SRC repression. Complimentary analysis of the effects of HDACs on SRC expression suggested that while class I HDACs abrogated SRC expression, class II HDACs were required for the maintenance of SRC transcript levels in a promoter-independent fashion. Together, these results provide the basis for a model whereby HDIs repress SRC transcriptional expression through the inhibition of class II HDAC activity to eventually result in curtailed SRC transcriptional elongation. Sp3 Sp1 RNA Polymerase II histone deacetylases inhibitors SRC acetylation transcription
28	Transcriptional regulation of SRC by the SP family of factors and histone deacetylase inhibitors Ellis, Danielle J. P. 05 July 2007 (has links) The SRC gene encodes pp60c-Src, a 60 kDa non-receptor tyrosine kinase that is frequently activated and/or overexpressed in many cancers including colon cancer. In a subset of colon cancer cell lines, it has been shown, that the overexpression of c-Src can be explained, in part, by the transcriptional activation of the SRC gene. As a result, the general goal of this thesis was to further characterize how SRC is transcriptionally regulated in human cancer cell lines. Two highly dissimilar promoters, the housekeeping-like SRC1A promoter, as well as the HIF-1Ñ regulated tissue-specific SRC1Ñ promoter, regulate SRC expression. hnRNP K and the Sp family of factors regulate the SRC1A promoter; however, the true impact of Sp3 on SRC1A activity was not understood. In this thesis, a comprehensive analysis of the effect of Sp3 on SRC1A activity was performed. Physiologically, Sp3 exists as four translational isoforms that, in part, dictate the activation potential of Sp3. In general, the longer forms of Sp3 were modest transcriptional activators of the SRC1A promoter whereas the shorter forms were unable to activate the SRC1A promoter. An analysis of all Sp3 isoforms identified that the shorter Sp3 isoforms could be converted into transcriptional activators of SRC1A if the SUMOylation of a critical lysine residue within the inhibitory domain was prevented. Conversely, SUMOylation of the same isoform had little effect on the activation potential of the longer Sp3 isoforms at the SRC1A promoter. These results suggest that transcriptional activation by Sp3 is promoter context-, isoform- and modification-dependent.<p>SRC is transcriptionally repressed by histone deacetylase inhibitors (HDIs) and despite unsuccessful studies attempting to identify HDI-responsive elements within the SRC promoter regions none could be identified. This finding also suggests that histone deacetylases (HDACs) may be required for SRC expression. Historically, it was believed that HDIs act at the histone level to alter chromatin dynamics through the inactivation of HDACs to result in histone hyperacetylation and increased transcriptional activation. As such, a systematic investigation of the changes in histone H3 and H4 acetylation status at the transcriptionally repressed SRC promoter regions and the transcriptionally activated p21WAF1 promoter region was performed. The p21WAF1 promoter was used as control in this study as p21WAF1 is a classical example of a gene transcriptionally activated by HDIs. Interestingly, similar changes in histone acetylation at the p21WAF1 promoter and both SRC promoter regions were observed. Upon closer examination of acetylation changes at discreet histone residues, it was observed that in the rare case that a particular residue was differentially acetylated upon treatment at the promoter regions analyzed, the SRC1Ñ and p21WAF1 promoter regions demonstrated more similar changes in acetylation as compared to SRC1A. Taken together, these results suggest that histone acetylation status is not an accurate indicator of transcriptional activity following HDI treatment. To further investigate HDI-mediated SRC repression, RNA Pol. II occupancy at the promoter and regions downstream of the promoter were assessed. Despite the continued occupancy of RNA Pol. II at the promoter regions, RNA Pol. II was lost from the 3¡¦ UTR upon treatment with HDIs. These findings suggest that RNA Pol. II . may be sequestered at the promoter regions upon treatment with HDIs possibly as a result of impeded transcription initiation and/or elongation. Further analysis of the phosphorylation status of RNA Pol. II identified that transcriptional initiation was indeed occurring despite HDI treatment; however, productive transcriptional elongation could not be confirmed thus suggesting a role for abrogated elongation in HDI mediated SRC repression. Complimentary analysis of the effects of HDACs on SRC expression suggested that while class I HDACs abrogated SRC expression, class II HDACs were required for the maintenance of SRC transcript levels in a promoter-independent fashion. Together, these results provide the basis for a model whereby HDIs repress SRC transcriptional expression through the inhibition of class II HDAC activity to eventually result in curtailed SRC transcriptional elongation. Sp3 Sp1 RNA Polymerase II histone deacetylases inhibitors SRC acetylation transcription
29	Mutated RAS Induced PLD1 Gene Expression through Increased Sp1 Trascription Factor MURATE, TAKASHI, NOZAWA, YOSHINORI, BANNO, YOSHIKO, SUZUKI, MOTOSHI, KOJIMA, TETSUHITO, TAKAGI, AKIRA, HAGIWARA, KAZUMI, TAGAWA, YOKO, YOSHIDA, KAYO, FURUHATA, AYAKO, ITO, HIROMI, MURAKAMI, MASASHI, GAO, SIQIANG 09 1900 (has links) No description available. ChIP assay Promoter analysis Sp1 transcription factor PLDI mRNA Mutated ras
30	Implication des gènes de Salmonella enterica sérovar Typhi dans les différentes étapes d'infection Béland, Maxime January 2008 (has links) Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal Salmonella enterica sérovar Typhi Fièvre typhoïde Humain spécifique Differential fluoresence induction GFP Macrophages humains Macrophages murins SP1-1 SP1-2 Salmonella enterica serovar Typhi Typhoid fever Human restricted pathogen Differential fluorescence induction GFP Human macrophages Murine macrophages SP1-1 SP1-2

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