Global ETD Search

1	An investigation of splicing-dependent transcriptional checkpoints Thelakkad Chathoth, Keerthi January 2013 (has links) Pre-mRNA splicing and other RNA processing events occur co-transcriptionally. High resolution kinetic studies performed in our lab showed splicing-dependent RNA Pol II (RNA polymerase II) pausing near the 3’ splice site of a reporter gene. Pausing requires splicing, as mutations that block splicing lead to loss of pausing, and restoring splicing restores pausing. It was proposed that RNA Pol II pausing may occur at splicing-dependent transcriptional checkpoints. In this study, I aimed to search for splicing helicases that might couple splicing with transcription. The ts alleles prp5-1 and prp16-2 were found to cause transcription defects. These genes encode RNA helicases that were reported to act as fidelity factors during splicing. In vivo RNA labelling and RT-qPCR experiments performed with these temperature-sensitive mutants demonstrated reduced transcription coinciding with the splicing defect at restrictive temperature. Furthermore, RNA Pol II ChIP analysis showed polymerase accumulating over intron-containing genes in both mutants. ChIP analysis using antibodies specific to the phosphorylation status of the CTD (Carboxy Terminal Domain) of RNA Pol II, revealed that the apparently stalled polymerase is hyper-phosphorylated at serine 5. Intriguingly, prp8-R1753K, a ts allele of PRP8, a non-helicase splicing factor mutant also showed reduced nascent RNA synthesis but no RNA Pol II accumulation. To elucidate the reason for the observed RNA Pol II accumulation and to identify a possible splicing-dependent transcriptional checkpoint factor, prp5-1 was investigated further. RNA Pol II ChIP-Seq analysis verified that maximum enrichment genome-wide occurred on introns at restrictive conditions in prp5-1, supporting the earlier observation. Furthermore, the double mutant strain cus2Δprp5-1 abolished the RNA Pol II accumulation observed in prp5-1 at restrictive temperature and restored transcription. Recreating a stalled spliceosome in a U2 mutant strain also showed RNA Pol II accumulation in the presence of Cus2p, as observed in prp5-1. My observations suggest a link between transcription and monitoring of splicing and indicate that Cus2p, a U2 snRNP associated protein, could be a checkpoint factor in transcription prior to pre-spliceosome formation. I speculate that fidelity factors may impose transcriptional checkpoints at different stages of splicing. 572.8
2	Helicases and DNA dependent ATPases of Sulfolobus solfataricus Richards, Jodi D. January 2008 (has links) DNA is susceptible to various types of damage as a result of normal cellular metabolism or from environmental sources. In order to maintain genome stability a number of different, partially overlapping DNA repair pathways have evolved to tackle specific lesions or distortions in the DNA. Nucleotide excision repair (NER) is highly conserved throughout eukarya, bacteria and archaea and predominantly targets lesions that result from exposure to UV light, for example cyclobutane pyrimidine dimers and 6-4 photoproducts. The majority of archaea possess homologous of the eukaryotic repair genes and this thesis describes the isolation and the characterization of two XPB homologues identified in the crenarchaeon Sulfolobus solfataricus, SsoXPB1 and SsoXPB2. Human XPB is one of 10 proteins that make up the TFIIH transcription complex. The activity of XPB is tightly controlled by protein interactions, in particular with p52, which stimulates the ATPase activity of XPB. Rather than a conventional helicase, human XPB is thought to act as an ATP dependent conformational switch. Consistent with human XPB, however, the S. solfataricus proteins were unable to catalyse strand separation and the identification of an archaeal protein partner, Bax1, for SsoXPB2 was one of the focuses of this project. In order to maintain genome stability, the DNA must be replicated accurately with each cell cycle. When the advancing replication fork stalls at a lesion or a DNA break, it is crucial that the fork is reset and that replication continues to completion. The helicase Hel308 is thought to clear the lagging strand template of a stalled replication fork in order for replication restart to proceed via homologous recombination (HR). Although the specific function of Hel308 is not well understood, the possibilities are described in this thesis. Strand exchange proceeds to form a D-loop, followed by branch migration to increase regions of heterology during the synapsis stage of HR. No motors for branch migration have previously been recognised in archaea, although the identification of a possible candidate was investigated during this project. 572.8
3	Možnosti zahradnické produkce v urbánních ladech a veřejných prostorách postindustriálního města / The possibilities of horticultural production in stalled spaces and public spaces of postindustrial city Adamková, Jana January 2019 (has links) The image of the postindustrial city is formed by public spaces (streets, plazas and squares, parks, riverfronts and waterfronts) together with a wide range of underused urban spaces and long-term unused areas of stalled spaces. The subject of this work is research of different types of urban gardening spaces and their optimal spatial, operational and functional parameters in the context of urbanism and urban planning. The aim is to apply them to the structure of unused urban spaces. On the basis of the case studies included in the research, the success of placement of individual community projects in different types of public spaces and stalled spaces is assessed. Recommendations for planning practice are based on these evaluations. The results of the work show that spaces with possibilities of horticultural production are a suitable solution for the temporary and also long-term use of under-utilized urban areas with many benefits in social, economic and environmental areas.
4	Saccharomyces cerevisiae DNA helicases Mph1, Srs2 and Sgs1 collaborate for the reinitiation of stalled or collapsed replication forks / Die DNA-Helikasen Mph1, Srs2 and Sgs1 aus Saccharomyces cerevisiae kollaborieren im Rahmen der Reinitiation arretierter oder kollabierter Replikationsgabeln Panico, Evandro Rocco 06 June 2006 (has links) No description available. 570 Biowissenschaften, Biologie Mathematics and Computer Science DNA-Helikase Hefe DNA-helicase yeast stalled replication fork collapsed replication fork 42.13 42.20 WF WJ
5	Détection à grande échelle des réarrangements génomiques et élucidation de leurs mécanismes Tremblay-Belzile, Samuel 04 1900 (has links) No description available. Réparation de l’ADN réarrangements génomiques fourches de réplication bloquées bris double-brin séquençage de nouvelle génération chloroplastes mitochondries noyau DNA repair genome rearrangements stalled replication forks double-strand breaks next-generation sequencing chloroplasts mitochondria nucleus
6	Untersuchungen zur Rolle des <i>MPH1</i>-Gens aus <i>Saccharomyces cerevisiae</i> bei der Reinitiation der Replikation nach schadensinduzierten Arresten / Investigations on the function of the <i>Saccharomyces cerevisiae MPH1</i> gene in reinitation of replication after damage induced arrests Rudolph, Christian 05 November 2003 (has links) No description available. 570 Biowissenschaften, Biologie Mathematics and Computer Science arretierte Replikationsgabeln Reinitiation der Replikation DNA-Schäden Camptothecin 4-NQO DNA-Replikation Hefe stalled replication forks reinitiation of replication DNA damage camptothecin 4-NQO DNA replication yeast 42.13 42.20 WJ 000: Genetik {Biologie}

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