Global ETD Search

91	THE ROLE OF RECA PROTEIN IN THE MULTIPLICITY REACTIVATION PATHWAY OF PHAGE T4. McCreary, Ronald Patrick. January 1983 (has links) No description available. DNA repair. Genetic recombination. Bacteriophage T4.
92	Investigating the mechanisms responsible for DNA double-strand break-induced loss of heterozygosity in fission yeast Cullen, Jason Kingsley January 2007 (has links) Loss of heterozygosity (LOH) is considered a causal event in the formation of many cancers, with increasing evidence suggesting that DNA double-strand breaks (DSBs) play a major role in its occurrence. Despite its prominence in cancer, however, the precise molecular mechanisms responsible for extensive LOH and how such events are suppressed in normal cells is poorly understood. To investigate the mechanisms responsible for extensive break-induced LOH in eukaryotes, this study took advantage of an assay system in which such events could be identified through screening for loss of an auxotrophic his3<sup>+</sup> marker, found ~25kb distal to an HO-endonuclease cut site in a non-essential minichromosome in Schizosaccharomyces pombe. Studies using this system had previously shown that extensive break-induced LOH in wild-type background, whilst infrequent, was predominantly associated with large translocations resulting from both allelic crossovers during G2 phase and breakinduced replication (BIR). Such extensive loss of allele specific information was also found to require rhp55<sup>+</sup>, rhp51<sup>+</sup>, rhp54<sup>+</sup> and mus81<sup>+</sup>. This study has identified an additional role for the MRN complex, Rad22 and RPA in such break-induced translocations, suggesting that both allelic crossovers and BIR require homologous recombination (HR) in fission yeast. Surprisingly, break-induced extensive LOH was still observed in HR mutants. In contrast to wild-type cells, however, such extensive LOH was found to arise predominantly through de novo telomere addition at, or near, the break-site. Interestingly, telomere addition was most frequently observed in a rad22Δ background that disrupts HR following end resection. Further analysis demonstrated that de novo telomere addition was also significantly increased in ku70Δ rhp55Δ cells. Moreover, overexpression of rhp51 in rhp55Δ cells led to a substantial reduction in break-induced de novo telomere addition. Together, these findings support a model in which HR prevents de novo telomere addition at DSBs by competing for resected ssDNA ends. In addition to providing information on break-induced LOH this study has identified a requirement for the MRN complex in efficient repair in rhp55Δ cells, which was previously found to occur via sister chromatid recombination (SCR) or a HRdependent end-joining pathway (EJ). Interestingly, deletion of MRN components also resulted in an increase in telomere addition, providing further evidence that HR competes with telomere addition for the repair of DSBs. Overall, these findings shed light on the competitive relationships between pathways of DSB repair/misrepair in S. pombe and how such mechanisms contribute to the prevention or promotion of genome instability. 579.5
93	Investigation of the transcriptional response of Sulfolobus solfataricus to damaging agents Munro, Stacey January 2009 (has links) It is vital for the survival of an organism that it can repair damage to its DNA. Exogenous and endogenous sources of damage are dealt with by a variety of repair pathways that have evolved to repair specific types of damage. Organisms in the archaeal domain, the third domain of life, contain homologues of many of the eukaryotic repair proteins, however little is known about how damage is detected in the archaeal domain. Microarray studies in the archaeal species Sulfolobus solfataricus determined a number of genes whose expression was effected by UV radiation (work by Dr D Götz). The change in expression of nine of these genes was confirmed by RT real time PCR. The expression of these genes was then investigated after exposure to different damaging agents, Mitomycin C, Methyl methane sulfonate, Phleomycin and Hydrogen peroxide. The expression of two genes, transcription factor tfb-3 and cell division control gene cdc6-2, was up regulated in all damage conditions. There was a huge induction of the dps-like gene (sso2079) after hydrogen peroxide damage. Transcription from this genes promoter was shown to be strong in vitro (work by Dr S Paytubi) suggesting a repressor was controlling the gene in vivo. A palindromic repeat in the promoter of the dps-like gene was used to ‘fish’ for a transcriptional repressor and the Sso2273 protein, a homologue of the diphtheria toxin repressor (DtxR) from Corynebacterium diphtheria, was identified as a possible repressor. Sso2273 was expressed and purified, and its crystal structure solved, its paralogue, Sso0669, was also expressed and purified. Electrophoretic mobility shift assays showed that the Sso2273 protein does not bind DNA, and had no effect on transcription from any promoter used in in vitro transcription assays. However Sso0669 appeared to inhibit transcription, although the inhibition was not sequence specific. A knockout strain of S. solfataricus PBL2025 missing the sso2273 gene was produced and used in microarray experiments in an attempt to determine the role of Sso2273 within the cell. The absence of Sso2273 appeared to have no effect on the expression of the dps-like gene, however strong repression of an operon containing genes involved in Sulphur assimilation was observed. 571.29 QH467.M8 ; DNA repair ; Archaebacteria
94	Investigations into the feasibility of single-strandedoligonucleotide-mediated targeted gene repair in mammalian cells Lu, Linyu., 陸林宇. January 2006 (has links) published_or_final_version / abstract / Biochemistry / Doctoral / Doctor of Philosophy Gene targeting DNA repair. Mice - Cytogenetics.
95	REV7-mediated polyubiquitination and degration of human REV1 Chun, Chiu-shun., 秦超舜. January 2009 (has links) published_or_final_version / Biochemistry / Doctoral / Doctor of Philosophy Ubiquitin. DNA polymerases. DNA damage. Dna repair.
96	Molecular mechanism of enhanced UV-mutagenesis in the TK-deficient mutant subclone of friend mouse erythroleukaemia cells Abu-Baker, Aida January 2000 (has links) No description available. 572.8 DNA repair; Cloning; dNTP pool imbalance
97	DNA mismatches : their structure and recognition by MutS Brown, James January 2000 (has links) No description available. 572.8 DNA repair; Mismatch; MutHLS pathway
98	Further characterisation of the rad18 gene of Schizosaccharomyces pombe Munday, Caroline Anne January 1998 (has links) No description available. 572.8 DNA repair; SMC proteins; Yeast
99	Defective mismatch repair and cisplatin resistance in ovarian cancer cells Anthoney, David Alan January 1997 (has links) No description available. 572.8
100	Molecular pathology of the hMSH2 mutator gene and its transcripts in patients with colorectal cancer in the west of Scotland Davoodi-Semiromi, Abdoreza January 1997 (has links) No description available. 572.8

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