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Fapy glycosylase and UvrABC excinuclease protect Escherichia coli from near-ultraviolet radiationShennan, Michael G.C. January 1995 (has links)
In contrast to the damage caused by far-UV, the damaging effects of UVA (320-400 nm) in living cells are not well understood. The damage caused by UVA irradiation is largely oxygen-dependent, suggesting UVA-mediated DNA damage involves reactive oxygen species produced through the action of an endogenous photosensitizer. Previous studies examining cellular responses to UVA irradiation in E. coli have been hindered by the fact that, at sublethal fluences, wild-type cells undergo a transient inhibition of cell growth termed a "growth delay". This effect is absent in nuvA⁻ strains, thereby facilitating the study of DNA repair factors required for the repair of UVA-mediated damage. Formamidopyrimidine (Fapy) glycosylase (encoded by fpg) and the UvrABC excinuclease are both capable of excising oxidatively damaged DNA bases. An fpg::kan mutation was placed into isogenic uvrA⁺ and uvrA⁻ strains of E. coli to evaluate the relative importance of these repair enzymes in the recovery from UVA-induced stress. In a nuvA⁻ background, the survival of fpg⁻ mutants exposed to UVA was significantly reduced relative to isogenic fpg⁺ control strains. This effect was enhanced in the absence of the UvrABC excinuclease, suggesting a role for both of these enzymes in repairing UVA-generated lesions. Survival of isogenic nuvA⁺ repair-deficient strains was significantly lower than nuvA⁻ strains, suggesting a role for the modified base 4-thiouridine in UVA-mediated lethality. An in vitro plasmid DNA irradiation assay in the presence and absence of 4-thiouridine was used to examine this possibility. When irradiated DNA was subsequently used to transform the fpg⁻ and uvrA⁻ mutant strains, no increase in DNA damage (as measured by a decrease in transformational efficiency) in the presence of 4-thiouridine was observed, suggesting that when present in solution this base does not play a photosensitizing role in UVA-mediated lethality. / Thesis / Master of Science (MSc)
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Subcloning, Expression and Purification of Functional E. coli Nucleotide Excision Repair Protein UvrA Using IMPACT-CN SystemLin, Cathy W, Mrs 01 May 2014 (has links)
DNA in cells is constantly damaged by both endogenous and exogenous genotoxic agents. DNA repair is a cellular machinery that counters DNA damage and thus preserve genome integrity. Nucleotide excision repair (NER) in Escherichia coli (E. coli) is one of the DNA repair systems that recognizes and removes a variety of DNA damage such as pyrimidine dimers, bulky chemical adducts, DNA intrastrand cross-links, etc. The genes responsible for E. coli NER incisions are UvrA, UvrB, and UvrC. As the first step of E. coli NER, DNA damage recognition is achieved through the UvrA2B complex. Purification of UvrA, UvrB, and UvrC is essential for research to understand the molecular mechanisms of NER and carcinogenesis. Although UvrA, a 115 kDa protein, has been successfully purified in our lab in the past, the experimental procedures were very time-consuming and technically challenging. In this study we employed IMPACT (Intein Mediated Purification with an Affinity Chitin-binding Tag) system to subclone the cDNA of UvrA and express and purify the recombinant UvrA protein by a single-column step using the cloned expression construct. Furthermore, the purified protein was found to be fully functional in the UvrABC incision assay in which the DNA adduct of FABP [N-(20-deoxyguanosin-8-yl)-4-fluoro-4-aminobiphenyl] was efficiently cleaved in a time course-dependent manner.
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Structural and Biochemical Investigation of the Molecular Mechanisms of DNA Response and Repair in Humans and <em>Escherichia coli</em>.Shell, Steven Michael 03 May 2008 (has links) (PDF)
The genomes of all living cells are under constant attack from both endogenous and exogenous agents that damage DNA. In order to maintain genetic integrity a variety of response pathways have evolved to recognize and eliminate DNA damage. Replication protein A (RPA), the eukaryotic single-stranded DNA (ssDNA) binding protein, is a required factor for all major DNA metabolisms. Although much work has been done to elucidate the nature of the interaction between RPA and ssDNA currently there is no structural information on how the full-length protein binds to ssDNA. This study presents a novel examination of the full nucleoprotein complex formed between RPA and ssDNA. We identified three previously unknown contacts between ssDNA and lysine residues in DNA binding domain C located in the p70 subunit. This represents the first single amino-acid resolution determination of how full-length RPA contacts ssDNA. The Ataxia-Telangiectasia Mutated and RAD3-Related (ATR) mediated DNA damage checkpoint and nucleotide excision repair (NER) pathway are primarily responsible for repair of UV-C-induced photolesions in DNA. However, it is unclear how these two pathways are coordinated. We found the ATR-dependent checkpoint induces a rapid nuclear accumulation of the required NER factor Xeroderma pigmentosum group A (XPA) in both a dose- and time-dependent fashion. Also, using surface topology mapping we have defined an α-helix motif on XPA required for XPA-ATR complex formation necessary for XPA phosphorylation. In addition, we have determined that XPA phosphorylation promotes repair of persistent DNA lesions, such as cyclobutane pyrimidine dimers. The basis for initial damage recognition in NER is structural distortion of duplex DNA; however, the effects of adduct structure and sequence on strand opening and recognition are unclear. Using the E. coli NER system we determined that the identity of the adduct dictates the size of the strand opening generated by the UvrA2B complex. In addition we found that the sequence immediately surrounding the damaged nucleotide affects damage recognition by influencing the amount of helical distortion induced by the adduct. These effects are a result of the equilibrium conformation the adduct adopts in addition to the amount of hydrogen bonding available to maintain the structure.
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Investigation of Novel Functions for DNA Damage Response and Repair Proteins in Escherichia coli and HumansHilton, Benjamin A 01 May 2016 (has links)
Endogenous and exogenous agents that can damage DNA are a constant threat to genome stability in all living cells. In response, cells have evolved an array of mechanisms to repair DNA damage or to eliminate the cells damaged beyond repair. One of these mechanisms is nucleotide excision repair (NER) which is the major repair pathway responsible for removing a wide variety of bulky DNA lesions. Deficiency, or mutation, in one or several of the NER repair proteins is responsible for many diseases, including cancer. Prokaryotic NER involves only three proteins to recognize and incise a damaged site, while eukaryotic NER requires more than 25 proteins to efficiently recognize and incise a damaged site. XPC-RAD23B (XPC) is the damage recognition factor in eukaryotic global genome NER. The association rate of XPC to damaged DNA has been extensively studied; however, our data suggests that the dissociation of the XPC-DNA complex is the rate-limiting step in NER. The factor that verifies DNA-damage downstream of XPC is XPA. XPA also has been implicated in binding of ds-ssDNA junctions and has been found to bind at or near double-strand break sites in the premature aging syndrome Hutchinson-Gilford progeria (HGPS). This role for XPA is outside of its known function in NER and suggests that XPA may bind at collapsed replication forks in HGPS that are unprotected due to a lack of binding by replication proteins. Along with XPC and XPA, ataxia telangiectasia and Rad3-related (ATR) is activated in response to DNA damage and initiates the cell cycle checkpoint pathway to rescue cells from genomic instability. We found that ATR functions outside of its known role in the checkpoint signaling cascade. Our data demonstrate that ATR can rescue cells from apoptosis by inhibiting cytochrome c release at the mitochondria though direct interaction with the outer mitochondrial membrane and the proapoptotic protein tBid. The role of ATR in apoptosis is regulated by Pin1, which can change the structure of ATR at the backbone level. All of the results presented here suggest novel roles for DNA repair proteins in the maintenance of genome stability.
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