Global ETD Search

11	Saccharomyces Cerevisiae as a Model Organism to Delineate Initial Lesion Detection Events in Chromatin Repair: A Focus On Ddb2-Mediated GG-NER Jones, Kristi L 07 June 2011 (has links) DNA damage repair is an essential and complex cellular process. Although the basic mechanisms of nucleotide excision repair (NER) have been studied for decades, some mechanistic details remain elusive. The lesion detection step remains one of the most elusive in the process of NER in the contest of chromatin. The work described herein addresses the initial events in the lesion detection step of chromatin repair, also referred to as global genome repair (GG-NER). Both the role of post-translational modifications of lesion identification proteins, and the initial sequence of events in recruitment of repair and remodeling factors are investigated. First, the controversial role of ubiquitination of DDB2 (a human lesion detection protein) is investigated. Due to documented DDB2 function in alternative physiological processes, its direct role in GG-NER is hard to study in human cells. To overcome this obstacle, we established the budding yeast, Saccharomyces cerevisiae as an alternative, simplified model organism to study DDB2-mediated GG-NER. Using this system, we show that inconsistent with the widely accepted model, rapid degradation of DDB2 post-UV irradiation is not an absolute requirement for progression of GG-NER. However, interestingly, our data suggest a role for ubiquitination in the release of DDB2 from chromatin. In both UV and mock treated samples, ubiquitin deficient cells had significantly higher amounts of DDB2 remaining bound to the chromatin compared to the isogenic parent cells. The discussion focuses on the possible physiological relevance of these observations. Additionally, the recruitment of the SWI/SNF chromatin remodeling complex to the silent HML (Hidden MAT Left) locus was also investigated. SWI/SNF is known to require recruitment for its role in transcription; therefore we investigate this requirement in GG-NER. Based on previously published data that indicate an UV-stimulated association of SWI/SNF and Rad4 (a lesion detection protein), we hypothesized that Rad4 is involved in recruitment of SWI/SNF to damaged DNA. Interestingly, our data suggest that Rad4 is not an absolute requirement for recruitment of Snf6 to the HML locus following UV irradiation. However, Rad16 appears to be. These data present an interesting insight into the lesion detection step in GG-NER and this will be discussed. chromatin DNA damage repair Nucleotide excision repair (NER) DDB2 ubiquitination Saccharomyces cerevisiae
12	Structural and Functional Studies of DNA Nucleases: SgrAI and Mk0566 Shah, Santosh January 2013 (has links) DNA nucleases are essential for various biological functions such as replication, recombination, and repair. Restriction endonucleases (REs) are excellent model system for the investigation of DNA recognition and specificity. SgrAI is a type IIF RE that cuts an 8 base pair primary sequence. In addition to its primary cleavage activity it also cleaves secondary sequences, but only appreciably in the presence of the primary sequence. The longer flanking DNA exhibits much greater activated DNA cleavage by SgrAI (>1000 fold activation by secondary site). Interestingly, the asymmetric cleavage seen in one of the two types of secondary site DNA is lost upon activation of SgrAI, suggesting a loss of communication between DNA recognition and activity upon specificity expansion. The structure of SgrAI bound to 22-1HT supports the cryoelectron microscopy structure of activated, oligomeric SgrAI highlighting the significance of the contacts made by the flanking DNA and the role played by N-terminal domain contacts in forming the run-on oligomer. The biological study suggests that the run-on oligomer formation sequesters the host DNA from being cleaved by the activated SgrAI complex. The DNA sequence binding, cleavage preference, and the structure of K96A SgrAI were determined. Unexpectedly, this mutation did not alter the structure of the enzyme, nor did it result in an enzyme lacking sequence preference at the 7ᵗʰ position. Instead, the largest effect of the mutation appears to be in making the enzyme more specific such that it fails to cleave either type of secondary site. It may be that the K96 side chain is required to distort the non YG sequences (specifically GG and TC) of secondary site DNA for proper positioning in the enzyme active site upon activation and specificity expansion. The crystal structure of Mk0566, XPG homologue from M. kandleri, was solved to 2.48 Å resolution and was found to be very similar to that of human FEN-1 and to other archaeal FEN-1/XPG homologues. These results suggest that the main biological role of Mk0566 is in DNA replication; however, they do not preclude involvement in a modified form of nucleotide excision repair. Allostery Indirect readout mechanism Nucleotide excision repair Restriction endonuclease Run-on oligomerization Biochemistry Activation
13	Characterization of the multifunctional XPG protein during Nucleotide-excision-repair Schubert, Steffen 15 May 2014 (has links) No description available.
14	Papel biológico dos dímeros de pirimidina em células humanas irradiadas com radiação UVA / Biological role of pyrimidine dimers in human cells irradiated with UVA radiation Barbara Helen Cortat Santos 06 October 2010 (has links) A radiação ultravioleta (UV) pode ser absorvida por diferentes moléculas celulares, incluindo o DNA no qual provoca distorções estruturais. As lesões mais comuns induzidas pela radiação UV são o ciclobutano de pirimidina (CPD) e o fotoproduto (6-4)-pirimidina-pirimidona [(6-4)PPs]. Estas lesões podem ser reparadas pela fotorreativação, caracterizada por ter uma única proteína (fotoliase) que remove lesões empregando luz visível (320-500 nm) como fonte de energia. Foram identificados dois tipos de fotoliases que diferem por sua especificidade ao substrato: CPD-fotoliase e (6-4)-fotoliase. Um outro mecanismo de reparo é o reparo por excisão de nucleotídeos (NER), um mecanismo que envolve múltiplos passos e proteínas. Enquanto os efeitos genotóxicos da UVC e UVB já estão relativamente esclarecidos e bem aceitos, ainda existem controvérsias sobre a genotoxicidade da radiação UVA, devido ao fato de ser fracamente absorvida pelo DNA. Alguns autores acreditam que os seus principais efeitos são gerados de forma indireta pela produção de espécies reativas de oxigênio enquanto outros acreditam que a UVA pode gerar danos ao DNA de forma direta, provocando a formação de dímeros de pirimidina. O objetivo deste trabalho foi verificar os efeitos genotóxicos da radiação UVA em fibroblastos humanos deficientes e proficientes em NER utilizando adenovírus recombinantes contendo uma ou outra fotoliase para verificar se as lesões CPD e (6-4)PP são geradas pela UVA e se elas teriam alguma importância nas respostas verificadas após irradiação. Foi verificado que as células deficientes no gene XPA são mais sensíveis à radiação UVA quando comparadas às células selvagens. Por meio da detecção imunológica, confirmamos a geração das lesões CPD, (6-4)PP e Dewar, fotoisômero da lesão (6-4)PP, após irradiação com UVA no genoma de células humanas. Empregando vetores adenovirais para transdução de fotoliase específica para lesões tipo CPD ou (6-4)PP, confirmamos que de fato essas lesões são formadas em células humanas deficientes em reparo de DNA após irradiação com UVA. Além disso, esses vírus permitiram verificar a relevância biológica dessas lesões na indução de morte celular em células XP-A irradiadas. De fato, os dados indicam que para doses baixas de radiação UVA essas lesões desempenham um importante papel na indução de morte. Não podemos descartar, porém, que lesões indiretas (provavelmente geradas por estresse oxidativo) também tenham papel na indução de morte pela radiação UVA, o que parece ser mais importante a doses médias e altas dessa radiação. / Ultraviolet radiation (UV) is absorbed by different cellular molecules, including DNA in which induces structural distortions. The most common lesions induced by UV radiation are the cyclobutane pyrimidine (CPD) and the photoproduct (6-4)-pyrimidine-pyrimidone [(6-4)PP]. These lesions can be repaired by the photoreactivation, characterized by a single protein (photolyase) that removes lesions using visible light (320-500 nm) as energy source. Two types of photolyases had been identified that differ by their substrate specificity: CPD-photolyase and (6-4)-photolyase. Another repair mechanism is the nucleotide excision repair (NER), a mechanism that involves multiple steps and proteins. While the genotoxic effects of UVB and UVC are already relatively well-understood and accepted, there is still controversy about the genotoxicity of UVA radiation, due to its low absorption by DNA. Some authors believe that the major effects are generated indirectly by the production of reactive oxygen species, while others believe that UVA can cause damage to DNA directly, inducing the formation of pyrimidine dimers. The aim of this study was to assess the genotoxic effects of UVA radiation in human fibroblasts deficient and proficient in NER, using recombinant adenovirus expressing the photolyases to verify if CPDs and (6-4)PPs are generated by UVA and whether they had any importance in the responses observed after irradiation. It was found that cells deficient in the XPA gene are more sensitive to UV radiation compared to wild type cells. By immunological detection, we confirm the generation of CPD, (6-4)PP and Dewar, photoisomer of the (6-4)PP lesion, in the genome of human cells after irradiation with UVA. Using adenoviral vectors for the transduction of photolyases specific for CPD or (6-4)PP lesions, we confirm that in fact these lesions are generated in human cells deficient in DNA repair after irradiation with UVA. Moreover, these viruses allowed us to verify the biological relevance of these lesions in the induction of cell death in irradiated XP-A cells. In fact, our data indicates that for low doses of UVA radiation, these lesions play important roles in the induction of death. We cannot rule out, however, that indirect lesions (probably caused by oxidative stress) could also have a role in the induction of death by UVA radiation, which seems to be more important in intermediate and high doses of this radiation. Dimeros de pirimidina Reparo por excisão de nucleotídeos UVA Nucleotide excision repair Pyrimidine dimers UVA
15	The role of DNA polymerases, in particular DNA polymerase ε in DNA repair and replication Pospiech, H. (Helmut) 19 April 2002 (has links) Abstract Analysis of the primary structure of DNA polymerase ε B subunit defined similarities to B subunits of eukaryotic DNA polymerases α, δ and ε as well as the small subunits of DNA polymerase DI of Euryarchaeota. Multiple sequence alignment of these proteins revealed the presence of 12 conserved motifs and defined a novel protein superfamily. The members of the B subunit family share a common domain architecture, suggesting a similar fold, and arguing for a conserved function among these proteins. The contribution of human DNA polymerase ε to nuclear DNA replication was studied using the antibody K18 that specifically inhibits the activity of this enzyme in vitro. This antibody significantly inhibited DNA synthesis both when microinjected into nuclei of exponentially growing human fibroblasts and in isolated HeLa cell nuclei, but did not inhibit SV40 DNA replication in vitro. These results suggest that the human DNA polymerase ε contributes substantially to the replicative synthesis of DNA and emphasises the differences between cellular replication and viral model systems. The human DNA polymerases ε and δ were found capable of gap-filling DNA synthesis during nucleotide excision repair in vitro. Both enzymes required PCNA and the clamp loader RFC, and in addition, polymerase δ required Fen-1 to prevent excessive displacement synthesis. Nucleotide excision repair of a defined DNA lesion was completely reconstituted utilising largely recombinant proteins, only ligase I and DNA polymerases δ and ε provided as highly purified human enzymes. This system was also utilised to study the role of the transcription factor II H during repair. Human non-homologous end joining of model substrates with different DNA end configurations was studied in HeLa cell extracts. This process depended partially on DNA synthesis as an aphidicolin-dependent DNA polymerase was required for the formation of a subset of end joining products. Experiments with neutralising antibodies reveal that DNA polymerase α but not DNA polymerases β or ε, may represent this DNA polymerase activity. Our results indicate that DNA synthesis contributes to the stability of DNA ends, and influences both the efficiency and outcome of the end joining event. Furthermore, our results suggest a minor role of PCNA in non-homologous end joining. DNA polymerase DNA repair DNA replication antibody non-homologous end joining nucleotide excision repair protein family
16	Replication-Mediated Disassociation of Replication Protein A-XPA Complex Upon Dna Damage: Implications for RPA Handing Off Jiang, Gaofeng, Zou, Yue, Wu, Xiaoming 01 August 2012 (has links) RPA (replication protein A), the eukaryotic ssDNA (single-stranded DNA)-binding protein, participates in most cellular processes in response to genotoxic insults, such as NER (nucleotide excision repair), DNA, DSB (double-strand break) repair and activation of cell cycle checkpoint signalling. RPA interacts with XPA (xeroderma pigmentosum A) and functions in early stage of NER. We have shown that in cells the RPA-XPA complex disassociated upon exposure of cells to high dose of UV irradiation. The dissociation required replication stress and was partially attributed to tRPA hyperphosphorylation. Treatment of cells with CPT (camptothecin) and HU (hydroxyurea), which cause DSB DNA damage and replication fork collapse respectively and also leads to the disruption of RPA-XPA complex. Purified RPA and XPA were unable to form complex in vitro in the presence of ssDNA. We propose that the competition-based RPA switch among different DNA metabolic pathways regulates the dissociation of RPA with XPA in cells after DNA damage. The biological significances of RPA-XPA complex disruption in relation with checkpoint activation, DSB repair and RPA hyperphosphorylation are discussed. DNA damage DNA repair nucleotide excision repair RPA XPA Biomedical Sciences
17	Differential DNA Damage Responses in p53 Proficient and Deficient Cells: Cisplatin-Induced Nuclear Import of XPA Is Independent of ATR Checkpoint in p53-Deficient Lung Cancer Cells Li, Zhengke, Musich, Phillip R., Zou, Yue 10 June 2011 (has links) Nucleotide excision repair (NER) and ataxia telangiectasia mutated (ATM)/ATR (ATM- and RAD3-related) NA damage checkpoints are among the major pathways that affect the chemotherapeutic efficiency of the anticancer rug cisplatin. Xeroderma pigmentosum group A (XPA) protein plays a crucial role in NER including both global enome repair (GG-NER) and transcription-coupled repair (TC-NER) subpathways, and has been a potential target for mproving cisplatin therapeutic effects. We report here that XPA translocates from the cytosol into the nucleus after NA damage induced by UV irradiation and cisplatin, a mimetic of UV damage, in human cells with or without p53 deficiency. However, the damage-induced response of XPA nuclear import was significantly slower in p53-deficient cells than in p53-proficient cells. We also found that while XPA is imported into the nucleus upon cisplatin or UV damage in an ATR-dependent manner in p53-proficient A549 lung cancer cells, the ATR checkpoint pathway has no effect on the XPA nuclear import in p53-deficient H1299 lung cancer cells. Similarly, the XPA nuclear translocation is not regulated by ATM checkpoint or by p38MAPK/MK2 either. Our findings suggest that NER is independent on the major DNA damage checkpoint pathways in H1299 (p53-/-) cells and that DNA damage responses are mechanistically different between p53-proficient and p53-deficient cells. Our results also highlight the possibility of selectively targeting XPA nuclear import as a way to sensitize cisplatin anticancer activity, but targeting ATR/ATM-dependent checkpoints may not be helpful in killing p53-deficient cancer cells. ataxia telangiectasia DNA damage checkpoints nucleotide excision repair (NER) p53 Xeroderma pigmentosum group A
18	A New Structural Insight Into XPA-DNA Interactions Hilton, Benjamin, Shkriabai, Nick, Musich, Phillip R., Kvaratskhelia, Mamuka, Shell, Steven, Zou, Yue 01 January 2014 (has links) XPA (xeroderma pigmentosum group A) protein is an essential factor for NER (nucleotide excision repair) which is believed to be involved in DNA damage recognition/verification, NER factor recruiting and stabilization of repair intermediates. Past studies on the structure of XPA have focused primarily on XPA interaction with damaged DNA. However, how XPA interacts with other DNA structures remains unknown though recent evidence suggest that these structures could be important for its roles in both NER and non-NER activities. Previously, we reported that XPA recognizes undamaged DNA ds/ssDNA (double-strand/single-strandDNA) junctions with a binding affinity much higher than its ability to bind bulky DNA damage. To understand how this interaction occurs biochemically we implemented a structural determination of the interaction using a MS-based protein footprinting method and limited proteolysis. By monitoring surface accessibility of XPA lysines to NHS-biotin modification in the free protein and the DNA junction-bound complex we show that XPA physically interacts with the DNA junctions via two lysines, K168 and K179, located in the previously known XPA(98-219) DBD (DNA-binding domain). Importantly, we also uncovered new lysine residues, outside of the known DBD, involved in the binding. We found that residues K221, K222, K224 and K236 in the C-terminal domain are involved in DNA binding. Limited proteolysis analysis of XPA-DNA interactions further confirmed this observation. Structural modelling with these data suggests a clamp-like DBD for the XPA binding to ds/ssDNA junctions. Our results provide a novel structure-function view of XPA-DNA junction interactions. DNA junction DNA-binding domain nucleotide excision repair XPA XPA-DNA binding Biomedical Sciences
19	New Insights into the Roles of Human DNA Damage Checkpoint Protein ATR in the Regulation of Nucleotide Excision Repair and DNA Damage-Induced Cell Death Li, Zhengke 01 December 2013 (has links) (PDF) Integrity of the human genome is frequently threatened by endogenous and exogenous DNA damaging reagents that may lead to genome instability and cancer. Cells have evolved multiple mechanisms to repair DNA damage or to eliminate the damaged cells beyond repair and to prevent diverse diseases. Among these are ataxia telangiectasia and Rad3-related (ATR)-mediated DNA damage checkpoint and nucleotide excision repair (NER) that are the major pathways by which cells handle ultraviolet C (UV-C)- or other exogenous genotoxin-induced bulky DNA damage. However, it is unclear how these 2 pathways may be coordinated. In this study we show that ATR physically interacts with NER factor xeroderma pigmentosum group A (XPA) where an ATR phosphorylation site on serine 196 is located. Phosphorylation of XPA on serine 196 is required for repair of UV-induced DNA damage. In addition, a K188A point mutation of XPA that disrupts the ATR-XPA interaction inhibits the UV-induced XPA phosphorylation and DNA repair. Moreover, we show that depletion of p53, a downstream checkpoint of ATR, and inhibition of p53 transcriptional activities reduced the UV-induced XPA import. Furthermore, we found that the ATR-directed XPA nuclear import happens primarily in the S phase of the cell cycle. In effort to determine the mechanism involved in the XPA nuclear import, we found that, in addition to the nuclear localization signal (NLS) of XPA, importin-α4 is required for the UV-induced XPA nuclear import in an ATR-dependent manner. These data suggest that NER could be regulated by the ATR-dependent checkpoint via modulation of XPA phosphorylation and nuclear import. In a separate study we show that, upon UV damage, cytoplasmic ATR translocates to mitochondria, blocks the recruitment of proapoptotic Bcl-2–associated X (Bax) protein to mitochondria and prevents the loss of mitochondrial membrane potential (ΔΨ) and apoptosis. Bax-depletion reduces the effect of ATR on ΔΨ. Remarkably, the cytoplasmic ATR exhibits no checkpoint kinase activity, a hallmark function of nuclear ATR. Silencing of ATR’s kinase activity failed to affect Bax relocalization to mitochondria. These results reveal a novel checkpoint-independent antiapoptotic function of ATR at mitochondria in the cellular response to DNA damage. ATR Nucleotide Excision Repair XPA S Phase p53 Importins Bax Cancer Biology Cell Biology Molecular Biology
20	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. Nucleotide excision repair ATR checkpoint RPA UvrABC XPA Life Sciences Molecular Biology

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