人XPB基因在核苷酸剪切修复和基因转录中的分子机制

核苷酸剪切修复(NER)途径是维持生物体基因组稳定的重要机制。人着色性干皮病B组(xeroderma pigmentosum group B,XPB)基因又名ERCC3基因,它既是NER途径不可缺少的成员又是转录因子TFIIH的最大p89亚基。它是具有从3’端→5’端依赖ATP的单链DNA解旋酶活性的蛋白质,执行依赖DNA的ATP酶和解旋酶功能,在损伤DNA修复和基因转录中均起重要作用,并将两者有机偶联。该基因突变将导致3种不同的遗传疾病：着色性干皮病(xeroderma pigmentosum,XP),科凯恩氏综合征(cockayne’s syndrome,CS),毛发硫营养不艮(trichothiodystrophy,TTD)。其基因型通过在DNA修复和转录中的功能与表型联系起来。另外,XPB与p53存在物理和功能上的相互作用。现从XPB的3个方面即“一个基因,两种功能,3种疾病”作一综述。     

Analysis of Ribonucleotide Removal from DNA by Human Nucleotide Excision Repair

Ribonucleotides are incorporated into the genome during DNA replication. The enzyme RNase H2 plays a critical role in targeting the removal of these ribonucleotides from DNA, and defects in RNase H2 activity are associated with both genomic instability and the human autoimmune/inflammatory disorder Aicardi-Goutières syndrome. Whether additional general DNA repair mechanisms contribute to ribonucleotide removal from DNA in human cells is not known. Because of its ability to act on a wide variety of substrates, we examined a potential role for canonical nucleotide excision repair in the removal of ribonucleotides from DNA. However, using highly sensitive dual incision/excision assays, we find that ribonucleotides are not efficiently targeted by the human nucleotide excision repair system in vitro or in cultured human cells. These results suggest that nucleotide excision repair is unlikely to play a major role in the cellular response to ribonucleotide incorporation in genomic DNA in human cells.     

Nucleotide excision repair in higher eukaryotes: Mechanism of primary damage recognition

Nucleotide excision repair (NER) is one of the major DNA repair pathways in eukaryotic cells. NER removes structurally diverse lesions such as pyrimidine dimers, arising upon UV irradiation, and bulky chemical adducts, arising upon exposure to carcinogens and some chemotherapeutic drugs. NER defects lead to severe diseases, including some forms of cancer. In view of the broad substrate specificity of NER, it is of interest to study how a certain set of proteins recognizes DNA lesions in contest of a large excess of intact DNA. The review focuses on DNA damage recognition, the key and, as yet, most questionable step of NER. The main models of primary damage recognition and preincision complex assembly are considered. The model of a sequential loading of repair proteins on damaged DNA seems most reasonable in light of the available data.     

DNA ADP-Ribosylation Stalls Replication and Is Reversed by RecF-Mediated Homologous Recombination and Nucleotide Excision Repair

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Oxidatively Generated Guanine(C8)-Thymine(N3) Intrastrand Cross-links in Double-stranded DNA Are Repaired by Base Excision Repair Pathways

Oxidatively generated guanine radical cations in DNA can undergo various nucleophilic reactions including the formation of C8-guanine cross-links with adjacent or nearby N3-thymines in DNA in the presence of O₂. The G*[C8-N3]T* lesions have been identified in the DNA of human cells exposed to oxidative stress, and are most likely genotoxic if not removed by cellular defense mechanisms. It has been shown that the G*[C8-N3]T* lesions are substrates of nucleotide excision repair in human cell extracts. Cleavage at the sites of the lesions was also observed but not further investigated (Ding et al. (2012) Nucleic Acids Res. 40, 2506–2517). Using a panel of eukaryotic and prokaryotic bifunctional DNA glycosylases/lyases (NEIL1, Nei, Fpg, Nth, and NTH1) and apurinic/apyrimidinic (AP) endonucleases (Apn1, APE1, and Nfo), the analysis of cleavage fragments by PAGE and MALDI-TOF/MS show that the G*[C8-N3]T* lesions in 17-mer duplexes are incised on either side of G*, that none of the recovered cleavage fragments contain G*, and that T* is converted to a normal T in the 3′-fragment cleavage products. The abilities of the DNA glycosylases to incise the DNA strand adjacent to G*, while this base is initially cross-linked with T*, is a surprising observation and an indication of the versatility of these base excision repair proteins.     

An Integrated Approach for Analysis of the DNA Damage Response in Mammalian Cells: NUCLEOTIDE EXCISION REPAIR,DNA DAMAGE CHECKPOINT,AND APOPTOSIS*

DNA damage by UV and UV-mimetic agents elicits a set of inter-related responses in mammalian cells, including DNA repair, DNA damage checkpoints, and apoptosis. Conventionally, these responses are analyzed separately using different methodologies. Here we describe a unified approach that is capable of quantifying all three responses in parallel using lysates from the same population of cells. We show that a highly sensitive in vivo excision repair assay is capable of detecting nucleotide excision repair of a wide spectrum of DNA lesions (UV damage, chemical carcinogens, and chemotherapeutic drugs) within minutes of damage induction. This method therefore allows for a real-time measure of nucleotide excision repair activity that can be monitored in conjunction with other components of the DNA damage response, including DNA damage checkpoint and apoptotic signaling. This approach therefore provides a convenient and reliable platform for simultaneously examining multiple aspects of the DNA damage response in a single population of cells that can be applied for a diverse array of carcinogenic and chemotherapeutic agents.     

The oxidative DNA lesions 8,5'-cyclopurines accumulate with aging in a tissue-specific manner

Accumulation of DNA damage is implicated in aging. This is supported by the fact that inherited defects in DNA repair can cause accelerated aging of tissues. However, clear-cut evidence for DNA damage accumulation in old age is lacking. Numerous studies report measurement of DNA damage in nuclear and mitochondrial DNA from tissues of young and old organisms, with variable outcomes. Variability results from genetic differences between specimens or the instability of some DNA lesions. To control these variables and test the hypothesis that elderly organisms have more oxidative DNA damage than young organisms, we measured 8,5'-cyclopurine-2'-deoxynucleosides (cPu), which are relatively stable, in tissues of young and old wild-type and congenic progeroid mice. We found that cPu accumulate spontaneously in the nuclear DNA of wild-type mice with age and to a greater extent in DNA repair-deficient progeroid mice, with a similar tissue-specific pattern (liver > kidney > brain). These data, generated under conditions where genetic and environmental variables are controlled, provide strong evidence that DNA repair mechanisms are inadequate to clear endogenous lesions over the lifespan of mammals. The similar, although exaggerated, results obtained from progeroid, DNA repair-deficient mice and old normal mice support the conclusion that DNA damage accumulates with, and likely contributes to, aging.     

Two‐polymerase mechanisms dictate error‐free and error‐prone translesion DNA synthesis in mammals

DNA replication across blocking lesions occurs by translesion DNA synthesis (TLS), involving a multitude of mutagenic DNA polymerases that operate to protect the mammalian genome. Using a quantitative TLS assay, we identified three main classes of TLS in human cells: two rapid and error‐free, and the third slow and error‐prone. A single gene, REV3L, encoding the catalytic subunit of DNA polymerase ζ (polζ), was found to have a pivotal role in TLS, being involved in TLS across all lesions examined, except for a TT cyclobutane dimer. Genetic epistasis siRNA analysis indicated that discrete two‐polymerase combinations with polζ dictate error‐prone or error‐free TLS across the same lesion. These results highlight the central role of polζ in both error‐prone and error‐free TLS in mammalian cells, and show that bypass of a single lesion may involve at least three different DNA polymerases, operating in different two‐polymerase combinations.     

Base Excision Repair and its Role in Maintaining Genome Stability

For all living organisms, genome stability is important, but is also under constant threat because various environmental and endogenous damaging agents can modify the structural properties of DNA bases. As a defense, organisms have developed different DNA repair pathways. Base excision repair (BER) is the predominant pathway for coping with a broad range of small lesions resulting from oxidation, alkylation, and deamination, which modify individual bases without large effect on the double helix structure. As, in mammalian cells, this damage is estimated to account daily for 10⁴ events per cell, the need for BER pathways is unquestionable. The damage-specific removal is carried out by a considerable group of enzymes, designated as DNA glycosylases. Each DNA glycosylase has its unique specificity and many of them are ubiquitous in microorganisms, mammals, and plants. Here, we review the importance of the BER pathway and we focus on the different roles of DNA glycosylases in various organisms.     

Mutations in Replicative Stress Response Pathways Are Associated with S Phase-specific Defects in Nucleotide Excision Repair

Nucleotide excision repair (NER) is a highly conserved pathway that removes helix-distorting DNA lesions induced by a plethora of mutagens, including UV light. Our laboratory previously demonstrated that human cells deficient in either ATM and Rad3-related (ATR) kinase or translesion DNA polymerase η (i.e. key proteins that promote the completion of DNA replication in response to UV-induced replicative stress) are characterized by profound inhibition of NER exclusively during S phase. Toward elucidating the mechanistic basis of this phenomenon, we developed a novel assay to quantify NER kinetics as a function of cell cycle in the model organism Saccharomyces cerevisiae. Using this assay, we demonstrate that in yeast, deficiency of the ATR homologue Mec1 or of any among several other proteins involved in the cellular response to replicative stress significantly abrogates NER uniquely during S phase. Moreover, initiation of DNA replication is required for manifestation of this defect, and S phase NER proficiency is correlated with the capacity of individual mutants to respond to replicative stress. Importantly, we demonstrate that partial depletion of Rfa1 recapitulates defective S phase-specific NER in wild type yeast; moreover, ectopic RPA1–3 overexpression rescues such deficiency in either ATR- or polymerase η-deficient human cells. Our results strongly suggest that reduction of NER capacity during periods of enhanced replicative stress, ostensibly caused by inordinate sequestration of RPA at stalled DNA replication forks, represents a conserved feature of the multifaceted eukaryotic DNA damage response.     

DNA损伤修复机制——解读2015年诺贝尔化学奖

Tomas Lindahl, Paul Modrich和Aziz Sancar三位科学家因发现“DNA损伤修复机制”获得了2015年诺贝尔化学奖．Lindahl首次发现Escherichia Coli中参与碱基切除修复的第一个蛋白质--尿嘧啶 DNA糖基化酶（UNG）; Modrich重建了错配修复的体外系统,从大肠杆菌到哺乳动物深入探究了错配修复的机制; Sancar利用纯化的UvrA、UvrB、UvrC重建了核苷酸切除修复的关键步骤,阐述了核苷酸切除修复的分子机制．DNA损伤是由生物所处体外环境和体内因素共同导致的,面对不同种类的损伤,机体启动多种不同的修复机制修复损伤,保护基因组稳定性．这些修复机制包括：光修复(light repairing);核苷酸切除修复（nucleotide excision repair, NER）;碱基切除修复（base excision repair, BER）;错配修复（mismatch repair, MMR）;以及DNA双链断裂修复（DNA double strand breaks repair, DSBR）．其中DNA双链断裂修复又分同源重组（homologous recombination, HR）和非同源末端连接（non homologous end joining, NHEJ）两种方式．本文将对上述几种修复的机制进行总结与讨论．     

How does a cell repair damaged DNA?

DNA in living cells is constantly subjected to different chemical and physical factors of the environment and to cell metabolites. Some changes altering DNA structure occur spontaneously. This raises the potential danger of harmful mutations that could be transmitted to offspring. To avoid the danger of mutations and changing genetic information, a cell is capable to switch on multiple mechanisms of DNA repair that remove damage and restore native structure. In many cases, removal of the same damage may involve several alternative pathways; this is very important for DNA repair under the most unfavorable conditions. This review summarizes data about all known mechanisms of eukaryotic DNA repair including excision repair (base excision repair and nucleotide excision repair), mismatch repair, repair of double-strand breaks, and cross-link repair. Special attention is given to the regulation of excision repair by different proteins—proliferating cell nuclear antigen (PCNA), p53, and proteasome. The review also highlights problem of bypassing irremovable lesions in DNA.Translated from Biokhimiya, Vol. 70, No. 3, 2005, pp. 341–359.Original Russian Text Copyright © 2005 by Sharova.     

Focus: 50 Years of DNA Repair: The Yale Symposium Reports: Early Days of DNA Repair: Discovery of Nucleotide Excision Repair and Homology-Dependent Recombinational Repair

The discovery of nucleotide excision repair in 1964 showed that DNA could berepaired by a mechanism that removed the damaged section of a strand andreplaced it accurately by using the remaining intact strand as the template.This result showed that DNA could be actively metabolized in a process that hadno precedent. In 1968, experiments describing postreplication repair, a processdependent on homologous recombination, were reported. The authors of thesepapers were either at Yale University or had prior Yale connections. Here werecount some of the events leading to these discoveries and consider the impacton further research at Yale and elsewhere.     

UV-Induced Apoptosis in Resistant HeLa Cells

Recently, apoptosis (genetically programmed cell death) induced by UV hasbeen documented in some cell culture models. However, the significance ofapoptosis in UV-induced cytotoxicity and resistance is uncertain. In thisstudy, we investigated the induction of apoptosis in HeLa cells and itsrole in acquired UV-resistance. The membrane receptor Fas was induced toassembly, and its immediate downstream target, caspase-8, was induced byUV in a dose- and time-dependent manner. Caspase-10, another possiblecandidate for forming the death-inducing signaling complex with Fas, wasalso activated in a dose- and time-dependent manner. There was significantactivation of caspase 9, 3 and 2 by UV. The apoptotic pathways appeared tobe normal in acquired UV-resistant HeLa cells. In addition, there was a UVdose-dependent induction of chromatin condensation in both parental andUV-resistant cells. However, resistant cells displayed significant reductionin chromatin condensation at lower doses. Inhibition of caspase-3 activation byspecific inhibitor significantly reduced the chromatin condensation in bothcell types, and unexpectedly, the difference between the two cell lines wascompletely eradicated, suggesting that the caspase-3 pathway plays asignificant role in reducing apoptosis in resistant cells. The resultsindicate that UV induces apoptosis by direct activation of apoptoticproteins in HeLa and resistant cells. Although resistant cells displayedpartial inhibition of UV-induced apoptosis through the caspase-3 pathway,there was no consistent difference in the activation of this and relatedcaspase-9 caspases compared to parental HeLa cells.     

天然产物产生菌自抗性中DNA损伤修复的研究进展

临床上使用的抗生素大多是由微生物次级代谢产生的天然产物及其衍生物,这类化合物可以抑制微生物的生长,具有显著的细胞毒性.产生菌在合成这些抗生素的同时,也需要通过多种自抗性机制来应对其对自身的毒害作用.本文总结了近年来DNA损伤修复途径参与的天然产物产生菌自抗性机制的研究进展,重点介绍了 DNA损伤类抗生素产生菌中的碱基切...     

Replication-mediated disassociation of replication protein A-XPA complex upon DNA damage: implications for RPA handing off

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.