Replication of a cis-syn thymine dimer at atomic resolution

Ultraviolet light damages DNA by catalysing covalent bond formation between adjacent pyrimidines, generating cis-syn cyclobutane pyrimidine dimers (CPDs) as the most common lesion. CPDs block DNA replication by high-fidelity DNA polymerases, but they can be efficiently bypassed by the Y-family DNA polymerase pol eta. Mutations in POLH encoding pol eta are implicated in nearly 20% of xeroderma pigmentosum, a human disease characterized by extreme sensitivity to sunlight and predisposition to skin cancer. Here we have determined two crystal structures of Dpo4, an archaeal pol eta homologue, complexed with CPD-containing DNA, where the 3' and 5' thymine of the CPD separately serves as a templating base. The 3' thymine of the CPD forms a Watson-Crick base pair with the incoming dideoxyATP, but the 5' thymine forms a Hoogsteen base pair with the dideoxyATP in syn conformation. Dpo4 retains a similar tertiary structure, but each unusual DNA structure is individually fitted into the active site for catalysis. A model of the pol eta-CPD complex built from the crystal structures of Saccharomyces cerevisiae apo-pol eta and the Dpo4-CPD complex suggests unique features that allow pol eta to efficiently bypass CPDs.     

Eukaryotic polymerases iota and zeta act sequentially to bypass DNA lesions

DNA lesions can often block DNA replication, so cells possess specialized low-fidelity, and often error-prone, DNA polymerases that can bypass such lesions and promote replication of damaged DNA. The Saccharomyces cerevisiae RAD30 and human hRAD30A encode Pol eta, which bypasses a cis-syn thymine-thymine dimer efficiently and accurately. Here we show that a related human gene, hRAD30B, encodes the DNA polymerase Pol iota, which misincorporates deoxynucleotides at a high rate. To bypass damage, Pol iota specifically incorporates deoxynucleotides opposite highly distorting or non-instructional DNA lesions. This action is combined with that of DNA polymerase Pol zeta, which is essential for damage-induced mutagenesis, to complete the lesion bypass. Pol zeta is very inefficient in inserting deoxynucleotides opposite DNA lesions, but readily extends from such deoxynucleotides once they have been inserted. Thus, in a new model for mutagenic bypass of DNA lesions in eukaryotes, the two DNA polymerases act sequentially: Pol iota incorporates deoxynucleotides opposite DNA lesions, and Pol zeta functions as a mispair extender.     

The XPV (xeroderma pigmentosum variant) gene encodes human DNA polymerase eta.

Xeroderma pigmentosum variant (XP-V) is an inherited disorder which is associated with increased incidence of sunlight-induced skin cancers. Unlike other xeroderma pigmentosum cells (belonging to groups XP-A to XP-G), XP-V cells carry out normal nucleotide-excision repair processes but are defective in their replication of ultraviolet-damaged DNA. It has been suspected for some time that the XPV gene encodes a protein that is involved in trans-lesion DNA synthesis, but the gene product has never been isolated. Using an improved cell-free assay for trans-lesion DNA synthesis, we have recently isolated a DNA polymerase from HeLa cells that continues replication on damaged DNA by bypassing ultraviolet-induced thymine dimers in XP-V cell extracts. Here we show that this polymerase is a human homologue of the yeast Rad30 protein, recently identified as DNA polymerase eta. This polymerase and yeast Rad30 are members of a family of damage-bypass replication proteins which comprises the Escherichia coli proteins UmuC and DinB and the yeast Rev1 protein. We found that all XP-V cells examined carry mutations in their DNA polymerase eta gene. Recombinant human DNA polymerase eta corrects the inability of XP-V cell extracts to carry out DNA replication by bypassing thymine dimers on damaged DNA. Together, these results indicate that DNA polymerase eta could be the XPV gene product.     

A model for SOS-lesion-targeted mutations in Escherichia coli

The UmuD'2C protein complex (Escherichia coli pol V) is a low-fidelity DNA polymerase (pol) that copies damaged DNA in the presence of RecA, single-stranded-DNA binding protein (SSB) and the beta,gamma-processivity complex of E. coli pol III (ref. 4). Here we propose a model to explain SOS-lesion-targeted mutagenesis, assigning specific biochemical functions for each protein during translesion synthesis. (SOS lesion-targeted mutagenesis occurs when pol V is induced as part of the SOS response to DNA damage and incorrectly incorporates nucleotides opposite template lesions.) Pol V plus SSB catalyses RecA filament disassembly in the 3' to 5' direction on the template, ahead of the polymerase, in a reaction that does not involve ATP hydrolysis. Concurrent ATP-hydrolysis-driven filament disassembly in the 5' to 3' direction results in a bidirectional stripping of RecA from the template strand. The bidirectional collapse of the RecA filament restricts DNA synthesis by pol V to template sites that are proximal to the lesion, thereby minimizing the occurrence of untargeted mutations at undamaged template sites.     

Insertion of specific bases during DNA synthesis past the oxidation-damaged base 8-oxodG

Oxidative damage to DNA, reflected in the formation of 8-oxo-7-hydrodeoxyguanosine (8-oxodG), may be important in mutagenesis, carcinogenesis and the ageing process. Kuchino et al. studied DNA synthesis on oligodeoxynucleotide templates containing 8-oxodG, concluding that the modified base lacked base pairing specificity and directed misreading of pyrimidine residues neighbouring the lesion. Here we report different results, using an approach in which the several products of a DNA polymerase reaction can be measured. In contrast to the earlier report, we find that dCMP and dAMP are incorporated selectively opposite 8-oxodG with transient inhibition of chain extension occurring 3' to the modified base. The potentially mutagenic insertion of dAMP is targeted exclusively to the site of the lesion. The ratio of dCMP to dAMP incorporated varies, depending on the DNA polymerase involved. Chain extension from the dA.8-oxodG pair was efficiently catalysed by all polymerases tested.     

An exonucleolytic activity of human apurinic/apyrimidinic endonuclease on 3' mispaired DNA

Human apurinic/apyrimidinic endonuclease (APE1) is an essential enzyme in DNA base excision repair that cuts the DNA backbone immediately adjacent to the 5' side of abasic sites to facilitate repair synthesis by DNA polymerase beta (ref. 1). Mice lacking the murine homologue of APE1 die at an early embryonic stage. Here we report that APE1 has a DNA exonuclease activity on mismatched deoxyribonucleotides at the 3' termini of nicked or gapped DNA molecules. The efficiency of this activity is inversely proportional to the gap size in DNA. In a base excision repair system reconstituted in vitro, the rejoining of nicked mismatched DNA depended on the presence of APE1, indicating that APE1 may increase the fidelity of base excision repair and may represent a new 3' mispaired DNA repair mechanism. The exonuclease activity of APE1 can remove the anti-HIV nucleoside analogues 3'-azido-3'-deoxythymidine and 2',3'-didehydro-2', 3'-dideoxythymidine from DNA, suggesting that APE1 might have an impact on the therapeutic index of antiviral compounds in this category.     

A specific partner for abasic damage in DNA.

In most models of DNA replication, Watson-Crick hydrogen bonding drives the incorporation of nucleotides into the new strand of DNA and maintains the complementarity of bases with the template strand. Studies with nonpolar analogues of thymine and adenine, however, have shown that replication is still efficient in the absence of hydrogen bonds. The replication of base pairs might also be influenced by steric exclusion, whereby inserted nucleotides need to be the correct size and shape to fit the active site against a template base. A simple steric-exclusion model may not require Watson-Crick hydrogen bonding to explain the fidelity of replication, nor should canonical purine and pyrimidine shapes be necessary for enzymatic synthesis of a base pair if each can fit into the DNA double helix without steric strain. Here we test this idea by using a pyrene nucleoside triphosphate (dPTP) in which the fluorescent 'base' is nearly as large as an entire Watson-Crick base pair. We show that the non-hydrogen-bonding dPTP is efficiently and specifically inserted by DNA polymerases opposite sites that lack DNA bases. The efficiency of this process approaches that of a natural base pair and the specificity is 10(2)-10(4)-fold. We use these properties to sequence abasic lesions in DNA, which are a common form of DNA damage in vivo. In addition to their application in identifying such genetic lesions, our results show that neither hydrogen bonds nor purine and pyrimidine structures are required to form a base pair with high efficiency and selectivity. These findings confirm that steric complementarity is an important factor in the fidelity of DNA synthesis.     

A single amino acid governs enhanced activity of DinB DNA polymerases on damaged templates

Translesion synthesis (TLS) by Y-family DNA polymerases is a chief mechanism of DNA damage tolerance. Such TLS can be accurate or error-prone, as it is for bypass of a cyclobutane pyrimidine dimer by DNA polymerase eta (XP-V or Rad30) or bypass of a (6-4) TT photoproduct by DNA polymerase V (UmuD'2C), respectively. Although DinB is the only Y-family DNA polymerase conserved among all domains of life, the biological rationale for this striking conservation has remained enigmatic. Here we report that the Escherichia coli dinB gene is required for resistance to some DNA-damaging agents that form adducts at the N2-position of deoxyguanosine (dG). We show that DinB (DNA polymerase IV) catalyses accurate TLS over one such N2-dG adduct (N2-furfuryl-dG), and that DinB and its mammalian orthologue, DNA polymerase kappa, insert deoxycytidine (dC) opposite N2-furfuryl-dG with 10-15-fold greater catalytic proficiency than opposite undamaged dG. We also show that mutating a single amino acid, the 'steric gate' residue of DinB (Phe13 --> Val) and that of its archaeal homologue Dbh (Phe12 --> Ala), separates the abilities of these enzymes to perform TLS over N2-dG adducts from their abilities to replicate an undamaged template. We propose that DinB and its orthologues are specialized to catalyse relatively accurate TLS over some N2-dG adducts that are ubiquitous in nature, that lesion bypass occurs more efficiently than synthesis on undamaged DNA, and that this specificity may be achieved at least in part through a lesion-induced conformational change.     

DNA polymerases: Hoogsteen base-pairing in DNA replication?

Human polymerase-iota belongs to the error-prone Y family of polymerases, which frequently incorporate incorrect nucleotides during DNA replication but can efficiently bypass DNA lesions. On the basis of X-ray diffraction data, Nair et al. propose that Hoogsteen base-pairing is adopted by DNA during its replication by this enzyme. Here I re-examine their X-ray data and find that the electron density is very weak for a Hoogsteen base pair formed between a template adenine deoxyribonucleotide in the syn conformation and a deoxythymidine 5'-triphosphate (dTTP), and that the fit is better for a normal Watson-Crick base pair. As a guanine-cytosine (G-C) base pair has no potential to form a Hoogsteen base pair at physiological pH, Hoogsteen base-pairing is unlikely to be used in replication by this polymerase.     

DNA polymerase beta overexpression correlates with poor prognosis in esophageal cancer patients

Gene of DNA polymerase beta (pol ) plays an important role in base excision repair, DNA replication and translesion synthesis. This study aims to investigate the expression and prognostic significance of DNA pol in esophageal cancer. DNA pol expression was analyzed using real-time quantitative PCR (RT-qPCR) and immunohistochemical staining on tissue samples from a consecutive series of 114 esophageal squamous carcinoma patients who underwent resections between 2002 and 2006. Pol expression was investigated on its correlation to clinico-pathological factors and survival. RT-qPCR results showed higher expression of DNA pol mRNA in tumor tissue than in its matched adjacent non-tumor tissue sample, different expression of DNA pol mRNA was noticed with significance between tumors with and without lymph node metastasis. Immunohistochemistry staining results indicated the pol strong-positive rate was 44.73% (51/114) in tumor tissue samples and 0.00% in matched adjacent non-tumor tissue samples, with significant difference. Kaplan-Meier survival curves revealed that high expression of pol was associated with tumor metastasis and poor prognosis in esophageal cancer patients. Our data suggests that pol plays an important role in tumor progression and that high pol expression predicts an unfavorable prognosis in esophageal squamous carcinoma patients.     

Replication by human DNA polymerase-iota occurs by Hoogsteen base-pairing

Almost all DNA polymerases show a strong preference for incorporating the nucleotide that forms the correct Watson-Crick base pair with the template base. In addition, the catalytic efficiencies with which any given polymerase forms the four possible correct base pairs are roughly the same. Human DNA polymerase-iota (hPoliota), a member of the Y family of DNA polymerases, is an exception to these rules. hPoliota incorporates the correct nucleotide opposite a template adenine with a several hundred to several thousand fold greater efficiency than it incorporates the correct nucleotide opposite a template thymine, whereas its efficiency for correct nucleotide incorporation opposite a template guanine or cytosine is intermediate between these two extremes. Here we present the crystal structure of hPoliota bound to a template primer and an incoming nucleotide. The structure reveals a polymerase that is 'specialized' for Hoogsteen base-pairing, whereby the templating base is driven to the syn conformation. Hoogsteen base-pairing offers a basis for the varied efficiencies and fidelities of hPoliota opposite different template bases, and it provides an elegant mechanism for promoting replication through minor-groove purine adducts that interfere with replication.     

Taq酶体外合成DNA时模板错位机制的探讨

利用Taq DNA聚合酶体外合成DNA过程中,当反应体系中缺少与模板链互补配对的dNTP底物时,产物合成并不会在底物缺失位点处终止,聚合反应继续进行.为研究此复制缺陷现象,设计一系列模板用于DNA体外酶促合成.除了已知的碱基错配机制,笔者发现存在另一种"模板错位"机制,即模板中与底物非Watson-Crick互补配对的碱基位点首先进行收缩滑动,形成模板bulge结构后再继续进行酶促合成反应.这项研究有助于提高DNA样品合成保真度以及继续深入探索体外DNA合成的详细机制.     

Induction of somatic hypermutation in immunoglobulin genes is dependent on DNA polymerase iota

Somatic hypermutation of immunoglobulin genes is a unique, targeted, adaptive process. While B cells are engaged in germinal centres in T-dependent responses, single base substitutions are introduced in the expressed Vh/Vl genes to allow the selection of mutants with a higher affinity for the immunizing antigen. Almost every possible DNA transaction has been proposed to explain this process, but each of these models includes an error-prone DNA synthesis step that introduces the mutations. The Y family of DNA polymerases--pol eta, pol iota, pol kappa and rev1--are specialized for copying DNA lesions and have high rates of error when copying a normal DNA template. By performing gene inactivation in a Burkitt's lymphoma cell line inducible for hypermutation, we show here that somatic hypermutation is dependent on DNA polymerase iota.     

Crystal structures of mismatch repair protein MutS and its complex with a substrate DNA

DNA mismatch repair is critical for increasing replication fidelity in organisms ranging from bacteria to humans. MutS protein, a member of the ABC ATPase superfamily, recognizes mispaired and unpaired bases in duplex DNA and initiates mismatch repair. Mutations in human MutS genes cause a predisposition to hereditary nonpolyposis colorectal cancer as well as sporadic tumours. Here we report the crystal structures of a MutS protein and a complex of MutS with a heteroduplex DNA containing an unpaired base. The structures reveal the general architecture of members of the MutS family, an induced-fit mechanism of recognition between four domains of a MutS dimer and a heteroduplex kinked at the mismatch, a composite ATPase active site composed of residues from both MutS subunits, and a transmitter region connecting the mismatch-binding and ATPase domains. The crystal structures also provide a molecular framework for understanding hereditary nonpolyposis colorectal cancer mutations and for postulating testable roles of MutS.     

Three-dimensional crystal structures of Escherichia coli met repressor with and without corepressor

The three-dimensional crystal structure of met repressor, in the presence or absence of bound corepressor (S-adenosylmethionine), shows a dimer of intertwined monomers, which do not have the helix-turn-helix motif characteristic of other bacterial repressor and activator structures. We propose that the interaction of met repressor with DNA occurs through either a pair of symmetry-related alpha-helices or a pair of beta-strands, and suggest a model for binding of several dimers to met operator regions.     

Cleavage of pyrimidine dimers in specific DNA sequences by a pyrimidine dimer DNA-glycosylase of M. luteus

Pyrimidine dimer formation in response to UV radiation is governed by the thymine content of the potential dimer and the two flanking nucleotides. An enzymatic activity can be purified from Micrococcus luteus that cleaves the N-glycosyl bond between the 5' pyrimidine of a dimer and the corresponding sugar without rupture of a phosphodiester bond. We propose that strand scission at a dimer site by the M. luteus enzyme requires two activities, a pyrimidine dimer DNA-glycosylase and an apyrimidinic/apurinic endonuclease.