Base excision repair enzyme family portrait: integrating the structure and chemistry of an entire DNA repair pathway

Repair pathway coordination from gap filling by polβ and subsequent nick sealing by LIG1 or LIG3α governs BER efficiency at the downstream steps

Base excision repair (BER) is the critical mechanism for preventing mutagenic and lethal consequences of single base lesions generated by endogenous factors or exposure to environmental hazards. BER pathway involves multi-step enzymatic reactions that require a tight coordination between repair proteins to transfer DNA intermediates in an orderly manner. Though often considered an accurate process, the BER can contribute to genome instability if normal coordination between gap filling by DNA polymerase (pol) β and subsequent nick sealing by DNA ligase 1 (LIG1) or DNA ligase 3α (LIG3α) breaks down at the downstream steps. Our studies demonstrated that an inaccurate DNA ligation by LIG1/LIG3α, stemming from an uncoordinated repair with polβ, leads to a range of deviations from canonical BER pathway, faulty repair events, and formation of deleterious DNA intermediates. Furthermore, X-ray repair cross-complementing protein 1 (XRCC1), as a scaffolding factor, enhances the processivity of downstream steps, and the DNA-end processing enzymes, Aprataxin (APTX), Flap-Endonuclease 1 (FEN1), and AP-Endonuclease 1 (APE1), play critical roles for cleaning of ligase failure products and proofreading of polβ errors in coordination with BER ligases. Overall, our studies contribute to understanding of how a multi-protein repair complex interplay at the final steps to maintain the repair efficiency.

Octahedral Iron in Catalytic Sites of Endonuclease IV from Staphylococcus aureus and Escherichia coli

During Staphylococcus aureus infections, reactive oxygen species cause DNA damage, including nucleotide base modification. After removal of the defective base, excision repair requires an endonuclease IV (Nfo), which hydrolyzes the phosphodiester bond 5' to the abasic nucleotide. This class of enzymes, typified by the enzyme from Escherichia coli, contains a catalytic site with three metal ions, previously reported to be all Zn2+. The 1.05 Å structure of Nfo from the Gram-positive organism S. aureus (SaNfo) revealed two inner Fe2+ ions and one Zn2+ as confirmed by dispersive anomalous difference maps. SaNfo has a previously undescribed water molecule liganded to Fe1 forming an octahedral coordination geometry and hydrogen bonded to Tyr33, an active site residue conserved in many Gram-positive bacteria, but which is Phe in Gram-negative species that coordinate Zn2+ at the corresponding site. The 1.9 Å structure of E. coli Nfo (EcNfo), purified without added metals, revealed that metal 2 is Fe2+ and not Zn2+. Octahedral coordination for the sites occupied by Fe2+ suggests a stereoselective mechanism for differentiating between Fe2+ and Zn2+ in this enzyme class. Kinetics and an inhibitor competition assay of SaNfo reveal product inhibition (or slow product release), especially at low ionic strength, caused in part by a Lys-rich DNA binding loop present in SaNfo and Gram-positive species but not in EcNfo. Biological significance of the slow product release is discussed. Catalytic activity in vitro is optimal at 300 mM NaCl, which is consistent with the halotolerant phenotype of S. aureus.

Impact of polβ/XRCC1 Interaction Variants on the Efficiency of Nick Sealing by DNA Ligase IIIα in the Base Excision Repair Pathway

Base excision repair (BER) requires a coordination from gap filling by DNA polymerase (pol) β to subsequent nick sealing by DNA ligase (LIG) IIIα at downstream steps of the repair pathway. X-ray cross-complementing protein 1 (XRCC1), a non-enzymatic scaffolding protein, forms repair complexes with polβ and LIGIIIα. Yet, the impact of the polβ mutations that affect XRCC1 interaction and protein stability on the repair pathway coordination during nick sealing by LIGIIIα remains unknown. Our results show that the polβ colon cancer-associated variant T304 exhibits a reduced interaction with XRCC1 and the mutations in the interaction interface of V303 loop (L301R/V303R/V306R) and at the lysine residues (K206A/K244A) that prevent ubiquitin-mediated degradation of the protein exhibit a diminished repair protein complex formation with XRCC1. Furthermore, we demonstrate no significant effect on gap and nick DNA binding affinity of wild-type polβ by these mutations. Finally, our results reveal that XRCC1 leads to an efficient channeling of nick repair products after nucleotide incorporation by polβ variants to LIGIIIα, which is compromised by the L301R/V303R/V306R and K206A/K244A mutations. Overall, our findings provide insight into how the mutations in the polβ/XRCC1 interface and the regions affecting protein stability could dictate accurate BER pathway coordination at the downstream steps involving nick sealing by LIGIIIα.

Circ-Udg Derived from Cyprinid Herpesvirus 2 Promotes Viral Replication

Cyprinid herpesvirus 2 (CyHV-2) has caused great losses to the gibel carp (Carassius auratus gibelio) industry. Previous studies showed that certain DNA viruses can encode circular RNAs (circRNAs) to regulate virus infection, which provides new clues for the treatment of viral disease. Whether CyHV-2 can encode circRNAs is still unknown. Here, 10 CyHV-2-derived circRNAs were identified, and the function of circ-udg, a circRNA derived from the CyHV-2 uracil DNA glycosylase (udg) gene, was studied. Although the expression level of circ-udg was lower than that of the parental gene, udg, its expression level was elevated in tandem with the proliferation of CyHV-2 and udg. In vitro experiments confirmed that circ-udg could promote the proliferation of CyHV-2. Moreover, circ-udg could encode a truncated UDG protein consisting of 147-amino-acid residues (termed circ-udg-P147). Both UDG and circ-udg-P147 were found to promote CyHV-2 proliferation, but the promoting effect of circ-udg on CyHV-2 proliferation was attenuated after circ-udg lost the ability to encode circ-udg-P147. Also, circ-udg-P147 could not change the transcription level of the udg gene. Interestingly, the UDG protein level was increased by circ-udg-P147. These results deepen the understanding of the genetic information carried by the genome of CyHV-2 and provide a new target for the treatment of gibel carp bleeding disease caused by CyHV-2. IMPORTANCE The outbreak of C. auratus gibelio gill hemorrhagic disease caused by CyHV-2 brought great losses to the gibel carp industry. Therefore, exploring the interaction between CyHV-2 and host and the molecular mechanism of viral infection is of great significance in preventing and treating the gibel carp gill hemorrhagic disease. Although some progress has been made in the study of CyHV-2, the mechanism of interaction between CyHV-2 and crucian carp is still unclear. In this study, we found that CyHV-2 can encode circRNA to regulate virus replication. Our study provides novel information on CyHV-2 functional genomics, a reference for research into the circRNA of other viruses, and theoretical guidance for preventing and treating gibel carp bleeding disease.

The scaffold protein XRCC1 stabilizes the formation of polβ/gap DNA and ligase IIIα/nick DNA complexes in base excision repair

The base excision repair (BER) pathway involves gap filling by DNA polymerase (pol) β and subsequent nick sealing by ligase IIIα. X-ray cross-complementing protein 1 (XRCC1), a nonenzymatic scaffold protein, assembles multiprotein complexes, although the mechanism by which XRCC1 orchestrates the final steps of coordinated BER remains incompletely defined. Here, using a combination of biochemical and biophysical approaches, we revealed that the polβ/XRCC1 complex increases the processivity of BER reactions after correct nucleotide insertion into gaps in DNA and enhances the handoff of nicked repair products to the final ligation step. Moreover, the mutagenic ligation of nicked repair intermediate following polβ 8-oxodGTP insertion is enhanced in the presence of XRCC1. Our results demonstrated a stabilizing effect of XRCC1 on the formation of polβ/dNTP/gap DNA and ligase IIIα/ATP/nick DNA catalytic ternary complexes. Real-time monitoring of protein–protein interactions and DNA-binding kinetics showed stronger binding of XRCC1 to polβ than to ligase IIIα or aprataxin, and higher affinity for nick DNA with undamaged or damaged ends than for one nucleotide gap repair intermediate. Finally, we demonstrated slight differences in stable polβ/XRCC1 complex formation, polβ and ligase IIIα protein interaction kinetics, and handoff process as a result of cancer-associated (P161L, R194W, R280H, R399Q, Y576S) and cerebellar ataxia-related (K431N) XRCC1 variants. Overall, our findings provide novel insights into the coordinating role of XRCC1 and the effect of its disease-associated variants on substrate-product channeling in multiprotein/DNA complexes for efficient BER.

Use of a molecular beacon based fluorescent method for assaying uracil DNA glycosylase (Ung) activity and inhibitor screening

Uracil DNA glycosylases are an important class of enzymes that hydrolyze the N-glycosidic bond between the uracil base and the deoxyribose sugar to initiate uracil excision repair. Uracil may arise in DNA either because of its direct incorporation (against A in the template) or because of cytosine deamination. Mycobacteria with G, C rich genomes are inherently at high risk of cytosine deamination. Uracil DNA glycosylase activity is thus important for the survival of mycobacteria. A limitation in evaluating the druggability of this enzyme, however, is the absence of a rapid assay to evaluate catalytic activity that can be scaled for medium to high-throughput screening of inhibitors. Here we report a fluorescence-based method to assay uracil DNA glycosylase activity. A hairpin DNA oligomer with a fluorophore at its 5′ end and a quencher at its 3′ ends was designed incorporating five consecutive U:A base pairs immediately after the first base pair (5′ C:G 3’) at the top of the hairpin stem. Enzyme assays performed using this fluorescent substrate were seen to be highly sensitive thus enabling investigation of the real time kinetics of uracil excision. Here we present data that demonstrate the feasibility of using this assay to screen for inhibitors of Mycobacterium tuberculosis uracil DNA glycosylase. We note that this assay is suitable for high-throughput screening of compound libraries for uracil DNA glycosylase inhibitors.

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A novel molecular beacon based fluorescent method to assay uracil DNA glycosylase (UDG) activity has been developed.

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The single step assay is useful to determine real-time kinetics of uracil release.

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The assay is useful for high throughput screening of uracil DNA glycosylase inhibitors.

The ligation of pol β mismatch insertion products governs the formation of promutagenic base excision DNA repair intermediates

DNA ligase I and DNA ligase III/XRCC1 complex catalyze the ultimate ligation step following DNA polymerase (pol) β nucleotide insertion during base excision repair (BER). Pol β Asn279 and Arg283 are the critical active site residues for the differentiation of an incoming nucleotide and a template base and the N-terminal domain of DNA ligase I mediates its interaction with pol β. Here, we show inefficient ligation of pol β insertion products with mismatched or damaged nucleotides, with the exception of a Watson–Crick-like dGTP insertion opposite T, using BER DNA ligases in vitro. Moreover, pol β N279A and R283A mutants deter the ligation of the promutagenic repair intermediates and the presence of N-terminal domain of DNA ligase I in a coupled reaction governs the channeling of the pol β insertion products. Our results demonstrate that the BER DNA ligases are compromised by subtle changes in all 12 possible noncanonical base pairs at the 3′-end of the nicked repair intermediate. These findings contribute to understanding of how the identity of the mismatch affects the substrate channeling of the repair pathway and the mechanism underlying the coordination between pol β and DNA ligase at the final ligation step to maintain the BER efficiency.

Selective interactions between mimivirus uracil-DNA glycosylase and inhibitory proteins determined by a single amino acid

Uracil-N-glycosylase (UNG) is found in most organisms as well as in large DNA viruses. Its inhibitory proteins, including uracil glycosylase inhibitor (UGI) and p56, tightly bind to the active site of UNG by mimicking the DNA substrates. As the binding motifs are conserved in UNG family proteins, the inhibitory proteins bind to various UNG proteins across species. However, the intercalation residue that penetrates the DNA minor groove during uracil excision is not conserved among UNG proteins. To understand the role of the intercalation residue in their binding to the inhibitory proteins, we prepared mutants of mimivirus UNG, measured the binding affinity between the UNG mutants and inhibitory proteins, and analyzed the interactions based on the crystal structures of mimivirus UNG mutants complexed with UGI. The results show that mimivirus UNG, which harbors Tyr as an intercalation residue, did not interact with the inhibitory proteins intrinsically, whereas mutations of the intercalation residue to Phe or Leu resulted in tight interactions with UGI and p56; mutation to Met resulted in tight interactions only with p56. The crystal structures revealed that Phe and Leu stabilize the interactions by fitting into the hydrophobic pocket of UGI. These results show that differences in size and hydrophobicity of the intercalation residues determine the interactions between UNG family proteins and the inhibitory proteins, UGI and p56.

Structural basis for recognition and repair of the 3'-phosphate by NExo, a base excision DNA repair nuclease from Neisseria meningitidis

NExo is an enzyme from Neisseria meningitidis that is specialized in the removal of the 3'-phosphate and other 3'-lesions, which are potential blocks for DNA repair. NExo is a highly active DNA 3'-phosphatase, and although it is from the class II AP family it lacks AP endonuclease activity. In contrast, the NExo homologue NApe, lacks 3'-phosphatase activity but is an efficient AP endonuclease. These enzymes act together to protect the meningococcus from DNA damage arising mainly from oxidative stress and spontaneous base loss. In this work, we present crystal structures of the specialized 3'-phosphatase NExo bound to DNA in the presence and absence of a 3'-phosphate lesion. We have outlined the reaction mechanism of NExo, and using point mutations we bring mechanistic insights into the specificity of the 3'-phosphatase activity of NExo. Our data provide further insight into the molecular origins of plasticity in substrate recognition for this class of enzymes. From this we hypothesize that these specialized enzymes lead to enhanced efficiency and accuracy of DNA repair and that this is important for the biological niche occupied by this bacterium.

Interplay between DNA Polymerases and DNA Ligases: Influence on Substrate Channeling and the Fidelity of DNA Ligation

DNA ligases are a highly conserved group of nucleic acid enzymes that play an essential role in DNA repair, replication, and recombination. This review focuses on functional interaction between DNA polymerases and DNA ligases in the repair of single- and double-strand DNA breaks, and discusses the notion that the substrate channeling during DNA polymerase-mediated nucleotide insertion coupled to DNA ligation could be a mechanism to minimize the release of potentially mutagenic repair intermediates. Evidence suggesting that DNA ligases are essential for cell viability includes the fact that defects or insufficiency in DNA ligase are casually linked to genome instability. In the future, it may be possible to develop small molecule inhibitors of mammalian DNA ligases and/or their functional protein partners that potentiate the effects of chemotherapeutic compounds and improve cancer treatment outcomes.

What Combined Measurements From Structures and Imaging Tell Us About DNA Damage Responses

DNA damage outcomes depend upon the efficiency and fidelity of DNA damage responses (DDRs) for different cells and damage. As such, DDRs represent tightly regulated prototypical systems for linking nanoscale biomolecular structure and assembly to the biology of genomic regulation and cell signaling. However, the dynamic and multifunctional nature of DDR assemblies can render elusive the correlation between the structures of DDR factors and specific biological disruptions to the DDR when these structures are altered. In this chapter, we discuss concepts and strategies for combining structural, biophysical, and imaging techniques to investigate DDR recognition and regulation, and thus bridge sequence-level structural biochemistry to quantitative biological outcomes visualized in cells. We focus on representative DDR responses from PARP/PARG/AIF damage signaling in DNA single-strand break repair and nonhomologous end joining complexes in double-strand break repair. Methods with exemplary experimental results are considered with a focus on strategies for probing flexibility, conformational changes, and assembly processes that shape a predictive understanding of DDR mechanisms in a cellular context. Integration of structural and imaging measurements promises to provide foundational knowledge to rationally control and optimize DNA damage outcomes for synthetic lethality and for immune activation with resulting insights for biology and cancer interventions.

XRCC1 Arg399Gln Gene Polymorphism and Hepatocellular Carcinoma Risk in the Italian Population

Background

The human X-ray repair cross-complementing protein 1 ( XRCC1) gene encodes for one of the major repair factors involved in base excision repair (BER), which is reported to be associated with the risk of several cancers. A few studies have explored the association between risk of hepatocellular carcinoma (HCC) and single-nucleotide polymorphisms (SNPs) in different DNA repair genes, with contradictory results. The purpose of this study was to evaluate the association between XRCC1 Arg399Gln polymorphism and susceptibility to HCC.

Methods

A total of 89 HCC patients and 99 randomly selected healthy controls were enrolled. Genotyping of XRCC1 rs25487 was performed by high-resolution melting analysis and Sanger sequencing.

Results

On univariate analysis, a statistically significant association was found between risk of HCC and XRCC1 399Arg/Gln genotype (odd ratio [OR] = 1.88; 95% CI, 1.04-3.43), which was confirmed after adjusting by sex (OR = 1.94; 95% CI, 1.04-3.63). Although not significant, Kaplan-Meier analysis showed a decreased median survival in Arg/Gln genotype carriers in comparison with Arg/Arg carriers.

Conclusions

To our knowledge, this is the first study reporting an association between BER SNP and HCC risk in a population of central-southern Italy.

Repair of Clustered Damage and DNA Polymerase Iota

Multiple DNA lesions occurring within one or two turns of the DNA helix known as clustered damage are a source of double-stranded DNA breaks, which represent a serious threat to the cells. Repair of clustered lesions is accomplished in several steps. If a clustered lesion contains oxidized bases, an individual DNA lesion is repaired by the base excision repair (BER) mechanism involving a specialized DNA polymerase after excising DNA damage. Here, we investigated DNA synthesis catalyzed by DNA polymerase iota using damaged DNA templates. Two types of DNA substrates were used as model DNAs: partial DNA duplexes containing breaks of different length, and DNA duplexes containing 5-formyluracil (5-foU) and uracil as a precursor of apurinic/apyrimidinic sites (AP) in opposite DNA strands. For the first time, we showed that DNA polymerase iota is able to catalyze DNA synthesis using partial DNA duplexes having breaks of different length as substrates. In addition, we found that DNA polymerase iota could catalyze DNA synthesis during repair of clustered damage via the BER system by using both undamaged and 5-foU-containing templates. We found that hPCNA (human proliferating cell nuclear antigen) increased efficacy of DNA synthesis catalyzed by DNA polymerase iota.

Reprint of "Oxidant and environmental toxicant-induced effects compromise DNA ligation during base excision DNA repair"

DNA lesions arise from many endogenous and environmental agents, and such lesions can promote deleterious events leading to genomic instability and cell death. Base excision repair (BER) is the main DNA repair pathway responsible for repairing single strand breaks, base lesions and abasic sites in mammalian cells. During BER, DNA substrates and repair intermediates are channeled from one step to the next in a sequential fashion so that release of toxic repair intermediates is minimized. This includes handoff of the product of gap-filling DNA synthesis to the DNA ligation step. The conformational differences in DNA polymerase β (pol β) associated with incorrect or oxidized nucleotide (8-oxodGMP) insertion could impact channeling of the repair intermediate to the final step of BER, i.e., DNA ligation by DNA ligase I or the DNA Ligase III/XRCC1 complex. Thus, modified DNA ligase substrates produced by faulty pol β gap-filling could impair coordination between pol β and DNA ligase. Ligation failure is associated with 5'-AMP addition to the repair intermediate and accumulation of strand breaks that could be more toxic than the initial DNA lesions. Here, we provide an overview of the consequences of ligation failure in the last step of BER. We also discuss DNA-end processing mechanisms that could play roles in reversal of impaired BER.

Oxidant and environmental toxicant-induced effects compromise DNA ligation during base excision DNA repair

DNA lesions arise from many endogenous and environmental agents, and such lesions can promote deleterious events leading to genomic instability and cell death. Base excision repair (BER) is the main DNA repair pathway responsible for repairing single strand breaks, base lesions and abasic sites in mammalian cells. During BER, DNA substrates and repair intermediates are channeled from one step to the next in a sequential fashion so that release of toxic repair intermediates is minimized. This includes handoff of the product of gap-filling DNA synthesis to the DNA ligation step. The conformational differences in DNA polymerase β (pol β) associated with incorrect or oxidized nucleotide (8-oxodGMP) insertion could impact channeling of the repair intermediate to the final step of BER, i.e., DNA ligation by DNA ligase I or the DNA Ligase III/XRCC1 complex. Thus, modified DNA ligase substrates produced by faulty pol β gap-filling could impair coordination between pol β and DNA ligase. Ligation failure is associated with 5'-AMP addition to the repair intermediate and accumulation of strand breaks that could be more toxic than the initial DNA lesions. Here, we provide an overview of the consequences of ligation failure in the last step of BER. We also discuss DNA-end processing mechanisms that could play roles in reversal of impaired BER.

Association between the PARP1 Val762Ala polymorphism and cancer risk: evidence from 43 studies

BACKGROUND

Poly (ADP-ribose) polymerase-1 (PARP-1) plays critical roles in the detection and repair of damaged DNA, as well as cell proliferation and death. Numerous studies have examined the associations between PARP1 Val762Ala (rs1136410 T>C) polymorphism and cancer susceptibility; nevertheless, the findings from different research groups remain controversial.

METHODS

We searched literatures from MEDLINE, EMBASE and CBM pertaining to such associations, and then calculated pooled odds ratio (OR) and 95% confidence interval (CI) by using random-effects model. The false-positive report probability (FPRP) analysis was used to confirm the validity of significant findings. Moreover, potential effects of rs1136410 variants on PARP1 mRNA expression were analyzed for three ethnicities by combining data from HapMap (genotype) and SNPexp (mRNA expression).

RESULTS

The final meta-analysis incorporated 43 studies, consisting of 17,351 cases and 22,401 controls. Overall, our results did not suggest significant associations between Ala variant (Ala/Ala or Ala/Val genotype) and cancer risk. However, further stratification analysis showed significantly increased risk for gastric cancer (Ala/Ala vs. Val/Val: OR = 1.56, 95% CI = 1.01-2.42, Ala/Val vs. Val/Val: OR = 1.34, 95% CI = 1.14-1.58, dominant model: OR = 1.41, 95% CI = 1.21-1.65 and Ala vs. Val: OR = 1.29, 95% CI = 1.07-1.55). On the contrary, decreased risk for brain tumor (Ala/Val vs. Val/Val: OR = 0.77, 95% CI = 0.68-0.87, dominant model: OR = 0.77, 95% CI = 0.68-0.87 and Ala vs. Val: OR = 0.82, 95% CI = 0.74-0.91). Additionally, we found that the Ala carriers had a significantly increased risk in all models for Asians. Our mRNA expression data provided further biological evidence to consolidate this finding.

CONCLUSIONS

Despite some limitations, this meta-analysis found evidence for an association between the PAPR1 Val762Ala and cancer susceptibility within gastric cancer, brain tumor and Asian subgroups.

Apurinic/apyrimidinic endonuclease 1 polymorphisms are associated with ovarian cancer susceptibility in a Chinese population

OBJECTIVE

Apurinic/apyrimidinic endonuclease 1 (APE1) plays an essential role in the base excision repair pathway. Recent studies have shown that APE1 polymorphisms are associated with an increased risk for many types of cancers. This study investigated the association between APE1 polymorphisms and the susceptibility of ovarian cancer.

METHODS

A case-control study was performed on 124 patients with ovarian cancer and 141 controls. We genotyped the rs1760944 and rs1130409 polymorphisms and assessed their associations with the risk for ovarian cancer.

RESULTS

The rs1130409 polymorphism was significantly associated with a risk for ovarian cancer. The TG/GG genotype and the G allele were associated with a decreased risk for ovarian cancer (adjusted odds ratio [aOR], 0.495; 95% confidence interval [CI], 0.267-0.920 for TG vs TT; aOR, 0.263; 95% CI, 0.132-0.521 for GG vs TT; aOR, 0.486; 95% CI, 0.344-0.0.688 for the G allele vs the T allele). In the stratified analyses, we found that when comparing the TG/GG genotype versus the TT genotype, the lower risk was more evident in subgroups of patients 50 years or older (aOR, 0.753; 95% CI, 0.604-0.938), patients with menarche age of 15 years or older (aOR, 0.722; 95% CI, 0.573-0.910), patients with gravidity of 3 or more times (aOR, 0.732; 95% CI, 0.587-0.912), and postmenopausal women (aOR, 0.763; 95% CI, 0.615-0.947). Meanwhile, the rs1760944 polymorphism was not found to be associated with a risk for ovarian cancer. However, by haplotype analysis, we found that the T-G and G-G haplotypes were associated with a decreased risk for ovarian cancer.

CONCLUSIONS

Our results suggest that in a Han Chinese population, the APE1 rs1130409 polymorphism may correlate with ovarian cancer susceptibility.

Polymorphisms in genes of APE1, PARP1, and XRCC1: risk and prognosis of colorectal cancer in a northeast Chinese population

Base excision repair (BER) pathway plays critical role in maintaining genome integrity. Polymorphisms in BER genes which modulate the DNA repair capacity may affect the susceptibility and prognosis of cancer. We conducted a case-control study and followed up the cases to explore the associations between BER genes polymorphisms and the risk and prognosis of colorectal cancer (CRC). This study included 451 CRC patients and 631 controls. Four single-nucleotide polymorphisms (SNPs) in genes of apurinic/apyrimidinic endonuclease-1 (APE1), ADP-ribosyltransferase (ADPRT, also known as PARP1), and X-ray repair cross-complementing groups 1 (XRCC1) were tested by PCR-RFLP. Odds ratio (OR), hazard ratio (HR), and their 95 % confidence intervals (CIs) were calculated by unconditional logistic regression and Cox proportional hazard model. PARP1 762 recessive model (OR = 1.57, 95 % CI 1.12-2.20) and XRCC1 194 dominant model (OR = 1.45, 95 % CI 1.12-1.88) were associated with increased CRC risk. A significant increasing trend for the risk of CRC was detected with the increasing number of putative risk genotypes (P (trend) = 0.00). However, no association was found between these four SNPs and the prognosis of CRC. In conclusion, APE1 (Asp148Glu), PARP1 (Ala762Val), and XRCC1 (Arg399Gln, Arg194Trp) were associated with the susceptibility to CRC, but were not associated with the prognosis of CRC.

Polymorphisms in base excision DNA repair genes and association with melanoma risk in a pilot study on Central-South Italian population

Base excision repair plays a key role in the removing of DNA damage from exposure to endogenous and exogenous carcinogens. The BER pathway removes alterations of a single oxidized, reduced or methylated base. Recently some studies have explored the association between risk for cutaneous melanoma and non-synonymous single-nucleotide polymorphisms (nsSNPs) in DNA-repair genes, although with contradictory results. We hypothesized that common nsSNPs of BER genes, specifically ADPRT rs1136410, XRCC1 rs25487, rs25489, rs1799782, APEX1 rs1130409, OGG1 rs1052133, LIG3 rs3136025 and MUTYH rs3219466, may contribute to risk of melanoma. The aim of this study is to investigate whether or not a correlation between these nsSNPs and melanoma risk and/or aggressiveness is present. 167 melanoma patients and 186 healthy control subjects were analysed. By multivariate statistical analysis no association was found between nsSNP and melanoma aggressiveness, while only the two XRCC1 (rs25487 and rs25489) nsSNPs showed a strong correlation (p<0.001) with melanoma risk. To our knowledge this is the first study reporting an association between BER nsSNPs and melanoma risk in Central-South Italian individuals. Our findings, if confirmed in larger population studies, will allow the inclusion of these XRCC1 nsSNPs in a screening panel for those individuals at higher risk for melanoma.

Specialization of an Exonuclease III family enzyme in the repair of 3' DNA lesions during base excision repair in the human pathogen Neisseria meningitidis

We have previously demonstrated that the two Exonuclease III (Xth) family members present within the obligate human pathogen Neisseria meningitidis, NApe and NExo, are important for survival under conditions of oxidative stress. Of these, only NApe possesses AP endonuclease activity, while the primary function of NExo remained unclear. We now reveal further functional specialization at the level of 3′-PO₄ processing for NExo. We demonstrate that the bi-functional meningococcal glycosylases Nth and MutM can perform strand incisions at abasic sites in addition to NApe. However, no such functional redundancy exists for the 3′-phosphatase activity of NExo, and the cytotoxicity of 3′-blocking lesions is reflected in the marked sensitivity of a mutant lacking NExo to oxidative stress, compared to strains deficient in other base excision repair enzymes. A histidine residue within NExo that is responsible for its lack of AP endonuclease activity is also important for its 3′-phosphatase activity, demonstrating an evolutionary trade off in enzyme function at the single amino acid level. This specialization of two Xth enzymes for the 3′-end processing and strand-incision reactions has not previously been observed and provides a new paradigm within the prokaryotic world for separation of these critical functions during base excision repair.

XPB and XPD helicases in TFIIH orchestrate DNA duplex opening and damage verification to coordinate repair with transcription and cell cycle via CAK kinase

Helicases must unwind DNA at the right place and time to maintain genomic integrity or gene expression. Biologically critical XPB and XPD helicases are key members of the human TFIIH complex; they anchor CAK kinase (cyclinH, MAT1, CDK7) to TFIIH and open DNA for transcription and for repair of duplex distorting damage by nucleotide excision repair (NER). NER is initiated by arrested RNA polymerase or damage recognition by XPC-RAD23B with or without DDB1/DDB2. XP helicases, named for their role in the extreme sun-mediated skin cancer predisposition xeroderma pigmentosum (XP), are then recruited to asymmetrically unwind dsDNA flanking the damage. XPB and XPD genetic defects can also cause premature aging with profound neurological defects without increased cancers: Cockayne syndrome (CS) and trichothiodystrophy (TTD). XP helicase patient phenotypes cannot be predicted from the mutation position along the linear gene sequence and adjacent mutations can cause different diseases. Here we consider the structural biology of DNA damage recognition by XPC-RAD23B, DDB1/DDB2, RNAPII, and ATL, and of helix unwinding by the XPB and XPD helicases plus the bacterial repair helicases UvrB and UvrD in complex with DNA. We then propose unified models for TFIIH assembly and roles in NER. Collective crystal structures with NMR and electron microscopy results reveal functional motifs, domains, and architectural elements that contribute to biological activities: damaged DNA binding, translocation, unwinding, and ATP driven changes plus TFIIH assembly and signaling. Coupled with mapping of patient mutations, these combined structural analyses provide a framework for integrating and unifying the rich biochemical and cellular information that has accumulated over forty years of study. This integration resolves puzzles regarding XP helicase functions and suggests that XP helicase positions and activities within TFIIH detect and verify damage, select the damaged strand for incision, and coordinate repair with transcription and cell cycle through CAK signaling.

Genetic polymorphisms in DNA repair and oxidative stress pathways associated with malignant melanoma susceptibility

BACKGROUND

Base excision repair (BER) and nucleotide excision repair (NER) pathways eliminate a wide variety of DNA damage, including UV photoproducts. The ability of each individual to repair DNA damage following different causes might explain at least in part the variability in cancer susceptibility. Moreover, inflammatory response to UV exposure may further contribute to skin carcinogenesis by oxidative stress mechanisms. Single nucleotide polymorphisms in genes encoding various DNA-repair enzymes and oxidative stress factors may be candidate low-penetrance variants with a role in susceptibility to different cancers, particularly in those with aetiologies linked to environmental exposure, such as malignant melanoma (MM).

METHODS

In this case-control study, 684 Spanish sporadic MM patients and 406 cancer-free control subjects were included and the role of 46 polymorphisms belonging to 16 BER and NER genes as well as 11 genes involved in oxidative stress processes were investigated.

RESULTS

One polymorphism was identified to be individually associated with MM in the Spanish population. The variant was found in the NOS1 oxidative stress gene (rs2682826; p-value=0.01). These results suggest a putative role of oxidative stress processes in the genetic predisposition to melanoma.

CONCLUSION

To the authors' knowledge, this is the largest DNA repair-related SNP study in melanoma risk conducted in the Spanish population up to now. Furthermore, it also represents a comprehensive genetic study of several oxidative stress polymorphisms tested in relation to MM susceptibility.

Conformational dynamics and pre-steady-state kinetics of DNA glycosylases

Results of investigations of E. coli DNA glycosylases using pre-steady-state kinetics are considered. Special attention is given to the connection of conformational changes in the interacting biomolecules with kinetic mechanisms of the enzymatic processes.

Association between single-nucleotide polymorphisms of selected genes involved in the response to DNA damage and risk of colon, head and neck, and breast cancers in a Polish population

Single-nucleotide polymorphisms in genes involved in DNA-damage-induced responses are reported frequently to be a risk factor in various cancer types. Here we analysed polymorphisms in 5 genes involved in DNA repair (XPD Asp312Asn and Lys751Gln, XRCC1 Arg399Gln, APE1 Asp148Glu, NBS1 Glu185Gln, and XPA G-4A) and in a gene involved in regulation of the cell-cycle (CCND1 A870G). We compared their frequencies in groups of colon, head and neck, and breast cancer patients, and 2 healthy control groups: (1) matched healthy Polish individuals and (2) a NCBI database control group. Highly significant differences in the distribution of genotypes of the APE1, XRCC1 and CCND1 genes were found between colon cancer patients and healthy individuals. The 148Asp APE1 allele and the 399Gln XRCC1 allele apparently increased the risk of colon cancer (OR = 1.9-2.3 and OR = 1.5-2.1, respectively). Additionally, frequencies of XPD genotypes differed between healthy controls and patients with colon or head and neck cancer. Importantly, no differences in the distribution of these polymorphisms were found between healthy controls and breast cancer patients. The data clearly indicate that the risk of colon cancer is associated with single-nucleotide polymorphism in genes involved in base-excision repair and DNA-damage-induced responses.

Structure of uracil-DNA glycosylase from Mycobacterium tuberculosis: insights into interactions with ligands

Uracil N-glycosylase (Ung) is the most thoroughly studied of the group of uracil DNA-glycosylase (UDG) enzymes that catalyse the first step in the uracil excision-repair pathway. The overall structure of the enzyme from Mycobacterium tuberculosis is essentially the same as that of the enzyme from other sources. However, differences exist in the N- and C-terminal stretches and some catalytic loops. Comparison with appropriate structures indicate that the two-domain enzyme closes slightly when binding to DNA, while it opens slightly when binding to the proteinaceous inhibitor Ugi. The structural changes in the catalytic loops on complexation reflect the special features of their structure in the mycobacterial protein. A comparative analysis of available sequences of the enzyme from different sources indicates high conservation of amino-acid residues in the catalytic loops. The uracil-binding pocket in the structure is occupied by a citrate ion. The interactions of the citrate ion with the protein mimic those of uracil, in addition to providing insights into other possible interactions that inhibitors could be involved in.

Genetic variants of XRCC1, APE1, and ADPRT genes and risk of bladder cancer

DNA damaged by exposure to exogenous and endogenous carcinogens could be removed effectively by the base excision repair pathway, in which the XRCC1, APE1, and ADPRT genes play a key role. Genetic variations in these important genes may alter repair function and contribute to cancer risk. We hypothesized that XRCC1, APE1, and ADPRT polymorphisms are associated with risk of bladder cancer. In a hospital-based case-control study of 234 patients with bladder cancer and 253 cancer-free controls, we genotyped the XRCC1-77T>C, Arg194Trp, Arg280His, Arg399Gln, APE1-656T>G, Asp148Glu, ADPRT-442G>A, and Val762Ala polymorphisms using polymerase chain reaction-restriction fragment length polymorphism method. We found an increased risk of bladder cancer associated with the XRCC1 194Trp/Trp and 280Arg/His genotypes (adjusted odds ratio = 3.90, 95% confidence interval = 1.69-8.98 for 194Trp/Trp and 2.53, 1.67-3.83 for 280Arg/His) compared with the 194Arg/Arg and 280Arg/Arg genotypes, respectively. In contrast, the APE1-656GG genotype was associated with a decreased risk of bladder cancer (0.57, 0.33-0.98) compared with the TT genotype. When we evaluated these eight polymorphisms together, we found that the combined genotypes with 9-13 variant (risk) alleles were associated with an increased risk of bladder cancer (2.25, 1.48-3.40) compared with those with 3-8 variants. These findings suggest that the XRCC1 and APE1 polymorphisms may contribute to susceptibility to bladder cancer. Larger studies are warranted to verify these findings.

Real-time studies of conformational dynamics of the repair enzyme E. coli formamidopyrimidine-DNA glycosylase and its DNA complexes during catalytic cycle

Fpg protein from Escherichia coli belongs to the class of DNA glycosylases/abasic site lyases excising several oxidatively damaged purines in the base excision repair pathway. In this review, we summarize the results of our studies of Fpg protein from E. coli, elucidating the intrinsic mechanism of recognition and excision of damaged bases in DNA.

Investigating the biochemical impact of DNA damage with structure-based probes: abasic sites, photodimers, alkylation adducts, and oxidative lesions

DNA sustains a wide variety of damage, such as the formation of abasic sites, pyrimidine dimers, alkylation adducts, or oxidative lesions, upon exposure to UV radiation, alkylating agents, or oxidative conditions. Since these forms of damage may be acutely toxic or mutagenic and potentially carcinogenic, it is of interest to gain insight into how their structures impact biochemical processing of DNA, such as synthesis, transcription, and repair. Lesion-specific molecular probes have been used to study polymerase-mediated translesion DNA synthesis of abasic sites and TT dimers, while other probes have been developed for specifically investigating the alkylation adduct O(6)-Bn-G and the oxidative lesion 8-oxo-G. In this review, recent examples of lesion-specific molecular probes are surveyed; their specificities of incorporation opposite target lesions compared to unmodified nucleotides are discussed, and limitations of their applications under physiologically relevant conditions are assessed.

The DNA repair gene APE1 T1349G polymorphism and cancer risk: a meta-analysis of 27 case-control studies

Published data regarding the association between the apurinic/apyrimidinic endonuclease 1 (APE1) T1349G (Asp148Glu) polymorphism and cancer risk show inconclusive results. To derive a more precise estimation of the relationship, we performed a meta-analysis of 27 published studies that included 12 432 cancer cases and 17 349 controls. We used odds ratios (ORs) and 95% confidence intervals (CIs) to evaluate the strength of the associations. The overall results suggested that the variant genotypes were associated with a moderately increased risk of all cancer types (OR = 1.09, 95% CI = 1.01-1.18 for TG versus TT; OR = 1.08, 95% CI = 1.00-1.18 for GG/TG versus TT). In the stratified analyses, the risk remained for studies of colorectal cancer, European populations and population-based studies. Although some modest bias could not be eliminated, this meta-analysis supported that the APE1 T1349G polymorphism is a low-penetrance risk factor for cancer development.

Accelerated search kinetics mediated by redox reactions of DNA repair enzymes

A charge transport (CT) mechanism has been proposed in several articles to explain the localization of base excision repair (BER) enzymes to lesions on DNA. The CT mechanism relies on redox reactions of iron-sulfur cofactors that modify the enzyme's binding affinity. These redox reactions are mediated by the DNA strand and involve the exchange of electrons between BER enzymes along DNA. We propose a mathematical model that incorporates enzyme binding/unbinding, electron transport, and enzyme diffusion along DNA. Analysis of our model within a range of parameter values suggests that the redox reactions can increase desorption of BER enzymes not already bound to lesions, allowing the enzymes to be recycled--thus accelerating the overall search process. This acceleration mechanism is most effective when enzyme copy numbers and enzyme diffusivity along the DNA are small. Under such conditions, we find that CT BER enzymes find their targets more quickly than simple passive enzymes that simply attach to the DNA without desorbing.

Family cancer syndromes: inherited deficiencies in systems for the maintenance of genomic integrity

Familial cancer syndromes have revealed important fundamental features regarding how all cancers arise through destabilization of the genome, such that somatic evolution can select for the disruption of critical cellular coordinating and regulatory features. The authors examine those cellular genes and systems whose normal role is to preserve genomic integrity and relate them to the genetic foundations of heritable cancers. By examining how these cellular systems normally function, how family cancer genes are able to affect the process of tumor progression can be learned. In so doing, a clearer picture of how sporadic cancers arise is additionally gained.

Charge-transport-mediated recruitment of DNA repair enzymes

Damaged or mismatched bases in DNA can be repaired by base excision repair enzymes (BER) that replace the defective base. Although the detailed molecular structures of many BER enzymes are known, how they colocalize to lesions remains unclear. One hypothesis involves charge transport (CT) along DNA [Yavin et al., Proc. Natl. Acad. Sci. U.S.A. 102, 3546 (2005)]. In this CT mechanism, electrons are released by recently adsorbed BER enzymes and travel along the DNA. The electrons can scatter (by heterogeneities along the DNA) back to the enzyme, destabilizing and knocking it off the DNA, or they can be absorbed by nearby lesions and guanine radicals. We develop a stochastic model to describe the electron dynamics and compute probabilities of electron capture by guanine radicals and repair enzymes. We also calculate first passage times of electron return and ensemble average these results over guanine radical distributions. Our statistical results provide the rules that enable us to perform implicit-electron Monte Carlo simulations of repair enzyme binding and redistribution near lesions. When lesions are electron absorbing, we show that the CT mechanism suppresses wasteful buildup of enzymes along intact portions of the DNA, maximizing enzyme concentration near lesions.

Genetic polymorphisms in DNA base-excision repair genes ADPRT, XRCC1, and APE1 and the risk of squamous cell carcinoma of the head and neck

BACKGROUND

Tobacco smoke contains numerous carcinogens that cause DNA damage, including oxidative lesions that are removed effectively by the base-excision repair (BER) pathway, in which adenosine diphosphate ribosyl transferase (ADPRT), x-ray repair cross-complementing 1 (XRCC1), and apurinic/apyimidinic endonuclease (APE1) play key roles. Genetic variations in the genes encoding for these DNA repair enzymes may alter their functions. Although there have been several studies that generated mixed results on the association between XRCC1 variants and the risk of squamous cell carcinoma of the head and neck (SCCHN), no reported studies have investigated the association between ADPRT and APE1 variants and SCCHN risk.

METHODS

In a hospital-based, case-control study of 830 non-Hispanic white patients with SCCHN and 854 cancer-free, matched control participants, the authors genotyped the ADPRT alanine 762 valine (Ala762Val) single-nucleotide polymorphism (SNP), the XRCC1 arginine 399 glutamine (Arg399Gln) SNP, and the APE aspartic acid 148 glutamic acid (Asp148Glu) SNP and assessed their associations with the risk of SCCHN in multivariate logistic regression models.

RESULTS

The findings indicated that a significantly decreased risk of SCCHN was associated with the ADPRT 762Ala/Ala genotype (adjusted odds ratio [OR], 0.51; 95% confidence interval [95% CI], 0.27-0.97) and the combined ADPRT 762Ala/Val and Ala/Ala genotypes (OR, 0.79; 95% CI; 0.63-1.00) compared with the ADPRT 762Val/Val genotype, but no altered risk was associated with the XRCC1 Arg399Gln or APE Asp148Glu polymorphisms, and no evidence of interactions was observed between the 3 selected SNPs and age, sex, smoking status, drinking status, or tumor site.

CONCLUSIONS

The ADPRT Ala762Val polymorphism may play a role in the etiology of SCCHN or in linkage disequilibrium with other untyped protective alleles. Larger studies with more SNPs in the BER genes will be needed to verify these findings.

Unusual structural features of hydantoin lesions translate into efficient recognition by Escherichia coli Fpg

Oxidation of guanine (G) and 8-oxoguanine (OG) with a wide variety of oxidants yields the hydantoin lesions, guanidinohydantoin (Gh) and spiroiminodihydantoin (Sp). These two lesions have garnered much recent attention due to their unusual structures and high mutagenic potential. We have previously shown that duplexes containing Gh and Sp are substrates for the base excision repair glycosylase Escherichia coli Fpg (EcFpg). To evaluate the recognition features of these unusual lesions, binding and footprinting experiments were performed using a glycosylase inactive variant, E3Q EcFpg, and 30 bp duplexes containing the embedded lesions. Surprisingly, E3Q EcFpg was found to bind significantly more tightly ( approximately 1000-fold) to duplexes containing Gh or Sp over the corresponding duplexes containing OG. This may be a consequence of the helix-destabilizing nature of the hydantoin lesions that facilitates their recognition within duplex DNA. Though DNA binding affinities of E3Q EcFpg with Gh- and Sp-containing duplexes were found to be similar to each other, hydroxyl radical footprinting using methidium-propyl-EDTA (MPE)-Fe(II) revealed subtle differences between binding of E3Q EcFpg to the two lesions. Most notably, in the presence of E3Q EcFpg, the Sp nucleotide (nt) is hyperreactive toward cleavage by MPE-Fe(II)-generated hydroxyl radicals, suggestive of the formation of an intercalation site for the MPE-Fe(II) reagent at the Sp nt. Interestingly, increasing the duplex length from 18 to 30 bp enhanced the excision efficiency of Gh and Sp paired with C, G, or T by EcFpg such that these substrates are processed as efficiently as the signature substrate lesion, OG. Moreover, the base removal activity with these two lesions was more efficient than removal of OG when in a base pairing context opposite A. The high affinity and efficient activity of EcFpg toward the hydantoin lesions suggest that EcFpg mediates repair of the lesions in vivo. Notably, the facile activity of EcFpg toward Gh and Sp in base pairing contexts with G and A, which are likely to be present after DNA replication, would be detrimental and enhance mutagenesis.

Base-excision repair of oxidative DNA damage by DNA glycosylases

Oxidative damage to DNA caused by free radicals and other oxidants generate base and sugar damage, strand breaks, clustered sites, tandem lesions and DNA-protein cross-links. Oxidative DNA damage is mainly repaired by base-excision repair in living cells with the involvement of DNA glycosylases in the first step and other enzymes in subsequent steps. DNA glycosylases remove modified bases from DNA, generating an apurinic/apyrimidinic (AP) site. Some of these enzymes that remove oxidatively modified DNA bases also possess AP-lyase activity to cleave DNA at AP sites. DNA glycosylases possess varying substrate specificities, and some of them exhibit cross-activity for removal of both pyrimidine- and purine-derived lesions. Most studies on substrate specificities and excision kinetics of DNA glycosylases were performed using oligonucleotides with a single modified base incorporated at a specific position. Other studies used high-molecular weight DNA containing multiple pyrimidine- and purine-derived lesions. In this case, substrate specificities and excision kinetics were found to be different from those observed with oligonucleotides. This paper reviews substrate specificities and excision kinetics of DNA glycosylases for removal of pyrimidine- and purine-derived lesions in high-molecular weight DNA.

Mismatch repair activity in mammalian mitochondria

Mitochondrial DNA (mtDNA) defects cause debilitating metabolic disorders for which there is no effective treatment. Patients suffering from these diseases often harbour both a wild-type and a mutated subpopulation of mtDNA, a situation termed heteroplasmy. Understanding mtDNA repair mechanisms could facilitate the development of novel therapies to combat these diseases. In particular, mismatch repair activity could potentially be used to repair pathogenic mtDNA mutations existing in the heteroplasmic state if heteroduplexes could be generated. To date, however, there has been no compelling evidence for such a repair activity in mammalian mitochondria. We now report evidence consistent with a mismatch repair capability in mammalian mitochondria that exhibits some characteristics of the nuclear pathway. A repair assay utilising a nicked heteroduplex substrate with a GT or a GG mismatch in the beta-galactosidase reporter gene was used to test the repair potential of different lysates. A low level repair activity was identified in rat liver mitochondrial lysate that showed no strand bias. The activity was mismatch-selective, bi-directional, ATP-dependent and EDTA-sensitive. Western analysis using antibody to MSH2, a key nuclear mismatch repair system (MMR) protein, showed no cross-reacting species in mitochondrial lysate. A hypothesis to explain the molecular mechanism of mitochondrial MMR in the light of these observations is discussed.

Structural insights by molecular dynamics simulations into differential repair efficiency for ethano-A versus etheno-A adducts by the human alkylpurine-DNA N-glycosylase

1,N6-ethenoadenine adducts (epsilonA) are formed by known environmental carcinogens and found to be removed by human alkylpurine-DNA N-glycosylase (APNG). 1,N6-ethanoadenine (EA) adducts differ from epsilonA by change of a double bond to a single bond in the 5-member exocyclic ring and are formed by chloroethyl nitrosoureas, which are used in cancer therapy. In this work, using purified recombinant human APNG, we show that EA is a substrate for the enzyme. However, the excision efficiency of EA was 65-fold lower than that of epsilonA. Molecular dynamics simulation produced similar structural motifs for epsilonA and EA when incorporated into a DNA duplex, suggesting that there are no specific conformational features in the DNA duplex which can account for the differences in repair efficiency. However, when EA was modeled into the APNG active site, based on the APNG/epsilonA-DNA crystallographic coordinates, in structures produced by 2 ns molecular dynamics simulation, we observed weakening in the stacking interaction between EA and aromatic side chains of the key amino acids in the active site. In contrast, the planar epsilonA is better stacked at the enzyme active site. We propose that the observed destabilization of the EA adduct at the active site, such as reduced stacking interactions, could account for the biochemically observed weaker recognition of EA by APNG as compared to epsilonA.

Embryonic extracts derived from the nematode Caenorhabditis elegans remove uracil from DNA by the sequential action of uracil-DNA glycosylase and AP (apurinic/apyrimidinic) endonuclease

DNA bases continuously undergo modifications in response to endogenous reactions such as oxidation, alkylation or deamination. The modified bases are primarily removed by DNA glycosylases, which cleave the N-glycosylic bond linking the base to the sugar, to generate an apurinic/apyrimidinic (AP) site, and this latter lesion is highly mutagenic. Previously, no study has demonstrated the processing of these lesions in the nematode Caenorhabditis elegans. Herein, we report the existence of uracil-DNA glycosylase and AP endonuclease activities in extracts derived from embryos of C. elegans. These enzyme activities were monitored using a defined 5'-end (32)P-labelled 42-bp synthetic oligonucleotide substrate bearing a single uracil residue opposite guanine at position 21. The embryonic extract rapidly cleaved the substrate in a time-dependent manner to produce a 20-mer product. The extract did not excise adenine or thymine opposite guanine, although uracil opposite either adenine or thymine was processed. Addition of the highly specific inhibitor of uracil-DNA glycosylase produced by Bacillus subtilis to the extract prevented the formation of the 20-mer product, indicating that removal of uracil is catalysed by uracil-DNA glycosylase. The data suggest that the 20-mer product was generated by a sequential reaction, i.e., removal of the uracil base followed by 5'-cleavage of the AP site. Further analysis revealed that product formation was dependent upon the presence of Mg(2+), suggesting that cleavage of the AP site, following uracil excision, is carried out by a Mg(2+)-dependent AP endonuclease. It would appear that these activities correspond to the first two steps of a putative base-excision-repair pathway in C. elegans.

Mechanistic comparisons among base excision repair glycosylases

The mechanisms by which various DNA glycosylases initiate the base excision repair pathways are discussed. Fundamental distinctions are made between "simple glycosylases," that do not form DNA single-strand breaks, and "glycosylases/abasic site lyases," that do form single-strand breaks. Several groupings of BER substrate sites are defined and some interactions between these groupings and glycosylase mechanisms discussed. Two characteristics are proposed to be common among all BER glycosylases: a nucleotide flipping step that serves to expose the scissile glycosyl bond to catalysis, and a glycosylase transition state characterized by substantial tetrahedral character at the base glycosyl atom.

UV-induced DNA damage and repair: a review

Increases in ultraviolet radiation at the Earth's surface due to the depletion of the stratospheric ozone layer have recently fuelled interest in the mechanisms of various effects it might have on organisms. DNA is certainly one of the key targets for UV-induced damage in a variety of organisms ranging from bacteria to humans. UV radiation induces two of the most abundant mutagenic and cytotoxic DNA lesions such as cyclobutane-pyrimidine dimers (CPDs) and 6-4 photoproducts (6-4PPs) and their Dewar valence Isomers. However, cells have developed a number of repair or tolerance mechanism to counteract the DNA damage caused by UV or any other stressors. Photoreactivation with the help of the enzyme photolyase is one of the most important and frequently occurring repair mechanisms in a variety of organisms. Excision repair, which can be distinguished into base excision repair (BER) and nucleotide excision repair (NER), also plays an important role in DNA repair in several organisms with the help of a number of glycosylases and polymerases, respectively. In addition, mechanisms such as mutagenic repair or dimer bypass, recombinational repair, cell-cycle checkpoints, apoptosis and certain alternative repair pathways are also operative in various organisms. This review deals with UV-induced DNA damage and the associated repair mechanisms as well as methods of detecting DNA damage and its future perspectives.

DNA polymerase beta

Mammalian DNA polymerase beta(beta-pol) is a single polypeptide chain enzyme of 39kDa. beta-pol has enzymatic activities appropriate for roles in base excision repair and other DNA metabolism events involving gap-filling DNA synthesis. Many crystal structures of beta-pol complexed with dNTP and DNA substrates have been solved, and mouse fibroblast cell lines deleted in the beta-pol gene have been examined. These approaches have enhanced our understanding of structural and functional aspects of beta-pol's role in protecting genomic DNA.

Backbone dynamics of DNA containing 8-oxoguanine: importance for substrate recognition by base excision repair glycosylases

Except for the functional groups sited within the major or minor grooves, the bases of B-DNA are quite protected from the external environment. Enzymes that modify the bases often "flip out" the target into an extrahelical position before the chemistry step is carried out. Examples of this mechanism are the base excision repair glycosylases and the restriction enzyme methylases. The question arises about the mechanism of substrate recognition for these enzymes and how closely it is linked to the base flipping step. Molecular dynamics simulations (AMBER, PME electrostatics) of fully solvated, cation neutralized, DNA sequences containing 8-oxoguanine (8OG) and of appropriate normal (control) DNAs have been carried out. The dynamics trajectories were analyzed to identify those properties of the DNA structure in the vicinity of the altered base, or its dynamics, that could contribute to molecular discrimination between substrate and non-substrate DNA sites. The results predict that the FPG enzyme should flip out the cytosine base paired with the scissile 8OG, not the target base itself.

Uracil DNA glycosylase: insights from a master catalyst

The recognition and removal of damaged bases in the genome is the province of a highly specialized assemblage of enzymes known as DNA glycosylases. In recent years, structural and mechanistic studies have rapidly moved forward such that in some cases, the high-resolution structures of all stable complexes along the reaction pathway are available. In parallel, advances in isotopic labeling of DNA have allowed the determination of a transition state structure of a DNA repair glycosylase using kinetic isotope effect methods. The use of stable substrate analogs and fluorescent probes have provided methods for real time measurement of the critical step of damaged base flipping. Taken together, these synergistic structural and chemical approaches have elevated our understanding of DNA repair enzymology to the level previously attained in only a select few enzymatic systems. This review summarizes recent studies of the paradigm enzyme, uracil DNA glycosylase, and discusses future areas for investigation in this field.