Single‐nucleotide and long‐patch base excision repair of DNA damage in plants

Base excision repair (BER) is a critical pathway in cellular defense against endogenous or exogenous DNA damage. This elaborate multistep process is initiated by DNA glycosylases that excise the damaged base, and continues through the concerted action of additional proteins that finally restore DNA to the unmodified state. BER has been subject to detailed biochemical analysis in bacteria, yeast and animals, mainly through in vitro reproduction of the entire repair reaction in cell‐free extracts. However, an understanding of this repair pathway in plants has consistently lagged behind. We report the extension of BER biochemical analysis to plants, using Arabidopsis cell extracts to monitor repair of DNA base damage in vitro. We have used this system to demonstrate that Arabidopsis cell extracts contain the enzymatic machinery required to completely repair ubiquitous DNA lesions, such as uracil and abasic (AP) sites. Our results reveal that AP sites generated after uracil excision are processed both by AP endonucleases and AP lyases, generating either 5′‐ or 3′‐blocked ends, respectively. We have also found that gap filling and ligation may proceed either through insertion of just one nucleotide (short‐patch BER) or several nucleotides (long‐patch BER). This experimental system should prove useful in the biochemical and genetic dissection of BER in plants, and contribute to provide a broader picture of the evolution and biological relevance of DNA repair pathways.     

Apn1 and Apn2 endonucleases prevent accumulation of repair-associated DNA breaks in budding yeast as revealed by direct chromosomal analysis

Base excision repair (BER) provides relief from many DNA lesions. While BER enzymes have been characterized biochemically, BER functions within cells are much less understood, in part because replication bypass and double-strand break (DSB) repair can also impact resistance to base damage. To investigate BER in vivo, we examined the repair of methyl methanesulfonate (MMS) induced DNA damage in haploid G1 yeast cells, so that replication bypass and recombinational DSB repair cannot occur. Based on the heat-lability of MMS-induced base damage, an assay was developed that monitors secondary breaks in full-length yeast chromosomes where closely spaced breaks yield DSBs that are observed by pulsed-field gel electrophoresis. The assay detects damaged bases and abasic (AP) sites as heat-dependent breaks as well as intermediate heat-independent breaks that arise during BER. Using a circular chromosome, lesion frequency and repair kinetics could be easily determined. Monitoring BER in single and multiple glycosylase and AP-endonuclease mutants confirmed that Mag1 is the major enzyme that removes MMS-damaged bases. This approach provided direct physical evidence that Apn1 and Apn2 not only repair cellular base damage but also prevent break accumulation that can result from AP sites being channeled into other BER pathway(s).     

DNA base excision repair in human malaria parasites is predominantly by a long-patch pathway

Mammalian cells repair apurinic/apyrimidinic (AP) sites in DNA by two distinct pathways: a polymerase beta (pol beta)-dependent, short- (one nucleotide) patch base excision repair (BER) pathway, which is the major route, and a PCNA-dependent, long- (several nucleotide) patch BER pathway. The ability of a cell-free lysate prepared from asexual Plasmodium falciparum malaria parasites to remove uracil and repair AP sites in a variety of DNA substrates was investigated. We found that the lysate contained uracil DNA glycosylase, AP endonuclease, DNA polymerase, flap endonuclease, and DNA ligase activities. This cell-free lysate effectively repaired a regular or synthetic AP site on a covalently closed circular (ccc) duplex plasmid molecule or a long (382 bp), linear duplex DNA fragment, or a regular or reduced AP site in short (28 bp), duplex oligonucleotides. Repair of the AP sites in the various DNA substrates involved a long-patch BER pathway. This biology is different from mammalian cells, yeast, Xenopus, and Escherichia coli, which predominantly repair AP sites by a one-nucleotide patch BER pathway. The apparent absence of a short-patch BER pathway in P. falciparum may provide opportunities to develop antimalarial chemotherapeutic strategies for selectively damaging the parasites in vivo and will allow the characterization of the long-patch BER pathway without having to knock-out or inactivate a short-patch BER pathway, which is necessary in mammalian cells.     

XRCC1 interactions with base excision repair DNA intermediates

Abasic (AP) sites in DNA arise either spontaneously, or through glycosylase-catalyzed excision of damaged bases. Their removal by the base excision repair (BER) pathway avoids their mutagenic and cytotoxic consequences. XRCC1 coordinates and facilitates single-strand break (SSB) repair and BER in mammalian cells. We report that XRCC1, through its NTD and BRCT1 domains, has affinity for several DNA intermediates in BER. As shown by its capacity to form a covalent complex via Schiff base, XRCC1 binds AP sites. APE1 suppresses binding of XRCC1 to unincised AP sites however, affinity was higher when the DNA carried an AP-lyase- or APE1-incised AP site. The AP site binding capacity of XRCC1 is enhanced by the presence of strand interruptions in the opposite strand. Binding of XRCC1 to BER DNA intermediates could play an important role to warrant the accurate repair of damaged bases, AP sites or SSBs, in particular in the context of clustered DNA damage.     

Roles of base excision repair subpathways in correcting oxidized abasic sites in DNA

Base excision DNA repair (BER) is fundamentally important in handling diverse lesions produced as a result of the intrinsic instability of DNA or by various endogenous and exogenous reactive species. Defects in the BER process have been associated with cancer susceptibility and neurodegenerative disorders. BER funnels diverse base lesions into a common intermediate, apurinic/apyrimidinic (AP) sites. The repair of AP sites is initiated by the major human AP endonuclease, Ape1, or by AP lyase activities associated with some DNA glycosylases. Subsequent steps follow either of two distinct BER subpathways distinguished by repair DNA synthesis of either a single nucleotide (short-patch BER) or multiple nucleotides (long-patch BER). As the major repair mode for regular AP sites, the short-patch BER pathway removes the incised AP lesion, a 5'-deoxyribose-5-phosphate moiety, and replaces a single nucleotide using DNA polymerase (Polbeta). However, short-patch BER may have difficulty handling some types of lesions, as shown for the C1'-oxidized abasic residue, 2-deoxyribonolactone (dL). Recent work indicates that dL is processed efficiently by Ape1, but that short-patch BER is derailed by the formation of stable covalent crosslinks between Ape1-incised dL and Polbeta. The long-patch BER subpathway effectively removes dL and thereby prevents the formation of DNA-protein crosslinks. In coping with dL, the cellular choice of BER subpathway may either completely repair the lesion, or complicate the repair process by forming a protein-DNA crosslink.     

A general role of the DNA glycosylase Nth1 in the abasic sites cleavage step of base excision repair in Schizosaccharomyces pombe

One of the most frequent lesions formed in cellular DNA are abasic (apurinic/apyrimidinic, AP) sites that are both cytotoxic and mutagenic, and must be removed efficiently to maintain genetic stability. It is generally believed that the repair of AP sites is initiated by the AP endonucleases; however, an alternative pathway seems to prevail in Schizosaccharomyces pombe. A mutant lacking the DNA glycosylase/AP lyase Nth1 is very sensitive to the alkylating agent methyl methanesulfonate (MMS), suggesting a role for Nth1 in base excision repair (BER) of alkylation damage. Here, we have further evaluated the role of Nth1 and the second putative S.pombe AP endonuclease Apn2, in abasic site repair. The deletion of the apn2 open reading frame dramatically increased the sensitivity of the yeast cells to MMS, also demonstrating that the Apn2 has an important function in the BER pathway. The deletion of nth1 in the apn2 mutant strain partially relieves the MMS sensitivity of the apn2 single mutant, indicating that the Apn2 and Nth1 act in the same pathway for the repair of abasic sites. Analysis of the AP site cleavage in whole cell extracts of wild-type and mutant strains showed that the AP lyase activity of Nth1 represents the major AP site incision activity in vitro. Assays with DNA substrates containing base lesions removed by monofunctional DNA glycosylases Udg and MutY showed that Nth1 will also cleave the abasic sites formed by these enzymes and thus act downstream of these enzymes in the BER pathway. We suggest that the main function of Apn2 in BER is to remove the resulting 3′-blocking termini following AP lyase cleavage by Nth1.     

Deletion of the MAG1 DNA glycosylase gene suppresses alkylation-induced killing and mutagenesis in yeast cells lacking AP endonucleases.

DNA base excision repair (BER) is initiated by DNA glycosylases that recognize and remove damaged bases. The phosphate backbone adjacent to the resulting apurinic/apyrimidinic (AP) site is then cleaved by an AP endonuclease or glycosylase-associated AP lyase to invoke subsequent BER steps. We have used a genetic approach in Saccharomyces cerevisiae to address whether AP sites are blocks to DNA replication and the biological consequences if AP sites persist in the genome. We found that yeast cells deficient in the two AP endonucleases (apn1 apn2 double mutant) are extremely sensitive to killing by methyl methanesulfonate (MMS), a model DNA alkylating agent. Interestingly, this sensitivity can be reduced up to 2500-fold by deleting the MAG1 3-methyladenine DNA glycosylase gene, suggesting that Mag1 not only removes lethal base lesions, but also benign lesions and possibly normal bases, and that the resulting AP sites are highly toxic to the cells. This rescuing effect appears to be specific for DNA alkylation damage, since the mag1 mutation reduces killing effects of two other DNA alkylating agents, but does not alter the sensitivity of apn cells to killing by UV, gamma-ray or H(2)O(2). Our mutagenesis assays indicate that nearly half of spontaneous and almost all MMS-induced mutations in the AP endonuclease-deficient cells are due to Mag1 DNA glycosylase activity. Although the DNA replication apparatus appears to be incapable of replicating past AP sites, Polzeta-mediated translesion synthesis is able to bypass AP sites, and accounts for all spontaneous and MMS-induced mutagenesis in the AP endonuclease-deficient cells. These results allow us to delineate base lesion flow within the BER pathway and link AP sites to other DNA damage repair and tolerance pathways.     

Replication protein A stimulates proliferating cell nuclear antigen-dependent repair of abasic sites in DNA by human cell extracts.

Base excision repair (BER) pathway is the major cellular process for removal of endogenous base lesions and apurinic/apyrimidinic (AP) sites in DNA. There are two base excision repair subpathways in mammalian cells, characterized by the number of nucleotides synthesized into the excision patch. They are the "single-nucleotide" (one nucleotide incorporated) and the "long-patch" (several nucleotides incorporated) BER pathways. Proliferating cell nuclear antigen (PCNA) is known to be an essential factor in long-patch base excision repair. We have studied the role of replication protein A (RPA) in PCNA-dependent, long-patch BER of AP sites in human cell extracts. PCNA and RPA were separated from the other BER proteins by fractionation of human whole-cell extract on a phosphocellulose column. The protein fraction PC-FII (phosphocellulose fraction II), which does not contain RPA and PCNA but otherwise contains all core BER proteins required for PCNA-dependent BER (AP endonuclease, DNA polymerases delta, beta and DNA ligase, and FEN1 endonuclease), had reduced ability to repair plasmid DNA containing AP sites. Purified PCNA or RPA, when added separately, could only partially restore the PC-FII repair activity of AP sites. However, additions of both proteins together greatly stimulated AP site repair by PC-FII. These results demonstrate a role for RPA in PCNA-dependent BER of AP sites.     

DNA repair in plant mitochondria – a complete base excision repair pathway in potato tuber mitochondria

Mitochondria are one of the major sites of reactive oxygen species (ROS) production in the plant cell. ROS can damage DNA, and this damage is in many organisms mainly repaired by the base excision repair (BER) pathway. We know very little about DNA repair in plants especially in the mitochondria. Combining proteomics, bioinformatics, western blot and enzyme assays, we here demonstrate that the complete BER pathway is found in mitochondria isolated from potato (Solanum tuberosum) tubers. The enzyme activities of three DNA glycosylases and an apurinic/apyrimidinic (AP) endonuclease (APE) were characterized with respect to Mg²⁺ dependence and, in the case of the APE, temperature sensitivity. Evidence for the presence of the DNA polymerase and the DNA ligase, which complete the repair pathway by replacing the excised base and closing the gap, was also obtained. We tested the effect of oxidative stress on the mitochondrial BER pathway by incubating potato tubers under hypoxia. Protein carbonylation increased significantly in hypoxic tuber mitochondria indicative of increased oxidative stress. The activity of two BER enzymes increased significantly in response to this oxidative stress consistent with the role of the BER pathway in the repair of oxidative damage to mitochondrial DNA.     

Arabidopsis ARP endonuclease functions in a branched base excision DNA repair pathway completed by LIG1

Base excision repair (BER) is an essential cellular defence mechanism against DNA damage, but it is poorly understood in plants. We used an assay that monitors repair of damaged bases and abasic (apurinic/apyrimidinic, AP) sites in Arabidopsis to characterize post-excision events during plant BER. We found that Apurinic endonuclease-redox protein (ARP) is the major AP endonuclease activity in Arabidopsis cell extracts, and is required for AP incision during uracil BER in vitro. Mutant plants that are deficient in ARP grow normally but are hypersensitive to 5-fluorouracil, a compound that favours mis-incorporation of uracil into DNA. We also found that, after AP incision, the choice between single-nucleotide or long-patch DNA synthesis (SN- or LP-BER) is influenced by the 5' end of the repair gap. When the 5' end is blocked and not amenable to β-elimination, the SN sub-pathway is abrogated, and repair is accomplished through LP-BER only. Finally, we provide evidence that Arabidopsis DNA ligase I (LIG1) is required for both SN- and LP-BER. lig1 RNAi-silenced lines show very reduced uracil BER, and anti-LIG1 antibody abolishes repair in wild-type cell extracts. In contrast, knockout lig4(-/-) mutants exhibit normal BER and nick ligation levels. Our results suggest that a branched BER pathway completed by a member of the DNA ligase I family may be an ancient feature in eukaryotic species.     

Variation in base excision repair capacity

The major DNA repair pathway for coping with spontaneous forms of DNA damage, such as natural hydrolytic products or oxidative lesions, is base excision repair (BER). In particular, BER processes mutagenic and cytotoxic DNA lesions such as non-bulky base modifications, abasic sites, and a range of chemically distinct single-strand breaks. Defects in BER have been linked to cancer predisposition, neurodegenerative disorders, and immunodeficiency. Recent data indicate a large degree of sequence variability in DNA repair genes and several studies have associated BER gene polymorphisms with disease risk, including cancer of several sites. The intent of this review is to describe the range of BER capacity among individuals and the functional consequences of BER genetic variants. We also discuss studies that associate BER deficiency with disease risk and the current state of BER capacity measurement assays.     

HMGA2 exhibits dRP/AP site cleavage activity and protects cancer cells from DNA-damage-induced cytotoxicity during chemotherapy

HMGA proteins are not translated in normal human somatic cells, but are present in high copy numbers in pluripotent embryonic stem cells and most neoplasias. Correlations between the degree of malignancy, patient prognostic index and HMGA levels have been firmly established. Intriguingly, HMGA2 is also found in rare tumor-inducing cells which are resistant to chemotherapy. Here, we demonstrate that HMGA1a/b and HMGA2 possess intrinsic dRP and AP site cleavage activities, and that lysines and arginines in the AT-hook DNA-binding domains function as nucleophiles. We also show that HMGA2 can be covalently trapped at genomic abasic sites in cancer cells. By employing a variety of cell-based assays, we provide evidence that the associated lyase activities promote cellular resistance against DNA damage that is targeted by base excision repair (BER) pathways, and that this protection directly correlates with the level of HMGA2 expression. In addition, we demonstrate an interaction between human AP endonuclease 1 and HMGA2 in cancer cells, which supports our conclusion that HMGA2 can be incorporated into the cellular BER machinery. Our study thus identifies an unexpected role for HMGA2 in DNA repair in cancer cells which has important clinical implications for disease diagnosis and therapy.     

DNA repair in neurons: So if they don’t divide what's to repair?

Neuronal DNA repair remains one of the most exciting areas for investigation, particularly as a means to compare the DNA repair response in mitotic (cancer) vs. post-mitotic (neuronal) cells. In addition, the role of DNA repair in neuronal cell survival and response to aging and environmental insults is of particular interest. DNA damage caused by reactive oxygen species (ROS) such as generated by mitochondrial respiration includes altered bases, abasic sites, and single- and double-strand breaks which can be prevented by the DNA base excision repair (BER) pathway. Oxidative stress accumulates in the DNA of the human brain over time especially in the mitochondrial DNA (mtDNA) and is proposed to play a critical role in aging and in the pathogenesis of several neurological disorders including Parkinson's disease, ALS, and Alzheimer's diseases. Because DNA damage accumulates in the mtDNA more than nuclear DNA, there is increased interest in DNA repair pathways and the consequence of DNA damage in the mitochondria of neurons. The type of damage that is most likely to occur in neuronal cells is oxidative DNA damage which is primarily removed by the BER pathway. Following the notion that the bulk of neuronal DNA damage is acquired by oxidative DNA damage and ROS, the BER pathway is a likely area of focus for neuronal studies of DNA repair. BER variations in brain aging and pathology in various brain regions and tissues are presented. Therefore, the BER pathway is discussed in greater detail in this review than other repair pathways. Other repair pathways including direct reversal, nucleotide excision repair (NER), mismatch repair (MMR), homologous recombination and non-homologous end joining are also discussed. Finally, there is a growing interest in the role that DNA repair pathways play in the clinical arena as they relate to the neurotoxicity and neuropathy associated with cancer treatments. Among the numerous side effects of cancer treatments, major clinical effects include neurocognitive dysfunction and peripheral neuropathy. These symptoms occur frequently and have not been effectively studied at the cellular or molecular level. Studies of DNA repair may help our understanding of how those cells that are not dividing could succumb to neurotoxicity with the clinical manifestations discussed in the following article.     

Cellular markers based on DNA damage and repair (BER, MMR), expression of MLHI, MSH2, FasR, and cell death of lymphocytes as predictive parameters for clinical response to chemotherapy of melanoma

Melanoma is a highly aggressive neoplastic disease attributed to transformed melanocytes. The efficacy of regimens of cytotoxic chemotherapy for advanced stage patients does not exceed 20%. Search for lymphocyte markers of patients' sensitivity to chemotherapy provides a rational basis for development of cytotoxic chemotherapy. Using blood lymphocytes we evaluated efficacy of BER and MMR, expression of MLH1, MSH2 and FasR, and cell death in melanoma patients relative to clinical response to chemotherapy. We found that LDCI-chemotherapy (lomustine, dacarbazine, cisplatin and interferon gamma), induced AP sites and DNA ss-breaks which repaired trough BER pathway. However, neither initial DNA damage nor the rate of their repair correlated with clinical response. This result prompts us to think that this type of damage is not crucial in cytotoxic effect of LDCI-regimen of chemotherapy. DNA ds-breakes appeared downstream ss-breakes were attributed to repair of 06-methylguanine by MMR mechanism in PHA-stimulated lymphocytes. The number of ds-breakes appeared by 48 correlated with positive clinical response of patients to chemotherapy. The same link was observed between clinical response and the number of dead lymphocytes. However, there was no correlation between clinical response and expression of MLHI + MSH2 and FasR. These results imply possible contribution of crosslink repair through NER pathway to formation of DNA ds-breaks as well as to cytotoxicity of LDCl-therapy. The observed link between high level of secondary ds-breaks and positive response to chemotherapy indicates the potential of these instruments to serve as prognostic end point in clinical trials.     

Second pathway for completion of human DNA base excision-repair: reconstitution with purified proteins and requirement for DNase IV (FEN1).

Two forms of DNA base excision-repair (BER) have been observed: a 'short-patch' BER pathway involving replacement of one nucleotide and a 'long-patch' BER pathway with gap-filling of several nucleotides. The latter mode of repair has been investigated using human cell-free extracts or purified proteins. Correction of a regular abasic site in DNA mainly involves incorporation of a single nucleotide, whereas repair patches of two to six nucleotides in length were found after repair of a reduced or oxidized abasic site. Human AP endonuclease, DNA polymerase beta and a DNA ligase (either III or I) were sufficient for the repair of a regular AP site. In contrast, the structure-specific nuclease DNase IV (FEN1) was essential for repair of a reduced AP site, which occurred through the long-patch BER pathway. DNase IV was required for cleavage of a reaction intermediate generated by template strand displacement during gap-filling. XPG, a related nuclease, could not substitute for DNase IV. The long-patch BER pathway was largely dependent on DNA polymerase beta in cell extracts, but the reaction could be reconstituted with either DNA polymerase beta or delta. Efficient repair of gamma-ray-induced oxidized AP sites in plasmid DNA also required DNase IV. PCNA could promote the Pol beta-dependent long-patch pathway by stimulation of DNase IV.     

A quantitative model of human DNA base excision repair. I. Mechanistic insights

Base excision repair (BER) is a multistep process involving the sequential activity of several proteins that cope with spontaneous and environmentally induced mutagenic and cytotoxic DNA damage. Quantitative kinetic data on single proteins of BER have been used here to develop a mathematical model of the BER pathway. This model was then employed to evaluate mechanistic issues and to determine the sensitivity of pathway throughput to altered enzyme kinetics. Notably, the model predicts considerably less pathway throughput than observed in experimental in vitro assays. This finding, in combination with the effects of pathway cooperativity on model throughput, supports the hypothesis of cooperation during abasic site repair and between the apurinic/apyrimidinic (AP) endonuclease, Ape1, and the 8-oxoguanine DNA glycosylase, Ogg1. The quantitative model also predicts that for 8-oxoguanine and hydrolytic AP site damage, short-patch Polβ-mediated BER dominates, with minimal switching to the long-patch subpathway. Sensitivity analysis of the model indicates that the Polβ-catalyzed reactions have the most control over pathway throughput, although other BER reactions contribute to pathway efficiency as well. The studies within represent a first step in a developing effort to create a predictive model for BER cellular capacity.     

The adduct formation between the thioguanine-polyamine ligands and DNA with the AP site under UVA irradiated and non-irradiated conditions

The AP sites are representative of DNA damage and known as an intermediate in the base excision repair (BER) pathway which is involved in the repair of damaged nucleobases by reactive oxygen species, UVA irradiation, and DNA alkylating agents. Therefore, it is expected that the inhibition or modulation of the AP site repair pathway may be a new type of anticancer drug. In this study, we investigated the effects of the thioguanine-polyamine ligands (^SG-ligands) on the affinity and the reactivity for the AP site under UVA irradiated and non-irradiated conditions. The ^SG-ligands have a photo-reactivity with the A-F-C sequence where F represents a tetrahydrofuran AP site analogue. Interestingly, the ^SG-ligands promoted the β-elimination of the AP site followed by the formation of a covalent bond with the β-eliminated fragment without UVA irradiation.