Bacterial DNA repair genes and their eukaryotic homologues: 1. Mutations in genes involved in base excision repair (BER) and DNA-end processors and their implication in mutagenesis and human disease

Base excision repair (BER) pathway executed by a complex network of proteins is the major system responsible for the removal of damaged DNA bases and repair of DNA single strand breaks (SSBs) generated by environmental agents, such as certain cancer therapies, or arising spontaneously during cellular metabolism. Both modified DNA bases and SSBs with ends other than 3'-OH and 5'-P are repaired either by replacement of a single or of more nucleotides in the processes called short-patch BER (SP-BER) or long-patch BER (LP-BER), respectively. In contrast to Escherichia coli cells, in human ones, the two BER sub-pathways are operated by different sets of proteins. In this review the selection between SP- and LP-BER and mutations in BER and end-processors genes and their contribution to bacterial mutagenesis and human diseases are considered.     

The mechanism of base excision repair in Chlamydiophila pneumoniae

Repair of damaged DNA is of great importance in maintaining genome integrity, and there are several pathways for repair of damaged DNA in almost all organisms. Base excision repair (BER) is a main process for repairing DNA carrying slightly damaged bases. Several proteins are required for BER; these include DNA glycosylases, AP endonuclease, DNA polymerase, and DNA ligase. In some bacteria the single-stranded specific exonuclease, RecJ, is also involved in BER. In this research, six Chlamydiophila pneumoniae (C. pneumoniae) genes, encoding uracil DNA glycosylase (CpUDG), endonuclease IV (CpEndoIV), DNA polymerase I (CpDNApolI), endonuclease III (CpEndoIII), single-stranded specific exonuclease RecJ (CpRecJ), and DNA ligase (CpDNALig), were inserted into the expression vector pET28a. All proteins, except for CpDNALig, were successfully expressed in E. coli, and purified proteins were characterized in vitro. C. pneumoniae BER was reconstituted in vitro with CpUDG, CpEndoIV, CpDNApolI and E. coli DNA ligase (EcDNALig). After uracil removal by CpUDG, the AP site could be repaired by two BER pathways that involved in the replacement of either one (short patch BER) or multiple nucleotides (long patch BER) at the lesion site. CpEndoIII promoted short patch BER via its 5'-deoxyribophosphodiesterase (5'-dRPase) activity, while CpRecJ had little effect on short patch BER. The flap structure generated during DNA extension could be removed by the 5'-exonuclease activity of CpDNApolI. Based on these observations, we propose a probable mechanism for BER in C. pneumoniae.     

Co-ordination of base excision repair and genome stability

Base excision repair (BER) is a major DNA repair pathway employed in mammalian cells that is required to maintain genome stability, thus preventing several human diseases, such as ageing, neurodegenerative diseases and cancer. This is achieved through the repair of damaged DNA bases, sites of base loss and single strand breaks of varying complexity that are continuously induced endogenously or via exogenous mutagens. Whilst the enzymes involved in BER are now well known and characterised, the role of the co-ordination of BER enzymatic activities in the cellular response to DNA damage and the mechanisms regulating this process are only now being revealed. Post-translational modifications of BER proteins, including ubiquitylation and phosphorylation, are increasingly being identified as key processes that regulate BER. In this review we will summarise recent evidence discovering novel mechanisms that are involved in maintaining genome stability by regulation of the key BER proteins in response to DNA damage.     

Early steps in the DNA base excision/single-strand interruption repair pathway in mammalian cells

Base excision repair （BER） is an evolutionarily conserved process for maintaining genomic integrity by eliminating several dozen damaged （oxidized or aikylated） or inappropriate bases that are generated endogenously or induced by genotoxicants, predominantly, reactive oxygen species （ROS）. BER involves 4-5 steps starting with base excision by a DNA glycosylase, followed by a common pathway usually involving an AP-endonuclease （APE） to generate 3＇ OH terminus at the damage site, followed by repair synthesis with a DNA polymerase and nick sealing by a DNA iigase. This pathway is also responsible for repairing DNA single-strand breaks with blocked termini directly generated by ROS. Nearly all glycosylases, far fewer than their substrate lesions particularly for oxidized bases, have broad and overlapping substrate range, and could serve as back-up enzymes in vivo. In contrast, mammalian cells encode only one APE, APEI, unlike two APEs in lower organisms. In spite of overall similarity, BER with distinct subpathways in the mammals is more complex than in E. coli. The glycosylases form complexes with downstream proteins to carry out efficient repair via distinct subpathways one of which, responsible for repair of strand breaks with 3＇ phosphate termini generated by the NEIL family glycosylases or by ROS, requires the phosphatase activity of polynucleotide kinase instead of APE1. Different complexes may utilize distinct DNA polymerases and iigases. Mammalian glycosylases have nonconserved extensions at one of the termini, dispensable for enzymatic activity but needed for interaction with other BER and non-BER proteins for complex formation and organeile targeting. The mammalian enzymes are sometimes covalently modified which may affect activity and complex formation. The focus of this review is on the early steps in mammalian BER for oxidized damage.     

Liposome mediated drug delivery for leukocyte adhesion deficieny I （LAD I）： Targeting the mutated gene ITGB2 and expression of CD18 protein

Leukocyte adhesion deficiency （LAD） I is a disorder caused due to mutations in a gene （ITGB2） located on chromosome 21 and encodes the β2 subunit of the leukocyte integrin molecules. This leads to defects in the adhesion of leukocytes on endothelial cells which further leads to recurrent microbial infections due to a decrease in the immune response. Base Excision Repair Mechanism （BER） is instrumental in repairing damaged DNA by removing mutated/ damaged bases. We have proposed a hypothesis for the treatment of LAD I by making use of the proteins/enzyme complexes responsible for base excision repair mechanism be introduced into the leukocytes via liposomes. This will target the mutated gene in the leukocytes （mostly neutrophils） and DNA repair will occur. The liposomes can be introduced into the patients via intravenous methods.     

Extracts of proliferating and non-proliferating human cells display different base excision pathways and repair fidelity

Base excision repair (BER) of damaged or inappropriate bases in DNA has been reported to take place by single nucleotide insertion or through incorporation of several nucleotides, termed short-patch and long-patch repair, respectively. We found that extracts from proliferating and non-proliferating cells both had capacity for single- and two-nucleotide insertion BER activity. However, patch size longer than two nucleotides was only detected in extracts from proliferating cells. Relative to extracts from proliferating cells, extracts from non-proliferating cells had approximately two-fold higher concentration of POLβ, which contributed to most of two-nucleotide insertion BER. In contrast, two-nucleotide insertion in extracts from proliferating cells was not dependent on POLβ. BER fidelity was two- to three-fold lower in extracts from the non-proliferating compared with extracts of proliferating cells. Furthermore, although one-nucleotide deletion was the predominant type of repair error in both extracts, the pattern of repair errors was somewhat different. These results establish two-nucleotide patch BER as a distinct POLβ-dependent mechanism in non-proliferating cells and demonstrate that BER fidelity is lower in extracts from non-proliferating as compared with proliferating cells.     

DNA damage and repair: consequences on dose-responses

Damage to DNA is considered to be the main initiating event by which genotoxins cause hereditary effects and cancer. Single or double strand breaks, bases modifications or deletions, intra- or interstrand DNA-DNA or DNA-protein cross-links constitute the major lesions formed in different proportions according to agents and to DNA sequence context. They can result in cell death or in mutational events which in turn may initiate malignant transformation. Normal cells are able to repair these lesions with fidelity or by introducing errors. Base excision (BER) and nucleotide excision (NER) repair are error-free processes acting on the simpler forms of DNA damage. A specialized form of BER involves the removal of mismatched DNA bases occurring as errors of DNA replication or from miscoding properties of damaged bases. Severe damage will be repaired according to several types of recombinational processes: homologous, illegitimate and site-specific recombination pathways. The loss of repair capacity as seen in a number of human genetic diseases and mutant cell lines leads to hypersensitivity to environmental agents. Repair-defective cells show qualitative (mutation spectrum) and quantitative alterations in dose-effect relationships. For such repair-deficient systems, direct measurements at low doses are possible and the extrapolation from large to low doses fits well with the linear or the linear-quadratic no-threshold models. Extensive debate still takes place as to the shape of the dose-response relationships in the region at which genetic effects are not directly detectable in repair-proficient normal cells. Comparison of repair mutants and wild-type organisms pragmatically suggests that, for many genotoxins and tissues, very low doses may have no effect at all in normal cells.     

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 repair fidelity of base excision repair pathways in human cell extracts

Base excision repair (BER), responsible for the removal of altered DNA bases, is accomplished via two pathways that involve different subsets of repair enzymes and result in removal and replacement of one (short-patch BER) or several (long-patch BER) nucleotides. In this study, we constructed single-lesion containing DNA substrates that are predominantly repaired via one of the two pathways and investigated the fidelity of pathway specific repair in human whole cell extracts. We find that a single nucleotide deletion generated during addition of the first nucleotide into the repair gap is the major mutation characteristic for both pathways. This data suggest that for both BER pathways, mutations generated during repair in human whole cell extracts are principally the result of a slippage of DNA polymerase during initiation of repair synthesis.     

Targeting base excision repair to improve cancer therapies

Most commonly used cancer therapies, particularly ionizing radiation and certain classes of cytotoxic chemotherapies, cause cell death by damaging DNA. Base excision repair (BER) is the major system responsible for the removal of corrupt DNA bases and repair of DNA single strand breaks generated spontaneously and induced by exogenous DNA damaging factors such as certain cancer therapies. In this review, the physico-chemical properties of the proteins involved in BER are discussed with particular emphasis on molecular mechanisms coordinating repair processes. The aim of this review is to apply extensive knowledge that currently exists regarding the biochemical mechanisms involved in human BER to the molecular biology of current therapies for cancer. It is anticipated that the application of this knowledge will translate into the development of novel effective therapies for improving existing treatments such as radiation therapy and oxaliplatin chemotherapy.     

DNA base repair – recognition and initiation of catalysis

Endogenous DNA damage induced by hydrolysis, reactive oxygen species and alkylation modifies DNA bases and the structure of the DNA duplex. Numerous mechanisms have evolved to protect cells from these deleterious effects. Base excision repair is the major pathway for removing base lesions. However, several mechanisms of direct base damage reversal, involving enzymes such as transferases, photolyases and oxidative demethylases, are specialized to remove certain types of photoproducts and alkylated bases. Mismatch excision repair corrects for misincorporation of bases by replicative DNA polymerases. The determination of the 3D structure and visualization of DNA repair proteins and their interactions with damaged DNA have considerably aided our understanding of the molecular basis for DNA base lesion repair and genome stability. Here, we review the structural biochemistry of base lesion recognition and initiation of one-step direct reversal (DR) of damage as well as the multistep pathways of base excision repair (BER), nucleotide incision repair (NIR) and mismatch repair (MMR).     

CHIP-mediated degradation and DNA damage-dependent stabilization regulate base excision repair proteins

Base excision repair (BER) is the major pathway for processing of simple lesions in DNA, including single-strand breaks, base damage, and base loss. The scaffold protein XRCC1, DNA polymerase beta, and DNA ligase IIIalpha play pivotal roles in BER. Although all these enzymes are essential for development, their cellular levels must be tightly regulated because increased amounts of BER enzymes lead to elevated mutagenesis and genetic instability and are frequently found in cancer cells. Here we report that BER enzyme levels are linked to and controlled by the level of DNA lesions. We demonstrate that stability of BER enzymes increases after formation of a repair complex on damaged DNA and that proteins not involved in a repair complex are ubiquitylated by the E3 ubiquitin ligase CHIP and subsequently rapidly degraded. These data identify a molecular mechanism controlling cellular levels of BER enzymes and correspondingly the efficiency and capacity of BER.     

Base excision repair and its role in maintaining genome stability

For all living organisms, genome stability is important, but is also under constant threat because various environmental and endogenous damaging agents can modify the structural properties of DNA bases. As a defense, organisms have developed different DNA repair pathways. Base excision repair (BER) is the predominant pathway for coping with a broad range of small lesions resulting from oxidation, alkylation, and deamination, which modify individual bases without large effect on the double helix structure. As, in mammalian cells, this damage is estimated to account daily for 10(4) events per cell, the need for BER pathways is unquestionable. The damage-specific removal is carried out by a considerable group of enzymes, designated as DNA glycosylases. Each DNA glycosylase has its unique specificity and many of them are ubiquitous in microorganisms, mammals, and plants. Here, we review the importance of the BER pathway and we focus on the different roles of DNA glycosylases in various organisms.     

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.     

Base excision repair

Damage to DNA bases resulting from deamination, oxidation, and alkylation is mainly repaired by base-excision repair. BER is initiated by DNA glycosylases, which recognize damaged bases and excise them from DNA by hydrolyzing the N-glycosidic bond between the base and the sugar phosphate backbone of DNA to generate an abasic site. Different human and E. coli DNA glycosylases have been cloned and characterized, each one with unique substrate specificity. Some of them additionally have AP lyase activity, which enables them to cleave the bond between the sugar and phosphate 3' to the damaged site. BER consist of two repair pathways (short or long) in which one or more nucleotides are introduced respectively. In conclusion, it seems to be likely that BER pathways are essential for genomic repair and stability in living cells.     

Base J, found in nuclear DNA of Trypanosoma brucei, is not a target for DNA glycosylases

Base excision repair (BER) is an evolutionarily conserved system which removes altered bases from DNA. The initial step in BER is carried out by DNA glycosylases which recognize altered bases and cut the N-glycosylic bond between the base and the DNA backbone. In kinetoplastid flagellates, such as Trypanosoma brucei, the modified base beta-D-glucosyl-hydroxymethyluracil (J) replaces a small percentage of thymine residues, predominantly in repetitive telomeric sequences. Base J is synthesized at the DNA level via the precursor 5-hydroxymethyluracil (5-HmU). We have investigated whether J in DNA can be recognized by DNA glycosylases from non-kinetoplastid origin, and whether the presence of J and 5-HmU in DNA has required modifications of the trypanosome BER system. We tested the ability of 15 different DNA glycosylases from various origins to excise J or 5-HmU paired to A from duplex oligonucleotides. No excision of J was found, but 5-HmU was excised by AlkA and Mug from Escherichia coli and by human SMUG1 and TDG, confirming previous reports. In a combination of database searches and biochemical assays we identified several DNA glycosylases in T. brucei, but in trypanosome extracts we detected no excision activity towards 5-HmU or ethenocytosine, a product of oxidative DNA damage and a substrate for Mug, TDG and SMUG1. Our results indicate that trypanosomes have a BER system similar to that of other organisms, but might be unable to excise certain forms of oxidatively damaged bases. The presence of J in DNA does not require a specific modification of the BER system, as this base is not recognized by any known DNA glycosylase.     

DNA synthesis and dRPase activities of polymerase beta are both essential for single-nucleotide patch base excision repair in mammalian cell extracts

In mammalian cells the majority of altered bases in DNA are processed through a single-nucleotide patch base excision repair mechanism. Base excision repair is initiated by a DNA glycosylase that removes a damaged base and generates an abasic site (AP site). This AP site is further processed by an AP endonuclease activity that incises the phosphodiester bond adjacent to the AP site and generates a strand break containing 3'-OH and 5'-sugar phosphate ends. In mammalian cells, the 5'-sugar phosphate is removed by the AP lyase activity of DNA polymerase beta (Pol beta). The same enzyme also fills the gap, and the DNA ends are finally rejoined by DNA ligase. We measured repair of oligonucleotide substrates containing a single AP site in cell extracts prepared from normal and Pol beta-null mouse cells and show that the reduced repair in Pol beta-null extracts can be complemented by addition of purified Pol beta. Using this complementation assay, we demonstrate that mutated Pol beta without dRPase activity is able to stimulate long patch BER. Mutant Pol beta deficient in DNA synthesis, but with normal dRPase activity, does not stimulate repair in Pol beta-null cells. However, under conditions where we measure base excision repair accomplished exclusively through a single-nucleotide patch BER, neither dRPase nor DNA synthesis mutants of Pol beta alone, or the two together, were able to complement the repair defect. These data suggest that the dRPase and DNA synthesis activities of Pol beta are coupled and that both of these Pol beta functions are essential during short patch BER and cannot be efficiently substituted by other cellular enzymes.     

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.     

The novel DNA glycosylase,NEIL1, protects mammalian cells from radiation-mediated cell death

DNA damage mediated by reactive oxygen species generates miscoding and blocking lesions that may lead to mutations or cell death. Base excision repair (BER) constitutes a universal mechanism for removing oxidatively damaged bases and restoring the integrity of genomic DNA. In Escherichia coli, the DNA glycosylases Nei, Fpg, and Nth initiate BER of oxidative lesions; OGG1 and NTH1 proteins fulfill a similar function in mammalian cells. Three human genes, designated NEIL1, NEIL2 and NEIL3, encode proteins that contain sequence homologies to Nei and Fpg. We have cloned the corresponding mouse genes and have overexpressed and purified mNeil1, a DNA glycosylase that efficiently removes a wide spectrum of mutagenic and cytotoxic DNA lesions. These lesions include the two cis-thymineglycol(Tg) stereoisomers, guanine- and adenine-derived formamidopyrimidines, and 5,6-dihydrouracil. Two of these lesions, fapyA and 5S,6R thymine glycol, are not excised by mOgg1 or mNth1. We have also used RNA interference technology to establish embryonic stem cell lines deficient in Neil1 protein and showed them to be sensitive to low levels of gamma-irradiation. The results of these studies suggest that Neil1 is an essential component of base excision repair in mammalian cells; its presence may contribute to the redundant repair capacity observed in Ogg1 -/- and Nth1 -/- mice.