Nucleotide excision repair or polymerase V-mediated lesion bypass can act to restore UV-arrested replication forks in Escherichia coli

Nucleotide excision repair and translesion DNA synthesis are two processes that operate at arrested replication forks to reduce the frequency of recombination and promote cell survival following UV-induced DNA damage. While nucleotide excision repair is generally considered to be error free, translesion synthesis can result in mutations, making it important to identify the order and conditions that determine when each process is recruited to the arrested fork. We show here that at early times following UV irradiation, the recovery of DNA synthesis occurs through nucleotide excision repair of the lesion. In the absence of repair or when the repair capacity of the cell has been exceeded, translesion synthesis by polymerase V (Pol V) allows DNA synthesis to resume and is required to protect the arrested replication fork from degradation. Pol II and Pol IV do not contribute detectably to survival, mutagenesis, or restoration of DNA synthesis, suggesting that, in vivo, these polymerases are not functionally redundant with Pol V at UV-induced lesions. We discuss a model in which cells first use DNA repair to process replication-arresting UV lesions before resorting to mutagenic pathways such as translesion DNA synthesis to bypass these impediments to replication progression.     

Asymmetry of DNA replication and translesion synthesis of UV-induced thymine dimers

In vitro replication assays for detection and quantification of bypass of UV-induced DNA photoproducts were used to compare the capacity of extracts prepared from different human cell lines to replicate past the cis,syn cyclobutane thymine dimer ([c,s]TT). The results demonstrated that neither nucleotide excision repair (NER) nor mismatch repair (MMR) activities in the intact cells interfered with measurements of bypass replication efficiencies in vitro. Extracts prepared from HeLa (NER- and MMR-proficient), xeroderma pigmentosum group A (NER-deficient), and HCT116 (MMR-deficient) cells displayed similar capacity for translesion synthesis, when the substrate carried the site-specific [c,s]TT on the template for the leading or the lagging strand of nascent DNA. Extracts from xeroderma pigmentosum variant cells, which lack DNA polymerase eta, were devoid of bypass activity. Bypass-proficient extracts as a group (n=16 for 3 extracts) displayed higher efficiency (P=0.005) for replication past the [c,s]TT during leading strand synthesis (84+/-22%) than during lagging strand synthesis (64+/-13%). These findings are compared to previous results concerning the bypass of the (6-4) photoproduct [Biochemistry 40 (2001) 15215] and analyzed in the context of the reported characteristics of bypass DNA polymerases implicated in translesion synthesis of UV-induced DNA lesions. Models to explain how these enzymes might interact with the DNA replication machinery are considered. An alternative pathway of bypass replication, which avoids translesion synthesis, and the mutagenic potential of post-replication repair mechanisms that contribute to the duplication of the human genome damaged by UV are discussed.     

Surviving the sun: repair and bypass of DNA UV lesions

Structural studies of UV-induced lesions and their complexes with repair proteins reveal an intrinsic flexibility of DNA at lesion sites. Reduced DNA rigidity stems primarily from the loss of base stacking, which may manifest as bending, unwinding, base unstacking, or flipping out. The intrinsic flexibility at UV lesions allows efficient initial lesion recognition within a pool of millions to billions of normal DNA base pairs. To bypass the damaged site by translesion synthesis, the specialized DNA polymerase η acts like a molecular "splint" and reinforces B-form DNA by numerous protein-phosphate interactions. Photolyases and glycosylases that specifically repair UV lesions interact directly with UV lesions in bent DNA via surface complementation. UvrA and UvrB, which recognize a variety of lesions in the bacterial nucleotide excision repair pathway, appear to exploit hysteresis exhibited by DNA lesions and conduct an ATP-dependent stress test to distort and separate DNA strands. Similar stress tests are likely conducted in eukaryotic nucleotide excision repair.     

Repair of DNA Damage Induced by Solar UV

Solar UV radiation induces significant levels of DNA damage in living things. This damage, if left unrepaired, is lethal in humans. Recent work has demonstrated that plants possess several repair pathways for UV-induced DNA damage, including pathways for the photoreactivation of both 6-4 products and cyclobutane pyrimidine dimers (CPDs), the two lesions most frequently induced by UV. Plants also possess the more general nucleotide excision repair (NER) pathway as well as bypass polymerases that enable the plant to replicate its DNA in the absence of DNA repair.This revised version was published online in October 2005 with corrections to the Cover Date.     

DNA damage response and cancer therapeutics through the lens of the Fanconi Anemia DNA repair pathway

Fanconi Anemia (FA) is a rare, inherited genomic instability disorder, caused by mutations in genes involved in the repair of interstrand DNA crosslinks (ICLs). The FA signaling network contains a unique nuclear protein complex that mediates the monoubiquitylation of the FANCD2 and FANCI heterodimer, and coordinates activities of the downstream DNA repair pathway including nucleotide excision repair, translesion synthesis, and homologous recombination. FA proteins act at different steps of ICL repair in sensing, recognition and processing of DNA lesions. The multi-protein network is tightly regulated by complex mechanisms, such as ubiquitination, phosphorylation, and degradation signals that are critical for the maintenance of genome integrity and suppressing tumorigenesis. Here, we discuss recent advances in our understanding of how the FA proteins participate in ICL repair and regulation of the FA signaling network that assures the safeguard of the genome. We further discuss the potential application of designing small molecule inhibitors that inhibit the FA pathway and are synthetic lethal with DNA repair enzymes that can be used for cancer therapeutics.     

Genetic interactions of DNA repair pathways in the pathogen Neisseria meningitidis

The current increase in the incidence and severity of infectious diseases mandates improved understanding of the basic biology and DNA repair profiles of virulent microbes. In our studies of the major pathogen and model organism Neisseria meningitidis, we constructed a panel of mutants inactivating genes involved in base excision repair, mismatch repair, nucleotide excision repair (NER), translesion synthesis, and recombinational repair pathways. The highest spontaneous mutation frequency among the N. meningitidis single mutants was found in the MutY-deficient strain as opposed to mutS mutants in Escherichia coli, indicating a role for meningococcal MutY in antibiotic resistance development. Recombinational repair was recognized as a major pathway counteracting methyl methanesulfonate-induced alkylation damage in the N. meningitidis. In contrast to what has been shown in other species, meningococcal NER did not contribute significantly to repair of alkylation-induced DNA damage, and meningococcal recombinational repair may thus be one of the main pathways for removal of abasic (apurinic/apyrimidinic) sites and strand breaks in DNA. Conversely, NER was identified as the main meningococcal defense pathway against UV-induced DNA damage. N. meningitidis RecA single mutants exhibited only a moderate decrease in survival after UV exposure as opposed to E. coli recA strains, which are extremely UV sensitive, possibly reflecting the lack of a meningococcal SOS response. In conclusion, distinct differences between N. meningitidis and established DNA repair characteristics in E. coli and other species were identified.     

C. elegans FANCD2 responds to replication stress and functions in interstrand cross-link repair

One of the least well understood DNA repair processes in cells is the repair of DNA interstrand cross-links (ICLs) which present a major obstacle to DNA replication and must be repaired or bypassed to allow fork progression. Fanconi anemia (FA) is an inherited genome instability syndrome characterized by hypersensitivity to ICL damage. Central to the FA repair pathway is FANCD2 that is mono-ubiquitylated in response to replication stress and ICL damage through the action of the FA core complex and its E3-ubiquitin ligase subunit, FANCL. In its mono-ubiquitylated form FANCD2 is recruited to repair foci where it is believed to somehow coordinate ICL repair and restart of impeded replication forks. However, the precise mechanism through which the FA pathway and mono-ubiquitylation of FANCD2 promotes ICL repair remains unclear. Here we report on a functional homologue of FANCD2 in C. elegans (FCD-2). Although fcd-2 mutants are homozygous viable, they are exquisitely sensitive to ICL-inducing agents, but insensitive to ionizing radiation (IR). fcd-2 is dispensable for meiotic recombination and activation of the S-phase checkpoint, indicating that ICL sensitivity is likely due to a repair rather than a signalling defect. Indeed, we show that FCD-2 is mono-ubiquitylated in response to ICL damage and is recruited to nuclear repair foci. Consistent with the sensitivity of fcd-2 mutants, FCD-2 focus formation is induced in response to ICL damage and replication stress, but not following IR, suggesting that FCD-2 responds to lesions that block DNA replication and not DNA double strand breaks per se. The realization that the FA pathway is conserved in a genetically tractable model system will permit the comprehensive analysis of the interplay between the FA, homologous recombination (HR), translesion synthesis (TLS) and nucleotide excision repair (NER) pathways, critical to the understanding of ICL repair.     

DNA polymerase I-mediated translesion synthesis in RecA-independent DNA interstrand cross-link repair in E. coli

DNA interstrand cross-links (ICLs) are mainly repaired by the combined action of nucleotide excision repair and homologous recombination in E. coli. Genetic data also suggest the existence of a nucleotide excision repair-dependent, homologous recombination-independent ICL repair pathway. The involvement of translesion synthesis in this pathway has been postulated; however, the molecular mechanism of this pathway is not understood. To examine the role of translesion synthesis in ICL repair, we generated a defined substrate with a single psoralen ICL that mimics a postincision structure generated by nucleotide excision repair. We demonstrated that the Klenow fragment (DNA polymerase I) performs translesion synthesis on this model substrate. This in vitro translesion synthesis assay will help in understanding the basic mechanism of a postincision translesion synthesis process in ICL repair.     

DNA polymerase zeta introduces multiple mutations when bypassing spontaneous DNA damage in Saccharomyces cerevisiae

Spontaneous DNA damage can be dealt with by multiple repair/bypass pathways that have overlapping specificities. We have used a frameshift reversion assay to examine spontaneous mutations that accumulate in yeast strains defective for the high-fidelity nucleotide excision repair or recombination pathways. In contrast to the simple frameshift mutations that occur in wild-type strains, the reversion events in mutant strains are often complex in nature, with the selected frameshift mutation being accompanied by one or more base substitutions. Genetic analyses demonstrate that the complex events are dependent on the Pol zeta translesion polymerase, thus implicating the DNA damage bypass activity of low-fidelity translesion polymerases in hypermutation phenomena.     

Mutations in the Gene Encoding the E2 Conjugating Enzyme UBE2T Cause Fanconi Anemia

Fanconi anemia (FA) is a rare genetic disorder characterized by genome instability, increased cancer susceptibility, progressive bone marrow failure (BMF), and various developmental abnormalities resulting from the defective FA pathway. FA is caused by mutations in genes that mediate repair processes of interstrand crosslinks and/or DNA adducts generated by endogenous aldehydes. The UBE2T E2 ubiquitin conjugating enzyme acts in FANCD2/FANCI monoubiquitination, a critical event in the pathway. Here we identified two unrelated FA-affected individuals, each harboring biallelic mutations in UBE2T. They both produced a defective UBE2T protein with the same missense alteration (p.Gln2Glu) that abolished FANCD2 monoubiquitination and interaction with FANCL. We suggest this FA complementation group be named FA-T.     

Caffeine delays replication fork progression and enhances UV-induced homologous recombination in Chinese hamster cell lines

The ability to bypass DNA lesions encountered during replication is important in order to maintain cell viability and avoid genomic instability. Exposure of mammalian cells to UV-irradiation induces the formation of DNA lesions that stall replication forks. In order to restore replication, different bypass mechanisms are operating, previously named post-replication repair. Translesion DNA synthesis is performed by low-fidelity polymerases, which can replicate across damaged sites. The nature of lesions and of polymerases involved influences the resulting frequency of mutations. Homologous recombination represents an alternative pathway for the rescue of stalled replication forks. Caffeine has long been recognized to influence post-replication repair, although the mechanism is not identified. Here, we found that caffeine delays the progress of replication forks in UV-irradiated Chinese hamster cells. The length of this enhanced delay was similar in wild-type cells and in cell deficient in either homologous recombination or nucleotide excision repair. Furthermore, caffeine attenuated the frequency of UV-induced mutations in the hprt gene, whereas the frequency of recombination, monitored in this same gene, was enhanced. These observations indicate that in cells exposed to UV-light, caffeine inhibits the rescue of stalled replication forks by translesion DNA synthesis, thereby causing a switch to bypass via homologous recombination. The biological consequence of the former pathway is mutations, while the latter results in chromosomal aberrations.     

The nucleotide excision repair pathway is required for UV-C-induced apoptosis in Caenorhabditis elegans

Ultraviolet (UV) radiation is a mutagen of major clinical importance in humans. UV-induced damage activates multiple signaling pathways, which initiate DNA repair, cell cycle arrest and apoptosis. To better understand these pathways, we studied the responses to UV-C light (254 nm) of germ cells in Caenorhabditis elegans. We found that UV activates the same cellular responses in worms as in mammalian cells. Both UV-induced apoptosis and cell cycle arrest were completely dependent on the p53 homolog CEP-1, the checkpoint proteins HUS-1 and CLK-2, and the checkpoint kinases CHK-2 and ATL-1 (the C. elegans homolog of ataxia telangiectasia and Rad3-related); ATM-1 (ataxia telangiectasia mutated-1) was also required, but only at low irradiation doses. Importantly, mutation of genes encoding nucleotide excision repair pathway components severely disrupted both apoptosis and cell cycle arrest, suggesting that these genes not only participate in repair, but also signal the presence of damage to downstream components of the UV response pathway that we delineate here. Our study suggests that whereas DNA damage response pathways are conserved in metazoans in their general outline, there is significant evolution in the relative importance of individual checkpoint genes in the response to specific types of DNA damage.     

Uv- and Gamma-Radiation Sensitive Mutants of Arabidopsis Thaliana

Arabidopsis seedlings repair UV-induced DNA damage via light-dependent and -independent pathways. The mechanism of the ``dark repair' pathway is still unknown. To determine the number of genes required for dark repair and to investigate the substrate-specificity of this process we isolated mutants with enhanced sensitivity to UV radiation in the absence of photoreactivating light. Seven independently derived UV sensitive mutants were isolated from an EMS-mutagenized population. These fell into six complementation groups, two of which (UVR1 and UVH1) have previously been defined. Four of these mutants are defective in the dark repair of UV-induced pyrimidine [6-4] pyrimidinone dimers. These four mutant lines are sensitive to the growth-inhibitory effects of gamma radiation, suggesting that this repair pathway is also involved in the repair of some type of gamma-induced DNA damage product. The requirement for the coordinate action of several different gene products for effective repair of pyrimidine dimers, as well as the nonspecific nature of the repair activity, is consistent with nucleotide excision repair mechanisms previously described in Saccharomyces cerevisiae and nonplant higher eukaryotes and inconsistent with substrate-specific base excision repair mechanisms found in some bacteria, bacteriophage, and fungi.     

范可尼贫血与泛素化

Fanconi贫血是一种罕见的隐性遗传性疾病,临床常以先天性畸形、进行性骨髓衰竭和遗传性肿瘤倾向为主要表现而确诊。FA病人细胞对DNA交联剂如丝裂霉素C (MMC)高度敏感。目前已经发现至少12种FA基因的缺失或突变能够引起FA表型的出现,其中10种相应的编码蛋白形成FA复合物共同参与FA/BRCA2 DNA损伤修复途径—FA途径。FA核心复合物蛋白FANCL具有泛素连接酶活性,在结合酶UBE2T共同作用下,催化下游蛋白FANCD2单泛化,泛素化FANCD2与BRCA2形成新的复合物,修复DNA损伤。去泛素化酶USP1在DNA修复完毕后移除FANCD2的单体泛素,使因损伤修复而阻滞的细胞周期继续进行。机体很可能在不同信号通路对FANCD2泛素化/去泛素化的精细调节下,调控FA途径参与不同的DNA修复过程。     

Two budding yeast RAD4 homologs in fission yeast play different roles in the repair of UV-induced DNA damage

We have identified two fission yeast homologs of budding yeast Rad4 and human xeroderma pigmentosum complementation group C (XP-C) correcting protein, designated Rhp4A and Rhp4B. Here we show that the rhp4 genes encode NER factors that are required for UV-induced DNA damage repair in fission yeast. The rhp4A-deficient cells but not the rhp4B-deficient cells are sensitive to UV irradiation. However, the disruption of both rhp4A and rhp4B resulted in UV sensitivity that was greater than that of the rhp4A-deficient cells, revealing that Rhp4B plays a role in DNA repair on its own. Fission yeast has two pathways to repair photolesions on DNA, namely, nucleotide excision repair (NER) and UV-damaged DNA endonuclease-dependent excision repair (UVER). Studies with the NER-deficient rad13 and the UVER-deficient (Delta)uvde mutants showed the two rhp4 genes are involved in NER and not UVER. Assessment of the ability of the various mutants to remove cyclobutane pyrimidine dimers (CPDs) from the rbp2 gene locus indicated that Rhp4A is involved in the preferential repair of lesions on the transcribed DNA strand and plays the major role in fission yeast NER. Rhp4B in contrast acts as an accessory protein in non-transcribed strand (NTS) repair.     

DNA Repair Mechanisms and the Bypass of DNA Damage in Saccharomyces cerevisiae

DNA repair mechanisms are critical for maintaining the integrity of genomic DNA, and their loss is associated with cancer predisposition syndromes. Studies in Saccharomyces cerevisiae have played a central role in elucidating the highly conserved mechanisms that promote eukaryotic genome stability. This review will focus on repair mechanisms that involve excision of a single strand from duplex DNA with the intact, complementary strand serving as a template to fill the resulting gap. These mechanisms are of two general types: those that remove damage from DNA and those that repair errors made during DNA synthesis. The major DNA-damage repair pathways are base excision repair and nucleotide excision repair, which, in the most simple terms, are distinguished by the extent of single-strand DNA removed together with the lesion. Mistakes made by DNA polymerases are corrected by the mismatch repair pathway, which also corrects mismatches generated when single strands of non-identical duplexes are exchanged during homologous recombination. In addition to the true repair pathways, the postreplication repair pathway allows lesions or structural aberrations that block replicative DNA polymerases to be tolerated. There are two bypass mechanisms: an error-free mechanism that involves a switch to an undamaged template for synthesis past the lesion and an error-prone mechanism that utilizes specialized translesion synthesis DNA polymerases to directly synthesize DNA across the lesion. A high level of functional redundancy exists among the pathways that deal with lesions, which minimizes the detrimental effects of endogenous and exogenous DNA damage.