Properties of damage-dependent DNA incision by nucleotide excision repair in human cell-free extracts.

Nucleotide excision repair (NER) is the primary mechanism for the removal of many lesions from DNA. This repair process can be broadly divided in two stages: first, incision at damaged sites and second, synthesis of new DNA to replace the oligonucleotide removed by excision. In order to dissect the repair mechanism, we have recently devised a method to analyze the incision reaction in vitro in the absence of repair synthesis (1). Damage-specific incisions take place in a repair reaction in which mammalian cell-free extracts are mixed with undamaged and damaged plasmids. Most of the incision events are accompanied by excision. Using this assay, we investigated here various parameters that specifically affect the level of damage-dependent incision activity by cell-free extracts in vitro. We have defined optimal conditions for the reaction and determined the kinetics of the incision with cell-free extracts from human cells. We present direct evidence that the incision step of NER is ATP-dependent. In addition, we observe that Mn2+ but no other divalent cation can substitute for Mg2+ in the incision reaction.     

DNA ligation during excision repair in yeast cell-free extracts is specifically catalyzed by the CDC9 gene product

Excision repair of DNA is an important cellular response to DNA damage induced by radiation and many chemicals. In eukaryotes, base excision repair (BER) and nucleotide excision repair (NER) are two major excision repair pathways which are completed by a DNA ligation step. Using a cell-free system, we have determined the DNA ligase requirement during BER and NER of the yeast S. cerevisiae. Under nonpermissive conditions in extracts of the cdc9-2 temperature-sensitive mutant, DNA ligation in both BER and NER pathways was defective, and the repair patches were enlarged. At the permissive temperature (23 degrees C), DNA ligation during excision repair was only partially functional in the mutant extracts. In contrast, deleting the DNA ligase IV gene did not affect DNA ligation of BER or NER. Defective DNA ligation of BER and NER in cdc9-2 mutant extracts was complemented in vitro by purified yeast Cdc9 protein, but not by DNA ligase IV even when overexpressed. These results demonstrate that the ligation step of excision repair in yeast cell-free extracts is catalyzed specifically by the Cdc9 protein, the homologue of mammalian DNA ligase I.     

Roles of exonucleases and translesion synthesis DNA polymerases during mitotic gap repair in yeast

Transformation-based gap-repair assays have long been used to model the repair of mitotic double-strand breaks (DSBs) by homologous recombination in yeast. In the current study, we examine genetic requirements of two key processes involved in DSB repair: (1) the processive 5′-end resection that is required to efficiently engage a repair template and (2) the filling of resected ends by DNA polymerases. The specific gap-repair assay used allows repair events resolved as crossover versus noncrossover products to be distinguished, as well as the extent of heteroduplex DNA formed during recombination to be measured. To examine end resection, the efficiency and outcome of gap repair were monitored in the absence of the Exo1 exonuclease and the Sgs1 helicase. We found that either Exo1 or Sgs1 presence is sufficient to inhibit gap-repair efficiency over 10-fold, consistent with resection-mediated destruction of the introduced plasmid. In terms of DNA polymerase requirements for gap repair, we focused specifically on potential roles of the Pol ζ and Pol η translesion synthesis DNA polymerases. We found that both Pol ζ and Pol η are necessary for efficient gap repair and that each functions independently of the other. These polymerases may be involved either in the initiation of DNA synthesis from the an invading end, or in a gap-filling process that is required to complete recombination.     

DNA tandem lesion repair by strand displacement synthesis and nucleotide excision repair

DNA tandem lesions are comprised of two contiguously damaged nucleotides. This subset of clustered lesions is produced by a variety of oxidizing agents, including ionizing radiation. Clustered lesions can inhibit base excision repair (BER). We report the effects of tandem lesions composed of a thymine glycol and a 5'-adjacent 2-deoxyribonolactone (LTg) or tetrahydrofuran abasic site (FTg). Some BER enzymes that act on the respective isolated lesions do not accept the tandem lesion as a substrate. For instance, endonuclease III (Nth) does not excise thymine glycol (Tg) when it is part of either tandem lesion. Similarly, endonuclease IV (Nfo) does not incise L or F when they are in tandem with Tg. Long-patch BER overcomes inhibition by the tandem lesion. DNA polymerase beta (Pol beta) carries out strand displacement synthesis, following APE1 incision of the abasic site. Pol beta activity is enhanced by flap endonuclease (FEN1), which cleaves the resulting flap. The tandem lesion is also incised by the bacterial nucleotide excision repair system UvrABC with almost the same efficiency as an isolated Tg. These data reveal two solutions that DNA repair systems can use to counteract the formation of tandem lesions.     

DNA damage recognition during nucleotide excision repair in mammalian cells

For the bulk of mammalian DNA, the core protein factors needed for damage recognition and incision during nucleotide excision repair (NER) are the XPA protein, the heterotrimeric RPA protein, the 6 to 9-subunit TFIIH, the XPC-hHR23B complex, the XPG nuclease, and the ERCC1-XPF nuclease. With varying efficiencies, NER can repair a very wide range of DNA adducts, from bulky helical distortions to subtle modifications on sugar residues. Several of the NER factors have an affinity for damaged DNA. The strongest binding factor appears to be XPC-hHR23B but preferential binding to damage is also a property of XPA, RPA, and components of TFIIH. It appears that in order to be repaired by NER, an adduct in DNA must have two features: it must create a helical distortion, and there must be a change in DNA chemistry. Initial recognition of the distortion is the most likely function for XPC-hHR23B and perhaps XPA and RPA, whereas TFIIH is well-suited to locate the damaged DNA strand by locating altered DNA chemistry that blocks translocation of the XPB and XPD components.     

DNA repair in a yeast origin of replication: contributions of photolyase and nucleotide excision repair

DNA damage formation and repair are tightly linked to protein–DNA interactions in chromatin. We have used minichromosomes in yeast as chromatin substrates in vivo to investigate how nucleotide excision repair (NER) and repair by DNA-photolyase (photoreactivation) remove pyrimidine dimers from an origin of replication (ARS1). The ARS1 region is nuclease sensitive and flanked by nucleosomes on both sides. Photoreactivation was generally faster than NER at all sites. Site-specific heterogeneity of repair was observed for both pathways. This heterogeneity was different for NER and photoreactivation and it was altered in a minichromosome where ARS1 was transcribed. The results indicate distinct interactions of the repair systems with protein complexes bound in the ARS region (ORC, Abf1) and a predominant role of photolyase in CPD repair of an origin of replication.     

Long-patch DNA repair synthesis during base excision repair in mammalian cells

The base excision repair (BER) process removes base damage such as oxidation, alkylation or abasic sites. Two BER sub-pathways have been characterized using in vitro methods, and have been classified according to the length of the repair patch as either 'short-patch' BER (one nucleotide) or 'long-patch' BER (LP-BER; more than one nucleotide). To investigate the occurrence of LP-BER in vivo, we developed an assay using a plasmid containing a single modified base in the transcribed strand of the enhanced green fluorescent protein (EGFP) gene and a stop codon, based on a single-nucleotide mismatch, at varying distances on the 3' side of the lesion. The reversion of the stop codon occurs after DNA repair synthesis and restores EGFP expression after transfection of mismatch-repair-deficient cells. Repair patches longer than one nucleotide were observed for 55-80% or 80-100% of the plasmids with a mean length of 2-6 or 6-12 nucleotides for 8-oxo-7,8-dihydroguanine or a synthetic abasic site, respectively. These data show the existence of LP-BER in vivo, and emphasize the effect of the type of BER substrate lesion on both the yield and the extent of the LP-BER sub-pathway.     

Damage recognition in nucleotide excision DNA repair

Nucleotide excision repair (NER) is a highly versatile DNA repair process. Its ability to repair a large number of different damages with the same subset of recognition factors requires structural tools for damage recognition that are both broad and very accurate. Over the past few years detailed structural information on damage recognition factors from eukaryotic and prokaryotic NER has emerged. These structures shed light on the toolkit utilized in the damage recognition process and help explain the broad substrate specificity of NER.     

Contribution of base excision repair, nucleotide excision repair, and DNA recombination to alkylation resistance of the fission yeast Schizosaccharomyces pombe

DNA damage is unavoidable, and organisms across the evolutionary spectrum possess DNA repair pathways that are critical for cell viability and genomic stability. To understand the role of base excision repair (BER) in protecting eukaryotic cells against alkylating agents, we generated Schizosaccharomyces pombe strains mutant for the mag1 3-methyladenine DNA glycosylase gene. We report that S. pombe mag1 mutants have only a slightly increased sensitivity to methylation damage, suggesting that Mag1-initiated BER plays a surprisingly minor role in alkylation resistance in this organism. We go on to show that other DNA repair pathways play a larger role than BER in alkylation resistance. Mutations in genes involved in nucleotide excision repair (rad13) and recombinational repair (rhp51) are much more alkylation sensitive than mag1 mutants. In addition, S. pombe mutant for the flap endonuclease rad2 gene, whose precise function in DNA repair is unclear, were also more alkylation sensitive than mag1 mutants. Further, mag1 and rad13 interact synergistically for alkylation resistance, and mag1 and rhp51 display a surprisingly complex genetic interaction. A model for the role of BER in the generation of alkylation-induced DNA strand breaks in S. pombe is discussed.     

Damage recognition in nucleotide excision repair of DNA

Nucleotide excision repair (NER) is found throughout nature, in eubacteria, eukaryotes and archaea. In human cells it is the main pathway for the removal of damage caused by UV light, but it also acts on a wide variety of other bulky helix-distorting lesions caused by chemical mutagens. An ongoing challenge is to understand how a site of DNA damage is located during NER and distinguished from non-damaged sites. This article reviews information on damage recognition in mammalian cells and the bacterium Escherichia coli. In mammalian cells the XPC-hHR23B, XPA, RPA and TFIIH factors may all have a role in damage recognition. XPC-hHR23B has the strongest affinity for damaged DNA in some assays, as does the similar budding yeast complex Rad4-Rad23. There is current discussion as to whether XPC or XPA acts first in the repair process to recognise damage or distortions. TFIIH may play a role in distinguishing the damaged strand from the non-damaged one, if translocation along a DNA strand by the TFIIH DNA helicases is interrupted by encountering a lesion. The recognition and incision steps of human NER use 15 to 18 polypeptides, whereas E. coli requires only three proteins to obtain a similar result. Despite this, many remarkable similarities in the NER mechanism have emerged between eukaryotes and bacteria. These include use of a distortion-recognition factor, a strand separating helicase to create an open preincision complex, participation of structure-specific endonucleases and the lack of a need for certain factors when a region containing damage is already sufficiently distorted.     

DNA interstrand crosslink repair during G1 involves nucleotide excision repair and DNA polymerase zeta

The repair mechanisms acting on DNA interstrand crosslinks (ICLs) in eukaryotes are poorly understood. Here, we provide evidence for a pathway of ICL processing that uses components from both nucleotide excision repair (NER) and translesion synthesis (TLS) and predominates during the G1 phase of the yeast cell cycle. Our results suggest that repair is initiated by the NER apparatus and is followed by a thwarted attempt at gap-filling by the replicative Polymerase delta, which likely stalls at the site of the remaining crosslinked oligonucleotide. This in turn leads to ubiquitination of PCNA and recruitment of the damage-tolerant Polymerase zeta that can perform TLS. The ICL repair factor Pso2 acts downstream of the incision step and is not required for Polymerase zeta activation. We show that this combination of NER and TLS is the only pathway of ICL repair available to the cell in G1 phase and is essential for viability in the presence of DNA crosslinks.     

Chromatin rearrangements during nucleotide excision repair

The removal of DNA damage from the eukaryotic genome requires DNA repair enzymes to operate within the complex environment of chromatin. We review the evidence for chromatin rearrangements during nucleotide excision repair and discuss the extent and possible molecular mechanisms of these rearrangements, focusing on events at the nucleosome level of chromatin structure.     

Base excision repair: AP endonucleases and DNA polymerases

The DNA base lesions in living cells occur permanently and with high frequency as a result of the action of exogenous and endogenous factors. The main mechanism providing removal of such lesions is base excision repair.     

Cdt2-mediated XPG degradation promotes gap-filling DNA synthesis in nucleotide excision repair

Xeroderma pigmentosum group G (XPG) protein is a structure-specific repair endonuclease, which cleaves DNA strands on the 3′ side of the DNA damage during nucleotide excision repair (NER). XPG also plays a crucial role in initiating DNA repair synthesis through recruitment of PCNA to the repair sites. However, the fate of XPG protein subsequent to the excision of DNA damage has remained unresolved. Here, we show that XPG, following its action on bulky lesions resulting from exposures to UV irradiation and cisplatin, is subjected to proteasome-mediated proteolytic degradation. Productive NER processing is required for XPG degradation as both UV and cisplatin treatment-induced XPG degradation is compromised in NER-deficient XP-A, XP-B, XP-C, and XP-F cells. In addition, the NER-related XPG degradation requires Cdt2, a component of an E3 ubiquitin ligase, CRL4^Cdt2. Micropore local UV irradiation and in situ Proximity Ligation assays demonstrated that Cdt2 is recruited to the UV-damage sites and interacts with XPG in the presence of PCNA. Importantly, Cdt2-mediated XPG degradation is crucial to the subsequent recruitment of DNA polymerase δ and DNA repair synthesis. Collectively, our data support the idea of PCNA recruitment to damage sites which occurs in conjunction with XPG, recognition of the PCNA-bound XPG by CRL4^Cdt2 for specific ubiquitylation and finally the protein degradation. In essence, XPG elimination from DNA damage sites clears the chromatin space needed for the subsequent recruitment of DNA polymerase δ to the damage site and completion of gap-filling DNA synthesis during the final stage of NER.     

Cdt2-mediated XPG degradation promotes gap-filling DNA synthesis in nucleotide excision repair

Xeroderma pigmentosum group G (XPG) protein is a structure-specific repair endonuclease, which cleaves DNA strands on the 3′ side of the DNA damage during nucleotide excision repair (NER). XPG also plays a crucial role in initiating DNA repair synthesis through recruitment of PCNA to the repair sites. However, the fate of XPG protein subsequent to the excision of DNA damage has remained unresolved. Here, we show that XPG, following its action on bulky lesions resulting from exposures to UV irradiation and cisplatin, is subjected to proteasome-mediated proteolytic degradation. Productive NER processing is required for XPG degradation as both UV and cisplatin treatment-induced XPG degradation is compromised in NER-deficient XP-A, XP-B, XP-C, and XP-F cells. In addition, the NER-related XPG degradation requires Cdt2, a component of an E3 ubiquitin ligase, CRL4^Cdt2. Micropore local UV irradiation and in situ Proximity Ligation assays demonstrated that Cdt2 is recruited to the UV-damage sites and interacts with XPG in the presence of PCNA. Importantly, Cdt2-mediated XPG degradation is crucial to the subsequent recruitment of DNA polymerase δ and DNA repair synthesis. Collectively, our data support the idea of PCNA recruitment to damage sites which occurs in conjunction with XPG, recognition of the PCNA-bound XPG by CRL4^Cdt2 for specific ubiquitylation and finally the protein degradation. In essence, XPG elimination from DNA damage sites clears the chromatin space needed for the subsequent recruitment of DNA polymerase δ to the damage site and completion of gap-filling DNA synthesis during the final stage of NER.     

Roles of Rad23 protein in yeast nucleotide excision repair

Nucleotide excision repair (NER) removes many different types of DNA lesions. Most NER proteins are indispensable for repair. In contrast, the yeast Rad23 represents a class of accessory NER proteins, without which NER activity is reduced but not eliminated. In mammals, the complex of HR23B (Rad23 homolog) and XPC (yeast Rad4 homolog) has been suggested to function in the damage recognition step of NER. However, the precise function of Rad23 or HR23B in NER remains unknown. Recently, it was suggested that the primary function of RAD23 protein in NER is its stabilization of XPC protein. Here, we tested the significance of Rad23-mediated Rad4 stabilization in NER, and analyzed the repair and biochemical activities of purified yeast Rad23 protein. Cellular Rad4 was indeed stabilized by Rad23 in the absence of DNA damage. Persistent overexpression of Rad4 in rad23 mutant cells, however, largely failed to complement the ultraviolet sensitivity of the mutant. Consistently, deficient NER in rad23 mutant cell extracts could not be complemented by purified Rad4 protein in vitro. In contrast, partial complementation was observed with purified Rad23 protein. Specific complementation to the level of wild-type repair was achieved by adding purified Rad23 together with small amounts of Rad4 protein to rad23 mutant cell extracts. Purified Rad23 protein was unable to bind to DNA, but stimulated the binding activity of purified Rad4 protein to N-acetyl-2-aminofluorene-damaged DNA. These results support two roles of Rad23 protein in NER: (i) its direct participation in the repair biochemistry, possibly due to its stimulatory activity on Rad4-mediated damage binding/recognition; and (ii) its stabilization of cellular Rad4 protein.