Nucleotide excision repair in chromatin and the right of entry

Collateral Victim or Rescue Worker?-The Role of Histone Methyltransferases in DNA Damage Repair and Their Targeting for Therapeutic Opportunities in Cancer

Disrupted DNA damage signaling greatly threatens cell integrity and plays significant roles in cancer. With recent advances in understanding the human genome and gene regulation in the context of DNA damage, chromatin biology, specifically biology of histone post-translational modifications (PTMs), has emerged as a popular field of study with great promise for cancer therapeutics. Here, we discuss how key histone methylation pathways contribute to DNA damage repair and impact tumorigenesis within this context, as well as the potential for their targeting as part of therapeutic strategies in cancer.

Nucleotide excision repair leaves a mark on chromatin: DNA damage detection in nucleosomes

Global genome nucleotide excision repair (GG-NER) eliminates a broad spectrum of DNA lesions from genomic DNA. Genomic DNA is tightly wrapped around histones creating a barrier for DNA repair proteins to access DNA lesions buried in nucleosomal DNA. The DNA-damage sensors XPC and DDB2 recognize DNA lesions in nucleosomal DNA and initiate repair. The emerging view is that a tight interplay between XPC and DDB2 is regulated by post-translational modifications on the damage sensors themselves as well as on chromatin containing DNA lesions. The choreography between XPC and DDB2, their interconnection with post-translational modifications such as ubiquitylation, SUMOylation, methylation, poly(ADP-ribos)ylation, acetylation, and the functional links with chromatin remodelling activities regulate not only the initial recognition of DNA lesions in nucleosomes, but also the downstream recruitment and necessary displacement of GG-NER factors as repair progresses. In this review, we highlight how nucleotide excision repair leaves a mark on chromatin to enable DNA damage detection in nucleosomes.

Focus on UV-Induced DNA Damage and Repair-Disease Relevance and Protective Strategies

The protective ozone layer is continually depleting due to the release of deteriorating environmental pollutants. The diminished ozone layer contributes to excessive exposure of cells to ultraviolet (UV) radiation. This leads to various cellular responses utilized to restore the homeostasis of exposed cells. DNA is the primary chromophore of the cells that absorbs sunlight energy. Exposure of genomic DNA to UV light leads to the formation of multitude of types of damage (depending on wavelength and exposure time) that are removed by effectively working repair pathways. The aim of this review is to summarize current knowledge considering cellular response to UV radiation with special focus on DNA damage and repair and to give a comprehensive insight for new researchers in this field. We also highlight most important future prospects considering application of the progressing knowledge of UV response for the clinical control of diverse pathologies.

Damage sensor role of UV-DDB during base excision repair

UV-DDB, a key protein in human global nucleotide excision repair (NER), binds avidly to abasic sites and 8-oxo-guanine (8-oxoG), suggesting a noncanonical role in base excision repair (BER). We investigated whether UV-DDB can stimulate BER for these two common forms of DNA damage, 8-oxoG and abasic sites, which are repaired by 8-oxoguanine glycosylase (OGG1) and apurinic/apyrimidinic endonuclease (APE1), respectively. UV-DDB increased both OGG1 and APE1 strand cleavage and stimulated subsequent DNA polymerase β-gap filling activity by 30-fold. Single-molecule real-time imaging revealed that UV-DDB forms transient complexes with OGG1 or APE1, facilitating their dissociation from DNA. Furthermore, UV-DDB moves to sites of 8-oxoG repair in cells, and UV-DDB depletion sensitizes cells to oxidative DNA damage. We propose that UV-DDB is a general sensor of DNA damage in both NER and BER pathways, facilitating damage recognition in the context of chromatin.

Genome-wide mapping of nucleotide excision repair with XR-seq

Nucleotide excision repair is a versatile mechanism to repair a variety of bulky DNA adducts. We developed excision repair sequencing (XR-seq) to study nucleotide excision repair of DNA adducts in humans, mice, Arabidopsis thaliana, yeast and Escherichia coli. In this protocol, the excised oligomers, generated in the nucleotide excision repair reaction, are isolated by cell lysis and fractionation, followed by immunoprecipitation with damage- or repair factor-specific antibodies from the non-chromatin fraction. The single-stranded excised oligomers are ligated to adapters and re-immunoprecipitated with damage-specific antibodies. The DNA damage in the excised oligomers is then reversed by enzymatic or chemical reactions before being converted into a sequencing library by PCR amplification. Alternatively, the excised oligomers containing DNA damage, especially those containing irreversible DNA damage such as benzo[a]pyrene-induced DNA adducts, can be converted to a double-stranded DNA (dsDNA) form by using appropriate translesion DNA synthesis (TLS) polymerases and then can be amplified by PCR. The current genome-wide approaches for studying repair measure the loss of damage signal with time, which limits their resolution. By contrast, an advantage of XR-seq is that the repair signal is directly detected above a background of zero. An XR-seq library using the protocol described here can be obtained in 7-9 d.

Nucleotide Excision Repair and Impact of Site-Specific 5',8-Cyclopurine and Bulky DNA Lesions on the Physical Properties of Nucleosomes

The nonbulky 5',8-cyclopurine DNA lesions (cP) and the bulky, benzo[ a]pyrene diol epoxide-derived stereoisomeric cis- and trans- N2-guanine adducts (BPDE-dG) are good substrates of the human nucleotide excision repair (NER) mechanism. These DNA lesions were embedded at the In or Out rotational settings near the dyad axis in nucleosome core particles reconstituted either with native histones extracted from HeLa cells (HeLa-NCP) or with recombinant histones (Rec-NCP). The cP lesions are completely resistant to NER in human HeLa cell extracts. The BPDE-dG adducts are also NER-resistant in Rec-NCPs but are good substrates of NER in HeLa-NCPs. The four BPDE-dG adduct samples are excised with different efficiencies in free DNA, but in HeLa-NCPs, the efficiencies are reduced by a common factor of 2.2 ± 0.2 relative to the NER efficiencies in free DNA. The NER response of the BPDE-dG adducts in HeLa-NCPs is not directly correlated with the observed differences in the thermodynamic destabilization of HeLa-NCPs, the Förster resonance energy transfer values, or hydroxyl radical footprint patterns and is weakly dependent on the rotational settings. These and other observations suggest that NER is initiated by the binding of the DNA damage-sensing NER factor XPC-RAD23B to a transiently opened BPDE-modified DNA sequence that corresponds to the known footprint of XPC-DNA-RAD23B complexes (≥30 bp). These observations are consistent with the hypothesis that post-translational modifications and the dimensions and properties of the DNA lesions are the major factors that have an impact on the dynamics and initiation of NER in nucleosomes.

DNA damage sensitivity of SWI/SNF-deficient cells depends on TFIIH subunit p62/GTF2H1

Mutations in SWI/SNF genes are amongst the most common across all human cancers, but efficient therapeutic approaches that exploit vulnerabilities caused by SWI/SNF mutations are currently lacking. Here, we show that the SWI/SNF ATPases BRM/SMARCA2 and BRG1/SMARCA4 promote the expression of p62/GTF2H1, a core subunit of the transcription factor IIH (TFIIH) complex. Inactivation of either ATPase subunit downregulates GTF2H1 and therefore compromises TFIIH stability and function in transcription and nucleotide excision repair (NER). We also demonstrate that cells with permanent BRM or BRG1 depletion have the ability to restore GTF2H1 expression. As a consequence, the sensitivity of SWI/SNF-deficient cells to DNA damage induced by UV irradiation and cisplatin treatment depends on GTF2H1 levels. Together, our results expose GTF2H1 as a potential novel predictive marker of platinum drug sensitivity in SWI/SNF-deficient cancer cells.

SWI/SNF genes are commonly found to be mutated in different cancers. Here the authors report that the remodelers BRM and BRG1 are necessary for efficient nucleotide excision repair by promoting the expression of TFIIH subunit GTF2H1.

Regulated acetylation and deacetylation of H4 K16 is essential for efficient NER in Saccharomyces cerevisiae

Acetylation status of H4 K16, a residue in the histone H4 N-terminal tail plays a unique role in regulating chromatin structure and function. Here we show that, during UV-induced nucleotide excision repair H4 K16 gets hyperacetylated following an initial phase of hypoacetylation. Disrupting H4 K16 acetylation-deacetylation by mutating H4 K16 to R (deacetylated state) or Q (acetylated state) leads to compromised chromatin functions. In the silenced mating locus and telomere region H4 K16 mutants show higher recruitment of Sir proteins and spreading beyond the designated boundaries. More significantly, chromatin of both the H4 K16 mutants has reduced accessibility in the silenced regions and genome wide. On UV irradiation, the mutants showed higher UV sensitivity, reduced NER rate and altered H3 N-terminal tail acetylation, compared to wild type. NER efficiency is affected by reduced or delayed recruitment of early NER proteins and chromatin remodeller Swi/Snf along with lack of nucleosome rearrangement during repair. Additionally UV-induced expression of RAD and SNF5 genes was reduced in the mutants. Hindered chromatin accessibility in the H4 K16 mutants is thus non-conducive for gene expression as well as recruitment of NER and chromatin remodeller proteins. Subsequently, inadequate nucleosomal rearrangement during early phases of repair impeded accessibility of the NER complex to DNA lesions, in the H4 K16 mutants. Effectively, NER efficiency was found to be compromised in the mutants. Interestingly, in the transcriptionally active chromatin region, both the H4 K16 mutants showed reduced NER rate during early repair time points. However, with progression of repair H4 K16R repaired faster than K16Q mutants and rate of CPD removal became differential between the two mutants during later NER phases. To summarize, our results establish the essentiality of regulated acetylation and deacetylation of H4 K16 residue in maintaining chromatin accessibility and efficiency of functions like NER and gene expression.

Single-nucleotide resolution dynamic repair maps of UV damage in Saccharomyces cerevisiae genome

We have adapted the eXcision Repair-sequencing (XR-seq) method to generate single-nucleotide resolution dynamic repair maps of UV-induced cyclobutane pyrimidine dimers and (6-4) pyrimidine-pyrimidone photoproducts in the Saccharomyces cerevisiae genome. We find that these photoproducts are removed from the genome primarily by incisions 13-18 nucleotides 5' and 6-7 nucleotides 3' to the UV damage that generate 21- to 27-nt-long excision products. Analyses of the excision repair kinetics both in single genes and at the genome-wide level reveal strong transcription-coupled repair of the transcribed strand at early time points followed by predominantly nontranscribed strand repair at later stages. We have also characterized the excision repair level as a function of the transcription level. The availability of high-resolution and dynamic repair maps should aid in future repair and mutagenesis studies in this model organism.

Persistence and Tolerance of DNA Damage Induced by Chronic UVB Irradiation of the Human Genome

Exposure to solar UVB radiation leads to the formation of the highly mutagenic cyclobutane pyrimidine dimers (CPDs), the DNA damage responsible for mutations found in skin cancer. The frequency of CPD formation and the repair rate of those lesions are two important parameters to determine the probability of UVR-induced mutations. Previous work has shown that chronic irradiation with sublethal doses of UVB radiation (chronic low-dose UVB radiation) leads to the accumulation of residual CPD that persists over time. We have thus investigated the persistence, localization, and consequences on genome stability of those chronic low-dose UVB radiation-induced residual CPDs. We show that chronic low-dose UVB radiation-induced residual CPDs persist on DNA and are diluted via semiconservative replication. They are overrepresented in the heterochromatin and at the TT dipyrimidine sites, and they catalyze the incidence of sister chromatin exchange. Our results shed some light on the impact of chronic UVB radiation exposure on DNA, with a focus on residual CPDs, their distribution, and consequences.

Human cells contain a factor that facilitates the DNA glycosylase-mediated excision of oxidized bases from occluded sites in nucleosomes

Reactive oxygen species generate some 20,000 base lesions per human cell per day. The vast majority of these potentially mutagenic or cytotoxic lesions are subject to base excision repair (BER). Although chromatin remodelers have been shown to enhance the excision of oxidized bases from nucleosomes in vitro, it is not clear that they are recruited to and act at sites of BER in vivo. To test the hypothesis that cells possess factors that enhance BER in chromatin, we assessed the capacity of nuclear extracts from human cells to excise thymine glycol (Tg) lesions from exogenously added, model nucleosomes. The DNA glycosylase NTHL1 in these extracts was able to excise Tg from both naked DNA and sites in nucleosomes that earlier studies had shown to be sterically accessible. However, the same extracts were able to excise lesions from sterically-occluded sites in nucleosomes only after the addition of Mg2+/ATP. Gel mobility shift assays indicated that nucleosomes remain largely intact following the Mg2+/ATP -dependent excision reaction. Size exclusion chromatography indicated that the NTHL1-stimulating activity has a relatively low molecular weight, close to that of NTHL1 and other BER glycosylases; column fractions that contained the very large chromatin remodeling complexes did not exhibit this same stimulatory activity. These results indicate that cells possess a factor(s) that promotes the initiation of BER in chromatin, but differs from most known chromatin remodeling complexes.

Defective DNA repair and chromatin organization in patients with quiescent systemic lupus erythematosus

Background

Excessive autoantibody production characterizing systemic lupus erythematosus (SLE) occurs irrespective of the disease’s clinical status and is linked to increased lymphocyte apoptosis. Herein, we tested the hypothesis that defective DNA damage repair contributes to increased apoptosis in SLE.

Methods

We evaluated nucleotide excision repair at the N-ras locus, DNA double-strand breaks repair and apoptosis rates in peripheral blood mononuclear cells from anti-dsDNA autoantibody-positive patients (six with quiescent disease and six with proliferative nephritis) and matched healthy controls following ex vivo treatment with melphalan. Chromatin organization and expression levels of DNA repair- and apoptosis-associated genes were also studied in quiescent SLE.

Results

Defective nucleotide excision repair and DNA double-strand breaks repair were found in SLE, with lupus nephritis patients showing higher DNA damage levels than those with quiescent disease. Melphalan-induced apoptosis rates were higher in SLE than control cells and correlated inversely with DNA repair efficiency. Chromatin at the N-ras locus was more condensed in SLE than controls, while treatment with the histone deacetylase inhibitor vorinostat resulted in hyperacetylation of histone H4, chromatin decondensation, amelioration of DNA repair efficiency and decreased apoptosis. Accordingly, genes involved in DNA damage repair and signaling pathways, such as DDB1, ERCC2, XPA, XPC, MRE11A, RAD50, PARP1, MLH1, MLH3, and ATM were significantly underexpressed in SLE versus controls, whereas PPP1R15A, BARD1 and BBC3 genes implicated in apoptosis were significantly overexpressed.

Conclusions

Epigenetically regulated functional abnormalities of DNA repair machinery occur in SLE, regardless of clinical disease activity, and may promote lymphocyte apoptosis. Approaches to correct these abnormalities may be of therapeutic value in SLE.

Electronic supplementary material

The online version of this article (doi:10.1186/s13075-016-1081-3) contains supplementary material, which is available to authorized users.

DNA repair of myeloma plasma cells correlates with clinical outcome: the effect of the nonhomologous end-joining inhibitor SCR7

DNA repair activity of malignant cells seems to influence therapeutic outcome and patients' survival. Herein, we investigated the mechanistic basis for the link between DNA repair efficiency and response to antimyeloma therapy. Nucleotide excision repair (NER), interstrand cross-links repair (ICL/R), double-strand breaks repair (DSB/R), and chromatin structure were evaluated in multiple myeloma (MM) cell lines (melphalan-sensitive RPMI8226; melphalan-resistant LR5) and bone marrow plasma cells (BMPCs) from MM patients who responded (n = 17) or did not respond (n = 9) to subsequent melphalan therapy. The effect of DSB/R inhibition was also evaluated. Responders' BMPCs showed slower rates of NER and DSB/R (P <0022), similar rates of ICL/R, and more condensed chromatin structure compared with nonresponders. Moreover, apoptosis rates of BMPCs were inversely correlated with individual DNA repair efficiency and were higher in responders' cells compared with those of nonresponders (P = .0011). Similarly, RPMI8226 cells showed slower rates of NER and DSB/R, comparable rates of ICL/R, more condensed chromatin structure, and higher sensitivity than LR5 cells. Interestingly, cotreatment of BMPCs or cell lines with DSB/R inhibitors significantly reduced the rates of DSB/R and increased melphalan sensitivity of the cells, with the nonhomologous end-joining inhibitor SCR7 showing the strongest effect. Together, responders' BMPCs are characterized by lower efficiencies of NER and DSB/R mechanisms, resulting in higher accumulation of the extremely cytotoxic ICLs and DSBs lesions, which in turn triggers the induction of the apoptotic pathway. Moreover, the enhancement of melphalan cytotoxicity by DSB/R inhibition offers a promising strategy toward improvement of existing antimyeloma regimens.

In vitro chromatin templates to study nucleotide excision repair

In eukaryotic cells, DNA associates with histones and exists in the form of a chromatin hierarchy. Thus, it is generally believed that many eukaryotic cellular DNA processing events such as replication, transcription, recombination and DNA repair are influenced by the packaging of DNA into chromatin. This mini-review covers the current knowledge of DNA damage and repair in chromatin based on in vitro studies. Specifically, nucleosome assembly affects DNA damage formation in both random sequences and sequences with strong nucleosome-positioning signals such as 5S rDNA. At least three systems have been used to analyze the effect of nucleosome folding on nucleotide excision repair (NER) in vitro: (a) human cell extracts that have to rely on labeling of repair synthesis to monitor DNA repair, due to very low repair efficacy; (b) Xenopus oocyte nuclear extracts, that have very robust DNA repair efficacy, have been utilized to follow direct removal of DNA damage; (c) six purified human DNA repair factors (RPA, XPA, XPC, TFIIH, XPG, and XPF-ERCC1) that have been used to reconstitute excision repair in vitro. In general, the results have shown that nucleosome folding inhibits NER and, therefore, its activity must be enhanced by chromatin remodeling factors like SWI/SNF. In addition, binding of transcription factors such as TFIIIA to the 5S rDNA promoter also modulates NER efficacy.

DNA excision repair at telomeres

DNA damage is caused by either endogenous cellular metabolic processes such as hydrolysis, oxidation, alkylation, and DNA base mismatches, or exogenous sources including ultraviolet (UV) light, ionizing radiation, and chemical agents. Damaged DNA that is not properly repaired can lead to genomic instability, driving tumorigenesis. To protect genomic stability, mammalian cells have evolved highly conserved DNA repair mechanisms to remove and repair DNA lesions. Telomeres are composed of long tandem TTAGGG repeats located at the ends of chromosomes. Maintenance of functional telomeres is critical for preventing genome instability. The telomeric sequence possesses unique features that predispose telomeres to a variety of DNA damage induced by environmental genotoxins. This review briefly describes the relevance of excision repair pathways in telomere maintenance, with the focus on base excision repair (BER), nucleotide excision repair (NER), and mismatch repair (MMR). By summarizing current knowledge on excision repair of telomere damage and outlining many unanswered questions, it is our hope to stimulate further interest in a better understanding of excision repair processes at telomeres and in how these processes contribute to telomere maintenance.

Histone ubiquitylation and its roles in transcription and DNA damage response

DNA in human cells is constantly assaulted by endogenous and exogenous DNA damaging agents. It is vital for the cell to respond rapidly and precisely to DNA damage to maintain genome integrity and reduce the risk of mutagenesis. Sophisticated reactions occur in chromatin surrounding the damaged site leading to the activation of DNA damage response (DDR), including transcription reprogramming, cell cycle checkpoint, and DNA repair. Histone proteins around the DNA damage play essential roles in DDR, through extensive post-translational modifications (PTMs) by a variety of modifying enzymes. One PTM on histones, mono-ubiquitylation, has emerged as a key player in cellular response to DNA damage. In this review, we will (1) briefly summarize the history of histone H2A and H2B ubiquitylation (H2Aub and H2Bub, respectively), (2) discuss their roles in transcription, and (3) their functions in DDR.

Molecular regulation of UV-induced DNA repair

Ultraviolet (UV) radiation from sunlight is a major etiologic factor for skin cancer, the most prevalent cancer in the United States, as well as premature skin aging. In particular, UVB radiation causes formation of specific DNA damage photoproducts between pyrimidine bases. These DNA damage photoproducts are repaired by a process called nucleotide excision repair, also known as UV-induced DNA repair. When left unrepaired, UVB-induced DNA damage leads to accumulation of mutations, predisposing people to carcinogenesis as well as to premature aging. Genetic loss of nucleotide excision repair leads to severe disorders, namely, xeroderma pigmentosum (XP), trichothiodystrophy (TTD) and Cockayne syndrome (CS), which are associated with predisposition to skin carcinogenesis at a young age as well as developmental and neurological conditions. Regulation of nucleotide excision repair is an attractive avenue to preventing or reversing these detrimental consequences of impaired nucleotide excision repair. Here, we review recent studies on molecular mechanisms regulating nucleotide excision repair by extracellular cues and intracellular signaling pathways, with a special focus on the molecular regulation of individual repair factors.

Evidence for evolutionary and nonevolutionary forces shaping the distribution of human genetic variants near transcription start sites

The regions surrounding transcription start sites (TSSs) of genes play a critical role in the regulation of gene expression. At the same time, current evidence indicates that these regions are particularly stressed by transcription-related mutagenic phenomena. In this work we performed a genome-wide analysis of the distribution of single nucleotide polymorphisms (SNPs) inside the 10 kb region flanking human TSSs by dividing SNPs into four classes according to their frequency (rare, two intermediate classes, and common). We found that, in this 10 kb region, the distribution of variants depends on their frequency and on their localization relative to the TSS. We found that the distribution of variants is generally different for TSSs located inside or outside of CpG islands. We found a significant relationship between the distribution of rare variants and nucleosome occupancy scores. Furthermore, our analysis suggests that evolutionary (purifying selection) and nonevolutionary (biased gene conversion) forces both play a role in determining the relative SNP frequency around TSSs. Finally, we analyzed the potential pathogenicity of each class of variant using the Combined Annotation Dependent Depletion score. In conclusion, this study provides a novel and detailed view of the distribution of genomic variants around TSSs, providing insight into the forces that instigate and maintain variability in such critical regions.

Understanding nucleotide excision repair and its roles in cancer and ageing

Nucleotide excision repair (NER) eliminates various structurally unrelated DNA lesions by a multiwise 'cut and patch'-type reaction. The global genome NER (GG-NER) subpathway prevents mutagenesis by probing the genome for helix-distorting lesions, whereas transcription-coupled NER (TC-NER) removes transcription-blocking lesions to permit unperturbed gene expression, thereby preventing cell death. Consequently, defects in GG-NER result in cancer predisposition, whereas defects in TC-NER cause a variety of diseases ranging from ultraviolet radiation-sensitive syndrome to severe premature ageing conditions such as Cockayne syndrome. Recent studies have uncovered new aspects of DNA-damage detection by NER, how NER is regulated by extensive post-translational modifications, and the dynamic chromatin interactions that control its efficiency. Based on these findings, a mechanistic model is proposed that explains the complex genotype-phenotype correlations of transcription-coupled repair disorders.

Enhanced chromatin dynamics by FACT promotes transcriptional restart after UV-induced DNA damage

Chromatin remodeling is tightly linked to all DNA-transacting activities. To study chromatin remodeling during DNA repair, we established quantitative fluorescence imaging methods to measure the exchange of histones in chromatin in living cells. We show that particularly H2A and H2B are evicted and replaced at an accelerated pace at sites of UV-induced DNA damage. This accelerated exchange of H2A/H2B is facilitated by SPT16, one of the two subunits of the histone chaperone FACT (facilitates chromatin transcription) but largely independent of its partner SSRP1. Interestingly, SPT16 is targeted to sites of UV light-induced DNA damage-arrested transcription and is required for efficient restart of RNA synthesis upon damage removal. Together, our data uncover an important role for chromatin dynamics at the crossroads of transcription and the UV-induced DNA damage response.

High-resolution characterization of CPD hotspot formation in human fibroblasts

Repair of DNA lesions must occur within the chromatin landscape and is associated with alterations in histone modifications and nucleosome rearrangement. To directly associate these chromatin features with DNA damage and repair, it is necessary to be able to map DNA adducts. We have developed a cyclobutane pyrimidine dimer (CPD)-specific immunoprecipitation method and mapped ultraviolet damage hotspots across human chromosomes 1 and 6. CPD hotspots occur almost equally in genic and intergenic regions. However, these hotspots are significantly more prevalent adjacent to repeat elements, especially Alu repeats. Nucleosome mapping studies indicate that nucleosomes are consistently positioned at Alu elements where CPD hotspots form, but by 2 h post-irradiation, these same regions are significantly depleted of nucleosomes. These results indicate that nucleosomes associated with hotspots of CPD formation are readily rearranged, potentially making them accessible to DNA repair machinery. Our results represent the first chromosome scale map of ultraviolet-induced DNA lesions in the human genome, and reveal the sequence features and dynamic chromatin changes associated with CPD hotspots.

Nucleotide excision repair in human cells: fate of the excised oligonucleotide carrying DNA damage in vivo

Nucleotide excision repair is the sole mechanism for removing the major UV photoproducts from genomic DNA in human cells. In vitro with human cell-free extract or purified excision repair factors, the damage is removed from naked DNA or nucleosomes in the form of 24- to 32-nucleotide-long oligomers (nominal 30-mer) by dual incisions. Whether the DNA damage is removed from chromatin in vivo in a similar manner and what the fate of the excised oligomer was has not been known previously. Here, we demonstrate that dual incisions occur in vivo identical to the in vitro reaction. Further, we show that transcription-coupled repair, which operates in the absence of the XPC protein, also generates the nominal 30-mer in UV-irradiated XP-C mutant cells. Finally, we report that the excised 30-mer is released from the chromatin in complex with the repair factors TFIIH and XPG. Taken together, our results show the congruence of in vivo and in vitro data on nucleotide excision repair in humans.

Downregulation of SWI/SNF chromatin remodeling factor subunits modulates cisplatin cytotoxicity

Chromatin remodeling complex SWI/SNF plays important roles in many cellular processes including transcription, proliferation, differentiation and DNA repair. In this report, we investigated the role of SWI/SNF catalytic subunits Brg1 and Brm in the cellular response to cisplatin in lung cancer and head/neck cancer cells. Stable knockdown of Brg1 and Brm enhanced cellular sensitivity to cisplatin. Repair kinetics of cisplatin DNA adducts revealed that downregulation of Brg1 and Brm impeded the repair of both intrastrand adducts and interstrand crosslinks (ICLs). Cisplatin ICL-induced DNA double strand break repair was also decreased in Brg1 and Brm depleted cells. Altered checkpoint activation with enhanced apoptosis as well as impaired chromatin relaxation was observed in Brg1 and Brm deficient cells. Downregulation of Brg1 and Brm did not affect the recruitment of DNA damage recognition factor XPC to cisplatin DNA lesions, but affected ERCC1 recruitment, which is involved in the later stages of DNA repair. Based on these results, we propose that SWI/SNF chromatin remodeling complex modulates cisplatin cytotoxicity by facilitating efficient repair of the cisplatin DNA lesions.

The emerging roles of ATP-dependent chromatin remodeling enzymes in nucleotide excision repair

DNA repair in eukaryotic cells takes place in the context of chromatin, where DNA, including damaged DNA, is tightly packed into nucleosomes and higher order chromatin structures. Chromatin intrinsically restricts accessibility of DNA repair proteins to the damaged DNA and impacts upon the overall rate of DNA repair. Chromatin is highly responsive to DNA damage and undergoes specific remodeling to facilitate DNA repair. How damaged DNA is accessed, repaired and restored to the original chromatin state, and how chromatin remodeling coordinates these processes in vivo, remains largely unknown. ATP-dependent chromatin remodelers (ACRs) are the master regulators of chromatin structure and dynamics. Conserved from yeast to humans, ACRs utilize the energy of ATP to reorganize packing of chromatin and control DNA accessibility by sliding, ejecting or restructuring nucleosomes. Several studies have demonstrated that ATP-dependent remodeling activity of ACRs plays important roles in coordination of spatio-temporal steps of different DNA repair pathways in chromatin. This review focuses on the role of ACRs in regulation of various aspects of nucleotide excision repair (NER) in the context of chromatin. We discuss current understanding of ATP-dependent chromatin remodeling by various subfamilies of remodelers and regulation of the NER pathway in vivo.

Radiation-induced alterations in histone modification patterns and their potential impact on short-term radiation effects

Detection and repair of radiation-induced DNA damage occur in the context of chromatin. An intricate network of mechanisms defines chromatin structure, including DNA methylation, incorporation of histone variants, histone modifications, and chromatin remodeling. In the last years it became clear that the cellular response to radiation-induced DNA damage involves all of these mechanisms. Here we focus on the current knowledge on radiation-induced alterations in post-translational histone modification patterns and their effect on the chromatin accessibility, transcriptional regulation and chromosomal stability.

Monoubiquitinated histone H2A destabilizes photolesion-containing nucleosomes with concomitant release of UV-damaged DNA-binding protein E3 ligase

How the nucleotide excision repair (NER) machinery gains access to damaged chromatinized DNA templates and how the chromatin structure is modified to promote efficient repair of the non-transcribed genome remain poorly understood. The UV-damaged DNA-binding protein complex (UV-DDB, consisting of DDB1 and DDB2, the latter of which is mutated in xeroderma pigmentosum group E patients, is a substrate-recruiting module of the cullin 4B-based E3 ligase complex, DDB1-CUL4B^DDB2. We previously reported that the deficiency of UV-DDB E3 ligases in ubiquitinating histone H2A at UV-damaged DNA sites in the xeroderma pigmentosum group E cells contributes to the faulty NER in these skin cancer-prone patients. Here, we reveal the mechanism by which monoubiquitination of specific H2A lysine residues alters nucleosomal dynamics and subsequently initiates NER. We show that DDB1-CUL4B^DDB2 E3 ligase specifically binds to mononucleosomes assembled with human recombinant histone octamers and nucleosome-positioning DNA containing cyclobutane pyrimidine dimers or 6-4 photoproducts photolesions. We demonstrate functionally that ubiquitination of H2A Lys-119/Lys-120 is necessary for destabilization of nucleosomes and concomitant release of DDB1-CUL4B^DDB2 from photolesion-containing DNA. Nucleosomes in which these lysines are replaced with arginines are resistant to such structural changes, and arginine mutants prevent the eviction of H2A and dissociation of polyubiquitinated DDB2 from UV-damaged nucleosomes. The partial eviction of H3 from the nucleosomes is dependent on ubiquitinated H2A Lys-119/Lys-120. Our results provide mechanistic insight into how post-translational modification of H2A at the site of a photolesion initiates the repair process and directly affects the stability of the human genome.

ATP-dependent chromatin remodeling in the DNA-damage response

The integrity of DNA is continuously challenged by metabolism-derived and environmental genotoxic agents that cause a variety of DNA lesions, including base alterations and breaks. DNA damage interferes with vital processes such as transcription and replication, and if not repaired properly, can ultimately lead to premature aging and cancer. Multiple DNA pathways signaling for DNA repair and DNA damage collectively safeguard the integrity of DNA. Chromatin plays a pivotal role in regulating DNA-associated processes, and is itself subject to regulation by the DNA-damage response. Chromatin influences access to DNA, and often serves as a docking or signaling site for repair and signaling proteins. Its structure can be adapted by post-translational histone modifications and nucleosome remodeling, catalyzed by the activity of ATP-dependent chromatin-remodeling complexes. In recent years, accumulating evidence has suggested that ATP-dependent chromatin-remodeling complexes play important, although poorly characterized, roles in facilitating the effectiveness of the DNA-damage response. In this review, we summarize the current knowledge on the involvement of ATP-dependent chromatin remodeling in three major DNA repair pathways: nucleotide excision repair, homologous recombination, and non-homologous end-joining. This shows that a surprisingly large number of different remodeling complexes display pleiotropic functions during different stages of the DNA-damage response. Moreover, several complexes seem to have multiple functions, and are implicated in various mechanistically distinct repair pathways.

Detecting UV-lesions in the genome: The modular CRL4 ubiquitin ligase does it best!

The DDB1-DDB2-CUL4-RBX1 complex serves as the primary detection device for UV-induced lesions in the genome. It simultaneously functions as a CUL4 type E3 ubiquitin ligase. We review the current understanding of this dual function ubiquitin ligase and damage detection complex. The DDB2 damage binding module is merely one of a large family of possible DDB1-CUL4 associated factors (DCAF), most of which are substrate receptors for other DDB1-CUL4 complexes. DDB2 and the Cockayne-syndrome A protein (CSA) function in nucleotide excision repair, whereas the remaining receptors operate in a wide range of other biological pathways. We will examine the modular architecture of DDB1-CUL4 in complex with DDB2, CSA and CDT2 focusing on shared architectural, targeting and regulatory principles.

Evidence that the histone methyltransferase Dot1 mediates global genomic repair by methylating histone H3 on lysine 79

Global genomic repair (GGR) and transcription coupled repair (TCR) are two pathways of nucleotide excision repair (NER) that differ in the damage recognition step. How NER factors, especially GGR factors, access DNA damage in the chromatin of eukaryotic cells has been poorly understood. Dot1, a histone methyltransferase required for methylation of histone H3 lysine 79 (H3K79), has been shown to confer yeast cells with resistance to DNA-damaging agents and play a role in activation of DNA damage checkpoints. Here, we show that Dot1 and H3K79 methylation are required for GGR in both nucleosomal core regions and internucleosomal linker DNA, but play no role in TCR. H3K79 trimethylation contributes to but is not absolutely required for GGR, and lower levels of H3K79 methylation (mono- and dimethylation) also promote GGR. Our results also indicate that the roles of Dot1 and H3K79 methylation in GGR are not achieved by either activating DNA damage checkpoints or regulating the expression of the GGR-specific factor Rad16. Rather, the methylated H3K79 may serve as a docking site for the GGR machinery on the chromatin. Our studies identified a novel GGR-specific NER factor and unveiled the critical link between a covalent histone modification and GGR.

Rotational dynamics of DNA on the nucleosome surface markedly impact accessibility to a DNA repair enzyme

Histones play a crucial role in the organization of DNA in the nucleus, but their presence can prevent interactions with DNA binding proteins responsible for repair of DNA damage. Uracil is an abundant mutagenic lesion recognized by uracil DNA glycosylase (UDG) in the first step of base excision repair (BER). In nucleosome core particles (NCPs), we find substantial differences in UDG-directed cleavage at uracils rotationally positioned toward (U-In) or away from (U-Out) the histone core, or midway between these orientations (U-Mid). Whereas U-Out NCPs show a cleavage rate just below that of naked DNA, U-In and U-Mid NCPs have markedly slower rates of cleavage. Crosslinking of U-In DNA to histones in NCPs yields a greater reduction in cleavage rate but, surprisingly, yields a higher rate of cleavage in U-Out NCPs compared with uncrosslinked NCPs. Moreover, the next enzyme in BER, APE1, stimulates the activity of human UDG in U-Out NCPs, suggesting these enzymes interact on the surface of histones in orientations accessible to UDG. These data indicate that the activity of UDG likely requires "trapping" transiently exposed states arising from the rotational dynamics of DNA on histones.

A cassette of N-terminal amino acids of histone H2B are required for efficient cell survival, DNA repair and Swi/Snf binding in UV irradiated yeast

The highly charged histone N-terminal domains are engaged in inter- and intra-nucleosomal interactions, and contain a host of sites used for posttranslational modification. We have studied the effect of deleting residues 30–37 from the N-terminal domain of histone H2B in yeast cells, on nucleotide excision repair (NER) following UV irradiation, as these cells are quite sensitive to UV. We find that H2B Δ30–37 cells exhibit reduced NER efficiency at three specific chromatin loci: the transcriptionally active, RPB2 locus; the transcriptionally silenced, nucleosome-loaded HML locus; and the transcriptionally repressed, non-silenced, GAL10 locus. Nuclease digestion studies indicate that H2B Δ30–37 chromatin has increased nucleosome accessibility and/or nucleosome mobility. In addition, H2B Δ30–37 mutants acquire more DNA damage, compared to wt cells, following the same dose of UV radiation. Reducing the level of damage in H2B Δ30–37 cells to match that of wt cells restores the NER rate to wt levels in the RPB2 and GAL10 loci, but NER efficiency remains low in the silenced HML locus. Interestingly, recruitment of Snf5 to the HML locus is reduced in H2B Δ30–37 cells and more transient following UV irradiation. This may reflect a lower binding affinity of the SWI/SNF complex to H2B Δ30–37 nucleosomes.

The nucleosome-binding protein HMGN2 modulates global genome repair

The HMGN family comprises nuclear proteins that bind to nucleosomes and alter the structure of chromatin. Here, we report that DT40 chicken cells lacking either HMGN2 or HMGN1a, or lacking both HMGN1a and HMGN2, are hypersensitive to killing by UV irradiation. Loss of both HMGN1a and HMGN2 or only HMGN2 increases the extent of UV-induced G(2)-M checkpoint arrest and the rate of apoptosis. HMGN null mutant cells showed slower removal of UV-induced DNA lesions from native chromatin, but the nucleotide excision repair remained intact, as measured by host cell reactivation assays. These results identify HMGN2 as a component of the global genome repair subpathway of the nucleotide excision repair pathway, and may indicate that HMGN2 facilitates the ability of the DNA repair proteins to access and repair UV-induced DNA lesions in chromatin. Our finding that HMGNs play a role in global DNA repair expands the role of these proteins in the maintenance of genome integrity.

Inhibition of type I histone deacetylase increases resistance of checkpoint-deficient cells to genotoxic agents through mitotic delay

Histone deacetylase (HDAC) inhibitors potently inhibit tumor growth and are currently being evaluated for their efficacy as chemosensitizers and radiosensitizers. This efficacy is likely to be limited by the fact that HDAC inhibitors also induce cell cycle arrest. Deletion of the class I HDAC Rpd3 has been shown to specifically suppress the sensitivity of Saccharomyces cerevisiae DNA damage checkpoint mutants to UV and hydroxyurea. We show that in the fission yeast Schizosaccharomyces pombe, inhibition of the homologous class I HDAC specifically suppresses the DNA damage sensitivity of checkpoint mutants. Importantly, the prototype HDAC inhibitor Trichostatin A also suppressed the sensitivity of DNA damage checkpoint but not of DNA repair mutants to UV and HU. TSA suppressed DNA damage activity independently of the mitogen-activated protein kinase-dependent and spindle checkpoint pathways. We show that TSA delays progression into mitosis and propose that this is the main mechanism for suppression of the DNA damage sensitivity of S. pombe checkpoint mutants, partially compensating for the loss of the G(2) checkpoint pathway. Our studies also show that the ability of HDAC inhibitors to suppress DNA damage sensitivity is not species specific. Class I HDACs are the major target of HDAC inhibitors and cancer cells are often defective in checkpoint activation. Effective use of these agents as chemosensitizers and radiosensitizers may require specific treatment schedules that circumvent their inhibition of cell cycle progression.

The molecular basis of chromatin dynamics during nucleotide excision repair

The assembly of DNA into chromatin in eukaryotic cells affects all DNA-related cellular activities, such as replication, transcription, recombination, and repair. Rearrangement of chromatin structure during nucleotide excision repair (NER) was discovered more than 2 decades ago. However, the molecular basis of chromatin dynamics during NER remains undefined. Pioneering studies in the field of gene transcription have shown that ATP-dependent chromatin-remodeling complexes and histone-modifying enzymes play a critical role in chromatin dynamics during transcription. Similarly, recent studies have demonstrated that the SWI/SNF chromatin-remodeling complex facilitates NER both in vitro and in vivo. Additionally, histone acetylation has also been linked to the NER of ultraviolet light damage. In this article, we will discuss the role of these identified chromatin-modifying activities in NER.

Assays for chromatin remodeling during nucleotide excision repair in Saccharomyces cerevisiae

How DNA repair proteins interact with the dynamic structure of chromatin is an emerging question. Chromatin structure impedes the access of repair proteins to sites of DNA damage. Several recent studies have implicated chromatin remodeling complexes in DNA repair. In this report we summarize the methods we used to investigate chromatin remodeling during nucleotide excision repair (NER) in vivo. We describe a procedure to analyze UV-induced chromatin remodeling at the silent mating-type locus HML using isolated nuclei from UV-treated yeast cells. In addition, a method to capture transient protein-protein associations in chromatin is outlined. We have used the methods described here to demonstrate that the SWI/SNF chromatin remodeling complex is involved in chromatin rearrangement during NER.

Intrinsic disorder explains diverse nuclear roles of chromatin remodeling proteins

Chromatin remodelers, a group of proteins involved in nucleosome re-positioning and modification, have extensive range of interacting partners. They form multimeric complexes and interact with modified histones, transcription, splicing, and replication factors, DNA, RNA, and the factors related to the maintenance of chromosome structure. Such diverse range of interactions is hard to explain with the presumed highly structured form of the protein. In the current analysis, the conformations of chromatin remodelers were explored using protein disorder prediction algorithms. The study revealed that a significant proportion (p < 2.2e-16) of these proteins harbor at least one long region of intrinsic disorder (>70 aa). These unstructured regions do not exhibit any preference to the N/C terminal or middle of the protein. They do not show any significant representation in the Protein Data Bank (PDB) structure repository. Limited examples from PDB indicate direct involvement of disordered regions in binding of chromatin remodeling proteins to naked or modified DNA, histones, and other chromatin-related factors. Furthermore, intrinsic disorder seen in these proteins correlates to the presence of low sequence complexity regions (p = 1.851e-10) particularly the tandem repeats of hydrophilic and charged amino acids. This probably hints at their evolutionary origin via repeat expansion. The disordered regions may enable these proteins to reversibly bind to various interacting partners and eventually contribute to functional diversity and specialization of chromatin remodeling complexes. These could also endow combinatorial action of multiple domains within a protein. We further discuss the prominent association of intrinsic disorder with other chromatin-related proteins and its functional relevance therein.

Histone H3 Lys79 methylation is required for efficient nucleotide excision repair in a silenced locus of Saccharomyces cerevisiae

Methylation of specific histone lysine residues regulates gene expression and heterochromatin function, but little is known about its role in DNA repair. To examine how changes in conserved methylated residues of histone H3 affect nucleotide excision repair (NER), viable H3K4R and H3K79R mutants were generated in Saccharomyces cerevisiae. These mutants show decreased UV survival and impaired NER at the transcriptionally silent HML locus, while maintaining normal NER in the constitutively expressed RPB2 gene and transcriptionally repressed, nucleosome loaded GAL10 gene. Moreover, the HML chromatin in these mutants has reduced accessibility to Micrococcal nuclease (MNase). Importantly, chromatin immunoprecipitation analysis demonstrates there is enhanced recruitment of the Sir complex at the HML locus of these mutants, and deletion of the SIR2 or SIR3 genes restores the MNase accessibility and DNA repair efficiency at this locus. Furthermore, following UV irradiation expression of NER genes in these mutants remains at wild type levels, with the exception of RAD16 which decreases by more than 2-fold. These results indicate that impaired NER occurs in the silenced chromatin of H3K79R and H3K4,79R mutants as a result of increased binding of Sir complexes, which may reduce DNA lesion accessibility to repair enzymes.

Altering the chromatin landscape for nucleotide excision repair

DNA acts as a 'workbench' for various nuclear processes that occur inside living cells. In eukaryotic cells, DNA is highly compacted in a structural hierarchy with histones and other proteins into chromatin. This compaction affects DNA structure and coordinates the accessibility to site-specific nuclear factors during DNA processing events. DNA repair is no exception to this general rule and several reviews have appeared recently that discuss this topic in detail [1-3]. Here, we focus on recent findings correlating changes in DNA repair with subtle variations in the chromatin landscape.

Chromatin recruitment of DNA repair proteins: lessons from the fanconi anemia and double-strand break repair pathways

In response to DNA damage, eukaryotic cells must rapidly load DNA repair proteins onto damaged chromatin. Chromatin recruitment often entails ubiquitination of a damage-specific DNA repair protein, interaction with a ubiquitin binding factor, assembly of a multisubunit DNA repair complex, and eventually a deubiquitination event once the DNA repair reaction has been completed. This review focuses on the recent discoveries in the Fanconi Anemia (FA) and DNA double-strand break (DSB) repair pathways, which underscore the importance of regulated chromatin loading in the DNA damage response. Interestingly, these two pathways share several features, suggesting a more general mechanism for DNA-repair regulation.

Chromatin restoration following nucleotide excision repair involves the incorporation of ubiquitinated H2A at damaged genomic sites

Restoration of functionally intact chromatin structure following DNA damage processing is crucial for maintaining genetic and epigenetic information in human cells. Here, we show the UV-induced uH2A foci formation in cells lacking XPC, DDB2, CSA or CSB, but not in cells lacking XPA, XPG or XPF indicating that uH2A incorporation relied on successful damage repair occurring through either GGR or TCR sub-pathway. In contrast, XPA, XPG or XPF were not required for formation of gammaH2AX foci in asynchronous cells. Notably, the H2A ubiquitin ligase Ring1B, a component of Polycomb repressor complex 1, did not localize at DNA damage sites. However, histone chaperone CAF-1 showed distinct localization to the damage sites. Knockdown of CAF-1 p60 abolished CAF-1 as well as uH2A foci formation. CAF-1 p150 was found to associate with NER factors TFIIH, RPA p70 and PCNA in chromatin. These data demonstrate that successful NER of genomic lesions and prompt CAF-1-mediated chromatin restoration link uH2A incorporation at the sites of damage repair within chromatin.

A single amino acid change in histone H4 enhances UV survival and DNA repair in yeast

Single amino acid changes at specific DNA contacts of histones H3 and H4 generate SWI/SNF-independent (Sin) mutants in yeast. We have analyzed the effect of the Sin mutation at R45 of histone H4 on cell survival following UV irradiation, nucleotide excision repair (NER) and chromatin structure. We find that this mutation renders yeast cells more resistant to UV damage and enhances NER at specific chromatin loci. In the transcriptionally silent HML, repressed GAL10 and the constitutively active RPB2 loci, H4 R45 mutants exhibit enhanced repair of UV-induced cyclobutane pyrimidine dimers (CPDs) compared to wild-type (wt). However, the H4 R45 mutation does not increase the transcription of NER genes, disrupt transcriptional silencing of the HML locus or alter repression in the GAL10 locus. We have further shown that the H4 R45C mutation increases the accessibility of nucleosome DNA in chromatin to exogenous nucleases and may expedite nucleosome rearrangements during NER. Taken together, our results indicate that the increased repair observed in Sin mutants is a direct effect of the altered chromatin landscape caused by the mutation, suggesting that such subtle changes in the conserved histone residues can influence the accessibility of DNA repair factors in chromatin.

Functionally distinct nucleosome-free regions in yeast require Rad7 and Rad16 for nucleotide excision repair

In yeast, Rad7 and Rad16 are two proteins required for nucleotide excision repair (NER) of non-transcribed chromatin. They have roles in damage recognition, in the postincision steps of NER, and in ultraviolet-light-dependent histone H3 acetylation. Moreover, Rad16 is an ATP-ase of the SNF2 superfamily and therefore might facilitate chromatin repair by nucleosome remodelling. Here, we used yeast rad7 Delta rad16 Delta mutants and show that Rad7-Rad16 is also required for NER of UV-lesions in three functionally distinct nucleosome-free regions (NFRs), the promoter and 3'-end of the URA3 gene and the ARS1 origin of replication. Moreover, rapid repair of UV-lesions by photolyase confirmed that nucleosomes were absent and that neither UV-damage formation nor rad7 Delta rad16 Delta mutations altered chromatin accessibility in NFRs. The data are consistent with a role of Rad7-Rad16 in damage recognition and processing in absence of nucleosomes. An additional role in nucleosome remodelling is discussed.

Depletion of poly(ADP-ribose) polymerase-1 reduces host cell reactivation of a UV-damaged adenovirus-encoded reporter gene in human dermal fibroblasts

In response to ultraviolet radiation (UV), mammalian cells rapidly activate a nuclear enzyme poly(ADP-ribose) polymerase-1 (PARP), and we recently showed that one of the causes for PARP-activation is UV-induced direct DNA photolesions which are repaired by nucleotide excision repair process (NER). To determine whether PARP can play a role in NER, we stably depleted PARP in NER-proficient human skin fibroblasts GM637 by DNA vector-based RNAi. In these cells, we examined host cell reactivation (HCR) of UVB or UVC-irradiated recombinant adenovirus AdCA35lacZ, encoding a beta-galactosidase (beta-gal) reporter gene. The depletion of PARP decreased the HCR of UVB- or UVC-damaged reporter gene to a similar extent, indicating the role of PARP in NER. Moreover, PARP-depletion reduced the HCR capacity of the NER-competent GM637 cells to a level closer to that in the XP-C and CS-B cell lines, which are deficient in the lesion recognition steps of the global genome repair (GGR) and transcription-coupled repair (TCR) sub-pathways of NER, respectively. In order to identify the potential role of PARP in these two sub-pathways of NER from that of its known role in base excision repair (BER) of UVB-induced oxidant damage, we depleted PARP from XP-C and CS-B cells and examined HCR of the reporter gene damaged by UVB, UVC or photoactivated methylene blue, the latter causing predominantly 8-oxo-2'-deoxyguanosine damage that is repaired by BER. Interestingly, a decreased HCR due to PARP-depletion was observed in both the NER-deficient cell lines in response to virus damaged by these three agents, albeit with different kinetics from 12 to 44h after infection. The role of PARP in NER was highlighted by a decreased clonogenic survival of UV-irradiated NER-competent GM637 cells depleted of PARP. Our results, while confirming the role of PARP in base excision repair, suggest a novel role of PARP in both the GGR and TCR sub-pathways of NER.

Role of the mammalian SWI/SNF chromatin remodeling complex in the cellular response to UV damage

Mammalian cells exhibit complex cellular responses to DNA damage, including cell cycle arrest, DNA repair and apoptosis. Defects in any one of these responses can result in carcinogenesis. Absence of the chromatin remodeling complex Swi/Snf is found in many instances of cancer, and we have investigated its role in the UV damage response. The human carcinoma cell line SW13 is deficient in Swi/Snf and is very sensitive to UV radiation. In contrast, SW13 cells with ectopic Brg1 expression regain active Swi/Snf and become significantly more resistant to UV radiation. Sensitivity to UV light correlates well with dramatic UV induced apoptosis in SW13 cells, but not in SW13 cells expressing Brg1. We show that SW13 cells synchronized at the G(1)/S border progress into S phase after UV irradiation, and this checkpoint deficiency is corrected after Brg1 expression is restored. Interestingly, Brg1 expression in SW13 cells restores expression of two DNA damage responsive genes, Gadd45a and p21. Furthermore, Gadd45a induction and p21 degradation were observed in the Brg1-expressing SW13 cells after UV irradiation. Our findings demonstrate that Swi/Snf protects cells against deleterious consequences of UV induced DNA damage. These results also indicate that Swi/Snf may modulate checkpoint activation after UV damage via regulation of the two PCNA-binding proteins Gadd45a and p21.

Tandem repeat mutation, global DNA methylation, and regulation of DNA methyltransferases in cultured mouse embryonic fibroblast cells chronically exposed to chemicals with different modes of action

Mutations at expanded simple tandem repeat (ESTR) DNA sequences provide a useful tool for screening germline mutation. However, the mechanisms resulting in induced mutations are unknown and provide an impediment to the utility of the method. Induced ESTR mutations arise through a nontargeted mechanism resulting in destabilization of the repeat locus. We hypothesized that alterations in DNA methylation, or in DNA methyltransferase expression, may be associated with this indirect mechanism of mutation. DNA mutation frequency was measured in C3H/10T1/2 mouse embryonic fibroblast cells following chronic exposure to six chemicals exhibiting different modes of genotoxic action: N-nitroso-N-ethylurea (ENU); benzo(a)pyrene (BaP); etoposide (ETOP); okadaic acid (OA); cisplatin (CisPt); and 5-azacytidine (5azadC). Induced mutation ranged from 2-fold (ENU, BaP, ETOP), to 1.3-1.4 fold (OA, 5azadC), to nonresponsive (CisPt). Global DNA methylation, measured using the cytosine extension assay, revealed hypomethylation following exposure to ENU and 5azadC, hypermethylation following BaP and OA exposure, and no change following treatment with ETOP or CisPt. DNA methyltransferase transcription (Dnmt1, Dnmt3a, Dnmt3b) was significantly affected by all treatments except ETOP, with the vast majority of changes being downregulation. There was no direct correlation between ESTR mutation, global methylation, or DNA methyltransferase transcription. However, 4/5 ESTR mutagens caused changes in global methylation, while the noninducer (CisPt) did not cause changes in methylation. We hypothesize that chemicals that modify chromatin conformation through changes in methylation may compromise the ability of mismatch repair enzymes (or other enzymes) to access and repair secondary structures that may form across ESTR loci resulting in mutation.

The roles of Rad16 and Rad26 in repairing repressed and actively transcribed genes in yeast

Nucleotide excision repair (NER) is a conserved DNA repair mechanism capable of removing a variety of helix-distorting DNA lesions. Rad26, a member of the Swi2/Snf2 superfamily of proteins, has been shown to be involved in a specialized NER process called transcription coupled NER. Rad16, another member of the same protein superfamily, has been shown to be required for genome-wide NER. Here we show that Rad16 and Rad26 play different roles in repairing repressed and actively transcribed genes in yeast. Rad16 is partially dispensable, and Rad26 plays a significant role in repairing certain regions of the repressed GAL1-10, PHO5 and ADH2 genes, especially in the core DNA of well-positioned nucleosomes. Simultaneous elimination of Rad16 and Rad26 results in no detectable repair in these regions of the repressed genes. Transcriptional induction of the GAL1-10 genes abolishes the role of Rad26, but does not affect the role of Rad16 in repairing the nontranscribed strand of the genes. Interestingly, when the transcription activator Gal4 is eliminated from the cells, Rad16 becomes partially dispensable and Rad26 plays a significant role in repairing both strands of the GAL1-10 genes even under inducing conditions. Our results suggest that Rad16 and Rad26 play different and, to some extent, complementary roles in repairing both strands of repressed genes, although the relative contributions of the two proteins can be different from gene to gene, and from region to region of a gene. However, Rad16 is solely responsible for repairing the nontranscribed strand of actively transcribed genes.

Roles of ATM and NBS1 in chromatin structure modulation and DNA double-strand break repair

We developed a novel system to create DNA double-strand breaks (DSBs) at defined endogenous sites in the human genome, and used this system to detect protein recruitment and loss at and around these breaks by chromatin immunoprecipitation (ChIP). The detection of human ATM protein at site-specific DSBs required functional NBS1 protein, ATM kinase activity and ATM autophosphorylation on Ser 1981. DSB formation led to the localized disruption of nucleosomes, a process that depended on both functional NBS1 and ATM. These two proteins were also required for efficient recruitment of the repair cofactor XRCC4 to DSBs, and for efficient DSB repair. These results demonstrate the functional importance of ATM kinase activity and phosphorylation in the response to DSBs, and support a model in which ordered chromatin structure changes that occur after DNA breakage depend on functional NBS1 and ATM, and facilitate DNA DSB repair.

The ING1b tumor suppressor facilitates nucleotide excision repair by promoting chromatin accessibility to XPA

ING1b is the most studied ING family protein and perhaps the most ubiquitously and abundantly expressed. This protein is involved in the regulation of various biological functions ranging from senescence, cell cycle arrest, apoptosis, to DNA repair. ING1b is upregulated by UV irradiation and enhances the removal of bulky nucleic acid photoproducts. In this study, we provide evidence that ING1b mediates nucleotide excision repair by facilitating the access to damaged nucleosomal DNA. We demonstrate that ING1b is not recruited to UV-induced DNA lesions but enhances nucleotide excision repair only in XPC-proficient cells, implying an essential role in early steps of the 'access, repair, restore' model. We also find that ING1b alters histone acetylation dynamics upon exposure to UV radiation and induces chromatin relaxation in microccocal nuclease digestion assay, revealing that ING1b may allow better access to nucleotide excision repair machinery. More importantly, ING1b associates with chromatin in a UV-inducible manner and facilitates DNA access to nucleotide excision repair factor XPA. Furthermore, depletion of the endogenous ING1b results to the sensitization of cells at S-phase to UV irradiation. Taken together, these observations establish a role of ING1b acting as a chromatin accessibility factor for DNA damage recognition proteins upon genotoxic injury.