Formation and repair of DNA-protein crosslinks in newly replicated DNA

The production and removal of gamma-radiation-induced DNA-protein crosslinks (DPC) in nuclear matrix-associated newly replicated DNA were examined, as well as the relationship of DPC to DNA replication. In unirradiated, exponentially growing Chinese hamster V79 cells, DNA pulse labeled with [3H]thymidine was observed to be bound preferentially to protein. The pulse-labeled DNA subsequently became dissociated from protein. After a 30- to 60-min chase period, the level of labeled DNA in DPC was reduced to the same level as for bulk DNA. The radiation dose response for the formation of DPC was similar in newly replicated DNA that had been chased for various times and in mature chromatin DNA. Labeled DNA, in the DPC formed after 60 Gy, was rapidly removed from protein during the postirradiation incubation period. However, no recovery of DNA synthesis was observed, even after the majority of DPC were released. Thus either DPC are not the sole cause of the inhibition of DNA synthesis or their removal is not sufficient for DNA synthesis to resume.     

Cellular pathways for DNA repair and damage tolerance of formaldehyde-induced DNA-protein crosslinks

Although it is well established that DNA-protein crosslinks are formed as a consequence of cellular exposure to agents such as formaldehyde, transplatin, ionizing and ultraviolet radiation, the biochemical pathways that promote cellular survival via repair or tolerance of these lesions are poorly understood. To investigate the mechanisms that function to limit DNA-protein crosslink-induced cytotoxicity, the Saccharomyces cerevisiae non-essential gene deletion library was screened for increased sensitivity to formaldehyde exposure. Following low dose, chronic exposure, strains containing deletions in genes mediating homologous recombination showed the greatest sensitivity, while under the same exposure conditions, deletions in genes associated with nucleotide excision repair conferred only low to moderate sensitivities. However, when the exposure regime was changed to a high dose acute (short-term) formaldehyde treatment, the genes that conferred maximal survival switched to the nucleotide excision repair pathway, with little contribution of the homologous recombination genes. Data are presented which suggest that following acute formaldehyde exposure, repair and/or tolerance of DNA-protein crosslinks proceeds via formation of nucleotide excision repair-dependent single-strand break intermediates and without a detectable accumulation of double-strand breaks. These data clearly demonstrate a differential pathway response to chronic versus acute formaldehyde exposures and may have significance and implications for risk extrapolation in human exposure studies.     

Mechanism of replication-coupled DNA interstrand crosslink repair

DNA interstrand crosslinks (ICLs) are toxic DNA lesions whose repair occurs in the S phase of metazoans via an unknown mechanism. Here, we describe a cell-free system based on Xenopus egg extracts that supports ICL repair. During DNA replication of a plasmid containing a site-specific ICL, two replication forks converge on the crosslink. Subsequent lesion bypass involves advance of a nascent leading strand to within one nucleotide of the ICL, followed by incisions, translesion DNA synthesis, and extension of the nascent strand beyond the lesion. Immunodepletion experiments suggest that extension requires DNA polymerase zeta. Ultimately, a significant portion of the input DNA is fully repaired, but not if DNA replication is blocked. Our experiments establish a mechanism for ICL repair that reveals how this process is coupled to DNA replication.     

DNA interstrand crosslink repair in mammalian cells

DNA damage by agents crosslinking the strands presents a formidable challenge to the cell to repair for survival and to repair accurately for maintenance of genetic information. It appears that repair of DNA crosslinks occurs in a path involving double strand breaks (DSBs) in the DNA. Mammalian cells have multiple systems involved in the repair response to such damage, including the Fanconi anemia pathway that appears to be directly involved, although the mechanisms and site of action remain elusive. A particular finding relating to deficiency of the Fanconi anemia pathway is the observation of chromosomal radial formations after ICL damage. The basis of formation of such chromosomal aberrations is unknown although they appear secondarily to DSBs. Here we review the processes involved in response to DNA interstrand crosslinks which might lead to radial formation and the role of the nucleotide excision repair gene, ERCC1, which is required for a normal response, not just to DNA crosslinks, but also for DSBs at collapsed replication forks caused by substrate depletion. J. Cell. Physiol. 220: 569–573, 2009. © 2009 Wiley‐Liss, Inc.     

Radiation damage to DNA in DNA-protein complexes

The most aggressive product of water radiolysis, the hydroxyl (OH) radical, is responsible for the indirect effect of ionizing radiations on DNA in solution and aerobic conditions. According to radiolytic footprinting experiments, the resulting strand breaks and base modifications are inhomogeneously distributed along the DNA molecule irradiated free or bound to ligands (polyamines, thiols, proteins). A Monte-Carlo based model of simulation of the reaction of OH radicals with the macromolecules, called RADACK, allows calculating the relative probability of damage of each nucleotide of DNA irradiated alone or in complexes with proteins. RADACK calculations require the knowledge of the three dimensional structure of DNA and its complexes (determined by X-ray crystallography, NMR spectroscopy or molecular modeling). The confrontation of the calculated values with the results of the radiolytic footprinting experiments together with molecular modeling calculations show that: (1) the extent and location of the lesions are strongly dependent on the structure of DNA, which in turns is modulated by the base sequence and by the binding of proteins and (2) the regions in contact with the protein can be protected against the attack by the hydroxyl radicals via masking of the binding site and by scavenging of the radicals.     

A novel function for BRCA1 in crosslink repair

In this issue of Molecular Cell, Bunting et al. (2012) provide new evidence that BRCA1 plays an important role in DNA interstrand crosslink repair that is distinct from its established function in promoting DNA end resection during homologous recombination.     

Deubiquitination of FANCD2 is required for DNA crosslink repair

Monoubiquitination of FANCD2 and PCNA promotes DNA repair. It causes chromatin accumulation of FANCD2 and facilitates PCNA's recruitment of translesion polymerases to stalled replication. USP1, a protease that removes monoubiquitin from FANCD2 and PCNA, was thought to reverse the DNA damage response of these substrates. We disrupted USP1 in chicken cells to dissect its role in a stable genetic system. USP1 ablation increases FANCD2 and PCNA monoubiquitination but unexpectedly results in DNA crosslinker sensitivity. This defective DNA repair is associated with constitutively chromatin-bound, monoubiquitinated FANCD2. In contrast, persistent PCNA monoubiquitination has negligible impact on DNA repair or mutagenesis. USP1 was previously shown to autocleave after DNA damage. In DT40, USP1 autocleavage is not stimulated by DNA damage, and expressing a noncleavable mutant in the USP1 knockout strain partially rescues crosslinker sensitivity. We conclude that efficient DNA crosslink repair requires FANCD2 deubiquitination, whereas FANCD2 monoubiquitination is not dependent on USP1 autocleavage.     

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.     

MEN1 and FANCD2 mediate distinct mechanisms of DNA crosslink repair

Cells mutant for multiple endocrine neoplasia type I (MEN1) or any of the Fanconi anemia (FA) genes are hypersensitive to the killing effects of crosslinking agents, but the precise roles of these genes in the response to interstrand crosslinks (ICLs) are unknown. To determine if MEN1 and the FA genes function cooperatively in the same repair process or in distinct repair processes, we exploited Drosophila genetics to compare the mutation frequency and spectra of MEN1 and FANCD2 mutants and to perform genetic interaction studies. We created a novel in vivo reporter system in Drosophila based on the supF gene and showed that MEN1 mutant flies were extremely prone to single base deletions within a homopolymeric tract. FANCD2 mutants, on the other hand, had a mutation frequency and spectrum similar to wild type using this assay. In contrast to the supF results, both MEN1 and FANCD2 mutants were hypermutable using a different assay based on the lats tumor suppressor gene. The lats assay showed that FANCD2 mutants had a high frequency of large deletions, which the supF assay was not able to detect, while large deletions were rare in MEN1 mutants. Genetic interaction studies showed that neither overexpression nor loss of MEN1 modified the ICL sensitivity of FANCD2 mutants. The strikingly different mutation spectra of MEN1 and FANCD2 mutants together with lack of evidence for genetic interaction between these genes indicate MEN1 plays an essential role in ICL repair distinct from the Fanconi anemia genes.     

DNA-protein crosslinks: their induction, repair, and biological consequences

The covalent crosslinking of proteins to DNA presents a major physical challenge to the DNA metabolic machinery. DNA-protein crosslinks (DPCs) are induced by a variety of endogenous and exogenous agents (including, paradoxically, agents that are known to cause cancer as well as agents that are used to treat cancer), and yet they have not received as much attention as other types of DNA damage. This review summarizes the current state of knowledge of DPCs in terms of their induction, structures, biological consequences and possible mechanisms of repair. DPCs can be formed through several different chemistries, which is likely to affect the stability and repair of these lesions, as well as their biological consequences. The considerable discrepancy in the DPC literature reflects both the varying chemistries of this heterogeneous group of lesions and the fact that a number of different methods have been used for their analysis. In particular, research in this area has long been hampered by the inability to chemically define these lesions in intact cells and tissues. However, the emergence of proteomics as a tool for identifying specific proteins that become crosslinked to DNA has heralded a new era in our ability to study these lesions. Although there are still many unanswered questions, the identification of specific proteins crosslinked to DNA should facilitate our understanding of the down-stream effects of these lesions.     

Nucleotide excision repair eliminates unique DNA-protein cross-links from mammalian cells

DNA-protein cross-links (DPCs) present a formidable obstacle to cellular processes because they are "superbulky" compared with the majority of chemical adducts. Elimination of DPCs is critical for cell survival because their persistence can lead to cell death or halt cell cycle progression by impeding DNA and RNA synthesis. To study DPC repair, we have used DNA methyltransferases to generate unique DPC adducts in oligodeoxyribonucleotides or plasmids to monitor both in vitro excision and in vivo repair. We show that HhaI DNA methyltransferase covalently bound to an oligodeoxyribonucleotide is not efficiently excised by using mammalian cell-free extracts, but protease digestion of the full-length HhaI DNA methyltransferase-DPC yields a substrate that is efficiently removed by a process similar to nucleotide excision repair (NER). To examine the repair of that unique DPC, we have developed two plasmid-based in vivo assays for DPC repair. One assay shows that in nontranscribed regions, DPC repair is greater than 60% in 6 h. The other assay based on host cell reactivation using a green fluorescent protein demonstrates that DPCs in transcribed genes are also repaired. Using Xpg-deficient cells (NER-defective) with the in vivo host cell reactivation assay and a unique DPC indicates that NER has a role in the repair of this adduct. We also demonstrate a role for the 26 S proteasome in DPC repair. These data are consistent with a model for repair in which the polypeptide chain of a DPC is first reduced by proteolysis prior to NER.     

The FANCJ helicase unfolds DNA-protein crosslinks to promote their repair

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Fanconi anemia signaling and Mus81 cooperate to safeguard development and crosslink repair

Individuals with Fanconi anemia (FA) are susceptible to bone marrow failure, congenital abnormalities, cancer predisposition and exhibit defective DNA crosslink repair. The relationship of this repair defect to disease traits remains unclear, given that crosslink sensitivity is recapitulated in FA mouse models without most of the other disease-related features. Mice deficient in Mus81 are also defective in crosslink repair, yet MUS81 mutations have not been linked to FA. Using mice deficient in both Mus81 and the FA pathway protein FancC, we show both proteins cooperate in parallel pathways, as concomitant loss of FancC and Mus81 triggered cell-type-specific proliferation arrest, apoptosis and DNA damage accumulation in utero. Mice deficient in both FancC and Mus81 that survived to birth exhibited growth defects and an increased incidence of congenital abnormalities. This cooperativity of FancC and Mus81 in developmental outcome was also mirrored in response to crosslink damage and chromosomal integrity. Thus, our findings reveal that both pathways safeguard against DNA damage from exceeding a critical threshold that triggers proliferation arrest and apoptosis, leading to compromised in utero development.     

Differential processing of UV mimetic and interstrand crosslink damage by XPF cell extracts

We have recently developed a mammalian cell free assay in which interstrand crosslinks induce DNA synthesis in both damaged and undamaged plasmids co-incubated in the same extract. We have also shown using hamster mutants that both ERCC1 and XPF are required for the observed incorporation. Here, we show that extracts from an XPF patient cell line differentially process UV mimetic damage and interstrand crosslinks in vitro. XPF extracts are highly defective in the stimulation of repair synthesis by N-acetoxy-N- acetylaminofluorene, but are proficient in the stimulation of DNA synthesis by psoralen interstrand crosslinks. In addition, we show that extracts from the hamster UV140 mutant, which has high UV sensitivity, but moderate mitomycin C sensitivity, are similar in both assays to XPF cell extracts. These findings support the hypothesis that the activities of XPF in nucleotide excision repair (NER) and crosslink repair are separable, and that mutations in XPF patients result in the abolition of NER, but not recombinational repair pathways, which are likely to be essential as has been observed in ERCC1 homozygous –/– mice.