Nucleotide Excision Repair Eliminates Unique DNA-Protein Cross-links from Mammalian Cells

Baker, David; Wuenschell, Gerald E.; Xia, Liqun; Termini, John; Bates, Steven; Riggs, Arthur D.; O’Connor, Timothy

doi:10.1074/jbc.m702856200

Cited by 102 publications

(129 citation statements)

References 81 publications

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“…The upper size limit of DPCs amenable to NER is determined by the loading efficiency of UvrB, the damage recognition protein in NER, onto DPCs. Consistent with this mechanism, the NER incision efficiency for DNA containing DPCs varies significantly with the size of cross-linked proteins and peptides in vitro (2,46,47,51,58). Interestingly, no chromosome breakage was observed in cells following FA treatment, although the HR of DPCs proceeded through the RecBCD pathway (51), which is specific to recombination initiated at DNA double-strand breaks.…”

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confidence: 74%

Genetic Analysis of Repair and Damage Tolerance Mechanisms for DNA-Protein Cross-Links in Escherichia coli

et al. 2009

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DNA-protein cross-links (DPCs) are unique among DNA lesions in their unusually bulky nature. We have recently shown that nucleotide excision repair (NER) and RecBCD-dependent homologous recombination (HR) collaboratively alleviate the lethal effect of DPCs in Escherichia coli. In this study, to gain further insight into the damage-processing mechanism for DPCs, we assessed the sensitivities of a panel of repair-deficient E. coli mutants to DPC-inducing agents, including formaldehyde (FA) and 5-azacytidine (azaC). We show here that the damage tolerance mechanism involving HR and subsequent replication restart (RR) provides the most effective means of cell survival against DPCs. Translesion synthesis does not serve as an alternative damage tolerance mechanism for DPCs in cell survival. Elimination of DPCs from the genome relies primarily on NER, which provides a second and moderately effective means of cell survival against DPCs. Interestingly, Cho rather than UvrC seems to be an effective nuclease for the NER of DPCs. Together with the genes responsible for HR, RR, and NER, the mutation of genes involved in several aspects of DNA repair and transactions, such as recQ, xth nfo, dksA, and topA, rendered cells slightly but significantly sensitive to FA but not azaC, possibly reflecting the complexity of DPCs or cryptic lesions induced by FA. UvrD may have an additional role outside NER, since the uvrD mutation conferred a slight azaC sensitivity on cells. Finally, DNA glycosylases mitigate azaC toxicity, independently of the repair of DPCs, presumably by removing 5-azacytosine or its degradation product from the chromosome.The DNA molecules of living organisms continuously suffer from various types of damage resulting from exposure to endogenous and environmental genotoxic agents. Damage to DNA impairs the faithful propagation of genetic information during replication and transcription, exerting deleterious effects on cells (20). DNA-protein cross-links (DPCs) are unique among DNA lesions in that they are extremely bulky compared to conventional bulky lesions, such as pyrimidine photodimers and the base adducts of aromatic compounds. DPCs are produced by a number of chemical agents, such as aldehydes and heavy metal ions, and also by physical agents such as ionizing radiation and UV light (reviewed in reference 3). DPCs have also been identified in cells or nuclei treated with antitumor agents (4, 10, 44, 62). In addition, we have shown that oxanine, which is produced by nitrosative damage to guanine, mediates the formation of DPCs and polyamine cross-link adducts (49, 50, 52). Thus, understanding the repair and/or damage tolerance mechanism of this ubiquitous and unique class of DNA lesions will provide further insight into how cells maintain genetic integrity and ensure survival in the face of genomic insults. However, the repair and damage tolerance mechanisms of DPCs have long remained elusive, partly because many but not all DPC-inducing agents produce other types of DNA lesions simultaneously, making it rather...

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confidence: 74%

Genetic Analysis of Repair and Damage Tolerance Mechanisms for DNA-Protein Cross-Links in Escherichia coli

et al. 2009

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“…It has been proposed that proteins cross-linked to DNA can be proteolytically processed to generate less bulky DNA-peptide conjugates, which can be subsequently bypassed by TLS polymerases in an error-free or error-prone manner. DNA-peptide conjugates are preferable substrates for DNA repair over DNA-protein crosslinks (57)(58)(59)(60)(61). Furthermore, proteasomal inhibitors have been reported to slow down the repair of formaldehyde-induced DPCs in cells (62) and to interfere with intracellular repair of DPC-containing plasmids (58).…”

Section: Discussionmentioning

confidence: 99%

“…DNA-peptide conjugates are preferable substrates for DNA repair over DNA-protein crosslinks (57)(58)(59)(60)(61). Furthermore, proteasomal inhibitors have been reported to slow down the repair of formaldehyde-induced DPCs in cells (62) and to interfere with intracellular repair of DPC-containing plasmids (58). In addition, several in vitro replication studies using site-specific substrates containing small peptides conjugated to the major or minor groove of DNA have provided direct evidence for the ability of lesion bypass polymerases to catalyze nucleotide incorporation opposite the DNA-peptide lesions (25)(26)(27).…”

Section: Discussionmentioning

confidence: 99%

Error-prone Translesion Synthesis Past DNA-Peptide Cross-links Conjugated to the Major Groove of DNA via C5 of Thymidine

Wickramaratne

Boldry²,

Buehler

et al. 2015

Journal of Biological Chemistry

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Background: DNA-protein conjugates can be induced by reactive oxygen species and proteolytically cleaved to the corresponding peptide conjugates. Results: Polymerase bypass past C5-dT peptide conjugates catalyzed by human polymerases and gives rise to base substitutions and deletions. Conclusion: Replication past C5-T peptide conjugates is mutagenic. Significance: This study provides the first evidence for error-prone replication of DPCs cross-linked to pyrimidines in DNA.

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“…In living cells, the protein component of DPC lesions may undergo proteolytic cleavage to smaller DNA-peptide or DNAamino acid adducts, which represent a lesser block to polymerase bypass (65)(66)(67)(68). For example, yeast Wss1 protease cleaves the protein constituent of DPC at blocked replisomes (21).…”

Section: 64mentioning

confidence: 99%

Bypass of DNA-Protein Cross-links Conjugated to the 7-Deazaguanine Position of DNA by Translesion Synthesis Polymerases

Wickramaratne

Mukherjee

et al. 2016

Journal of Biological Chemistry

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DNA-protein cross-links (DPCs) are bulky DNA lesions that form both endogenously and following exposure to bis-electrophiles such as common antitumor agents. The structural and biological consequences of DPCs have not been fully elucidated due to the complexity of these adducts. The most common site of DPC formation in DNA following treatment with bis-electrophiles such as nitrogen mustards and cisplatin is the N7 position of guanine, but the resulting conjugates are hydrolytically labile and thus are not suitable for structural and biological studies. In this report, hydrolytically stable structural mimics of N7-guanine-conjugated DPCs were generated by reductive amination reactions between the Lys and Arg side chains of proteins/peptides and aldehyde groups linked to 7-deazaguanine residues in DNA. These model DPCs were subjected to in vitro replication in the presence of human translesion synthesis DNA polymerases. DPCs containing full-length proteins (11-28 kDa) or a 23-mer peptide blocked human polymerases and . DPC conjugates to a 10-mer peptide were bypassed with nucleotide insertion efficiency 50 -100-fold lower than for native G. Both human polymerase (hPol) and hPol inserted the correct base (C) opposite the 10-mer peptide cross-link, although small amounts of T were added by hPol . Molecular dynamics simulation of an hPol ternary complex containing a template-primer DNA with dCTP opposite the 10-mer peptide DPC revealed that this bulky lesion can be accommodated in the polymerase active site by aligning with the major groove of the adducted DNA within the ternary complex of polymerase and dCTP.

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Nucleotide Excision Repair Eliminates Unique DNA-Protein Cross-links from Mammalian Cells

Cited by 102 publications

References 81 publications

Genetic Analysis of Repair and Damage Tolerance Mechanisms for DNA-Protein Cross-Links in Escherichia coli

Genetic Analysis of Repair and Damage Tolerance Mechanisms for DNA-Protein Cross-Links in Escherichia coli

Error-prone Translesion Synthesis Past DNA-Peptide Cross-links Conjugated to the Major Groove of DNA via C5 of Thymidine

Bypass of DNA-Protein Cross-links Conjugated to the 7-Deazaguanine Position of DNA by Translesion Synthesis Polymerases

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