Formation and repair of DNA-protein crosslink damage

Klages-Mundt, Naeh L.; Li, Lei

doi:10.1007/s11427-017-9183-4

Cited by 42 publications

(33 citation statements)

References 100 publications

(213 reference statements)

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“…SPRTN, in contrast, possesses ubiquitin-binding motifs, binds PCNA, is cell-cycle regulated and activated by de-ubiquitination and ssDNA (Larsen et al, 2018;Mosbech et al, 2012;Stingele et al, 2016). In addition to the dedicated proteolytic mechanism, it was proposed previously and confirmed recently that the 26S proteasome is directly involved in DPC proteolysis (Klages-Mundt and Li, 2017;Larsen et al, 2018;Lin et al, 2008;Quievryn and Zhitkovich, 2000). In addition, the CMG helicase can bypass DPCs with the help of RTEL1 prior to proteolysis, however SPRTN and 26S proteasome activities remain the prerequisite for the full performance of a downstream repair pathway (Sparks et al, 2019).…”

Section: Introductionmentioning

confidence: 97%

“…The crosslinking agents include but are not limited to reactive aldehydes, ionizing radiation, UV light, or metal ions (Ide et al, 2018). Several spontaneous or druginduced abortive enzymatic reactions catalyzed by topoisomerases, PARP1, DNA Polb, DNMT1, etc, can also result in the formation of DPCs (Klages-Mundt and Li, 2017;Stingele et al, 2017). Canonical repair pathways, including homologous recombination (HR) and nucleotide excision repair (NER), are required for cell survival in the presence of DPCs (de Graaf et al, 2009;Nakano et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

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The Aspartic Protease Ddi1 Contributes to DNA-Protein Crosslink Repair in Yeast

Serbyn

Noireterre

Bagdiul

et al. 2019

Preprint

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Naturally occurring or drug-induced DNA-protein crosslinks (DPCs) interfere with key DNA transactions if not timely repaired. The unique family of DPC-specific proteases Wss1/SPRTN targets DPC protein moieties for degradation, including topoisomerase-1 trapped in covalent crosslinks (Top1ccs). Here we describe that the efficient DPC disassembly requires Ddi1, another conserved predicted protease in Saccharomyces cerevisiae. We found Ddi1 in a genetic screen of the tdp1wss1 mutant defective in Top1cc processing. Ddi1 is recruited to a persistent Top1cc-like DPC lesion in an S-phase dependent manner to assist eviction of crosslinked protein from DNA. Loss of Ddi1 or its putative protease activity hypersensitize cells to DPC trapping agents independently from Wss1 and 26S proteasome, implying its broader role in DPC repair. Among potential Ddi1 targets we found the core component of RNAP II and show that its genotoxin-induced degradation is impaired in ddi1. Together, we propose that the Ddi1 protease contributes to DPC proteolysis.

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Section: Introductionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

The Aspartic Protease Ddi1 Contributes to DNA-Protein Crosslink Repair in Yeast

Serbyn

Noireterre

Bagdiul

et al. 2019

Preprint

View full text Add to dashboard Cite

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“…DNA-protein complexes are typically dissociated in the order of seconds (Phair et al, 2004), while formation of an aberrant covalent bond abrogates this process. Persistent DNA-protein crosslinks (DPCs) are highly toxic if not resolved in a timely manner, as they cause genome instability and eventually promote cell death (Ide et al, 2018;Klages-Mundt and Li, 2017;Stingele et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

SUMO orchestrates multiple alternative DNA-protein crosslink repair pathways

Serbyn

Bagdiul

Michel

et al. 2020

Preprint

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Several endogenous metabolites, environmental agents, and therapeutic drugs promote formation of covalent DNA-protein crosslinks (DPCs). Persistent DPCs pose a serious threat to genome integrity and are eliminated by multiple repair pathways. Aberrant Top1 crosslinks to DNA, or Top1ccs, are processed by Tdp1 and Wss1 functioning in parallel pathways in Saccharomyces cerevisiae. It remains obscure how cells choose between these diverse mechanisms of DPC repair. Here we show that several SUMO biogenesis factors -Ulp1, Siz2, Slx5, Slx8 -control repair of Top1cc or an analogous DPC lesion. Genetic analysis reveals that SUMO promotes Top1cc processing in the absence of Tdp1 but has an inhibitory role if cells additionally lack Wss1. In the tdp1D wss1D mutant, the E3 SUMO ligase Siz2 stimulates sumoylation in the vicinity of the DPC, but not SUMO conjugation to Top1. This Siz2-dependent sumoylation delays DPC repair when cells progress through S and G2 phases.Our findings suggest that SUMO tunes available repair pathways to facilitate faithful DPC repair.

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“…Protein carbonylation has been found to play a vital role in the pathogenesis of numerous diseases 4 . Reactive species can also modify DNA bases, induce interand intra-strand crosslinks, promote DNA-protein crosslinks, produce sugar moiety modifications and create strand break 5 . Accumulation of DNA damage induces mutagenesis that results in carcinogenesis 6 .…”

Section: Ijpsr (2019) Volume 10 Issue 2 (Research Article)mentioning

confidence: 99%

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2019

IJPSR

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Free radicals and reactive oxygen species (ROS) production above basal levels cause irreversible damage to the cell membrane, DNA and other cellular structures by oxidizing lipids, proteins and nucleic acids resulting in dysfunction of biomolecules within cells and, finally, cell death. These free radical-induced reactions are ascertained to play multiple roles in degenerative or pathological events especially carcinogenesis. Apart from the radical scavenging activity, the antioxidant potential of a test compound or herbal preparation is also based on their protective effect against oxidant-induced damage to cellular biomolecules. In the present study, the protective effect of the methanolic extract of the three different flowers of Caesalpinia pulcherrima (yellow, pink and orange) against oxidative stress-induced damage to biomolecules like lipids, DNA and proteins were analyzed in both cell-free systems and intact cells. The results showed that the flowers of C. pulcherrima rendered significant biomolecular protection against oxidative stress, both in cell-free systems and in intact cells. INTRODUCTION: A deleterious phenomenon called the oxidative stress is caused by excessive production of free radicals and oxidants beyond the antioxidant defense. Oxidative stress induces alterations in the cell membranes and other structures such as proteins, lipids, lipoproteins and DNA 1. Such progressive adverse changes accumulate with age throughout the body. Genetics and environment factors influence these changes and modulate free radical damage, thereby causing various pathological conditions such as diabetes, cardiovascular disease, neurological disorders, ischemia, aging and cancer 2 .

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Formation and repair of DNA-protein crosslink damage

Cited by 42 publications

References 100 publications

The Aspartic Protease Ddi1 Contributes to DNA-Protein Crosslink Repair in Yeast

The Aspartic Protease Ddi1 Contributes to DNA-Protein Crosslink Repair in Yeast

SUMO orchestrates multiple alternative DNA-protein crosslink repair pathways

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