Abstract
BackgroundBase-excision repair (BER) is a central DNA repair mechanism responsible for the maintenance of genome integrity. Accordingly, BER defects have been implicated in cancer, presumably by precipitating cellular transformation through an increase in the occurrence of mutations. Hence, tight adaptation of BER capacity is essential for DNA stability. However, counterintuitive to this, prolonged exposure of cells to pro-inflammatory molecules or DNA-damaging agents causes a BER deficiency by downregulating the central scaffold protein XRCC1. The rationale for this XRCC1 downregulation in response to persistent DNA damage remains enigmatic. Based on our previous findings that XRCC1 downregulation causes wide-ranging anabolic changes, we hypothesised that BER depletion could enhance cellular survival under stress, such as nutrient restriction.ResultsHere, we demonstrate that persistent single-strand breaks (SSBs) caused by XRCC1 downregulation trigger the integrated stress response (ISR) to promote cellular survival under nutrient-restricted conditions. ISR activation depends on DNA damage signalling via ATM, which triggers PERK-mediated eIF2α phosphorylation, increasing translation of the stress-response factor ATF4. Furthermore, we demonstrate that SSBs, induced either through depletion of the transcription factor Sp1, responsible for XRCC1 levels, or through prolonged oxidative stress, trigger ISR-mediated cell survival under nutrient restriction as well. Finally, the ISR pathway can also be initiated by persistent DNA double-strand breaks.ConclusionsOur results uncover a previously unappreciated connection between persistent DNA damage, caused by a decrease in BER capacity or direct induction of DNA damage, and the ISR pathway that supports cell survival in response to genotoxic stress with implications for tumour biology and beyond.
Highlights
Base-excision repair (BER) is a central DNA repair mechanism responsible for the maintenance of genome integrity
We have previously shown that a BER deficiency, brought about by downregulation of XRCC1 by siRNA, induces wide-ranging gene-expression changes in cellular metabolism that are comparable to changes found in tumours [28]
XRCC1 KD imparts human fibroblasts with a survival advantage in nutrient-restricted conditions Why do persistently stressed cells lower the expression of XRCC1? Based on our previous findings, we hypothesised that the downregulation of BER capacity would lead to a metabolic rewiring towards nutritional selfsufficiency that would be advantageous for cells to survive under nutrient-starved conditions
Summary
Base-excision repair (BER) is a central DNA repair mechanism responsible for the maintenance of genome integrity. Counterintuitive to this, prolonged exposure of cells to pro-inflammatory molecules or DNA-damaging agents causes a BER deficiency by downregulating the central scaffold protein XRCC1. The rationale for this XRCC1 downregulation in response to persistent DNA damage remains enigmatic. Even in the absence of exogenous noxious influences, DNA is prone to spontaneous alterations, due to its chemical reactivity in the aquatic milieu and reactive side-products that are created by the cellular metabolism [4] This leads to a high level of DNA lesions even under physiological ‘unstressed’ circumstances that are in constant need of repair to avert potential mutagenic and cytotoxic consequences [5]. To avoid deleterious consequences of mutations and maintain DNA integrity, the capacity for DNA repair has to be tightly adapted to cellular needs [24, 25]
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