Abstract
In checkpoint-deficient cells, DNA double-strand breaks (DSBs) are produced during replication by the structure-specific endonuclease MUS81. The mechanism underlying MUS81-dependent cleavage, and the effect on chromosome integrity and viability of checkpoint deficient cells is only partly understood, especially in human cells. Here, we show that MUS81-induced DSBs are specifically triggered by CHK1 inhibition in a manner that is unrelated to the loss of RAD51, and does not involve formation of a RAD51 substrate. Indeed, CHK1 deficiency results in the formation of a RAD52-dependent structure that is cleaved by MUS81. Moreover, in CHK1-deficient cells depletion of RAD52, but not of MUS81, rescues chromosome instability observed after replication fork stalling. However, when RAD52 is down-regulated, recovery from replication stress requires MUS81, and loss of both these proteins results in massive cell death that can be suppressed by RAD51 depletion. Our findings reveal a novel RAD52/MUS81-dependent mechanism that promotes cell viability and genome integrity in checkpoint-deficient cells, and disclose the involvement of MUS81 to multiple processes after replication stress.
Highlights
Faithful completion of DNA replication and accurate transmission of the genetic information to daughter cells is of paramount importance
The double-strand breaks (DSBs) level was highest after CHK1 or ATR depletion, whereas RAD9 or TOPBP1 down-regulation resulted in a limited DSBs enhancement
DSBs in replication checkpoint-deficient cells are derived from MUS81-dependent cleavage of a substrate generated by RAD52 Since we showed that DSBs occurring in RAD51-depleted cells are independent from MUS81 function, we examined the possible involvement of RAD52 in generating a MUS81 substrate
Summary
Faithful completion of DNA replication and accurate transmission of the genetic information to daughter cells is of paramount importance. ATR regulates directly or indirectly the function of several proteins involved in maintaining replisome stability, promoting restart of perturbed replication forks, and controlling cell cycle arrest [3]. The coordination of these activities is needed for completing replication, and avoiding accumulation of DNA damage or chromosomal rearrangements [4]. Replication checkpoint mutants fail to resume replication without accumulating DNA damage once the cause of the arrest is removed. These mutants show chromosomal instability [1]. Studies in yeast demonstrated that collapsed forks can be processed by exonucleases or converted into unusual replication intermediates, i.e. reversed forks, which can be substrates for endonucleases [5,6,7]
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