The mammalian DNA replication elongation checkpoint: Implication of Chk1 and relationship with origin firing as determined by single DNA molecule and single cell analyses

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Abstract

The regulation of DNA replication initiation is well documented, for both unperturbed and damaged cells. The regulation of elongation, or fork velocity, however, has only recently been revealed with the advent of new techniques allowing us to view DNA replication at the single cell and single DNA molecule levels. Normally in S phase, the progression of replication forks and their stability are regulated by the ATR-Claspin-Chk1 pathway. We recently showed that replication fork velocity varies across the human genome in normal and cancer cells, but that the velocity of a given fork is positively correlated with the distance between origins on the same DNA fiber.19 Accordingly, in DNA replication-deficient Bloom's syndrome cells, reduced fork velocity is associated with an increased density of replication origins.21 Replication elongation is also regulated in response to DNA damage. In human colon carcinoma cells treated with the topoisomerase I inhibitor camptothecin, DNA replication is inhibited both at the level of initiation and at the level of elongation through a Chk1-dependent checkpoint mechanism.10 Together, these new findings demonstrate that replication fork velocity (fork progression) is coordinated with inter-origin distance and that it can be actively slowed down by Chk1-dependent mechanisms in response to DNA damage. Thus, we propose that the intra-S phase checkpoint consist of at least three elements: (1) stabilization of damaged replication forks; (2) suppression of firing of late origins; and (3) arrest of normal ongoing forks to prevent further DNA lesions by replication of a damaged DNA template.

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Conti, C., Seiler, J. A., & Pommier, Y. (2007, November 15). The mammalian DNA replication elongation checkpoint: Implication of Chk1 and relationship with origin firing as determined by single DNA molecule and single cell analyses. Cell Cycle. Taylor and Francis Inc. https://doi.org/10.4161/cc.6.22.4932

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