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Mitomycin C reduces abundance of replication forks but not rates of fork progression in primary and transformed human cells.


ABSTRACT: DNA crosslinks can block replication in vitro and slow down S phase progression in vivo. We characterized the effect of mitomycin C crosslinker on S phase globally and on individual replication forks in wild type and FANCD2-deficient human cells. FANCD2 is critical to crosslink repair, and is also implicated in facilitating DNA replication. We used DNA fiber analysis to demonstrate persistent reduction in abundance but not progression rate of replication forks during an S phase of MMC-treated cells. FANCD2 deficiency did not eliminate this phenotype. Immunoprecipitation of EdU-labeled DNA indicated that replication was not suppressed in the domains that were undergoing response to MMC as marked by the presence of ?H2AX, and in fact ?H2AX was overrepresented on DNA that had replicated immediately after MMC in wild type through less so in FANCD2-depleted cells. FANCD2-depleted cells also produced fewer tracks of uninterrupted replication of up to 240Kb long, regardless of MMC treatment. Overall, the data suggest that crosslinks may not pose a block to S phase as a whole, but instead profoundly change its progress by reducing density of replication forks and causing at least a fraction of forks to operate within a DNA damage response-altered chromatin.

SUBMITTER: Kehrli KR 

PROVIDER: S-EPMC4278321 | biostudies-literature | 2014

REPOSITORIES: biostudies-literature

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Mitomycin C reduces abundance of replication forks but not rates of fork progression in primary and transformed human cells.

Kehrli Keffy R M KR   Sidorova Julia M JM  

Oncoscience 20140101 7


DNA crosslinks can block replication <i>in vitro</i> and slow down S phase progression <i>in vivo</i>. We characterized the effect of mitomycin C crosslinker on S phase globally and on individual replication forks in wild type and FANCD2-deficient human cells. FANCD2 is critical to crosslink repair, and is also implicated in facilitating DNA replication. We used DNA fiber analysis to demonstrate persistent reduction in abundance but not progression rate of replication forks during an S phase of  ...[more]

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