Abstract
Bloom's syndrome is a rare human autosomal recessive disorder that combines a marked genetic instability and an increased risk of developing all types of cancers and which results from mutations in both copies of the BLM gene encoding a RecQ 3'-5' DNA helicase. We recently showed that BLM is phosphorylated and excluded from the nuclear matrix during mitosis. We now show that the phosphorylated mitotic BLM protein is associated with a 3'-5' DNA helicase activity and interacts with topoisomerase III alpha. We demonstrate that in mitosis-arrested cells, ionizing radiation and roscovitine treatment both result in the reversion of BLM phosphorylation, suggesting that BLM could be dephosphorylated through the inhibition of cdc2 kinase. This was supported further by our data showing that cdc2 kinase activity is inhibited in gamma-irradiated mitotic cells. Finally we show that after ionizing radiation, BLM is not involved in the establishment of the mitotic DNA damage checkpoint but is subjected to a subcellular compartment change. These findings lead us to propose that BLM may be phosphorylated during mitosis, probably through the cdc2 pathway, to form a pool of rapidly available active protein. Inhibition of cdc2 kinase after ionizing radiation would lead to BLM dephosphorylation and possibly to BLM recruitment to some specific sites for repair.
Highlights
Mutations in both copies of the BLM gene give rise to Bloom’s syndrome (BS),1 a rare disorder characterized by marked genetic instability combined with a greatly increased predisposi
We first showed that the mitotic BLM protein is associated with a 3Ј-5Ј DNA helicase activity and interacts with topoisomerase III␣, and this led us to wonder whether BLM could play a functional role during mitosis
We found that the mitotic BLM protein was dephosphorylated after ionizing radiation, suggesting that BLM could be involved in the cellular response to DNA damage during mitosis
Summary
Mutations in both copies of the BLM gene give rise to Bloom’s syndrome (BS), a rare disorder characterized by marked genetic instability combined with a greatly increased predisposi-. We showed recently that BLM is phosphorylated during mitosis both in cells treated with microtubule-disrupting agents and in mitotic cells isolated from untreated asynchronous populations and that mitotic phosphorylated BLM is excluded from the nuclear matrix and is not degraded via the ubiquitin-proteasome pathway (4). These data prompted us to investigate further the possible role of BLM phosphorylation in mitosis. If BLM acts in mitosis-arrested cells in the same pathways as those described for exponentially growing cells, it could be involved in the cellular response to DNA damage. Smits et al (12) showed for the first time that responses to DNA damage in mammalian cells are not restricted to the interphase and occur during mitosis through a mitotic DNA damage checkpoint that blocks the exit from mitosis
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