SummaryMutations in RECQL4 helicase are associated with Rothmund-Thomson syndrome (RTS). A subset of RTS patients is predisposed to cancer and is sensitive to DNA damaging agents. The enhanced sensitivity of cells from RTS patients correlates with the accumulation of transcriptionally active nuclear p53. We found that in untreated normal human cells these two nuclear proteins, p53 and RECQL4, instead colocalize in the mitochondrial nucleoids. RECQL4 accumulates in mitochondria in all phases of the cell cycle except S phase and physically interacts with p53 only in the absence of DNA damage. p53-RECQL4 binding leads to the masking of the nuclear localization signal of p53. The N-terminal 84 amino acids of RECQL4 contain a mitochondrial localization signal, which causes the localization of RECQL4-p53 complex to the mitochondria. RECQL4-p53 interaction is disrupted after stress, allowing p53 translocation to the nucleus. In untreated normal cells RECQL4 optimizes de novo replication of mtDNA, which is consequently decreased in fibroblasts from RTS patients. Wild-type RECQL4-complemented RTS cells show relocalization of both RECQL4 and p53 to the mitochondria, loss of p53 activation, restoration of de novo mtDNA replication and resistance to different types of DNA damage. In cells expressing D84 RECQL4, which cannot translocate to mitochondria, all the above functions are compromised. The recruitment of p53 to the sites of de novo mtDNA replication is also regulated by RECQL4. Thus these findings elucidate the mechanism by which p53 is regulated by RECQL4 in unstressed normal cells and also delineates the mitochondrial functions of the helicase.
Mutation of BLM helicase results in the autosomal recessive disorder Bloom syndrome (BS). Patients with BS exhibit hyper-recombination and are prone to almost all forms of cancer. BLM can exhibit its anti-recombinogenic function either by dissolution of double Holliday junctions or by disruption of RAD51 nucleofilaments. We have now found that BLM can interact with the pro-recombinogenic protein RAD54 through an internal ten-residue polypeptide stretch in the N-terminal region of the helicase. The N-terminal region of BLM prevented the formation of RAD51-RAD54 complex, both in vitro and in vivo. Using the fluorescence recovery after photobleaching (FRAP) technique, we found that RAD54 and BLM rapidly and concurrently, yet transiently, bound to the chromatinized foci. Presence of BLM enhanced the mobility of both soluble and chromatinized RAD51 but not RAD54. The BLM-RAD54 interaction could occur even in absence of functional RAD51. The N-terminal 1-212 amino acids of BLM or an ATPase-dead mutant of the full-length helicase enhanced the ATPase and chromatin-remodeling activities of RAD54. These results indicate that apart from its dominant function as an anti-recombinogenic protein, BLM also has a transient pro-recombinogenic function by enhancing the activity of RAD54.
BLM helicase, the protein mutated in Bloom syndrome, is involved in signal transduction cascades after DNA damage. BLM is phosphorylated on multiple residues by different kinases either after stress induction or during mitosis. Here, we have provided evidence that both Chk1 and Chk2 phosphorylated the NH 2 -terminal 660 amino acids of BLM. An internal region within the DExH motif of BLM negatively regulated the Chk1/Chk2-dependent NH 2 -terminal phosphorylation event. Using in silico analysis involving the Chk1 structure and its known substrate specificity, we predicted that Chk1 should preferentially phosphorylate BLM on serine 646 (Ser 646 ). The prediction was validated in vitro by phosphopeptide analysis on BLM mutants and in vivo by usage of a newly generated phosphospecific polyclonal antibody. We showed that the phosphorylation at Ser 646 on BLM was constitutive and decreased rapidly after exposure to DNA damage. This resulted in the diminished interaction of BLM with nucleolin and PML isoforms, and consequently decreased BLM accumulation in the nucleolus and PML nuclear bodies. Instead, BLM relocalized to the sites of DNA damage and bound with the damage sensor protein, Nbs1. Mutant analysis confirmed that the binding to nucleolin and PML isoforms required Ser 646 phosphorylation. These results indicated that Chk1-mediated phosphorylation on BLM at Ser 646 might be a determinant for regulating subnuclear localization and could act as a marker for the activation status of BLM in response to DNA damage. Mol Cancer Res; 8(9); 1234-47. ©2010 AACR.
SummaryThe spectrum of tumors that arise owing to the overexpression of c-Myc and loss of BLM is very similar. Hence, it was hypothesized that the presence of BLM negatively regulates c-Myc functions. By using multiple isogenic cell lines, we observed that the decrease of endogenous c-Myc levels that occurs in the presence of BLM is reversed when the cells are treated with proteasome inhibitors, indicating that BLM enhances c-Myc turnover. Whereas the N-terminal region of BLM interacts with c-Myc, the rest of the helicase interacts with the c-Myc E3 ligase Fbw7. The two BLM domains act as 'clamp and/or adaptor', enhancing the binding of c-Myc to Fbw7. BLM promotes Fbw7-dependent K48-linked c-Myc ubiquitylation and its subsequent degradation in a helicase-independent manner. A subset of BLM-regulated genes that are also targets of c-Myc were determined and validated at both RNA and protein levels. To obtain an in vivo validation of the effect of BLM on c-Myc-mediated tumor initiation, isogenic cells from colon cancer cells that either do or do not express BLM had been manipulated to block c-Myc expression in a controlled manner. By using these cell lines, the metastatic potential and rate of initiation of tumors in nude mice were determined. The presence of BLM decreases c-Myc-mediated invasiveness and delays tumor initiation in a mouse xenograft model. Consequently, in tumors that express BLM but not c-Myc, we observed a decreased ratio of proliferation to apoptosis together with a suppressed expression of the angiogenesis marker CD31. Hence, partly owing to its regulation of c-Myc stability, BLM acts as a 'caretaker tumor suppressor'.
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