In response to DNA damage, eukaryotic cells activate ATM-Chk2 and/or ATR-Chk1 to arrest the cell cycle and initiate DNA repair. We show that, in the absence of p53, cells depend on a third cell-cycle checkpoint pathway involving p38MAPK/MK2 for cell-cycle arrest and survival after DNA damage. MK2 depletion in p53-deficient cells, but not in p53 wild-type cells, caused abrogation of the Cdc25A-mediated S phase checkpoint after cisplatin exposure and loss of the Cdc25B-mediated G2/M checkpoint following doxorubicin treatment, resulting in mitotic catastrophe and pronounced regression of murine tumors in vivo. We show that the Chk1 inhibitor UCN-01 also potently inhibits MK2, suggesting that its clinical efficacy results from the simultaneous disruption of two critical checkpoint pathways in p53-defective cells.
Summary Mass spectrometry has been widely used to analyze biological samples and has evolved into an indispensable tool for proteomics research. Our desire to understand the proteome has led to new technologies that push the boundary of mass spectrometry capabilities, which in return has allowed mass spectrometry to address an ever-increasing array of biological questions. The recent development of a novel mass spectrometer (Orbitrap) and new dissociation methods such as electron transfer dissociation have made possible exciting new areas of proteomic application. Although bottom-up proteomics (analysis of proteolytic peptide mixtures) remains the workhorse for proteomic analysis, middle- and top-down strategies (analysis of longer peptides and intact proteins, respectively) should allow more complete characterization of protein isoforms and post-translational modifications. Finally, stable isotope labeling strategies have transformed mass spectrometry from merely descriptive to a tool for measuring dynamic changes in protein expression, interaction and modification.
SUMMARY Central to the replication checkpoint are two protein kinases, ATR, and its downstream target kinase, Chk1. Signaling pathways leading to activation of ATR-Chk1 have been extensively investigated; however, events that mediate checkpoint termination and replication fork restart are less well understood. Here, we define a coupled activation-destruction mechanism of Chk1 that regulates checkpoint termination and cellular sensitivity to replicative stress. DNA damage-induced phosphorylation or mutation of a conserved motif of Chk1 both activates Chk1 and exposes a degron-like region at the carboxyl-terminus of Chk1 to a Fbx6-containing SCF (Skp1-Cul1-F-box) E3 ligase, which mediates the ubiquitination and degradation of Chk1, and, in turn, terminates the checkpoint. The expression levels of Chk1 and Fbx6 proteins showed an inverse correlation in both cultured cancer cell lines and in a small cohort of human breast tumor tissues. Further, we show that low levels of Fbx6 and consequent impairment of replication stress-induced Chk1 degradation are associated with cancer cell resistance to killing by the chemotherapeutic agent, camptothecin (CPT). We propose that Fbx6-dependent Chk1 degradation contributes to S-phase checkpoint termination, and that a defect in this mechanism might increase tumor cell resistance to certain anticancer drugs.
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