DUSP6 regulates drug sensitivity by modulating DNA damage response.

BACKGROUND: Dual specificity phosphatase 6 (DUSP6) is a member of a family of mitogen-activated protein kinase phosphatases that dephosphorylates and inhibits activated ERK1/2. Dual specificity phosphatase 6 is dynamically regulated in developmental and pathological conditions such as cancer. METHODS: Cancer cell lines were made deficient in DUSP6 by siRNA and shRNA silencing. Sensitivity to anti-EGFR and chemotherapeutic agents was determined in viability and apoptosis assays, and in xenografts established in SCID mice. Cellular effects of DUSP6 inactivation were analysed by proteomic methods, followed by analysis of markers of DNA damage response (DDR) and cell cycle. RESULTS: We determined that depletion of DUSP6 reduced the viability of cancer cell lines and increased the cytotoxicity of EGFR and other targeted inhibitors, and cytotoxic agents, in vitro and in vivo. Subsequent phosphoproteomic analysis indicated DUSP6 depletion significantly activated CHEK2 and p38, which function in the DDR pathway, and elevated levels of phosphorylated H2AX, ATM, and CHEK2, for the first time identifying a role for DUSP6 in regulating DDR. CONCLUSION: Our results provide a novel insight into the DUSP6 function in regulating genomic integrity and sensitivity to chemotherapy in cancer.

Dual inhibition of SRC and Aurora kinases induces postmitotic attachment defects and cell death.

Increased activity of SRC family kinases promotes tumor invasion and metastasis, and overexpression of the mitotic regulator Aurora kinase A (AURKA) drives tumor aneuploidy and chromosomal instability. These functions nominate SRC and AURKA as valuable therapeutic targets for cancer, and inhibitors for SRC and Aurora kinases are now being used in the clinic. In this study, we demonstrate potent synergy between multiple inhibitors of Aurora and SRC kinases in ovarian and colorectal cancer cell lines, but not in normal ovarian epithelial cell lines. Combination of Aurora and SRC inhibitors selectively killed cells that have undergone a preceding aberrant mitosis, and was associated with a postmitotic reattachment defect, and selective removal of aneuploid cell populations. Combined inhibition of Aurora kinase and SRC potentiated dasatinib-dependent loss of activated (Y(416)-phosphorylated) SRC. SRC and AURKA share a common interaction partner, NEDD9, which serves as a scaffolding protein with activities in cell attachment and mitotic control, suggesting SRC and AURKA might interact directly. In vitro, we observed physical interaction and mutual cross-phosphorylation between SRC and AURKA that enhanced SRC kinase activity. Together, these findings suggest that combination of SRC and Aurora-targeting inhibitors in the clinic may be a productive strategy.

Telomere dynamics in response to chemotherapy.

The use of chemotherapy provides an essential arm in the treatment of a number of cancers. The biological feature common to all cancerous cells that sensitizes them to chemotherapeutic agents is their elevated division rate. Rapidly dividing cells, such as tumor cells, are more sensitive to chemotherapeutic agents that act to initiate pathways leading to cell death, a process enhanced in cells with compromised DNA damage responses. The toxicity accompanying chemotherapy is due to side-effects induced in normal regenerative tissues which also have relatively high replication rates, such as hair follicles, the hematopoietic system, the gastrointestinal system, the germline and skin cells. While the side-effects of chemotherapy may be tolerated by the patient, the long term impact of the cytotoxic effects of chemotherapy on healthy tissues is only now becoming apparent. Chemotherapy-induced cytotoxicity in regenerative tissues requires multiple cell divisions in order to reconstitute the affected tissues. At least in part as a consequence of these extra divisions, telomeres in individuals treated with chemotherapy are shorter than age-matched control individuals who have never been exposed to these drugs. Given the essential role of telomeres in regulating cellular aging and chromosomal stability, it is possible that the prematurely shortened telomeres that arise following chemotherapy may impact the long-term replicative potential of these tissues. This review is focused on how telomeres may be modulated, directly or indirectly, by anticancer drugs and the potential long-term consequences of accelerated telomere shortening in healthy tissue as a result of current cancer treatment protocols.

Fatty acid protection from palmitic acid-induced apoptosis is lost following PI3-kinase inhibition.

We have previously shown that saturated fatty acids induce DNA damage and cause apoptotic cell death in insulin-producing beta-cells. Here we examine further the effects of single or combined dietary fatty acids on RINm5F survival or cell death signalling. Palmitate and stearate, but not linoleate, oleate or palmitoylmethyl ester, induced growth inhibition and increased apoptosis in RINm5F cells following 24 h exposure. Co-incubation with inhibitors of ceramide synthesis, myriocin or fumonisin B(1), did not improve viability of palmitic acid treated RINm5F cells. The inhibitor of inducible nitric oxide synthase, 1400 W, similarly had no protective effect. However, linoleic acid protected against palmitic acid-induced apoptotic and necrotic cell death. The specific pharmacological inhibitors of phosphatidylinositol 3-kinase, LY294002 and wortmannin, abolished the protective effect of linoleic acid on apoptosis but not on necrosis. These data show that the growth inhibitory and apoptosis-inducing effect of the saturated fatty acid palmitate on RINm5F cells is prevented by co-incubation with the polyunsaturated fatty acid linoleate but not inhibitors of ceramide or nitric oxide generation. A key role for phosphatidylinositol 3-kinase in mediating the linoleic-acid reduction in apoptosis is suggested.

Cytokines and nitric oxide inhibit the enzyme activity of catalase but not its protein or mRNA expression in insulin-producing cells.

Pancreatic beta-cells have low activities of the antioxidant enzyme catalase. Nitric oxide interacts with the haem group of catalase inhibiting its activity. We have studied the activity of catalase in beta-cells under conditions mimicking prediabetes and in which nitric oxide is generated from cytokine treatment in vitro. We also studied whether there is regulation of catalase enzyme activity by nitric oxide at the protein or gene expression level. RINm5F insulin-producing cells, treated for 24 h with cytokines, showed increased medium nitrite production (17+/-2.2 vs 0.3+/-0.2 pmol/ micro g protein) and significantly decreased cellular catalase activity (42.4+/-4.5%) compared with control cells. A similar reduction was seen in catalase-overexpressing RIN-CAT cells and in rat or human pancreatic islets of Langerhans. Catalase activity was also suppressed by the long-acting nitric oxide donor diethylenetriamine/nitric oxide adduct (Deta-NO) and this inhibition was reversible. The inhibition of catalase activity by cytokines in RINm5F cells was significantly reversed by the addition of the nitric oxide synthase 2 (NOS2) inhibitors nitro monomethylarginine or N-(3-(aminomethyl)benzyl)acetamidine (1400W). Protein expression was found to be unchanged in cytokine- or Deta-NO-treated RINm5F cells, while mRNA expression was marginally increased. We have shown that inhibition of catalase activity by cytokines is nitric oxide dependent and propose that this inhibition may confer increased susceptibility to cytokine- or nitric oxide-induced cell killing.