T0901317 inhibits cisplatin-induced apoptosis in ovarian cancer cells [corrected].

OBJECTIVE: To determine the function of T0901317 in combination treatment with cisplatin in ovarian cancer cells. METHODS: We screened the effects of 3 nuclear hormone receptor ligands on cell viability in a panel of ovarian cancer cell lines. T0901317 regulation of apoptosis and cell cycle regulators was determined when applied as a single agent or in combination with cisplatin. RESULTS: Surprisingly, the liver X receptor agonist T0901317 had no significant effects on a panel of 7 ovarian cancer cell lines as a single agent. T0901317 does, however, significantly decrease cisplatin efficacy in at least 3 ovarian cancer cell lines. T0901317 reduces cisplatin-induced apoptosis and reverses cisplatin-induced expression of cell cycle regulators. T0901317 seems to work in a liver X receptor-, pregnane X receptor-, and farnesoid X receptor-independent manner, as agonists of these nuclear hormone receptors did not show similar effects. Interestingly, in the A2780-cp drug-resistant cell line, the effect of T0901317 is lost, suggesting that the pathways stimulated by T0901317 to reduce cisplatin efficacy could be inherently active features of the selected resistance. CONCLUSIONS: Together, these data suggest that T0901317 inhibits cisplatin in some ovarian cancer cells. These data provide an avenue to investigate when T0901317 may be acting to promote tumor survival and drug resistance through control of apoptosis and when it may be acting as an antitumor agent as has been previously reported.

Silencing of USP18 potentiates the antiviral activity of interferon against hepatitis C virus infection.

BACKGROUND & AIMS: Modulation of the host innate immune response is an attractive means of inhibiting hepatitis C virus (HCV) replication. Having previously determined that expression of the interferon-sensitive gene (ISG)15 protease USP18 is increased in the liver biopsy specimens of patients who do not respond to interferon (IFN)-alfa therapy, we hypothesized that USP18 might hinder the ability of IFN to inhibit HCV replication. METHODS: The role of USP18 in IFN antiviral activity was examined using an in vitro model of HCV replication that reproduces the full viral life cycle. USP18 was silenced specifically using small inhibitory RNAs (siRNAs), and the dose response of HCV replication and infectious virus production to IFN-alfa was measured. RESULTS: The siRNA knockdown of USP18 in human cells consistently potentiated the ability of IFN to inhibit HCV-RNA replication and infectious virus particle production by a factor of 1-2 log(10). USP18 knockdown also resulted in a number of cellular changes consistent with increased sensitivity to IFN. Decreasing USP18 expression led to increased cellular protein ISGylation in response to exogenous IFN-alfa, prolonged tyrosine phosphorylation of signal transducer and activation of transcription (STAT1), and a general enhancement of IFN-stimulated gene expression. CONCLUSIONS: These data suggest that USP18 modulates the anti-HCV type I IFN response, and is a possible therapeutic target for the treatment of HCV infection.