JAK/STAT inhibition with ruxolitinib enhances oncolytic virotherapy in non-small cell lung cancer models.

The concept of using viruses to treat cancer has now shown proof of concept in several recent clinical trials, leading to the first FDA approval of virotherapy for melanoma last year. Vesicular stomatitis virus (VSV) is a promising oncolytic virus that has inhibitory effects on a number of cancer types including non-small cell lung cancer. One of the major mechanisms of resistance to VSV infection is the type I interferon (IFN) response, leading to the development of VSV expressing IFNß which will lead to resistance of viral replication in normal cells which have intact IFN signaling but allow replication in cancer cells with defective IFNß signaling. However, some cancer cells have intact or partially intact IFN signaling pathways leading to resistance to virotherapy. Here we utilized JAK/STAT inhibitor, ruxolitinib, in combination with VSV-IFNß to see if inhibition of JAK/STAT signaling will enhance VSV-IFNß therapy for lung cancer. We used five human and two murine NSCLC cell lines in vitro, and the combination treatment was assayed for cytotoxicity. We performed western blots on treated cells to see the effects of ruxolitinib on JAK/STAT signaling and PDL-1 expression in treated cells. Finally, the combination of VSV-IFNß and ruxolitinib was tested in an immune competent murine model of NSCLC. Ruxolitinib enhanced virotherapy in resistant and sensitive NSCLC cells. The addition of ruxolitinib inhibited STAT1 phosphorylation and to a lesser extent STAT3 phosphorylation. Ruxolitinib treatment prevented NSCLC cells from enhancing PDL-1 expression in response to virotherapy. Combination ruxolitinib and VSV-IFNß therapy resulted in a trend toward improved survival of mice without substantially effecting PDL-1 levels or levels of immune infiltration into the tumor. These results support further clinical evaluation of the combination of JAK/STAT inhibition with virotherapy.

Trichloroethylene perturbs HNF4a expression and activity in the developing chick heart.

Exposure to trichloroethylene (TCE) is linked to formation of congenital heart defects in humans and animals. Prior interactome analysis identified the transcription factor, Hepatocyte Nuclear Factor 4 alpha (HNF4a), as a potential target of TCE exposure. As a role for HNF4a is unknown in the heart, we examined developing avian hearts for HNF4a expression and for sensitivity to TCE and the HNF4a agonist, Benfluorex. In vitro analysis using a HNF4a reporter construct showed both TCE and HFN4a to be antagonists of HNF4a-mediated transcription at the concentrations tested. HNF4a mRNA is expressed transiently in the embryonic heart during valve formation and cardiac development. Embryos were examined for altered gene expression in the presence of TCE or Benfluorex. TCE altered expression of selected mRNAs including HNF4a, TRAF6 and CYP2C45. There was a transition between inhibition and induction of marker gene expression in embryos as TCE concentration increased. Benfluorex was largely inhibitory to selected markers. Echocardiography of exposed embryos showed reduced cardiac function with both TCE and Benfluorex. Cardiac contraction was reduced by 29% and 23%, respectively at 10 ppb. The effects of TCE and Benfluorex on autocrine regulation of HNF4a, selected markers and cardiac function argue for a functional interaction of TCE and HNF4a. Further, the dose-sensitive shift between inhibition and induction of marker expression may explain the nonmonotonic-like dose response observed with TCE exposure in the heart.