In support of LGK974 this hypothesis, we demonstrate that STA-21 treatment induces
significant disorganization of the MT network in Huh-7.5 cells (Fig. 6A). α-Tubulin displayed a dispersed punctate pattern in STA-21 treated cells, which was not observed in control treated cells, that displayed an organized MT network with long intact MTs radiating from the MT-organizing center (MTOC). If the STAT3/STMN1 interaction plays a role in HCV replication then the siRNA mediated knockdown of STMN1 should restore HCV replication in the presence of STA-21. To establish if this observation was dependent on STMN1, investigation of α-tubulin cellular distribution was performed in the presence of an siRNA knockdown of STMN1 (Fig. 6C) and STA-21 treatment (Fig. 6B). As predicted, siRNA knockdown of STMN1
rescued the effect of MT disorganization induced by STA-21. We therefore monitored JFH-1 RNA in the presence of STMN1 knockdown and STA-21 treatment and showed that under these conditions a significant but partial rebound selleck products in HCV RNA levels occurred (Fig. 6D). This partial rescue was most likely attributed to some residual STMN1 expression and the likelihood that STAT3 impacts HCV replication through multiple mechanisms. These results indicate that STAT3 may play an important role in mediating MT dynamics to create a cellular environment favorable for HCV replication. The number of host factors that impact the HCV life cycle continues to grow. These factors have been shown to play roles in multiple facets of the HCV life
cycle, including entry, RNA replication, and egress.[24] Early work using the HCV replicon model and more recently using a genome-wide siRNA screen have implicated STAT3 as a candidate host factor playing a role in HCV replication.[1, 2] However, to date the role of STAT3 in the HCV life cycle has been observational and this raises the Methane monooxygenase question of how STAT3 exerts its effect on HCV replication, whether it is in an indirect or a direct manner. The highly pleiotropic nature of STAT3 due in part to its ability to be activated by such a large variety of growth factors and cytokines suggests that STAT3′s impact on HCV replication will be multifactorial. It is likely that in the liver, during an active HCV infection, STAT3 activation may occur by way of multiple pathways including virally induced oxidative stress, IL-6, LIF, and EGF. To this end we have shown in vitro that LIF treatment of Huh-7.5 cells markedly increases HCV RNA replication. Oxidative stress is a known activator of STAT3 and as such it is not surprising that HCV replication is capable of activating STAT3.[2] Our study extends the work of Waris et al.