Promote activation of ERK via activation of the upstream MAPKKK, Ras

Promote activation of ERK via activation of the upstream MAPKKK, Ras (Li et al., 2005). Activation of STAT-1 plays an important role in IFN-dependent apoptosis (Cao et al., 2015). Dual phosphorylation of STAT-1 is required for maximal activation (Varinou et al., 2003), and this occurred in cells treated with DCLF/IFN but not in cells treated with IFN or DCLF alone (Maiuri et al., 2015 and Figure 7). Not surprisingly, treatment of HepG2 cells with IFN caused phosphorylation of STAT-1 at Tyr 701 (Maiuri et al., 2015 and Figure 7) presumably via activation of JAK (Schroder et al., 2004). DCLF in the presence of IFN promoted phosphorylation of STAT-1 at Ser 727 via activated ERK (Maiuri et al., 2015). BX795 cancer Consistent with their effects on DCLF-induced ERK activation, treatment with either BAPTA/AM or 2-APB reduced DCLF/IFN-induced phosphorylation of STAT-1 at Ser 727 (Figure 7). These results indicate that cytoplasmic-free Ca�� contributes to STAT-1 activation induced by DCLF/IFN cotreatment. Interestingly, treatment with BAPTA/ AM or 2-APB did not affect IFN-induced phosphorylation of STAT-1 at Tyr 701 (Figure 7). JNK can also phosphorylate STAT-1 at Ser 727 (Zhang et al., 2004). Indeed, treatment of HepG2 cells with a JNK inhibitor eliminated the IFN-mediated enhancement of DCLF/TNF-induced cytotoxicity, suggesting that, along with ERK, JNK drives the IFN component of the DCLF/cytokine interaction (Maiuri et al., 2015). Treatment with the JNK inhibitor SP600125 eliminated DCLF/ IFN-induced phosphorylation of STAT-1 at Ser 727 without affecting IFN-mediated phosphorylation of STAT-1 at Tyr 701 (Figure 8A). These results indicate that in addition to ERK, JNK mediates activation of STAT-1 in response to DCLF/IFN and raise the question, does JNK contribute to the activation of ERK in response to DCLF treatment? The kinetics of DCLF-induced JNK activation were similar to the kinetics of DCLF-induced ERK activation (Maiuri et al., 2015). Treatment with SP600125 reduced DCLF-induced ERK activation (Figure 8B), suggesting that JNK is involved in the activation of ERK in response to DCLF treatment but is not solely responsible for it. In addition, these results raise the possibility that JNK contributes to the phosphorylation of STAT-1 at Ser 727 by promoting the activation of ERK. We and others have shown that aspirin, an NSAID not associated with IDILI, does not synergize with cytokines to kill primary human hepatocytes (Cosgrove et al., 2009) or HepG2 cells (Maiuri et al., 2015). Unlike DCLF, treatment with aspirin did not|TOXICOLOGICAL SCIENCES, 2016, Vol. 149, No.FIG. 10. Proposed mechanism of DCLF/cytokine-induced cytotoxic synergy. DCLF treatment causes early activation of the ER RG7800 manufacturer stress response pathway (Fredriksson et al., 2014). ER stress results in release of Ca�� from the ER via IP3 receptors, leading to an increase in cytoplasmic free Ca�� (Deniaud et al., 2008). Ca�� released from the ER during ER stress can participate in a feedback amplification loop, leading to persistent ER stress, which is known to be associated with apoptosis (Timmins et al., 2009). Consistent with its induction of the ER stress pathway, DCLF treatment caused an increase in intracellular Ca��. Although not shown in the diagram, TNF/IFN treatment caused a delayed enhancement of the DCLF-mediated increase in intracellular Ca��. The increase in intracellular free Ca�� contributes to the cytotoxic DCLF/cytokine interaction not only by contributing to persistent ER stress but a.Promote activation of ERK via activation of the upstream MAPKKK, Ras (Li et al., 2005). Activation of STAT-1 plays an important role in IFN-dependent apoptosis (Cao et al., 2015). Dual phosphorylation of STAT-1 is required for maximal activation (Varinou et al., 2003), and this occurred in cells treated with DCLF/IFN but not in cells treated with IFN or DCLF alone (Maiuri et al., 2015 and Figure 7). Not surprisingly, treatment of HepG2 cells with IFN caused phosphorylation of STAT-1 at Tyr 701 (Maiuri et al., 2015 and Figure 7) presumably via activation of JAK (Schroder et al., 2004). DCLF in the presence of IFN promoted phosphorylation of STAT-1 at Ser 727 via activated ERK (Maiuri et al., 2015). Consistent with their effects on DCLF-induced ERK activation, treatment with either BAPTA/AM or 2-APB reduced DCLF/IFN-induced phosphorylation of STAT-1 at Ser 727 (Figure 7). These results indicate that cytoplasmic-free Ca�� contributes to STAT-1 activation induced by DCLF/IFN cotreatment. Interestingly, treatment with BAPTA/ AM or 2-APB did not affect IFN-induced phosphorylation of STAT-1 at Tyr 701 (Figure 7). JNK can also phosphorylate STAT-1 at Ser 727 (Zhang et al., 2004). Indeed, treatment of HepG2 cells with a JNK inhibitor eliminated the IFN-mediated enhancement of DCLF/TNF-induced cytotoxicity, suggesting that, along with ERK, JNK drives the IFN component of the DCLF/cytokine interaction (Maiuri et al., 2015). Treatment with the JNK inhibitor SP600125 eliminated DCLF/ IFN-induced phosphorylation of STAT-1 at Ser 727 without affecting IFN-mediated phosphorylation of STAT-1 at Tyr 701 (Figure 8A). These results indicate that in addition to ERK, JNK mediates activation of STAT-1 in response to DCLF/IFN and raise the question, does JNK contribute to the activation of ERK in response to DCLF treatment? The kinetics of DCLF-induced JNK activation were similar to the kinetics of DCLF-induced ERK activation (Maiuri et al., 2015). Treatment with SP600125 reduced DCLF-induced ERK activation (Figure 8B), suggesting that JNK is involved in the activation of ERK in response to DCLF treatment but is not solely responsible for it. In addition, these results raise the possibility that JNK contributes to the phosphorylation of STAT-1 at Ser 727 by promoting the activation of ERK. We and others have shown that aspirin, an NSAID not associated with IDILI, does not synergize with cytokines to kill primary human hepatocytes (Cosgrove et al., 2009) or HepG2 cells (Maiuri et al., 2015). Unlike DCLF, treatment with aspirin did not|TOXICOLOGICAL SCIENCES, 2016, Vol. 149, No.FIG. 10. Proposed mechanism of DCLF/cytokine-induced cytotoxic synergy. DCLF treatment causes early activation of the ER stress response pathway (Fredriksson et al., 2014). ER stress results in release of Ca�� from the ER via IP3 receptors, leading to an increase in cytoplasmic free Ca�� (Deniaud et al., 2008). Ca�� released from the ER during ER stress can participate in a feedback amplification loop, leading to persistent ER stress, which is known to be associated with apoptosis (Timmins et al., 2009). Consistent with its induction of the ER stress pathway, DCLF treatment caused an increase in intracellular Ca��. Although not shown in the diagram, TNF/IFN treatment caused a delayed enhancement of the DCLF-mediated increase in intracellular Ca��. The increase in intracellular free Ca�� contributes to the cytotoxic DCLF/cytokine interaction not only by contributing to persistent ER stress but a.