Aruna Murti

Interferon α/β Promotes Cell Survival by Activating Nuclear Factor κB through Phosphatidylinositol 3-Kinase and Akt

Interferons (IFNs) play critical roles in host defense by modulating gene expression via activation of signal transducer and activator of transcription (STAT) factors. IFN-α/β also activates another transcription factor, nuclear factor κB (NF-κB), which protects cells against apoptotic stimuli. NF-κB activation requires the IFN-dependent association of STAT3 with the IFNAR1 chain of the IFN receptor. IFN-dependent NF-κB activation involves the sequential activation of a serine kinase cascade involving phosphatidylinositol 3-kinase (PI-3K) and Akt. Whereas constitutively active PI-3K and Akt induce NF-κB activation, Ly294002 (a PI-3K inhibitor), dominant-negative PI-3K, and kinase-dead Akt block IFN-dependent NF-κB activation. Moreover, dominant-negative PI-3K blocks IFN-promoted degradation of κBox α. Ly294002, a dominant-negative PI-3K construct, and kinase-dead Akt block IFN-promoted cell survival, enhancing apoptotic cell death. Therefore, STAT3, PI-3K, and Akt are components of an IFN signaling pathway that promotes cell survival through NF-κB activation.

Non‐conventional signal transduction by type 1 interferons: The NF‐κB pathway

Type I interferons (IFNs) regulate diverse cellular functions by modulating the expression of IFN‐stimulated genes (ISGs) through the activation of the well established signal transduction pathway of the Janus Kinase (JAK) and signal transducers and activators of transcription (STAT) proteins. Although the JAK–STAT signal transduction pathway is critical in mediating IFNs antiviral and antiproliferative activities, other signaling pathways are activated by IFNs and regulate cellular response to IFN. The NF‐κB transcription factor regulates the expression of genes involved in cell survival and immune responses. We have identified a novel IFN mediated signal pathway that leads to NF‐κB activation and demonstrate that a subset of ISGs that play key roles in cellular response to IFN is regulated by NF‐κB. This review focuses on the IFN‐induced NF‐κB activation pathway and the role of NF‐κB in ISG expression, antiviral activity and apoptosis, and the therapeutic application of IFN in cancer and infectious disease. J. Cell. Biochem. 102: 1087–1094, 2007.

The Short Form of the Interferon α/β Receptor Chain 2 Acts as a Dominant Negative for Type I Interferon Action

We have characterized the functional properties of the short form of the human interferon α/β receptor chain 2 (IFNAR2), denoted IFNAR2.1. IFNAR2.1 contains a shortened cytoplasmic domain when compared with the recently cloned full-length IFNAR2 chain (IFNAR2.2). We show that IFNα8 and IFNβ1b induce antiviral and antiproliferative activity in mouse cell transfectants expressing the human IFNAR1 chain of the receptor and induce the formation of STAT1/STAT2 dimers in IFN-stimulated response element (ISRE)-dependent gel shift assays. In contrast, coexpression of IFNAR2.1 with IFNAR1 reduces the IFN-induced antiviral, antiproliferative and ISRE-dependent gel shift binding activity conferred by IFNAR1 alone. No antiviral or antiproliferative response to IFN, nor IFN-induced ISRE-dependent gel shift binding activity, was observed when IFNAR2.1 was expressed alone in murine cells. Therefore, IFNAR2.1 acts as a dominant negative for these IFN-induced activities. Our results suggest that IFNAR2.1 represents a nonfunctional version of the full-length chain (IFNAR2.2).

Identification of CXCL11 as a STAT3-Dependent Gene Induced by IFN

IFNs selectively regulate gene expression through several signaling pathways. The present study explored the involvement of STAT3 in the IFN-induced expression of the gene encoding the CXCL11 chemokine. The CXCL11 gene was induced in IFN-sensitive Daudi cells, but not in an IFN-resistant DRST3 subline with a defective STAT3 signaling pathway. Although the IFN-stimulated gene ISG15 was induced to a similar extent in Daudi and DRST3 cells, expression of wild-type STAT3 in DRST3 cells restored the IFN inducibility of CXCL11. Reconstitution of STAT3 knockout mouse embryonic fibroblasts with wild-type STAT3, or STAT3 with the canonical STAT3 dimerization site at Y705 mutated, restored IFN inducibility of the CXCL11 gene. These data indicate that CXCL11 gene induction by IFN is STAT3 dependent, but that phosphorylation of Y705 of STAT3 is not required. Chromatin immunoprecipitation assays demonstrated that IFN treatment of Daudi and DRST3 cells induced STAT3 binding to the CXCL11 promoter. Chromatin immunoprecipitation assays also revealed that NF-κB family member p65 and IFN regulatory factor (IRF)1 were bound to CXCL11 promoter upon IFN treatment of Daudi cells. In contrast, IFN induced the binding of p50 and IRF2 to the CXCL11 promoter in DRST3 cells. The profile of promoter binding was indistinguishable in IFN-sensitive Daudi cells and DRST3 cells reconstituted with wild-type STAT3. Thus, STAT3 also plays a role in the recruitment of the transcriptional activators p65 and IRF1, and the displacement of the transcriptional repressors p50 and IRF2 from the CXCL11 promoter also appears to regulate the induction of CXCL11 gene transcription.

The Role of TRAF2 Binding to the Type I Interferon Receptor in Alternative NFκB Activation and Antiviral Response

Type I interferons (IFNs) play critical roles in the host defense by modulating gene expression through the IFN-dependent activation of STAT and NFκB transcription factors. Previous studies established that IFN activates NFκB through a classical NFκB pathway that results in IκBα degradation and formation of p50-containing NFκB complexes, as well as an alternative pathway that involves NFκB-inducing kinase and TRAF2, which results in the formation of p52-containing NFκB complexes. In this study, we examined the interaction of TRAF proteins with the type I IFN receptor. We found that TRAF2 was directly coupled to the signal-transducing IFNAR1 subunit of the IFN receptor. By immunoprecipitation, overexpression of epitope-tagged IFNAR1 constructs, and glutathione S-transferase pulldown experiments, we demonstrate that TRAF2 rapidly binds to the IFNAR1 subunit of the IFN receptor upon IFN binding. The membrane proximal half of the IFNAR1 subunit was found to directly bind TRAF2. Moreover, analysis of mouse embryo fibroblasts derived from TRAF2 knock-out mice demonstrated that TRAF2 plays a critical role in the activation of the alternative NFκB pathway by IFN, but not the classical NFκB pathway, as well as in the antiviral action of IFN. Our results place TRAF2 directly in the signaling pathway transduced through the IFNAR1 subunit of the IFN receptor. These findings provide an important insight into the molecular mechanisms by which IFN generates signals to induce its biological effects.