The type I interferon (IFN) receptor consists of 2 subunits, IFN-α receptor 1 (IFNAR1) and IFNAR2, which belong to the type II cytokine receptor superfamily (1). This heterodimeric complex is able to interact with IFN-α and IFN-β, resulting in the phosphorylation of Tyk2 and Jak1 that are bound to IFNAR1 and IFNAR2, respectively (2). Subsequently, the Stat proteins, Stat1 and Stat2 are phosphorylated at specific tyrosine residues, which allows the 2 proteins to form a Stat1/2 heterodimer based on SH2/phosphotyrosine interactions. The formation of this heterodimer facilitates its association with IFN regulatory factor (IRF)9 to form an active heterotrimeric transcription factor called IFN-stimulated gene factor (ISGF)3. ISGF3 targets specific sequences such as IFN-stimulated response element and IFN-γ-activated sequence in the promoters of IFN-stimulated genes, leading to the establishment of antiviral status (3).

After type I IFN binds to its cognate type I IFN receptor, the receptor is downregulated by endocytosis mediated by cargo-specific clathrin machinery, and degraded via the lysosomal and proteosomal pathways in order to limit the magnitude and duration of IFN signaling (4,5). The adaptin protein 2 complex, a component of the cargo-specific clathrin machinery recognizes the Tyr-based endocytic motif of IFNAR1, leading to the efficient endocytosis of IFNAR1 (5). The Skip, Cullin, F-box containing complex β-TrCP E3 ubiquitin ligase mediates the ubiquitination of IFNAR1 in a phosphorylation-dependent manner, eventually designating IFNAR1 for lysosomal degradation (5). Catalytic activation of Tyk2 is required for these events but is not essential for IFNAR1 internalization (6). Conversely, it has been also reported that Tyk2 is essential for the stable cell surface expression of IFNAR1 and stabilizes IFNAR1 by its interaction in the basal condition (in the absence of ligand) (7). Further studies have revealed that binding of Tyk2 in the proximity of the Tyr-based linear motif of IFNAR1 is required to prevent IFNAR1 internalization and to maintain its cell surface expression by physically shielding the Tyr-based motif from recognition by AP2, a component of the endocytic cargo machinery (8).

The human hepatitis B virus (HBV) induces acute and chronic hepatitis and is closely associated with the incidence of human liver cancer (9). Among the 4 proteins that are derived from the HBV genome, the hepatitis B virus X (HBX) protein is involved in multiple signaling pathways associated with cell survival and proliferation. Cell signal transduction pathways that are activated by HBX include the Jak1/Stat3, PI-3 kinase pathways (10–13), and the Ras/Raf/MAPK signaling cascade which leads to NF-κB activation (14,15). HBX expression also increases reactive oxygen species via calcium signaling and cellular kinases, resulting in the activation of transcription factors NF-κB and Stat3 (10). Studies have revealed that HBV-induced oxidative stress also stimulates the translocation of Raf-1. Src inhibitors or a dominant negative PAK mutant abolishes HBX-mediated Raf-1 mitochondrial translocation (16). Recently, we have shown that HBX-mediated up-regulation of Foxo4 plays a critical role in the prevention of oxidative stress-induced apoptosis in a liver cell line (17).

Based on our observation that HBX induces the production of type I IFN by the activation of Stat1 (18), we believed it is likely that secreted type I IFN from HBX-expressing hepatic cells enforces antiviral signals through its binding to the cognate type I IFN receptor. We initiated this study to investigate how HBX-expressing hepatic cells overcome this unfavorable situation. Here, we reported that HBX expression downregulates type I IFN receptor, leading to disturbance of extracellular type I IFN signaling.

HBV infection afflicts more than 400 million people worldwide and accelerates the development of hepatocellular carcinoma (21). Regarding the role of HBX-mediated type I IFN production, we initially proposed that type I IFN inhibits super-infection by the virus, protecting the host and eventually maintaining chronic infection of HBV (18). We additionally propose that type I IFN mediated by HBX may play a role in inflammation which is believed to be closely related to liver carcinogenesis on the basis of mounting evidence from preclinical and clinical studies that persistent inflammation functions as a driving force in the development of cancer (22,23). However, the autocrine or paracrine effects of the released type I IFN from HBV-infected hepatic cells are yet unknown. Type I IFN enforces antiviral status through its binding to the cognate receptor; how do the HBV-infected hepatic cells respond to this unfavorable condition? In this study, we report the answer to this question; HBX downregulates IFNAR1, leading to avoidance of extracellular type I IFN-mediated signaling.

Several viruses have evolved strategies of immune evasion to impair type I IFN signaling pathways. The E6 protein of human papillomavirus (HPV) 18 has been shown to selectively interact with Tyk2 and block its activation (24). Japanese encephalitis virus infection also selectively impairs Tyk2 phosphorylation and West Nile virus infection hinders the phosphorylation of both Tyk2 and Jak1 (25,26); however, the mediators of this blockade are unknown in both cases. Other viruses affect immune escape by causing a blockage of IFN signaling at the level of Stat activation. The V protein of Sendai virus 5 and other paramyxoviruses target the Stat protein for degradation and the Sendai virus C protein interferes with Stat phosphorylation (27,28). In addition, the E7 protein of HPV impairs the assembly of IRF9 and the E1A protein of adenovirus impedes the interaction of Stat1 with transcriptional machinery (29,30). Recently, the hepatitis C virus has been shown to interfere with Stat1 activation by up-regulation of protein phosphatase 2A and the RIF protein of Kaposi’s sarcoma associated herpesvirus forms inhibitory complexes with several proteins including Tyk2, Jak1, Stat1 and Stat2, leading to the inhibition of Stat1 and Stat2 (31,32). Reviewing these lines of evidence, downregulation of Tyk2 mediated by HBX is a unique mechanism different from dephosphorylation of Tyk2 in Chang cells and, eventually leads to cytosolic localization of IFNAR1. In this study, we provide evidence of a novel mechanism for the modulation of type I IFN signaling by the downregulation of Tyk2. Related to regulation via Tyk2, another study has reported that expression of SHP-1 is diminished or abolished in most lymphoma cell lines and in some colorectal cancer (33–35). Conversely, transient expression of SHP-1 inhibits tumor cell growth via downregulation of Jak1 and Tyk2 (33). Our future study will be directed towards exploring whether protein phosphatases including SHP-1 are associated with the specific degradation of Tyk2. Type I IFN signaling pathway involves the binding of type I IFN to its receptor, and then phosphorylation of Jak1 and Tyk2 takes place followed by the activation of Stat1. We herein suggest that the phosphorylation of Stat1 is independent of Tyk2 at least in the Chang-HBX cells.

In addition, we also observed that IFNAR1 is regulated at the transcriptional level. It is possible that HBX induces a transcription factor with suppressor activity to bind to the promoter of IFNAR1 as seen in the case of PTEN promoter, which is occupied by the p53 tumor suppressor in the presence of HBX (36). HBX might cause an instability in IFNAR1 mRNA by inducing the release of a RNA-binding protein such as HuR from the 3′ untranslated region (37). Moreover, HBX may induce methylation at a G/C region in the IFNAR1 promoter via the upregulation of DNA methyltransferase (DNMT) 1 activity; HBX has similarly been reported to activate DNMT1, resulting in suppression of p16(INK1a), a cyclin-dependent kinase inhibitor through hypermethylation of the p16(INK1a) promoter (38). The detailed mechanism of HBX-mediated suppression of IFNAR1 at the transcriptional level remains under investigation.