Establishment of an in vitro reporter system for screening HBx-targeting molecules

IL35 modulates HBV-related HCC progression via IL6-STAT3 signaling

Hepatocellular carcinoma (HCC) is a common malignant tumor with incidences reported worldwide along with high mortality rates. It is a significant public health concern as hepatitis B virus (HBV) infection is the leading cause of HCC. IL35, a novel heterodimeric cytokine belonging to the IL-12 family, comprises two subunits, namely IL-12p35 and Epstein-Barr virus-induced gene 3 (EBI3). They are crucial in regulating immune responses to tumors and infectious diseases. However, their function in HBV-related HCC is unclear. The objective of this study was to identify the regulatory role of IL35 in the occurrence of HBV-related HCC and its underlying molecular mechanisms. The expression of IL35 was enhanced in human HBV-related HCC tissues. HBV induction, particularly HBx, enhanced the expression of IL-35 in hepatoma cell lines. Silencing IL-35 promoted apoptosis and suppressed proliferation, cell cycle progression, migration, and invasion of HBx-induced hepatoma cells. Mechanistically, silencing IL-35 effectively inhibited the activation of the IL-6-STAT3 signaling pathway by suppressing the expression of IL-6 and nuclear import and phosphorylation of STAT3 in HBx-induced hepatoma cells. Therefore, inhibiting the IL6-STAT3 signaling pathway by silencing IL35 effectively alleviated the progression of HBV-related HCC. IL35 is a potential target for treating HBV-related HCC.

Homeobox protein MSX-1 restricts hepatitis B virus by promoting ubiquitin-independent proteasomal degradation of HBx protein

Hepatitis B virus (HBV) X protein (HBx) is a key factor for regulating viral transcription and replication. We recently characterized homeobox protein MSX-1 (MSX1) as a host restriction factor that inhibits HBV gene expression and genome replication by directly binding to HBV enhancer II/core promoter (EnII/Cp) and suppressing its promoter and enhancer activities. Notably, HBx expression was observed to be repressed more drastically by MSX1 compared to other viral antigens. In this work, we report that in addition to transcriptional repression, MSX1 also post-transcriptionally downregulates HBx protein stability. Mechanistically, MSX1 induces ubiquitin-independent proteasomal degradation of HBx, which is mediated through HBx C-terminal domain. Furthermore, this effect on HBx degradation correlates with MSX1-induced upregulation of DNAJA4 and CRYAB expression. Similar to MSX1, both DNAJA4 and CRYAB promote HBx degradation and repress HBV gene expression and genome replication. In chronic hepatitis B (CHB) patients, immune active phase (IA) is associated with higher intrahepatic expression of MSX1, DNAJA4 and CRYAB, and lower serum HBV markers compared to immune tolerant (IT) phase. Finally, HBV infection is significantly suppressed by MSX1 overexpression in both NTCP-overexpressing cell and humanized liver mouse models. These results demonstrate additional and novel mechanisms of MSX1-mediated repression of HBV, and establish MSX1 as a multi-functional HBV restriction factor with therapeutic potential.

Development of benzimidazole-based compounds as novel capsid assembly modulators for the treatment of HBV infection

Hepatitis B virus (HBV) capsid assembly modulators (CAMs) represent a promising therapeutic approach for the treatment of HBV infection. In this study, the hit compound CDI (IC50 = 2.46 ± 0.33 μM) was identified by screening of an in-house compound library. And then novel potent benzimidazole derivatives were designed and synthesized as core assembly modulators, and their antiviral effects were evaluated in vitro and in vivo biological experiments. The results indicated that compound 26f displayed the most optimized modulator of HBV capsid assembly (IC50 = 0.51 ± 0.20 μM, EC50 = 2.24 ± 0.43 μM, CC50 = 84.29 μM) and high selectivity index. Moreover, treatment with compound 26f for 14 days significantly decreased serum levels of HBV DNA levels in the Hydrodynamic-Injection (HDI) mouse model. Therefore, compound 26f could be considered as a promising candidate drug for further development of novel HBV CAMs with the desired potency and safety.

The First Yarrowia lipolytica Yeast Models Expressing Hepatitis B Virus X Protein: Changes in Mitochondrial Morphology and Functions

Chronic hepatitis B virus infection is the dominant cause of hepatocellular carcinoma, the main cause of cancer death. HBx protein, a multifunctional protein, is essential for pathogenesis development; however, the underlying mechanisms are not fully understood. The complexity of the system itself, and the intricate interplay of many factors make it difficult to advance in understanding the mechanisms underlying these processes. The most obvious solution is to use simpler systems by reducing the number of interacting factors. Yeast cells are particularly suitable for studying the relationships between oxidative stress, mitochondrial dynamics (mitochondrial fusion and fragmentation), and mitochondrial dysfunction involved in HBx-mediated pathogenesis. For the first time, genetically modified yeast, Y. lipolytica, was created, expressing the hepatitis B virus core protein HBx, as well as a variant fused with eGFP at the C-end. It was found that cells expressing HBx experienced stronger oxidative stress than the control cells. Oxidative stress was alleviated by preincubation with the mitochondria-targeted antioxidant SkQThy. Consistent with these data, in contrast to the control cells (pZ-0) containing numerous mitochondrial forming a mitochondrial reticulum, in cells expressing HBx protein, mitochondria were fragmented, and preincubation with SkQThy partially restored the mitochondrial reticulum. Expression of HBx had a significant influence on the bioenergetic function of mitochondria, making them loosely coupled with decreased respiratory rate and reduced ATP formation. In sum, the first highly promising yeast model for studying the impact of HBx on bioenergy, redox-state, and dynamics of mitochondria in the cell and cross-talk between these parameters was offered. This fairly simple model can be used as a platform for rapid screening of potential therapeutic agents, mitigating the harmful effects of HBx.

Transfected DNA is targeted by STING-mediated restriction

DNA transfection is routinely used for delivering expression of gene of interest to target cells. Transfected DNA has been known to activate cellular DNA sensor(s) and innate immune responses, but the effects of such responses on transfected DNA are not fully understood. STING (stimulator of interferon genes) is an important adaptor protein in cellular innate immune response to various DNA and RNA stimuli and upon activation induces significant type I interferon responses. In this work, we characterized the effects of STING on gene expression driven by transfected double-stranded DNA. We observed that gene expression from transfected DNA was repressed in the presence of overexpressed STING, but increased if endogenous STING was knocked down through RNA interference. Endogenous chromosomal genes and chromosome-integrated exogenous genes were not affected by such STING-mediated restriction, which did not depend on DNA circularity or linearity, promoter used, or bacterial sequences in transfected DNA. Mechanistically, STING-mediated repression of transfected DNA correlates with reduced mRNA levels, and partially involves the induction of interferon β production by STING. Collectively, these data indicate that episomal double-stranded DNA is targeted by STING-mediated cell defense.

Characterization and engineering of broadly reactive monoclonal antibody against hepatitis B virus X protein that blocks its interaction with DDB1

Hepatitis B virus (HBV) X protein (HBx) plays diverse roles in both viral life cycle and HBV-related carcinogenesis. Its interaction with DNA damage-binding protein 1 (DDB1) was shown to be essential for engendering cellular conditions favorable for optimal viral transcription and replication. Previously, we described a mouse monoclonal antibody against HBx (anti-HBx 2A7) recognizing HBx encoded by representative strains from 7 of 8 known HBV genotypes. In this work, we further characterized 2A7 in order to explore its potential usefulness in HBx-targeting applications. We demonstrated that 2A7 recognizes a linear epitope mapped to L⁸⁹PKVLHKR⁹⁶ on HBx, a segment that is highly conserved across genotypes and coincidentally overlaps with the DDB1-interacting segment. HBx-DDB1 binding could be inhibited by 2A7 in vitro, suggesting therapeutic potential. Nucleic acid and amino acid sequences of 2A7 were then obtained, which allowed construction of recombinant antibody and single chain variable fragments (scFv). 2A7-derived recombinant antibody and scFv recapitulate 2A7's HBx-binding capacity and epitope specificity. We also reported preliminary results using cell-penetrating peptide for delivering 2A7 antibody across cell membrane to target intracellular HBx. Anti-HBx 2A7 and 2A7-derived scFv characterized here may give rise to novel HBx-targeting diagnostics and therapeutics for HBV- and HBx-related pathologies.