King-Song Jeng

Hepatitis C Virus Triggers Mitochondrial Permeability Transition with Production of Reactive Oxygen Species, Leading to DNA Damage and STAT3 Activation

ABSTRACT Hepatitis C virus (HCV) infection is frequently associated with the development of hepatocellular carcinomas and non-Hodgkins B-cell lymphomas. Previously, we reported that HCV infection causes cellular DNA damage and mutations, which are mediated by nitric oxide (NO). NO often damages mitochondria, leading to induction of double-stranded DNA breaks (DSBs) and accumulation of oxidative DNA damage. Here we report that HCV infection causes production of reactive oxygen species (ROS) and lowering of mitochondrial transmembrane potential (ΔΨm) in in vitro HCV-infected cell cultures. The changes in membrane potential could be inhibited by BCL-2. Furthermore, an inhibitor of ROS production, antioxidant N-acetyl-l-cysteine (NAC), or an inhibitor of NO, 1400W, prevented the alterations of ΔΨm. The HCV-induced DSB was also abolished by a combination of NO and ROS inhibitors. These results indicated that the mitochondrial damage and DSBs in HCV-infected cells were mediated by both NO and ROS. Among the HCV proteins, core, E1, and NS3 are potent ROS inducers: their expression led to DNA damage and activation of STAT3. Correspondingly, core-protein-transgenic mice showed elevated levels of lipid peroxidation and oxidatively damaged DNA. These HCV studies thus identified ROS, along with the previously identified NO, as the primary inducers of DSBs and mitochondrial damage in HCV-infected cells.

Rab5 and Class III Phosphoinositide 3-Kinase Vps34 Are Involved in Hepatitis C Virus NS4B-Induced Autophagy

ABSTRACT Autophagy has been shown to facilitate replication or production of hepatitis C virus (HCV); nevertheless, how HCV induces autophagy remains unclear. Here, we demonstrate that HCV nonstructural protein 4B (NS4B) alone can induce autophagy signaling; amino acid residues 1 to 190 of NS4B are sufficient for this induction. Further studies showed that the phosphorylation levels of S6K and 4E-BP1 were not altered, suggesting that the mTOR/S6 kinase pathway and mTOR/4E-BP1 pathway did not contribute to NS4B- or HCV-induced autophagy. Inhibition of Rab5 function by silencing Rab5 or overexpressing dominant-negative Rab5 mutant (S34N) resulted in significant reduction of NS4B- or HCV-induced autophagic vesicle formation. Moreover, the autophagy induction was impaired by inhibition of class III phosphoinositide 3-kinase (PI 3-kinase) Vps34 function. Finally, the coimmunoprecipitation assay indicated that NS4B formed a complex with Rab5 and Vps34, supporting the notion that Rab5 and Vps34 are involved in NS4B-induced autophagy. Taken together, these results not only reveal a novel role of NS4B in autophagy but also offer a clue to the mechanism of HCV-induced autophagy.

Association of Hepatitis C Virus Replication Complexes with Microtubules and Actin Filaments Is Dependent on the Interaction of NS3 and NS5A

ABSTRACT The hepatitis C virus (HCV) RNA replication complex (RC), which is composed of viral nonstructural (NS) proteins and host cellular proteins, replicates the viral RNA genome in association with intracellular membranes. Two viral NS proteins, NS3 and NS5A, are essential elements of the RC. Here, by using immunoprecipitation and fluorescence resonance energy transfer assays, we demonstrated that NS3 and NS5A interact with tubulin and actin. Furthermore, immunofluorescence microscopy and electron microscopy revealed that HCV RCs were aligned along microtubules and actin filaments in both HCV replicon cells and HCV-infected cells. In addition, the movement of RCs was inhibited when microtubules or actin filaments were depolymerized by colchicine and cytochalasin B, respectively. Based on our observations, we propose that microtubules and actin filaments provide the tracks for the movement of HCV RCs to other regions in the cell, and the molecular interactions between RCs and microtubules, or RCs and actin filaments, are mediated by NS3 and NS5A.

Varied assembly and RNA editing efficiencies between genotypes I and II hepatitis D virus and their implications

The mechanisms that link genotypes of hepatitis D virus (HDV) with clinical outcomes have not yet been elucidated. Genotypic variations are unevenly distributed along the sequences of hepatitis delta antigens (HDAgs). Of these variations, the packaging signal at the C-terminus has a divergence of 74% between genotypes I and II. In this report, we address the issue of whether these high variations between genotypes affect assembly efficiency of HDV particles and editing efficiency of RNA. Viral package systems of transfection with expression plasmids of hepatitis B surface antigen and HDAgs or whole genomes of HDV consistently indicate that the package efficiency of genotype I HDV is higher than that of genotype II. Segment swapping of large-form HDAg indicates that the C-terminal 19-residue region plays a key role for the varied assembly efficiencies. Also, the editing efficiency of genotype I HDV is higher than that of genotype II. The nucleotide and structural changes surrounding the editing site may explain why genotype II HDV has a low RNA editing efficiency. The findings of in vitro assembly systems were further supported by the observations that patients infected with genotype II had significantly lower alanine transaminase (ALT) levels, more favorable outcomes (P <.05), and a trend to have lower serum HDV RNA levels as compared with those infected with genotype I HDV (P =.094). In conclusion, genotype II HDV secretes fewer viral particles than genotype I HDV does, which in turn may reduce the extent of infection of hepatocytes and result in less severe hepatic inflammation.

Ubiquitination and deubiquitination of NP protein regulates influenza A virus RNA replication

Influenza A virus RNA replication requires an intricate regulatory network involving viral and cellular proteins. In this study, we examined the roles of cellular ubiquitinating/deubiquitinating enzymes (DUBs). We observed that downregulation of a cellular deubiquitinating enzyme USP11 resulted in enhanced virus production, suggesting that USP11 could inhibit influenza virus replication. Conversely, overexpression of USP11 specifically inhibited viral genomic RNA replication, and this inhibition required the deubiquitinase activity. Furthermore, we showed that USP11 interacted with PB2, PA, and NP of viral RNA replication complex, and that NP is a monoubiquitinated protein and can be deubiquitinated by USP11 in vivo. Finally, we identified K184 as the ubiquitination site on NP and this residue is crucial for virus RNA replication. We propose that ubiquitination/deubiquitination of NP can be manipulated for antiviral therapeutic purposes.

Poly(C)-Binding Protein 2 Interacts with Sequences Required for Viral Replication in the Hepatitis C Virus (HCV) 5′ Untranslated Region and Directs HCV RNA Replication through Circularizing the Viral Genome

ABSTRACT Sequences in the 5′ untranslated region (5′UTR) of hepatitis C virus (HCV) RNA is important for modulating both translation and RNA replication. The translation of the HCV genome depends on an internal ribosome entry site (IRES) located within the 341-nucleotide 5′UTR, while RNA replication requires a smaller region. A question arises whether the replication and translation functions require different regions of the 5′UTR and different sets of RNA-binding proteins. Here, we showed that the 5′-most 157 nucleotides of HCV RNA is the minimum 5′UTR for RNA replication, and it partially overlaps with the IRES. Stem-loops 1 and 2 of the 5′UTR are essential for RNA replication, whereas stem-loop 1 is not required for translation. We also found that poly(C)-binding protein 2 (PCBP2) bound to the replication region of the 5′UTR and associated with detergent-resistant membrane fractions, which are the sites of the HCV replication complex. The knockdown of PCBP2 by short hairpin RNA decreased the amounts of HCV RNA and nonstructural proteins. Antibody-mediated blocking of PCBP2 reduced HCV RNA replication in vitro, indicating that PCBP2 is directly involved in HCV RNA replication. Furthermore, PCBP2 knockdown reduced IRES-dependent translation preferentially from a dual reporter plasmid, suggesting that PCBP2 also regulated IRES activity. These findings indicate that PCBP2 participates in both HCV RNA replication and translation. Moreover, PCBP2 interacts with HCV 5′- and 3′UTR RNA fragments to form an RNA-protein complex and induces the circularization of HCV RNA, as revealed by electron microscopy. This study thus demonstrates the mechanism of the participation of PCBP2 in HCV translation and replication and provides physical evidence for HCV RNA circularization through 5′- and 3′UTR interaction.

Polo-Like Kinase 1 Is Involved in Hepatitis C Virus Replication by Hyperphosphorylating NS5A

ABSTRACT Hepatitis C virus (HCV) replication involves many viral and host factors. Here, we employed a lentivirus-based RNA interference (RNAi) screening approach to search for possible cellular factors. By using a kinase-phosphatase RNAi library and an HCV replicon reporter system, we identified a serine-threonine kinase, Polo-like kinase 1 (Plk1), as a potential host factor regulating HCV replication. Knockdown of Plk1 reduced both HCV RNA replication and nonstructural (NS) protein production in both HCV replicon cells and HCV-infected cells while it did not significantly affect host cellular growth or cell cycle. Overexpression of Plk1 in the knockdown cells rescued HCV replication. Interestingly, the ratio between the hyperphosphorylated form (p58) and the basal phosphorylated form (p56) of NS5A was lower in the Plk1 knockdown cells and Plk1 kinase inhibitor-treated cells than in the control groups. Further studies showed that Plk1 could be immunoprecipitated together with NS5A. Both proteins partially colocalized in the perinuclear region. Furthermore, Plk1 could phosphorylate NS5A to both the p58 and p56 forms in an in vitro assay system; the phosphorylation efficiency was comparable to that of the reported casein kinase. Taken together, this study shows that Plk1 is an NS5A phosphokinase and thereby indirectly regulates HCV RNA replication. Because of the differential effects of Plk1 on HCV replication and host cell growth, Plk1 could potentially serve as a target for anti-HCV therapy.

The SUMOylation of Matrix Protein M1 Modulates the Assembly and Morphogenesis of Influenza A Virus

ABSTRACT SUMOylation is an important posttranslational modification for regulation of cellular functions and viral replication. Here, we report that protein SUMOylation regulates the replication of influenza A virus at the steps of viral maturation and assembly. Knocking down the SUMO-conjugating enzyme Ubc9 resulted in the reduction of virus production. Dissection of the virus life cycle revealed that SUMOylation is involved in the processes of virus maturation and assembly. The viral matrix protein M1 is SUMOylated at K242. A virus carrying the SUMO-defective M1 produced a lower titer of virus, while its viral proteins and viral RNA (vRNA) accumulated in the cells. Furthermore, the mechanistic studies showed that the SUMOylation of M1 is required for the interaction between M1 and viral RNP (vRNP) to form the M1-vRNP complex. The lack of M1 SUMOylation prevented the nuclear export of vRNP and subsequent viral morphogenesis. Taken together, our findings elucidate that the maturation and assembly of influenza A virus is controlled by the SUMO modification of M1 protein. Therefore, we suggest that M1 can serve as a target for developing a new generation of drugs for flu therapy.

Molecular pathogenesis of Gilbert's syndrome: decreased Tata-binding protein binding affinity of ugt1a1 gene promoter

Objectives Gilberts syndrome is a congenital, nonhemolytic, unconjugated hyperbilirubinemia. The most common genotype of Gilberts syndrome is the homozygous polymorphism, A(TA)7TAA, in the promoter of the gene for UDP-glucuronosyltransferase 1A1 (UGT1A1), with a thymine adenine insertion in the TATA-box-like sequence, which results in a decrease in UGT1A1 activity. The mechanism responsible for this decrease in UGT1A1 activity, however, has not been elucidated. To clarify the mechanism underlying this deficiency in UGT1A1 activity in patients with Gilberts syndrome. Methods The promoter activity assay using the wild-type A(TA)6TAA or the mutant A(TA)7TAA promoter and a luciferase reporter was performed in two different hepatoma cell lines. The binding affinity for a nuclear protein complex or for TATA-binding protein was evaluated by a competitive electophoretic mobility shift assay using wild-type or mutant TATA-box-like oligonucleotide probes and nuclear extract or TATA-binding protein. The formation of complexes between TATA-binding protein and wild-type or mutant oligonucleotide probes was also studied by a quantitive electophoretic mobility shift assay. Results A TA insertion in the TATA-box-like sequence of the promoter activity of UGT1A1 gene. A competitive electrophoretic mobility shift assay showed a decrease in nuclear proteincomplex binding affinity and TATA-binding protein binding affinity of the mutant TATA-box-like sequence A(TA)7TAA. When the mutants A(TA)5TAA and A(TA)8TAA were also compared, quantitative electrophoretic mobility shift assay demonstrated that the TATA-binding protein binding affinity progressively decreased as the number of TA repeats in the TATA-box-like sequence increased. Conclusion TA insertion in the TATA-box-like sequence of the UGT1A1 promoter affected its binding affinity for TATA-binding protein, causing a decrease in its activity. This explains the pathogenesis of Gilberts syndrome.

Annexin A2 is involved in the formation of hepatitis C virus replication complex on the lipid raft

ABSTRACT The hepatitis C virus (HCV) RNA replicates in hepatic cells by forming a replication complex on the lipid raft (detergent-resistant membrane [DRM]). Replication complex formation requires various viral nonstructural (NS) proteins as well as host cellular proteins. In our previous study (C. K. Lai, K. S. Jeng, K. Machida, and M. M. Lai, J. Virol. 82:8838–8848, 2008), we found that a cellular protein, annexin A2 (Anxa2), interacts with NS3/NS4A. Since NS3/NS4A is a membranous protein and Anxa2 is known as a lipid raft-associated scaffold protein, we postulate that Anxa2 helps in the formation of the HCV replication complex on the lipid raft. Further studies showed that Anxa2 was localized at the HCV-induced membranous web and interacted with NS4B, NS5A, and NS5B and colocalized with them in the perinuclear region. The silencing of Anxa2 decreased the formation of membranous web-like structures and viral RNA replication. Subcellular fractionation and bimolecular fluorescence complementation analysis revealed that Anxa2 was partially associated with HCV at the lipid raft enriched with phosphatidylinositol-4-phosphate (PI4P) and caveolin-2. Further, the overexpression of Anxa2 in HCV-nonsusceptible HEK293 cells caused the enrichment of HCV NS proteins in the DRM fraction and increased the colony-forming ability of the HCV replicon. Since Anxa2 is known to induce the formation of the lipid raft microdomain, we propose that Anxa2 recruits HCV NS proteins and enriches them on the lipid raft to form the HCV replication complex.