Sphingomyelin Activates Hepatitis C Virus RNA Polymerase in a Genotype-Specific Manner

Hepatitis C virus (HCV) replication and infection depend on the lipid components of the cell, and replication is inhibited by inhibitors of sphingomyelin biosynthesis. We found that sphingomyelin bound to and activated genotype 1b RNA-dependent RNA polymerase (RdRp) by enhancing its template binding activity. Sphingomyelin also bound to 1a and JFH1 (genotype 2a) RdRps but did not activate them. Sphingomyelin did not bind to or activate J6CF (2a) RdRp. The sphingomyelin binding domain (SBD) of HCV RdRp was mapped to the helix-turn-helix structure (residues 231 to 260), which was essential for sphingomyelin binding and activation. Helix structures (residues 231 to 241 and 247 to 260) are important for RdRp activation, and 238S and 248E are important for maintaining the helix structures for template binding and RdRp activation by sphingomyelin. 241Q in helix 1 and the negatively charged 244D at the apex of the turn are important for sphingomyelin binding. Both amino acids are on the surface of the RdRp molecule. The polarity of the phosphocholine of sphingomyelin is important for HCV RdRp activation. However, phosphocholine did not activate RdRp. Twenty sphingomyelin molecules activated one RdRp molecule. The biochemical effect of sphingomyelin on HCV RdRp activity was virologically confirmed by the HCV replicon system. We also found that the SBD was the lipid raft membrane localization domain of HCV NS5B because JFH1 (2a) replicon cells harboring NS5B with the mutation A242C/S244D moved to the lipid raft while the wild type did not localize there. This agreed with the myriocin sensitivity of the mutant replicon. This sphingomyelin interaction is a target for HCV infection because most HCV RdRps have 241Q.Hepatitis C virus (HCV) has a positive-stranded RNA genome and belongs to the family Flaviviridae (21). HCV chronically infects more than 130 million people worldwide (34), and HCV infection often induces liver cirrhosis and hepatocellular carcinoma (19, 28). To date, pegylated interferon (PEG-IFN) and ribavirin are the standard treatments for HCV infection. However, many patients cannot tolerate their serious side effects. Therefore, the development of new and safer therapeutic methods with better efficacy is urgently needed.Lipids play important roles in HCV infection and replication. For example, the HCV core associates with lipid droplets and recruits nonstructural proteins and replication complexes to lipid droplet-associated membranes which are involved in the production of infectious virus particles (24). HCV RNA replication depends on viral protein association with raft membranes (2, 30). The association of cholesterol and sphingolipid with HCV particles is also important for virion maturation and infectivity (3). The inhibitors of the sphingolipid biosynthetic pathway, ISP-1 and HPA-12, which specifically inhibit serine palmitoyltransferase (SPT) (23) and ceramide trafficking from the endoplasmic reticulum (ER) to the Golgi apparatus (37), suppress HCV virus production in cell culture but not viral RNA replication by the JFH1 replicon (3). Other serine SPT inhibitors (myriocin and NA255) inhibit genotype 1b replication (4, 29, 33). Very-low-density lipoprotein (VLDL) also interacts with the HCV virion (15).Sakamoto et al. reported that sphingomyelin bound to HCV RNA-dependent polymerase (RdRp) at the sphingomyelin binding domain (SBD; amino acids 230 to 263 of RdRp) to recruit HCV RdRp on the lipid rafts, where the HCV complex assembles, and that NA255 suppressed HCV replication by releasing HCV RdRp from the lipid rafts (29). In the present study, we analyzed the effect of sphingomyelin on HCV RdRp activity in vitro and found that sphingomyelin activated HCV RdRp activity in a genotype-specific manner. We also determined the sphingomyelin activation domain and the activation mechanism. Finally, we confirmed our biochemical data by a HCV replicon system.     

A Disulfide-Bonded Dimer of the Core Protein of Hepatitis C Virus Is Important for Virus-Like Particle Production

Hepatitis C virus (HCV) core protein forms the nucleocapsid of the HCV particle. Although many functions of core protein have been reported, how the HCV particle is assembled is not well understood. Here we show that the nucleocapsid-like particle of HCV is composed of a disulfide-bonded core protein complex (dbc-complex). We also found that the disulfide-bonded dimer of the core protein (dbd-core) is formed at the endoplasmic reticulum (ER), where the core protein is initially produced and processed. Mutational analysis revealed that the cysteine residue at amino acid position 128 (Cys128) of the core protein, a highly conserved residue among almost all reported isolates, is responsible for dbd-core formation and virus-like particle production but has no effect on the replication of the HCV RNA genome or the several known functions of the core protein, including RNA binding ability and localization to the lipid droplet. The Cys128 mutant core protein showed a dominant negative effect in terms of HCV-like particle production. These results suggest that this disulfide bond is critical for the HCV virion. We also obtained the results that the dbc-complex in the nucleocapsid-like structure was sensitive to proteinase K but not trypsin digestion, suggesting that the capsid is built up of a tightly packed structure of the core protein, with its amino (N)-terminal arginine-rich region being concealed inside.Hepatitis C virus (HCV) infection is a major cause of chronic hepatitis, liver cirrhosis, and hepatocellular carcinoma, affecting approximately 200 million people worldwide (13, 29, 44). Current treatment strategies, including interferon coupled with ribavirin, are not effective for all patients infected with HCV. An error-prone replication strategy allows HCV to undergo rapid mutational evolution in response to immune pressure and thus evade adaptive immune responses (10). New approaches to HCV therapy include the development of specifically targeted antiviral therapies for hepatitis C (STAT-Cs) which target such HCV proteins as the nonstructural 3/4A (NS3/4A), serine protease, and RNA-dependent RNA polymerase NS5B proteins (3). Despite the potent antiviral activities of some of these approaches, many resistant HCV strains have been reported after treatment with existing STAT-Cs (23, 48, 51). Therefore, identification of new targets that are common to all HCV strains and that are associated with low mutation rates is an area of active research.HCV has a 9.6-kb, plus-strand RNA genome composed of a 5′ untranslated region (UTR), an open reading frame that encodes a single polyprotein of about 3,000 amino acids, and a 3′ UTR. The polyprotein is processed by host and viral proteases to produce three structural proteins (the core, envelope 1 [E1], and E2 proteins) and seven nonstructural proteins (the p7, NS2, NS3, NS4A, NS4B, NS5A, and NS5B proteins) (14, 16, 17, 22, 49). The HCV core protein is produced cotranslationally via carboxyl (C)-terminal cleavage to generate an immature core protein, 191 amino acids in length, on the endoplasmic reticulum (ER) (16). This protein consists of three predicted domains: the N-terminal hydrophilic domain (D1), the C-terminal hydrophobic domain (D2), and the tail domain (33), which serves as a signal peptide for the E1 protein. D1 includes a number of positively charged amino acids responsible for viral RNA binding (amino acids 1 to 75) (43) and the region involved in multimerization of the core protein via homotypic interactions (amino acids 36 to 91 and 82 to 102) (32, 40) (see Fig. S1 in the supplemental material). Hydrophobic D2 includes the region responsible for core protein association with lipid droplets (LDs; amino acids 125 to 144) (7, 18, 37), which accumulate in response to core protein production (1, 6).Many functions of the core protein have been reported (13, 38, 50), yet because infectious HCV particles cannot be appropriately produced in currently available experimental systems, HCV particle assembly has not been elucidated to date. A cell culture system that reproduces the complete life cycle of HCV in vitro was developed by Wakita et al. using a cloned HCV genome (JFH1) (53). Using this system, the assembly of infectious HCV particles was found to occur near LDs and ER-derived LD-associated membranes (36, 47). Neither the structures nor the functions of the virus proteins involved in virus particle assembly are known, however. To elucidate this point, we have analyzed the biochemical characteristics of the proteins within the fraction containing the HCV particle and found a disulfide-bonded core protein complex (dbc-complex). We revealed that the disulfide-bonded dimer of core protein (dbd-core) was formed by a single cysteine residue at amino acid position 128 on the ER. The roles of the disulfide bond of the core protein in virus-like particle formation are discussed in this paper.     

Characteristic effect of an anticancer dinuclear platinum(II) complex on the higher-order structure of DNA

It is known that a 1,2,3-triazolato-bridged dinuclear platinum(II) complex, [{cis-Pt(NH₃)₂}₂(μ-OH)(μ-1,2,3-ta-N ¹,N ²)](NO₃)₂ (AMTA), shows high in vitro cytotoxicity against several human tumor cell lines and circumvents cross-resistance to cisplatin. In the present study, we examined a dose- and time-dependent effect of AMTA on the higher-order structure of a large DNA, T4 phage DNA (166 kbp), by adapting single-molecule observation with fluorescence microscopy. It was found that AMTA induces the shrinking of DNA into a compact state with a much higher potency than cisplatin. From a quantitative analysis of the Brownian motion of individual DNA molecules in solution, it became clear that the density of a DNA segment in the compact state is about 2,000 times greater than that in the absence of AMTA. Circular dichroism spectra suggested that AMTA causes a transition from the B to the C form in the secondary structure of DNA, which is characterized by fast and slow processes. Electrophoretic measurements indicated that the binding of AMTA to supercoiled DNA induces unwinding of the double helix. Our results indicate that AMTA acts on DNA through both electrostatic interaction and coordination binding; the former causes a fast change in the secondary structure from the B to the C form, whereas the latter promotes shrinking in the higher-order structure as a relatively slow kinetic process. The shrinking effect of AMTA on DNA is attributable to the possible increase in the number of bridges along a DNA molecule. It is concluded that AMTA interacts with DNA in a manner markedly different from that of cisplatin.     

Signal Peptidase Complex Subunit 1 Participates in the Assembly of Hepatitis C Virus through an Interaction with E2 and NS2

Hepatitis C virus (HCV) nonstructural protein 2 (NS2) is a hydrophobic, transmembrane protein that is required not only for NS2-NS3 cleavage, but also for infectious virus production. To identify cellular factors that interact with NS2 and are important for HCV propagation, we screened a human liver cDNA library by split-ubiquitin membrane yeast two-hybrid assay using full-length NS2 as a bait, and identified signal peptidase complex subunit 1 (SPCS1), which is a component of the microsomal signal peptidase complex. Silencing of endogenous SPCS1 resulted in markedly reduced production of infectious HCV, whereas neither processing of structural proteins, cell entry, RNA replication, nor release of virus from the cells was impaired. Propagation of Japanese encephalitis virus was not affected by knockdown of SPCS1, suggesting that SPCS1 does not widely modulate the viral lifecycles of the Flaviviridae family. SPCS1 was found to interact with both NS2 and E2. A complex of NS2, E2, and SPCS1 was formed in cells as demonstrated by co-immunoprecipitation assays. Knockdown of SPCS1 impaired interaction of NS2 with E2. Our findings suggest that SPCS1 plays a key role in the formation of the membrane-associated NS2-E2 complex via its interaction with NS2 and E2, which leads to a coordinating interaction between the structural and non-structural proteins and facilitates the early step of assembly of infectious particles.     

Enterovirus 71 Binding to PSGL-1 on Leukocytes: VP1-145 Acts as a Molecular Switch to Control Receptor Interaction

Some strains of enterovirus 71 (EV71), but not others, infect leukocytes by binding to a specific receptor molecule: the P-selectin glycoprotein ligand-1 (PSGL-1). We find that a single amino acid residue within the capsid protein VP1 determines whether EV71 binds to PSGL-1. Examination of capsid sequences of representative EV71 strains revealed that the PSGL-1-binding viruses had either a G or a Q at residue 145 within the capsid protein VP1 (VP1-145G or Q), whereas PSGL-1-nonbinding viruses had VP1-145E. Using site-directed mutagenesis we found that PSGL-1-binding strains lost their capacity to bind when VP1-145G/Q was replaced by E; conversely, nonbinding strains gained the capacity to bind PSGL-1 when VP1-145E was replaced with either G or Q. Viruses with G/Q at VP1-145 productively infected a leukocyte cell line, Jurkat T-cells, whereas viruses with E at this position did not. We previously reported that EV71 binds to the N-terminal region of PSGL-1, and that binding depends on sulfated tyrosine residues within this region. We speculated that binding depends on interaction between negatively charged sulfate groups and positively charged basic residues in the virus capsid. VP1-145 on the virus surface is in close proximity to conserved lysine residues at VP1-242 and VP1-244. Comparison of recently published crystal structures of EV71 isolates with either Q or E at VP1-145 revealed that VP1-145 controls the orientation of the lysine side-chain of VP1-244: with VP1-145Q the lysine side chain faces outward, but with VP1-145E, the lysine side chain is turned toward the virus surface. Mutation of VP1-244 abolished virus binding to PSGL-1, and mutation of VP1-242 greatly reduced binding. We propose that conserved lysine residues on the virus surface are responsible for interaction with sulfated tyrosine residues at the PSGL-1 N-terminus, and that VP1-145 acts as a switch, controlling PSGL-1 binding by modulating the exposure of VP1-244K.     

Antiviral Activity of Glycyrrhizin against Hepatitis C Virus In Vitro

Glycyrrhizin (GL) has been used in Japan to treat patients with chronic viral hepatitis, as an anti-inflammatory drug to reduce serum alanine aminotransferase levels. GL is also known to exhibit various biological activities, including anti-viral effects, but the anti-hepatitis C virus (HCV) effect of GL remains to be clarified. In this study, we demonstrated that GL treatment of HCV-infected Huh7 cells caused a reduction of infectious HCV production using cell culture-produced HCV (HCVcc). To determine the target step in the HCV lifecycle of GL, we used HCV pseudoparticles (HCVpp), replicon, and HCVcc systems. Significant suppressions of viral entry and replication steps were not observed. Interestingly, extracellular infectivity was decreased, and intracellular infectivity was increased. By immunofluorescence and electron microscopic analysis of GL treated cells, HCV core antigens and electron-dense particles had accumulated on endoplasmic reticulum attached to lipid droplet (LD), respectively, which is thought to act as platforms for HCV assembly. Furthermore, the amount of HCV core antigen in LD fraction increased. Taken together, these results suggest that GL inhibits release of infectious HCV particles. GL is known to have an inhibitory effect on phospholipase A2 (PLA2). We found that group 1B PLA2 (PLA2G1B) inhibitor also decreased HCV release, suggesting that suppression of virus release by GL treatment may be due to its inhibitory effect on PLA2G1B. Finally, we demonstrated that combination treatment with GL augmented IFN-induced reduction of virus in the HCVcc system. GL is identified as a novel anti-HCV agent that targets infectious virus particle release.     

The Synergistic Effects among β-,3-Glucanases from Oerskovia sp. CK on Lysis of Viable Yeast Cells

Oerskovia sp. CK produced three types of β-1,3-glucanases designated as F-L, F-0 and F-2. F-L showed high lytic activity to viable yeast cells and weak activity to yeast glucan. F-0 and F-2 had little or no lytic activity and strong β-1,3-gIucanase activity.

F-0 or F-2 showed high lytic activities to yeast cells pretreated with small amounts of F-L which did not lysed the cells. Lytic activity of F-0 or F-2 also increased when cells were treated with alkaline pH or with both reducing agents and pH.

From these results, it is supposed that the ineffectiveness of F-0 or F-2 on the lysis of yeast cells might be attributed to a spatial inaccessibility of enzymes to the yeast glucan layer. However, the treatment of F-L, alkaline pH and reducing agents would bring about a modification of cells to give F-0 or F-2 access to the wall glucan and consequently the lysis of cells would occur.     

Proteolytic Enzyme from Oerskovia sp. CK Lysing Viable Yeast Cells

Oerskovia sp. CK produced three types of yeast glucan hydrolases, one of them, F-L lysing viable yeast cells had proteolytic activity and considerable difference was observed between lytic and proteolytic activities in thermal stability. F-L was considered to be a single protein from following results. Both activities were influenced in parallel by acid treatment and inhibitors. The reaction rates of two substrates being added to the enzyme system were less than the sum of the rates of reactions measured separately. Both activities were detected in the same fraction by isoelectric focusing.

On the evidence that F-L lost lytic activity by the heat treatment at 60°C for 15 min, we speculated that the enzyme underwent autolysis during heat treatment and binding site for polysaccharide was released, subsequently lost the lytic activity, since active site of F-L remained unaffectedly. These speculations were based on the following results. Difference in specific activity between native and treated F-L was not observed. The specific activity of heat treated F-L purified by gel filtration was 1.6 times more active than that of native F-L. Native F-L had a affinity for dextran but treated F-L lost it. F-L being treated in the presence of DFP was eluted at the same fraction where native F-L was eluted. Based on these results, a model for the yeast cell wall was proposed.     

Development of recombinant hepatitis C virus with NS5A from strains of genotypes 1 and 2

Nonstructural protein 5A (NS5A) of hepatitis C virus (HCV) plays multiple and diverse roles in the viral lifecycle, and is currently recognized as a novel target for anti-viral therapy. To establish an HCV cell culture system with NS5A of various strains, recombinant viruses were generated by replacing NS5A of strain JFH-1 with those of strains of genotypes 1 (H77; 1a and Con1; 1b) and 2 (J6CF; 2a and MA; 2b). All these recombinant viruses were capable of replication and infectious virus production. The replacement of JFH-1 NS5A with those of genotype 1 strains resulted in similar or slightly reduced virus production, whereas replacement with those of genotype 2 strains enhanced virus production as compared with JFH-1 wild-type. A single cycle virus production assay with a CD81-negative cell line revealed that the efficient virus production elicited by replacement with genotype 2 strains depended on enhanced viral assembly, and that substitutions in the C-terminus of NS5A were responsible for this phenotype. Pulse-chase assays revealed that these substitutions in the C-terminus of NS5A were possibly associated with accelerated cleavage kinetics at the NS5A–NS5B site. Using this cell culture system with NS5A-substituted recombinant viruses, the anti-viral effects of an NS5A inhibitor were then examined. A 300- to 1000-fold difference in susceptibility to the inhibitor was found between strains of genotypes 1 and 2. This system will facilitate not only a better understanding of strain-specific roles of NS5A in the HCV lifecycle, but also enable the evaluation of genotype and strain dependency of NS5A inhibitors.