A comparative analysis of the substrate permissiveness of HCV and GBV-B NS3/4A proteases reveals genetic evidence for an interaction with NS4B protein during genome replication

The hepatitis C virus (HCV) serine protease (NS3/4A) processes the NS3-NS5B segment of the viral polyprotein and also cleaves host proteins involved in interferon signaling, making it an important target for antiviral drug discovery and suggesting a wide breadth of substrate specificity. We compared substrate specificities of the HCV protease with that of the GB virus B (GBV-B), a distantly related nonhuman primate hepacivirus, by exchanging amino acid sequences at the NS4B/5A and/or NS5A/5B cleavage junctions between these viruses within the backbone of subgenomic replicons. This mutagenesis study demonstrated that the GBV-B protease had a broader substrate tolerance, a feature corroborated by structural homology modeling. However, despite efficient polyprotein processing, GBV-B RNAs containing HCV sequences at the C-terminus of NS4B had a pseudo-lethal replication phenotype. Replication-competent revertants contained second-site substitutions within the NS3 protease or NS4B N-terminus, providing genetic evidence for an essential interaction between NS3 and NS4B during genome replication.     

A replicon trans-packaging system reveals the requirement of nonstructural proteins for the assembly of bovine viral diarrhea virus (BVDV) virion

A selective trans-packaging system was developed to produce and isolate bovine viral diarrhea virus (BVDV) pseudo-particles with complementing reporter replicons and their packaging proteins expressed in trans with recombinant vaccinia virus. The encapsidation of replicon rNS3-5B was dependent not only on the in trans expression of structural proteins C, E^rns, E1 and E2, but also the nonstructural proteins, p7 and contiguous precursor NS2-3-4A. Nonstructural p7, NS4B, NS5A or NS5B could be expressed in cis and in trans with precursor NS2-3-4A without significantly affecting virion assembly efficiency. NS2-3-4A was identified as an in trans functional precursor in virion assembly. BVDV genomes with mutant NS5B, which did not undergo active replication, were packaged 5-fold less efficiently than the intact genomes demonstrating the importance of replication in virion packaging. These results suggest that genome replication and assembly are closely associated, consistent with a model in which these two steps are coupled for maximum efficiency.     

A novel high throughput screening assay for HCV NS3 serine protease inhibitors

Hepatitis C virus (HCV) infection is a major worldwide health problem, causing chronic hepatitis, liver cirrhosis and primary liver cancer (Hepatocellular carcinoma). HCV encodes a precursor polyprotein that is enzymatically cleaved to release the individual viral proteins. The viral non-structural proteins are cleaved by the HCV NS3 serine protease. NS3 is regarded currently as a potential target for anti-viral drugs thus specific inhibitors of its enzymatic activity should be of importance. A prime requisite for detailed biochemical studies of the protease and its potential inhibitors is the availability of a rapid reliable in vitro assay of enzyme activity. A novel assay for measurement of HCV NS3 serine protease activity was developed for screening of HCV NS3 serine protease potential inhibitors. Recombinant NS3 serine protease was isolated and purified, and a fluorometric assay for NS3 proteolytic activity was developed. As an NS3 substrate we engineered a recombinant fusion protein where a green fluorescent protein is linked to a cellulose-binding domain via the NS5A/B site that is cleavable by NS3. Cleavage of this substrate by NS3 results in emission of fluorescent light that is easily detected and quantitated by fluorometry. Using our system we identified NS3 serine protease inhibitors from extracts obtained from natural Indian Siddha medicinal plants. Our unique fluorometric assay is very sensitive and has a high throughput capacity making it suitable for screening of potential NS3 serine protease inhibitors.     

Classical swine fever virus NS5A regulates viral RNA replication through binding to NS5B and 3'UTR

In this report, classical swine fever virus (CSFV) NS5A inhibit viral RNA replication when its concentration reached and surpassed the level of NS5B. Three amino acid fragments of CSFV NS5A, 137-172, 224-268 and 390-414 individually were shown to be essential to NS5B binding. The former two fragments were independently necessary for regulation of viral RNA replication and correlated with NS5B and 3′UTR binding activity. We also found that amino acids W143, V145, P227, T246, P257, K399, T401, E406 and L413 of CSFV NS5A were essential to NS5B binding activity. Furthermore, these amino acids were shown to be necessary for viral RNA replication and infection and conserved in NS5A proteins of CSFV, BDV, BVDV and HCV. These results indicated that NS5A may regulate viral RNA replication by binding to NS5B and 3′UTR. NS5A can still regulate viral RNA synthesis through binding to 3′UTR when binding to NS5B is not available.     

Expression of HCV structural proteins impairs IFN-mediated antiviral response

Hepatitis C virus (HCV), especially the genotype 1, is naturally resistant to the antiviral effects of interferon-alpha (IFN-alpha). Expression of the whole HCV genome and the NS5A protein has been suggested to interfere with the antiviral activity of IFN-alpha. Here we have analyzed the effect of individual or various combinations of HCV proteins on IFN-alpha-mediated antiviral effect against vesicular stomatitis virus (VSV). When the structural proteins (core-E1-E2) of HCV genotype 1 were expressed in human osteosarcoma cells in a tetracycline-regulated manner, partial VSV resistance to IFN-alpha was established. This was seen as an enhancement of both viral protein synthesis and production of infectious virus. Priming of core-E1-E2-expressing cells with low doses of IFN-gamma (10 IU/ml) partially restored the antiviral activity of IFN-alpha. The core (high-level expression) and NS4B protein expression also showed some rescue of VSV replication. In this model cell system NS3A-NS4A complex and NS5A showed no inhibition of IFN-alpha-induced antiviral activity. Our results indicate that the expression of structural proteins of HCV may impair the antiviral activity of IFNs.     

The hepatitis C virus NS5A inhibitor (BMS-790052) alters the subcellular localization of the NS5A non-structural viral protein

The hepatitis C virus (HCV) non-structural (NS) 5A protein plays an essential role in the replication of the viral RNA by the membrane-associated replication complex (RC). Recently, a putative NS5A inhibitor, BMS-790052, exhibited the highest potency of any known anti-HCV compound in inhibiting HCV replication in vitro and showed a promising clinical effect in HCV-infected patients. The precise mechanism of action for this new class of potential anti-HCV therapeutics, however, is still unclear. In order to gain further insight into its mode of action, we sought to test the hypothesis that the antiviral effect of BMS-790052 might be mediated by interfering with the functional assembly of the HCV RC. We observed that BMS-790052 indeed altered the subcellular localization and biochemical fractionation of NS5A. Taken together, our data suggest that NS5A inhibitors such as BMS-790052 can suppress viral genome replication by altering the proper localization of NS5A into functional RCs.     

Autophagy protein ATG5 interacts transiently with the hepatitis C virus RNA polymerase (NS5B) early during infection

Autophagy is an important cellular process by which ATG5 initiates the formation of double membrane vesicles (DMVs). Upon infection, DMVs have been shown to harbor the replicase complex of positive-strand RNA viruses such as MHV, poliovirus, and equine arteritis virus. Recently, it has been shown that autophagy proteins are proviral factors that favor initiation of hepatitis C virus (HCV) infection. Here, we identified ATG5 as an interacting protein for the HCV NS5B. ATG5/NS5B interaction was confirmed by co-IP and metabolic labeling studies. Furthermore, ATG5 protein colocalizes with NS4B, a constituent of the membranous web. Importantly, immunofluorescence staining demonstrated a strong colocalization of ATG5 and NS5B within perinuclear regions of infected cells at 2 days postinfection. However, colocalization was completely lacking at 5 DPI, suggesting that HCV utilizes ATG5 as a proviral factor during the onset of viral infection. Finally, inhibition of autophagy through ATG5 silencing blocks HCV replication.     

Hepatitis C virus nonstructural proteins are localized in a modified endoplasmic reticulum of cells expressing viral subgenomic replicons

For many years our knowledge on hepatitis C virus (HCV) replication has been based on in vitro experiments or transfection studies. Recently, the first reliable system for studying viral replication in tissue culture cells was developed. Taking advantage of this system, we examined in detail the localization of viral nonstructural (NS) proteins in cells containing functional replication complexes. By fractionation experiments and immunomicroscopy, we observed that all NS proteins were associated with the endoplasmic reticulum (ER) membranes, confirming the hypothesis that the ER is the site of membrane-associated HCV RNA replication. Interestingly, NS3 and NS4A were preferentially localized in endoplasmic reticulum cisternae surrounding mitochondria, suggesting additional subcellular compartment-related functions for these viral proteins. Furthermore, the immunoelectron microscopy revealed the loss of the organization and other morphological alterations of the ER (convoluted cisternae and paracrystalline structures), resembling alterations observed in liver biopsies of HCV-infected individuals and in flavivirus-infected cells.     

Formation and function of hepatitis C virus replication complexes require residues in the carboxy-terminal domain of NS4B protein

During replication, hepatitis C virus (HCV) NS4B protein rearranges intracellular membranes to form foci, or the web, the putative site for HCV replication. To understand the role of the C-terminal domain (CTD) in NS4B function, mutations were introduced into NS4B alone or in the context of HCV polyprotein. First, we show that the CTD is required for NS4B-induced web structure, but it is not sufficient to form the web nor is it required for NS4B membrane association. Interestingly, all the mutations introduced into the CTD impeded HCV genome replication, but only two resulted in a disruption of NS4B foci. Further, we found that NS4B interacts with NS3 and NS5A, and that mutations causing NS4B mislocalization have a similar effect on these proteins. Finally, we show that the redistribution of Rab5 to NS4B foci requires an intact CTD, suggesting that Rab5 facilitates NS4B foci formation through interaction with the CTD.     

A hepatitis C virus NS4B inhibitor suppresses viral genome replication by disrupting NS4B’s dimerization/multimerization as well as its interaction with NS5A

Chronic hepatitis C virus (HCV) infection is responsible for severe liver diseases including liver cirrhosis and hepatocellular carcinoma. An HCV non-structural protein 4B (NS4B) plays an essential role in viral RNA genome replication by building multi-vesicular structures around endoplasmic reticulum membranes. Especially, the second amphipathic helix of NS4B (NS4B-AH2) was shown to be essential for this process. By screening compounds against a membrane-aggregating activity of NS4B-AH2, several anti-HCV replication small molecules targeting NS4B-AH2 were discovered. However, little is known about detailed molecular mechanism of action for these NS4B-AH2 inhibitors. In this report, we provide evidences that NS4B-AH2 is required for NS4B’s dimerization/multimerization, its proper subcellular localization, as well as its interaction with NS5A. More importantly, one of NS4B-AH2 inhibitors called “anguizole” was found to be able to disrupt all of these NS4B-AH2-mediated biological functions of NS4B. This newly elucidated mechanism of action will enable us not only to better understand a central role of NS4B-AH2 in HCV life cycle but also to develop a more safe and effective new class of NS4B-AH2 inhibitors of HCV replication in the future.     

Cell culture-adaptive mutations in the NS5B gene of hepatitis C virus with delayed replication and reduced cytotoxicity

Remarkable advances have been made through recent demonstrations of hepatitis C virus (HCV) replication in cultured cells transfected with in vitro synthesized viral genome RNA. From the HCV JFH1 (genotype 2a) subcultured successively in Huh-7 cells we have identified several missense mutations near the junction of NS5A and NS5B genes. Reverse genetic analysis indicated that two mutations in the N-terminal region of NS5B replicase caused delayed viral RNA replication and protein expression in the early stage of infection. However, the mutant viruses showed significantly alleviated effects on cell growth inhibition, proteolysis of viral proteins, apoptotic DNA cleavage, and induction of antiviral responses, giving rise to a 100-fold higher titer compared to the parental JFH1 virus in a more extended time period. These results suggested that delayed replication and reduced cytotoxicity can be characteristic features of cell culture-adaptive mutants with enhanced infectivity.     

Chaperonin TRiC/CCT participates in replication of hepatitis C virus genome via interaction with the viral NS5B protein

To identify the host factors implicated in the regulation of hepatitis C virus (HCV) genome replication, we performed comparative proteome analyses of HCV replication complex (RC)-rich membrane fractions prepared from cells harboring genome-length bicistronic HCV RNA at the exponential and stationary growth phases. We found that the eukaryotic chaperonin T-complex polypeptide 1 (TCP1)-ring complex/chaperonin-containing TCP1 (TRiC/CCT) plays a role in the replication possibly through an interaction between subunit CCT5 and the viral RNA polymerase NS5B. siRNA-mediated knockdown of CCT5 suppressed RNA replication and production of the infectious virus. Gain-of-function activity was shown following co-transfection with whole eight TRiC/CCT subunits. HCV RNA synthesis was inhibited by an anti-CCT5 antibody in a cell-free assay. These suggest that recruitment of the chaperonin by the viral nonstructural proteins to the RC, which potentially facilitate folding of the RC component(s) into the mature active form, may be important for efficient replication of the HCV genome.     

Analysis of mutant NS5B proteins encoded by isolates from chimpanzees chronically infected following clonal HCV RNA inoculation

We hypothesized that mutations in the HCV NS5B polymerase, which occur during infection, may affect RNA-dependent RNA polymerase (RdRp) activity. NS5B proteins corresponding to a genotype 1a infectious clone and mutants identified in chimpanzees following inoculation with the clone were expressed and purified and their in vitro RdRp activity was compared to a NS5B genotype 1b control. A Gln-65-to-His mutation increased RdRp activity by 1.8-fold as compared to the infectious clone. Moreover, this NS5B1a protein had RdRp activity similar to the NS5B1b control. Three NS5B proteins representing mutations found in another animal had no in vitro RdRp activity. All mutations were maintained in the majority circulating virus for at least 216 weeks. The results demonstrate that some in vivo mutations of NS5B directly enhance in vitro RdRp activity. In addition, they suggest that the in vitro RdRp activity of NS5B may not always reflect in vivo activity within replication complexes.     

Hepatitis C virus NS2 protein inhibits gene expression from different cellular and viral promoters in hepatic and nonhepatic cell lines

The mechanisms leading to viral persistence and hepatocarcinogenesis in hepatitis C virus (HCV) infection are not fully understood. Recently, evidence has been accumulated that HCV viral proteins might interfere with gene expression of host cells. Here, we demonstrate that the amino-terminal portion of HCV NS2 protein inhibits the expression of reporter genes driven by different promoters or enhancer elements and also inhibits hepatitis B virus (HBV) gene expression and HBV DNA replication. The inhibitory effect of HCV NS2 on liver and non-liver-specific promoters and enhancer elements might be relevant for the pathogenesis of chronic HCV infection.     

Synthesis of dengue virus RNA in vitro: initiation and the involvement of proteins NS3 and NS5

Summary An assay for flavivirus RNA-dependent RNA polymerase activity in vitro was established using extracts of Vero cells infected with dengue virus type 2 (DEN-2) or Kunjin virus (KUN). RNA synthesis was initiated on a template of viral replicative form (RF) and RF was converted to the replicative intermediate (RI). The RNA-dependent RNA polymerase complex of DEN-2 utilised either DEN-2 or KUN RF as template, and similarly the KUN polymerase complex utilised either DEN-2 or KUN RF template. In addition, antibodies against the nonstructural proteins NS3 and NS5 inhibited the conversion of RF to RI, indicating that NS3 and NS5 are involved in viral RNA replication.     

寨卡病毒NS4A蛋白影响小鼠大脑皮质神经元的迁移

目的在体研究寨卡病毒(Zika virus)NS3和NS4A蛋白对大脑皮质神经元迁移的影响。方法通过c DNA末端快速扩增技术(RACE)及反转录PCR测定Zika病毒SZ01株基因组的开放阅读框,确定NS3和NS4A蛋白编码序列,构建融合Flag标签的p CIG蛋白表达载体。通过子宫内电转技术在E13.5 d小鼠的大脑皮质的神经前体细胞中表达病毒蛋白。免疫组化检测Flag标签、TBR1与e GFP,观察表达NS3和NS4A蛋白的细胞在E18.5 d大脑皮质中的分布,评估Zika病毒蛋白对大脑皮质神经元迁移的影响。结果 1)NS4A的氨基酸序列与NCBI数据库一致,NS3存在1处氨基酸位点突变。2)Flag标签荧光信号与e GFP荧光共定位,提示e GFP可以指示病毒蛋白在皮质中的表达。3)TBR1荧光显示在体表达NS4A后,神经元的分布与p CIG对照组及表达NS3相比有显著差异(P0.001)。结论在体表达Zika病毒的NS4A蛋白可能影响神经元迁移。     

Nonstructural proteins NS2-3 and NS4A of classical swine fever virus: essential features for infectious particle formation

The nonstructural protein NS2-3 of pestiviruses undergoes tightly regulated processing. For bovine viral diarrhea virus it was shown that uncleaved NS2-3 is required for infectious particle formation while cleaved NS3 is essential for genome replication. To further investigate the functions of NS2-3 and NS4A in the pestivirus life cycle, we established T7 RNA polymerase-dependent trans-complementation for p7-NS2-3-4A of classical swine fever virus (CSFV). Expression of NS2-3 and NS4A in trans restored the production of infectious particles from genomes lacking NS2-3 expression. Co-expression of cleaved NS4A was essential. None of the enzymatic activities harbored by NS2-3 were required for infectious particle formation. Importantly, expression of uncleavable NS2-3 together with NS4A rescued infectious particles from a genome lacking NS2, demonstrating that cleaved NS2 per se has no additional essential function. These data indicate that NS2-3 and NS3, each in association with NS4A, have independent functions in the CSFV life cycle.     

Internal cleavage of hepatitis C virus NS3 protein is dependent on the activity of NS34A protease

The nonstructural protein NS3 of the hepatitis C virus (HCV) is indispensable for virus replication and a multifunctional enzyme that contains three catalytic activities such as serine protease, helicase, and NTPase. Here, we demonstrated that the internal cleavage of the HCV NS3 protein occurs in various mammalian cells such as HepG2, COS-7, and NIH3T3. As is observed for the internal cleavage mechanism of the NS3 protein of dengue virus 2, the internal processing of HCV NS3 protein was catalyzed by the active NS3 serine protease and NS4A, but not NS3 alone. From the data acquired from extensive site-directed mutagenesis, we observed that the NS3 protein was internally cleaved at two different sites, FCH(1395) ||S(1396)KK and IPT(1428) ||S(1429)GD, within RNA helicase domain. The internal cleavage of NS3 protein by NS34A protease was also confirmed in a different isolate of HCV-1b strain. In addition, in vitro transforming assays demonstrated that the internal cleavage product of NS3, NS3a-1, appeared to have higher oncogenic potential than does intact NS3. Taken together, our results suggest that the internal cleavage of NS3 may be associated with the replication and oncogenesis of HCV.