Proteomic approach identifies HSP27 as an interacting partner of the hepatitis C virus NS5A protein

Chronic infection by HCV is closely correlated with liver diseases such as cirrhosis, steatosis, and hepatocellular carcinoma. To understand how long-term interaction between HCV and the host leads to pathogenesis, we identified cellular proteins that interact with NS5A and NS5B using a biochemical approach. Stable cell lines that express flag-NS5A or flag-NS5B under tetracycline induction were generated. The induced flag-tagged proteins were immunoprecipitated (IP'd) and associated proteins separated on 2D gels. Protein spots that specifically co-IP'd with NS5A or NS5B were identified by mass spectrometry. HSP27 was identified as a protein that specifically co-IP'd with NS5A but not with NS5B. The N-terminal regions of NS5A (a.a. 1-181) and HSP27 (a.a. 1-122) were defined to be the domains that interact with each other. HSP27 is generally distributed in the cytoplasm. When heat shocked, HSP27 is concentrated in the ER where NS5A is co-localized.     

A promiscuous biotin ligase fusion protein identifies proximal and interacting proteins in mammalian cells

We have developed a new technique for proximity-dependent labeling of proteins in eukaryotic cells. Named BioID for proximity-dependent biotin identification, this approach is based on fusion of a promiscuous Escherichia coli biotin protein ligase to a targeting protein. BioID features proximity-dependent biotinylation of proteins that are near-neighbors of the fusion protein. Biotinylated proteins may be isolated by affinity capture and identified by mass spectrometry. We apply BioID to lamin-A (LaA), a well-characterized intermediate filament protein that is a constituent of the nuclear lamina, an important structural element of the nuclear envelope (NE). We identify multiple proteins that associate with and/or are proximate to LaA in vivo. The most abundant of these include known interactors of LaA that are localized to the NE, as well as a new NE-associated protein named SLAP75. Our results suggest BioID is a useful and generally applicable method to screen for both interacting and neighboring proteins in their native cellular environment.     

Bovine leukemia virus SU protein interacts with zinc,and mutations within two interacting regions differently affect viral fusion and infectivity in vivo

Bovine leukemia virus (BLV) and human T-cell lymphotropic virus type 1 (HTLV-1) belong to the genus of deltaretroviruses. Their entry into the host cell is supposed to be mediated by interactions of the extracellular (SU) envelope glycoproteins with cellular receptors. To gain insight into the mechanisms governing this process, we investigated the ability of SU proteins to interact with specific ligands. In particular, by affinity chromatography, we have shown that BLV SU protein specifically interacted with zinc ions. To identify the protein domains involved in binding, 16 peptides distributed along the sequence were tested. Two of them appeared to be able to interact with zinc. To unravel the role of these SU regions in the biology of the virus, mutations were introduced into the env gene of a BLV molecular clone in order to modify residues potentially interacting with zinc. The fusogenic capacity of envelope mutated within the first zinc-binding region (104 to 123) was completely abolished. Furthermore, the integrity of this domain was also required for in vivo infectivity. In contrast, mutations within the second zinc-binding region (218 to 237) did not hamper the fusogenic capacity; indeed, the syncytia were even larger. In sheep, mutations in region 218 to 237 did not alter infectivity or viral spread. Finally, we demonstrated that the envelope of the related HTLV-1 was also able to bind zinc. Interestingly, zinc ions were found to be associated with the receptor-binding domain (RBD) of Friend murine leukemia virus (Fr-MLV) SU glycoprotein, further supporting their relevance in SU structure. Based on the sequence similarities shared with the Fr-MLV RBD, whose three-dimensional structure has been experimentally determined, we located the BLV zinc-binding peptide 104-123 on the opposite side of the potential receptor-binding surface. This observation supports the hypothesis that zinc ions could mediate interactions of the SU RBD either with the C-terminal part of SU, thereby contributing to the SU structural integrity, or with a partner(s) different from the receptor.     

Characterization of fusion determinants points to the involvement of three discrete regions of both E1 and E2 glycoproteins in the membrane fusion process of hepatitis C virus

Infection of eukaryotic cells by enveloped viruses requires the merging of viral and cellular membranes. Highly specific viral surface glycoproteins, named fusion proteins, catalyze this reaction by overcoming inherent energy barriers. Hepatitis C virus (HCV) is an enveloped virus that belongs to the genus Hepacivirus of the family Flaviviridae. Little is known about the molecular events that mediate cell entry and membrane fusion for HCV, although significant progress has been made due to recent developments in infection assays. Here, using infectious HCV pseudoparticles (HCVpp), we investigated the molecular basis of HCV membrane fusion. By searching for classical features of fusion peptides through the alignment of sequences from various HCV genotypes, we identified six regions of HCV E1 and E2 glycoproteins that present such characteristics. We introduced conserved and nonconserved amino acid substitutions in these regions and analyzed the phenotype of HCVpp generated with mutant E1E2 glycoproteins. This was achieved by (i) quantifying the infectivity of the pseudoparticles, (ii) studying the incorporation of E1E2 and their capacity to mediate receptor binding, and (iii) determining their fusion capacity in cell-cell and liposome/HCVpp fusion assays. We propose that at least three of these regions (i.e., at positions 270 to 284, 416 to 430, and 600 to 620) play a role in the membrane fusion process. These regions may contribute to the merging of viral and cellular membranes either by interacting directly with lipid membranes or by assisting the fusion process through their involvement in the conformational changes of the E1E2 complex at low pH.     

Hepatitis C virus NS4A inhibits cap-dependent and the viral IRES-mediated translation through interacting with eukaryotic elongation factor 1A

Summary The genomic RNA of hepatitis C virus (HCV) encodes the viral polyprotein precursor that undergoes proteolytic cleavage into structural and nonstructural proteins by cellular and the viral NS3 and NS2-3 proteases. Nonstructural protein 4A (NS4A) is a cofactor of the NS3 serine protease and has been demonstrated to inhibit protein synthesis. In this study, GST pull-down assay was performed to examine potential cellular factors that interact with the NS4A protein and are involved in the pathogenesis of HCV. A trypsin digestion followed by LC-MS/MS analysis revealed that one of the GST-NS4A-interacting proteins to be eukaryotic elongation factor 1A (eEF1A). Both the N-terminal domain of NS4A from amino acid residues 1–20, and the central domain from residues 21–34 interacted with eEF1A, but the central domain was the key player involved in the NS4A-mediated translation inhibition. NS4A(21–34) diminished both cap-dependent and HCV IRES-mediated translation in a dose-dependent manner. The translation inhibitory effect of NS4A(21–34) was relieved by the addition of purified recombinant eEF1A in an in vitro translation system. Taken together, NS4A inhibits host and viral translation through interacting with eEF1A, implying a possible mechanism by which NS4A is involved in the pathogenesis and chronic infection of HCV.     

A novel general approach to eucaryotic mutagenesis functionally identifies conserved regions within the adenovirus 13S E1A polypeptide.

A new approach to the isolation of mutations in mammalian genes was developed which permits both the selection of infrequently occurring mutants that alter the cellular morphology of recipient cells and the rapid reisolation of the mutant gene. The adenovirus type 5 13S early region 1a (E1a) gene was mutagenized in vitro with sodium bisulfite and then efficiently transferred into cells with a retrovirus shuttle vector. Three classes of mutants of the 13S E1a gene product were isolated, each of which induced a distinct morphological alteration. The mutant E1a gene was reisolated from each cell line, and the precise nucleotide changes were determined. The E1a-induced morphological alterations were further examined by the construction of single and double point mutations within different regions of the polypeptides by utilizing the amino acid substitutions obtained from the original mutants. The results suggest that each of the three regions of highly conserved amino acids within the E1a 13S polypeptide has a distinct role in the alteration of cellular morphology and the activation of gene expression.     

Transmembrane domains of hepatitis C virus envelope glycoproteins: residues involved in E1E2 heterodimerization and involvement of these domains in virus entry

The transmembrane (TM) domains of hepatitis C virus (HCV) envelope glycoproteins E1 and E2 have been shown to play multiple roles during the biogenesis of the E1E2 heterodimer. By using alanine scanning insertion mutagenesis within the TM domains of HCV envelope glycoproteins, we have previously shown that the central regions of these domains as well as the N-terminal part of the TM domain of E1 are involved in heterodimerization. Here, we used a tryptophan replacement scan of these regions to identify individual residues that participate in those interactions. Our mutagenesis study identified at least four residues involved in heterodimerization: Gly 354, Gly 358, Lys 370, and Asp 728. Interestingly, Gly 354 and Gly 358 belong to a GXXXG oligomerization motif. Our tryptophan mutants were also used to generate retrovirus-based, HCV-pseudotyped particles (HCVpp) in order to analyze the effects of these mutations on virus entry. Surprisingly, two mutants consistently displayed higher infectivity compared to that of the wild type. In contrast, HCVpp infectivity was strongly affected for many mutants, despite normal E1E2 heterodimerization and normal levels of incorporation of HCV glycoproteins into HCVpp. The characterization of some of these HCVpp mutants in the recently developed in vitro fusion assay using fluorescent-labeled liposomes indicated that mutations reducing HCVpp infectivity without altering E1E2 heterodimerization affected the fusion properties of HCV envelope glycoproteins. In conclusion, this mutational analysis identified residues involved in E1E2 heterodimerization and revealed that the TM domains of HCV envelope glycoproteins play a major role in the fusion properties of these proteins.     

The dynamic properties of the Hepatitis C Virus E2 envelope protein unraveled by molecular dynamics

Hepatitis C Virus (HCV) is one of the most persistent human viruses. Although effective therapeutic approaches have been recently discovered, their use is limited by the elevated costs. Therefore, the development of alternative/complementary strategies is an urgent need. The E2 glycoprotein, the most immunogenic HCV protein, and its variants represent natural candidates to achieve this goal. Here we report an extensive molecular dynamics (MD) analysis of the intrinsic properties of E2. Our data provide interesting clues on the global and local intrinsic dynamic features of the protein. Present MD data clearly indicate that E2 combines a flexible structure with a network of covalent bonds. Moreover, the analysis of the two most important antigenic regions of the protein provides some interesting insights into their intrinsic structural and dynamic properties. Our data indicate that a fluctuating β-hairpin represents a populated state by the region E2^412?423. Interestingly, the analysis of the epitope E2^427?446 conformation, that undergoes a remarkable rearrangement in the simulation, has significant similarities with the structure that the E2^430?442 fragment adopts in complex with a neutralizing antibody. Present data also suggest that the strict conservation of Gly436 in E2 protein of different HCV genotypes is likely dictated by structural restraints. Moreover, the analysis of the E2^412?423 flexibility provides insights into the mechanisms that some antibodies adopt to anchor Trp437 that is fully buried in E2. Finally, the present investigation suggests that MD simulations should systematically complement crystallographic studies on flexible proteins that are studied in combination with antibodies.     

Directed mutagenesis of the Trypanosoma cruzi trans-sialidase enzyme identifies two domains involved in its sialyltransferase activity

Of the increasing number of sialidases found to be made by microorganisms,the trypanosome trans-sialidase is unique in its added abilityto efficiently carry out a sialyltransferase reaction usingpreformed glymonjugates. The enzyme is predicted to have a multidomainstructure, with one domain containing sequence and expectedstructural features found in bacterial sialidases. The trans-sialidaseis very similar in overall sequence to another trypanosome enzymethat has only sialidase activity. Hybrid expression constructscontaining pieces of these trypanosome transsialidase and sialidasegenes were used to determine which regions of trans-sialidaseare required for sialyltransferase activity. Two domains werefound to influence the enzymatic activity: the N-terminal catalyticdomain, and a downstream domain that resembles an Fn3-like module. mutagenesis enzyme sialyltransferase trypanosome     

Hepatitis C virus-encoded nonstructural protein NS4A has versatile functions in viral protein processing.

A transient protein expression system in COS-1 cells was used to study the role of hepatitis C virus (HCV)-encoded NS4A protein on HCV nonstructural polyprotein processing. By analyzing the protein expression and processing of a deletion mutant polypeptide, NS delta 4A, which encodes the entire putative HCV nonstructural polyprotein except the region encoding NS4A, the versatile functions of NS4A were revealed. Most of the NS3 processed from NS delta 4A was localized in the cytosol fraction and was degraded promptly. Coproduction of NS4A stabilizes NS3 and assists in its localization in the membrane. NS4A was found to be indispensable for cleavage at the 4B/5A site but not essential for cleavage at the 5A/5B site in NS delta 4A. The functioning of NS4A as a cofactor for cleavage at the 4B/5A site was also observed when 30 amino acids around this site was used as a substrate and a serine proteinase domain of 167 amino acids, from Gly-1049 to Ser-1215, was used as an enzyme protein, suggesting that possible domains for the interaction of NS4A were in those regions of the enzyme protein (NS3) and/or the substrate protein. Two proteins, p58 and p56, were produced from NS5A. For the production of p58, equal or excess molar amounts of NS4A relative to NS delta 4A were required. Deletion analysis of NS4A revealed a minimum functional domain of NS4A of 10 amino acids, from Gly-1678 to Ile-1687.     

丙型肝炎病毒囊膜蛋白基因DNA疫苗的构建及动物免疫试验

丙型肝炎病毒(Hepatitis C virus,HCV)主要通过输血传播,可以导致多种临床型的肝炎及其它肝脏疾病,包括肝硬化及肝细胞癌[1,2].目前尚无一种有效的抗HCV的措施,这使人们把眼光放到该病的预防上,DNA疫苗的产生为研制丙型肝炎(丙肝)的预防及治疗性疫苗提供了新的思路.     

丙型肝炎病毒囊膜蛋白基因DNA疫苗的构建及动物免疫试验

丙型肝炎病毒（Hepatitis Cvirus,HCV）主要通过输血传播,可以导致多种临床型的肝炎及其它肝脏疾病,包括肝硬化及肝细胞癌。目前尚无一种有效的抗HCV的措施,这使人们把眼光放到该病的预防上,DNA疫苗的产生为研制丙型肝炎（丙肝）的预防及治疗性疫苗提供了新的思路。基因免疫是近几年快速发展起来的一种新型方法,它是将带有目的蛋白的编码基因和表达调控序列的质粒DNA导入机体组织后,使目的基因在体内表达,并全方位的刺激机体的免疫系统,     

REF-1, a protein with two bHLH domains, alters the pattern of cell fusion in C. elegans by regulating Hox protein activity

Hox genes control the choice of cell fates along the anteroposterior (AP) body axis of many organisms. In C. elegans, two Hox genes, lin-39 and mab-5, control the cell fusion decision of the 12 ventrally located Pn.p cells. Specific Pn.p cells fuse with an epidermal syncytium, hyp7, in a sexually dimorphic pattern. In hermaphrodites, Pn.p cells in the mid-body region remain unfused whereas in males, Pn.p cells adopt an alternating pattern of syncytial and unfused fates. The complexity of these fusion patterns arises because the activities of these two Hox proteins are regulated in a sex-specific manner. MAB-5 activity is inhibited in hermaphrodite Pn.p cells and thus MAB-5 normally only affects the male Pn.p fusion pattern. Here we identify a gene, ref-1, that regulates the hermaphrodite Pn.p cell fusion pattern largely by regulating MAB-5 activity in these cells. Mutation of ref-1 also affects the fate of other epidermal cells in distinct AP body regions. ref-1 encodes a protein with two basic helix-loop-helix domains distantly related to those of the hairy/Enhancer of split family. ref-1, and another hairy homolog, lin-22, regulate similar cell fate decisions in different body regions along the C. elegans AP body axis.     

Rational scanning mutagenesis of a protein kinase identifies functional regions involved in catalysis and substrate interactions

A systematic mutagenesis strategy was used to identify the functional regions and residues of a protein kinase. Clusters of the charged amino acids in the catalytic subunit of Saccharomyces cerevisiae cAMP-dependent protein kinase, were systematically mutated to alanine, producing a set of mutations that encompassed the entire molecule. Residues indispensable for enzyme activity were identified by testing the ability of the mutants to function in vivo. Active mutants were assayed in vitro, and mutants with reduced specific activity were subsequently analyzed by steady-state kinetics to determine the effects of the mutation on kcat and on Km for MgATP and for a peptide substrate. Specific residues and regions of the enzyme were identified that are likely to be important in catalysis and in binding of MgATP, functions that are common to all protein kinases. Additional regions were identified that are likely to be important in binding a peptide substrate, the recognition of which is likely to be specific to the serine/threonine protein kinases that have a requirement for basic residues around the target hydroxyamino acid. The properties of mutants defective in substrate recognition were consistent with an ordered sequential reaction mechanism. This represents the first comprehensive analysis of a protein kinase by a rational mutagenesis strategy.     

Deacylation of the transmembrane domains of Sindbis virus envelope glycoproteins E1 and E2 does not affect low-pH-induced viral membrane fusion activity

The envelope glycoproteins E1 and E2 of Sindbis virus are palmitoylated at cysteine residues within their transmembrane domains (E1 at position 430, and E2 at positions 388 and 390). Here, we investigated the in vitro membrane fusion activity of Sindbis virus variants (derived from the Toto 1101 infectious clone), in which the E1 C430 and/or E2 C388/390 residues had been substituted for alanines. Both the E1 and E2 mutant viruses, as well as a triple mutant virus, fused with liposomes in a strictly low-pH-dependent manner, the fusion characteristics being indistinguishable from those of the parent Toto 1101 virus. These results demonstrate that acylation of the transmembrane domain of Sindbis virus E1 and E2 is not required for expression of viral membrane fusion activity.     

Identification of GBF1 as a Cellular Factor Required for Hepatitis C Virus RNA Replication

In infected cells, hepatitis C virus (HCV) induces the formation of membrane alterations referred to as membranous webs, which are sites of RNA replication. In addition, HCV RNA replication also occurs in smaller membrane structures that are associated with the endoplasmic reticulum. However, cellular mechanisms involved in the formation of HCV replication complexes remain largely unknown. Here, we used brefeldin A (BFA) to investigate cellular mechanisms involved in HCV infection. BFA acts on cell membranes by interfering with the activation of several members of the family of ADP-ribosylation factors (ARF), which can lead to a wide range of inhibitory actions on membrane-associated mechanisms of the secretory and endocytic pathways. Our data show that HCV RNA replication is highly sensitive to BFA. Individual knockdown of the cellular targets of BFA using RNA interference and the use of a specific pharmacological inhibitor identified GBF1, a guanine nucleotide exchange factor for small GTPases of the ARF family, as a host factor critically involved in HCV replication. Furthermore, overexpression of a BFA-resistant GBF1 mutant rescued HCV replication in BFA-treated cells, indicating that GBF1 is the BFA-sensitive factor required for HCV replication. Finally, immunofluorescence and electron microscopy analyses indicated that BFA does not block the formation of membranous web-like structures induced by expression of HCV proteins in a nonreplicative context, suggesting that GBF1 is probably involved not in the formation of HCV replication complexes but, rather, in their activity. Altogether, our results highlight a functional connection between the early secretory pathway and HCV RNA replication.Hepatitis C virus (HCV) is an important human pathogen. It mainly infects human hepatocytes, and this often leads to chronic hepatitis, cirrhosis, or hepatocarcinoma. HCV studies have been hampered for many years by the difficulty in propagating this virus in vitro. Things have recently changed with the development of a cell culture model referred to as HCVcc (34, 60, 65), which allows the study of the HCV life cycle in cell culture and facilitates studies of the interactions between HCV and the host cell.HCV is an enveloped positive-strand RNA virus belonging to the family Flaviviridae (35). The viral genome contains a single open reading frame, which is flanked by two noncoding regions that are required for translation and replication. All viral proteins that are produced after proteolytic processing of the initially synthesized polyprotein are membrane associated (15, 43). This reflects the fact that virtually all steps of the viral life cycle occur in close association with cellular membranes.Interactions of HCV with cell membranes begin during entry. Several receptors, coreceptors, and other entry factors have been discovered over the years, which link HCV entry to specialized domains of the plasma membrane, such as tetraspanin-enriched microdomains and tight junctions (8, 16, 59). The internalization of the viral particle occurs by clathrin-mediated endocytosis (5, 40). The fusion of the viral envelope with the membrane of an acidic endosome likely mediates the transfer of the viral genome to the cytosol of the cell (5, 40, 57). However, little is known regarding the pre- and postfusion intracellular transport steps of entering viruses in the endocytic pathway.HCV RNA replication is also associated with cellular membranes. Replication begins with the translation of the genomic RNA of an incoming virus. This leads to the production of viral proteins, which in turn initiate the actual replication of the viral RNA. Mechanisms regulating the transition from the translation of the genomic RNA to its replication are not yet known. All viral proteins are not involved in RNA replication. Studies performed with subgenomic replicons demonstrated that proteins NS3-4A, NS4B, NS5A, and NS5B are necessary and sufficient for replication (6, 27, 37). RNA replication proceeds through the synthesis of a cRNA strand (negative strand), catalyzed by the RNA-dependent RNA polymerase activity of NS5B, which is then used as a template for the synthesis of new positive strands.Electron microscopy studies using a subgenomic replicon model suggested that replication takes place in membrane structures made of small vesicles, referred to as “membranous webs,” which are induced by the virus (26). Membranous webs are detectable not only in cells carrying subgenomic replicons but also in infected cells (50). They appear to be associated with the endoplasmic reticulum (ER) (26). In addition to the membranous webs, a second type of ER-associated replicase that is smaller and more mobile has recently been described (63). Cellular mechanisms leading to these membrane alterations are still poorly understood. In cells replicating and secreting infectious viruses effectively, the situation appears to be even more complex, since replicase components appear to be, at least in part, associated with cytoplasmic lipid droplets (41, 50, 56). This association depends on the capsid protein (41) and may reflect a coupling between replication and assembly. Indeed, HCV assembly and secretion show some similarities with very-low-density lipoprotein (VLDL) maturation and secretion (24, 64).Our knowledge of the cellular membrane mechanisms involved in the HCV life cycle is still limited. The expression of NS4B alone induces membrane alterations that are reminiscent of membranous webs (19). However, cellular factors that participate in this process are still unknown. On the other hand, several cellular proteins potentially involved in the HCV life cycle have been identified through their interactions with viral proteins. For some of these proteins, a functional role in infection was recently confirmed using RNA interference (48). It is very likely that other cellular factors critical to HCV infection have yet to be identified.To gain more insight into cellular mechanisms underlying HCV infection, we made use of brefeldin A (BFA), a macrocyclic lactone of fungal origin that exhibits a wide range of inhibitory actions on membrane-associated mechanisms of the secretory and endocytic pathways (30). BFA acts on cell membranes by interfering with the activation of several members of the family of ADP-ribosylation factors (ARFs). ARFs are small GTP-binding proteins of the Ras superfamily. They function as regulators of vesicular traffic, actin remodeling, and phospholipid metabolism by recruiting effectors to membranes. BFA does not actually interfere directly with ARF GTPases but rather interferes with their activation by regulators known as guanine nucleotide exchange factors (GEFs) (14, 25). We now report the identification of an ARF GEF as a cellular BFA-sensitive factor that is required for HCV replication.