Membrane interaction of segment H1 (NS4B(H1)) from hepatitis C virus non-structural protein 4B

NS4B protein from hepatitis C virus (HCV) is a highly hydrophobic protein inducing a rearrangement of endoplasmic reticulum membranes responsible of the HCV replication process. Different helical elements have been found in the N- and C- terminal domains of the protein, which seem to be responsible for many key aspects of the viral replication process. In this work we have carried out a study of the binding and interaction with model biomembranes of peptide NS4B(H1), patterned after segment H1, one of these C-terminal previously identified segments. We show that NS4B(H1) partitions into phospholipid membranes; its membrane activity is modulated by lipid composition, interacting preferentially with negatively charged phospholipids as well as with sphingomyelin. Furthermore, the change in its sequence prevents the resulting peptide from interacting with the membrane. These data would support its role in the interaction of NS4B with the membrane and suggest that the region where this peptide resides could be involved in the membrane alteration which must occur in the HCV replication and/or assembly process.     

Interaction with membranes of the full C-terminal domain of protein NS4B from hepatitis C virus

Hepatitis C virus (HCV) NS4B protein is a transmembrane highly hydrophobic protein responsible for many key aspects of the viral replication process. The C-terminal part of NS4B is essential for replication and is a potential target for HCV replication inhibitors. In this work we have carried out a study of the binding to and interaction with model biomembranes of a peptide corresponding to the C-terminal domain of NS4B, NS4B(Cter). We show that NS4B(Cter) partitions into phospholipid membranes, is capable of rupturing membranes even at very low peptide-to-lipid ratios and its membrane-activity is modulated by lipid composition. NS4B(Cter) is located in a shallow position in the membrane but it is able to affect the lipid environment from the membrane surface down to the hydrophobic core. Our results identify the C-terminal region of the HCV NS4B protein as a membrane interacting domain, and therefore directly implicated in the HCV life cycle and possibly in the formation of the membranous web.     

NS4A and NS4B proteins from dengue virus: membranotropic regions

Proteins NS4A and NS4B from Dengue Virus (DENV) are highly hydrophobic transmembrane proteins which are responsible, at least in part, for the membrane arrangements leading to the formation of the viral replication complex, essential for the viral life cycle. In this work we have identified the membranotropic regions of DENV NS4A and NS4B proteins by performing an exhaustive study of membrane rupture induced by NS4A and NS4B peptide libraries on simple and complex model membranes as well as their ability to modulate the phospholipid phase transitions P(β')-L(α) of DMPC and L(β)-L(α)/L(α)-H(II) of DEPE. Protein NS4A presents three membrane active regions coincident with putative transmembrane segments, whereas NS4B presented up to nine membrane active regions, four of them presumably putative transmembrane segments. These data recognize the existence of different membrane-active segments on these proteins and support their role in the formation of the replication complex and therefore directly implicated in the DENV life cycle.     

Subcellular localization and membrane topology of the Dengue virus type 2 Non-structural protein 4B

Dengue virus (DV) is a member of the family Flaviviridae. These positive strand RNA viruses encode a polyprotein that is processed in case of DV into 10 proteins. Although for most of these proteins distinct functions have been defined, this is less clear for the highly hydrophobic non-structural protein (NS) 4B. Despite its possible role as an antagonist of the interferon-induced antiviral response, this protein may play an additional more direct role for viral replication. In this study we determined the subcellular localization, membrane association, and membrane topology of DV NS4B. We found that NS4B resides primarily in cytoplasmic foci originating from the endoplasmic reticulum. NS4B colocalizes with NS3 and double-stranded RNA, an intermediate of viral replication, arguing that NS4B is part of the membrane-bound viral replication complex. Biochemical analysis revealed that NS4B is an integral membrane protein, and that its preceding 2K signal sequence is not required for this integration. We identified three membrane-spanning segments in the COOH-terminal part of NS4B that are sufficient to target a cytosolic marker protein to intracellular membranes. Furthermore, we established a membrane topology model of NS4B in which the NH2-terminal part of the protein is localized in the endoplasmic reticulum lumen, whereas the COOH-terminal part is composed of three trans-membrane domains with the COOH-terminal tail localized in the cytoplasm. This topology model provides a good starting point for a detailed investigation of the function of NS4B in the DV life cycle.     

Conserved GXXXG- and S/T-like motifs in the transmembrane domains of NS4B protein are required for hepatitis C virus replication

Hepatitis C virus (HCV) nonstructural protein 4B (NS4B) is an integral membrane protein, which plays an important role in the organization and function of the HCV replication complex (RC). Although much is understood about its amphipathic N-terminal and C-terminal domains, we know very little about the role of the transmembrane domains (TMDs) in NS4B function. We hypothesized that in addition to anchoring NS4B into host membranes, the TMDs are engaged in intra- and intermolecular interactions required for NS4B structure/function. To test this hypothesis, we have engineered a chimeric JFH1 genome containing the Con1 NS4B TMD region. The resulting virus titers were greatly reduced from those of JFH1, and further analysis indicated a defect in genome replication. We have mapped this incompatibility to NS4B TMD1 and TMD2 sequences, and we have defined putative TMD dimerization motifs (GXXXG in TMD2 and TMD3; the S/T cluster in TMD1) as key structural/functional determinants. Mutations in each of the putative motifs led to significant decreases in JFH1 replication. Like most of the NS4B chimeras, mutant proteins had no negative impact on NS4B membrane association. However, some mutations led to disruption of NS4B foci, implying that the TMDs play a role in HCV RC formation. Further examination indicated that the loss of NS4B foci correlates with the destabilization of NS4B protein. Finally, we have identified an adaptive mutation in the NS4B TMD2 sequence that has compensatory effects on JFH1 chimera replication. Taken together, these data underscore the functional importance of NS4B TMDs in the HCV life cycle.     

The non-structural protein 4A of dengue virus is an integral membrane protein inducing membrane alterations in a 2K-regulated manner

Dengue virus (DV) is a positive sense RNA virus replicating in the cytoplasm in membranous compartments that are induced by viral infection. The non-structural protein (NS) 4A is one of the least characterized DV proteins. It is highly hydrophobic with its C-terminal region (designated 2K fragment) serving as a signal sequence for the translocation of the adjacent NS4B into the endoplasmic reticulum (ER) lumen. In this report, we demonstrate that NS4A associates with membranes via 4 internal hydrophobic regions, which are all able to mediate membrane targeting of a cytosolic reporter protein. We also developed a model for the membrane topology of NS4A in which the N-terminal third of NS4A localizes to the cytoplasm, while the remaining part contains three transmembrane segments, with the C-terminal end localized in the ER lumen. Subcellular localization experiments in DV-infected cells revealed that NS4A resides primarily in ER-derived cytoplasmic dot-like structures that also contain dsRNA and other DV proteins, suggesting that NS4A is a component of the membrane-bound viral replication complex (RC). Interestingly, the individual expression of DV NS4A lacking the 2K fragment resulted in the induction of cytoplasmic membrane alterations resembling virus-induced structures, whereas expression of full-length NS4A does not induce comparable membrane alterations. Thus, proteolytic removal of the 2K peptide appears to be important for induction of membrane alterations that may harbor the viral RC. These results shed new light on the role of NS4A in the DV replication cycle and provide a model of how this protein induces membrane rearrangements and how this property may be regulated.     

Determinants for membrane association of the hepatitis C virus RNA-dependent RNA polymerase

The hepatitis C virus (HCV) RNA-dependent RNA polymerase (RdRp), represented by nonstructural protein 5B (NS5B), is believed to form a membrane-associated RNA replication complex together with other nonstructural proteins and as yet unidentified host components. However, the determinants for membrane association of this essential viral enzyme have not been defined. By double label immunofluorescence analyses, NS5B was found in the endoplasmic reticulum (ER) or an ER-like modified compartment both when expressed alone or in the context of the entire HCV polyprotein. The carboxyl-terminal 21 amino acid residues were necessary and sufficient to target NS5B or a heterologous protein to the cytosolic side of the ER membrane. This hydrophobic domain is highly conserved among 269 HCV isolates analyzed and predicted to form a transmembrane alpha-helix. Association of NS5B with the ER membrane occurred by a posttranslational mechanism that was ATP-independent. These features define the HCV RdRp as a new member of the tail-anchored protein family, a class of integral membrane proteins that are membrane-targeted posttranslationally via a carboxyl-terminal insertion sequence. Formation of the HCV replication complex, therefore, involves specific determinants for membrane association that represent potential targets for antiviral intervention.     

Membrane topology of the hepatitis C virus NS2 protein

The hepatitis C virus (HCV) NS2 protein is a hydrophobic protein. Previous studies indicate that this protein is an integral membrane protein, which is targeted to the membrane of the endoplasmic reticulum (ER) by the signal sequence located in its preceding p7 protein. In this report, we demonstrate that the membrane association of NS2 is p7-independent and occurs co-translationally. Further deletion-mapping studies suggest the presence of two internal signal sequences in NS2. These two internal signal sequences, which are located within amino acids 839-883 and amino acids 928-960, could target the alpha-globin reporter, a cytosolic protein, to the membrane compartments in HuH7 hepatoma cells. The presence of multiple signal sequences for its membrane association suggests that NS2 has multiple transmembrane domains. The glycosylation studies indicate that both amino and carboxyl termini of NS2 are located in the endoplasmic reticulum lumen. Based on these results, a model for the NS2 membrane topology is presented.     

Topology of the membrane-associated hepatitis C virus protein NS4B

Hepatitis C virus (HCV) belongs to the Hepacivirus genus in the Flaviviridae family. Among the least known viral proteins in this family is the nonstructural protein NS4B, which has been suggested to be a part of the replication complex. Hydrophobicity plots indicate a common profile among the NS4B proteins from different members of the Flaviviridae family, suggesting a common function. In order to gain a deeper understanding of the nature of HCV NS4B, we have determined localization and topology of this protein by using recombinant HCV NS4B constructs. The protein localized to the endoplasmic reticulum (ER), but also induced a pattern of cytoplasmic foci positive for markers of the ER. Computer predictions of the membrane topology of NS4B suggested that it has four transmembrane segments. The N and C termini were anticipated to be localized in the cytoplasm, because they are processed by the cytoplasmic NS3 protein. By introducing glycosylation sites at various positions in HCV NS4B, we show that the C terminus is cytoplasmic and the loop around residue 161 is lumenal as predicted. Surprisingly, the N-terminal tail was translocated into the lumen in a considerable fraction of the NS4B molecules, most likely by a posttranslational process. Interestingly, NS4B proteins of the yellow fever and dengue viruses also have their N termini located in the ER lumen due to an N-terminal signal peptide not found in NS4B of HCV. A shared topology achieved in two different ways supports the notion of a common function for NS4B in FLAVIVIRIDAE:     

Conserved determinants for membrane association of nonstructural protein 5A from hepatitis C virus and related viruses

Nonstructural protein 5A (NS5A) is a membrane-associated essential component of the hepatitis C virus (HCV) replication complex. An N-terminal amphipathic alpha helix mediates in-plane membrane association of HCV NS5A and at the same time is likely involved in specific protein-protein interactions required for the assembly of a functional replication complex. The aim of this study was to identify the determinants for membrane association of NS5A from the related GB viruses and pestiviruses. Although primary amino acid sequences differed considerably, putative membrane anchor domains with amphipathic features were predicted in the N-terminal domains of NS5A proteins from these viruses. Confocal laser scanning microscopy, as well as membrane flotation analyses, demonstrated that NS5As from GB virus B (GBV-B), GBV-C, and bovine viral diarrhea virus, the prototype pestivirus, display membrane association characteristics very similar to those of HCV NS5A. The N-terminal 27 to 33 amino acid residues of these NS5A proteins were sufficient for membrane association. Circular dichroism analyses confirmed the capacity of these segments to fold into alpha helices upon association with lipid-like molecules. Despite structural conservation, only very limited exchanges with sequences from related viruses were tolerated in the context of functional HCV RNA replication, suggesting virus-specific interactions of these segments. In conclusion, membrane association of NS5A by an N-terminal amphipathic alpha helix is a feature shared by HCV and related members of the family Flaviviridae. This observation points to conserved roles of the N-terminal amphipathic alpha helices of NS5A in replication complex formation.     

Reticulon 3 interacts with NS4B of the hepatitis C virus and negatively regulates viral replication by disrupting NS4B self‐interaction

The non‐structural protein 4B (NS4B) of the hepatitis C virus (HCV) is an endoplasmic reticulum (ER) membrane protein comprising two consecutive amphipathic α‐helical domains (AH1 and AH2). Its self‐oligomerization via the AH2 domain is required for the formation of the membranous web that is necessary for viral replication. Previously, we reported that the host‐encoded ER‐associated reticulon 3 (RTN3) protein is involved in the formation of the replication‐associated membranes of (+)RNA enteroviruses during viral replication. In this study, we demonstrated that the second transmembrane region of RTN3 competed for, and bound to, the AH2 domain of NS4B, thus abolishing NS4B self‐interaction and leading to the downregulation of viral replication. This interaction was mediated by two crucial residues, lysine 52 and tyrosine 63, of AH2, and was regulated by the AH1 domain. The silencing of RTN3 in Huh7 and AVA5 cells harbouring an HCV replicon enhanced the replication of HCV, which was counteracted by the overexpression of recombinant RTN3. The synthesis of viral RNA was also increased in siRNA‐transfected human primary hepatocytes infected with HCV derived from cell culture. Our results demonstrated that RTN3 acted as a restriction factor to limit the replication of HCV.     

Hepatitis C virus NS4B targets lipid droplets through hydrophobic residues in the amphipathic helices

Lipid droplets (LD) are dynamic storage organelles that are involved in lipid homeostasis. Hepatitis C virus (HCV) is closely associated with LDs. HCV Core and nonstructural (NS) proteins colocalize with LDs and presumably are involved in virion formation at that site. We demonstrated that HCV NS4B, an integral membrane protein in endoplasmic reticulum (ER), strongly targeted LDs. Confocal imaging studies showed that NS4B localized at the margins of LDs. Biochemical fractionation of HCV-replicating cells suggested that NS4B existed in membranes associated with LDs rather than on the LD surface membrane itself. The N- and C-terminal cytosolic domains of NS4B showed targeting of LDs, with the former being much stronger. In both domains, activity was present in the region containing an amphipathic α-helix, in which 10 hydrophobic residues were identified as putative determinants for targeting LDs. JFH1 mutants with alanine substitutions for the hydrophobic residues were defective for virus replication. W43A mutant with a single alanine substitution showed loss of association of NS4B with LDs and severely reduced release of infectious virions compared with wild-type JFH1. NS4B plays a crucial role in virus replication at the site of virion formation, namely, the microenvironment associated with LDs.     

Regulated cleavages at the West Nile virus NS4A-2K-NS4B junctions play a major role in rearranging cytoplasmic membranes and Golgi trafficking of the NS4A protein

A common feature associated with the replication of most RNA viruses is the formation of a unique membrane environment encapsulating the viral replication complex. For their part, flaviviruses are no exception, whereupon infection causes a dramatic rearrangement and induction of unique membrane structures within the cytoplasm of infected cells. These virus-induced membranes, termed paracrystalline arrays, convoluted membranes, and vesicle packets, all appear to have specific functions during replication and are derived from different organelles within the host cell. The aim of this study was to identify which protein(s) specified by the Australian strain of West Nile virus, Kunjin virus (KUNV), are responsible for the dramatic membrane alterations observed during infection. Thus, we have shown using immunolabeling of ultrathin cryosections of transfected cells that expression of the KUNV polyprotein intermediates NS4A-4B and NS2B-3-4A, as well as that of individual NS4A proteins with and without the C-terminal transmembrane domain 2K, resulted in different degrees of rearrangement of cytoplasmic membranes. The formation of the membrane structures characteristic for virus infection required coexpression of an NS4A-NS4B cassette with the viral protease NS2B-3pro which was shown to be essential for the release of the individual NS4A and NS4B proteins. Individual expression of NS4A protein retaining the C-terminal transmembrane domain 2K resulted in the induction of membrane rearrangements most resembling virus-induced structures, while removal of the 2K domain led to a less profound membrane rearrangement but resulted in the redistribution of the NS4A protein to the Golgi apparatus. The results show that cleavage of the KUNV polyprotein NS4A-4B by the viral protease is the key initiation event in the induction of membrane rearrangement and that the NS4A protein intermediate containing the uncleaved C-terminal transmembrane domain plays an essential role in these membrane rearrangements.     

The C-terminal hydrophobic domain of hepatitis C virus RNA polymerase NS5B can be replaced with a heterologous domain of poliovirus protein 3A

Replication of the plus-stranded RNA genome of hepatitis C virus (HCV) occurs in a membrane-bound replication complex consisting of viral and cellular proteins and viral RNA. NS5B, the RNA polymerase of HCV, is anchored to the membranes via a C-terminal 20-amino-acid-long hydrophobic domain, which is flanked on each side by a highly conserved positively charged arginine. Using a genotype 1b subgenomic replicon (V. Lohmann, F. Korner, J. O. Koch, U. Herian, L. Theilmann, and R. Bartensclager, Science 285:110-113, 1999), we determined the effect of mutations of some highly conserved residues in this domain. The replacement of arginine 570 with alanine completely abolished the colony-forming ability by the replicon, while a R591A change was found to be highly detrimental to replication, viability, and membrane binding by the mutant NS5B protein. Mutations of two other highly conserved amino acids (L588A and P589A) reduced but did not eliminate colony formation. It was of interest, if specific amino acid residues play a role in membrane anchoring of NS5B and replication, to determine whether a complete exchange of the NS5B hydrophobic domain with a domain totally unrelated to NS5B would ablate replication. We selected the 22-amino-acid-long hydrophobic domain of poliovirus polypeptide 3A that is known to adopt a transmembrane configuration, thereby anchoring 3A to membranes. Surprisingly, either partial or full replacement of the NS5B hydrophobic domain with the anchor sequences of poliovirus polypeptide 3A resulted in the replication of replicons whose colony-forming abilities were reduced compared to that of the wild-type replicon. Upon continued passage of the replicon in Huh-7 cells in the presence of neomycin, the replication efficiency of the replicon increased. However, the sequence of the poliovirus polypeptide 3A hydrophobic domain, in the context of the subgenomic HCV replicon, was stably maintained throughout 40 passages. Our results suggest that anchoring NS5B to membranes is necessary but that the amino acid sequence of the anchor per se does not require HCV origin. This suggests that specific interactions between the NS5B hydrophobic domain and other membrane-bound factors may not play a decisive role in HCV replication.     

The essential role of C-terminal residues in regulating the activity of hepatitis C virus RNA-dependent RNA polymerase

We have previously determined the crystal structure of a non-structural 5B (NS5B) protein, an RNA-dependent RNA polymerase (RdRp) of hepatitis C virus (HCV). NS5B protein with the hydrophobic C-terminal 21 amino acid residues truncated, designated NS5B(570), shows a typical nucleotide polymerase structure resembling a right-hand shape. In the crystal structure, a C-terminal region between Leu545 and His562 occupies a putative RNA-binding cleft of this polymerase and seems to inhibit the polymerase activity. Varieties of recombinant NS5B proteins (NS5B(552), NS5B(544), NS5B(536) or NS5B(531), with C-terminal 39, 47, 55 or 60 amino acid residues truncated, respectively) were systematically constructed to elucidate effects of the region on the polymerase activity. NS5B(544), NS5B(536) and NS5B(531) showed markedly higher RdRp activities compared to the activities of NS5B(570) or NS5B(552). Furthermore, when the hydrophobic amino acid residues Leu547, Trp550 and Phe551 (LWF) in NS5B(570) and NS5B(552) were changed to alanine, their activities were higher than that of the original NS5B(570). The crystal structures of the various recombinant NS5B proteins were also determined. Structural comparison of the NS5B proteins indicates that the activation was caused by elimination of a unique hydrophobic interaction between the three C-terminal residues and a shallowly concave pocket consisting of thumb and palm domains.     

乙型肝炎病毒S蛋白的序列特征分析

乙肝病毒S蛋白是病毒的包膜蛋白,与病毒进入细胞有关,它存在逆转录过程并且具有极强的潜伏性。本论文应用生物信息学分析乙肝病毒S蛋白的序列特征,利用在线分析软件预测乙肝病毒S蛋白的理化性质和亲疏水性、跨膜区域、信号肽特征、磷酸化位点、二级结构以及乙肝病毒S蛋白的最佳抗原表位形成位置等。结果显示了乙肝病毒S蛋白由226个氨基酸组成,理论等电点是8.21,为不稳定蛋白,总平均亲水性为0.649,是疏水蛋白质,并且该蛋白存在信号肽,有4个跨膜区,有30个潜在的磷酸化位点,主要二级结构为α螺旋和无规则卷曲,同时,结合乙型肝炎病毒S蛋白的序列可及性、线性表位、β转角、柔性、抗原性的预测结果,可以找到潜在的抗原表位区域,为乙型肝炎的表位疫苗研制提供重要的参考依据,有利于进一步对乙型肝炎S蛋白的抗原性进行研究。     

A genetic interaction between hepatitis C virus NS4B and NS3 is important for RNA replication

Hepatitis C virus (HCV) nonstructural protein 4B (NS4B), a poorly characterized integral membrane protein, is thought to function as a scaffold for replication complex assembly; however, functional interactions with the other HCV nonstructural proteins within this complex have not been defined. We report that a Con1 chimeric subgenomic replicon containing the NS4B gene from the closely related H77 isolate is defective for RNA replication in a transient assay, suggesting that H77 NS4B is unable to productively interact with the Con1 replication machinery. The H77 NS4B sequences that proved detrimental for Con1 RNA replication resided in the predicted N- and C-terminal cytoplasmic domains as well as the central transmembrane region. Selection for Con1 derivatives that could utilize the entire H77 NS4B or hybrid Con1-H77 NS4B proteins yielded mutants containing single amino acid substitutions in NS3 and NS4A. The second-site mutations in NS3 partially restored the replication of Con1 chimeras containing the N-terminal or transmembrane domains of H77 NS4B. In contrast, the deleterious H77-specific sequences in the C terminus of NS4B, which mapped to a cluster of four amino acids, were completely suppressed by second-site substitutions in NS3. Collectively, these results provide the first evidence for a genetic interaction between NS4B and NS3 important for productive HCV RNA replication.     

The membrane-active regions of the dengue virus proteins C and E

We have identified the membranotropic regions of proteins C and E of DENV virus by performing an exhaustive study of membrane rupture induced by two C and E-derived peptide libraries on model membranes having different phospholipid compositions as well as its ability to modulate the DEPE L(β)-L(α) and L(α)-H(II) phospholipid phase transitions. Protein C presents one hydrophobic leakage-prone region coincidental with a proposed membrane interacting domain, whereas protein E presents five membrane-rupture zones coincidental with different significant zones of the protein, i.e., the fusion peptide, a proline-rich sequence, a sequence containing a hydrophobic pocket as well as the stem and transmembrane domains of the protein. The identification of these membrane-active segments supports their role in viral membrane fusion, formation of the replication complex and morphogenesis and therefore attractive targets for development of new anti-viral compounds.     

Dimerization of the hepatitis C virus nonstructural protein 4B depends on the integrity of an aminoterminal basic leucine zipper

The hepatitis C virus (HCV) nonstructural (NS) protein 4B is known for protein–protein interactions with virus and host cell factors. Only little is known about the corresponding protein binding sites and underlying molecular mechanisms. Recently, we have predicted a putative basic leucine zipper (bZIP) motif within the aminoterminal part of NS4B. The aim of this study was to investigate the importance of this NS4B bZIP motif for specific protein–protein interactions. We applied in silico approaches for 3D‐structure modeling of NS4B‐homodimerization via the bZIP motif and identified crucial amino acid positions by multiple sequence analysis. The selected sites were used for site‐directed mutagenesis within the NS4B bZIP motif and subsequent co‐immunoprecipitation of wild‐type and mutant NS4B molecules. Respective interaction energies were calculated for wild‐type and mutant structural models. NS4B‐homodimerization with a gradual alleviation of dimer interaction from wild‐type towards the mutant‐dimers was observed. The putative bZIP motif was confirmed by a co‐immunoprecipitation assay and western blot analysis. NS4B‐NS4B interaction depends on the integrity of the bZIP hydrophobic core and can be abolished due to changes of crucial residues within NS4B. In conclusion, our data indicate NS4B‐homodimerization and that this interaction is facilitated by the aminoterminal part containing a bZIP motif.     

Characterization of GB virus B polyprotein processing reveals the existence of a novel 13-kDa protein with partial homology to hepatitis C virus p7 protein

Although responsible for a major health problem worldwide, hepatitis C virus is difficult to study because of the absence of fully permissive cell cultures or experimental animal models other than the chimpanzee. GB virus B (GBV-B), a closely related hepatotropic virus that infects small New World primates and replicates efficiently in primary hepatocyte cultures, is an attractive surrogate model system. However, little is known about processing of the GBV-B polyprotein. Because an understanding of these events is critical to further development of model GBV-B systems, we characterized signal peptidase processing of the polyprotein segment containing the putative structural proteins. We identified the exact N termini of the mature GBV-B envelope proteins, E1 and E2, and the first nonstructural protein, NS2, by direct amino acid sequencing. Interestingly, these studies document the existence of a previously unrecognized 13-kDa protein (p13) located between E2 and NS2 within the polyprotein. We compared the sequence of the p13 protein to that of hepatitis C virus p7, a small membrane-spanning protein with a similar location in the polyprotein and recently identified ion channel activity. The C-terminal half of p13 shows clear homology with p7, suggesting a common function, but the substantially larger size of p13, with 4 rather than 2 predicted transmembrane segments, indicates a different structural organization and/or additional functions. The identification of p13 in the GBV-B polyprotein provides strong support for the hypothesis that ion channel-forming proteins are essential for the life cycle of flaviviruses, possibly playing a role in virion morphogenesis and/or virus entry into cells.