A Concerted Action of Hepatitis C Virus P7 and Nonstructural Protein 2 Regulates Core Localization at the Endoplasmic Reticulum and Virus Assembly
Hepatitis C virus (HCV) assembly remains a poorly understood process. Lipid droplets (LDs) are thought to act as platforms for the assembly of viral components. The JFH1 HCV strain replicates and assembles in association with LD-associated membranes, around which viral core protein is predominantly detected. In contrast, despite its intrinsic capacity to localize to LDs when expressed individually, we found that the core protein of the high-titer Jc1 recombinant virus was hardly detected on LDs of cell culture-grown HCV (HCVcc)-infected cells, but was mainly localized at endoplasmic reticulum (ER) membranes where it colocalized with the HCV envelope glycoproteins. Furthermore, high-titer cell culture-adapted JFH1 virus, obtained after long-term culture in Huh7.5 cells, exhibited an ER-localized core in contrast to non-adapted JFH1 virus, strengthening the hypothesis that ER localization of core is required for efficient HCV assembly. Our results further indicate that p7 and NS2 are HCV strain-specific factors that govern the recruitment of core protein from LDs to ER assembly sites. Indeed, using expression constructs and HCVcc recombinant genomes, we found that p7 is sufficient to induce core localization at the ER, independently of its ion-channel activity. Importantly, the combined expression of JFH1 or Jc1 p7 and NS2 induced the same differential core subcellular localization detected in JFH1- vs. Jc1-infected cells. Finally, results obtained by expressing p7-NS2 chimeras between either virus type indicated that compatibilities between the p7 and the first NS2 trans-membrane domains is required to induce core-ER localization and assembly of extra- and intra-cellular infectious viral particles. In conclusion, we identified p7 and NS2 as key determinants governing the subcellular localization of HCV core to LDs vs. ER and required for initiation of the early steps of virus assembly.
Published in the journal:
. PLoS Pathog 7(7): e32767. doi:10.1371/journal.ppat.1002144
Category:
Research Article
doi:
https://doi.org/10.1371/journal.ppat.1002144
Summary
Hepatitis C virus (HCV) assembly remains a poorly understood process. Lipid droplets (LDs) are thought to act as platforms for the assembly of viral components. The JFH1 HCV strain replicates and assembles in association with LD-associated membranes, around which viral core protein is predominantly detected. In contrast, despite its intrinsic capacity to localize to LDs when expressed individually, we found that the core protein of the high-titer Jc1 recombinant virus was hardly detected on LDs of cell culture-grown HCV (HCVcc)-infected cells, but was mainly localized at endoplasmic reticulum (ER) membranes where it colocalized with the HCV envelope glycoproteins. Furthermore, high-titer cell culture-adapted JFH1 virus, obtained after long-term culture in Huh7.5 cells, exhibited an ER-localized core in contrast to non-adapted JFH1 virus, strengthening the hypothesis that ER localization of core is required for efficient HCV assembly. Our results further indicate that p7 and NS2 are HCV strain-specific factors that govern the recruitment of core protein from LDs to ER assembly sites. Indeed, using expression constructs and HCVcc recombinant genomes, we found that p7 is sufficient to induce core localization at the ER, independently of its ion-channel activity. Importantly, the combined expression of JFH1 or Jc1 p7 and NS2 induced the same differential core subcellular localization detected in JFH1- vs. Jc1-infected cells. Finally, results obtained by expressing p7-NS2 chimeras between either virus type indicated that compatibilities between the p7 and the first NS2 trans-membrane domains is required to induce core-ER localization and assembly of extra- and intra-cellular infectious viral particles. In conclusion, we identified p7 and NS2 as key determinants governing the subcellular localization of HCV core to LDs vs. ER and required for initiation of the early steps of virus assembly.
Introduction
About 170 million people worldwide are infected with the hepatitis C virus (HCV), a pathogen that causes chronic liver infection often leading to cirrhosis and hepatocellular carcinoma. HCV is an enveloped virus belonging to the genus Hepacivirus within the Flaviviridae family [1]. The viral genome consists of a single-stranded positive sense RNA molecule of approximately 9.6 kb. It encodes a polyprotein of about 3,000 amino acids that is cleaved both co- and post-translationally at the endoplasmic reticulum (ER) by cellular and viral proteases, giving rise to 10 proteins. The structural proteins include core, the capsid protein, and two envelope glycoproteins, E1 and E2 that mediate binding to co-receptors and entry into hepatocytes [2]–[5]. The non-structural (NS) proteins are separated from the structural proteins by a short membrane protein, p7, thought to act as a viroporin [6]. At least in vitro, p7 functions as a calcium ion channel; in cell culture, it is required for virus assembly and optimal release from infected cells [7], [8] by altering the pH equilibration in intracellular vesicles [9]. In vivo, p7 is essential for infectivity [10]. The NS region consists of the 6 following proteins: the cysteine autoprotease NS2, the serine protease/helicase complex composed of NS3 and NS4A, two proteins involved in genome replication and assembly, NS4B and NS5A, and the RNA-dependent RNA polymerase NS5B [11].
An essential function of the NS proteins is to generate cellular conditions necessary for i) viral genome replication and mRNA synthesis in specialized, ER-derived structures called replication complexes forming a higher order structure that is known as the membranous web and ii) assembly of viral particles. HCV assembly and envelopment are believed to occur at the ER [12], [13], where E1E2 accumulate [14], [15], and appear to require a coordinated integration of the cellular and viral pathways that bring the viral structural components, core, E1, E2 and viral RNA (vRNA) to the assembly site. Translation of the HCV polyprotein also occurs at ER sites and following maturation by the ER-resident signal peptidase that cleaves core-E1, E1–E2, E2–p7 and p7-NS2, the HCV structural proteins initially remain associated to ER or ER-derived membranes [11], [16]. However, this close vicinity per se is not believed to induce assembly of viral particles at ER translation sites since soon after its release from the HCV polyprotein by signal peptide peptidase (SPP) cleavage, the core protein is detected on the surface of lipid droplets (LDs) [15], [17]–[20]. Yet, the degree of core accumulation on LDs appears to depend on particular core sequences and thus the viral isolate [20].
LDs are neutral lipid storage organelles possessing an outer phospholipid monolayer proposed to form by detachment from the cytosolic leaflet of the ER membrane (reviewed in [21]). LDs are mostly tethered to the ER [22] where they serve as a source for lipid esters utilized to generate very low-density lipoproteins (VLDL) in the ER lumen. Transfer of core to LDs requires SPP-mediated removal of a C-terminal fragment corresponding to part of the E1 signal peptide that initially retains core at the ER membrane bilayer [23]. This final maturation event of core is efficient and, at steady state, fully SPP-processed core protein is detected in transfected as well as in cells infected with cell culture-grown HCV (HCVcc) [17]. Core-LD association is mediated by the D2 domain of the core protein, a domain composed of two amphipathic helices and a hydrophobic loop that insert in the LD lipid monolayer [24]. Importantly, some mutants of the D2 domain impaired in transfer to LDs give rise to lower titers of infectious HCV particles [17], [19] thus highlighting the importance of core-LD association in HCV assembly. Progressive accumulation of core on the LD surface occurs within a few hours after infection resulting in complete coating of the organelle in core-expressing cells concomitant with displacement of LD marker proteins, most notably adipophilin-related protein (ADRP) [18]. Core association to LDs is not a cell type specific event as it is observed in most LD-expressing cell types from different species [16], [25]. Whether assembly of HCV particles is restricted to hepatocytes of only humans and chimpanzees remains to be determined.
Until recently, propagation of HCV in tissue culture was not possible. This was overcome by the development of the efficiently replicating full-length HCV genome, of the JFH1 (Japanese fulminant hepatitis clone 1) isolate [26]–[28] and the high-titer Jc1 virus chimera, which is an engineered intra-genotypic chimera between J6-CF and JFH1 HCV strains [29], [30]. The JFH1 HCVcc was shown to replicate and assemble in association with LD-associated membranes, around which core was predominantly detected [17], [19]. However, one study with Jc1 chimeric genomes demonstrated a different binding affinity of core to LDs, suggesting that this difference could be important for efficiency of HCVcc assembly [20].
By comparing the replication of JFH1 and Jc1, we analyzed the subcellular localization pattern of core protein in HCV-infected cells with a particular focus on core colocalization with E2 at the ER or with specific markers of LDs. In particular, we analyzed whether E1–E2, p7 or p7-NS2 proteins expressed in cis or in trans with core modify its subcellular distribution and we characterized a minimal set of viral proteins as well as their domains involved in JFH1 vs. Jc1 differential core subcellular localization and assembly of infectious viral particles.
Results
Intracellular core localization at the ER correlates with production of infectious particles
We investigated the intracellular localization of core and E2 structural proteins in Huh7.5 cells producing JFH1 and Jc1 HCVcc particles using confocal microscopy and subcellular fractionation. Seventy-two hours after transfection with full-length RNA genomes, the core protein showed distinct cellular localization patterns in JFH1- vs. Jc1-containing cells (Figure 1). As shown earlier [15], [17]–[20], [23], [24], [31], [32], JFH1 core was mainly detected as ring-like structures associated to LD membranes (i.e., in over 98% of totals LDs; Figure 1B), indicating the accumulation of the core protein on the surface of this organelle (Figure 1A), whereas the E2 glycoprotein was strictly localized at the ER (Figure 1A) and was not detected on LDs. Moreover, JFH1 core protein was poorly detected at the ER (Figure 1A, 1B) in agreement with these previous studies. This was in sharp contrast to Jc1 core that exhibited poor localization on lipids droplets (i.e., on less than 8% of total LDs; Figure 1B), but that was readily detected throughout the ER (Figure 1A, 1B) where it colocalized with E2 (Figure 1A). Identical findings were obtained when fresh Huh7.5 cells were infected with JFH1 and Jc1 HCVcc particles harvested from the supernatants of these Huh7.5 cells 72 hr after transfection (Figure S1A). Likewise, no changes of these differential core intracellular localizations were detected whether the HCVcc carried, or did not carry, a YFP marker gene (Figure S1A vs. S1B). Altogether, these results demonstrated that the distinct intracellular core localization patterns observed were intrinsically due to strain-specific features of either virus type and not to transfection-related effects. Finally, similar poor core-LD colocalizations were detected at earlier time points (24 hr and 48 hr) upon infection with Jc1 HCVcc, in contrast to continuous strong core-ER colocalization and to sustained levels of infectious HCVcc production throughout this kinetics (Figure S2).
Interestingly, these different intracellular localization patterns correlated with efficiency of virus production attained with either virus strain. Indeed, as described earlier [20], [30], Jc1 HCVcc exhibited ca. 50–100 fold higher infectivity titers than JFH1 (Figure 1C). Furthermore, Jc1 virus was characterized by a rapid propagation in Huh7.5 cells that resulted in infection of 50–60% of cells 10 days post-transfection, whereas JFH1 spread at much lower rates, with a maximum of 5% of infected cells during the same time period (Figure 1C).
To confirm that these ER core-E2 colocalization sites represent areas of intracellular HCV assembly, fractionations of JFH1 and Jc1 HCVcc-expressing Huh7.5 cell lysates were performed using gradient centrifugation. We then analyzed the different fractions for infectious, intracellular HCV particles and for core and E2 proteins. LDs and ER present in these fractions were monitored by Western blotting for the markers ADRP (adipophilin-related protein), a LD membrane-associated protein [33], and Calnexin, an ER resident protein (Figure 2). ADRP appeared as a double band, as previously reported [34]. Note that low amounts of Calnexin (and also E2) were also detected in LD-containing fractions, as shown elsewhere [35], [36], and, vice-versa, that low amounts of ADRP were detected in the ER fraction, owing to LD tethering to and/or origin from ER membranes [37], [38]. Indeed, in IF studies, neither Calnexin nor E2 were detected on the surface of LDs (data not shown). Interestingly, core showed different enrichment in the subcellular fractions between the two viral clones (Figure 2B and 2C). JFH1 core was mainly observed in top, ADRP-labeled fractions, i.e., fractions 1–3, representing ca. 38% of total JFH1 core protein whereas Jc1 core was weakly detected in these LD fractions (less than 9%) but strongly enriched in ER fractions, i.e., fractions 9–21, where E2 co-fractionated (over 85% of total Jc1 core protein). Thus, these results corroborated our observations by confocal microscopy (Figure 1, Figure S1). Furthermore, we found that the intracellular HCV infectivity was detected in ER-containing fractions where core and E2 were detected, but never in LD-containing fractions (Figure 2, see color bars above histograms), thus indicating that core-E2 colocalization in the ER correlates with assembly of infectious HCV particles. Consistently, much lower intracellular infectivity was detected in ER fractions of JFH1 HCVcc-containing cells that produce ca. 50–100 fold less infectious particles than Jc1 (Figure 1C).
Altogether, these results indicate that the cellular localization and/or accumulation of core at the ER, which match that of E2, are necessary for efficient assembly and viral particles production.
ER localization of core in JFH1 HCVcc long-term cultures
As recent studies have characterized the adaptation of JFH1 and intergenotypic chimeras, resulting in the selection of viruses with enhanced replication [39], [40], we next analyzed the cellular localization of core protein in JFH1 and Jc1 HCVcc long-term cultures (LTC). Jc1 virus production was characterized by rapid kinetics of virus release and spread of infection affecting up to 50% of cells at day 21 (Figure 3A). In contrast, JFH1 HCVcc propagation remained restricted to up to 5% of the cell culture until day 24, when virus spread suddenly increased and reached a maximum of 55% of infected cells at day 43 (Figure 3A, left panel), suggesting an adaptation of virus propagation during LTC, as discussed earlier [41]. Surprisingly, when the cellular localization of core was analyzed in HCVcc-infected LTCs, JFH1 core displayed a predominant ER localization pattern at day 49, with some remaining associations to LDs, i.e., in ca. 16% of total LDs (Figure 3B). This pattern, which reproducibly appeared in independent HCVcc long-term cultures, was in sharp difference to the strict JFH1 core LD-localization detected at day 3 of the culture, i.e., in over 98% of total LDs (Figure 3B, Figure 1A, 1B, Figure S1). In contrast, the subcellular localization of Jc1 core remained unchanged throughout the culture period of Jc1 HCVcc (Figure 3B) consistent with constantly high virus titers obtained with this chimera. No significant changes in the sizes and numbers of LDs were detected in long-term cultures of JFH1 or Jc1 HCVcc infected cells compared to non-infected cells (data not shown).
Viruses recovered at day 49 from supernatants of JFH1 and Jc1 HCVcc-infected LTCs, termed JFH1LTC and Jc1LTC, were then used to infect fresh Huh7.5 cells. Remarkably, JFH1LTC HCVcc propagated as quickly as Jc1 in these cells, in contrast to the parental JFH1 virus (Figure 3C vs. 3A, left panels). Furthermore, the infectivity titer of JFH1LTC HCVcc correlated well with the increase of viral spread and the rise in virus titer, by ca. 40-fold, between day 3 and day 49 (Figure 3C vs. 3A, right panels). Interestingly, this increased infectivity and propagation correlated with localization of core at the ER (Figure 3D, Figure S3), a cellular compartment where E1E2 proteins were detected, and with a loss of core colocalization with LDs (Figure 3D, Figure S3). Altogether, these results indicated that JFH1LTC HCVcc, but not the infected cells themselves, underwent genetic modification(s) that favor(s) spread and infectivity, most likely through sequence changes that optimized assembly of viral particles at the ER. Several mutations were indeed detected along the adapted JFH1LTC HCVcc, in core, E1, E2, p7 and NS2 sequences (Fig. 3E). The investigation of HCVcc genomes harboring these mutations individually or in combination will be reported elsewhere (BB, OG and FLC, in preparation).
The E1/E2/p7/NS2 polyprotein influence cellular localization of core protein
To address whether the differential JFH1 vs. Jc1 core localization could be influenced by core itself and/or by other HCV factors, we generated a set of constructs that express different HCV proteins, from core to NS2 (Figure 4A). Western blotting analysis demonstrated efficient expression and maturation of core and E2 proteins in Huh7.5 cells transfected with either construct and appropriate cleavage between core and E1, E1 and E2, E2 and p7, and between p7 and NS2 (Figure 4B). A smaller band at ca. 17 kDa was detected below NS2 (23 kDa), most likely representing a truncated NS2 form, termed tNS2 as described elsewhere [42], [43].
Strikingly, the cellular localization of JFH1 or Jc1 core proteins expressed alone revealed strict localizations to the LDs, i.e., core was detected in up to 95% of total LDs but only very poorly at the ER (Figure 5A, 5B), in sharp contrast to the observations made in HCVcc-containing cells (Figure 1, Figure S1). Since core expressed alone was not secreted in the cells supernatants (data not shown), this indicated that core protein not involved in assembly accumulates on the surface of LDs, therefore arguing for additional viral factors required to target core protein to the ER. Thus, we co-expressed with core the part of the HCV polyprotein sequence differing between JFH1 and Jc1 viruses, i.e., E1, E2, p7, and NS2 [30]. Interestingly, under these conditions, we observed different cellular localization patterns for JFH1 and Jc1 core mimicking those observed in HCVcc-containing cells. Indeed, JFH1 core expressed in cis with E1 to NS2 proteins was strictly detected around the LDs, i.e., in ca. 90% of total LDs (JFH1 C—NS2 construct), whereas Jc1 core expressed with the Jc1 E1 to NS2 proteins (Jc1 C—NS2 construct) was readily localized at the ER and poorly on the LDs (i.e., in ca. 4% of total LDs) (Figure 5A, 5B). Of note and consistent with results obtained with HCVcc-containing cells (Figure 2), upon fractionation of cells expressing core to NS2 polyproteins, JFH1 core was abundantly enriched in ADRP-labeled fractions (i.e., 23% of total JFH1 core protein) in contrast to Jc1 core (i.e., 1%) that was essentially detected in ER fractions (i.e., 84%) (data not shown).
In summary, these results indicate that the co-expression of E1, E2, p7 and/or NS2 with core altered its subcellular localization similar to what was found in cells containing the corresponding full-length genomes. The data further suggest that one, or more, of the HCV proteins affected directly or indirectly the subcellular localization of core.
Protein p7 induces core localization at the endoplasmic reticulum
As E1E2 glycoproteins accumulate and are retained in the ER (Figure 1A) [14], [44] we first investigated whether E1E2 co-expression with core or core-E1E2 cleavage efficiency between JFH1 and Jc1 strains could modulate the subcellular localization of core. When core and E1E2 proteins were co-expressed (C—E2 constructs) in Huh7.5 cells, the LD localization of core from either strain remained unchanged (i.e., over 95% of LDs were coated whether JFH1 or Jc1 core were co-expressed, or not, with E1E2), as compared to core expressed alone (Figure S4 and data not shown). Likewise, E2 remained associated to the ER compartment whether or not core was co-expressed (data not shown). Thus, these data indicated that core-E1E2 protein co-expression and core-E1E2 cleavage were not implicated in the targeting of core to the LDs vs. at the ER.
To investigate the potential role of p7 in the subcellular localization of core, we co-expressed in trans core and p7 in Huh7.5 cells. Strikingly, co-expression of p7 with JFH1 or Jc1 core resulted in an ER staining pattern as deduced from the strong colocalization of core and Calnexin and in almost absent core-LD colocalization (Figure 6A, 6B). Similar results of core-ER localization were obtained when p7 was expressed stably, via retroviral vectors (Figure 6A) vs. transiently (data not shown) and when either core or core-E1E2 was expressed along with p7 (compare Figure 6A and Figure S5). Of note, no differences were detected in the distribution, size and number of LDs in cells expressing p7 as compared to mock-transduced cells (Figure S6 and data not shown). Altogether, the data indicate that core expressed alone is intrinsically targeted to the LDs, but the presence of p7, independent of E1E2 and/or cleavage between E2 and p7, induces localization of both JFH1 and Jc1 core at the ER. Moreover, using p7 and core protein sequences from different HCV strains and/or genotypes, i.e., H77, JFH1 and J6-CF, we found that p7-induced core localization at the ER occurred independent from the viral strain/genotype origin of p7 or core and when co-expressing non-autologous core and p7 proteins (data not shown). Finally, when a mutated form of p7 that abolishes its ion-channel function in vitro and in vivo (RR33/35AA JFH1 p7 or KR33/35AA Jc1 p7) [8], [9] was co-expressed, the core protein remained localized at the ER and was poorly detected on LDs (p7mut in Figure 6A, 6B, and Figure S5).
Altogether, these results indicate that p7 modulates the subcellular localization of core and that this activity is independent of p7 ion channel function; yet, this did not account for the different, strain-specific profiles of core localization observed in cells transfected or infected with full-length HCV genomes (Figure 1, Figure S1), arguing for a specific role of NS2.
Strain-specific influence of p7-NS2 in cellular localization of core
In order to test the hypothesis of an additional function provided by NS2, we expressed core in the presence of p7-NS2. Like for p7 expressed alone, co-expression of p7-NS2 did not induce differences in size and number of LDs as compared to mock-transduced cells (Figure S6). Interestingly, when core was co-expressed with p7-NS2, Jc1 core localized at the ER and poorly around LDs whereas JFH1 core was only detected around LDs (Figure 6C, 6D). The same differential core localization was detected when core and p7-NS2 were co-expressed with E1E2 (Figure S7). Hence, we concluded that the co-expression of p7-NS2 with core was sufficient to induce the differential subcellular localizations detected in JFH1- vs. Jc1-infected cells (Figures 1 and 2, Figure S1A). These results indicated that p7 and NS2 are determinants of core-E1E2 colocalization at the ER.
To determine whether the tripartite relationship between core, p7 and NS2 was strain-specific, we co-expressed JFH1 core with Jc1 p7-NS2 and Jc1 core with JFH1 p7-NS2. Surprisingly, we observed intermediate profiles as compared to the rather strict localization patterns detected for core and p7-NS2 originating from the same HCV strain. Indeed, when co-expressed with non-autologous p7-NS2 constructs, both JFH1 and Jc1 core proteins were readily detected at the ER (Figure 6C, 6D). Yet, a significant proportion of core still remained localized at the surface of LDs (Figure 6C, 6D), although JFH1 core was significantly less often found associated to LDs when co-expressed with Jc1 p7-NS2 as compared to Jc1 core co-expressed with JFH1 p7-NS2.
Altogether, these data indicate that while Jc1 p7-NS2 readily induces localization of core from either virus strain at the ER, there are direct or indirect strain-specific interactions between core, p7 and NS2 that dictate the extent by which core is associated with LDs vs. the ER.
Core-ER colocalization requires compatible trans-membranes in p7 and NS2
To investigate further the molecular basis of core, p7 and NS2 compatibility allowing core-ER vs. core-LD colocalization, we designed a series of constructs encoding JFH1 core to NS2 polyproteins in which sub-domains of p7 and/or NS2 were swapped between JFH1 and J6-CF sequences (Figure 7A). All constructs induced similar expression levels of E2, core and NS2 proteins, as compared to the parental constructs (Figure 7B).
Insertion in JFH1 C—NS2 sequence of the first trans-membrane segment (TMS) of J6-CF NS2 [42] (construct JFH1 C—p7/Jc1 NS2, Figure 7A, corresponding to the Jc1 cross-over point [30]), induced core-LD colocalization, but was not sufficient to localize JFH1 core at the ER (Figure 7C). Combined with other results above (Figure 6C, 6D and Figure S7), this suggested that the first TMS of NS2 may require compatibility with p7 to induce core localization at the ER. Indeed, the Jc1 NS2 chimera expressed along with Jc1 p7 was sufficient to localize Jc1 or JFH1 (Figure 6C, 6D) core at the ER. Thus, we expressed this chimeric NS2 protein in the context of JFH1 core to NS2 polyproteins in which the first and/or second TMS of p7 were derived from J6-CF sequence (Figure 7A). We found that replacement of both p7 TMS by those from J6-CF (JFH1 C—p7/Jc1 TM1,2—NS2 construct, Figure 7A) induced core re-localization at the ER and loss from core-LD colocalization (Figure 7C), underscoring the requirement of compatibility between p7 and NS2 TMS for core re-distribution. Furthermore, the replacement of the second p7 TMS (JFH1 C—p7/Jc1 TM2—NS2 construct, Figure 7A) was sufficient to re-localize core at the ER and to reduce LD-localization (Figure 7C). Altogether, these results suggest that a critical interaction and/or compatibility between the second TMS of p7 and the first TMS of NS2 is required to induce core-ER localization.
HCV assembly and production requires core-ER colocalization induced by p7 and NS2 interactions
To address the relevance of these findings in the context of HCVcc assembly, first, we expressed a modified JFH1 genome in which the first and second TMS of NS2 were deleted (JFH1 ΔTM1,2 NS2 construct, Figure 8A). In cells expressing this recombinant, non-infectious HCVcc genome, core protein localized around LDs and was readily detected at the ER, in contrast to the very poor core-ER colocalization detected in cells containing unmodified JFH1 HCVcc (Figure 8B). This phenotype, resembling that of core co-expressed with p7 alone (Figure 6), underscored the conclusion that the loss of a critical p7-NS2 interaction alters core distribution. Thus, we generated a series of JFH1-derived HCVcc recombinant genomes in which the first TMS of NS2 (NS2 TMS1) and either TMS of p7 (p7 TMS1 and p7 TMS2) were substituted, alone or in combination, by those from the J6-CF genome (Figure 8A). Seventy-two hours after transfection of Huh7.5 with full-length RNAs from these genomes and, as control, the parental JFH1 and Jc1 genomes, cells were analyzed for core expression and LD vs. ER localization by confocal microscopy (Figure 8B) and for production of infectious HCVcc particles (Figure 8C, D). We found that although core was detected on LDs and/or at the ER, the extent of core localization to each of these compartments differed substantially according to the specific p7/NS2 TMS combination. Interestingly, the levels of core-LD and core-ER associations were similar to those found in cells transfected with the corresponding expression constructs (compare Figure 8 with Figure 7). Overall, these results confirmed that while NS2 TMS1 from J6-CF was not sufficient to induce core localization of JFH1 HCVcc at the ER (JFH1/Jc1 NS2 HCVcc chimera), the combination of both p7 TMS1 and TMS2 with NS2 TMS1 (JFH1/Jc1 TM1,2—NS2 HCVcc chimera) induced core re-localization at the ER (Figure 8B). Moreover, the combination of p7 TMS2 (JFH1/Jc1 TM2—NS2 HCVcc chimera) induced core localization at the ER (Figure 8B).
Importantly, the ER localization of core in cells expressing these HCVcc chimeras correlated with the assembly of infectious particles. First, the introduction of the first TMS from J6-CF NS2 in JFH1 HCVcc (JFH1/Jc1 NS2 chimera; Figure 8A) strongly reduced propagation (Figure 8C) and production and infectivity (Figure 8D) of viral particles, most likely through loss of an interaction between p7 and NS2, in line with a recent study [45]. Second, supporting the hypothesis that matching p7 and NS2 TMS compatibility would restore infectivity, the simultaneous insertion of both J6-CF p7 TMS1 and TMS2 in the latter chimera (JFH1/Jc1 TM1,2—NS2 chimera; Figure 8A) increased production of both infectious and physical particles by ca. 11- and 95-fold, respectively, relative to the parental JFH1/Jc1 NS2 recombinant HCVcc genome (Figure 8D). Furthermore, the results highlighted compatibility requirements between NS2 TMS1 and either p7 TMS that correlated well core-ER colocalization to production of infectious HCV particles. Indeed, higher production of viral particles was obtained with the p7 TMS2/NS2 TMS1 combination (JFH1/Jc1 TM2—NS2 chimera), as compared to the p7 TMS1/NS2 TMS1 combination (JFH1/Jc1 TM1—NS2 HCVcc), in agreement with the poorer capacity of the latter virus to induce core-ER localization (Figure 8B). Of note, production of both extra-cellular and intra-cellular infectious particles were increased upon optimization of p7/NS2 TMS compatibility (Figure 8D), indicating that p7-NS2 concerted action regulates assembly of viral particles rather than their morphogenesis and/or egress. Finally, the increase of assembly and production of these HCVcc chimeras stimulated the growth of HCVcc in cell culture (Figure 8C). Indeed, while propagation of JFH1/Jc1 NS2 and JFH1/Jc1 TM1—NS2 HCVcc progressed very slowly, upon infection at low multiplicities of infection (MOIs of 0.01), the JFH1/Jc1 TM1,2—NS2 and JFH1/Jc1 TM2—NS2 viruses displayed much faster propagation rates, in a manner correlated with the extent of core-ER localization.
Altogether, these data indicated that core localization at the ER is necessary to allow virus assembly and requires compatible p7 and NS2 TMS.
Discussion
Soon after synthesis on ER membranes, the HCV core protein accumulates almost quantitatively on LDs surface in core-expressing cells [16] as well as in JFH1 HCVcc-infected cells [17], [19], [20], [23]. It has been proposed [19] that LDs could induce concentration of core close to the ER-located assembly site of viral particles thus providing a physical link with the vRNA replication site, an HCV-modified area of the ER. This close proximity between replication and assembly sites may facilitate the recruitment of the two HCV nucleocapsid components, core and vRNA, and allows their optimal usage towards assembly of the viral particles at E1E2-containing sites of the ER [46], [47]. LDs themselves cannot therefore be considered as assembly sites but, rather, as factories or platforms facilitating the local concentration of the different viral components in order to induce efficient assembly.
Among the different questions that arise from this model, one is how does core dissociate from the LD surface to reach the cytosolic side of the ER-membrane and the virion-forming vesicle that buds within the ER lumen? Our data sheds light on these events and underscore the crucial role of p7 and NS2 as determinants of core-E1E2 colocalization at the ER. Indeed, our results highlight intrinsic differences between low titer (JFH1) and high titer (Jc1) infectivity-producing HCV genomes regarding the intracellular localization of their core proteins. While JFH1 core is found associated around LDs of infected cells, inducing a perfect coating of these organelles, Jc1 core is poorly detected on LDs but rather, is found primarily distributed at the ER (Figures 1 and 2, Figure S1). Different hypothesis could explain the much stronger Jc1 core-ER colocalization, including: i) a rapid core-LD dissociation and re-transfer of core from the LD back to the ER membrane or to ER-derived assembly sites, ii) a blockage of core-LD association, i.e., through a poor transfer of newly synthesized, SPP-cleaved core from the ER membrane to the LD, or iii) an active capture mechanism of core localized at the border of nascent LDs where core transfers from the ER, before core can coat these organelles, towards assembly sites. Several studies [15]–[20] including those performed in JFH1 HCVcc-infected cells have indicated that accumulation of core protein on LDs occurs quantitatively and is dependent on SPP-cleavage, an efficient process in most cell types, as in our experimental conditions (Figure 4). Thus, it seems plausible that Jc1 core-ER localization is a re-association that occurs by fast dissociation of core from LDs and that promotes efficient Jc1 HCV assembly. However, the two latter hypothesis are also plausible since our kinetics experiments in Jc1 HCVcc-infected cells indicated that core does not accumulate around LDs neither at early time-points following infection, before steady-state production of novel viral particles (Figure S2) nor at later time-points, in contrast to JFH1 [17], [23].
While our data do not argue against a specific role of LDs in HCV assembly, they throw light on the functions of these organelles relatively to the ER during the initial steps of formation of viral particles. Indeed our results indicate that such an ER distribution or re-distribution of Jc1 core is likely important for HCVcc assembly since, as shown in this report, this induces colocalization with the viral surface glycoproteins, which correlates well with ca. 50–100 fold higher levels of infectious particles, as compared to JFH1. Conversely, much less frequent JFH1 core-ER localization could be detected, in relation with its lower level formation of infectious HCVcc particles. Furthermore, high-titer JFH1 HCVcc rescued after long-term culture in Huh7.5 cells exhibited an ER-localized core as compared to non-adapted JFH1 virus and to Jc1 virus (Figure 3), strongly strengthening the notion that the ER localization of core plays an important role in HCV assembly.
Data of others indicate that core, expressed alone or in JFH1 HCVcc-infected cells, induces important modifications of the LDs and of their intracellular mobility by excluding ADRP, an LD surface-resident protein, which, in turn, results in LDs accumulation to the perinuclear region [18]. This LD redistribution that occurs in a microtubule-dependent manner and involves the dynein motor protein [18], has been shown to induce their close apposition to the ER membrane [22], [38], partially surrounding the LDs and forming ‘egg-cup’ structures that facilitate transfer of small molecules in the absence of membrane fusion [37]. LD apposition to ER membranes may favor the transfer of replicated RNA to core proteins at the ER replication sites and/or the recruitment of core at assembly sites. However, despite its lower particle production, JFH1 but not Jc1 seems to induce such a modification of LD distribution [18], [20]. This suggests that other events, besides the mere LD-ER apposition, promote genome packaging and/or nucleocapsid assembly. Intriguingly, when expressed alone, the core proteins of both JFH1 and Jc1 have an intrinsic property to reach and accumulate on LDs, as shown in this report and by others [16], [25], [31], and are not detected at the ER. Altogether, these data and our results indicated that there are additional, viral strain-specific factors that govern how either core protein expressed in HCVcc-infected cells could be differentially recruited from the LDs to the ER assembly sites.
We reasoned that the identification of such viral factors would be facilitated using a complementation assay whereby core is co-expressed with other HCV protein candidates. Strikingly, our results indicate that the p7 protein is pivotal for the LD vs. ER localization of core. Indeed, p7 expression, independent of its strain-specific origin, exhibited the capacity to induce core localization at the ER.
HCV p7, an integral membrane protein, is a viroporin that has an ion-channel activity in vitro [48]–[52] and in vivo [9]. It most likely forms hexameric or heptameric complexes [53]–[55] and is primarily localized to the ER [56]–[59]. Deletion of p7 from HCV blocks an early event in virus assembly, before the formation of infectious intracellular particles [7], [20], [60]. Interestingly, our results suggest that the p7 ion-channel activity harbored by its small cytosolic loop is not required for core redistribution, because in our complementation assay, core was similarly re-localized to the ER when co-expressed with wt vs. p7 ion channel mutants. Recent evidence indicate that p7 has an proton-selective ion-channel activity in vivo and protects the acid pH-sensitive intracellular particles by preventing their acidification while transiting through otherwise acidic intracellular compartments [9]. Thus, our data are in line with these previous evidence indicating that the cytosolic loop of p7 is required for egress of infectious particles rather than for the assembly step itself [7]–[9]. Furthermore our results highlight an additional function for p7 at an early stage of viral assembly. We propose that through this function, p7 could recruit core at the ER by interacting with core itself or, alternatively, could alter core-LD colocalization by modifying LD-ER interactions. This may induce the accumulation of core at ER-derived assembly sites or allow the efficient core transfer from the LD to the ER, respectively, through mechanisms that remain to be determined. The conserved early assembly role of p7 from either BVDV [61], a pestivirus that has not been reported to require LDs for virion assembly, or HCV would rather argue for a direct interaction with core rather than for a indirect effect.
Importantly, although p7 induced core-ER localization in core/p7 co-expression assays, this did not fit with our observations in HCVcc-infected cells that revealed differential core-LD vs. core-ER localization according to JFH1 vs. Jc1 HCV strain-specificities. Interestingly, our results underscore the role of NS2 as another pivotal factor of HCV assembly. Indeed, co-expression of core with p7 and NS2 induced the same differential localization of core as detected in JFH1 vs. Jc1 HCVcc-infected cells. NS2 is a hydrophobic protein homodimer containing three transmembrane domains in its N-terminal part [42], [45] and primarily localizes with membranes of the ER [45], [59], [62]). Besides its cysteine auto-protease activity at the NS2–NS3 junction, the precise function of NS2 remains poorly defined although growing evidence suggests its involvement at an early stage of virus morphogenesis rather than during vRNA replication. Indeed, through analysis of point mutants in HCVcc, NS2 was found essential for production of infectious virus and its protease domain, but not its proteolytic activity, seemed important for this function [7], [42], [63], [64]. Furthermore, the characterization of intergenotypic chimeras has highlighted genetic interactions between the first transmembrane domain of NS2 and upstream sequences, whereas downstream NS2 regions function optimally with other NS proteins [30], [65]. Moreover, through NS2 mutations in HCVcc and analysis of revertant, infectious viruses, second-site changes have been identified in the E1, E2, p7, NS2, NS3 and NS4 sequences [8], [45], [65], [66]. Finally, recent studies identified a role of NS2 factoring the coordination of virus assembly through stable interactions with the E1E2 glycoprotein, p7, NS3–NS4A enzyme complex, and, to a lower degree, NS5A [43], [45], [59], [67]. These results were in agreement with immunofluorescence studies demonstrating colocalization of NS2 with E2 and NS3 at the ER or an ER-derived membrane compartment prior to accumulation in close proximity of LDs [45], [59], suggesting that NS2 recruits these factors to assembly sites at the LD-ER interface. Interestingly, in these analysis performed in H77, Jc1 or JFH1 HCVcc-infected cells [43], [45], [67], core was not detected in co-immunoprecipitation studies with NS2, suggesting that additional events are required to bring core, or the vRNA-core complex, to these NS2 complexes.
The molecular basis of these latter events is unknown currently although several evidence argues for p7-NS2 specific interactions that may control the recruitment of core protein to the assembly site. Indeed, in contrast to the predominant core-LD colocalization detected in JFH1 HCVcc-containing cells, a modified JFH1 HCVcc in which the first and second trans-membrane segments of NS2 were deleted induced core localization at the ER (Figure 8), thus mirroring the phenotype of core co-expressed with p7, in the absence of NS2 (Figure 6). Likewise, also indicating that the loss of a critical p7-NS2 interaction altered core distribution, our results support well an earlier report showing that core accumulates around LDs in cells expressing p7-deleted Jc1 HCVcc in contrast to parental Jc1 virus [20]. A recent study provided biochemical and cell biological evidence for a functional interaction between p7 and NS2, which, consistent with our results, was independent of its ion channel function [68]. Other evidence suggests genetic interactions between core, p7 and NS2 and indicates that the latter proteins can compensate assembly-defective mutations in core protein [46]. By using expression constructs and HCVcc recombinant genomes harboring JFH1/J6-CF p7-NS2 trans-membrane chimeras (Figure 7 and Figure 8), we provide a biochemical support for these recent results. Importantly, our study extends them by underscoring a requirement for compatibilities between the p7 and the first NS2 trans-membranes that regulate core-E2 colocalization at the ER and assembly of both extra- and intra-cellular infectious particles. Thus, it seems possible that through p7-NS2 interactions [59], NS2 modulates the capacity of p7 to induce core accumulation at the ER (Figure 6). NS2 could therefore account for two complementary functions during assembly of viral particles, first, by attracting the envelope glycoproteins at the assembly sites [43], [45], [59], [67] and second, by promoting along with p7 the recruitment of nucleocapsids to such sites. In the case of the JFH1 isolate and compared to Jc1, NS2 seems to prevent the capacity of p7 to induce core-ER accumulation (Figure 6), which could perhaps reflects a mechanism aimed to avoid the over-production of viral particles in vivo. Yet, one would expect that optimization of p7-NS2 compatibilities in recombinant JFH1-derived genomes harboring JFH1/Jc1 swaps in p7 and NS2 TMS should exhibit higher viral production (Figure 8). However, in a previous study [20], specific core sequences and/or residues were also found to modulate subcellular distribution of core and its mobility. Indeed, the insertion of the J6-CF core sequence or of its D2 domain into the JFH1 genome reduced core localization around LDs, increased its localization at alternative sites (presumably the ER) and resulted in higher yields of infectivity. Thus, our results are in agreement with this study and, combined with it [20] and with the analyses of revertant viruses [8], [45], [65], [66], indicate that interactions between core, p7 and NS2 modulate core distribution and the early stages of viral particle assembly. This presumably facilitates the encountering between HCV nucleocapsids and envelopes.
Materials and Methods
Cell culture and reagents
Huh7.5 and 293T cells were grown in Dulbecco's modified minimal essential medium (DMEM, Invitrogen, France) supplemented with 100 U/ml of penicillin, 100 µg/ml of streptomycin, and 10% fetal bovine serum. 293T cells were used as producer cells for the assembly of pseudotyped viral particles. Huh7.5 cells were used for production of HCVcc and as target cells for infection and transfection assays.
Rabbit antiserum against Calnexin (Sigma Aldrich, France), mouse anti-ADRP (clone AP125, Progen, Heidelberg, Germany), mouse anti-Actin (clone AC74, Sigma, France), mouse anti-core 19D9D6 (kind gift from C. Jolivet, bioMérieux, Lyon, France), rat anti-E2 clone 3/11 (kind gift from J. McKeating, University of Birmingham, UK), mouse anti-NS2 6H6 and mouse anti-NS5A 9E10 (kind gift from C. Rice, Rockefeller University, New York, USA) were used according to the manufacturer's instructions.
Expression constructs
All nucleotide and amino-acid positions refer to the JFH1 genome (GenBank accession number AB047639). To individually express JFH1 and Jc1 core proteins, the core sequences were amplified by PCR from the molecular clones of JFH1 and Jc1 viruses, an intra-genotypic recombinant between JFH1 and J6-CF sequences (AF177036) from core to up to the first domain of NS2 from and the remaining parts from JFH1 sequences [30], and were cloned into the phCMV-IRES expression plasmid [69]. Similar strategies were used to express core-E1E2 (C—E2 construct) and core-E1E2-p7 (C—p7 construct) polyproteins from JFH1 and Jc1 strains. NS2 sequences were amplified by PCR, sequenced and subcloned into the C—p7 expression plasmids to express the core-E1E2-p7-NS2 (C—NS2 construct) polyprotein from either HCV strains. Then, the amino acids (aa) 818 to 846, 763 to 782, 786 to 808, or 763 to 782 and 786 to 808 from the J6-CF sequence were introduced in the JFH1 C—NS2 construct to replace its p7 or NS2 trans-membrane segments, leading to JFH1 C—p7/Jc1 NS2, JFH1 C—p7/Jc1 TM1—NS2, JFH1 C—p7/Jc1 TM2—NS2 and JFH1 C—p7/Jc1 TM1,2—NS2 expression plasmids, respectively. Recombinant JFH1-derived HCVcc genomes with modified p7 and NS2 trans-membrane segments were generated from these latter constructs by swapping the corresponding p7-NS2 sequences. Finally, p7 and p7-NS2 sequences were PCR-amplified from JFH1 and Jc1 molecular clones, fused to the last 45 amino-acids derived from E2 to provide a signal peptide [60] and subcloned into the CHC murine leukemia virus (MLV)-based retroviral vector also expressing hygromycin as a selective marker [70]. The JFH1 ΔTM1,2 NS2 recombinant genome was constructed by an in-frame deletion of the first two NS2 trans-membrane segments, as described in [42] for the Jc1 virus. Details of primers, subcloning strategies and sequences are available upon request.
In vitro transcription, HCVcc production, titration and viral spread kinetics
To generate infectious HCV RNAs, plasmids pFK-JFH1 or nucleus-targeted Venus YFP-encoding pFKi389-Venus-JFH1, pFK-Jc1 or pFKi389-Venus-Jc1, and pFKi389-Venus-JFH1ΔE1E2 DNAs [8], [26], [30], [71], termed JFH1, Jc1 and JFH1ΔE1E2, respectively, were linearized at the 3′ end by AseI digestion and were treated with Mung Bean nuclease. Purified linearized DNAs were used as template for in vitro transcription with the RiboMAX (Promega Corp. USA). In vitro-transcribed RNA was delivered to cells by electroporation using Gene Pulser II apparatus (Biorad) in a L3 laboratory, according to European safety regulations, and cells were cultured under standard conditions. Infectivity titers were determined as focus-forming units (FFU)/ml. Huh7.5 cells were infected with different dilutions of culture supernatants containing extra-cellular particles or, alternatively, of lysates of HCVcc-infected cells, containing intracellular particles, that were prepared as described before [72]. Three days post-infection, FFUs were detected by FACS for YFP expression or by colony counting following NS5A immunostaining, as described previously [40]. FFU calculations were based on counts of 1 to 5% YFP or NS5A positive cells, respectively. To assess the kinetics of virus spread, Huh7.5 producer cells were split at different times and analyzed by FACS for detection of YFP reporter gene or by NS5A immuno-staining.
Quantitative detection of HCV RNA
Viral RNAs were isolated from clarified cell supernatants following Triazol/chloroform extraction and from cells pellet using a QRNeasy mini kit (Qiagen, France) as recommended by the manufacturer. 300 ng of RNA was used for Reverse Transcription (RT) using a iScript TM cDNA Synthesis kit (Biorad, France) following a step reaction of 5 min at 25°C, 30 min at 42°C and 5 min at 85°C. 5 µl of the 1/10 diluted cDNA was used for quantitative PCR (qPCR) with a StepOne Real-Time PCR apparatus (Applied Biosystems, France). HCV-specific qPCR was conducted in duplicate utilizing a FastStart Universal SYBR Green Master (ROX) (Roche, Mannheim, Germany) and the following HCV-specific primers: HCVqS: 5′-CAA GCG CCC TAT CAG GCA GT-3′ and HCVqAS: 5′-CTT CAC GCA GAA AGC GCC TA-3′. Reactions were performed in two stages by using the following conditions: stage 1, 5 min at 95°C (initial denaturation); stage 2, 40 cycles of 15 s at 95°C and 1 min at 60°C (amplification). The amount of HCV RNA was calculated by comparison to serial dilution of a full-length HCV genome encoding plasmid.
Generation of Huh7.5 stably expressing p7 and p7-NS2 proteins
Retroviral vectors expressing p7 and p7-NS2 from JFH1 and Jc1 viruses were produced from 293T cells via VSV-G-pseudotyped particles, as described previously [73], [74]. Stable expression of p7 and p7-NS2 in Huh7.5 targets cells was obtained by transduction with retroviral vector-particles recovered from supernatants of 293T producer cells, followed by hygromycin-selection.
Immuno-fluorescence (IF) and confocal microscopy imaging
Huh7.5 cells were grown on uncoated 14 mm-diameter glass coverslips and transfected using DMRIE-C reagent (Invitrogen, Cergy-Pontoise, France), according to the manufacturer's instructions. The IF stainings were performed 72 h post-transfection at room temperature. The cells were washed with PBS, fixed with 3% of paraformaldehyde in PBS for 15 min, quenched with 50 mM NH4Cl and permeabilized with 0.2% Triton-X-100 for 7 minutes. Subsequently the cells were incubated for 1 h with the primary antibody in 1% BSA/PBS, washed and stained for 1 h with the corresponding fluorescent Alexa-conjugated secondary antibody (Alexa-488 for green channel and Alexa-555 for red channel, Molecular Probes Europe BV, The Netherlands) in 1% BSA/PBS. LD staining was performed using specific cellular tracers of neutral lipids, Bodipy 493/503 (Molecular Probes Europe BV, The Netherlands) according to the manufacturer's instructions. The cells were washed several times with PBS and mounted in Mowiol 40–88 (Fluka, Buchs, Switzerland) prior to image acquisition with LSM 510 confocal equipped with an Axiovert 100 M camera (Carl Zeiss Inc., Thornwood NY, USA). We verified the absence of signal overlap in the red channel as reported in some studies [75]. We also compared permeabilization with Triton-X-100 vs. 0.1% Saponin and Mowiol 40–88 vs. Fluoromount (Sigma-Aldrich) mounting media for imaging studies of LDs owing to previous studies reporting eventual loss of LD-associated proteins while using detergent such as Triton-X-100 and glycerol-containing mounting media [76], [77]. Using either procedure, we found no differences neither in LD number, size and cellular distribution in mock-infected cells nor in core-LD vs. core-ER differential distribution between JFH1 and Jc1 HCVcc-expressing cells (Figure S8). Therefore, the results of IF presented in this article were generated using Triton-X-100 permeabilization and Mowiol 40–88 mounting media.
The frequency of core-positive LDs was determined in cells stained for core and LDs by manual counting of ca. 4,000–10,000 LDs. LDs were scored as core-positive when full core-coating of LD was detected, as previously reported [20]. The degree of localization of core at the ER was quantified by determining Pearson's correlation coefficients providing a measure for the relative degree of colocalization of core and Calnexin by using the ImageJ software [45]. The percentage of core-ER colocalization was then determined by expressing the coefficient of determination (square of Pearson's correlation coefficient), which figures the fraction of variability in the green channel that can be explained by its linear regression with the red channel [78].
Subcellular fractionation
Separation of different membrane compartments was achieved as described previously [79] with some modifications. The Huh7.5 cell pellets were washed in PBS and homogenized in 1 volume of 10 mM Hepes-NaOH 10 mM pH 7.8 (hypo-osmotic buffer). The cells were allowed to swell on ice for 10 min and were re-isolated by centrifugation at 800×g at 4°C for 2 min. The medium was returned to iso-osmoticity by removing 2/3rd of the volume of the supernatant and adding 1/3 volume of 0.60 M sucrose, 10 mM Hepes-NaOH at pH 7.8 (hyper-osmotic buffer). Cells were disrupted by passaging 20 times through a 25 G needle and lysates were separated from the nuclei by centrifugation at 13,000×g for 30 min at 4°C. Subcellular fractionation was performed in three-step iodixanol gradients. Equal protein amounts of the post-nuclear extracts (PNE) were mixed with 60% iodixanol to give a final concentration of 30%, the hypo-osmotic buffer was mixed with 60% iodixanol to generate 10 and 20% iodixanol solutions. Equal volumes of these three solutions were layered in SW60Ti centrifuge tubes and centrifuged at 50 krpm for 3 h at 4°C. 25 Fractions were collected from the top and analyzed by Western blotting, proteins were probed with antibodies directed against core, ADRP, and Calnexin.
Western blotting
After separation by SDS-polyacrylamide gel electrophoresis (PAGE), protein preparations were transferred to nitrocellulose membranes (Optitran BA-S83, Whatman, Dassel, Germany) and revealed with specific Mab, followed by the addition of goat anti-mouse, anti-rat or anti-rabbit immunoglobulin conjugated to peroxydase (Dako A/S, Glostrup, Denmark). The proteins of interest were revealed by enhanced chemiluminescence detection (SuperSignal West Pico Chemiluminescent, Thermo Scientific, Rockford, USA) as recommended by the manufacturer.
Statistical analysis
Results were expressed as mean ± SEM of n observations, as indicated in the legends of figures. Sets of data were compared with a Student's t test. Differences were considered statistically significant when P<0.05. Symbols used in figures were (*) for P<0.05, (**) for P<0.01, (***) for P<0.001, and (ns) for no significant difference, respectively.
Supporting Information
Zdroje
1. SimmondsPBukhJCombetCDeleageGEnomotoN 2005 Consensus proposals for a unified system of nomenclature of hepatitis C virus genotypes. Hepatology 42 962 973
2. EvansMJvon HahnTTscherneDMSyderAJPanisM 2007 Claudin-1 is a hepatitis C virus co-receptor required for a late step in entry. Nature 446 801 805
3. PileriPUematsuYCampagnoliSGalliGFalugiF 1998 Binding of hepatitis C virus to CD81. Science 282 938 941
4. PlossAEvansMJGaysinskayaVAPanisMYouH 2009 Human occludin is a hepatitis C virus entry factor required for infection of mouse cells. Nature 457 882 886
5. ScarselliEAnsuiniHCerinoRRoccaseccaRMAcaliS 2002 The human scavenger receptor class B type I is a novel candidate receptor for the hepatitis C virus. EMBO J 21 5017 5025
6. GonzalezMECarrascoL 2003 Viroporins. FEBS Lett 552 28 34
7. JonesCTMurrayCLEastmanDKTasselloJRiceCM 2007 Hepatitis C virus p7 and NS2 proteins are essential for production of infectious virus. J Virol 81 8374 8383
8. SteinmannEPeninFKallisSPatelAHBartenschlagerR 2007 Hepatitis C virus p7 protein is crucial for assembly and release of infectious virions. PLoS Pathog 3 e103
9. WozniakALGriffinSRowlandsDHarrisMYiM 2010 Intracellular proton conductance of the hepatitis C virus p7 protein and its contribution to infectious virus production. PLoS Pathog 6 e1001087
10. SakaiAClaireMSFaulkKGovindarajanSEmersonSU 2003 The p7 polypeptide of hepatitis C virus is critical for infectivity and contains functionally important genotype-specific sequences. Proc Natl Acad Sci U S A 100 11646 11651
11. LindenbachBDThielHJRiceCM 2007 Flaviviridae: the viruses and their replication. KnipeDMHowleyPM Fields Virology. 5th ed Philadelphia Lippincott-Raven 1101 1152
12. RoingeardPHouriouxCBlanchardEBrandDAit-GoughoulteM 2004 Hepatitis C virus ultrastructure and morphogenesis. Biol Cell 96 103 108
13. GastaminzaPChengGWielandSZhongJLiaoW 2008 Cellular determinants of hepatitis C virus assembly, maturation, degradation, and secretion. J Virol 82 2120 2129
14. DeleersnyderVPillezAWychowskiCBlightKXuJ 1997 Formation of native hepatitis C virus glycoprotein complexes. J Virol 71 697 704
15. RouilleYHelleFDelgrangeDRoingeardPVoissetC 2006 Subcellular localization of hepatitis C virus structural proteins in a cell culture system that efficiently replicates the virus. J Virol 80 2832 2841
16. BarbaGHarperFHaradaTKoharaMGoulinetS 1997 Hepatitis C virus core protein shows a cytoplasmic localization and associates to cellular lipid storage droplets. Proc Natl Acad Sci U S A 94 1200 1205
17. BoulantSTargett-AdamsPMcLauchlanJ 2007 Disrupting the association of hepatitis C virus core protein with lipid droplets correlates with a loss in production of infectious virus. J Gen Virol 88 2204 2213
18. BoulantSDouglasMWMoodyLBudkowskaATargett-AdamsP 2008 Hepatitis C virus core protein induces lipid droplet redistribution in a microtubule- and dynein-dependent manner. Traffic 9 1268 1282
19. MiyanariYAtsuzawaKUsudaNWatashiKHishikiT 2007 The lipid droplet is an important organelle for hepatitis C virus production. Nat Cell Biol 9 1089 1097
20. ShavinskayaABoulantSPeninFMcLauchlanJBartenschlagerR 2007 The lipid droplet binding domain of hepatitis C virus core protein is a major determinant for efficient virus assembly. J Biol Chem 282 37158 37169
21. MurphySMartinSPartonRG 2009 Lipid droplet-organelle interactions; sharing the fats. Biochim Biophys Acta 1791 441 447
22. OzekiSChengJTauchi-SatoKHatanoNTaniguchiH 2005 Rab18 localizes to lipid droplets and induces their close apposition to the endoplasmic reticulum-derived membrane. J Cell Sci 118 2601 2611
23. Targett-AdamsPHopeGBoulantSMcLauchlanJ 2008 Maturation of hepatitis C virus core protein by signal peptide peptidase is required for virus production. J Biol Chem 283 16850 16859
24. BoulantSMontserretRHopeRGRatinierMTargett-AdamsP 2006 Structural determinants that target the hepatitis C virus core protein to lipid droplets. J Biol Chem 281 22236 22247
25. RoingeardPHouriouxCBlanchardEPrensierG 2008 Hepatitis C virus budding at lipid droplet-associated ER membrane visualized by 3D electron microscopy. Histochem Cell Biol 130 561 566
26. WakitaTPietschmannTKatoTDateTMiyamotoM 2005 Production of infectious hepatitis C virus in tissue culture from a cloned viral genome. Nat Med 11 791 796
27. LindenbachBDEvansMJSyderAJWolkBTellinghuisenTL 2005 Complete replication of hepatitis C virus in cell culture. Science 309 623 626
28. ZhongJGastaminzaPChengGKapadiaSKatoT 2005 Robust hepatitis C virus infection in vitro. Proc Natl Acad Sci U S A 102 9294 9299
29. LindenbachBDMeulemanPPlossAVanwolleghemTSyderAJ 2006 Cell culture-grown hepatitis C virus is infectious in vivo and can be recultured in vitro. Proc Natl Acad Sci U S A 103 3805 3809
30. PietschmannTKaulAKoutsoudakisGShavinskayaAKallisS 2006 Construction and characterization of infectious intragenotypic and intergenotypic hepatitis C virus chimeras. Proc Natl Acad Sci U S A 103 7408 7413
31. MajeauNFromentinRSavardCDuvalMTremblayMJ 2009 Palmitoylation of hepatitis C virus core protein is important for virion production. J Biol Chem 284 33915 33925
32. MoradpourDEnglertCWakitaTWandsJR 1996 Characterization of cell lines allowing tightly regulated expression of hepatitis C virus core protein. Virology 222 51 63
33. NakamuraNAkashiTTanedaTKogoHKikuchiA 2004 ADRP is dissociated from lipid droplets by ARF1-dependent mechanism. Biochem Biophys Res Commun 322 957 965
34. WolinsNEQuaynorBKSkinnerJRSchoenfishMJTzekovA 2005 S3-12, Adipophilin, and TIP47 package lipid in adipocytes. J Biol Chem 280 19146 19155
35. BrasaemleDLDoliosGShapiroLWangR 2004 Proteomic analysis of proteins associated with lipid droplets of basal and lipolytically stimulated 3T3-L1 adipocytes. J Biol Chem 279 46835 46842
36. BartzRZehmerJKZhuMChenYSerreroG 2007 Dynamic activity of lipid droplets: protein phosphorylation and GTP-mediated protein translocation. J Proteome Res 6 3256 3265
37. MartinSPartonRG 2006 Lipid droplets: a unified view of a dynamic organelle. Nat Rev Mol Cell Biol 7 373 378
38. RobenekHHofnagelOBuersIRobenekMJTroyerD 2006 Adipophilin-enriched domains in the ER membrane are sites of lipid droplet biogenesis. J Cell Sci 119 4215 4224
39. KaulAWoerzIMeulemanPLeroux-RoelsGBartenschlagerR 2007 Cell culture adaptation of hepatitis C virus and in vivo viability of an adapted variant. J Virol 81 13168 13179
40. GottweinJMScheelTKHoeghAMLademannJBEugen-OlsenJ 2007 Robust hepatitis C genotype 3a cell culture releasing adapted intergenotypic 3a/2a (S52/JFH1) viruses. Gastroenterology 133 1614 1626
41. BartenschlagerRPietschmannT 2005 Efficient hepatitis C virus cell culture system: what a difference the host cell makes. Proc Natl Acad Sci U S A 102 9739 9740
42. JiraskoVMontserretRAppelNJanvierAEustachiL 2008 Structural and functional characterization of nonstructural protein 2 for its role in hepatitis C virus assembly. J Biol Chem 283 28546 28562
43. StaplefordKALindenbachBD 2011 Hepatitis C virus NS2 coordinates virus particle assembly through physical interactions with the E1–E2 glycoprotein and NS3-NS4A enzyme complexes. J Virol 85 1706 1717
44. SandrinVCossetFL 2006 Intracellular versus cell surface assembly of retroviral pseudotypes is determined by the cellular localization of the viral glycoprotein, its capacity to interact with Gag, and the expression of the Nef protein. J Biol Chem 281 528 542
45. JiraskoVMontserretRLeeJYGouttenoireJMoradpourD 2010 Structural and functional studies of nonstructural protein 2 of the hepatitis C virus reveal its key role as organizer of virion assembly. PLoS Pathog 6 e1001233
46. MurrayCLJonesCTTasselloJRiceCM 2007 Alanine scanning of the hepatitis C virus core protein reveals numerous residues essential for production of infectious virus. J Virol 81 10220 10231
47. McLauchlanJ 2009 Hepatitis C virus: viral proteins on the move. Biochem Soc Trans 37 986 990
48. GriffinSDBealesLPClarkeDSWorsfoldOEvansSD 2003 The p7 protein of hepatitis C virus forms an ion channel that is blocked by the antiviral drug, Amantadine. FEBS Lett 535 34 38
49. PavlovicDNevilleDCArgaudOBlumbergBDwekRA 2003 The hepatitis C virus p7 protein forms an ion channel that is inhibited by long-alkyl-chain iminosugar derivatives. Proc Natl Acad Sci U S A 100 6104 6108
50. PremkumarAWilsonLEwartGDGagePW 2004 Cation-selective ion channels formed by p7 of hepatitis C virus are blocked by hexamethylene amiloride. FEBS Lett 557 99 103
51. GriffinSDHarveyRClarkeDSBarclayWSHarrisM 2004 A conserved basic loop in hepatitis C virus p7 protein is required for amantadine-sensitive ion channel activity in mammalian cells but is dispensable for localization to mitochondria. J Gen Virol 85 451 461
52. MontserretRSaintNVanbelleCSalvayAGSimorreJP 2010 NMR structure and ion channel activity of the p7 protein from hepatitis C virus. J Biol Chem 285 31446 31461
53. ClarkeDGriffinSBealesLGelaisCSBurgessS 2006 Evidence for the formation of a heptameric ion channel complex by the hepatitis C virus p7 protein in vitro. J Biol Chem 281 37057 37068
54. LuikPChewCAittoniemiJChangJWentworthPJr 2009 The 3-dimensional structure of a hepatitis C virus p7 ion channel by electron microscopy. Proc Natl Acad Sci U S A 106 12712 12716
55. PatargiasGZitzmannNDwekRFischerWB 2006 Protein-protein interactions: modeling the hepatitis C virus ion channel p7. J Med Chem 49 648 655
56. Carrere-KremerSMontpellier-PalaCCocquerelLWychowskiCPeninF 2002 Subcellular localization and topology of the p7 polypeptide of hepatitis C virus. J Virol 76 3720 3730
57. GriffinSClarkeDMcCormickCRowlandsDHarrisM 2005 Signal peptide cleavage and internal targeting signals direct the hepatitis C virus p7 protein to distinct intracellular membranes. J Virol 79 15525 15536
58. HaqshenasGMackenzieJMDongXGowansEJ 2007 Hepatitis C virus p7 protein is localized in the endoplasmic reticulum when it is encoded by a replication-competent genome. J Gen Virol 88 134 142
59. PopescuCICallensNTrinelDRoingeardPMoradpourD 2011 NS2 Protein of Hepatitis C Virus Interacts with Structural and Non-Structural Proteins towards Virus Assembly. PLoS Pathog 7 e1001278
60. BrohmCSteinmannEFrieslandMLorenzICPatelA 2009 Characterization of determinants important for hepatitis C virus p7 function in morphogenesis by using trans-complementation. J Virol 83 11682 11693
61. HaradaTTautzNThielHJ 2000 E2-p7 region of the bovine viral diarrhea virus polyprotein: processing and functional studies. J Virol 74 9498 9506
62. YamagaAKOuJH 2002 Membrane topology of the hepatitis C virus NS2 protein. J Biol Chem 277 33228 33234
63. DentzerTGLorenzICEvansMJRiceCM 2009 Determinants of the hepatitis C virus nonstructural protein 2 protease domain required for production of infectious virus. J Virol 83 12702 12713
64. YiMMaYYatesJLemonSM 2009 Trans-complementation of an NS2 defect in a late step in hepatitis C virus (HCV) particle assembly and maturation. PLoS Pathog 5 e1000403
65. YiMMaYYatesJLemonSM 2007 Compensatory mutations in E1, p7, NS2, and NS3 enhance yields of cell culture-infectious intergenotypic chimeric hepatitis C virus. J Virol 81 629 638
66. PhanTBeranRKPetersCLorenzICLindenbachBD 2009 Hepatitis C virus NS2 protein contributes to virus particle assembly via opposing epistatic interactions with the E1-E2 glycoprotein and NS3-NS4A enzyme complexes. J Virol 83 8379 8395
67. MaYAnantpadmaMTimpeJMShanmugamSSinghSM 2011 Hepatitis C Virus NS2 Protein Serves as a Scaffold for Virus Assembly by Interacting with both Structural and Nonstructural Proteins. J Virol 85 86 97
68. TedburyPWelbournSPauseAKingBGriffinS 2011 The subcellular localization of the hepatitis C virus non-structural protein NS2 is regulated by an ion channel-independent function of the p7 protein. J Gen Virol 92 819 830
69. LavilletteDTarrAWVoissetCDonotPBartoschB 2005 Characterization of host-range and cell entry properties of the major genotypes and subtypes of hepatitis C virus. Hepatology 41 265 274
70. DreuxMDao ThiVLFresquetJGuerinMJuliaZ 2009 Receptor complementation and mutagenesis reveal SR-BI as an essential HCV entry factor and functionally imply its intra- and extra-cellular domains. PLoS Pathog 5 e1000310
71. KoutsoudakisGHerrmannEKallisSBartenschlagerRPietschmannT 2007 The level of CD81 cell surface expression is a key determinant for productive entry of hepatitis C virus into host cells. J Virol 81 588 598
72. GastaminzaPKapadiaSBChisariFV 2006 Differential biophysical properties of infectious intracellular and secreted hepatitis C virus particles. J Virol 80 11074 11081
73. SandrinVBosonBSalmonPGayWNegreD 2002 Lentiviral vectors pseudotyped with a modified RD114 envelope glycoprotein show increased stability in sera and augmented transduction of primary lymphocytes and CD34+ cells derived from human and nonhuman primates. Blood 100 823 832
74. NegreDMangeotPEDuisitGBlanchardSVidalainPO 2000 Characterization of novel safe lentiviral vectors derived from simian immunodeficiency virus (SIVmac251) that efficiently transduce mature human dendritic cells. Gene Ther 7 1613 1623
75. OhsakiYShinoharaYSuzukiMFujimotoT 2010 A pitfall in using BODIPY dyes to label lipid droplets for fluorescence microscopy. Histochem Cell Biol 133 477 480
76. OhsakiYMaedaTFujimotoT 2005 Fixation and permeabilization protocol is critical for the immunolabeling of lipid droplet proteins. Histochem Cell Biol 124 445 452
77. FukumotoSFujimotoT 2002 Deformation of lipid droplets in fixed samples. Histochem Cell Biol 118 423 428
78. DunnKWKamockaMMMcDonaldJH 2011 A practical guide to evaluating colocalization in biological microscopy. Am J Physiol Cell Physiol 300 C723 C742
79. KolesnikovaLBambergSBerghoferBBeckerS 2004 The matrix protein of Marburg virus is transported to the plasma membrane along cellular membranes: exploiting the retrograde late endosomal pathway. J Virol 78 2382 2393
Štítky
Hygiena a epidemiologie Infekční lékařství LaboratořČlánek vyšel v časopise
PLOS Pathogens
2011 Číslo 7
- Perorální antivirotika jako vysoce efektivní nástroj prevence hospitalizací kvůli COVID-19 − otázky a odpovědi pro praxi
- Stillova choroba: vzácné a závažné systémové onemocnění
- Diagnostický algoritmus při podezření na syndrom periodické horečky
- Jak souvisí postcovidový syndrom s poškozením mozku?
- Diagnostika virových hepatitid v kostce – zorientujte se (nejen) v sérologii
Nejčtenější v tomto čísle
- Requires Glycerol for Maximum Fitness During The Tick Phase of the Enzootic Cycle
- Comparative Genomics Yields Insights into Niche Adaptation of Plant Vascular Wilt Pathogens
- The Role of IL-15 Deficiency in the Pathogenesis of Virus-Induced Asthma Exacerbations
- “Persisters”: Survival at the Cellular Level