Proteinase-polymerase precursor as the active form of feline calicivirus RNA-dependent RNA polymerase

The objective of this study was to identify the active form of the feline calicivirus (FCV) RNA-dependent RNA polymerase (RdRP). Multiple active forms of the FCV RdRP were identified. The most active enzyme was the full-length proteinase-polymerase (Pro-Pol) precursor protein, corresponding to amino acids 1072 to 1763 of the FCV polyprotein encoded by open reading frame 1 of the genome. Deletion of 163 amino acids from the amino terminus of Pro-Pol (the Val-1235 amino terminus) caused a threefold reduction in polymerase activity. Deletion of an additional one (the Thr-1236 amino terminus) or two (the Ala-1237 amino terminus) amino acids produced derivatives that were 7- and 175-fold, respectively, less active than Pro-Pol. FCV proteinase-dependent processing of Pro-Pol in the interdomain region preceding Val-1235 was not observed in the presence of a catalytically active proteinase; however, processing within the polymerase domain was observed. Inactivation of proteinase activity by changing the catalytic cysteine-1193 to glycine permitted the production and purification of intact Pro-Pol. Biochemical analysis of Pro-Pol showed that this enzyme has properties expected of a replicative polymerase, suggesting that Pro-Pol is an active form of the FCV RdRP.     

Mapping of the Feline Calicivirus Proteinase Responsible for Autocatalytic Processing of the Nonstructural Polyprotein and Identification of a Stable Proteinase-Polymerase Precursor Protein

Expression of the region of the feline calicivirus (FCV) ORF1 encoded by nucleotides 3233 to 4054 in an in vitro rabbit reticulocyte system resulted in synthesis of an active proteinase that specifically processes the viral nonstructural polyprotein. Site-directed mutagenesis of the cysteine (Cys1193) residue in the putative active site of the proteinase abolished autocatalytic cleavage as well as cleavage of the viral capsid precursor, suggesting that this "3C-like" proteinase plays an important role in proteolytic processing during viral replication. Expression of the region encoding the C-terminal portion of the FCV ORF1 (amino acids 942 to 1761) in bacteria allowed direct N-terminal sequence analysis of the virus-specific polypeptides produced in this system. The results of these analyses indicate that the proteinase cleaves at amino acid residues E960-A961, E1071-S1072, E1345-T1346, and E1419-G1420; however, the cleavage efficiency is varied. The E1071-S1072 cleavage site defined the N terminus of a 692-amino-acid protein that contains sequences with similarity to the picornavirus 3C proteinase and 3D polymerase domains. Immunoprecipitation of radiolabeled proteins from FCV-infected feline kidney cells with serum raised against the FCV ORF1 C-terminal region showed that this "3CD-like" proteinase-polymerase precursor protein is apparently stable and accumulates in cells during infection.     

Cleavage of the Feline Calicivirus Capsid Precursor Is Mediated by a Virus-Encoded Proteinase

Feline calicivirus (FCV), a member of the Caliciviridae, produces its major structural protein as a precursor polyprotein from a subgenomic-sized mRNA. In this study, we show that the proteinase responsible for processing this precursor into the mature capsid protein is encoded by the viral genome at the 3′-terminal portion of open reading frame 1 (ORF1). Protein expression studies of either the entire or partial ORF1 indicate that the proteinase is active when expressed either in in vitro translation or in bacterial cells. Site-directed mutagenesis was used to characterize the proteinase Glu-Ala cleavage site in the capsid precursor, utilizing an in vitro cleavage assay in which mutant precursor proteins translated from cDNA clones were used as substrates for trans cleavage by the proteinase. In general, amino acid substitutions in the P1 position (Glu) of the cleavage site were less well tolerated by the proteinase than those in the P1′ position (Ala). The precursor cleavage site mutations were introduced into an infectious cDNA clone of the FCV genome, and transfection of RNA derived from these clones into feline kidney cells showed that efficient cleavage of the capsid precursor by the virus-encoded proteinase is a critical determinant in the growth of the virus.     

Cleavage map and proteolytic processing of the murine norovirus nonstructural polyprotein in infected cells

Murine norovirus (MNV) is presently the only member of the genus Norovirus in the Caliciviridae that can be propagated in cell culture. The goal of this study was to elucidate the proteolytic processing strategy of MNV during an authentic replication cycle in cells. A proteolytic cleavage map of the ORF1 polyprotein was generated, and the virus-encoded 3C-like (3CL) proteinase (Pro) mediated cleavage at five dipeptide cleavage sites, 341E/G342, Q705/N706, 870E/G871, 994E/A995, and 1177Q/G1178, that defined the borders of six proteins with the gene order p38.3 (Nterm)-p39.6 (NTPase)-p18.6-p14.3 (VPg)-p19.2 (Pro)-p57.5 (Pol). Bacterially expressed MNV 3CL Pro was sufficient to mediate trans cleavage of the ORF1 polyprotein containing the mutagenized Pro sequence into products identical to those observed during cotranslational processing of the authentic ORF1 polyprotein in vitro and to those observed in MNV-infected cells. Immunoprecipitation and Western blot analysis of proteins produced in virus-infected cells demonstrated efficient cleavage of the proteinase-polymerase precursor. Evidence for additional processing of the Nterm protein in MNV-infected cells by caspase 3 was obtained, and Nterm sequences 118DRPD121 and 128DAMD131 were mapped as caspase 3 cleavage sites by site-directed mutagenesis. The availability of the MNV nonstructural polyprotein cleavage map in concert with a permissive cell culture system should facilitate studies of norovirus replication.     

Processing of the yellow fever virus nonstructural polyprotein: a catalytically active NS3 proteinase domain and NS2B are required for cleavages at dibasic sites.

The vaccinia virus-T7 transient expression system was used to further examine the role of the NS3 proteinase in processing of the yellow fever (YF) virus nonstructural polyprotein in BHK cells. YF virus-specific polyproteins and cleavage products were identified by immunoprecipitation with region-specific antisera, by size, and by comparison with authentic YF virus polypeptides. A YF virus polyprotein initiating with a signal sequence derived from the E protein fused to the N terminus of NS2A and extending through the N-terminal 356 amino acids of NS5 exhibited processing at the 2A-2B, 2B-3, 3-4A, 4A-4B, and 4B-5 cleavage sites. Similar results were obtained with polyproteins whose N termini began within NS2A (position 110) or with NS2B. When the NS3 proteinase domain was inactivated by replacing the proposed catalytic Ser-138 with Ala, processing at all sites was abolished. The results suggest that an active NS3 proteinase domain is necessary for cleavage at the diabasic nonstructural cleavage sites and that cleavage at the proposed 4A-4B signalase site requires prior cleavage at the 4B-5 site. Cleavages were not observed with a polyprotein whose N terminus began with NS3, but cleavage at the 4B-5 site could be restored by supplying the the NS2B protein in trans. Several experimental results suggested that trans cleavage at the 4B-5 site requires association of NS2B and the NS3 proteinase domain. Coexpression of different proteinases and catalytically inactive polyprotein substrates revealed that trans cleavage at the 2B-3 and 4B-5 sites was relatively efficient when compared with trans cleavage at the 2A-2B and 3-4A sites.     

Isolation of enzymatically active replication complexes from feline calicivirus-infected cells

A membranous fraction that could synthesize viral RNA in vitro in the presence of magnesium salt, ribonucleotides, and an ATP-regenerating system was isolated from feline calicivirus (FCV)-infected cells. The enzymatically active component of this fraction was designated FCV replication complexes (RCs), by analogy to other positive-strand RNA viruses. The newly synthesized RNA was characterized by Northern blot analysis, which demonstrated the production of both full-length (8.0-kb) and subgenomic-length (2.5-kb) RNA molecules similar to those synthesized in FCV-infected cells. The identity of the viral proteins associated with the fraction was investigated. The 60-kDa VP1 major capsid protein was the most abundant viral protein detected. VP2, a minor structural protein encoded by open reading frame 3 (ORF3), was also present. Nonstructural proteins associated with the fraction included the precursor polypeptides Pro-Pol (76 kDa) and p30-VPg (43 kDa), as well as the mature nonstructural proteins p32 (derived from the N-terminal region of the ORF1 polyprotein), p30 (the putative "3A-like" protein), and p39 (the putative nucleoside triphosphatase). The isolation of enzymatically active RCs containing both viral and cellular proteins should facilitate efforts to dissect the contributions of the virus and the host to FCV RNA replication.     

Mutational analysis of tobacco etch virus polyprotein processing: cis and trans proteolytic activities of polyproteins containing the 49-kilodalton proteinase.

The genome of tobacco etch virus contains a single open reading frame with the potential to encode a 346-kilodalton (kDa) polyprotein. The large polyprotein is cleaved at several positions by a tobacco etch virus genome-encoded, 49-kDa proteinase. The locations of the 49-kDa proteinase-mediated cleavage sites flanking the 71-kDa cytoplasmic pinwheel inclusion protein, 6-kDa protein, 49-kDa proteinase, and 58-kDa putative polymerase have been determined by using cell-free expression, proteolytic processing, and site-directed mutagenesis systems. Each of these sites is characterized by the conserved sequence motif Glu-Xaa-Xaa-Tyr-Xaa-Gln-Ser or Gly (in which cleavage occurs after the Gln residue). The amino acid residue (Gln) predicted to occupy the -1 position relative to the scissile bond has been substituted, by mutagenesis of cloned cDNA, at each of four cleavage sites. The altered sites were not cleaved by the 49-kDa proteinase. A series of synthetic polyproteins that contained the 49-kDa proteinase linked to adjoining proteins via defective cleavage sites were expressed, and their proteolytic activities were analyzed. As part of a polyprotein, the proteinase was found to exhibit cis (intramolecular) and trans (intermolecular) activity.     

Kinetic and structural analyses of hepatitis C virus polyprotein processing.

Recombinant vaccinia viruses were used to study the processing of hepatitis C virus (HCV) nonstructural polyprotein precursor. HCV-specific proteins and cleavage products were identified by size and by immunoprecipitation with region-specific antisera. A polyprotein beginning with 20 amino acids derived from the carboxy terminus of NS2 and ending with the NS5B stop codon (amino acids 1007 to 3011) was cleaved at the NS3/4A, NS4A/4B, NS4B/5A, and NS5A/5B sites, whereas a polyprotein in which the putative active site serine residue was replaced by an alanine remained unprocessed, demonstrating that the NS3-encoded serine-type proteinase is essential for cleavage at these sites. Processing of the NS3'-5B polyprotein was complex and occurred rapidly. Discrete polypeptide species corresponding to various processing intermediates were detected. With the exception of NS4AB-5A/NS5A, no clear precursor-product relationships were detected. Using double infection of cells with vaccinia virus recombinants expressing either a proteolytically inactive NS3'-5B polyprotein or an active NS3 proteinase, we found that cleavage at the NS4A/4B, NS4B/5A, and NS5A/5B sites could be mediated in trans. Absence of trans cleavage at the NS3/4A junction together with the finding that processing at this site was insensitive to dilution of the enzyme suggested that cleavage at this site is an intramolecular reaction. The trans-cleavage assay was also used to show that (i) the first 211 amino acids of NS3 were sufficient for processing at all trans sites and (ii) small deletions from the amino terminus of NS3 selectively affected cleavage at the NS4B/5A site, whereas more extensive deletions also decreased processing efficiencies at the other sites. Using a series of amino-terminally truncated substrate polyproteins in the trans-cleavage assay, we found that NS4A is essential for cleavage at the NS4B/5A site and that processing at this site could be restored by NS4A provided in cis (i.e., together with the substrate) or in trans (i.e., together with the proteinase). These results suggest that in addition to the NS3 proteinase, NS4A sequences play an important role in HCV polyprotein processing.     

Complex formation between the NS3 serine-type proteinase of the hepatitis C virus and NS4A and its importance for polyprotein maturation.

Processing of the hepatitis C virus polyprotein is mediated by host cell signalases and at least two virally encoded proteinases. Of these, the serine-type proteinase encompassing the amino-terminal one-third of NS3 is responsible for cleavage at the four sites carboxy terminal of NS3. The activity of this proteinase is modulated by NS4A, a 54-amino-acid polyprotein cleavage product essential for processing at the NS3/4A, NS4A/4B, and NS4B/5A sites and enhancing cleavage efficiency between NS5A and NS5B. Using the vaccinia virus-T7 hybrid system to express hepatitis C virus polypeptides in BHK-21 cells, we studied the role of NS4A in proteinase activation. We found that the NS3 proteinase and NS4A form a stable complex when expressed as a single polyprotein or as separate molecules. Results from deletion mapping show that the minimal NS4A domain required for proteinase activation is located in the center of NS4A between amino acids 1675 and 1686 of the polyprotein. Amino acid substitutions within this domain destabilizing the NS3-NS4A complex also impair trans cleavage at the NS4A-dependent sites. Similarly, deletion of amino-terminal NS3 sequences impairs complex formation as well as cleavage at the NS4B/5A site but not at the NS4A-independent NS5A/5B site. These results suggest that a stable NS3-NS4A interaction is important for cleavage at the NS4A-dependent sites and that amino-terminal NS3 sequences and the central NS4A domain are directly involved in complex formation.     

Variability at human immunodeficiency virus type 1 subtype C protease cleavage sites: an indication of viral fitness?

Naturally occurring polymorphisms in the protease of human immunodeficiency virus type 1 (HIV-1) subtype C would be expected to lead to adaptive (compensatory) changes in protease cleavage sites. To test this hypothesis, we examined the prevalences and patterns of cleavage site polymorphisms in the Gag, Gag-Pol, and Nef cleavage sites of C compared to those in non-C subtypes. Codon-based maximum-likelihood methods were used to assess the natural selection and evolutionary history of individual cleavage sites. Seven cleavage sites (p17/p24, p24/p2, NC/p1, NC/TFP, PR/RT, RT/p66, and p66/IN) were well conserved over time and in all HIV-1 subtypes. One site (p1/p6(gag)) exhibited moderate variation, and four sites (p2/NC, TFP/p6(pol), p6(pol)/PR, and Nef) were highly variable, both within and between subtypes. Three of the variable sites are known to be major determinants of polyprotein processing and virion production. P2/NC controls the rate and order of cleavage, p6(gag) is an important phosphoprotein required for virion release, and TFP/p6(pol), a novel cleavage site in the transframe domain, influences the specificity of Gag-Pol processing and the activation of protease. Overall, 58.3% of the 12 HIV-1 cleavage sites were significantly more diverse in C than in B viruses. When analyzed as a single concatenated fragment of 360 bp, 96.0% of group M cleavage site sequences fell into subtype-specific phylogenetic clusters, suggesting that they coevolved with the virus. Natural variation at C cleavage sites may play an important role, not only in regulation of the viral cycle but also in disease progression and response to therapy.     

Comparative site-directed mutagenesis in the catalytic amino acid triad in calicivirus proteases

Calicivirus proteases cleave the viral precursor polyprotein encoded by open reading frame 1 (ORF1) into multiple intermediate and mature proteins. These proteases have conserved histidine (His), glutamic acid (Glu) or aspartic acid (Asp), and cysteine (Cys) residues that are thought to act as a catalytic triad (i.e. general base, acid and nucleophile, respectively). However, is the triad critical for processing the polyprotein? In the present study, we examined these amino acids in viruses representing the four major genera of Caliciviridae: Norwalk virus (NoV), Rabbit hemorrhagic disease virus (RHDV), Sapporo virus (SaV) and Feline calicivirus (FCV). Using single amino‐acid substitutions, we found that an acidic amino acid (Glu or Asp), as well as the His and Cys in the putative catalytic triad, cannot be replaced by Ala for normal processing activity of the ORF1 polyprotein in vitro. Similarly, normal activity is not retained if the nucleophile Cys is replaced with Ser. These results showed the calicivirus protease is a Cys protease and the catalytic triad formation is important for protease activity. Our study is the first to directly compare the proteases of the four representative calicivirus genera. Interestingly, we found that RHDV and SaV proteases critically need the acidic residues during catalysis, whereas proteolytic cleavage occurs normally at several cleavage sites in the ORF1 polyprotein without a functional acid residue in the NoV and FCV proteases. Thus, the substrate recognition mechanism may be different between the SaV and RHDV proteases and the NoV and FCV proteases.     

Maturation of the Hepatitis A Virus Capsid Protein VP1 Is Not Dependent on Processing by the 3Cpro Proteinase

Most details of the processing of the hepatitis A virus (HAV) polyprotein are known. Unique among members of the family Picornaviridae, the primary cleavage of the HAV polyprotein is mediated by 3Cpro, the only proteinase known to be encoded by the virus, at the 2A/2B junction. All other cleavages of the polyprotein have been considered to be due to 3Cpro, although the precise location and mechanism responsible for the VP1/2A cleavage have been controversial. Here we present data that argue strongly against the involvement of the HAV 3Cpro proteinase in the maturation of VP1 from its VP1-2A precursor. Using a heterologous expression system based on recombinant vaccinia viruses directing the expression of full-length or truncated capsid protein precursors, we show that the C terminus of the mature VP1 capsid protein is located near residue 764 of the polyprotein. However, a proteolytically active HAV 3Cpro that was capable of directing both VP0/VP3 and VP3/VP1 cleavages in vaccinia virus-infected cells failed to process the VP1-2A precursor. Using site-directed mutagenesis of an infectious molecular clone of HAV, we modified potential VP1/2A cleavage sites that fit known 3Cpro recognition criteria and found that a substitution that ablates the presumed 3Cpro dipeptide recognition sequence at Glu764-Ser765 abolished neither infectivity nor normal VP1 maturation. Altered electrophoretic mobility of VP1 from a viable mutant virus with an Arg764 substitution indicated that this residue is present in VP1 and that the VP1/2A cleavage occurs downstream of this residue. These data indicate that maturation of the HAV VP1 capsid protein is not dependent on 3Cpro processing and may thus be uniquely dependent on a cellular proteinase.     

Cleavage specificity of purified recombinant hepatitis A virus 3C proteinase on natural substrates.

Hepatitis A virus (HAV) 3C proteinase expressed in Escherichia coli was purified to homogeneity, and its cleavage specificity towards various parts of the viral polyprotein was analyzed. Intermolecular cleavage of the P2-P3 domain of the HAV polyprotein gave rise to proteins 2A, 2B, 2C, 3ABC, and 3D, suggesting that in addition to the primary cleavage site, all secondary sites within P2 as well as the 3C/3D junction are cleaved by 3C. 3C-mediated processing of the P1-P2 precursor liberated 2A and 2BC, in addition to the structural proteins VP0, VP3, and VP1-2A and the respective intermediate products. A clear dependence on proteinase concentration was found for most cleavage sites, possibly reflecting the cleavage site preference of 3C. The most efficient cleavage occurred at the 2A/2B and 2C/3A junctions. The electrophoretic mobility of processing product 2B, as well as cleavage of the synthetic peptide KGLFSQ*AKISLFYT, suggests that the 2A/2B junction is located at amino acid position 836/837 of the HAV polyprotein. Furthermore, using suitable substrates we obtained evidence that sites VP3/VP1 and VP1/2A are alternatively processed by 3C, leading to either VP1-2A or to P1 and 2A. The results with regard to intermolecular cleavage by purified 3C were confirmed by the product pattern derived from cell-free expression and intramolecular processing of the entire polyprotein. We therefore propose that polyprotein processing of HAV relies on 3C as the single proteinase, possibly assisted by as-yet-undetermined viral or host cell factors and presumably controlled in a concentration-dependent fashion.     

Regulation of hepatitis C virus polyprotein processing by signal peptidase involves structural determinants at the p7 sequence junctions

The hepatitis C virus genome encodes a polyprotein precursor that is co- and post-translationally processed by cellular and viral proteases to yield 10 mature protein products (C, E1, E2, p7, NS2, NS3, NS4A, NS4B, NS5A, and NS5B). Although most cleavages in hepatitis C virus polyprotein precursor proceed to completion during or immediately after translation, the cleavages mediated by a host cell signal peptidase are partial at the E2/p7 and p7/NS2 sites, leading to the production of an E2p7NS2 precursor. The sequences located immediately N-terminally of E2/p7 and p7/NS2 cleavage sites can function as signal peptides. When fused to a reporter protein, the signal peptides of p7 and NS2 were efficiently cleaved. However, when full-length p7 was fused to the reporter protein, partial cleavage was observed, indicating that a sequence located N-terminally of the signal peptide reduces the efficiency of p7/NS2 cleavage. Sequence analyses and mutagenesis studies have also identified structural determinants responsible for the partial cleavage at both the E2/p7 and p7/NS2 sites. Finally, the short distance between the cleavage site of E2/p7 or p7/NS2 and the predicted transmembrane alpha-helix within the P' region might impose additional structural constraints to the cleavage sites. The insertion of a linker polypeptide sequence between P-3' and P-4' of the cleavage site released these constraints and led to improved cleavage efficiency. Such constraints in the processing of a polyprotein precursor are likely essential for hepatitis C virus to post-translationally regulate the kinetics and/or the level of expression of p7 as well as NS2 and E2 mature proteins.     

Flavivirus enzyme-substrate interactions studied with chimeric proteinases: identification of an intragenic locus important for substrate recognition.

The proteins of flaviviruses are translated as a single long polyprotein which is co- and posttranslationally processed by both cellular and viral proteinases. We have studied the processing of flavivirus polyproteins in vitro by a viral proteinase located within protein NS3 that cleaves at least three sites within the nonstructural region of the polyprotein, acting primarily autocatalytically. Recombinant polyproteins in which part of the polyprotein is derived from yellow fever virus and part from dengue virus were used. We found that polyproteins containing the yellow fever virus cleavage sites were processed efficiently by the yellow fever virus enzyme, by the dengue virus enzyme, and by various chimeric enzymes. In contrast, dengue virus cleavage sites were cleaved inefficiently by the dengue virus enzyme and not at all by the yellow fever virus enzyme. Studies with chimeric proteinases and with site-directed mutants provided evidence for a direct interaction between the cleavage sites and the proposed substrate-binding pocket of the enzyme. We also found that the efficiency and order of processing could be altered by site-directed mutagenesis of the proposed substrate-binding pocket.     

Proteolytic processing of turnip yellow mosaic virus replication proteins and functional impact on infectivity

Turnip yellow mosaic virus (TYMV), a positive-strand RNA virus belonging to the alphavirus-like supergroup, encodes its nonstructural replication proteins as a 206K precursor with domains indicative of methyltransferase (MT), proteinase (PRO), NTPase/helicase (HEL), and polymerase (POL) activities. Subsequent processing of 206K generates a 66K protein encompassing the POL domain and uncharacterized 115K and 85K proteins. Here, we demonstrate that TYMV proteinase mediates an additional cleavage between the PRO and HEL domains of the polyprotein, generating the 115K protein and a 42K protein encompassing the HEL domain that can be detected in plant cells using a specific antiserum. Deletion and substitution mutagenesis experiments and sequence comparisons indicate that the scissile bond is located between residues Ser879 and Gln880. The 85K protein is generated by a host proteinase and is likely to result from nonspecific proteolytic degradation occurring during protein sample extraction or analysis. We also report that TYMV proteinase has the ability to process substrates in trans in vivo. Finally, we examined the processing of the 206K protein containing native, mutated, or shuffled cleavage sites and analyzed the effects of cleavage mutations on viral infectivity and RNA synthesis by performing reverse-genetics experiments. We present evidence that PRO/HEL cleavage is critical for productive virus infection and that the impaired infectivity of PRO/HEL cleavage mutants is due mainly to defective synthesis of positive-strand RNA.