Site-specific mutations at a picornavirus VP3/VP1 cleavage site disrupt in vitro processing and assembly of capsid precursors.

Most proteolytic cleavages within the picornavirus polyproteins are carried out by viral protease 3C. For encephalomyocarditis virus, the protease 3C-catalyzed processing occurs between Gln-Gly or Gln-Ser amino acid pairs which are flanked by proline residues, but the sequence-specific constraints on recognition and cleavage by the enzyme are not completely understood. To examine alternative cleavage site sequences, we constructed a cDNA plasmid which expresses the viral L-P1-2A capsid precursor in vitro and introduced site-specific mutations into the Gln-Gly pair at the VP3/VP1 junction. The altered protein substrates were tested for cleavage activity in assays with protease 3C. The encephalomyocarditis virus 3C processed Gln-Ala as efficiently as its natural sites but did not cleave Gln-Val, Gln-Glu, Lys-Gly, Lys-Ala, Lys-Val, Lys-Glu, or Pro-Gly combinations. Displacement of the flanking proline residue by an engineered insertion slowed but did not prevent cleavage at this site. Also, a mutant defective in processing at the VP3/VP1 junction was unable to form 14S pentameric assembly intermediates in vitro.     

Poliovirus capsid proteins derived from P1 precursors with glutamine-valine cleavage sites have defects in assembly and RNA encapsidation.

Assembly of poliovirus virions requires proteolytic cleavage of the P1 capsid precursor polyprotein between two separate glutamine-glycine (QG) amino acid pairs by the viral protease 3CD. In this study, we have investigated the effects on P1 polyprotein processing and subsequent assembly of processed capsid proteins caused by substitution of the glycine residue at the individual QG cleavage sites with valine (QG-->QV). P1 cDNAs encoding the valine substitutions were created by site-directed mutagenesis and were recombined into wild-type vaccinia virus to generate recombinant vaccinia viruses which expressed the mutant P1 precursors. The recombinant vaccinia virus-expressed mutant P1 polyproteins were analyzed for proteolytic processing defects in cells coinfected with a recombinant vaccinia virus (VVP3) that expresses the poliovirus 3CD protease and for processing and assembly defects by using a trans complementation system in which P1-expressing recombinant vaccinia viruses provide capsid precursor to a defective poliovirus genome that does not express functional capsid proteins (D. C. Ansardi, D. C. Porter, and C. D. Morrow, J. Virol. 67:3684-3690, 1993). The QV-substituted precursors were proteolytically processed at the altered sites both in cells coinfected with VVP3 and in cells coinfected with defective poliovirus, although the kinetics of cleavage at the altered sites were slower than those of cleavage at the wild-type QG site in the precursor. Completely processed capsid proteins VP0, VP3, and VP1 derived from the mutant precursor containing a valine at the amino terminus of VP3 (VP3-G001V) were unstable and failed to assemble stable subviral structures in cells coinfected with defective poliovirus. In contrast, capsid proteins derived from the P1 precursor with a valine substitution at the amino terminus of VP1 (VP1-G001V) assembled empty capsid particles but were deficient in assembling RNA-containing virions. The assembly characteristics of the VP1-G001V mutant were compared with those of a previously described VP3-VP1 cleavage site mutant (K. Kirkegaard and B. Nelsen, J. Virol. 64:185-194, 1990) which contained a deletion of the first four amino-terminal residues of VP1 (VP1-delta 1-4) and which was reconstructed for our studies into the recombinant vaccinia virus system. Complete proteolytic processing of the VP1-delta 1-4 precursor also occurred more slowly than complete cleavage of the wild-type precursor, and formation of virions was delayed; however, capsid proteins derived from the VP1-G001V mutant assembled RNA-containing virions less efficiently than those derived from the VP1-delta 1-4 precursor.(ABSTRACT TRUNCATED AT 400 WORDS)     

The nucleotide and deduced amino acid sequences of the encephalomyocarditis viral polyprotein coding region.

The nucleotide sequence of 7200 bases of encephalomyocarditis (EMC) viral RNA, including the complete polyprotein-coding region, was determined. The polyprotein is encoded within a unique translational reading frame, 6870 bases in length. Protein synthesis begins with the sequence Met-Ala-Thr, and ends with the sequence Leu-Phe-Trp, 126 bases from the 3' end of the RNA. Viral capsid and noncapsid proteins were aligned with the deduced amino acid sequence of the polyprotein. The proteolytic processing map follows the standard 4-3-4 picornaviral pattern except for a short leader peptide (8 kd), which precedes the capsid proteins. Identification of the proteolytic cleavage sites showed that EMC viral protease, p22, has cleavage specificity for gln-gly or gln-ser sequences with adjacent proline residues. The cleavage specificity of the host-coded protease(s) includes both tyr-pro and gln-gly sequences.     

Mutational analysis of the encephalomyocarditis virus primary cleavage.

Sixteen substitution mutations of the conserved DvExNPGP sequence, implicated in cardiovirus and aphthovirus primary polyprotein cleavage, were created in encephalomyocarditis virus cDNA, expressed, and characterized for processing activity. Nearly all the mutations severely decreased the efficiency of the primary cleavage reaction during cell-free synthesis of viral precursors, indicating a stringent requirement for the natural sequence in this processing event. When representative mutations were tested in full-length genomic contexts, they were lethal and no revertants were observed. Not only were the primary cleavage reactions deficient in these polyproteins, but subsequent cleavage of P1 by endogenous or exogenous 3C pro was also impaired. This indicates that primary cleavage has a role in the proper processing of the viral capsid precursor.     

Functional characterization of cleavage-defective mutants of encephalomyocarditis virus.

We characterized seven temperature-sensitive capsid cleavage (cleavage-defective) mutants of encephalomyocarditis virus. Our experimental approach was to monitor in vitro proteolysis reactions of either wild-type or cleavage-defective mutant capsid precursors mixed with cell-free translation products (containing the viral protease) of either wild-type or mutant viral RNA. The cell-free translation reactions and in vitro proteolysis reactions were done at 38 degrees C, because at this temperature cleavage of the capsid precursors was restricted in reactions containing cleavage-defective mutant viral RNA as the message, relative to those reactions containing wild-type viral RNA as the message. Wild-type or cleavage-defective mutant capsid precursors were prepared by adding cycloheximide to cell-free translation reactions primed with wild-type or mutant viral RNA, respectively, 12 min after the initiation of translation. In vitro proteolysis of wild-type capsid precursors with cell-free translation products of either wild-type or cleavage-defective mutant viral RNA led to similar products at 38 degrees C, indicating that the cleavage-defective mutant viral protease was not temperature sensitive. As a corollary to this, at 38 degrees C cleavage-defective mutant capsid precursors were not cleaved as completely as were wild-type capsid precursors by products of cell-free translation of wild-type viral RNA. The results from these in vitro proteolysis experiments indicate that all seven of the cleavage-defective mutants have capsid precursors with a temperature-sensitive configuration.     

Functional analysis of potential carboxy-terminal cleavage sites of tick-borne encephalitis virus capsid protein

The mature capsid protein C of flaviviruses is generated through the proteolytic cleavage of the precursor polyprotein by the viral NS2B/3 protease. This cleavage is a prerequisite for the subsequent processing of the viral surface protein prM, and the concerted progression of these events plays a key role in the process of the assembly of infectious virions. Protein C of tick-borne encephalitis virus (TBEV) contains two amino acid sequence motifs within the carboxy-terminal region that match the canonical NS2B/3 recognition site. Site-specific mutagenesis in the context of the full-length TBEV genome was used to investigate the in vivo cleavage specificity of the viral protease in this functionally important domain. The results indicate that the downstream site is necessary and sufficient for efficient cleavage and virion assembly; in contrast, the upstream site is dispensable and placed in a structural context that renders it largely inaccessible to the viral protease. Mutants with impaired C-prM cleavage generally exhibited a significantly increased cytotoxicity. In spite of the clear preference of the protease for only one of the two naturally occurring motifs, the enzyme was unexpectedly tolerant to both the presence of a noncanonical threonine residue at position P2 and the position of cleavage relative to the adjacent internal prM signal sequence. The insertion of three amino acid residues downstream of the cleavage site did not change the viral phenotype. Thus, this study further illuminates the specificity of the TBEV protease and reveals that the carboxy-terminal region of protein C has a remarkable functional flexibility in its role in the assembly of infectious virions.     

Functional characterization of the cleavage specificity of the sapovirus chymotrypsin-like protease

Sapovirus is a positive-stranded RNA virus with a translational strategy based on processing of a polyprotein precursor by a chymotrypsin-like protease. So far, the molecular mechanisms regulating cleavage specificity of the viral protease are poorly understood. In this study, the catalytic activities and substrate specificities of the predicted forms of the viral protease, the 3C-like protease (NS6) and the 3CD-like protease-polymerase (NS6-7), were examined in vitro. The purified NS6 and NS6-7 were able to cleave synthetic peptides (15 to 17 residues) displaying the cleavage sites of the sapovirus polyprotein, both NS6 and NS6-7 proteins being active forms of the viral protease. High-performance liquid chromatography and subsequent mass spectrometry analysis of digested products showed a specific trans cleavage of peptides bearing Gln-Gly, Gln-Ala, Glu-Gly, Glu-Pro, or Glu-Lys at the scissile bond. In contrast, peptides bearing Glu-Ala or Gln-Asp at the scissile bond (NS4-NS5 and NS5-NS6, or NS6-NS7 junctions, respectively) were resistant to trans cleavage by NS6 or NS6-7 proteins, whereas cis cleavage of the Glu-Ala scissile bond of the NS5-NS6 junction was evidenced. Interestingly, the presence of a Phe at position P4 overruled the resistance to trans cleavage of the Glu-Ala junction (NS5-NS6), whereas substitutions at the P1 and P2′ positions altered the cleavage efficiency. The differential cleavage observed is supported by a model of the substrate-binding site of the sapovirus protease, indicating that the P4, P1, and P2′ positions in the substrate modulate the cleavage specificity and efficiency of the sapovirus chymotrypsin-like protease.     

Processing of the intracellular form of the west Nile virus capsid protein by the viral NS2B-NS3 protease: an in vitro study.

According to the existing model of flavivirus polyprotein processing, one of the cleavages in the amino-terminal part of the flavivirus polyprotein by host cell signalases results in formation of prM (precursor to one of the structural proteins, M) and the membrane-bound intracellular form of the viral capsid protein (Cint) retaining the prM signal sequence at its carboxy terminus. This hydrophobic anchor is subsequently removed by the viral protease, resulting in formation of the mature viral capsid protein found in virions (Cvir). We have prepared in vitro expression cassettes coding for both forms of the capsid protein, for the prM protein, for the C-prM precursor, and for the viral protease components of West Nile flavivirus and characterized their translation products. Using Cint and Cvir translation products as molecular markers, we have observed processing of the intracellular form of the West Nile capsid protein by the viral protease in vitro both upon cotranslation of the C-prM precursor and the viral protease-encoding cassette and by incubation of C-prM translation products with a detergent-solubilized extract of cells infected with a recombinant vaccinia virus expressing the active viral protease. The cleavage of Cint by the viral protease at the predicted dibasic site was verified by introduction of point mutations into the cleavage site and an adjacent region. These studies provide the first direct demonstration of processing of the intracellular form of the flavivirus capsid protein by the viral protease.     

Rapid method for the preparation of encephalomyocarditis virus protease from rabbit reticulocyte lysates.

Fractionation of the reticulocyte lysate translation products of encephalomyocarditis virus RNA by ultracentrifugation showed that the viral proteins were distributed differentially in the supernatant and the ribosomal pellet fractions. The viral noncapsid proteins C and D, which contain the viral protease sequence, sedimented preferentially with the pellet fraction. Incubation of the resuspended pellet and subsequent centrifugation of the suspension resulted in cleavage of the protease from proteins C and D and separation of the enzyme from reticulocyte particulate proteins. Preparations thus obtained contained only three encephalomyocarditis virus proteins and were almost devoid of reticulocyte proteins.     

Stimulation of encephalomyocarditis virus RNA translation in wheat embryo extracts by rabbit reticulocyte ribosomal wash.

Encephalomyocarditis virus RNA induced a low level of amino acid incorporation in wheat embryo extracts, but the incorporation did not result in the formation of any viral proteins. However, if wheat embryo extracts were supplemented with a ribosomal wash fraction from rabbit reticulocytes, a large stimulation of amino acid incorporation and the formation of encephalomyocarditis virus-specific proteins were obtained. Among the proteins synthesized were capsid precursor proteins which can be processed by an encephalomyocarditis virus-coded protease to produce the viral capsid proteins.     

Poliovirus proteinase 3C: large-scale expression, purification, and specific cleavage activity on natural and synthetic substrates in vitro.

Proteinase 3C of poliovirus type 2 (Sabin) was expressed at 4% total protein in Escherichia coli. The protein was soluble and could be purified by a simple scheme. It was weakly active on the capsid precursor P1 (expressed in vitro), which contains two cleavage sites. The products of processing P1 were 1ABC and 1D (VP1). The activity was insensitive to Triton X-100. Crude extracts of cells infected with poliovirus type 1 (Mahoney) gave strong processing and yielded 1AB (VP0), 1C (VP3), and 1D in the same assay system but were sensitive to detergent. 3C from cell extracts that was separated from its precursors resembled the recombinant proteinase in its activity. Recombinant 3C cleaved the peptide dansyl-Glu-Glu-Glu-Ala-Met-Glu-Gln-Gly-Ile-Thr-Asn-Lys-NH2 at the Gln-Gly bond. We conclude that 3C is merely the core of the Gln-Gly-cleaving activity which processes P1 in vivo and that there is probably a hydrophobic contact between a larger 3C precursor and its P1 substrate which allows the second processing reaction: 1ABC, 1D----1AB, 1C, 1D.     

Human immunodeficiency virus type 1 gag-protease fusion proteins are enzymatically active.

We have introduced mutations into the region of the genome of human immunodeficiency virus type 1 (HIV-1) that encodes the cleavage sites between the viral protease (PR) and the adjacent upstream region of the polyprotein precursor. Segments containing these mutations were introduced into plasmids, and the retroviral proteins were expressed in Escherichia coli. The mutations prevented cleavage between the PR and the adjacent polypeptide; however, other PR cleavage sites in the polyprotein were cleaved normally, showing that the release of free PR is not a prerequisite for the appropriate processing of HIV-1 precursors.     

Formation of the flavivirus envelope: role of the viral NS2B-NS3 protease.

One of the late processing events in the flavivirus replication cycle involves cleavage of the intracellular form of the flavivirus capsid protein (Cint) to the mature virion form (Cvir) lacking the carboxy-terminal stretch of hydrophobic amino acids which serves as a signal peptide for the downstream prM protein. This cleavage event was hypothesized to be effected by a viral protease and to be associated with virion formation. We have proposed a model of flavivirus virion formation in which processing of the C-prM precursor at the upstream signalase site is upregulated by interaction of the NS2B part of the protease with the prM signal peptide or with an adjacent carboxy-terminal region of the capsid protein in the precursor, and processing of Cint by the NS2B-NS3 protease follows the signalase cleavage. Recently, an alternative hypothesis was proposed which suggests a reverse order of these two cleavage events, namely, that cleavage of the C-prM precursor by the NS2B-NS3 protease at the Cint-->Cvir dibasic cleavage site is a prerequisite for the subsequent signalase cleavage of the prM signal peptide. To distinguish between these alternative models, we prepared a series of expression cassettes carrying mutations at the Cint-->Cvir dibasic cleavage site and investigated the effects of these mutations on signalase processing of C-prM and on formation and secretion of prM-E heterodimers. For certain mutated C-prM precursors, namely, for those with Lys-->Gly disruption of the dibasic site, efficient formation of prM was observed upon expression from larger cassettes encoding the viral protease, despite the absence of processing at the Cint-->Cvir cleavage site. Surprisingly, formation and secretion of prM-E heterodimers accompanied by late cleavage of prM was also observed for these cassettes, with an efficiency comparable to that of the wild-type expression cassette. These observations contradict the model in which cleavage of the C-prM precursor at the Cint-->Cvir dibasic site is a prerequisite for signalase cleavage.     

Cleavage site mutations in the encephalomyocarditis virus P3 region lethally abrogate the normal processing cascade.

Site-specific mutations within the proteinase 3C-dependent P3 region cleavage sequences of encephalomyocarditis virus have been constructed. The mutations altered the normal QG cleavage site dipeptide pairs of the 2C/3A, 3A/3B, 3B/3C, and 3C/3D junctions into QV, QC, QF, QY, and RG sequences. When translated in vitro in the context of full-length viral polyproteins, all mutations blocked endogenous 3C-mediated processing at their engineered sites and produced stable forms of the expected viral P3 precursors that were also resistant to cleavage by exogenously added recombinant 3C. Relative to wild-type viral sequences, each mutant form of P3 had a somewhat different ability to mediate overall polyprotein processing. Mutations at the 2C/3A, 3A/3B, and 3B/3C sites, for example, were generally less impaired than 3C/3D mutations, when the cleavage reactions were quantitated with cotranslated L-P1-2A precursors. A notable exception was mutant 3B3C(QG-->RG), which proved far less active than sibling mutants 3B3C(QG-->QF) and 3B3C(QG-->QV), a finding that possibly implicates this segment in the proper folding of an active 3C. When transfected into HeLa cells, all mutant sequences were lethal, presumably because of the reduced L-P1-2A processing levels or reduced RNA synthesis capacity. However, when specifically tested for the latter activity, all mutations except those at the 3C/3D cleavage site were indeed able to initiate and perpetuate viral RNA replication in transfected cells, albeit to RNA accumulation levels lower than those produced by wild-type sequences. The transfection effects could be mimicked with cell-free synthesized proteins, in that translation samples containing locked 3CD polymerase precursors were catalytically inactive in poly(A)-oligo(U)-dependent assays, while all other mutant processing samples initiated detectable RNA synthesis. Surprisingly, not only did the 3B/3C mutant sequences prove capable of directing RNA synthesis, but the viral RNA thus synthesized could be immunolabeled and precipitated with 3C-specific monoclonal antibody reagents, indicating an unexpected covalent attachment of the proteinase to the RNA product whenever this cleavage site was blocked.     

Analysis of retroviral protease cleavage sites reveals two types of cleavage sites and the structural requirements of the P1 amino acid

Retroviruses encode a protease which cleaves the viral Gag and Gag/Pol protein precursors into mature products. To understand the target sequence specificity of the viral protease, the amino acid sequences from 46 known processing sites from 10 diverse retroviruses were compared. Sequence preference was evident in positions P4 through P3' when compared to flanking sequences. Approximately 80% of all cleavage site sequences could be grouped into two classes based on the sequence composition flanking the scissile bond. The sequences at the amino-terminal cleavage site of the major capsid protein of Gag is always a member of one of the two classes while the carboxyl-terminal cleavage site is of the other class, suggesting a biological role for the two classes. Known processing site sequences proved useful in a motif searching strategy to identify processing sites in retroviral protein sequences, particularly in Gag. In all known cleavage sites, the P1 amino acid is hydrophobic and unbranched at the beta-carbon. The sequence requirements of the P1 position were tested by site-directed mutagenesis of the P1 Phe codon in an HIV-1 Pol cleavage site. Mutations were tested for protease-mediated cleavage of the Pol precursor expressed in Escherichia coli.     

Analysis of deletion mutants indicates that the 2A polypeptide of hepatitis A virus participates in virion morphogenesis

Unlike all other picornaviruses, the primary cleavage of the hepatitis A virus (HAV) polyprotein occurs at the 2A/2B junction and is carried out by the only proteinase encoded by the virus, 3C(pro). The resulting P1-2A capsid protein precursor is subsequently cleaved by 3C(pro) to generate VP0, VP3, and VP1-2A, which associate as pentamers. An unidentified cellular proteinase acting at the VP1/2A junction releases the mature capsid protein VP1 from VP1-2A later in the morphogenesis process. Although these aspects of polyprotein processing are well characterized, the function of 2A is unknown. To study its role in the viral life cycle, we assessed the infectivity of synthetic, genome-length RNAs containing 11 different in-frame deletions in the 2A region. Deletions in the N-terminal 40% of 2A abolished infectivity, whereas deletions in the C-terminal 60% resulted in viruses with a small-focus replication phenotype. C-terminal deletions in 2A had no effect on RNA replication kinetics under one-step growth conditions, nor did they have an effect on capsid protein synthesis and 3C(pro)-mediated processing. However, C-terminal deletions in 2A altered the VP1/2A cleavage, resulting in accumulation of uncleaved VP1-2A precursor in virions and possibly accounting for a delay in the appearance of infectious particles with these mutants, as well as a fourfold decrease in specific infectivity of the virus particles. When the capsid proteins were expressed from recombinant vaccinia viruses, the N-terminal part of 2A was required for efficient cleavage of the P1-2A precursor by 3C(pro) and assembly of structural precursors into pentamers. These data indicate that the N-terminal domain of 2A must be present as a C-terminal extension of P1 for folding of the capsid protein precursor to allow efficient 3C(pro)-mediated cleavages and to promote pentamer assembly, after which cleavage at the VP1/2A junction releases the mature VP1 protein, a process that appears to be necessary to produce highly infectious particles.     

Cleavage of synthetic peptides by purified poliovirus 3C proteinase

Synthetic peptides, 14-16 residues in length, were used as substrates for purified recombinant poliovirus proteinase 3C. The sequences of the substrates correspond to the sequences of authentic cleavage sites in the poliovirus polyprotein, all of which contain Gln-Gly at the scissile bond. Specificity of cleavages was demonstrated by analysis of 3C digests of synthetic peptides. Relative rate constants for the cleavages were derived by competition experiments. The rate constants roughly correlated with the estimated half-life of the homologous precursor proteins detected in poliovirus-infected cells. The peptide most resistant to cleavage corresponded to the 3C/3D junction, a site known to be cleaved very slowly by 3C in vivo. Substitution of threonine for alanine in P4 position of this peptide, however, resulted in significant cleavage. This observation supports the hypothesis that the residue in P4 position, in addition to the Gln-Gly in P1 and P1', respectively, contributes to substrate recognition. Ac-Gln-Gly-NH2 was not a substrate for 3C.     

Amino acid substitutions in the poliovirus maturation cleavage site affect assembly and result in accumulation of provirions.

The assembly of infectious poliovirus virions requires a proteolytic cleavage between an asparagine-serine amino acid pair (the maturation cleavage site) in VP0 after encapsidation of the genomic RNA. In this study, we have investigated the effects that mutations in the maturation cleavage site have on P1 polyprotein processing, assembly of subviral intermediates, and encapsidation of the viral genomic RNA. We have made mutations in the maturation cleavage site which change the asparagine-serine amino acid pair to either glutamine-glycine or threonine-serine. The mutations were created by site-directed mutagenesis of P1 cDNAs which were recombined into wild-type vaccinia virus to generate recombinant vaccinia viruses. The P1 polyproteins expressed from the recombinant vaccinia viruses were analyzed for proteolytic processing and assembly defects in cells coinfected with a recombinant vaccinia virus (VV-P3) that expresses the poliovirus 3CD protease. A trans complementation system using a defective poliovirus genome was utilized to assess the capacity of the mutant P1 proteins to encapsidate genomic RNA (D. C. Ansardi, D. C. Porter, and C. D. Morrow, J. Virol. 67:3684-3690, 1993). The mutant P1 proteins containing the glutamine-glycine amino acid pair (VP4-QG) and the threonine-serine pair (VP4-TS) were processed by 3CD provided in trans from VV-P3. The processed capsid proteins VP0, VP3, and VP1 derived from the mutant precursor VP4-QG were unstable and failed to assemble into subviral structures in cells coinfected with VV-P3. However, the capsid proteins derived from VP4-QG did assemble into empty-capsid-like structures in the presence of the defective poliovirus genome. In contrast, the capsid proteins derived from processing of the VP4-TS mutant assembled into subviral intermediates both in the presence and in the absence of the defective genome RNA. By a sedimentation analysis, we determined that the capsid proteins derived from the VP4-TS precursor encapsidated the defective genome RNA. However, the cleavage of VP0 to VP4 and VP2 was delayed, resulting in the accumulation of provirions. The maturation cleavage of the VP0 protein containing the VP4-TS mutation was accelerated by incubation of the provirions at 37 degrees C. The results of these studies demonstrate that mutations in the maturation cleavage site have profound effects on the subsequent capability of the capsid proteins to assemble and provide evidence for the existence of the provirion as an assembly intermediate.