A second virus-encoded proteinase involved in proteolytic processing of poliovirus polyprotein

Viral cysteine proteases are homologous to the trypsin-like family of serine proteases: structural and functional implications

Proteases that are encoded by animal picornaviruses and plant como- and potyviruses form a related group of cysteine-active-center enzymes that are essential for virus maturation. We show that these proteins are homologous to the family of trypsin-like serine proteases. In our model, the active-site nucleophile of the trypsin catalytic triad, Ser-195, is changed to a Cys residue in these viral proteases. The other two residues of the triad, His-57 and Asp-102, are otherwise absolutely conserved in all the viral protease sequences. Secondary structure analysis of aligned sequences suggests the location of the component strands of the twin beta-barrel trypsin fold in the viral proteases. Unexpectedly, the 2a and 3c subclasses of viral cysteine proteases are, respectively, homologous to the small and large structural subclasses of trypsin-like serine proteases. This classification allows the molecular mapping of residues from viral sequences onto related tertiary structures; we precisely identify amino acids that are strong determinants of specificity for both small and large viral cysteine proteases.

Proteolytic processing of poliovirus polyprotein: elimination of 2Apro-mediated, alternative cleavage of polypeptide 3CD by in vitro mutagenesis

The polypeptide 3CD of many poliovirus strains can be cleaved at two different amino acid pairs. The viral proteinase 3C and the viral polymerase 3D result from cleavage at a Gln-Gly pair by proteinase 3C, whereas cleavage at a Tyr-Gly pair by proteinase 2A yields the alternative products 3C' and 3D'. Specific mutations were introduced into the 3C'/3D' cleavage site in an infectious cDNA clone of poliovirus type 1 (Mahoney) by oligonucleotide-directed mutagenesis in order to investigate the role of 3C' and 3D' in viral proliferation and to obtain information about the cleavage specificity of 2Apro. Substitution of a threonine residue by an alanine residue at position -2 (P2) of this cleavage site abolished cleavage, whereas substitution of a tyrosine residue by a phenylalanine residue at amino acid position -1 (P1) of the cleavage site did not influence processing. Both mutated cDNA clones produced infectious viruses (T147A and Y148F) on transfection. The phenotypes of the mutant viruses were similar to that of the parental strain. We conclude that (i) 3C' and 3D' are not essential for virus replication, (ii) a Phe-Gly pair at the cleavage site can be cleaved by 2Apro, and (iii) a threonine residue in the P2 position of the cleavage site may be important in substrate recognition by 2Apro.

Expression and processing of human rhinovirus type 14 polypeptide precursors in Escherichia coli maxicells

Human rhinovirus serotype-14 (HRV-14) cDNA, encompassing 87.9% of the coding region, was subcloned in an Escherichia coli expression vector, generating plasmid pKCC101. HRV-14 polypeptides encoded by pKCC101 were synthesized in E. coli maxicells. Pulse-chase experiments with pKCC110, a smaller derivative of pKCC101 containing the protease 3C coding region, have clearly demonstrated the proteolysis of a 55-kDa precursor to several polypeptides, including a doublet with the expected size of protease 3C (20 kDa). The proteolysis of the 55-kDa precursor polypeptide was prevented by ZnCl2, a known inhibitor of picornavirus 3C proteases. Results with a derivative of pKCC110 (pKCC115) which is partially deleted for the protease 3C sequence, support the idea that the doublet proteins are specified by the protease 3C coding region. Taken together, our investigations indicate that the precursor form of protease 3C must be responsible for its own cleavage.

Protein 3CD is the major poliovirus proteinase responsible for cleavage of the P1 capsid precursor

The rate and extent of polyprotein processing are the major steps controlling picornavirus gene expression. It is, therefore, important to determine the enzymes responsible for each proteolytic event. The poliovirus protein 3C has been identified as a proteinase which specifically cleaves between Q-G pairs. However, recent data have suggested that 3C precursor polypeptides containing 3C sequences may also have proteolytic capabilities. In this study we have analyzed the cleavage specificities of protein 3C and its precursor, 3CD. We have carried out in vitro translation of genetically altered poliovirus mRNAs to demonstrate that 3CD is required for efficient processing of the P1 capsid precursor to capsid proteins. In addition, we suggest 3CD and 3C process Q-G pairs in the P2 and P3 precursors with similar efficiencies.

Sobemovirus genome appears to encode a serine protease related to cysteine proteases of picornaviruses

A putative serine protease was identified among non-structural proteins of southern bean mosaic virus (SBMV) by sequence comparison with cellular and viral proteases. The predicted SBMV protease displayed a significant similarity to cysteine proteases of picornaviruses, providing a possible evolutionary link between the two enzyme classes. It is suggested that SBMV follows the general expression strategy characteristic of other positive-strand RNA viruses containing 5'-terminal covalently linked proteins (VPg), i.e. generation of functional proteins by polyprotein processing.

Human rhinovirus 3C protease: cloning and expression of an active form in Escherichia coli

A cDNA encoding the viral protease from the 3C region of human rhinovirus type 14 was expressed in Escherichia coli through the use of a periplasmic secretion vector. The recombinant protease contained an eight amino acid N-terminal extension that enabled its detection by a specific antibody. It was expressed at a level of approximately 1 mg/L of E. coli culture. Biological activity of the protease was assessed in vitro by using a chemically synthesized peptide consisting of a consensus picornavirus protease cleavage site, Arg-Ala-Glu-Leu-Gln-Gly-Pro-Tyr-Asp-Glu. The peptide was cleaved by the recombinant protease at the Gln-Gly bond, generating the product peptides Arg-Ala-Glu-Leu-Gln and Gly-Pro-Tyr-Asp-Glu, which could be separated from the substrate peptide by reversed-phase HPLC. An in vitro assay for the rhinovirus 3C protease was developed by observing the rate of disappearance of the substrate peak from chromatograms of the supernatants of digestion mixtures.

The molecular evolution of genes and proteins: a tale of two serines

The advent of techniques for cloning and rapidly sequencing DNA has produced an explosive increase of sequence information for nucleic acids and their inferred proteins. Careful study of this large store of data might give us new insights into the relations between the linear sequences of genes and their functions embodied in the three-dimensional structure of proteins, and also illuminate the origin and evolution of the structural complexity of present-day proteins. Here I argue from such a study that the active site sequences of enzymes that have analogous essential serine residues lie in fact on two lines of descent from an ancient ancestral enzyme which had a cysteine instead of serine in its active site. This is based on the assumption that the two codon types which define the separate lines of descent and which have different bases in two positions could not interconvert by single mutations.

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.

Purification and partial characterization of poliovirus protease 2A by means of a functional assay

The purification of poliovirus protease 2A from infected cells by a functional assay is described. A small synthetic peptide was cleaved specifically by an esterase present in poliovirus-infected cells. Since the enzyme proved extremely unstable in crude extracts a rapid and efficient purification procedure had to be developed. By treatment with different detergents followed by high-speed centrifugation, the esterase activity was separated from inactivating cellular enzymes and was solubilized. Purification to more than 90% homogeneity could be achieved by a single chromatography step, namely, by gel filtration through Superose 12 under fast-protein liquid chromatography conditions. The esterase activity was associated with a protein of 17,000 daltons and copurified with poliovirus protein 2A. Furthermore, antibodies to 2A specifically precipitated the esterase activity. Thus, the esterase was identified as poliovirus protease 2A. Inhibition studies with known protease inhibitors revealed that 2A is probably a sulfhydryl protease. Of the metal ions tested, only zinc exerted significant inhibitory effects. The esterase activity was optimal near neutral pH and had an extremely short half-life at physiological temperatures.

A poliovirus mutant defective for self-cleavage at the COOH-terminus of the 3C protease exhibits secondary processing defects

By in vitro recombination between the wild-type full-length infectious cDNA of poliovirus and a clone generated by the construction of a cDNA bank from a chemically derived temperature-sensitive plurimutant, we obtained a mutant cDNA with a T to C change at nucleotide 5658. This mutation replaces the isoleucine at residue 74 of the viral protease 3C by a threonine. The mutant virus recovered after transfection exhibited a small-plaque phenotype, and was deficient for viral RNA synthesis. Both these defects were more marked at 39 than at 37 degrees. The mutation was introduced into a bacterial plasmid which expresses the 3C protease along with its flanking autocatalytic cleavage sites. Analysis of the cleavage products expressed in Escherichia coli provided direct evidence that the modification impaired cleavage at the COOH-terminus of 3C. Cleavage at this same site was partially defective in mutant virus-infected HeLa cells, reducing the production of mature 3C and the viral replicase, 3D. Cleavage of P1, the precursor to the capsid polypeptides, was apparently unaffected by this defect, whereas cleavage events within the P2 region of the genome occurred inefficiently. This is indicative of differential strategies for 3C-specific cleavage events in vivo.

Distinct binding sites for zinc and double-stranded RNA in the reovirus outer capsid protein sigma 3

By atomic absorption analysis, we determined that the reovirus outer capsid protein sigma 3, which binds double-stranded RNA (dsRNA), is a zinc metalloprotein. Using Northwestern blots and a novel zinc blotting technique, we localized the zinc- and dsRNA-binding activities of sigma 3 to distinct V8 protease-generated fragments. Zinc-binding activity was contained within an amino-terminal fragment that contained a transcription factor IIIA-like zinc-binding sequence, and dsRNA-binding activity was associated with a carboxy-terminal fragment. By these techniques, new zinc- and dsRNA-binding activities were also detected in reovirus core proteins. A sequence similarity was observed between the catalytic site of the picornavirus proteases and the transcription factor IIIA-like zinc-binding site within sigma 3. We suggest that the zinc- and dsRNA-binding activities of sigma 3 may be important for its proposed regulatory effects on viral and host cell transcription and translation.

An apparent deletion of an oligonucleotide detected by RNA fingerprint in the nondiabetogenic B variant of encephalomyocarditis virus is caused by a point mutation

The diabetogenic D variant of encephalomyocarditis virus (EMC-D) was previously shown to be different from the nondiabetogenic B variant of encephalomyocarditis virus (EMC-B) by a single spot in an oligonucleotide fingerprint after RNase T1 digestion of their genomic RNAs. An oligoribonucleotide was missing from EMC-B but was present in EMC-D. The oligoribonucleotide specific to EMC-D was isolated from a two-dimensional polyacrylamide gel and sequenced as 5'-ACAAUCUCACUUUUCCAACAACAG-3'. Molecular hybridizations of EMC-D and EMC-B genomic RNAs with a DNA primer complementary to the EMC-D-specific oligoribonucleotide revealed that the absence of a corresponding spot in EMC-B was due to a point mutation rather than a deletion. By sequencing a cloned cDNA of EMC-B corresponding to the EMC-D-specific oligoribonucleotide, the point mutation was identified as a G for EMC-B and an A for EMC-D transversion at base 9 of the oligonucleotide. Comparative sequence analysis of eight randomly picked RNA segments around the EMC-D-specific oligoribonucleotide revealed that there were no base changes between EMC-D and EMC-B. It is concluded that the diabetogenic EMC-D viral genome differs from the nondiabetogenic EMC-B viral genome by at least a point mutation.

Distinct binding sites for zinc and double-stranded RNA in the reovirus outer capsid protein sigma 3

By atomic absorption analysis, we determined that the reovirus outer capsid protein sigma 3, which binds double-stranded RNA (dsRNA), is a zinc metalloprotein. Using Northwestern blots and a novel zinc blotting technique, we localized the zinc- and dsRNA-binding activities of sigma 3 to distinct V8 protease-generated fragments. Zinc-binding activity was contained within an amino-terminal fragment that contained a transcription factor IIIA-like zinc-binding sequence, and dsRNA-binding activity was associated with a carboxy-terminal fragment. By these techniques, new zinc- and dsRNA-binding activities were also detected in reovirus core proteins. A sequence similarity was observed between the catalytic site of the picornavirus proteases and the transcription factor IIIA-like zinc-binding site within sigma 3. We suggest that the zinc- and dsRNA-binding activities of sigma 3 may be important for its proposed regulatory effects on viral and host cell transcription and translation.

Viral RNA polymerases

Recent progress in molecular biological techniques revealed that genomes of animal viruses are complex in structure, for example, with respect to the chemical nature (DNA or RNA), strandedness (double or single), genetic sense (positive or negative), circularity (circle or linear), and so on. In agreement with this complexity in the genome structure, the modes of transcription and replication are various among virus families. The purpose of this article is to review and bring up to date the literature on viral RNA polymerases involved in transcription of animal DNA viruses and in both transcription and replication of RNA viruses. This review shows that the viral RNA polymerases are complex in both structure and function, being composed of multiple subunits and carrying multiple functions. The functions exposed seem to be controlled through structural interconversion.

Polyprotein processing in picornavirus replication

The primary translation product of the picornavirus genome is a single large protein which is processed to the mature viral polypeptides by progressive, co- and post-translational cleavages. Replication of the picornaviruses is thus entirely dependent upon the proteolysis of viral precursor proteins. In poliovirus, two virus-encoded proteinases have been identified that catalyze all but the final cleavage of the viral polyprotein. The final processing event, maturation of the virion polypeptide VPO, appears to occur by an unusual autocatalytic serine proteinase-like mechanism. Proteolytic processing of viral precursor proteins is basically similar in all picornaviruses, but recently it has become clear that there are also important differences between these viruses. Understanding of the processing events in picornavirus replication may ultimately lead to the discovery of specific inhibitors of the viral enzymes that could prove clinically useful as anti-viral agents.

Viral proteases: an emerging therapeutic target

Only a few viral diseases are presently treatable because of our limited knowledge of specific viral target molecules. An attractive class of viral molecules toward which chemotherapeutic agents could be aimed are proteases coded by some virus groups such as retro- or picornaviruses (poliomyelitis, common cold virus). The picornavirus enzymes were discovered first, and they have now been characterized by a combination of molecular-genetic and biochemical approaches. Several laboratories have expressed the picornaviral enzymes in heterologous systems and have reported proteolytic activity, as well as the high cleavage fidelity diagnostic of the viral proteases. After dealing with several technical difficulties often encountered in standard genetic engineering approaches, one viral protease is now available to us in quantity and is amendable to mutagenic procedures. The initial outcome of the mutagenesis studies has been the confirmation of our earlier work with inhibitors, which suggested a cysteine active-site class. There is a clustering of active-site residues which may be unique to these viruses. The requirement for an active-site cysteine-histidine pair in combination with detailed information on the viral cleavage sites has permitted design of selective inhibitors with attractive antiviral properties. Future goals include investigation of the structural basis for selective processing and application of the cleavage specificity to general problems in genetic engineering.

Use of cRNA probes for the detection of enteroviruses by molecular hybridization

Subgenomic fragments of cDNA from poliovirus type 1 were inserted downstream from the SP6 or the T7 promoter in a Gemini riboprobe vector and their in vitro synthesized RNA transcripts were used as radiolabeled probes for the detection of enteroviral RNAs by molecular hybridization. The cRNA transcripts appeared to be more sensitive probes than the corresponding cDNAs. In vitro transcripts of the 5' noncoding region (5' nc riboprobe) were able to detect all of 14 reference enterovirus strains tested, as well as human rhinovirus 2, by dot blot hybridization with infected cell lysates. The same riboprobe also detected the enteroviral RNAs present in 16 of 18 samples of successive passages of stools in tissue culture and in some cases even in crude stool extracts. A riboprobe from the VP 1 region detected specifically poliovirus types 1, 2, and 3 in lysates of infected cells and in 50% of the infected stool specimens tested. These probes could be of particular interest for the epidemic survey of poliovirus infections.

Complete nucleotide sequence of the Japanese encephalitis virus genome RNA

The complete nucleotide sequence of the Japanese encephalitis virus (JEV) genome RNA was determined. The JEV genome contains 10,976 nucleotides and encodes a single long open reading frame (ORF) of 10,296 nucleotides corresponding to 3432 amino acid residues. This long polypeptide is thought to be cleaved into three structural proteins and several nonstructural proteins of the virus. The genetic location of the three structural proteins was determined by comparing the deduced amino acid sequence from the nucleotide sequence with the N-terminal amino acid sequences that were determined from the three purified structural proteins. The C-terminal region of the ORF may encode a RNA-dependent RNA polymerase which has significant sequence homology with those of other RNA viruses.

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.

Studies on the recombination between RNA genomes of poliovirus: the primary structure and nonrandom distribution of crossover regions in the genomes of intertypic poliovirus recombinants

A series of intertypic (type 3/type 1) poliovirus recombinants was obtained whose crossover sites were expected to be located in the middle of the viral genome, between the loci encoding type-specific antigenic properties, on the 5' side, and an altered sensitivity to guanidine, on the 3' side. The primary structures of the crossover regions in the genomes of these recombinants were determined by the primer extension method. The length of the crossover sites (the uninterrupted sequences shared by the recombinant and both parental genomes that are flanked, in the recombinant RNAs, by two heterotypic segments) varied between 2 and 32 nucleotides, but the majority of the sites were 5 nucleotides long or shorter. The crossover sites were nonrandomly distributed over the presumably available genome region: only a single such site was found within the gene for polypeptide 2A, whereas an apparent clustering of the crossover sites was encountered in other genomic segments. When the crossover sites were superimposed on a model of the secondary structure of the relevant region of the viral RNA molecule, a pattern consistent with the previously proposed mechanism of poliovirus recombination (L.I. Romanova, V.M. Blinov, E.A. Tolskaya, E.G. Viktorova, M.S. Kolesnikova, E.I. Guseva, and V.I. Agol (1986) Virology 155, 202-213) was observed. It is suggested that the nonrandom distribution of the crossover sites in the genomes of intertypic poliovirus recombinants was due to two factors: the existence of preferred sites for recombination, and selection against recombinants with a lowered level of viability.

Processing determinants required for in vitro cleavage of the poliovirus P1 precursor to capsid proteins

We generated defined alterations in poliovirus protein-processing substrates and assayed the effects of these alterations with an in vitro expression system. A complete cDNA copy of the poliovirus genome was inserted into a bacteriophage T7 transcription vector. Using this expression template, we produced RNA transcripts containing defined regions of the poliovirus capsid precursor polypeptide (P1) and RNA transcripts containing mutations in the P1 and P2 regions. In vitro translation of P1-derived transcripts allowed us to characterize the 3C-mediated cleavage of P1 to capsid proteins. We demonstrated that, for either posttranslational or cotranslational cleavage at any of the Q-G amino acid pairs within P1, almost the entire P1 precursor is required. We also demonstrated that minimal sequences 3' to the 2A coding sequence are required to generate active 2A proteinase in vitro and that two specific four-amino-acid insertions in protein 2C do not alter 2A- or 3C-mediated processing of the poliovirus polyprotein. In addition, we demonstrated that substantial deletion of P1 sequences does not alter 2A-mediated cleavage of the Y-G site at the P1-P2 junction. These results allowed us to compare the P1 sequences required for 2A- versus 3C-mediated processing of the capsid precursor, and we discuss these results in the context of the three-dimensional structure of the capsid proteins.

Geographic distribution of wild poliovirus type 1 genotypes

Determination of the patterns of genomic variation among RNA virus isolates is a powerful approach for establishing their epidemiologic interrelationships. The standard technique for such studies, ribonuclease T1 oligonucleotide fingerprinting, can detect similarities only among very closely related isolates. The rapid evolution of the poliovirus genome during transmission in humans requires the application of alternate methods to identify more distant relationships. To obtain a substantially broader view of the distribution of wild poliovirus type 1 genotypes in nature, we compared 150 bases of genomic sequence information (encoding parts of the capsid protein VP1 and the noncapsid protein 2A) from 62 isolates obtained from poliomyelitis patients in five continents. The partial sequence information allowed us to (1) identify numerous geographic foci of endemic circulation of wild type 1 polioviruses, (2) reveal previously unsuspected links between cases in distant communities, (3) monitor the displacement from the environment of preexisting polioviruses by viruses from other regions, and (4) recognize the recombinant (vaccine-wild; wild-wild) origins of some epidemic polioviruses.

Proteolytic processing of foot-and-mouth disease virus polyproteins expressed in a cell-free system from clone-derived transcripts

All picornaviral genes are expressed as a single, large polyprotein, which is proteolytically processed into the system produces functional proteins, including viral protease 3C, which plays a major role in processing the precursor proteins. To study the function of the two putative proteases 3C and leader (L) in processing, we constructed several cDNA plasmids encoding various regions of the FMDV type A12 genome. These plasmids, containing FMDV cDNA segments under the control of the T7 promoter, were transcribed in vitro by using T7 RNA polymerase and then translated in rabbit reticulocyte lysates. The expressed FMDV gene products were identified by immunoprecipitation with specific antisera and analyzed by gel electrophoresis. The results demonstrate the following: (i) the leader protein, L, is processed from the structural protein precursor, P1, in the absence of any P2 or P3 region proteins; (ii) protein 2A remains associated with the structural protein precursor, P1, rather than the precursor, P2; (iii) the processing of the P1-2A/P2 junction is not catalyzed by 3C or L; (iv) the proteolytic processing of polyproteins from the structural P1 region (except VP4/VP2) and the nonstructural P2 and P3 region is catalyzed by 3C.

Poliovirus proteinase 2A induces cleavage of eucaryotic initiation factor 4F polypeptide p220

Poliovirus infection of HeLa cells induces rapid shutoff of host protein synthesis, whereas translation of poliovirus RNA is not inhibited. It is presumed that shutoff is the result of proteolytic cleavage of component p220 of eucaryotic initiation factor 4F. To study whether poliovirus proteinase 2A is involved in this cleavage, we translated synthetic RNAs that contained the coding region for poliovirus-specific polypeptides P1 and 2A in vitro and assayed for cleavage of p220. We report here that cleavage of p220 occurred in all cases when active proteinase 2A was translated and that disruption of the coding sequence of 2A by linker insertion or deletion prevented processing of p220 in vitro. Activity of 2A was determined by its ability to cleave at the P1-P2 site of a segment of the poliovirus polyprotein. We also constructed a plasmid in which the 3'-most 500 nucleotides of the nontranslated region of encephalomyocarditis virus were linked to the coding sequence for poliovirus polypeptide 2A. Translation of the RNA transcript of this clone was very efficient and yielded a fusion protein that included 2A; this polypeptide also induced cleavage of p220. In vitro translation in the presence of antibodies against 2A specifically inhibited processing of p220, whereas incubation of in vitro translation products with antibodies against 2A after translation was completed did not prevent proteolysis of p220.

The entire nucleotide sequence of the genome of human hepatitis A virus (isolate MBB)

Hepatitis A virus (HAV) is an important human pathogen causing hepatitis, with high incidence in developed as well as in developing countries. No vaccines are available. In order to determine the primary structure of the HAV genome, we have prepared cDNAs from viral RNA and cloned these into plasmid pBR322. These clones were used to determine the entire nucleotide sequence of the HAV RNA by rapid sequencing methods. We have compared this sequence of 7470 bases to known partial sequences, and one complete sequence of HAV RNA which were obtained recently from different strains of HAV. It is hoped that a comparison of sequence data from different isolates will help in the elucidation of the unusual growth pattern of HAV. In addition, it might provide helpful information about the immunological determinants that elicit the antibody response to infection.

Proteolytic activity of the cowpea mosaic virus encoded 24K protein synthesized in Escherichia coli

The function of the 24-kilodalton (24K) protein encoded by cowpea mosaic virus (CPMV) has been studied by constructing a bacterial expression plasmid that contained a cloned chimeric segment consisting of partial DNA copies of CPMV M-RNA (including sequences coding for both capsid proteins) and B-RNA (including sequences coding for the 24K protein). Viral sequences were transcribed from the phage T7 promoter phi 10 of plasmid pT7-6 using T7-RNA polymerase expressed from plasmid pGP1-2 present in the same cells. Upon inducing the synthesis of T7-RNA polymerase several new polypeptides that contained CPMV-specific sequences were expressed, as demonstrated by immunoprecipitation and immunoblotting. Furthermore a proteolytic activity was detected in induced cells which cleaved the viral protein sequences specifically at two glutamine-glycine sites. One of the cleavage products represented capsid protein VP23. The proteolytic activity was absent when an 87-bp deletion was introduced in the coding region for the 24K protein, indicating that this protein represented the protease involved in the proteolytic processing at those specific sites.

Site-directed mutagenesis of proteinase 3C results in a poliovirus deficient in synthesis of viral RNA polymerase

We used a synthetic double-stranded oligonucleotide to introduce amino acid substitutions into the proteinase 3C region of a poliovirus type 1 cDNA clone. The six different mutant viruses recovered exhibited a small-plaque phenotype when assayed on HeLa cells. Further investigation revealed that all the mutations (with the exception of one) yielded P3 region proteins that displayed altered mobility in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A conservative Val----Ala change at amino acid 54 of the proteinase resulted in a virus that was deficient in the production of the mature viral RNA polymerase 3D. Although this mutant achieved less than one-half of the wild-type levels of RNA synthesis during the course of infection, it still grew to nearly wild-type titers.

Poliovirus polypeptide precursors: expression in vitro and processing by exogenous 3C and 2A proteinases

Plasmids have been constructed to generate substrates for the study of proteinases 2A and 3C of poliovirus. They contain the P1 (capsomer precursor) region of the poliovirus genome or P1 and part of P2 (a nonstructural precursor), which can be transcribed and translated in vitro. A transcript containing the entire 5' nontranslated region and the P1 region of the viral RNA gave poor translation in a reticulocyte translation system. Truncation of the 5' nontranslated region to its 3'-most segment gave acceptably good yields of radiolabeled P1. P1 was specifically processed to yield capsomer proteins by enzymes supplied in a postmitochondrial supernatant from poliovirus-infected cells. Thus, proteinase 3C can be supplied exogenously (in trans) and effect processing. This system may be used to provide P1 for the assay of proteinase 3C. Precursors that lacked either the 1A or 1D regions were poor substrates for proteinase 3C--observations that demonstrated a stringent structural requirement in processing by 3C. The translation product of a transcript encoding P1 and part of P2 was rapidly cleaved at the P1-P2 site in the absence of infected-cell extract. A transcript that contained a mutated 2A region gave a stable P1-P2 precursor that could be processed specifically by exogenous proteinase from infected-cell fractions. Processing of P1 appeared to require cleavage of the P1-P2 bond. These results support our previous data that 2A is the second polioviral proteinase and also provides a means of assaying proteinase 2A in vitro.

Processing of the Semliki Forest virus structural polyprotein: role of the capsid protease

The protease activities responsible for the cotranslational processing of the Semliki Forest virus structural polyprotein were investigated by using an in vitro transcription-translation system. Three cleavages released the individual chains from the nascent polyprotein in the order capsid, p62, 6K (a nonstructural peptide), and E1. We showed directly that the protease activity responsible for the release of the capsid protein resides in the capsid itself: by progressive truncation of the cDNA used for the SP6 transcription, we showed that a precursor containing as few as 38 residues of the p62 protein left at the C terminus of the capsid was still very efficiently cleaved in vitro. We further tested the possibility that serine-219 of the capsid is involved in autoproteolysis by site-directed in vitro mutagenesis. A change in the sequence Gly-Asp-Ser(219)-Gly, a tetrapeptide conserved among several animal serine proteases, to Gly-Asp-Arg-Ser-Thr was shown to completely abolish in vitro cleavage. This supports the notion that the capsid is a serine protease. The role of the capsid protease in the processing of the 6K junctions was then investigated by translations of a hybrid polyprotein in which the capsid and most of the p62 sequences are replaced by those of the secretory protein lysozyme. The cleavages and concomitant appearance of the 6K peptide occurred efficiently and were shown to require the presence of membranes. This demonstrates that the capsid protease is not required for those cleavages and suggests that a membrane-associated host protease is responsible for the cleavage.

Evolutionary relationships within the human rhinovirus genus: comparison of serotypes 89, 2, and 14

The complete nucleotide sequence of the genome of human rhinovirus type 89 was determined from the cDNA that had been cloned into Escherichia coli. The genome is 7152 nucleotides long and contains a single large open reading frame of 2164 codons. Translation commences at position 619 and ends 42 nucleotides before the poly(A) tract. The positions of three proteolytic cleavage sites in the polyprotein were determined by N-terminal amino acid sequencing of the capsid proteins; the remainder were predicted from comparisons with other picornaviruses. Extensive similarity between the derived amino acid sequences of human rhinovirus types 89 and 2 was found, whereas the similarity between human rhinovirus types 89 and 14 was considerably less. It is apparent that human rhinoviruses may be more closely related than has been previously thought.

Construction of viable deletion and insertion mutants of the Sabin strain of type 1 poliovirus: function of the 5' noncoding sequence in viral replication

A number of deletion and insertion sequences were introduced into the 5' noncoding sequence (742 nucleotides long) of the genome of the Sabin strain of type 1 poliovirus by using an infectious cDNA clone of the virus strain. The genomes of all three poliovirus serotypes contained highly homologous sequences (nucleotide positions 509 to 639) as well as highly variable sequences (positions 640 to 742) in the 5' noncoding region. The viability of mutant viruses was tested by transfecting mutant cDNA clones into African green monkey kidney cells and then estimating the plaque sizes displayed on the cells. The results suggested that the highly variable sequence next to the VP4 coding region did not play an important role, at least in the in vitro culture system used, that the loci of highly conserved nucleotide sequences were not always expected to be the genome regions essential for viral replication, that the sequence between positions 564 and 599 carried genetic information to maintain the efficiency of certain steps in viral replication, and that the sequence between positions 551 to 563 might play an essential role in viral replication. Four-base deletion or insertion mutations were introduced into relatively variable sequences in the genome region upstream of position 509. The results suggest that variable sequences do not always indicate that the corresponding genome regions are less important. Apparent revertants (large-plaque variants) were easily generated from one of the viable mutants with the small-plaque phenotype. The determination of nucleotide sequences of the revertant genomes revealed the second mutation site. The results suggested that the different loci at around positions 200 and 500 might specifically interact with each other. This interaction may result in the formation of a functional structure that influences the efficiency of certain steps in the viral replication.

Proteolysis of the p220 component of the cap-binding protein complex is not sufficient for complete inhibition of host cell protein synthesis after poliovirus infection

Infection of cells with poliovirus results in the complete shutoff of host protein synthesis. It is presumed that proteolysis of the p220 component of the cap-binding protein complex that is required for the translation of host mRNAs is responsible for the shutoff phenomenon. In this paper, we show that when cells are infected with poliovirus in the presence of guanidine or 3-methylquercetin, both inhibitors of poliovirus replication, complete cleavage of p220 occurs by 3.5 h postinfection. However, under these conditions only 55 to 77% of host protein synthesis is suppressed. Results obtained with extracts prepared from poliovirus-infected cells were similar to those obtained in vivo. These results suggest that complete inhibition of host protein synthesis after poliovirus infection requires at least one event in addition to proteolysis of p220. Thus, proteolysis of p220 is probably necessary but not sufficient for total suppression of host protein synthesis after poliovirus infection.

In vitro molecular genetics as a tool for determining the differential cleavage specificities of the poliovirus 3C proteinase

We describe a completely in vitro system for generating defined poliovirus proteinase mutations and subsequently assaying the phenotypic expression of such mutations. A complete cDNA copy of the entire poliovirus genome has been inserted into a bacteriophage T7 transcription vector. We have introduced proteinase and/or cleavage site mutations into this cDNA. Mutant RNA is transcribed from the altered cDNA template and is subsequently translated in vitro. Employing such a system, we provide direct evidence for the bimolecular cleavage events carried out by the 3C proteinase. We show that specific genetically-altered precursor polypeptides containing authentic Q-G cleavage sites will not act as substrates for 3C either in cis or in trans. We also provide evidence that almost the entire P3 region is required to generate 3C proteinase activity capable of cleaving the P1 precursor to capsid proteins. However, only the 3C portion of P3 is required to generate 3C proteinase activity capable of cleaving P2 and its processing products.

Site-specific mutagenesis of cDNA clones expressing a poliovirus proteinase

The cleavage of poliovirus precursor polypeptides occurs at specific amino acid pairs that are recognized by viral proteinases. Most of the polio-specific cleavages occur at glutamine-glycine (Q-G) pairs that are recognized by the viral-encoded proteinase 3C (formerly called P3-7c). In order to carry out a defined molecular genetic study of the enzymatic activity of protein 3C, we have made cDNA clones of the poliovirus genome. The cDNA region corresponding to protein 3C was inserted into an inducible bacterial expression vector. This recombinant plasmid (called pIN-III-C3-7c) utilizes the bacterial lipoprotein promoter to direct the synthesis of a precursor polypeptide that contains the amino acid sequence of protein 3C as well as the amino- and carboxy-terminal Q-G cleavage signals. These signals have been previously shown to allow autocatalytic production of protein 3C in bacteria transformed with plasmid pIN-III-C3-7c. We have taken advantage of the autocatalytic cleavage of 3C in a bacterial expression system to study the effects of site-specific mutagenesis on its proteolytic activity. One mutation that we have introduced into the cDNA region encoding 3C is a single amino acid insertion near the carboxy-terminal Q-G cleavage site. The mutant recombinant plasmid (designated pIN-III-C3-mu 10) directs the synthesis of a bacterial-polio precursor polypeptide that is like the wild-type construct (pIN-III-C3-7c). However, unlike the wild-type precursor, the mutant precursor cannot undergo autocatalytic cleavage to generate the mature proteinase 3C. Rather, the precursor is able to carry out cleavage at the amino-terminal Q-G site but not at the carboxy-terminal site. Thus, we have generated an altered poliovirus proteinase that is still able to carry out at least part of its cleavage activities but is unable to be a suitable substrate for self-cleavage at its carboxy-terminal Q-G pair.

Complete nucleotide sequence of the genome of coxsackievirus B1

The complete nucleotide sequence of the genome of the coxsackievirus B1, a human enterovirus that belongs to the Picornaviridae, was determined by using molecular cloning and rapid sequence analysis techniques. Sequence analysis of the cloned cDNAs revealed that the virion RNA was 7389 nucleotides long and polyadenylylated at the 3' terminus. Similar to other picornavirus genomes, a single large open reading frame was identified. The translated sequence starts at nucleotide position 742 and ends at 7287 of the genome. Thus, the viral polyprotein should consist of 2182 amino acids. When the predicted amino acid sequence of the viral polyprotein was compared with those of other human enteroviruses such as polioviruses, a striking sequence homology was observed, especially in viral proteins 1B, 2C, and 3D. This allowed us to predict precise map locations of the viral structural and nonstructural proteins on the genome, although two proteolytic processing sites, between 1D and 2A and between 2B and 2C, were obscure. The result presented here implied important information with respect to the genetical variation of human enteroviruses.

Implications of the picornavirus capsid structure for polyprotein processing

Mature picornaviral proteins are derived by progressive, posttranslational cleavage of a precursor polyprotein. These cleavages play a role in the control of virus functions. Although the processed termini are separated by as much as 75 A in the native virus capsid, the fold and arrangement of polypeptide chains in a protomer before proteolysis are likely to be similar to that found in the mature virus. The three-dimensional structures of rhinovirus and Mengo virus suggest that the cleavage sites within the protomeric precursor are in structurally flexible regions. The final proteolytic processing event, maturation of the virion peptide VP0 (also called peptide 1AB) appears to occur by an unusual autocatalytic serine protease-type mechanism possibly involving viral RNA basic groups that would serve as proton-abstractors during the cleavage reaction.

Vectors for selective expression of cloned DNAs by T7 RNA polymerase

Plasmid vectors are described that allow cloning of target DNAs at sites where they will be minimally transcribed by Escherichia coli RNA polymerase but selectively and actively transcribed by T7 RNA polymerase, in vitro or in E. coli cells. Transcription is controlled by the strong phi 10 promoter for T7 RNA polymerase, and in some cases by the T phi transcription terminator. The RNA produced can have as few as two foreign nucleotides ahead of the target sequence or can be cut by RNase III at the end of the target sequence. Target mRNAs can be translated from their own start signals or can be placed under control of start signals for the major capsid protein of T7, with the target coding sequence fused at the start codon or after the 2nd, 11th or 260th codon for the T7 protein. The controlling elements are contained on small DNA fragments that can easily be removed and used to create new expression vectors.