Viral Proteins Formed in a Cell-Free RABBIT Reticulocyte System Programmed with RNA from a Temperature-Sensitive Mutant of Sindbis Virus

Viral messenger RNA was isolated from BHK cells infected with a temperature-sensitive mutant of Sindbis virus and was further purified using an oligo(dT) column. Addition of this mRNA cell-free extracts from rabbit reticulocytes led to formation of discrete authentic viral capsid protein when the reaction was performed at 29 C. However, this same protein-synthesizing system failed to make discrete viral capsid when incubated with the viral RNA at 39 C. Instead, larger-molecular-weight polypeptides that contained the viral capsid peptide sequences were produced. The inability to make a separate viral capside protein in vitro at elevated temperatures by the mRNA from this mutant exactly mimics the phenotype of this ts mutant in viral-infected cells. Three mechanisms are discussed that might account for a temperature-sensitive release of capsid. One of these is based on a model in which there are multiple sites for initiation of translation of polypeptides on a polycistronic viral mRNA.     

Preliminary characterization of coxsackievirus B3 temperature-sensitive mutants.

Prototype temperature-sensitive (ts) mutants of a coxsackievirus B3 parent virus capable of replication to similar levels at 34 or 39.5 degrees C were examined for the nature of the temperature-sensitive event restricting replication in HeLa cells at 39.5 degrees C. The ts mutant prototypes represented three different non-overlapping complementation groups. The ts1 mutant (complementation group III) synthesized less than 1% of the infectious genomic RNA synthesized by the coxsackievirus B3 parent virus at 39.5 degrees C and was designated an RNA- mutant. Agarose gel analysis of glyoxal-treated RNA from cells inoculated with ts1 virus revealed that cell RNA synthesis continued in the presence of synthesis of the small amount of viral RNA. This mutant was comparatively ineffective in inducing cell cytopathology and in directing synthesis of viral polypeptides, likely due to the paucity of nascent genomes for translation. The ts5 mutant (complementation group II) directed synthesis of appreciable quantities of both viral genomes (RNA+) and capsid polypeptides; however, assembly of these products into virions occurred at a low frequency, and virions assembled at 39.5 degrees C were highly unstable at that temperature. Shift-down experiments with ts5-inoculated cells showed that capsid precursor materials synthesized at 39.5 degrees C can, after shift to 34 degrees C, be incorporated into ts5 virions. We suggest that the temperature-sensitive defect in this prototype is in the synthesis of one of the capsid polypeptides that cannot renature into the correct configuration required for stability in the capsid at 39.5 degrees C. The ts11 mutant (complementation group I) also synthesized appreciable amounts of viral genomes (RNA+) and viral polypeptides at 39.5 degrees C. Assembly of ts11 virions at 39.5 degrees C occurred at a low frequency, and the stability of these virions at 39.5 degrees C was similar to that of the parent coxsackievirus B3 virions. The temperature-sensitive defect in the ts11 prototype is apparently in assembly. The differences in biochemical properties of the three prototype ts mutants at temperatures above 34 degrees C may ultimately offer insight into the differences in pathogenicity observed in neonatal mice for the three prototype ts mutants.     

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.     

Proteolytic cleavage of encephalomyocarditis virus capsid region substrates by precursors to the 3C enzyme.

Picornavirus protease 3C is normally released from its P3 precursor by two successive self-cleavage reactions. The free enzyme can then catalyze most of the remaining processing events within the viral polyprotein. To investigate the role of the 3C precursors in the processing cascade, we constructed cDNA clones which expressed genetically altered forms of the encephalomyocarditis P3 region in vitro. Site-specific substitutions were introduced into the Gln-Gly residues at the 3B-3C and 3C-3D junctions, and the resulting proteins were tested for their ability to self-process and to catalyze cleavage of viral capsid precursors in cell-free protease assays. We determined that three P3 region precursor proteins (3ABC, 3CD, and P3), harboring inactive cleavage sites, were as active as the free enzyme (3C) in processing assays with capsid substrates. Further, we found that in addition to the naturally occurring Gln-Gly and Gln-Ser amino acid pairs, the encephalomyocarditis 3C enzyme was able to process Gln-Cys but not Gln-Thr, Gln-Ile, Gln-Tyr, Arg-Gly, or Leu-Gly combinations when these residues were substituted into normal cleavage site contexts.     

Site-directed mutagenesis of the proposed catalytic amino acids of the Sindbis virus capsid protein autoprotease.

The structural proteins of Sindbis virus are translated as a polyprotein precursor that is cleaved upon translation. The capsid protein is postulated to be a serine protease that releases itself from the N terminus of the nascent polyprotein by autoproteolysis. We have tested the importance in autoproteolysis of His-141, Asp-147, and Ser-215, previously postulated to form the catalytic triad of the protease, and of Asp-163. Several site-specific mutations were constructed at each of these positions, and the release of the capsid protein during translation in a cell-free system was examined. Because proteolysis occurs in cis during translation, the kinetics of release cannot be determined in this system, but the extent of proteolysis can be ascertained. Ser-215 appears to be the catalytic serine of the proteinase. Cys or Thr could substitute inefficiently for Ser-215, but substitution with Ala or Ile led to complete loss of activity. His-141 was also important for proteolysis. Substitution with Ala or Pro led to total loss of activity. Surprisingly, substitution with Arg resulted in complete proteolysis in vitro. Changes at the two Asp residues resulted in complete proteolysis of the substrate in vitro. All mutations that resulted in at least partial cleavage in vitro were incorporated into a full-length clone of Sindbis virus and an attempt was made to recover mutant virus. All changes tested were lethal for the virus except Asp-163 to Asn. Thus, production of infectious virus is either a more sensitive measure of the catalytic rate than the extent of in vitro cleavage, or these residues have necessary functions in addition to their possible role in proteolysis.     

Effects of temperature and lipophilic agents on poliovirus formation and RNA synthesis in a cell-free system.

The translation and primary processing events of poliovirus polyproteins in HeLa cell extracts were more efficient at 34 degrees C than at 30 or 36 degrees C. The cleavage products of P2 such as 2Apro, 2BC, and 2C appeared early in the reaction before the appearance of the cleavage products of P1 and of 3CDpro, an observation suggesting that P2 was cleaved in cis by 3CDpro. Proteolytic processing of the capsid precursor P1 into VP0, VP1, and VP3 was also more efficient at 34 degrees C than at either 30 or 32 degrees C. Surprisingly, processing of 3CDpro to 3Cpro and 3Dpol was almost completely inhibited at 36 degrees C. The synthesis of virus in the cell extract was greatly enhanced at 34 degrees C over that at 30 or 32 degrees C, whereas incubation at 36 degrees C yielded very little virus. Cerulenin, an inhibitor of lipid synthesis, did not appear to affect virus-specific translation or protein processing, but it almost completely inhibited viral synthesis in vitro. Oleic acid drastically inhibited in vitro translation at 100 microM and in vitro poliovirus synthesis at 25 microM. Addition of HeLa cell smooth membranes partially restored translation but not virus formation. Our observations suggest that in vitro translation, proteolytic processing, and virus formation require intact membranes. Analysis of the in vitro translation products revealed that viral RNA polymerase activity increased linearly during incubation of the translation mixture. RNA polymerase in the crude mixture was inhibited by oleic acid but not by cerulenin. Surprisingly, oleic acid had no direct effect on oligo(U)-primed, poly(A)-dependent poly(U) synthesis catalyzed by purified 3Dpol.     

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.     

Effects of mutations in poliovirus 3Dpol on RNA polymerase activity and on polyprotein cleavage.

A series of short insertion mutations was introduced into the poliovirus gene for 3Dpol at a number of different locations. When substituted for wild-type sequences in a full-length, infectious cDNA and tested for infectivity, all 3D mutants were nonviable. The mutant cDNAs were introduced into a bacterial plasmid designed to direct the expression of poliovirus 3CD, a viral protein composed of contiguous protease and RNA polymerase sequences. Bacteria transformed with these plasmids all expressed similar amounts of 3CD, and all mutant proteins cleaved themselves to generate wild-type 3Cpro and mutant 3Dpol polypeptides with approximately the same efficiency as wild-type 3CD. The released mutant 3Dpol proteins were all defective in RNA-dependent RNA polymerase activity in vitro. Uncleaved 3CD is a protease required for processing the viral capsid protein precursor, P1. In an in vitro assay of P1 cleavage activity, some of the mutant 3CD proteins expressed in Escherichia coli showed normal activity, while others were clearly inactive. Thus, alterations in the sequence and/or folding of different regions of the 3D protein have differential effects on its various activities.     

Protein Synthesis Directed by an RNA? Temperature-Sensitive Mutant of Sindbis Virus

The structural proteins of wild-type Sindbis virus were shown to arise by posttranslational cleavage of larger precursors. The proteins synthesized in wildtype infection were compared with those specified by ts-11, a temperature-sensitive mutant unable to synthesize viral RNA at the restrictive temperature. Abnormally large, virus-specific proteins were found in the mutant-infected cells after the shift from 28 C to 41.5 C. These large polypeptides were presumably precursors which were cleaved too rapidly to be detected in the wild-type infection. The largest had a molecular weight of 133,000 and was the same size as the apparent precursor detected during infection with a group of Sindbis mutants which could not form nucleocapsids at the nonpermissive temperature. The stability of ts-11-specific RNA synthesis, after shift from permissive to restrictive conditions, differed from that in cells infected by wild-type virus, indicating that the virus had a genetic lesion in an enzyme involved in RNA synthesis. This mutation might have caused the precursor to fold incorrectly so that it could not be cleaved. The possibility cannot be excluded, however, that a second lesion in an uncharacterized viral function, such as a protease, was the cause of the accumulation of the precursors.     

Physical mapping of herpes simplex virus type 1 mutations by marker rescue.

Thirty temperature-sensitive mutants of encephalomyocarditis virus have been isolated and partially characterized. Fifteen of these mutants are phenotypically RNA+ thirteen are RNA-, and two are RNA +/-. Six RNA + mutants, one RNA- mutants, and one RNA +/- mutant have virions which are more thermosensitive at 56 degree C than the wild-type virions. Hela cells infected at the nonpermissive temperature with any of the RNA+ mutants produced neither infective nor noninfective viral particles. The cleavage of the precursor polypeptides in cells infected with 11 of the RNA+ mutants was defective at the nonpermissive temperature. This defect in cleavage occurred only in those precursor polypeptides leading to capsid proteins.     

Efficient cleavage of ribosome-associated poly(A)-binding protein by enterovirus 3C protease

Poliovirus (PV) causes a rapid and drastic inhibition of host cell cap-dependent protein synthesis during infection while preferentially allowing cap-independent translation of its own genomic RNA via an internal ribosome entry site element. Inhibition of cap-dependent translation is partly mediated by cleavage of an essential translation initiation factor, eIF4GI, during PV infection. In addition to cleavage of eIF4GI, cleavage of eIF4GII and poly(A)-binding protein (PABP) has been recently proposed to contribute to complete host translation shutoff; however, the relative importance of eIF4GII and PABP cleavage has not been determined. At times when cap-dependent translation is first blocked during infection, only 25 to 35% of the total cellular PABP is cleaved; therefore, we hypothesized that the pool of PABP associated with polysomes may be preferentially targeted by viral proteases. We have investigated what cleavage products of PABP are produced in vivo and the substrate determinants for cleavage of PABP by 2A protease (2A(pro)) or 3C protease (3C(pro)). Our results show that PABP in ribosome-enriched fractions is preferentially cleaved in vitro and in vivo compared to PABP in other fractions. Furthermore, we have identified four N-terminal PABP cleavage products produced during PV infection and have shown that viral 3C protease generates three of the four cleavage products. Also, 3C(pro) is more efficient in cleaving PABP in ribosome-enriched fractions than 2A(pro) in vitro. In addition, binding of PABP to poly(A) RNA stimulates 3C(pro)-mediated cleavage and inhibits 2A(pro)-mediated cleavage. These results suggest that 3C(pro) plays a major role in processing PABP during virus infection and that the interaction of PABP with translation initiation factors, ribosomes, or poly(A) RNA may promote its cleavage by viral 2A and 3C proteases.     

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.     

Temperature-sensitive translation of MS2 bacteriophage RNA

A comparison was made of bacteriophage MS2 RNA translation in infected Escherichia coli cells and in a defined cell-free system. A number of temperature-sensitive mutants were used as hosts for viral RNA translation at permissive and restrictive temperatures. The amount of viral coat protein synthesis was determined after gel electrophoresis of proteins from the cell lysates. These results were compared to those obtained with cell-free translation assays conducted with ribosomes isolated from the same mutants. Compared with control cells, a reduced activity in vivo and in vitro was found for each mutant examined at elevated temperatures. A good correlation between the two types of translational assays was observed. These findings are discussed in terms of the translational defects known to be a characteristic of some of these mutant strains.     

Regulation of Sindbis virus RNA replication: uncleaved P123 and nsP4 function in minus-strand RNA synthesis, whereas cleaved products from P123 are required for efficient plus-strand RNA synthesis.

Nonstructural proteins of Sindbis virus, nsP1, nsP2, nsP3, and nsP4, as well as intermediate polyproteins, are produced from two precursor polyproteins, P123 and P1234, by a proteolytic enzyme encoded in the C-terminal half of nsP2. We studied the requirements for and the functions of the intermediate and mature processing products for Sindbis virus RNA synthesis by using site-directed mutants which have a defect(s) in processing the 1/2, 2/3, or 3/4 cleavage sites either singly or in various combinations. A mutant defective in cleaving both the 1/2 and 2/3 sites, which makes only uncleavable P123 and mature nsP4 as final products, produced 10(-3) as much virus as did the wild-type virus after 10 h at 30 degrees C and was nonviable at 40 degrees C. A mutant defective in processing the 2/3 site, which makes nsP1, nsP4, and P23 as well as precursor P123, grew 10(-1) as efficiently as wild-type virus at 30 degrees C and 10(-3) as efficiently at 40 degrees C. Early minus-strand RNA synthesis by these mutants was as efficient as that by wild-type virus, whereas plus-strand RNA synthesis was substantially decreased compared with that by wild-type virus. A mutant defective in processing the 3/4 site was nonviable at either 30 or 40 degrees C. The 3/4 site mutant could be complemented by the mutant unable to cleave either the 1/2 or 2/3 site, which can provide mature nsP4. We interpret these results to signify that (i) mature nsP4 is required for RNA replication, (ii) nsP4 and uncleaved P123 function in minus-strand RNA synthesis, and (iii) cleavage of P123 is required for efficient plus-strand RNA synthesis. We propose that Sindbis virus RNA replication is regulated by differential proteolysis of P123. Early in infection, nsP4 and uncleaved P123 form transient minus-strand RNA replication complexes which vanish upon cleavage of P123. Later in infection, an elevated level of viral proteinase activity eliminates de novo synthesis of P123, and no further synthesis of minus-strand RNA is possible. In contrast, nsP4 and cleavage products from P123 form plus-strand RNA replication complexes which are stable and remain active throughout the infection cycle.     

Evidence for intramolecular self-cleavage of picornaviral replicase precursors.

It has previously been shown that when encephalomyocarditis viral RNA is translated in cell-free extracts of rabbit reticulocytes, it synthesizes a virus-coded protease, p22, which is derived by cleavage of a precursor protein, C. Protein C is shown here to be cleaved by two different mechanisms, which were distinguished by their sensitivity to dilution. One mechanism was sensitive to dilution; the other was not. The biphasic cleavage behavior was unchanged by diluting incubation mixtures with untranslated reticulocyte extract instead of buffer, suggesting that both types of cleavage were mediated by virus translation products. It is proposed that the dilution-sensitive cleavage of protein C is due to a virus-coded protease, probably p22 itself, and that the dilution-independent cleavage is due to intramolecular self-cleavage of protein C.     

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)