Formation of a Sindbis virus nonstructural protein and its relation of 42S mRNA function

Synthesis and processing of the nonstructural polyproteins of several temperature-sensitive mutants of Sindbis virus

We have examined the synthesis and processing of nonstructural polyproteins by several temperature-sensitive mutants of Sindbis virus, representing the four known RNA-minus complementation groups. Four mutants that possess mutations in the C-terminal domain of nonstructural protein nsP2 all demonstrated aberrant processing patterns when cells infected with these mutants were shifted from a permissive (30 degrees) to a nonpermissive (40 degrees) temperature. Mutants ts17, ts18, and ts24 showed severe defects in processing of nonstructural polyproteins at 40 degrees, whereas ts7 showed only a minor defect. In each case, cleavage of the bond between nsP2 and nsP3 was greatly reduced whereas cleavage between nsP1 and nsP2 occurred almost normally, giving rise to a set of polyprotein precursors not seen in wild-type-infected cells at this stage of infection. The nsP1 produced by these mutants was unstable and only small amounts could be detected in infected cells at the nonpermissive temperature. Submolar quantities of nsP2 were also present. We suggest that nsP1 and nsP2 may function as a complex and that free nsP1, and possibly nsP2, is degraded. Cleavage between nsP3 and nsP4 appeared to be normal in the mutants except in the case of ts17, where upon shift to 40 degrees P34 was unstable and nsP4 accumulated. We propose that the change in the P34/nsP4 ratio upon shift is responsible for the previously observed temperature sensitivity of subgenomic 26 S RNA synthesis in ts17 and for the failure of the mutant to regulate minus strand synthesis at 40 degrees. Other mutations tested, including ts21, which is found in the N-terminal half of nsP2, ts11, which has a mutation in nsP1, and ts6, which has a mutation in nsP4, all demonstrated nonstructural polyprotein processing indistinguishable from that in wild-type-infected cells. These results support our conclusion, based upon deletion mapping studies, that the C-terminal domain of nsP2 contains the nonstructural proteinase activity.

Evidence that Sindbis virus NSP2 is an autoprotease which processes the virus nonstructural polyprotein

The four nonstructural proteins (nsP1-4) of Sindbis virus, a member of the Togaviridae family, are initially expressed from the 5' segment of the single-stranded genomic (+)RNA as a polyprotein which is subsequently proteolytically processed. In attempts to identify the protease acting on this nonstructural polyprotein, we established a coupled in polyprotein, we established a coupled in vitro transcription-translation system which was able to faithfully process the major polyprotein when an mRNA encoding all four nonstructural proteins was used. A cDNA plasmid containing the entire Sindbis virus genome positioned immediately downstream of the phage SP6 polymerase promoter was cut with restriction endonucleases at sites located within the genes for the nonstructural proteins and mRNAs transcribed from these DNA fragments. The nsP1-2 and nsP2-3 cleavage sites are alanyl-alanine and both were susceptible to proteolysis in vitro only after all of nsp1 and nsP2 and 157 amino acids of nsP3 were translated. The nsP1-2 site was cleaved from a polyprotein that contained nsP1 and nsP2 and 59 amino acids of nsP3 but not from six polyproteins whose sequences terminated in the nsP2 gene. These data support our hypothesis that the nonstructural polyprotein is processed by a virus autoprotease and we propose that its active site is encoded within the nsP2 sequences.

Processing the nonstructural polyproteins of Sindbis virus: study of the kinetics in vivo by using monospecific antibodies

Plasmids were constructed which contained a large portion of each of the four nonstructural genes of Sindbis virus fused to the N-terminal two-thirds of the trpE gene of Escherichia coli. The large quantity of fusion protein induced from cells containing these plasmids was subsequently used as an antigen to generate polyclonal antisera in rabbits. Each antiserum was specific for the corresponding nonstructural protein and allowed ready identification of each nonstructural protein and of precursors containing the sequences of two or more nonstructural proteins. These antisera were used to determine the stability of the mature nonstructural proteins and to examine the kinetics of processing of the nonstructural proteins from their respective precursors in vivo. Pulse-chase experiments showed that the precursor P123 is cleaved with a half-life of approximately 19 min to produce P12 and nsP3; P12 is then cleaved with a half-life of approximately 9 min to produce nsP1 and nsP2. Thus, although the rate of cleavage between nsP1 and nsP2 is faster than that between nsP2 and nsP3, the latter cleavage must occur first and is therefore the rate-limiting step. The rate at which P34 is chased suggests that the cleavage between nsP3 and nsP4 is the last to occur; however the regulation of nsP4 function in Sindbis virus-infected cells may be even more complex than was previously thought. The products nsP1 and nsP2 (and nsP4) are relatively stable; nsP3, however, is unstable, with a half-life of about 1 h, and appears to be modified to produce heterodisperse, higher-molecular-mass forms. In general, the processing schemes used by Sindbis virus and Semliki Forest virus appear very similar, the major difference being that most nsP3 in Sindbis virus results from termination at an opal condon, whereas in Semliki Forest virus cleavage of the P34 precursor is required.

Functional analysis of the A complementation group mutants of Sindbis HR virus

The 10 members of the A complementation group of temperature-sensitive (ts) mutants of SIN HR, the heat-resistant strain of Sindbis virus, were divided into two phenotypic subgroups. Subgroup I mutants (ts15, ts17, ts21, ts24, and ts133) demonstrated temperature-sensitive 26 S mRNA synthesis, whereas subgroup II mutants (ts4, ts14, ts16, ts19, and ts138) did not; both ts4 and ts19 demonstrated defective 26 S mRNA synthesis at 30 degrees. None of the A group mutants demonstrated temperature-sensitive 49 S plus-strand synthesis. Temperature-sensitive cleavage of ns230 was demonstrated by subgroup I mutants, except ts21, but not by subgroup II mutants. A revertant of ts133 that grew at 40 degrees retained temperature-sensitive 26 S mRNA synthesis but lost temperature-sensitive cleavage of ns230 and the RNA-negative phenotype. Only ts4, like ts11 of the B complementation group, demonstrated temperature-sensitive minus-strand RNA synthesis. In addition to ts24, cells infected with ts17 or ts133 continued to synthesize minus strands after shiftup in the absence of continued protein synthesis, and resumed synthesis of minus strands if shifted to the nonpermissive temperature after minus-strand synthesis had ceased at the permissive temperature.

The nonstructural proteins of Sindbis virus as studied with an antibody specific for the C terminus of the nonstructural readthrough polyprotein

A dodecapeptide containing the sequence of the C terminus of the nonstructural polyprotein of Sindbis virus has been synthesized and used to immunize rabbits. The antisera obtained precipitated polypeptides from cells infected with the HR strains of Sindbis or with temperature-sensitive mutants ts11 or ts18. Four different polypeptides, having apparent molecular weights of approximately 250,000, 220,000, 155,000, and 72,000, were immunoprecipitated by the antipeptide antiserum. The largest of these polypeptides is sufficiently large to represent a polyprotein translated from the entire nonstructural region of the genome. These data suggest that nsP4 of molecular weight 72,000 is produced by translation of the entire nonstructural region of the genome, which requires readthrough of an opal termination codon immediately upstream of nsP4, followed by post-translational cleavage of this polyprotein. The amounts of nsP4 and its precursors found in infected cells are small relative to the amounts of other nonstructural proteins present, as would be expected if readthrough of a termination codon is required. In addition, the relative amounts of nsP4 and of its precursors differ in HR-infected or ts mutant-infected cells and differ with temperature of infection, suggesting that temperature of infection or ts lesions affect translation and processing of the precursor polyprotein.

St. Louis encephalitis virus temperature-sensitive mutants. I. Induction, isolation and preliminary characterization

Nine temperature-sensitive (ts) mutants of St. Louis encephalitis virus were isolated after "forced mutagenesis" with 5-fluorouracil or 5-azacytidine. The ts mutants could be grouped on the basis of RNA synthesis at 40 degrees C, the nonpermissive temperature and complementation analysis. Four complementation groups were identified. Members of two of the groups were negative for RNA synthesis at 40 degrees C while the remainder were positive.

Specific Sindbis virus-coded function for minus-strand RNA synthesis

The synthesis of minus-strand RNA was studied in cell cultures infected with the heat-resistant strain of Sindbis virus and with temperature-sensitive (ts) belonging to complementation groups A, B, F, and G, all of which exhibited an RNA-negative (RNA-) phenotype when infection was initiated and maintained at 39 degrees C, the nonpermissive temperature. When infected cultures were shifted from 28 degrees C (the permissive temperature) to 39 degrees C at 3 h postinfection, the synthesis of viral minus-strand RNA ceased in cultures infected with ts mutants of complementation groups B and F, but continued in cultures infected with the parental virus and mutans of complementation groups A and G. In cultures infected with ts11 of complementation group B, the synthesis of viral minus-strand RNA ceased, whereas the synthesis of 42S and 26S plus-strand RNAs continued for at least 5 h after the shift to 39 degrees C. However, when ts11-infected cultures were returned to 28 degrees C 1 h after the shift to 39 degrees C, the synthesis of viral minus-strand RNA resumed, and the rate of viral RNA synthesis increased. The recovery of minus-strand synthesis translation of new proteins. We conclude that at least one viral function is required for alphavirus minus-strand synthesis that is not required for plus-strand synthesis. In cultures infected with ts6 of complementation group F, the syntheses of both viral plus-strand and minus-strand RNAs were drastically reduced after the shift to 39 degrees C. Since ts6 failed to synthesize both plus-strand and minus-strand RNAs after the shift to 39 degrees C, at least one common viral component appears to be required for the synthesis of both minus-strand and plus-strand RNAs.

Synthesis and processing of Semliki Forest virus-specific nonstructural proteins in vivo and in vitro

A large short-lived virus-specific nonstructural protein with an apparent molecular weight of about 250000 (nsp250) has been isolated from cells infected with the temperature-sensitive mutants ts-4 and ts-6 of the Semliki Forest virus. nsp250 contained all peptides characteristic of the two previously identified nonstructural precursor proteins, nsp155 and nsp135, as revealed by limited proteolysis with Staphylococcus aureus V8 protease. Thus nsp250 is probably the translational product of the 5' two-thirds of the 42-S RNA genome which codes for the virus-specific nonstructural proteins. A second viral nonstructural precursor protein, nsp220, was also characterized by peptide mapping. This protein contained all the peptides of nsp155, and several but not all of the peptides of nsp135. Some peptides were demonstrated which possibly are derived from ns60, the only nonstructural protein not yet isolated. Small amounts of proteins with identical mobility to nsp250 and nsp220 were synthesized at 38 degrees C in micrococcal-nuclease-treated rabbit reticulocyte lysate in response to virion 42-S RNA from the ts-6 mutant. The product of the wild-type 42-S RNA in vitro contained, in addition to nsp220 and nsp155, polypeptides which comigrated with ns86, ns72 and ns70, indicating processing of the translational product. The authenticity of nsp220, nsp155 and ns70 synthesized in vitro was confirmed by limited proteolysis with V8 protease.

Functional defects of RNA-negative temperature-sensitive mutants of Sindbis and Semliki Forest viruses

Defects in RNA and protein synthesis of seven Sindbis virus and seven Semliki Forest virus RNA-negative, temperature-sensitive mutants were studied after shift to the restrictive temperature (39 degrees C) in the middle of the growth cycle. Only one of the mutants, Ts-6 of Sindbis virus, a representative of complementation group F, was clearly unable to continue RNA synthesis at 39 degrees C, apparently due to temperature-sensitive polymerase. The defect was reversible and affected the synthesis of both 42S and 26S RNA equally, suggesting that the same polymerase component(s) is required for the synthesis of both RNA species. One of the three Sindbis virus mutants of complementation group A, Ts-4, and one RNA +/- mutant of Semliki Forest virus, ts-10, showed a polymerase defect even at the permissive temperature. Seven of the 14 RNA-negative mutants showed a preferential reduction in 26S RNA synthesis. The 26S RNA-defective mutants of Sindbis virus were from two different complementation groups, A and G, indicating that functions of two viral nonstructural proteins ("A" and "G") are required in the regulation of the synthesis of 26S RNA. Since the synthesis of 42S RNA continued, these functions of proteins A and G are not needed for the polymerization of RNA late in infection. The RNA-negative phenotype of 26S RNA-deficient mutants implies that proteins regulating the synthesis of this subgenomic RNA must have another function vital for RNA synthesis early in infection or in the assembly of functional polymerase. Several of the mutants having a specific defect in the synthesis of 26S RNA showed an accumulation of a large nonstructural precursor protein with a molecular weight of about 200,000. One even larger protein was demonstrated in both Semliki Forest virus- and Sindbis virus-infected cells which probably represents the entire nonstructural polyprotein.

Heterologous interference in Aedes albopictus cells infected with alphaviruses

Maximum amounts of 42S and 26S single-stranded viral RNA and viral structural proteins were synthesized in Aedes albopictus cells at 24 h after Sindbis virus infection. Thereafter, viral RNA and protein syntheses were inhibited. By 3 days postinfection, only small quantities of 42S RNA and no detectable 26S RNA or structural proteins were synthesized in infected cells. Superinfection of A. albopictus cells 3 days after Sindbis virus infection with Sindbis, Semliki Forest, Una, or Chikungunya alphavirus did not lead to the synthesis of intracellular 26S viral RNA. In contrast, infection with snowshoe hare virus, a bunyavirus, induced the synthesis of snowshoe hare virus RNA in both A. Ablpictus cells 3 days after Sindbis virus infection and previously uninfected mosquito cells. These results suggested that at 3 days after infection with Sindbis virus, mosquito cells restricted the replication of both homologous and heterologous alphaviruses but remained susceptible to infection with a bunyavirus. In superinfection experiments the the alphaviruses were differentiated on the basis of plaque morphology and the electrophoretic mobility of their intracellular 26S viral RNA species. Thus, it was shown that within 1 h after infection with eigher Sindbis or Chikungunya virus, A. albopictus cells were resistant to superinfection with Sindbis, Chikungunya, Una, and Semliki Forest viruses. Infected cultures were resistant to superinfection with the homologous virus indefinitely, but maximum resistance to superinfection with heterologous alphaviruses lasted for approximately 8 days. After that time, infected cultures supported the replication of heterologous alphaviruses to the same extent as did persistently infected cultures established months previously. However, the titer of heterologous alphavirus produced after superinfection of persistently infected cultures was 10- to 50-fold less than that produced by an equal number of previously uninfected A. albopictus cells. Only a small proportion (8 to 10%) of the cells in a persistently infected culture was capable of supporting the replication of a heterologous alphavirus.

Synthesis of alphavirus-specified RNA

UV irradiation of chicken fibroblasts infected with Semliki Forest or Sindbis virus has been used to investigate the mechanism of synthesis of 42S and 26S RNA, the major plus-strand virus-specified RNAs formed during the multiplication of standard virus particles. From an analysis of the kinetics of UV inactivation of the synthesis of these two RNAs, we conclude (i) that 26S RNA is formed by internal transcriptive initiation from a point about two-thirds of the way from the 3' end of the 42S negative-strand template; (ii) that there exists a population of plus-strand synthesizing complexes whose members are each capable of synthesizing both 42S and 26S RNA; and (iii) that, on a time-averaged basis, each complex in wild-type virus-infected cells contains one virus polymerase mediating 42S RNA synthesis and three mediating 26S RNA synthesis. The RNA phenotypes of 15 RNA(-)ts mutants of Sindbis virus have been examined after temperature shift to the restrictive temperature. Under these conditions, cells infected with three mutants, N2, N7, and E268, synthesized four to six times as much 42S RNA (relative to 26S RNA) as wild-type virus-infected cells. These studies were extended by examining, in detail, the RNA and polypeptide phenotypes of mutants N2 and E268. These experiments showed that, in N2- and E268-infected cells, one of the virus-specified nonstructural (NS) polypeptides (NS p89; H. Brzeski and S. I. T. Kennedy, J. Virol. 22:420-429, 1977) is thermolabile after shift up to restrictive temperature. This finding, together with the observation that, after shift, the 26S/42S RNA ratio in N2-infected cells changes markedly in favor of 42S RNA synthesis, leads us to conclude that, of the three NS polypeptides, NS p89 modulates 26S RNA synthesis.

Mechanism for control of synthesis of Semliki Forest virus 26S and 42s RNA

When cells infected with the Semliki Forest virus (SFV) mutant ts-4 were shifted to the nonpermissive temperature, synthesis of 26S RNA ceased, whereas synthesis of 42S RNA continued normally. These two single-stranded SFV RNAs are synthesized in two types of replicative intermediate (RI), 26S RNA in RI(b) and 42S RNA in RI(a). Cessation of 26S RNA synthesis after shift up in temperature was accompanied by loss of RI(b). When infected cells were shifted back down to 27 degrees C, 26S RNA synthesis resumed, coincident with the reappearance of RI(b). In both types of RI, the 42S minus-strand RNA is template for synthesis of plus-strand RNA. In pulse-chase experiments, we obtained RIs labeled only in their minus-strand RNA, and thus could follow the fate of RIs assembled at 27 degrees C when they were shifted to 39 degrees C. Our results show that, after shift up to 39 degrees C, there was a quantitative conversion of RIs in which 26S RNA had been synthesized to RIs in which 42S RNA was synthesized. This conversion of RI(b) to RI(a) was reversible, since RIs in which 26S RNA was synthesized reappeared when the infected cultures were shifted back down to 27 degrees C. We propose that, associated with RI(b), in which 26S RNA is synthesized, there is a virus-specific protein that functions to promote initiation of 26S RNA transcription at an internal site on the 42S minus-strand RNA and to block transcription on the minus strand in this region by the SFV RNA polymerase that had bound and was copying the minus-strand RNA from its 3' end. A ribonuclease-sensitive region would thus result in the sequence adjacent to the one that was complementary to 26S RNA. This virus-specific protein is not a component of the SFV RNA polymerase that continues to transcribe 42S RNA, and it is temperature sensitive in ts-4 mutant-infected cells. When this virus-specific protein is not present on RIs, the SFV polymerase transcribes the whole 42S minus-strand RNA and yields 42S plus-strand RNA.

Free and membrane-bound polyribosomes in BHK cells infected with Sindbis virus

The data presented in the paper demonstrate that in BHK cells infected with Sindbis virus virtually all the 42S mRNA not in nucleocapsid is associated with free polyribosomes, whereas the 26S mRNA is distributed between free and membrane-bound polyribosomes. We suggest that the 26S RNA polyribosomes are bound to the membranes through the nascent chains of the B1 protein and that a large percentage of 26S RNA polyribosomes free in the cytoplasm may be due to the small amount of rough endoplasmic reticulum in BHK cells. In addition, we found that intracellular nucleocapsid is in the nonmembrane fraction of the cytoplasm of infected cells.