Tryptic peptide mapping of the nonstructural proteins of Semliki Forest virus and their precursors

Functions of alphavirus nonstructural proteins in RNA replication

Alphaviruses are enveloped positive-strand RNA viruses transmitted to vertebrate hosts by mosquitoes. Several alphaviruses are pathogenic to humans or domestic animals, causing serious central nervous system infections or milder infections, for example, arthritis, rash, and fever. The structure and replication of Semliki Forest virus (SFV) and Sindbis virus (SIN) have been studied extensively during the past 30 years. Alphaviruses have been important probes in cell biology to study the translation, glycosylation, folding, and transport of membrane glycoproteins, as well as endocytosis and membrane fusion mechanisms. A new organelle, the intermediate compartment, operating between the endoplasmic retieulum and the Golgi complex has been found by the aid of SFV. During the past 10 years, alphavirus replicons have been increasingly used as expression vectors for basic research, for the generation of vaccines, and for the production of recombinant proteins in industrial scale. The main approaches of laboratories in the recent years have been twofold. On one hand, they have discovered and characterized the enzymatic activities of the individual replicase proteins and on the other hand, they have studied the localization, membrane association, and other cell biological aspects of the replication complex.

Proteolytic processing of Semliki Forest virus-specific non-structural polyprotein by nsP2 protease

The RNA replicase proteins of Semliki Forest virus (SFV) are translated as a P1234 polyprotein precursor that contains two putative autoproteases. Point mutations introduced into the predicted active sites of both proteases nsP2 (P2) and nsP4 (P4), separately or in combination, completely abolished virus replication in mammalian cells. The effects of these mutations on polyprotein processing were studied by in vitro translation and by expression of wild-type polyproteins P1234, P123, P23, P34 and their mutated counterparts in insect cells using recombinant baculoviruses. A mutation in the catalytic site of the P2 protease, C(478)A, (P2(CA)) completely abolished the processing of P12(CA)34, P12(CA)3 and P2(CA)3. Co-expression of P23 and P12(CA)34 in insect cells resulted in in trans cleavages at the P2/3 and P3/4 sites. Co-expression of P23 and P34 resulted in cleavage at the P3/4 site. In contrast, a construct with a mutation in the active site of the putative P4 protease, D(6)A, (P1234(DA)) was processed like the wild-type protein. P34 or its truncated forms were not processed when expressed alone. In insect cells, P4 was rapidly destroyed unless an inhibitor of proteosomal degradation was used. It is concluded that P2 is the only protease needed for the processing of SFV polyprotein P1234. Analysis of the cleavage products revealed that P23 or P2 could not cleave the P1/2 site in trans.

The Semliki-Forest-virus-specific nonstructural protein nsP4 is an autoproteinase

The Semliki-Forest-virus-specific nonstructural proteins are translated as a large polyprotein (2431 amino acid residues), from which the mature polymerase components nsP1, nsP2, and nsP4 are released by proteolytic cleavages. The complete ns polyprotein (P1234) can be cleaved in two alternative ways yielding either P123 (with sequences of nsP1, nsP2 and nsP3) and nsP4 or P12 (nsP1 plus nsP2) and P34 (nsP3 plus nsP4). We studied the possible autoproteolytic role of nsP4 involved in the cleavage between nsP3 and nsP4 in an in vitro transcription-translation system. cDNAs encoding P34 precursor and shorter precursor protein segments covering the nsP3-nsP4 cleavage region, were cloned under the T7 RNA polymerase promoter. The mRNAs synthesized in vitro were capped and translated in rabbit reticulocyte lysates. The translational products were analyzed by SDS/PAGE. The precursor proteins containing nsP4 sequences were cleaved yielding the products with expected sizes, indicating that the cleavage took place at the nsP3-nsP4 junction. By deleting and truncating the cDNA coding for nsP4, the proteolytic activity was mapped within the 102 amino-terminal amino acids of nsP4. The cleavage between nsP3 and nsP4 can be inhibited by pepstatin A and probably takes place in cis, since exogenously added nsP4 was unable to mediate it.

Nonstructural proteins of Semliki Forest virus: synthesis, processing, and stability in infected cells

The synthesis of the nonstructural (ns) proteins of Semliki Forest virus was studied in vivo. The fourth ns protein, ns60, was identified and isolated. The order of translation (NH2-ns70-ns86-ns60-ns72-COOH) was determined by using various labeling procedures after or in the presence of a hypertonic block of translation initiation. A sequential labeling procedure was devised to specifically label defined segments of the polyprotein. The specific labeling procedures allowed isolation of the four ns proteins in radiochemically pure form by gradient polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The four ns proteins were shown to have different primary structures by digestion with V8 protease of Staphylococcus aureus. The processing of the ns polyprotein and the stability of the mature ns proteins were studied by pulse-chase experiments. The cleavage of each of the proteins from the polyprotein took place within 2 to 3 min after the translation of the polypeptide chain. The N-terminal protein, ns70, appeared in its mature form later than ns86, which follows it in the polyprotein, suggesting that ns70 undergoes a post-translational modification. The migration of the C-terminal protein, ns72, immediately after a pulse was slightly faster than after a chase, suggesting that ns72 also undergoes a post-translational modification other than a cleavage. The half-life of ns72 was shorter than that of the other ns proteins.

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.

Translational analysis of the killer-associated virus-like particle dsRNA genome of S. cerevisiae: M dsRNA encodes toxin

The M species (medium sized) dsRNA (1.1-1.4 x 10(6) daltons) isolated from a toxin-producing yeast killer strain (K+R+) and three related, defective interfering (suppressive) S species dsRNAs of the yeast killer-associated cytoplasmic multicomponent viral-like particle system were analyzed by in vitro translation in a wheat germ cell-free protein synthesis system. Heat-denatured M species dsRNA programmed the synthesis of two major polypeptides, M-P1 (32,000 daltons) and M-P2 (30,000 daltons). M-P1 has been shown by the criteria of proteolytic peptide mapping and cross-antigenicity to contain ihe 12,000 dalton polypeptide corresponding to the in vivo produced killer toxin, thus establishing thiat it is the M species dsRNA which carries the toxin gene. An M species dsRNA obtained from a neutral strain (K-R+) also programmed the in vitro synthesis of a polypeptide identical in molecular weight to M-P1, thus indicating that the cytoplasmic determinant of the mutant neutral phenotype is either a simple point mutation in the dsRNA toxin gene or a mutation in a dsRNA gene which is required for functional toxin production. In vitro translation of each of the three different suppressive S dsRNAs resulted in the production of a polypeptide (S-P1) of approximately 8000 daltons instead of the 32,000 dalton M-P1 polypeptide programmed by M dsRNA. This result is consistent with the heteroduplex analysis of these dsRNAs by Fried and Fink (1978), which shows retention of M dsRNA ends, accompanied by large internal deletions in each of the S dsRNAs translated.

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.