Sindbis virus RNA-negative mutants that fail to convert from minus-strand to plus-strand synthesis: role of the nsP2 protein.

We identified mutations in the gene for nsP2, a nonstructural protein of the alphavirus Sindbis virus, that appear to block the conversion of the initial, short-lived minus-strand replicase complex (RCinitial) into mature, stable forms that are replicase and transcriptase complexes (RCstable), producing 49S genome or 26S mRNA. Base changes at nucleotide (nt) 2166 (G-->A, predicting a change of Glu-163-->Lys), at nt 2502 (G-->A, predicting a change of Val-275-->Ile), and at nt 2926 (C-->U, predicting a change of Leu-416-->Ser) in the nsP2 N domain were responsible for the phenotypes of ts14, ts16, and ts19 members of subgroup 11 (D.L. Sawicki and S.G. Sawicki, Virology 44:20-34, 1985) of the A complementation group of Sindbis virus RNA-negative mutants. Unlike subgroup I mutants, the RCstable formed at 30 degrees C transcribed 26S mRNA normally and did not synthesize minus strands in the absence of protein synthesis after temperature shift. The N-domain substitutions did not inactivate the thiol protease in the C domain of nsP2 and did not stop the proteolytic processing of the polyprotein containing the nonstructural proteins. The distinct phenotypes of subgroup I and 11 A complementation group mutants are evidence that the two domains of nsP2 are essential and functionally distinct. A detailed analysis of ts14 found that its nsPs were synthesized, processed, transported, and assembled at 40 degrees C into complexes with the properties of RCinitial and synthesized minus strands for a short time after shift to 40 degrees C. The block in the pathway to the formation of RCstable occurred after cleavage of the minus-strand replicase P123 or P23 polyprotein into mature nsP1, nsP2, nsP3, and nsP4, indicating that structures resembling RCstable, were formed at 40 degrees C. However, these RCstable or pre-RCstable structures were not capable of recovering activity at 30 degrees C. Therefore, failure to increase the rate of plus-strand synthesis after shift to 40 degrees C appears to result from failure to convert RCinitial to RCstable. We conclude that RCstable is derived from RCinitial by a conversion process and that ts14 is a conversion mutant. From their similar phenotypes, we predict that other nsP2 N-domain mutants are blocked also in the conversion of RCinitial to RCstable. Thus, the N domain of nsP2 plays an essential role in a folding pathway of the nsPs responsible for formation of the initial minus-strand replicase and for its conversion into stable plus-strand RNA-synthesizing enzymes.