A conditional-lethal murine coronavirus mutant that fails to incorporate the spike glycoprotein into assembled virions.

The coronavirus spike glycoprotein (S) mediates both the attachment of virus to the host cell receptor and membrane fusion. We describe here the characterization of a temperature-sensitive mutant of the coronavirus mouse hepatitis virus A59 (MHV-A59) having multiple S protein-related defects. The most remarkable of these was that the mutant, designated Albany 18 (Alb18), assembled virions devoid of the S glycoprotein at the nonpermissive temperature. Alb18 also failed to bring about syncytia formation in cells infected at the nonpermissive temperature. Virions of the mutant assembled at the permissive temperature were much more thermolabile than wild type. Moreover, mutant S protein that was incorporated into virions at the permissive temperature showed enhanced pH-dependent thermolability in its ability to bind to the MHV receptor. Alb18 was found to have a single point mutation in S resulting in a change of serine 287 to isoleucine, and it was shown by revertant analysis that this was the lesion responsible for the phenotype of the mutant.

Construction of a mouse hepatitis virus recombinant expressing a foreign gene.

The genome of the coronavirus mouse hepatitis virus (MHV) contains genes which have been shown to be nonessential for viral replication and which could, in principle, be used as sites for the introduction of foreign sequences. We have inserted heterologous genetic material into gene 4 of MHV in order (i) to test the applicability of targeted RNA recombination for site-directed mutagenesis of the MHV genome upstream of the N gene; (ii) to develop further genetic tools for mutagenesis of structural genes other than N; and (iii) to examine the feasibility of using MHV as an expression vector. A DI-like donor RNA vector containing the MHV S gene and all genes distal to S was constructed. Initially, a derivative of this was used to insert a 19-nucleotide tag into the start of ORF 4a of MHV-A59 using the N gene deletion mutant A1b4 as the recipient virus. Subsequently, the entire gene for the green fluorescent protein (GFP) was inserted in place of gene 4. This heterologous gene was shown to be expressed by recombinant viruses but not at levels sufficient to allow detection of fluorescence of viral plaques. Northern blot analysis of transcripts of GFP recombinants showed the expected displacement of the mobility, relative to those of wild-type, of all subgenomic mRNAs larger than mRNA5. An unexpected result of the Northern analysis was the observation that GFP recombinants also produced an RNA species the same size as that of wild-type mRNA4. RT-PCR analysis of the 5' end of this species revealed that it was actually a collection of mRNAs originating from a cluster of 10 different sites, none of which possessed a canonical intergenic sequence. The finding of these aberrant mRNAs, all of nearly the same size as wild-type mRNA4, suggests that long range structure of the MHV genome can sometimes be the sole determinant of the site of initiation of transcription.

Site-directed mutagenesis of the genome of mouse hepatitis virus by targeted RNA recombination.

We have genetically characterized a nucleocapsid (N) protein mutant of the coronavirus mouse hepatitis virus (MHV). This mutant, designated Alb4, is both temperature-sensitive and thermolabile, and its N protein is smaller than wild-type N. Sequence analysis of the Alb4 N gene revealed that it contains an internal deletion of 87 nucleotides, producing an in-frame deletion of 29 amino acids. All of these properties of Alb4 made it ideal for use as a recipient in a targeted RNA recombination experiment in which the deletion in Alb4 was repaired by recombination with synthetic RNA7, the smallest MHV subgenomic mRNA. Progeny from a cotransfection of Alb4 genomic RNA and synthetic RNA7 were selected for thermal stability. PCR analysis of candidate recombinants showed that they had regained the material that is deleted in the Alb4 mutant. They also had acquired a five nucleotide insertion in the 3' untranslated region, which had been incorporated into the synthetic RNA7 as a molecular tag. The presence of the tag was directly verified, as well, by sequencing the genomic RNA of purified recombinant viruses. This provided a clear genetic proof that the Alb4 phenotype was due to the observed deletion in the N gene. In addition, these results demonstrated that it is possible to obtain stable, independently replicating progeny from recombination between coronaviral genomic RNA and a tailored, synthetic RNA species. To date, we have constructed three additional mutants by this procedure. For two of these, a second-site point mutation that reverts the Alb4 phenotype has been transduced into a wild type background, which does not contain the Alb4 deletion.(ABSTRACT TRUNCATED AT 250 WORDS)

Analysis of second-site revertants of a murine coronavirus nucleocapsid protein deletion mutant and construction of nucleocapsid protein mutants by targeted RNA recombination.

The Alb4 mutant of the coronavirus mouse hepatitis virus (MHV) is both temperature sensitive and thermolabile owing to a deletion in the gene encoding its nucleocapsid (N) protein. The deletion removes 29 amino acids that constitute a putative spacer region preceding the carboxyl-terminal domain of the protein. As a step toward understanding the structure and function of the MHV N protein, we isolated multiple independent revertants of Alb4 that totally or partially regained the ability to form large (wild-type-sized) plaques at the nonpermissive temperature. The N proteins of these revertant viruses concomitantly regained the ability to bind to RNA in vitro at a temperature that was restrictive for RNA binding by Alb4 N protein. Sequence analysis of the N genes of the revertants revealed that each contained a single second-site point mutation that compensated for the effects of the deletion. All reverting mutations were clustered within a stretch of 40 amino acids centered some 80 residues on the amino side of the Alb4 deletion, within a domain to which the RNA-binding activity of N had been previously mapped. By means of a targeted RNA recombination method that we have recently developed, two of the reverting mutations were introduced into a wild-type MHV genomic background. The resulting recombinants were stable and showed no gross phenotypic differences from the wild type. A detailed analysis of one, however, revealed that it was at a selective disadvantage with respect to the wild type.

Analysis of a recombinant mouse hepatitis virus expressing a foreign gene reveals a novel aspect of coronavirus transcription.

We have inserted heterologous genetic material into the nonessential gene 4 of the coronavirus mouse hepatitis virus (MHV) in order to test the applicability of targeted RNA recombination for site-directed mutagenesis of the MHV genome upstream of the nucleocapsid (N) gene and to develop further genetic tools for site-directed mutagenesis of structural genes other than N. Initially, a 19-nucleotide tag was inserted into the start of gene 4a of MHV strain A59 with the N gene deletion mutant Alb4 as the recipient virus. In further work, the entire gene for the green fluorescent protein (GFP) was inserted in place of gene 4, creating the currently largest known RNA virus. The expression of GFP was demonstrated by Western blot analysis of infected cell lysates; however, the level of GFP expression was not sufficient to allow detection of fluorescence of viral plaques. Northern blot analysis of transcripts of GFP recombinants showed the expected alteration of the pattern of the nested MHV subgenomic mRNAs. Surprisingly, though, GFP recombinants also produced an RNA species that was the same size as wild-type mRNA4. Analysis of the 5' end of this species revealed that it was actually a collection of mRNAs originating from 10 different genomic fusion sites, none possessing a canonical intergenic sequence. The finding of these aberrant mRNAs suggests that long-range RNA or the ribonucleoprotein structure of the MHV genome can sometimes be the sole determinant of the site of initiation of transcription.

Optimization of targeted RNA recombination and mapping of a novel nucleocapsid gene mutation in the coronavirus mouse hepatitis virus.

We have recently described a method of introducing site-specific mutations into the genome of the coronavirus mouse hepatitis virus (MHV) by RNA recombination between cotransfected genomic RNA and a synthetic subgenomic mRNA (C. A. Koetzner, M. M. Parker, C. S. Ricard, L. S. Sturman, and P. S. Masters, J. Virol. 66:1841-1848, 1992). By using a thermolabile N protein mutant of MHV (Alb4) as the recipient virus and synthetic RNA7 (the mRNA for the nucleocapsid protein N) as the donor, we selected engineered recombinant viruses as heat-stable progeny resulting from cotransfection. We have now been able to greatly increase the efficiency of targeted recombination in this process by using a synthetic defective interfering (DI) RNA in place of RNA7. The frequency of recombination is sufficiently high that, with Alb4 as the recipient, recombinants can be directly identified without using thermal selection. The synthetic DI RNA has been used to demonstrate that the lesion in another temperature-sensitive and thermolabile MHV mutant, Alb1, maps to the N gene. Sequencing of the Alb1 N gene revealed two closely linked point mutations that fall in a region of the N molecule previously noted as being the most highly conserved region among all of the coronavirus N proteins. Analysis of revertants of the Alb1 mutant revealed that one of the two mutations is critical for the temperature-sensitive phenotype; the second mutation is phenotypically silent.

Construction of murine coronavirus mutants containing interspecies chimeric nucleocapsid proteins.

Targeted RNA recombination was used to construct mouse hepatitis virus (MHV) mutants containing chimeric nucleocapsid (N) protein genes in which segments of the bovine coronavirus N gene were substituted in place of their corresponding MHV sequences. This defined portions of the two N proteins that, despite evolutionary divergence, have remained functionally equivalent. These regions included most of the centrally located RNA-binding domain and two putative spacers that link the three domains of the N protein. By contrast, the amino terminus of N, the acidic carboxy-terminal domain, and a serine- and arginine-rich segment of the central domain could not be transferred from bovine coronavirus to MHV, presumably because these parts of the molecule participate in protein-protein interactions that are specific for each virus (or, possibly, each host). Our results demonstrate that targeted recombination can be used to make extensive substitutions in the coronavirus genome and can generate recombinants that could not otherwise be made between two viruses separated by a species barrier. The implications of these findings for N protein structure and function as well as for coronavirus RNA recombination are discussed.

Repair and mutagenesis of the genome of a deletion mutant of the coronavirus mouse hepatitis virus by targeted RNA recombination.

The genetic characterization of a nucleocapsid (N) protein mutant of the coronavirus mouse hepatitis virus (MHV) is described. The mutant, Albany 4 (Alb4), is both temperature sensitive and thermolabile. Analysis of the progeny of a mixed infection showed that the defective Alb4 allele is recessive to wild type, and its gene product is diffusible. The N protein of Alb4 was found to be smaller than its wild-type counterpart, and sequence analysis of the Alb4 N gene revealed that it contains an internal deletion of 87 nucleotides, producing an in-frame deletion of 29 amino acids. All of these properties of Alb4 made it ideal for use as a recipient in a targeted RNA recombination experiment in which the deletion in Alb4 was repaired by recombination with synthetic RNA7, the smallest MHV subgenomic mRNA. Progeny from a cotransfection of Alb4 genomic RNA and synthetic RNA7 were selected for thermal stability. Polymerase chain reaction analysis of candidate recombinants showed that they had regained the material that is deleted in the Alb4 mutant. They also had acquired a five-nucleotide insertion in the 3' untranslated region, which had been incorporated into the synthetic RNA7 as a molecular tag. The presence of the tag was directly verified, as well, by sequencing the genomic RNA of purified recombinant viruses. This provided a clear genetic proof that the Alb4 phenotype was due to the observed deletion in the N gene. In addition, these results demonstrated that it is possible to obtain stable, independently replicating progeny from recombination between coronavirus genomic RNA and a tailored, synthetic RNA species.