ABSTRACT
We report the construction and characterization of deletion mutants in the herpes simplex virus type 1 gene encoding the immediate-early protein ICP0. In the event that ICP0 proved to play an essential role in virus replication, ICP0-transformed Vero cells were generated to serve as permissive hosts for such mutants. Two mutants, dlX0.7 and dlX3.1, were isolated in these cells by a marker rescue-transfer procedure involving the rescue of an ICP4 deletion mutant and the simultaneous insertion of a linked deletion in the ICP0 gene. Mutant dlX0.7 contained a 700-base-pair deletion in both copies of ICP0. The deletion lay entirely within the transcript specified by the gene. dlX0.7 induced the synthesis of an ICP0-specific mRNA that was approximately 0.7 kilobases smaller than the corresponding mRNA specified by wild-type virus. The 3.1-kilobase deletion in both copies of the ICP0 gene in mutant dlX3.1 removed the majority of the transcriptional-regulatory signals and coding sequences, retaining only sequences at the 3' end of the gene. As expected, no ICP0-specific mRNA was detected in dlX3.1-infected Nero cells (G418-resistant Vero cells). Both mutants grew in all cells tested, although their burst sizes were 10- to 100-fold lower than that of wild-type virus. Although the plaque sizes of dlX0.7 and dlX3.1 were equally small on Nero and ICP0-transformed cells, the plating efficiency of the mutants was 15- to 50-fold greater on ICP0-transformed cells than on Nero cells. The mutants exhibited modest interference with the growth of wild-type virus in mixed infections, an effect that was abolished by UV irradiation of the mutants, implying that interference required viral gene expression. Polypeptide profiles generated by the mutants in Nero cells were qualitatively similar to that of wild-type virus. Quantitatively, only slight reductions in the levels of certain late viral polypeptides were observed, a phenomenon also borne out by analysis of viral glycoproteins. Both mutants induced the synthesis of significant, although reduced, levels of viral DNA relative to wild-type virus. Taken together, the results demonstrate that ICP0 is not essential for productive infection in cell culture but that this protein plays a significant role in viral growth, as indicated by the impaired abilities of the mutants to replicate.
