Identification and characterization of a small modular domain in the herpes simplex virus host shutoff protein sufficient for interaction with VP16.

The herpes simplex virus transactivator VP16 and the virion host shutoff protein vhs are viral structural components that direct the activation of immediate-early gene expression and the arrest of host protein synthesis, respectively, during an infection. Recent studies show that VP16 and vhs physically interact with each other in vitro and in infected cells, suggesting that their respective regulatory functions are coupled. In this report, we used the yeast two-hybrid system and affinity chromatography with purified VP16 fusion proteins to precisely map a region in vhs that directs interaction with VP16. Deletion analysis of vhs demonstrated that a 21-amino-acid-long domain spanning residues 310 to 330 (PAAGGTEMRVSWTEILTQQIA) was sufficient for directing complex formation with VP16 in vivo and in vitro when fused to a heterologous protein. Site-directed mutagenesis of this region identified tryptophan 321 as a crucial determinant for interaction with VP16 in vitro and in vivo and additional residues that are important for stable complex formation in vitro. These findings indicate that vhs residues 310 to 330 constitute an independent and modular binding interface that is recognized by VP16.     

Role of the VP16-binding domain of vhs in viral growth, host shutoff activity, and pathogenesis

The virion host shutoff (vhs) protein of herpes simplex virus type 1 causes the degradation of host and viral mRNA immediately upon infection of permissive cells. vhs can interact with VP16 through a 20-amino-acid binding domain, and viruses containing a deletion of this VP16-binding domain of vhs (Delta20) and a corresponding marker rescue (Delta20R) were constructed and characterized. Transient-transfection assays showed that this domain was dispensable for vhs activity. The Delta20 recombinant virus, however, was unable to induce mRNA degradation in the presence of actinomycin D, while degradation induced by Delta20R was equivalent to that for wild-type virus. Delta20, Delta20R, and KOS caused comparable RNA degradation in the absence of actinomycin D. Western blot analysis of infected cells indicated that comparable levels of vhs were expressed by Delta20, Delta20R, and KOS, and there was only a modest reduction of vhs packaging in Delta20. Immunoprecipitation of protein from cells infected with Delta20 and Delta20R showed equivalent coprecipitation of vhs and VP16. Pathogenesis studies with Delta20 showed a significant decrease in replication in the corneas, trigeminal ganglia, and brains, as well as a significant reduction in clinical disease and lethality, but no significant difference in the establishment of, or reactivation from, latency compared to results with KOS and Delta20R. These results suggest that the previously described VP16-binding domain is not required for vhs packaging or for binding to VP16. It is required, however, for RNA degradation activity of tegument-derived vhs and wild-type replication and virulence in mice.     

Control of mRNA stability by the virion host shutoff function of herpes simplex virus

vhs1 is a mutant of herpes simplex virus type 1 that is defective in the virion host shutoff function responsible for the degradation of cellular mRNAs and the concomitant shutoff of host protein synthesis. In this study, the effect of the vhs1 mutation on the metabolism of viral mRNAs was examined by measuring the half-lives and patterns of accumulation of 10 different viral mRNAs representing all kinetic classes. The vhs1 mutation had the effect of dramatically lengthening the cytoplasmic half-lives of all 10 mRNAs. In wild-type virus infections, the 10 mRNAs had similar half-lives, suggesting that little, if any, target mRNA selectivity was exhibited by the vhs function. The vhs1 mutation caused overaccumulation of a number of mRNAs. The effect was most dramatic for the alpha (immediate-early) mRNA for ICP27 and the beta (early) mRNAs encoding thymidine kinase, ICP8, and DNA polymerase. Whereas in wild-type infections these mRNAs increased to peak levels and subsequently declined in abundance, in vhs1 infections they continued to accumulate until late times. A significant but less dramatic overaccumulation was observed for several beta-gamma (delayed-early) and gamma (late) mRNAs. The results suggest that the vhs protein plays an important role in determining the half-lives of viral mRNAs belonging to all kinetic classes and in so doing is important in the normal downregulation at late times of alpha and beta gene expression.     

Disruption of virion host shutoff activity improves the immunogenicity and protective capacity of a replication-incompetent herpes simplex virus type 1 vaccine strain

The virion host shutoff (vhs) protein encoded by herpes simplex virus type 1 (HSV-1) destabilizes both viral and host mRNAs. An HSV-1 strain with a mutation in vhs is attenuated in virulence and induces immune responses in mice that are protective against corneal infection with virulent HSV-1, but it has the capacity to establish latency. Similarly, a replication-incompetent HSV-1 strain with a mutation in ICP8 elicits an immune response protective against corneal challenge, but it may be limited in viral antigen production. We hypothesized therefore that inactivation of vhs in an ICP8(-) virus would yield a replication-incompetent mutant with enhanced immunogenicity and protective capacity. In this study, a vhs(-)/ICP8(-) HSV-1 mutant was engineered. BALB/c mice were immunized with incremental doses of the vhs(-)/ICP8(-) double mutant or vhs(-) or ICP8(-) single mutants, or the mice were mock immunized, and protective immunity against corneal challenge with virulent HSV-1 was assessed. Mice immunized with the vhs(-)/ICP8(-) mutant showed prechallenge serum immunoglobulin G titers comparable to those immunized with replication-competent vhs(-) virus and exceed those of mice immunized with the ICP8(-) single mutant. Following corneal challenge, the degrees of protection against ocular disease, weight loss, encephalitis, and establishment of latency were similar for vhs(-)/ICP8(-) and vhs(-) virus-vaccinated mice. Moreover, the double deleted vhs(-)/ICP8(-) virus protected mice better in all respects than the single deleted ICP8(-) mutant virus. The data indicate that inactivation of vhs in a replication-incompetent virus significantly enhances its protective efficacy while retaining its safety for potential human vaccination. Possible mechanisms of enhanced immunogenicity are discussed.     

Selective ablation of virion host shutoff protein RNase activity attenuates herpes simplex virus 2 in mice

The virion host shutoff (vhs) protein of herpes simplex virus (HSV) has endoribonuclease activity and rapidly reduces protein synthesis in infected cells through mRNA degradation. Herpes simplex virus 1 (HSV-1) and HSV-2 vhs mutants are highly attenuated in vivo, but replication and virulence are largely restored to HSV-2 vhs mutants in the absence of a type I interferon (IFN) response. The role of vhs in pathogenesis and the hindrance of the type I IFN response have classically been examined with viruses that completely lack vhs or express a truncated vhs protein. To determine whether RNase activity is the principal mechanism of vhs-mediated type I IFN resistance and virulence, we constructed a HSV-2 point mutant that synthesizes full-length vhs protein lacking RNase activity (RNase(-) virus). Wild-type and mutant HSV-2 vhs proteins coimmunoprecipitated with VP16 and VP22. vhs protein bearing the point mutation was packaged into the virion as efficiently as the wild-type vhs protein. Like a mutant encoding truncated vhs, the RNase(-) virus showed IFN-dependent replication that was restricted compared with that of the wild-type virus. The RNase(-) virus was highly attenuated in wild-type mice infected intravaginally, with reduced mucosal replication, disease severity, and spread to the nervous system comparable to those of the vhs truncation mutant. Surprisingly, in alpha/beta interferon (IFN-alpha/beta) receptor knockout mice, the vhs RNase mutant was more attenuated than the vhs truncation mutant in terms of disease severity and virus titer in vaginal swabs and central nervous system samples, suggesting that non-enzymatically active vhs protein interferes with efficient virus replication. Our results indicate that vhs enzymatic activity plays a complex role in vhs-mediated type I IFN resistance during HSV-2 infection.     

Replication-competent herpes simplex virus 1 isolates selected from cells transfected with a bacterial artificial chromosome DNA lacking only the UL49 gene vary with respect to the defect in the UL41 gene encoding host shutoff RNase

To generate a null U(L)49 gene mutant of herpes simplex virus 1 (HSV-1), we deleted from the viral DNA, encoded as a bacterial artificial chromosome (BAC), the U(L)49 open reading frame and, in a second step, restored it. Upon transfection into Vero cells, the BAC-DeltaU(L)49 DNA yielded foci of degenerated cells that could not be expanded and a few replication-competent clones. The replication-competent viral clones derived from independent transfections yielded viruses that expressed genes with some delay, produced smaller plaques, and gave lower yields than wild-type virus. A key finding is that the independently derived replication-competent viruses lacked the virion host shutoff (vhs) activity expressed by the RNase encoded by the U(L)41 gene. One mutant virus expressed no vhs protein, whereas two others, derived from independent transfections, produced truncated vhs proteins consistent with the spontaneous in-frame deletion. In contrast, cells infected with the virus recovered upon transfection of the BAC-U(L)49R DNA (R-U(L)49) accumulated a full-length vhs protein, indicating that in the parental BAC-DeltaU(L)49 DNA, the U(L)41 gene was intact. We conclude that expression of the vhs protein in the absence of U(L)49 protein is lethal, a conclusion bolstered by the evidence reported elsewhere that in transfected cells vhs requires both VP16 and VP22, the product of U(L)49, to be neutralized.     

The vhs1 mutant form of herpes simplex virus virion host shutoff protein retains significant internal ribosome entry site-directed RNA cleavage activity

The virion host shutoff (vhs) protein of herpes simplex virus (HSV) triggers global shutoff of host protein synthesis and accelerated turnover of host and viral mRNAs during HSV infection. As well, it induces endoribonucleolytic cleavage of RNA substrates when produced in a rabbit reticulocyte lysate (RRL) in vitro translation system. The vhs1 point mutation (Thr 214-->Ile) eliminates vhs function during virus infection and in transiently transfected mammalian cells and was therefore previously considered to abolish vhs activity. Here we demonstrate that the vhs1 mutant protein induces readily detectable endoribonuclease activity on RNA substrates bearing the internal ribosome entry site of encephalomyocarditis virus in the RRL assay system. These data document that the vhs1 mutation does not eliminate catalytic activity and raise the possibility that the vhs-dependent endoribonuclease employs more than one mode of substrate recognition.     

Mutational analysis of the herpes simplex virus virion host shutoff protein: evidence that vhs functions in the absence of other viral proteins.

Herpes simplex virus (HSV) virions contain one or more factors that trigger rapid shutoff of host protein synthesis and accelerated decay of cellular and viral mRNAs in infected cells. HSV isolates bearing mutations at the virion host shutoff (vhs) locus (gene UL41) are defective for both processes, indicating that the vhs protein is required; however, it is not clear whether the role of vhs in shutoff is direct or indirect and if other virion components are also necessary. We therefore used a transient-cotransfection assay to determine if the vhs protein displays activity in the absence of other viral gene products. We found that a vhs expression vector strongly suppressed expression of a cotransfected lacZ reporter gene and that this effect was eliminated by the vhs1 point mutation that abolishes virion-induced host shutoff during HSV infection. Further evidence for the biological relevance of the transfection assay came from the demonstration that five vhs in-frame linker insertion mutations yielded concordant results when assayed in cotransfected cells and following transfer into the viral genome: three mutations eliminated activity in both assays, while two had no effect. On the basis of these results, we conclude that the vhs protein can trigger host shutoff in the absence of other HSV proteins. The cotransfection assay was used to rapidly assess the activities of a panel of linker insertion mutants spanning the vhs polypeptide. All mutations that mapped to regions conserved among the vhs homologs of alphaherpesvirus inactivated function; in contrast, four of five mutations that mapped to regions that are absent from several vhs homologs had no effect. These results further support the biological relevance of the transfection assay and begin to delineate functional domains of the vhs polypeptide.