Herpes simplex virus virion host shutoff protein requires a mammalian factor for efficient in vitro endoribonuclease activity

The virion host shutoff protein (vhs) of herpes simplex virus (HSV) triggers global shutoff of host protein synthesis and accelerated mRNA turnover during virus infection and induces endoribonucleolytic cleavage of exogenous RNA substrates when it is produced in a rabbit reticulocyte (RRL) in vitro translation system. Although vhs induces RNA turnover in the absence of other HSV gene products, it is not yet known whether cellular factors are required for its activity. As one approach to addressing this question, we expressed vhs in the budding yeast Saccharomyces cerevisiae. Expression of vhs inhibited colony formation, and the severity of this effect varied with the carbon source. The biological relevance of this effect was assessed by examining the activity of five mutant forms of vhs bearing previously characterized in-frame linker insertions. The results indicated a complete concordance between the growth inhibition phenotype in yeast and mammalian host cell shutoff. Despite these results, expression of vhs did not trigger global mRNA turnover in vivo, and cell extracts of yeast expressing vhs displayed little if any vhs-dependent endoribonuclease activity. However, activity was readily detected when such extracts were mixed with RRL. These data suggest that the vhs-dependent endoribonuclease requires one or more mammalian macromolecular factors for efficient activity.     

Herpes simplex virus tegument protein VP22 contains an internal VP16 interaction domain and a C-terminal domain that are both required for VP22 assembly into the virus particle

Many steps along the herpesvirus assembly and maturation pathway remain unclear. In particular, the acquisition of the virus tegument is a poorly understood process, and the molecular interactions involved in tegument assembly have not yet been defined. Previously we have shown that the two major herpes simplex virus tegument proteins VP22 and VP16 are able to interact, although the relevance of this to virus assembly is not clear. Here we have constructed a number of recombinant viruses expressing N- and C-terminal truncations of VP22 and have used them to identify regions of the protein involved in its assembly into the virus structure. Analysis of the packaging of these VP22 variants into extracellular virions revealed that the C terminus of VP22 is absolutely required for this process, with removal of the C-terminal 89 residues abrogating its incorporation. However, while these 89 residues alone were sufficient for specific incorporation of small amounts of VP22 into the tegument, efficient packaging of VP22 to the levels of full-length protein required an additional 52 residues of the protein. Coimmunoprecipitation assays indicated that these 52 residues also contained the interaction domain for VP16. Furthermore, analysis of the subcellular localization of the mutant forms of VP22 revealed that only those truncations that were efficiently assembled formed characteristic cytoplasmic trafficking complexes, suggesting that these complexes may represent the cellular location for VP22 assembly into the virus. Taken together, these results suggest that there are two determinants involved in the packaging of VP22-a C-terminal domain and an internal VP16 interaction domain, both of which are required for the efficient recruitment of VP22 to sites of virus assembly.     

Herpes simplex virus type 1 and pseudorabies virus bind to a common saturable receptor on Vero cells that is not heparan sulfate.

Herpes simplex virus type 1 (HSV-1) and pseudorabies virus (PRV) infect different natural hosts but are very similar in structure, replicative cycle, and entry into cultured cells. We determined whether HSV-1 and PRV use the same cellular components during entry into Vero cells, which are highly susceptible to each virus but are not from native hosts for either. UV-inactivated virions of either HSV-1 or PRV could saturate cell surfaces to block infection of challenge HSV-1 or PRV. In the presence of saturating levels for infection of either virus, radiolabeled virus bound well and in a heparin-sensitive manner. This result shows that heparan sulfate proteoglycans on Vero cells are not the limiting cellular component. To identify the virus component required for blocking, we used an HSV-1 null mutant virus lacking gB, gD, or gH as blocking virus. Virions lacking gB were able to block infection of challenge virus to the same level as did virus containing gB. In contrast, virions lacking gD lost all and most of the ability to block infection of HSV-1 and PRV, respectively. HSV-1 lacking gH and PRV lacking gp50 also were less competent in blocking infection of challenge virus. We conclude that HSV-1 and PRV bind to a common receptor for infection of Vero cells. Although both viruses bind a heparin-like cell component on many cells, including Vero cells, they also attach to a different and limited cell surface component that is bound at least by HSV-1 gD and possibly gH and to some degree by PRV gp50 but not gB. These results clearly demonstrate binding of both HSV-1 and PRV to a common cell receptor that is not heparan sulfate and demonstrate that several types of attachment occur for both viruses during infectious entry.     

Herpes simplex virus gE/gI and US9 proteins promote transport of both capsids and virion glycoproteins in neuronal axons

Following reactivation from latency, alphaherpesviruses replicate in sensory neurons and assemble capsids that are transported in the anterograde direction toward axon termini for spread to epithelial tissues. Two models currently describe this transport. The Separate model suggests that capsids are transported in axons independently from viral envelope glycoproteins. The Married model holds that fully assembled enveloped virions are transported in axons. The herpes simplex virus (HSV) membrane glycoprotein heterodimer gE/gI and the US9 protein are important for virus anterograde spread in the nervous systems of animal models. It was not clear whether gE/gI and US9 contribute to the axonal transport of HSV capsids, the transport of membrane proteins, or both. Here, we report that the efficient axonal transport of HSV requires both gE/gI and US9. The transport of both capsids and glycoproteins was dramatically reduced, especially in more distal regions of axons, with gE(-), gI(-), and US9-null mutants. An HSV mutant lacking just the gE cytoplasmic (CT) domain displayed an intermediate reduction in capsid and glycoprotein transport. We concluded that HSV gE/gI and US9 promote the separate transport of both capsids and glycoproteins. gE/gI was transported in association with other HSV glycoproteins, gB and gD, but not with capsids. In contrast, US9 colocalized with capsids and not with membrane glycoproteins. Our observations suggest that gE/gI and US9 function in the neuron cell body to promote the loading of capsids and glycoprotein-containing vesicles onto microtubule motors that ferry HSV structural components toward axon tips.     

Herpes simplex virus phosphoproteins. II. Characterization of the virion protein kinase and of the polypeptides phosphorylated in the virion.

The protein kinase associated with purified herpes simplex virus 1 and 2 virions partitioned with the capsid-tegument structures and was not solubilized by non-ionic detergents and low, non-inhibitory concentrations of urea. The enzyme required Mg2+ or Mn2+ and utilized ATP or GTP. The activity was enhanced by non-ionic detergents and by Na+ even in the presence of high concentrations of of Mg2+, but not by cyclic nucleotides. The enzyme associated with capsid-tegument structures phosphorylated virion polypeptides only; exogenously added substrates (acidic and basic histones, casein, phosphovitin, protamine, and bovine serum albumin) were not phosphorylated. The major phosphorylated species were virion polypeptides (VP) 1-2, 4, 11-12, 13-14, 18.7, 18.8 and 23. VP 18.7 and VP 18.8 have not been previously detected, but may be phosphorylated forms of polypeptides co-migrating with VP 19. Of the remainder, only VP 23 has been previously identified as a capsid protein; the others are constituents of the tegument or of the under surface of the virion envelope. The distribution of the phosphate bound to viral polypeptides varied depending on the Mg2+ concentration and pH. In the absence of dithiothreitol, in vitro phosphate exchange was demonstrable in VP 23 and to a lesser extent in two other polypeptides on sequential phosphorylation frist with saturating amounts off unlabeled ATP and then with [gamma-32P]ATP. Analysis of the virion polypeptides specified by herpes simplex virus 1 X herpes simplex virus 2 recombinants indicates that the genes specifying the polypeptides which serve as a substrate for the protein kinase map in the unique sequences near the left and right reinterated DNA sequences of the L component.     

Herpes simplex virus type 1 targets the MHC class II processing pathway for immune evasion

HSV type 1 (HSV-1) has evolved numerous strategies for modifying immune responses that protect against infection. Important targets of HSV-1 infection are the MHC-encoded peptide receptors. Previous studies have shown that a helper T cell response and Ab production play important roles in controlling HSV-1 infection. The reduced capacity of infected B cells to stimulate CD4(+) T cells is beneficial for HSV-1 to evade immune defenses. We investigated the impact of HSV-1 infection on the MHCII processing pathway, which is critical to generate CD4(+) T cell help. HSV-1 infection targets the molecular coplayers of MHC class II processing, HLA-DR (DR), HLA-DM (DM), and invariant chain (Ii). HSV-1 infection strongly reduces expression of Ii, which impairs formation of SDS-resistant DR-peptide complexes. Residual activity of the MHC class II processing pathway is diminished by viral envelope glycoprotein B (gB). Binding of gB to DR competes with binding to Ii. In addition, we found gB associated with DM molecules. Both, gB-associated DR and DM heterodimers are exported from the endoplasmic reticulum, as indicated by carbohydrate maturation. Evaluation of DR, DM, and gB subcellular localization revealed abundant changes in intracellular distribution. DR-gB complexes are localized in subcellular vesicles and restrained from cell surface expression.     

A human protein specific for the immunoglobulin octamer DNA motif contains a functional homeobox domain

The homeobox domain is shared by Drosophila homeotic proteins, yeast mating type proteins, and some functionally uncharacterized mammalian proteins. A lymphoid-restricted human protein that binds to the immunoglobulin octamer regulatory motif was shown to contain an amino acid sequence that has 33% amino acid identity with the consensus sequence of the previously cloned homebox domains. This homeobox gene was localized to chromosome 19, thus mapping separately from other human homebox genes. A mutant protein containing amino acid substitutions within a putative helix-turn-helix motif in the homeobox domain did not bind DNA detectably. This human homeobox protein was shown to bind the same DNA sequence as the homeobox domains of the yeast mating type proteins and Drosophila homeotic protein, suggesting that homeobox proteins may have closely related DNA binding characteristics.     

A 165 kd protein of the herpes simplex virion shares a common epitope with the regulatory protein, ICP4

We have investigated the possibility that immediate-early (IE) protein ICP4 could be a part of herpes simplex virus type 1 (HSV-1) virion particle. Immunodetection with a monoclonal antibody against ICP4 reveals that a component of the virion, migrating at 165 kd, shares a common epitope with this immediate-early protein. Immunolocalization studies on purified virions indicate that the antigen can be detected only in virions without membranes, and is located outside the capsid, most probably in the tegument. Ultrastructural localizations on HSV-1 infected BHK cells extracted with a nonionic detergent confirm that the protein immunoreacting with anti-ICP4 is present in virions.     

Herpes simplex virus 1 precludes replenishment of the short-lived receptor of tumor necrosis factor alpha by virion host shutoff-dependent degradation of its mRNA

Cell function is tightly regulated by surface receptors. Earlier reports showed that herpes simplex virus 1 regulates by diverse mechanisms the presentation of antigenic peptides, downregulates the signaling pathways associated with receptor tyrosine kinases, and posttranslationally modifies members of the Src family of protein kinases. Here we report that the receptor for tumor necrosis factor alpha (TNF-R1) rapidly disappears from both the cell surface and total cell lysates in cells infected with wild-type virus or a variety of mutants but not in cells infected with the mutant DeltaU(L)41, which lacks the U(L)41 gene, the virion host shutoff gene. The half-life of TNF-R1 appears to be less than 30 min in both mock-infected and infected cells. The disappearance of TNF-R1 correlates with the disappearance of cytoplasmic TNF-R1 mRNA in wild-type-virus-infected cells. The results suggest that by degrading the TNFR1 mRNA, the virus precludes the replenishment of naturally decaying TNF-R1.     

Purification and characterization of the carboxyl-terminal transactivation domain of Vmw65 from herpes simplex virus type 1.

A glutathione S-transferase fusion to the COOH-terminal acidic transactivation domain of Vmw65 from herpes simplex virus type 1 was overexpressed in Escherichia coli and isolated by affinity chromatography on glutathione-Sepharose. Following cleavage of the fusion protein with thrombin, the transactivation domain was purified to homogeneity by ion exchange chromatography yielding approximately 0.6 mg of protein/liter of bacterial culture. Equilibrium sedimentation analysis showed the purified polypeptide to be monomeric; however, it displayed aberrant electrophoretic and chromatographic properties. Contrary to secondary structure predictions, circular dichroism spectroscopy demonstrated that this transactivation domain was devoid of significant alpha-helical structure at physiological conditions. The polypeptide, however, became notably more structured under hydrophobic conditions or at low pH, suggesting that it was sensitive to its environment. Near-UV circular dichroism suggested that phenylalanyl and tyrosyl residues were under influence from tertiary structure.     

Herpes simplex virus glycoproteins gD and gE/gI serve essential but redundant functions during acquisition of the virion envelope in the cytoplasm

The late stages of assembly of herpes simplex virus (HSV) and other herpesviruses are not well understood. Acquisition of the final virion envelope apparently involves interactions between viral nucleocapsids coated with tegument proteins and the cytoplasmic domains of membrane glycoproteins. This promotes budding of virus particles into cytoplasmic vesicles derived from the trans-Golgi network or endosomes. The identities of viral membrane glycoproteins and tegument proteins involved in these processes are not well known. Here, we report that HSV mutants lacking two viral glycoproteins, gD and gE, accumulated large numbers of unenveloped nucleocapsids in the cytoplasm. These aggregated capsids were immersed in an electron-dense layer that appeared to be tegument. Few or no enveloped virions were observed. More subtle defects were observed with an HSV unable to express gD and gI. A triple mutant lacking gD, gE, and gI exhibited more severe defects in envelopment. We concluded that HSV gD and the gE/gI heterodimeric complex act in a redundant fashion to anchor the virion envelope onto tegument-coated capsids. In the absence of either one of these HSV glycoproteins, envelopment proceeds; however, without both gD and gE, or gE/gI, there is profound inhibition of cytoplasmic envelopment.     

Herpes simplex virus 1 ICP0 phosphorylation site mutants are attenuated for viral replication and impaired for explant-induced reactivation

In cell culture experiments, phosphorylation appears to be a critical regulator of the herpes simplex virus 1 (HSV-1) immediate-early (IE) protein, ICP0, which is an E3 ubiquitin ligase that transactivates viral gene expression. Three major regions of phosphorylation in ICP0 (amino acids 224 to 232, 365 to 371, and 508 to 518) have been identified, and mutant viruses that block phosphorylation sites within each region (termed Phos 1, 2, and 3, respectively) have been constructed. Previous studies indicated that replication of Phos 1 is significantly reduced compared to that of wild-type virus in cell culture (C. Boutell, et al., J. Virol. 82:10647-10656, 2008). To determine the effects these phosphorylation site mutations have on the viral life cycle in vivo, mice were ocularly infected with wild-type HSV-1, the Phos mutants, or their marker rescue counterparts. Subsequently, viral replication, establishment of latency, and viral explant-induced reactivation of these viruses were examined. Relative to wild-type virus, Phos 1 eye titers were reduced as much as 7- and 18-fold on days 1 and 5 postinfection, respectively. Phos 2 eye titers showed a decrease of 6-fold on day 1 postinfection. Titers of Phos 1 and 2 trigeminal ganglia were reduced as much as 16- and 20-fold, respectively, on day 5 postinfection. Additionally, the reactivation efficiencies of Phos 1 and 2 were impaired relative to wild-type HSV-1, although both viruses established wild-type levels of latency in vivo. The acute replication, latency, and reactivation phenotypes of Phos 3 were similar to those of wild-type HSV-1. We conclude from these studies that phosphorylation is likely a key modulator of ICP0's biological activities in a mouse ocular model of HSV-1 infection.