Functional anatomy of herpes simplex virus 1 overlapping genes encoding infected-cell protein 22 and US1.5 protein

Earlier studies have shown that (i) the coding domain of the alpha22 gene encodes two proteins, the 420-amino-acid infected-cell protein 22 (ICP22) and a protein, US1.5, which is initiated from methionine 147 of ICP22 and which is colinear with the remaining portion of that protein; (ii) posttranslational processing of ICP22 mediated largely by the viral protein kinase UL13 yields several isoforms differing in electrophoretic mobility; and (iii) mutants lacking the carboxyl-terminal half of the ICP22 and therefore DeltaUS1.5 are avirulent and fail to express normal levels of subsets of both alpha (e.g., ICP0) or gamma2 (e.g., US11 and UL38) proteins. We have generated and analyzed two sets of recombinant viruses. The first lacked portions of or all of the sequences expressed solely by ICP22. The second set lacked 10 to 40 3'-terminal codons of ICP22 and US1. 5. The results were as follows. (i) In cells infected with mutants lacking amino-terminal sequences, translation initiation begins at methionine 147. The resulting protein cannot be differentiated in mobility from authentic US1.5, and its posttranslational processing is mediated by the UL13 protein kinase. (ii) Expression of US11 and UL38 genes by mutants carrying only the US1.5 gene is similar to that of wild-type parent virus. (iii) Mutants which express only US1. 5 protein are avirulent in mice. (iv) The coding sequences Met147 to Met171 are essential for posttranslational processing of the US1.5 protein. (v) ICP22 made by mutants lacking 15 or fewer of the 3'-terminal codons are posttranslationally processed whereas those lacking 18 or more codons are not processed. (vi) Wild-type and mutant ICP22 proteins localized in both nucleus and cytoplasm irrespective of posttranslational processing. We conclude that ICP22 encodes two sets of functions, one in the amino terminus unique to ICP22 and one shared by ICP22 and US1.5. These functions are required for viral replication in experimental animals. US1.5 protein must be posttranslationally modified by the UL13 protein kinase to enable expression of a subset of late genes exemplified by UL38 and US11. Posttranslational processing is determined by two sets of sequences, at the amino terminus and at the carboxyl terminus of US1.5, respectively, a finding consistent with the hypothesis that both domains interact with protein partners for specific functions.     

Colocalization of the herpes simplex virus 1 UL4 protein with infected cell protein 22 in small, dense nuclear structures formed prior to onset of DNA synthesis

Herpes simplex virus 1 infected cell protein 22 (ICP22) localizes in small, dense nuclear bodies of primate cells early in infection and in the more diffuse replicative complexes after the onset of DNA synthesis. UL4, a gamma2 protein, localizes in cytoplasm and in the small nuclear structures containing ICP22 but not in replicative complexes. In rabbit skin cells, both ICP22 and UL4 localize in the dense nuclear bodies late in infection. The results suggest that the small nuclear structures perform a function involving both proteins late in infection.     

Comprehensive characterization of interaction complexes of herpes simplex virus type 1 ICP22, UL3, UL4, and UL20.5

It has been reported that herpes simplex virus type 1 UL3, UL4, and UL20.5 proteins are localized to small, dense nuclear bodies together with ICP22 in infected cells. In the present study, we comprehensively characterized these interactions by subcellular colocalization, coimmunoprecipitation, and bimolecular fluorescence complementation assays. For the first time, it was demonstrated that both UL3 and UL20.5 are targeted to small, dense nuclear bodies by a direct interaction with ICP22, whereas UL4 colocalizes with ICP22 through its interaction with UL3 but not UL20.5 or ICP22. There was no detectable interaction between UL3 and UL20.5.     

Herpes simplex virus ICP27 activation of stress kinases JNK and p38

We previously reported that herpes simplex virus type 1 (HSV-1) can activate the stress-activated protein kinases (SAPKs) p38 and JNK. In the present study, we undertook a comprehensive and comparative analysis of the requirements for viral protein synthesis in the activation of JNK and p38. Infection with the UL36 mutant tsB7 or with UV-irradiated virus indicated that both JNK and p38 activation required viral gene expression. Cycloheximide reversal or phosphonoacetic acid treatment of wild-type virus-infected cells as well as infection with the ICP4 mutant vi13 indicated that only the immediate-early class of viral proteins were required for SAPK activation. Infection with ICP4, ICP27, or ICP0 mutant viruses indicated that only ICP27 was necessary. Additionally, we determined that in the context of virus infection ICP27 was sufficient for SAPK activation and activation of the p38 targets Mnk1 and MK2 by infecting with mutants deleted for various combinations of immediate-early proteins. Specifically, the d100 (0-/4-) and d103 (4-/22-/47-) mutants activated p38 and JNK, while the d106 (4-/22-/27-/47-) and d107 (4-/27-) mutants did not. Finally, infections with a series of ICP27 mutants demonstrated that the functional domain of ICP27 required for activation was located in the region encompassing amino acids 20 to 65 near the N terminus of the protein and that the C-terminal transactivation activity of ICP27 was not necessary.     

Interaction of herpes simplex virus 1 alpha regulatory protein ICP0 with elongation factor 1delta: ICP0 affects translational machinery.

The herpes simplex virus 1 (HSV-1)-infected cell protein 0 (ICP0) is a promiscuous transactivator, and by necessity, its functions must be mediated through cellular gene products. In an attempt to identify cellular factors interacting with ICP0, we used the carboxyl-terminal domain of ICP0 as "bait" in the yeast (Saccharomyces cerevisiae) two-hybrid system. Our results were as follows: (i) All 43 cDNAs in positive yeast colonies were found to encode the same translation factor, elongation factor delta-1 (EF-1delta). (ii) Purified chimeric protein consisting of glutathione S-transferase (GST) fused to EF-1delta specifically formed complexes with ICP0 contained in HSV-1-infected cell lysate. (iii) Fractionation of infected HEp-2 cells and immunofluorescence studies revealed that ICP0 was localized both in the nucleus and in the cytoplasm. In primary human foreskin fibroblasts, ICP0 was localized predominantly in the cytoplasm throughout HSV-1 infection even early in infection. (iv) Addition of the chimeric protein GST-carboxyl-terminal domain of ICP0 to the rabbit reticulocyte lysate in vitro translation system resulted in a dose-dependent decrease in protein synthesis. In contrast, GST alone or GST fused to the amino-terminal domain of ICP0 had no effect on the in vitro translation system. (v) The predominant forms of EF-1delta on electrophoresis in denaturing gels have apparent Mrs of 38,000 and 40,000. The higher-Mr form is a minor species in mock-infected cells, whereas in human fibroblasts and Vero cells infected with HSV-1, this isoform becomes dominant. These results indicate that ICP0 is present and may have a significant role in the cytoplasm of infected cells, possibly by altering the efficiency of translation of viral mRNAs.     

Deletion of the herpes simplex virus VP22-encoding gene (UL49) alters the expression, localization, and virion incorporation of ICP0

The role of the herpes simplex virus tegument protein VP22 is not yet known. Here we describe the characterization of a virus in which the entire VP22 open reading frame has been deleted. We show that VP22 is not essential for virus growth but that virus lacking VP22 (Delta22) displays a cell-specific replication defect in epithelial MDBK cells. Virus particles assembled in the absence of VP22 show few obvious differences to wild-type (WT) particles, except for a moderate reduction in glycoproteins gD and gB. In addition, the Delta22 virus exhibits a general delay in the initiation of virus protein synthesis, but this is not due to a glycoprotein-related defect in virus entry. Intriguingly, however, the absence of VP22 has an obvious effect on the intracellular level of the immediate-early (IE) protein ICP0. Moreover, following translocation from the nucleus to the cytoplasm, ICP0 is unable to localize to the characteristic cytoplasmic sites observed in a WT infection. We demonstrate that, in WT-infected cells, VP22 and ICP0 are concentrated in the same cytoplasmic sites. Furthermore, we show that, while ICP0 and ICP4 are components of WT extracellular virions, the altered localization of ICP0 in the cytoplasm of Delta22-infected cells correlates with an absence of both ICP0 and ICP4 from Delta22 virions. Hence, while a role has not yet been defined for virion IE proteins in virus infection, our results suggest that their incorporation is a specific event requiring the tegument protein VP22. This report provides the first direct evidence that VP22 influences virus assembly.     

Posttranslational processing of infected cell protein 22 mediated by viral protein kinases is sensitive to amino acid substitutions at distant sites and can be cell-type specific

Infected cell protein 22 (ICP22) is posttranslationally phosphorylated by the viral kinases encoded by U(S)3 and U(L)13 and nucleotidylylated by casein kinase II. In rabbit and rodent cells and in primary human fibroblasts infected with mutants from which the alpha 22 gene encoding ICP22 had been deleted, a subset of late (gamma(2)) gene products exemplified by U(L)38 and U(S)11 proteins are expressed at a reduced level, as measured by the accumulation of both mRNA and protein. The same phenotype was observed in cells infected with mutants lacking the U(L)13 gene. The focus of this report is on three serine- and threonine-rich domains of ICP22. Two of these domains are homologs located between residues 38 to 66 and 300 to 328. The third domain is near the carboxyl terminus and contains the sequence T374SS. The results were as follows. (i) Alanine substitutions in the amino-terminal homolog precluded the posttranslational processing of ICP22 in rabbit skin cells and in Vero cells but had no effect on the accumulation of either U(S)11 or U(L)38 protein. (ii) Alanine substitutions in the carboxyl-terminal homolog had no effect on posttranslational processing of ICP22 accumulating in Vero cells but precluded full processing of ICP22 accumulating in rabbit skin cells. The effect on accumulation of U(L)38 and U(S)11 proteins was insignificant in Vero cells and minimal in rabbit skin cells. (iii) Substitutions of alanine for the threonine and serines in the third domain precluded full processing of ICP22 and caused a reduction of accumulation of U(S)11 and U(L)38 proteins. These results indicate the following. (i) The posttranslational processing of ICP22 is sensitive to mutations within the domains of ICP22 tested and is cell-type dependent. (ii) Posttranslational processing of ICP22 is not required for accumulation of U(L)38 and U(S)11 proteins to the same level as that seen in cells infected with the wild-type virus. (iii) The T374SS sequence shared by ICP22 and the U(S)1.5 proteins is essential for the accumulation of a subset of gamma(2) proteins exemplified by U(S)11 and U(L)38 and is the first step in mapping of the sequences necessary for optimal accumulation of U(S)11 and U(L)38 proteins.     

Retention of the herpes simplex virus type 1 (HSV-1) UL37 protein on single-stranded DNA columns requires the HSV-1 ICP8 protein.

The UL37 and ICP8 proteins present in herpes simplex virus type 1 (HSV-1)-infected-cell extracts produced at 24 h postinfection coeluted from single-stranded-DNA-cellulose columns. Experiments carried out with the UL37 protein expressed by a vaccinia virus recombinant (V37) revealed that the UL37 protein did not exhibit DNA-binding activity in the absence of other HSV proteins. Analysis of extracts derived from cells coinfected with V37 and an ICP8-expressing vaccinia virus recombinant (V8) and analysis of extracts prepared from cells infected with the HSV-1 ICP8 deletion mutants d21 and n10 revealed that the retention of the UL37 protein on single-stranded DNA columns required a DNA-binding-competent ICP8 protein.     

Regulatory function of the equine herpesvirus 1 ICP27 gene product.

The UL3 protein of equine herpesvirus 1 (EHV-1) KyA strain is a homolog of the ICP27 alpha regulatory protein of herpes simplex virus type 1 (HSV-1) and the ORF 4 protein of varicella-zoster virus. To characterize the regulatory function of the UL3 gene product, a UL3 gene expression vector (pSVUL3) and a vector expressing a truncated version of the UL3 gene (pSVUL3P) were generated. These effector plasmids, in combination with an EHV-1 immediate-early (IE) gene expression vector (pSVIE) and chimeric EHV-1 promoter-chloramphenicol acetyltransferase (CAT) reporter constructs, were used in transient transfection assays. These assays demonstrated that the EHV-1 UL3 gene product is a regulatory protein that can independently trans activate the EHV-1 IE promoter; however, this effect can be inhibited by the repressive function of the IE gene product on the IE promoter (R. H. Smith, G. B. Caughman, and D. J. O'Callaghan, J. Virol. 66:936-945, 1992). In the presence of the IE gene product, the UL3 gene product significantly augments gene expression directed by the promoters of three EHV-1 early genes (thymidine kinase; IR4, which is the homolog of HSV-1 ICP22; and UL3 [ICP27]) and the promoter of the EHV-1 late gene IR5, which is the homolog of HSV-1 US10. Sequences located at nucleotides -123 to +20 of the UL3 promoter harbor a TATA box, SP1 binding site, CAAT box, and octamer binding site and, when linked to the CAT reporter gene, are trans activated to maximal levels by the pSVIE construct in transient expression assays. Results from CAT assays also suggest that the first 11 amino acids of the UL3 protein are not essential for the regulatory function of the UL3 gene product.     

Prolonged gene expression and cell survival after infection by a herpes simplex virus mutant defective in the immediate-early genes encoding ICP4, ICP27, and ICP22.

Very early in infection, herpes simplex virus (HSV) expresses four immediate-early (IE) regulatory proteins, ICP4, ICP0, ICP22, and ICP27. The systematic inactivation of sets of the IE proteins in cis, and the subsequent phenotypic analysis of the resulting mutants, should provide insights into how these proteins function in the HSV life cycle and also into the specific macromolecular events that are altered or perturbed in cells infected with virus strains blocked very early in infection. This approach may also provide a rational basis to assess the efficacy and safety of HSV mutants for use in gene transfer experiments. In this study, we generated and examined the phenotype of an HSV mutant simultaneously mutated in the ICP4, ICP27, and ICP22 genes of HSV. Unlike mutants deficient in ICP4 (d120), ICP4 and ICP27 (d92), and ICP4 and ICP22 (d96), mutants defective in ICP4, ICP27, and ICP22 (d95) were visually much less toxic to Vero and human embryonic lung cells. Cells infected with d95 at a multiplicity of infection of 10 PFU per cell retained a relatively normal morphology and expressed genes from the viral and cellular genomes for at least 3 days postinfection. The other mutant backgrounds were too toxic to allow examination of gene expression past 1 day postinfection. However, when cell survival was measured by the capacity of the infected cells to form colonies, d95 inhibited colony formation similarly to d92. This apparent paradox was reconciled by the observation that host cell DNA synthesis was inhibited in cells infected with d120, d92, d96, and d95. In addition, all of the mutants exhibited pronounced and distinctive alterations in nuclear morphology, as determined by electron microscopy. The appearance of d95-infected cells deviated from that of uninfected cells in that large circular structures formed in the nucleus. d95-infected cells abundantly expressed ICP0, which accumulated in fine punctate structures in the nucleus at early times postinfection and coalesced or grew to the large circular objects that were revealed by electron microscopy. Therefore, while the abundant accumulation of ICPO in the absence of ICP4, ICP22, and ICP27 may allow for prolonged gene expression, cell survival is impaired, in part, as a result of the inhibition of cellular DNA synthesis.     

Overexpression of the herpes simplex virus type 1 immediate-early regulatory protein, ICP27, is responsible for the aberrant localization of ICP0 and mutant forms of ICP4 in ICP4 mutant virus-infected cells.

ICP0 and ICP4 are immediate-early regulatory proteins of herpes simplex virus type 1. Previous studies by Knipe and Smith demonstrated that these two proteins are characteristically observed in the nuclei of wild-type virus-infected cells but predominantly in the cytoplasms of cells infected with several ICP4 temperature-sensitive (ts) mutant viruses at the nonpermissive temperature (NPT) (D. M. Knipe and J. L. Smith, Mol. Cell. Biol. 6:2371-2381, 1986). Consistent with this observation, it has been shown previously that ICP0 is present predominantly in the cytoplasms of cells infected with an ICP4 null mutant virus (n12) at high multiplicities of infection and that the level of ICP27, a third viral regulatory protein, plays an important role in determining the intracellular localization of ICP0 (Z. Zhu, W. Cai, and P. A. Schaffer, J. Virol. 68:3027-3040, 1994). To address whether the cytoplasmic localization of ICP0 is a common feature of cells infected with all ICP4 mutant viruses or whether mutant ICP4 polypeptides, together with ICP27, determine the intracellular localization of ICP0, we used double-staining immunofluorescence tests to examine the intracellular staining patterns of ICP0 and ICP4 in cells infected with an extensive series of ICP4 mutant viruses. In these tests, compared with the localization pattern of ICP0 in wild-type virus-infected cells, more ICP0 was detected in the cytoplasms of cells infected with all ICP4 mutants tested at high multiplicities of infection. Each of the mutant forms of ICP4 exhibiting predominantly cytoplasmic staining contains both the nuclear localization signal and the previously mapped ICP27-responsive region (Z. Zhu and P. A. Schaffer, J. Virol. 69:49-59, 1995). No correlation between the intracellular staining patterns of ICP0 and mutant forms of ICP4 was demonstrated, suggesting that mutant ICP4 polypeptides per se are not responsible for retention of ICP0 in the cytoplasm. This observation was confirmed in studies of cells cotransfected with plasmids expressing ICP0 and mutant forms of ICP4, in which the staining pattern of ICP0 was not changed in the presence of mutant ICP4 proteins. Studies of cells infected at low multiplicities with a variety of ICP4 ts mutant viruses at the NPT showed that both ICP0 and ts forms of ICP4 were localized predominantly within the nucleus. These observations are a further indication that the aberrant localization of the ts forms of ICP4 at the NPT is not a direct result of specific mutations in the ICP4 gene. In the final series of tests, the localization of ICP0 in cells infected with a double-mutant virus unable to express either ICP4 or ICP27 was examined. In these tests, ICP0 was detected exclusively in the nuclei of Vero cells but in both the nuclei and the cytoplasms of ICP27-expressing cells infected with the double mutant. These results demonstrate that ICP27, rather than the absence of functional ICP4, is responsible for the cytoplasmic localization of ICP0 in ICP4 mutant virus-infected cells. Taken together, these findings demonstrate that the aberrant localization of ICP0 and certain mutant forms of ICP4 in cells infected with ICP4 mutant viruses is mediated by high levels of ICP27 resulting from the inability of mutant forms of ICP4 to repress the expression of ICP27.     

Phenotype of the herpes simplex virus type 1 protease substrate ICP35 mutant virus.

The herpes simplex virus type 1 ICP35 assembly protein is involved in the formation of viral capsids. ICP35 is encoded by the UL26.5 gene and is specifically processed by the herpes simplex virus type 1 protease encoded by the UL26 gene. To better understand the functions of ICP35 in infected cells, we have isolated and characterized an ICP35 mutant virus, delta ICP35. The mutant virus was propagated in complementing 35J cells, which express wild-type ICP35. Phenotypic analysis of delta ICP35 shows that (i) mutant virus growth in Vero cells was severely restricted, although small amounts of progeny virus was produced; (ii) full-length ICP35 protein was not produced, although autoproteolysis of the protease still occurred in mutant-infected nonpermissive cells; (iii) viral DNA replication of the mutant proceeded at wild-type levels, but only a very small portion of the replicated DNA was processed to unit length and encapsidated; (iv) capsid structures were observed in delta ICP35-infected Vero cells by electron microscopy and by sucrose sedimentation analysis; (v) assembly of VP5 into hexons of the capsids was conformationally altered; and (vi) ICP35 has a novel function which is involved in the nuclear transport of VP5.