Herpes simplex virus 1 protein kinase Us3 and major tegument protein UL47 reciprocally regulate their subcellular localization in infected cells

Us3 is a serine-threonine protein kinase encoded by herpes simplex virus 1 (HSV-1). We have identified UL47, a major virion protein, as a novel physiological substrate of Us3. In vitro kinase assays and systematic analysis of mutations at putative Us3 phosphorylation sites near the nuclear localization signal of UL47 showed that serine at residue 77 (Ser-77) was required for Us3 phosphorylation of UL47. Replacement of UL47 Ser-77 by alanine produced aberrant accumulation of UL47 at the nuclear rim and impaired the nuclear localization of UL47 in a significant fraction of infected cells. The same defect in UL47 localization was produced by an amino acid substitution in Us3 that inactivated its protein kinase activity. In contrast, a phosphomimetic mutation at UL47 Ser-77 restored wild-type nuclear localization. The UL47 S77A mutation also reduced viral replication in the mouse cornea and the development of herpes stromal keratitis in mice. In addition, UL47 formed a stable complex with Us3 in infected cells, and nuclear localization of Us3 was significantly impaired in the absence of UL47. These results suggested that Us3 phosphorylation of UL47 Ser-77 promoted the nuclear localization of UL47 in cell cultures and played a critical role in viral replication and pathogenesis in vivo. Furthermore, UL47 appeared to be required for efficient nuclear localization of Us3 in infected cells. Therefore, Us3 protein kinase and its substrate UL47 demonstrated a unique regulatory feature in that they reciprocally regulated their subcellular localization in infected cells.     

Herpes simplex virus 1-encoded protein kinase UL13 phosphorylates viral Us3 protein kinase and regulates nuclear localization of viral envelopment factors UL34 and UL31

UL13 and Us3 are protein kinases encoded by herpes simplex virus 1. We report here that Us3 is a physiological substrate for UL13 in infected cells, based on the following observations. (i) The electrophoretic mobility, in denaturing gels, of Us3 isoforms from Vero cells infected with wild-type virus was slower than that of isoforms from cells infected with a UL13 deletion mutant virus (DeltaUL13). After treatment with phosphatase, the electrophoretic mobility of the Us3 isoforms from cells infected with wild-type virus changed, with one isoform migrating as fast as one of the Us3 isoforms from DeltaUL13-infected cells. (ii) A recombinant protein containing a domain of Us3 was phosphorylated by UL13 in vitro. (iii) The phenotype of DeltaUL13 resembles that of a recombinant virus lacking the Us3 gene (DeltaUs3) with respect to localization of the viral envelopment factors UL34 and UL31, whose localization has been shown to be regulated by Us3. UL34 and UL31 are localized in a smooth pattern throughout the nuclei of cells infected with wild-type virus, whereas their localization in DeltaUL13- and DeltaUs3-infected cells appeared as nuclear punctate patterns. These results indicate that UL13 phosphorylates Us3 in infected cells and regulates UL34 and UL31 localization, either by phosphorylating Us3 or by a Us3-independent mechanism.     

The herpes simplex virus 1 protein kinase encoded by the US3 gene mediates posttranslational modification of the phosphoprotein encoded by the UL34 gene.

Earlier studies have shown that a herpes simplex virus 1 (HSV-1) open reading frame, US3, encodes a novel protein kinase and have characterized the cognate amino acid sequence which is phosphorylated by this enzyme. This report identifies an apparently essential viral phosphoprotein whose posttranslational processing involves the viral protein kinase. Analyses of viral proteins phosphorylated in the course of productive infection revealed a phosphoprotein whose mobility was viral protein kinase and serotype dependent. Thus, the corresponding HSV-1 and HSV-2 phosphoproteins differ in their electrophoretic mobilities, and the phosphoprotein specified by the HSV-1 mutant deleted in US3 (R7041) differs from that of the corresponding HSV-1 and HSV-2 proteins. Analyses of HSV-1 x HSV-2 recombinants mapped the phosphoprotein between 0.42 and 0.47 map units on the prototype HSV-1 DNA map. Within this region, the UL34 open reading frame was predicted to encode a protein of appropriate molecular weight which would also contain the consensus target site for phosphorylation by the viral protein kinase as previously defined with synthetic peptides. Replacement of the native UL34 gene with a UL34 gene tagged with a 17-amino-acid epitope from the alpha 4 protein identified this gene as encoding the phosphoprotein. Finally, mutagenesis of the predicted phosphorylation site on UL34 in the viral genome, and specifically the substitution of threonine or serine with alanine in the product of the UL34 gene, yielded phosphoproteins whose electrophoretic mobilities could not be differentiated from that of the US3- mutant. We conclude that the posttranslational processing of the UL34 gene product to its wild-type phenotype requires the participation of the viral protein kinase. While the viral protein kinase is not essential for viral replication in cells in culture, the UL34 gene product itself may not be dispensable.     

Identification of proteins directly phosphorylated by UL13 protein kinase from herpes simplex virus 1

Herpes simplex virus 1 (HSV-1) UL13 is a viral protein kinase that regulates optimal viral replication in cell cultures. Identification of substrates of protein kinases is a crucial step to elucidate the mechanism by which they function. Using our developed system to analyze the specific protein kinase activity of UL13, we have shown that UL13 protein kinase directly phosphorylates the viral proteins ICP22 and UL49 previously reported to be putative substrates. We also identified UL41 as a previously unreported and novel substrate of UL13. These data will serve as a basis to clarify the mechanism by which UL13 influences viral replication.     

Effects of Phosphorylation of Herpes Simplex Virus 1 Envelope Glycoprotein B by Us3 Kinase In Vivo and In Vitro

We recently reported that the herpes simplex virus 1 (HSV-1) Us3 protein kinase phosphorylates threonine at position 887 (Thr-887) in the cytoplasmic tail of envelope glycoprotein B (gB) (A. Kato, J. Arii, I. Shiratori, H. Akashi, H. Arase, and Y. Kawaguchi, J. Virol. 83:250-261, 2009; T. Wisner, C. C. Wright, A. Kato, Y. Kawaguchi, F. Mou, J. D. Baines, R. J. Roller and D. C. Johnson, J. Virol. 83:3115-3126, 2009). In the studies reported here, we examined the effect(s) of this phosphorylation on viral replication and pathogenesis in vivo and present data showing that replacement of gB Thr-887 by alanine significantly reduced viral replication in the mouse cornea and development of herpes stroma keratitis and periocular skin disease in mice. The same effects have been reported for mice infected with a recombinant HSV-1 carrying a kinase-inactive mutant of Us3. These observations suggested that Us3 phosphorylation of gB Thr-887 played a critical role in viral replication in vivo and in HSV-1 pathogenesis. In addition, we generated a monoclonal antibody that specifically reacted with phosphorylated gB Thr-887 and used this antibody to show that Us3 phosphorylation of gB Thr-887 regulated subcellular localization of gB, particularly on the cell surface of infected cells.The herpes simplex virus 1 (HSV-1) Us3 gene encodes a serine/threonine protein kinase with an amino acid sequence that is conserved in the subfamily Alphaherpesvirinae (9, 20, 29). The Us3 kinase phosphorylation target site has been reported to be similar to that of protein kinase A (PKA), a cellular cyclic AMP-dependent protein kinase (3, 12). Us3 catalytic activity plays important roles in viral replication and pathogenesis in vivo, based on studies showing that recombinant Us3 null mutant viruses and recombinant viruses encoding catalytically inactive Us3 have significantly reduced virulence, pathogenicity, and replication in mouse models (21, 34). In contrast, Us3 is not essential for growth in tissue culture cells (29). Thus, recombinant Us3 mutants grow as well as wild-type virus in Vero cells and have modestly impaired growth in a specific cell line such as HEp-2 cells (32, 33). The catalytic activity of Us3 is, in part, regulated by autophosphorylation of its serine at position 147 (Ser-147), and regulation of Us3 activity by autophosphorylation of Ser-147 appears to play a critical role in HSV-1 replication in vivo and in HSV-1 pathogenesis (34). Numerous studies have elucidated the potential downstream effects of Us3, including blocking apoptosis (18, 26-28), promoting nuclear egress of progeny nucleocapsids through the nuclear membrane (24, 32, 33), redistributing and phosphorylating nuclear membrane-associated viral nuclear egress factors UL31 and UL34 (13, 24, 30, 31) and cellular proteins including lamin A/C and emerin (16, 22, 23), controlling infected cell morphology (12, 27), and downregulating cell surface expression of viral envelope glycoprotein B (gB) (11).Two substrates that mediate some of the Us3 functions described above have been identified. First, it has been shown that Us3 phosphorylates Thr-887 in the cytoplasmic tail of gB, which appears to downregulate cell surface expression of gB (11). This conclusion is based on the observation that a T887A mutation in gB (gB-T887A) markedly upregulated cell surface expression of gB in infected cells: this upregulation was also observed with a recombinant virus encoding a Us3 kinase-inactive mutant, whereas a phosphomimetic substitution for gB Thr-887 restored wild-type cell surface expression of gB (11). Us3 phosphorylation of gB Thr-887 has also been proposed to be involved in regulation of fusion of the nascent progeny virion envelope with the cell''s outer nuclear membrane, based on the observation that virions accumulated aberrantly in the perinuclear space in cells infected with a mutant virus carrying the gB-T887A substitution mutation and lacking the capacity to produce gH (42). Second, it has been shown that Us3 may phosphorylate some or all of the six serines in the UL31 N-terminal region (24). Such phosphorylation might regulate proper localization of UL31 and UL34 at the nuclear membrane, nuclear egress of nucleocapsids, and viral growth in cell cultures since the Us3 kinase-inactive mutant phenotype for nuclear egress (i.e., mislocalization of UL31 and UL34 at the nuclear membrane, aberrant accumulation of virions within herniations of the nuclear membrane, and decreased viral growth in cell cultures) is also produced by replacement of the six serines in the UL31 N-terminal region with alanines while phosphomimetic substitutions of the six serines restored the wild-type phenotype (24).Thus, the molecular mechanisms for some of the downstream effects of Us3 phosphorylation have been gradually elucidated. However, it remains to be shown whether the Us3 functions reported to date are in fact involved in viral replication and pathogenicity in vivo. In the present study, we focused on Us3 phosphorylation of gB Thr-887 and examined the effect(s) of this phosphorylation on viral replication and pathogenesis in vivo. These studies have shown that replacement of gB Thr-887 by alanine significantly reduced viral replication in the mouse cornea and development of herpes stroma keratitis (HSK) and periocular skin disease in mice, as reported for infection of mice with a recombinant virus carrying a Us3 kinase-inactive mutant (34). These observations suggested that Us3 phosphorylation of gB Thr-887 played a critical role in viral replication in vivo and in HSV-1 pathogenesis. In addition, we generated a monoclonal antibody that specifically recognized phosphorylated gB Thr-887 and used this antibody to directly study the functional consequences of Us3 phosphorylation of gB Thr-887 in infected cells. We also present data showing that Us3 phosphorylation of gB Thr-887 regulated subcellular localization of gB, particularly gB localization on the cell surface of infected cells.     

Relationship between autophosphorylation and phosphorylation of exogenous substrates by the human cytomegalovirus UL97 protein kinase

Human cytomegalovirus encodes an unusual protein kinase, UL97, which is a member of the HvU(L) family of protein kinases encoded by diverse herpesviruses. UL97 is able to autophosphorylate and to phosphorylate certain exogenous substrates, including nucleoside analogs such as ganciclovir. It has previously been concluded that phosphorylation of UL97 is essential for its phosphorylation of ganciclovir. We examined the relationship between autophosphorylation of UL97 and its activity on exogenous substrates. Glutathione S-transferase-UL97 fusion protein purified from insect cells was found to be already partially phosphorylated, but neither extensive autophosphorylation nor phosphatase treatment meaningfully altered the time course of its phosphorylation of the exogenous substrate, histone H2B. Sequencing and mass spectrometric analyses of (32)P-labeled tryptic peptides of the UL97 fusion protein identified nine sites of autophosphorylation, all within the first 200 residues of the protein, outside of conserved protein kinase subdomains. A peptide corresponding to the N-terminal UL97 segment that was most extensively autophosphorylated was readily phosphorylated by UL97, confirming that fusion protein sequences are not required for phosphorylation at this site. Deletion mutants lacking at least the first 239 residues exhibited drastically reduced autophosphorylation (<5%) but retained near-wild-type H2B phosphorylation activity. Baculoviruses expressing these mutants efficiently directed the phosphorylation of ganciclovir in insect cells. Taken together, these results identify the autophosphorylation sites of a herpesvirus protein kinase and show that autophosphorylation of UL97 is not required for phosphorylation of exogenous substrates.     

Herpes simplex virus type 1 primary envelopment: UL34 protein modification and the US3-UL34 catalytic relationship

The herpes simplex virus type 1 (HSV-1) US3 kinase is likely important for primary envelopment of progeny nucleocapsids since it localizes to the nuclear envelope of infected cells and largely determines the phosphorylation state and localization of the necessary primary envelopment factor, the UL34 protein. In HEp-2 cells, the production of infectious US3 null progeny is delayed and decreased relative to that of the parental strain, HSV-1(F). Furthermore, the US3 kinase affects the morphology of primary envelopment such that in its absence, UL34 protein-containing enveloped virions accumulate within membrane-bound vesicles. These vesicles are most often found along the interior periphery of the nucleus and may be derived from the inner nuclear membrane. Since the US3 and UL34 proteins comprise a kinase-substrate pair, a reasonable hypothesis is that the US3 kinase influences these replication parameters by direct phosphorylation of the UL34 protein. For this report, recombinant viruses were constructed to determine the significance of UL34 protein phosphorylation and US3 catalytic activity on UL34 protein localization, single-step growth, and envelopment morphology in both HEp-2 and Vero cells. The data presented suggest that the significance of UL34 phosphorylation is cell type dependent and that efficient viral morphogenesis requires US3-mediated phosphorylation of an infected cell protein other than UL34.     

Differences in the Regulatory and Functional Effects of the Us3 Protein Kinase Activities of Herpes Simplex Virus 1 and 2

Us3 protein kinases encoded by herpes simplex virus 1 (HSV-1) and 2 (HSV-2) are serine/threonine protein kinases and play critical roles in viral replication and pathogenicity in vivo. In the present study, we investigated differences in the biological properties of HSV-1 and HSV-2 Us3 protein kinases and demonstrated that HSV-2 Us3 did not have some of the HSV-1 Us3 kinase functions, including control of nuclear egress of nucleocapsids, localization of UL31 and UL34, and cell surface expression of viral envelope glycoprotein B. In agreement with the observations that HSV-2 Us3 was less important for these functions, the effect of HSV-2 Us3 kinase activity on virulence in mice following intracerebral inoculation was much lower than that of HSV-1 Us3. Furthermore, we showed that alanine substitution in HSV-2 Us3 at a site (aspartic acid at position 147) corresponding to one that can be autophosphorylated in HSV-1 Us3 abolished HSV-2 Us3 kinase activity. Thus, the regulatory and functional effects of Us3 kinase activity are different between HSV-1 and HSV-2.Us3 protein kinases encoded by herpes simplex virus 1 (HSV-1) and 2 (HSV-2) are serine/threonine protein kinases with amino acid sequences that are conserved in the subfamily Alphaherpesvirinae (6, 24, 36). Based on studies showing that recombinant Us3 mutants of HSV-1 and HSV-2 have significantly impaired viral replication and virulence in mice models, it has been concluded that both HSV-1 and HSV-2 Us3 protein kinases play important roles in viral replication and pathogenicity in vivo (25, 33, 41). In contrast, HSV-1 and HSV-2 Us3 protein kinases are not essential for growth in tissue culture cells (33, 36). Thus, recombinant Us3 mutants grow as well as wild-type viruses in Vero cells, and the mutants exhibit modestly impaired replication in HEp-2 cells (33, 36, 39, 40). The possible functions of Us3 have been extensively studied and gradually elucidated for HSV-1 Us3, but much less is known about HSV-2 Us3. These functions include (i) blocking apoptosis (1, 22, 30, 31, 35); (ii) promoting nuclear egress of progeny nucleocapsids through the nuclear membrane (39, 40, 45); (iii) redistributing and phosphorylating nuclear membrane-associated viral nuclear egress factors UL31 and UL34 (14, 37, 38) and cellular proteins, including lamin A/C and emerin (21, 27, 28); (iv) controlling infected cell morphology (13, 31, 32); and (v) downregulating cell surface expression of viral envelope glycoprotein B (gB) (12).To determine the molecular mechanisms for a viral protein kinase''s effects in infected cells, the kinase''s physiological substrates and its phosphorylation sites must be identified. This can involve studies showing that the altered phenotypes observed in cells infected with a mutant virus lacking the protein kinase activity is also detected in cells infected with a mutant virus in which the substrate''s phosphorylation sites have been modified by mutations. Although more than 15 potential HSV Us3 substrates have been reported, HSV-1 Us3 phosphorylation of only three substrates (Us3 itself, gB, and UL31) has been demonstrated to be linked directly with Us3 functions in infected cells (12, 13, 29, 41) as follows. (i) Us3 has been reported to autophosphorylate serine at position 147 (Ser-147), and this phosphorylation augments Us3''s kinase activity in infected cells (13, 41). Even though only a small fraction of Us3 is autophosphorylated at Ser-147 in infected cells, alanine replacement of Ser-147 in Us3 significantly reduced HSV-1 replication in the mouse cornea and pathogenic manifestations of herpes stroma keratitis and periocular skin disease in mice (41). These results indicated that Us3 kinase activity was, in part, regulated by autophosphorylation of Ser-147, and regulation of Us3 activity by autophosphorylation played a critical role in viral replication in vivo and HSV-1 pathogenesis. (ii) It has been reported that HSV-1 Us3 phosphorylates Thr-887 in the cytoplasmic tail of gB, and this phosphorylation downregulates the cell surface expression of gB (12). Us3 phosphorylation of gB at Thr-887 also has been proposed to be involved in the regulation of fusion of the nascent progeny virion envelope with the cell''s outer nuclear membrane, based on the observation that virions accumulated aberrantly in the perinuclear space in cells infected with mutant viruses carrying the amino acid substitution mutation T887A in gB and lacking the capacity to produce gH (45). The Us3 phosphorylation of gB at Thr-887 appeared to be critical for HSV-1 replication and pathogenesis in vivo, based on studies showing that the T887A substitution in the phosphorylation site in gB significantly reduced viral replication in the mouse cornea and pathogenic manifestations of herpes stroma keratitis and periocular skin disease in mice (Takahiko Imai, Ken Sagou, and Yasushi Kawaguchi, unpublished observations). (iii) It has been shown that Us3 phosphorylated some or all of the six serines in the UL31 N-terminal region, and this phosphorylation regulated the proper localization of UL31 and UL34 at the nuclear membrane and nuclear egress of nucleocapsids (29). Thus, the molecular basis of HSV-1 Us3 effects in infected cells have been gradually elucidated.However, the Us3 phosphorylation sites in Us3 itself and in gB are not conserved between HSV serotypes (12, 13). The amino acid residues in HSV-2 Us3 and gB corresponding to HSV-1 Us3 Ser-147 and gB Thr-887 are aspartic acid (Asp-147) and alanine (Ala-887), respectively. These results suggest that some HSV-1 Us3 functions, such as regulation of its own catalytic activity and control of gB expression on the cell surface, are not regulated by HSV-2 Us3 or are regulated in a manner(s) different from HSV-1 Us3. In agreement with this suggestion, there is a marked difference between HSV-1 and HSV-2 virulence in mice following intracerebral infection, with the HSV-1 Us3 null mutant being >10⁴-fold less virulent than the parent wild-type virus (25), while the HSV-2 Us3 null mutant was only ∼10-fold less virulent (33). Although these results were from different reports and the mouse strains used in the studies were different, they indicate that some HSV-1 Us3 functions are different from those of HSV-2 Us3.Therefore, we investigated differences in the biological properties of HSV-1 and HSV-2 Us3 protein kinases. It was of particular interest to examine whether Asp-147 in HSV-2 Us3 is required for its own kinase activity, since it is well established that acidic amino acids such as Asp or glutamic acid sometimes mimic the negative charges produced by phosphorylation (29, 46). In the present study, using a genetic manipulation system of HSV-2 with our newly constructed HSV-2 bacterial artificial chromosome (BAC) clone, we have shown that HSV-2 Us3 exhibited marked differences from HSV-1 Us3 in its catalytic functions, including the regulation of UL31/UL34 localization, nuclear egress of nucleocapsids, cell surface expression of gB, and virulence in mice. We also found that Asp-147 in HSV-2 Us3 was critical for its kinase activity, raising a possibility that the activity of Us3 kinases was regulated differently in HSV-1 and HSV-2.     

Human Cytomegalovirus UL34 Binds to Multiple Sites within the Viral Genome

The human cytomegalovirus UL34 gene encodes a sequence-specific DNA binding protein that downregulates expression of the viral immune evasion gene US3. Analysis of the viral genome identified 14 potential UL34 binding sites. Using mobility shift experiments, UL34 bound to all predicted sites that were assayed (7 of 14). Furthermore, the UL34 binding site present within the regulatory region of the US9 gene downregulates expression in a manner similar to that seen for the US3 gene.     

Regulation of eIF2alpha phosphorylation by different functions that act during discrete phases in the herpes simplex virus type 1 life cycle

Multiple herpes simplex virus type 1 functions control translation by regulating phosphorylation of the initiation factor eIF2 on its alpha subunit. Both of the two known regulators, the gamma(1)34.5 and Us11 gene products, are produced late in the viral life cycle, although the gamma(1)34.5 gene is expressed prior to the gamma(2) Us11 gene, as gamma(2) genes require viral DNA replication for their expression while gamma(1) genes do not. The gamma(1)34.5 protein, through a GADD34-related domain, binds a cellular phosphatase (PP1alpha), maintaining pools of active, unphosphorylated eIF2. Infection of a variety of cultured cells with a gamma(1)34.5 mutant virus results in the accumulation of phosphorylated eIF2alpha and the inhibition of translation prior to the completion of the viral lytic program. Ectopic, immediate-early Us11 expression prevents eIF2alpha phosphorylation and the inhibition of translation observed in cells infected with a gamma(1)34.5 mutant by inhibiting activation of the cellular kinase PKR and the subsequent phosphorylation of eIF2alpha; however, a requirement for the Us11 protein, produced in its natural context as a gamma(2) polypeptide, remains to be demonstrated. To determine if Us11 regulates late translation, we generated two Us11 null viruses. In cells infected with a Us11 mutant, elevated levels of activated PKR and phosphorylated eIF2alpha were detected, viral translation rates were reduced 6- to 7-fold, and viral replication was reduced 13-fold compared to replication in cells infected with either wild-type virus or a virus in which the Us11 mutation was repaired. This establishes that the Us11 protein is critical for proper late translation rates. Moreover, it demonstrates that the shutoff of protein synthesis observed in cells infected with a gamma(1)34.5 mutant virus, previously ascribed solely to the gamma(1)34.5 mutation, actually results from the combined loss of gamma(1)34.5 and Us11 functions, as the gamma(2) Us11 mRNA is not translated in cells infected with a gamma(1)34.5 mutant.     

UL34, the target of the herpes simplex virus U(S)3 protein kinase, is a membrane protein which in its unphosphorylated state associates with novel phosphoproteins.

Previous studies (F. C. Purves, D. Spector, and B. Roizman, J. Virol. 65:5757-5764, 1991) have shown that the protein kinase encoded by the U(S)3 gene mediates posttranslational modification of a viral phosphoprotein with an apparent M(r) of 30,000 encoded by the UL34 gene. Here we report the following. (i) UL34 protein is not phosphorylated in cells infected with recombinant viruses deleted in the U(S)3 gene. (ii) Several new phosphoproteins (apparent M(r)s, 25,000 to 35,000) are present in cells infected with recombinant viruses deleted in the U(S)3 gene or with viruses carrying a mutation in the UL34 gene that precluded phosphorylation of the UL34 gene product by the U(S)3 protein kinase, but not in cells infected under conditions which permit phosphorylation of the UL34 protein. These proteins are genetically unrelated to the product of the UL34 gene. (iii) Polyclonal rabbit anti-UL34 protein serum precipitated not only the UL34 protein but also the other (25,000- to 35,000-M(r)) phosphoproteins from lysates of cells infected with U(S)3- virus. (iv) The UL34 gene product is a membrane protein inasmuch as the polyclonal anti-UL34 serum reacted with surfaces of intact, unfixed, infected cells and the antigen-antibody complex formed in this reaction contained the UL34 protein. (v) Small amounts of the UL34 protein were present in virions of infected cells. We conclude that the UL34 gene product is a membrane protein exclusively phosphorylated by the U(S)3 protein kinase which can either directly or indirectly form complexes with several other phosphoproteins. Experiments done thus far suggest that these phosphoproteins are present only under conditions in which the UL34 protein is not phosphorylated.     

Bovine herpesvirus 1 UL49.5 homolog gene encodes a novel viral envelope protein that forms a disulfide-linked complex with a second virion structural protein.

We previously reported that the genome of bovine herpesvirus 1 (BHV-1) contains an open reading frame (ORF) homologous to the herpes simplex virus UL49.5 ORF, and as with the herpes simplex virus UL49.5 ORF, the deduced amino acid sequence of the BHV-1 UL49.5 homolog (UL49.5h) contains features characteristic of an integral membrane protein, implying that it may constitute a functional gene encoding a novel viral envelope protein. This communication reports on the identification of the BHV-1 UL49.5h gene product. By employing an antibody against a synthetic BHV-1 UL49.5h peptide and an UL49.5h gene deletion mutant, the primary product of BHV-UL49.5h gene was identified as a polypeptide with a size of approximately 9 kDa; in both infected cells and isolated virions, the UL49.5h products were found to exist in three forms; monomer, disulfide-linked homodimer, and disulfide-linked heterodimer containing a second viral protein with a size of about 39 kDa. O-Glycosidase digestion and [3H]glucosamine labelling experiments showed that the UL49.5h protein is not glycosylated. Although the deduced amino acid sequence contains putative sites for myristylation and phosphorylation, we were unable to detect either modification. Surface labelling and trypsin digestion protection experiments showed that the BHV-1 UL49.5h protein was present on the surface of infected cells and on the surface of mature virions. Nonionic detergent partition of isolated virions revealed that the UL49.5h protein is more tightly associated with the virion tegument-nucleocapsid structure than envelope protein gD. The results from this study demonstrate that the BHV-1 UL49.5h gene encodes a nonglycosylated virion envelope protein which may associate with virion internal structures by forming a complex with the 39-kDa virion structural protein.     

Specific phosphorylation of exogenous protein and peptide substrates by the human cytomegalovirus UL97 protein kinase. Importance of the P+5 position

Human cytomegalovirus UL97 is an unusual protein kinase that can phosphorylate nucleoside analogs such as ganciclovir but whose specificity for exogenous protein substrates has remained unknown. We found that purified, recombinant glutathione S-transferase-UL97 fusion protein can phosphorylate histone H2B. Phosphorylation was abrogated by substitution of glutamine for a conserved lysine in subdomain II and inhibited by a new antiviral drug, maribavir. Sequencing and mass spectrometric analyses of purified (32)P-labeled tryptic peptides of H2B revealed that the sites of phosphorylation were, in order of extent, Ser-38, Ser-87, Ser-6, Ser-112, and Ser-124. Phosphorylation of synthetic peptides containing these sites, analyzed using a new, chimeric gel system, correlated with their phosphorylation in H2B. Phosphorylation of the Ser-38 peptide by UL97 occurred on Ser-38 and was specifically sensitive to maribavir, whereas phosphorylation of this peptide by cAMP-dependent protein kinase occurred on Ser-36. The extent of phosphorylation was greatest with peptides containing an Arg or Lys residue 5 positions downstream (P+5) from the Ser. Substitution with Ala at this position essentially eliminated activity. These results identify exogenous protein and peptide substrates of UL97, reveal an unusual dependence on the P+5 position, and may abet discovery of new inhibitors of UL97 and human cytomegalovirus replication.     

Role of herpes simplex virus 1 Us3 in viral neuroinvasiveness

Us3 is a serine–threonine protein kinase that is encoded by herpes simplex virus 1 (HSV‐1). In experimental animal models of HSV infection, peripheral and intracranial inoculations can be used to study viral pathogenicity in peripheral sites (e.g., eyes and vagina) and central nervous systems (CNSs), respectively. In addition, peripheral inoculation can be used to investigate this virus' ability to invade the CNS (neuroinvasiveness) from peripheral sites. HSV‐1 Us3 has previously been shown to be critical for viral pathogenicity in both peripheral sites and CNSs of mice. However, the role of HSV‐1 Us3 in viral neuroinvasiveness has not yet been elucidated. In the present study, the yields of a Us3 null mutant virus and its repaired virus in the eyes, trigeminal ganglia, and brains of mice following ocular inoculation were examined. It was found that, although the repaired virus appeared in the brains of mice 3 days after infection, peak replication occurring 7 days after infection, no viral replication of the Us3 null mutant virus was detectable. These findings indicate that HSV‐1 Us3 plays a crucial role in the ability of the virus to invade the brain from the eyes. Thus, HSV‐1 Us3 is a significant neuroinvasiveness factor in vivo.     

Herpes simplex virus 1 protein kinase Us3 phosphorylates viral envelope glycoprotein B and regulates its expression on the cell surface

Us3 is a serine-threonine protein kinase encoded by herpes simplex virus 1 (HSV-1). As reported here, we attempted to identify the previously unreported physiological substrate of Us3 in HSV-1-infected cells. Our results were as follows. (i) Bioinformatics analysis predicted two putative Us3 phosphorylation sites in the viral envelope glycoprotein B (gB) at codons 557 to 562 (RRVSAR) and codons 884 to 889 (RRNTNY). (ii) In in vitro kinase assays, the threonine residue at position 887 (Thr-887) in the gB domain was specifically phosphorylated by Us3, while the serine residue at position 560 was not. (iii) The phosphorylation of gB Thr-887 in Vero cells infected with wild-type HSV-1 was specifically detected using an antibody that recognized phosphorylated serine or threonine residues with arginine at the −3 and −2 positions. (iv) The phosphorylation of gB Thr-887 in infected cells was dependent on the kinase activity of Us3. (v) The replacement of Thr-887 with alanine markedly upregulated the cell surface expression of gB in infected cells, whereas replacement with aspartic acid, which sometimes mimics constitutive phosphorylation, restored the wild-type phenotype. The upregulation of gB expression on the cell surface also was observed in cells infected with a recombinant HSV-1 encoding catalytically inactive Us3. These results supported the hypothesis that Us3 phosphorylates gB and downregulates the cell surface expression of gB in HSV-1-infected cells.     

A herpesvirus ribosome-associated, RNA-binding protein confers a growth advantage upon mutants deficient in a GADD34-related function

The herpes simplex virus type 1 gamma34.5 gene product and the cellular GADD34 protein both contain similar domains that can regulate the activity of eukaryotic initiation factor 2 (eIF2), a critical translation initiation factor. Viral mutants that lack the GADD34-related function grow poorly on a variety of malignant human cells, as activation of the cellular PKR kinase leads to the accumulation of inactive, phosphorylated eIF2 at late times postinfection. Termination of translation prior to the completion of the viral reproductive cycle leads to impaired growth. Extragenic suppressors that regain the ability to synthesize proteins efficiently in the absence of the viral GADD34-related function have been isolated. These suppressor alleles are dominant in trans and affect the steady-state accumulation of several viral mRNA species. We demonstrate that deregulated expression of Us11, a virus-encoded RNA-binding, ribosome-associated protein is necessary and sufficient to confer a growth advantage upon viral mutants that lack a GADD34-related function. Ectopic expression of Us11 reduces the accumulation of the activated cellular PKR kinase and allows for sustained protein synthesis. Thus, an RNA-binding, ribosome-associated protein (Us11) and a GADD34-related protein (gamma34.5) both function in a signal pathway that regulates translation by modulating eIF2 phosphorylation.     

pUL21 regulation of pUs3 kinase activity influences the nature of nuclear envelope deformation by the HSV-2 nuclear egress complex

It is well established that the herpesvirus nuclear egress complex (NEC) has an intrinsic ability to deform membranes. During viral infection, the membrane-deformation activity of the NEC must be precisely regulated to ensure efficient nuclear egress of capsids. One viral protein known to regulate herpes simplex virus type 2 (HSV-2) NEC activity is the tegument protein pUL21. Cells infected with an HSV-2 mutant lacking pUL21 (ΔUL21) produced a slower migrating species of the viral serine/threonine kinase pUs3 that was shown to be a hyperphosphorylated form of the enzyme. Investigation of the pUs3 substrate profile in ΔUL21-infected cells revealed a prominent band with a molecular weight consistent with that of the NEC components pUL31 and pUL34. Phosphatase sensitivity and retarded mobility in phos-tag SDS-PAGE confirmed that both pUL31 and pUL34 were hyperphosphorylated by pUs3 in the absence of pUL21. To gain insight into the consequences of increased phosphorylation of NEC components, the architecture of the nuclear envelope in cells producing the HSV-2 NEC in the presence or absence of pUs3 was examined. In cells with robust NEC production, invaginations of the inner nuclear membrane were observed that contained budded vesicles of uniform size. By contrast, nuclear envelope deformations protruding outwards from the nucleus, were observed when pUs3 was included in transfections with the HSV-2 NEC. Finally, when pUL21 was included in transfections with the HSV-2 NEC and pUs3, decreased phosphorylation of NEC components was observed in comparison to transfections lacking pUL21. These results demonstrate that pUL21 influences the phosphorylation status of pUs3 and the HSV-2 NEC and that this has consequences for the architecture of the nuclear envelope.     

Properties of the protein encoded by the UL32 open reading frame of herpes simplex virus 1.

The functions previously assigned to the essential herpes simplex virus 1 UL32 protein were in cleavage and/or packaging of viral DNA and in maturation and/or translocation of viral glycoproteins to the plasma membrane. The amino acid sequence predicts N-linked glycosylation sites and sequences conserved in aspartyl proteases and in zinc-binding proteins. We report the following. (i) The 596-amino-acid UL32 protein accumulated predominantly in the cytoplasm of infected cells but was not metabolically labeled with glucosamine and did not band with membranes containing a known glycoprotein in flotation sucrose density gradients. The UL32 protein does not, therefore, have the properties of an intrinsic membrane protein. (ii) Experiments designed to demonstrate aspartyl protease activity in a phage display system failed to reveal proteolytic activity. Moreover, substitution of Asp-110 with Gly in the sequence Asp-Thr-Gly, the hallmark of aspartyl proteases, had no effect on viral replication in Vero and SK-N-SH cell lines or in human foreskin fibroblasts. Therefore, if the UL32 protein functions as a protease, this function is not required in cells in culture. (iii) Both the native UL32 protein and a histidine-tagged UL32 protein made in recombinant baculovirus-infected insect cells bound zinc. The consensus sequence is conserved in the UL32 homologs from varicella-zoster virus and equine herpesvirus 1. UL32 protein is therefore a cysteine-rich, zinc-binding essential cytoplasmic protein whose function is not yet clear.     

Identification of an essential domain in the herpes simplex virus 1 UL34 protein that is necessary and sufficient to interact with UL31 protein

Previous results have indicated that the herpes simplex virus 1 UL31 and UL34 proteins interact and form a complex at the inner nuclear membranes of infected cells, where both play important roles in the envelopment of nucleocapsids at the inner nuclear membrane. In the work described here, mapping studies using glutathione S-transferase pull-down assays indicated that amino acids 137 to 181 of the UL34 protein are sufficient to mediate an interaction with the UL31 protein. A recombinant virus (v3480) lacking UL34 codons 138 to 181 was constructed. Similar to a UL34 null virus, v3480 failed to replicate on Vero cells and grew to a limited extent on rabbit skin cells. A UL34-expressing cell line restored v3480 growth and plaque formation. Similar to the localization of UL31 protein in cells infected with a UL34 null virus, the UL31 protein was present in the nuclei of Hep2 cells infected with v3480. Hep2 cells infected with v3480 contained the UL34 protein in the cytoplasm, the nucleus, and the nuclear membrane, and this was noted to be similar to the appearance of cells infected with a UL31 null virus. In transient expression assays, the interaction between UL34 amino acids 137 to 181 and the UL31 protein was sufficiently robust to target green fluorescent protein and emerin to intranuclear sites that contained the UL31 protein. These data indicate that amino acids 137 to 181 of the UL34 protein are (i) sufficient to mediate interactions with the UL31 protein in vitro and in vivo, (ii) necessary for the colocalization of UL31 and UL34 in infected cells, and (iii) essential for normal viral replication.