Inverted repeat regions of Marek''s disease virus DNA possess a structure similar to that of the a sequence of herpes simplex virus DNA and contain host cell telomere sequences.

The genomic structure of Marek's disease virus (MDV) is similar to those of the alphaherpesviruses herpes simplex virus (HSV) types 1 and 2. Sequence analysis of the junction region between the long component (L) and the short component (S) revealed the existence of an a-like sequence, similar in structure to the a sequence of HSV-1. Further study revealed that the MDV genome contains five copies of the a-like sequence within the long terminal repeat region as well as in the short terminal repeat region. The junction between the L and S components was found to contain 10 copies of the a-like sequence. Within the a-like sequence, a structure homologous to the DR2 of HSV was found to contain 17 copies of the telomeric sequence, GGGGTTA. There appears to be little to no sequence homology between the HSV a sequence and the MDV a-like sequence; however, the strong physical homology to its counterpart in HSV-1 suggests that the MDV a-like sequence may have the same functional homology (the domain for cleavage/packaging of the DNA into the viral capsids and for genomic inversion) as well.     

Amino acid substitutions in the V domain of nectin-1 (HveC) that impair entry activity for herpes simplex virus types 1 and 2 but not for Pseudorabies virus or bovine herpesvirus 1

The entry of herpes simplex virus (HSV) into cells requires the interaction of viral glycoprotein D (gD) with a cellular gD receptor to trigger the fusion of viral and cellular membranes. Nectin-1, a member of the immunoglobulin superfamily, can serve as a gD receptor for HSV types 1 and 2 (HSV-1 and HSV-2, respectively) as well as for the animal herpesviruses porcine pseudorabies virus (PRV) and bovine herpesvirus 1 (BHV-1). The HSV-1 gD binding domain of nectin-1 is hypothesized to overlap amino acids 64 to 104 of the N-terminal variable domain-like immunoglobulin domain. Moreover, the HSV-1 and PRV gDs compete for binding to nectin-1. Here we report that two amino acids within this region, at positions 77 and 85, are critical for HSV-1 and HSV-2 entry but not for the entry of PRV or BHV-1. Replacement of either amino acid 77 or amino acid 85 reduced HSV-1 and HSV-2 gD binding but had a lesser effect on HSV entry activity, suggesting that weak interactions between gD and nectin-1 are sufficient to trigger the mechanism of HSV entry. Substitution of both amino acid 77 and amino acid 85 in nectin-1 significantly impaired entry activity for HSV-1 and HSV-2 and eliminated binding to soluble forms of HSV-1 and HSV-2 gDs but did not impair the entry of PRV and BHV-1. Thus, amino acids 77 and 85 of nectin-1 form part of the interface with HSV gD or influence the conformation of that interface. Moreover, the binding sites for HSV and PRV or BHV-1 gDs on nectin-1 may overlap but are not identical.     

Herpes simplex virus 1 ICP22 regulates the accumulation of a shorter mRNA and of a truncated US3 protein kinase that exhibits altered functions

The U(S)3 open reading frame of herpes simplex virus 1 (HSV-1) was reported to encode two mRNAs each directing the synthesis of the same protein. We report that the U(S)3 gene encodes two proteins. The predominant U(S)3 protein is made in wild-type HSV-1-infected cells. The truncated mRNA and a truncated protein designated U(S)3.5 and initiating from methionine 77 were preeminent in cells infected with a mutant lacking the gene encoding ICP22. Both the wild-type and truncated proteins also accumulated in cells transduced with a baculovirus carrying the entire U(S)3 open reading frame. The U(S)3.5 protein accumulating in cells infected with the mutant lacking the gene encoding ICP22 mediated the phosphorylation of histone deacetylase 1, a function of U(S)3 protein, but failed to block apoptosis of the infected cells. The U(S)3.5 and U(S)3 proteins differ with respect to the range of functions they exhibit.     

US3 Protein Kinase of Herpes Simplex Virus 1 Blocks Caspase 3 Activation Induced by the Products of US1.5 and UL13 Genes and Modulates Expression of Transduced US1.5 Open Reading Frame in a Cell Type-Specific Manner

The coding domain of the herpes simplex virus type 1 (HSV-1) alpha22 gene encodes two proteins, the 420-amino-acid infected-cell protein 22 (ICP22) and U(S)1.5, a protein colinear with the carboxyl-terminal domain of ICP22. In HSV-1-infected cells, ICP22 and U(S)1.5 are extensively modified by the U(L)13 and U(S)3 viral protein kinases. In this report, we show that in contrast to other viral proteins defined by their properties as alpha proteins, U(S)1.5 becomes detectable and accumulated only at late times after infection. Moreover, significantly more U(S)1.5 protein accumulated in cells infected with a mutant lacking the U(L)13 gene than in cells infected with wild-type virus. To define the role of viral protein kinases on the accumulation of U(S)1.5 protein, rabbit skin cells or Vero cells were exposed to recombinant baculoviruses that expressed U(S)1.5, U(L)13, or U(S)3 proteins under a human cytomegalovirus immediate-early promoter. The results were as follows. (i) Accumulation of the U(S)1.5 protein was reduced by concurrent expression of the U(L)13 protein kinase and augmented by concurrent expression of the U(S)3 protein kinase. The magnitude of the reduction or increase in the accumulation of the U(S)1.5 protein was cell type dependent. The effect of U(L)13 kinase appears to be specific inasmuch as it did not affect the accumulation of glycoprotein D in cells doubly infected by recombinant baculoviruses expressing these genes. (ii) The reduction in accumulation of the U(S)1.5 protein was partially due to proteasome-dependent degradation. (iii) Both U(S)1.5 and U(L)13 proteins activated caspase 3, indicative of programmed cell death. (iv) Concurrent expression of the U(S)3 protein kinase blocked activation of caspase 3. The results are concordant with those published elsewhere (J. Munger and B. Roizman, Proc. Natl. Acad. Sci. USA 98:10410-10415, 2001) that the U(S)3 protein kinase can block apoptosis by degradation or posttranslational modification of BAD.     

Herpes B virus utilizes human nectin-1 but not HVEM or PILRα for cell-cell fusion and virus entry

To investigate the requirements of herpesvirus entry and fusion, the four homologous glycoproteins necessary for herpes simplex virus (HSV) fusion were cloned from herpes B virus (BV) (or macacine herpesvirus 1, previously known as cercopithecine herpesvirus 1) and cercopithecine herpesvirus 2 (CeHV-2), both related simian simplexviruses belonging to the alphaherpesvirus subfamily. Western blots and cell-based enzyme-linked immunosorbent assay (ELISA) showed that glycoproteins gB, gD, and gH/gL were expressed in whole-cell lysates and on the cell surface. Cell-cell fusion assays indicated that nectin-1, an HSV-1 gD receptor, mediated fusion of cells expressing glycoproteins from both BV and CeHV-2. However, herpesvirus entry mediator (HVEM), another HSV-1 gD receptor, did not facilitate BV- and CeHV-2-induced cell-cell fusion. Paired immunoglobulin-like type 2 receptor alpha (PILRα), an HSV-1 gB fusion receptor, did not mediate fusion of cells expressing glycoproteins from either simian virus. Productive infection with BV was possible only with nectin-1-expressing cells, indicating that nectin-1 mediated entry while HVEM and PILRα did not function as entry receptors. These results indicate that these alphaherpesviruses have differing preferences for entry receptors. The usage of the HSV-1 gD receptor nectin-1 may explain interspecies transfer of the viruses, and altered receptor usage may result in altered virulence, tropism, or pathogenesis in the new host. A heterotypic cell fusion assay resulting in productive fusion may provide insight into interactions that occur to trigger fusion. These findings may be of therapeutic significance for control of deadly BV infections.     

Structural features of nectin-2 (HveB) required for herpes simplex virus entry

One step in the process of herpes simplex virus (HSV) entry into cells is the binding of viral glycoprotein D (gD) to a cellular receptor. Human nectin-2 (also known as HveB and Prr2), a member of the immunoglobulin (Ig) superfamily, serves as a gD receptor for the entry of HSV-2, variant forms of HSV-1 that have amino acid substitutions at position 25 or 27 of gD (for example, HSV-1/Rid), and porcine pseudorabies virus (PRV). The gD binding region of nectin-2 is believed to be localized to the N-terminal variable-like (V) Ig domain. In order to identify specific amino acid sequences in nectin-2 that are important for HSV entry activity, chimeric molecules were constructed by exchange of sequences between human nectin-2 and its mouse homolog, mouse nectin-2, which mediates entry of PRV but not HSV-1 or HSV-2. The nectin-2 chimeric molecules were expressed in Chinese hamster ovary cells, which normally lack a gD receptor, and tested for cell surface expression and viral entry activity. As expected, chimeric molecules containing the V domain of human nectin-2 exhibited HSV entry activity. Replacement of either of two small regions in the V domain of mouse nectin-2 with amino acids from the equivalent positions in human nectin-2 (amino acids 75 to 81 or 89) transferred HSV-1/Rid entry activity to mouse nectin-2. The resulting chimeras also exhibited enhanced HSV-2 entry activity and gained the ability to mediate wild-type HSV-1 entry. Replacement of amino acid 89 of human nectin-2 with the corresponding mouse amino acid (M89F) eliminated HSV entry activity. These results identify two different amino acid sequences, predicted to lie adjacent to the C' and C" beta-strands of the V domain, that are critical for HSV entry activity. This region is homologous to the human immunodeficiency virus binding region of CD4 and to the poliovirus binding region of CD155.     

Recombinants between herpes simplex virus types 1 and 2: analyses of genome structures and expression of immediate early polypeptides.

Recombinants between temperature-sensitive mutants of herpes simplex virus types 1 (HSV-1) and 2 (HSV-2) were constructed. Using restriction endonucleases, we analyzed the genome composition of 17 intertypic recombinants and detected crossovers in every region of the genome. The virion DNA of one recombinant appeared to be largely "frozen" in two of the four possible genome arrangements of HSV. Knowledge of the genome structures of recombinants enabled us to physically map immediate early polypeptides. We present evidence that the immediate early polypeptide Vmw IE 110 of HSV-1 and its functionally equivalent polypeptide, Vmw IE 118, of HSV-2 may map in the repetitive sequences bounding the long unique region of HSV.     

Anatomy of herpes simplex virus (HSV) DNA. X. Mapping of viral genes by analysis of polypeptides and functions specified by HSV-1 X HSV-2 recombinants.

In an earlier paper (Morse et al., J. Virol 24:231--248, 1977) we reported on the provenance of the DNA sequences in 26 herpes simplex virus type 1 (HSV-1) X HSV-2 recombinants as determined from analyses of their DNAs with at least five restriction endonucleases. This report deals with the polypeptides specified by the recombinants and by their HSV-1 and HSV-2 parents. We have identified (i) the corresponding HSV-1 and HSV-2 polypeptides with molecular weights ranging from 20,000 to more than 200,000, (ii) the polypeptides that undergo rapid post-translational processing, and (iii) polypeptides that vary intratypically in apparent molecular weight. By comparing the segregation patterns of the polypeptides with those of the DNA sequence of the recombinants, we have mapped the templates specifying 26 polypeptides and several viral functions on the physical map of HSV DNA. The data show the following: (i) alpha polypeptides map at the termini of the L and S components of the HSV DNA. Although alpha ICP 27 maps entirely within the reiterated region of the L component, the template for alpha ICP 4 may lie only in part within the reiterated sequences of the S component. Of note is the finding that cells infected with a recombinant that contains both HSV-1 and HSV-2 DNA sequences in the S component produced alpha ICP 4 of both HSV-1 and HSV-2. (ii) Templates specifying beta and gamma polypeptides map in the L component and appear to be randomly distributed. (iii) Thymidine kinase and resistance to phosphonoacetic acid mapped in the L component. In addition, we have taken advantage of the rapid inhibition of host protein synthesis characteristic of HSV-2 infections and syncytial plaque morphology to also map the template(s) responsible for these functions in the L component. The implications of the template arrangement in HSV DNA are discussed.     

Rapid detection of HSV from cytologic specimens collected into ThinPrep fixative

OBJECTIVE: Herpes simplex virus (HSV) infection is associated with substantial morbidity and mortality in neonates. A diagnosis of HSV on cervical cytologic studies could lead to a cesarean section, with an increase in the risk of maternal morbidity. The identification of viral lesions in sexually active women has medical and social implications. There have been reports of false positive diagnoses of HSV in patients with altered endocervical cells and with cervical intraepithelial neoplasia 3. We evaluated a polymerase chain reaction (PCR)-based assay to detect HSV-1 and HSV-2 in routinely collected cervical cytology specimens in ThinPrep fixative (Cytyc Corp., Marlborough, Massachussets, U.S.A.). STUDY DESIGN: DNA was extracted from five cases that demonstrated cytologic changes suggestive of an HSV infection. PCR amplification with subsequent gel electrophoresis was performed to detect the presence of HSV. RESULTS: HSV DNA was detected in three of five cases that were cytologically diagnosed as suspicious or strongly suspicious for HSV infection. CONCLUSION: The combination of the ThinPrep liquid-based method for cervical cytology with PCR allows prompt confirmation of the diagnosis of HSV without sacrificing the diagnostic morphology on the slide.     

Locations of herpes simplex virus type 2 glycoprotein B epitopes recognized by human serum immunoglobulin G antibodies.

Herpes simplex virus type 2 (HSV-2) glycoprotein B (gB-2) gene segments were expressed as recombinant proteins in Escherichia coli. gB-2 recombinant proteins were reacted with human serum immunoglobulin G (IgG) antibodies in Western immunoblot assays. Initially, samples were tested for the presence of HSV-1-specific antibodies and HSV-2-specific antibodies by using HSV-infected cell lysates as antigen targets in Western blot assays. Serum samples that contained HSV-2-specific IgG (n = 58), HSV-1-specific IgG (n = 33), or no detectable HSV antibodies (n = 31) were tested for reactivities with the gB-2 recombinant proteins. In 58 of 58 samples that contained HSV-2-specific IgG, antibodies were present that reacted strongly with a gB-2 amino-proximal segment between amino acids (aa) 18 and 75. Three of 33 serum samples that contained HSV-1- and not HSV-2-specific IgG (as defined by the HSV lysate Western blot assay) reacted with this segment. Both HSV-2 antibodies and HSV-1 antibodies reacted strongly with a carboxy-terminal gB-2 segment between aa 819 and 904; a second minor cross-reactive region was mapped to a gB-2 segment between aa 564 and 626. The gB-2 segment from aa 18 to 75 may constitute a useful reagent for the virus type-specific serodiagnosis of HSV-2 infections. Further studies will be required to determine the relative sensitivities and specificities of the assay for gB-2 aa 18 to 75, HSV gG assays, and HSV lysate Western blot assays for detecting virus type-specific antibody responses in acute and chronic HSV-2 infections.     

Human cytotoxic T cell clones directed against herpes simplex virus-infected cells. III. Analysis of viral glycoproteins recognized by CTL clones by using recombinant herpes simplex viruses

Human cytotoxic T cell (CTL) clones specific for herpes simplex virus (HSV) type 1- and type 2-infected cells were generated and were analyzed with regard to the viral glycoproteins they recognize on autologous HSV-infected cells. By use of target cells infected with wild-type HSV strains, a gC deletion mutant of HSV-1, and HSV-1 X HSV-2 intertypic recombinants, some HSV-1-specific CTL clones were found to be directed against L region-encoded gA/B-1, and others against S region-encoded glycoproteins (gD-1 or gE-1). Some HSV-2-specific clones were found to be directed against L region-encoded gC-2, whereas others were directed against S region-encoded glycoproteins (gD-2, gE-2, or gG). These findings provide direct evidence that several HSV glycoproteins that are expressed on the surface of HSV-infected cells serve as recognition structures for human HSV-specific CTL.     

Size, Composition, and Structure of the Deoxyribonucleic Acid of Herpes Simplex Virus Subtypes 1 and 2

Studies of the size, composition, and structure of the deoxyribonucleic acid (DNA) of the F and G prototypes of herpes simplex virus (HSV) subtypes 1 and 2 (HSV-1 and HSV-2) showed the following. (i) As previously reported by Good-heart et al. HSV-1 and HSV-2 DNA have a buoyant density of 1.726 and 1.728 g/cm(3), corresponding to 67 and 69 guanine +/- cytosine moles per cent, respectively. The difference in guanine plus cytosine content of the DNA species was confirmed by the finding of a 1 C difference in T(m). (ii) The DNA from purified virus on cocentrifugation with T4 DNA in neutral sucrose density gradients sedimented at 55S, corresponding to 99 +/- 5 million daltons in molecular weight. HSV-1 and HSV-2 DNA could not be differentiated with respect to size. (iii) Cosedimentation of alkali-denatured DNA from purified virus with T4 DNA on alkaline sucrose density gradients consistently yielded several bands of single-stranded HSV DNA ranging from fragments 7 x 10(6) daltons to intact strands 48 x 10(6) daltons in molecular weight.     

Second-site mutation outside of the U(S)10-12 domain of Deltagamma(1)34.5 herpes simplex virus 1 recombinant blocks the shutoff of protein synthesis induced by activated protein kinase R and partially restores neurovirulence.

Earlier studies have shown that herpes simplex virus type 1 (HSV-1) activated protein kinase R (PKR) but that the product of the product of the gamma(1)34.5 gene binds and redirects the host phosphatase 1 to dephosphorylate the alpha subunit of eukaryotic translation initiation factor 2 (eIF-2alpha). In consequence, the gamma(1)34.5 gene product averts the threatened shutoff of protein synthesis caused by activated PKR. Serial passages of Deltagamma(1)34.5 mutants in human cells led to isolation of two classes of second-site, compensatory mutants. The first, reported earlier, resulted from the juxtaposition of the alpha promoter of the U(S)12 gene to the coding sequence of the U(S)11 gene. The mutant blocks the phosphorylation of eIF-2alpha but does not restore the virulence phenotype of the wild-type virus. We report another class of second-site, compensatory mutants that do not map to the U(S)10-12 domain of the HSV-1 genome. All mutants in this series exhibit sustained late protein synthesis, higher yields in human cells, and reduced phosphorylation of PKR that appears to be phosphatase dependent. Specific dephosphorylation of eIF-2alpha was not demonstrable. At least one mutant in this series exhibited a partial restoration of the virulence phenotype characteristic of the wild-type virus phenotype. The results suggest that the second-site mutations reflect activation of fossilized functions designed to block the interferon response pathways in cells infected with the progenitor of present HSV.     

HSV neutralization by the microbicidal candidate C5A

Genital herpes is a major risk factor in acquiring human immunodeficiency virus type-1 (HIV-1) infection and is caused by both Herpes Simplex virus type 1 (HSV-1) and HSV-2. The amphipathic peptide C5A, derived from the non-structural hepatitis C virus (HCV) protein 5A, was shown to prevent HIV-1 infection but neither influenza nor vesicular stomatitis virus infections. Here we investigated the antiviral function of C5A on HSV infections. C5A efficiently inhibited both HSV-1 and HSV-2 infection in epithelial cells in vitro as well as in an ex vivo epidermal infection model. C5A destabilized the integrity of the viral HSV membrane. Furthermore, drug resistant HSV strains were inhibited by this peptide. Notably, C5A-mediated neutralization of HSV-1 prevented HIV-1 transmission. An in vitro HIV-1 transmigration assay was developed using primary genital epithelial cells and HSV infection increased HIV-1 transmigration. Treatment with C5A abolished HIV-1 transmigration by preventing HSV infection and by preserving the integrity of the genital epithelium that was severely compromised by HSV infection. In conclusion, this study demonstrates that C5A represents a multipurpose microbicide candidate, which neutralizes both HIV-1 and HSV, and which may interfere with HIV-1 transmission through the genital epithelium.     

Construction of an excisable bacterial artificial chromosome containing a full-length infectious clone of herpes simplex virus type 1: viruses reconstituted from the clone exhibit wild-type properties in vitro and in vivo

In recent years, several laboratories have reported on the cloning of herpes simplex virus type 1 (HSV-1) genomes as bacterial artificial chromosomes (BACs) in Escherichia coli and on procedures to manipulate these genomes by using the bacterial recombination machinery. However, the HSV-BACs reported so far are either replication incompetent or infectious, with a deletion of one or more viral genes due to the BAC vector insertion. For use as a multipurpose clone in research on HSV-1, we attempted to generate infectious HSV-BACs containing the full genome of HSV-1 without any loss of viral genes. Our results were as follows. (i) E. coli (YEbac102) harboring the full-length HSV-1 genome (pYEbac102) in which a BAC flanked by loxP sites was inserted into the intergenic region between U(L)3 and U(L)4 was constructed. (ii) pYEbac102 was an infectious molecular clone, given that its transfection into rabbit skin cells resulted in production of infectious virus (YK304). (iii) The BAC vector sequence was almost perfectly excisable from the genome of the reconstituted virus YK304 by coinfection of Vero cells with YK304 and a recombinant adenovirus, AxCANCre, expressing Cre recombinase. (iv) As far as was examined, the reconstituted viruses from pYEbac102 could not be phenotypically differentiated from wild-type viruses in vitro and in vivo. Thus, the viruses grew as well in Vero cells as did the wild-type virus and exhibited wild-type virulence in mice on intracerebral inoculation. (v) The infectious molecular clone pYEbac102 is in fact useful for mutagenesis of the HSV-1 genome by bacterial genetics, and a recombinant virus carrying amino acid substitutions in both copies of the alpha0 gene was generated. pYEbac102 will have multiple applications to the rapid generation of genetically engineered HSV-1 recombinants in basic research into HSV-1 and in the development of HSV vectors in human therapy.     

Site-Directed Mutagenesis of the Virion Host Shutoff Gene (UL41) of Herpes Simplex Virus (HSV): Analysis of Functional Differences between HSV Type 1 (HSV-1) and HSV-2 Alleles

During lytic herpes simplex virus (HSV) infections, the HSV virion host shutoff protein (UL41) accelerates the turnover of host and viral mRNAs. Although the UL41 polypeptides from HSV type 1 (HSV-1) strain KOS and HSV-2 strain 333 are 87% identical, HSV-2 strains generally shut off the host more rapidly and completely than HSV-1 strains. In a previous study, we identified three regions of the HSV-2 UL41 polypeptide (amino acids 1 to 135, 208 to 243, and 365 to 492) that enhance the activity of KOS when substituted for the corresponding portions of the KOS protein (D. N. Everly, Jr., and G. S. Read, J. Virol. 71:7157-7166, 1997). These results have been extended through the analysis of more than 50 site-directed mutants of UL41 in which selected HSV-2 amino acids were introduced into an HSV-1 background and HSV-1 amino acids were introduced into the HSV-2 allele. The HSV-2 amino acids R22 and E25 were found to contribute dramatically to the greater activity of the HSV-2 allele, as did the HSV-2 amino acids A396 and S423. The substitution of six HSV-2 amino acids between residues 210 and 242 enhanced the HSV-1 activity to a lesser extent. In most cases, individual substitutions or the substitution of combinations of fewer than all six amino acids reduced the UL41 activity to less than that of KOS. The results pinpoint several type-specific amino acids that are largely responsible for the greater activity of the UL41 polypeptide of HSV-2. In addition, several spontaneous mutations that abolish detectable UL41 activity were identified.