N-terminal mutants of herpes simplex virus type 2 gH are transported without gL but require gL for function

Glycoprotein H (gH) is conserved among all herpesviruses and is essential for virus entry and cell fusion along with gL, gB, and, in most alphaherpesviruses, gD. Within the gH/gL heterodimer, it is thought that gH accounts for the fusion function and gL acts as a chaperone for the folding and transport of gH. Here, we found that the N terminus of gH2 contains important elements involved in both its folding and its transport. Our conclusions are based on the phenotypes of a series of gH deletion mutants in which the signal sequence (residues 1 to 18) was retained and N-terminal residues were removed up to the number indicated. The first mutant, gH2Delta29 (deletion of residues 19 to 28), like wild-type (WT) gH, required gL for both transport and function. To our surprise, two other mutants (gH2Delta64 and gH2Delta72) were transported to the cell surface independent of gL but were nonfunctional, even when complexed with gL. Importantly, a fourth mutant (gH2Delta48) was transported independent of gL but was functional only when complexed with gL. Using a panel of monoclonal antibodies against gH2, we found that when gH2Delta48 was expressed alone, its antigenic structure differed from that of gH2Delta48/gL or gH2-WT/gL. Mutation of gH2 residue R39, Y41, W42, or D44 allowed gL-independent transport of gH. Our results also show that gL is not merely required for gH transport but is also necessary for the folding and function of the complex. Since gH2Delta64/gL and gH2Delta72/gL were nonfunctional, we hypothesized that residues critical for gH/gL function lie within this deleted region. Additional mutagenesis identified L66 and L72 as important for function. Together, our results highlight several key gH residues: R39, Y41, W42, and D44 for gH transport and L66 and L72 for gH/gL structure and function.     

Epitopes of herpes simplex virus type 1 glycoprotein gC are clustered in two distinct antigenic sites.

Epitopes of herpes simplex virus type 1 (HSV-1) strain KOS glycoprotein gC were identified by using a panel of gC-specific, virus-neutralizing monoclonal antibodies and a series of antigenic variants selected for resistance to neutralization with individual members of the antibody panel. Variants that were resistant to neutralization and expressed an antigenically altered form of gC were designated monoclonal antibody-resistant (mar) mutants. mar mutants were isolated at frequencies of 10(-3) to 10(-5), depending on the antibody used for selection. The epitopes on gC were operationally grouped into antigenic sites by evaluating the patterns of neutralization observed when a panel of 22 antibodies was tested against 22 mar mutants. A minimum of nine epitopes was identified by this process. Three epitopes were assigned to one antigenic site (I), and six were clustered in a second complex site (II) composed of three distinct subsites, IIa, IIb, and IIc. The two antigenic sites were shown to reside in physically distinct domains of the glycoprotein, by radioimmunoprecipitation of truncated forms of gC. These polypeptides lacked portions of the carboxy terminus and ranged in size from approximately one-half that of the wild-type molecule to nearly full size. Antibodies recognizing epitopes in site II immunoprecipitated the entire series of truncated polypeptides and thereby demonstrated that site II resided in the N-terminal half of gC. Antibodies reactive with site I, however, did not immunoprecipitate fragments smaller than at least two-thirds the size of the wild-type polypeptide, suggesting that site I was located in the C-terminal portion. Sites I and II were also shown to be spatially separate on the gC polypeptide by competition enzyme-linked immunosorbent assay with monoclonal antibodies representative of different site I and site II epitopes.     

A novel herpes simplex virus glycoprotein, gL, forms a complex with glycoprotein H (gH) and affects normal folding and surface expression of gH.

A glycoprotein encoded by the UL1 gene of herpes simplex virus type 1 (HSV-1) was detected in infected cells with antipeptide sera. The UL1 gene has previously been implicated in virus-induced cell fusion (S. Little and P. A. Schaffer, Virology 112:686-697, 1981). Two protein species, a 30-kDa precursor form and a 40-kDa mature form of the glycoprotein, both of which were modified with N-linked oligosaccharides, were observed. This novel glycoprotein is the 10th HSV-1 glycoprotein to be described and was named glycoprotein L (gL). A complex was formed between gL and gH, a glycoprotein known to be essential for entry of HSV-1 into cells and for virus-induced cell fusion. Previously, it had been reported that gH expressed in the absence of other viral proteins was antigenically abnormal, not processed, and not expressed at the cell surface (U.A. Gompels and A. C. Minson, J. Gen. Virol. 63:4744-4755, 1989; A. J. Forrester, V. Sullivan, A. Simmons, B. A. Blacklaws, G. L. Smith, A. A. Nash, and A. C. Minson, J. Gen. Virol. 72:369-375, 1991). However, gH coexpressed with gL by using vaccinia virus recombinants was antigenically normal, processed normally, and transported to the cell surface. Similarly, gL was dependent on gH for proper posttranslational processing and cell surface expression. These results suggest that it is a hetero-oligomer of gH and gL which is incorporated into virions and transported to the cell surface and which acts during entry of virus into cells.     

The nucleotide sequence of herpes simplex virus type 2 (333) glycoprotein gB2 and analysis of predicted antigenic sites

The gene coding for glycoprotein B2 (gB2) of herpes simplex virus type 2 (HSV-2) strain 333 was mapped and its nucleotide sequence determined. Open reading frame analysis deduced a polypeptide consisting of 902 amino acids and having close homology to gB1 of HSV type 1. Several predicted features of gB2 are consistent with a membrane-bound glycoprotein, i.e., a signal peptide sequence, a hydrophilic extracellular domain containing possible N-linked glycosylation sites, a hydrophobic membrane spanning sequence, and a cytoplasmic domain. Computer analysis on hydrophilicity, accessibility, and flexibility of the gB2 amino acid sequence, produced a composite surface value plot. At least nine major antigenic regions were predicted on the extracellular domain. The amino acids between residues 59-74, 127-139, 199-205, 460-476, and 580-594 exhibited the highest surface values. Comparison of the primary sequence with gB1 revealed localized regions showing amino acid diversity. Several of these locations correspond to major antigenic regions. Chou and Fasman analyses indicated that the amino acid substitutions, between positions 57-66, 461-472, and 473-481, induced changes in the secondary structure of gB. These sites could represent site-specific epitopes in the gB polypeptide.     

Fine mapping of antigenic site II of herpes simplex virus glycoprotein D.

Glycoprotein D (gD) is a virion envelope component of herpes simplex virus types 1 (HSV-1) and 2 (HSV-2) which plays an important role in viral infection and pathogenesis. Previously, anti-gD monoclonal antibodies (MAbs) were arranged into groups which recognize distinct type-common and type-specific sites on HSV-1 gD (gD-1) and HSV-2 gD (gD-2). Several groups recognize discontinuous epitopes which are dependent on tertiary structure. Three groups, VII, II, and V, recognize continuous epitopes present in both native and denatured gD. Previously, group II consisted of a single MAb, DL6, whose epitope was localized between amino acids 268 and 287. In the study reported here, we extended our analysis of the antigenic structure of gD, concentrating on continuous epitopes. The DL6 epitope was localized with greater precision to residues 272 to 279. Four additional MAbs including BD78 were identified, each of which recognizes an epitope within residues 264 to 275. BD78 and DL6 blocked each other in binding to gD. In addition, a mutant form of gD was constructed in which the proline at 273 was replaced by serine. This change removes a predicted beta turn in gD. Neither antibody reacted with this mutant, indicating that the BD78 and DL6 epitopes overlap and constitute an antigenic site (site II) within residues 264 to 279. A separate antigenic site (site XI) was recognized by MAb BD66 (residues 284 to 301). This site was only six amino acids downstream of site II, but was distinct as demonstrated by blocking studies. Synthetic peptides mimicking these and other regions of gD were screened with polyclonal antisera to native gD-1 or gD-2. The results indicate that sites II, V, VII, and XI, as well as the carboxy terminus, are the major continuous antigenic determinants on gD. In addition, the results show that the region from residues 264 through 369, except the transmembrane anchor, contains a series of continuous epitopes.     

Physical mapping of the herpes simplex virus type 2 nuc- lesion affecting alkaline exonuclease activity by using herpes simplex virus type 1 deletion clones

The nuc- lesion affecting alkaline exonuclease activity in the herpes simplex virus type 2 (HSV-2) mutant ts1348 had previously been mapped to the EcoRI-D restriction enzyme fragment of HSV-1. Eight clones with deletions representing most of HSV-1 EcoRI fragment D were selected with lambda gtWES hybrids. These clones were tested for their ability to rescue the alkaline exonuclease activity of HSV-2 nuc- ts1348 virus. The sequences colinear with the HSV-2 nuc- lesion were found to map between 0.169 and 0.174 map units on the HSV-1 Patton genome, representing an 0.8-kilobase-pair region that is 12.9 to 13.7 kilobase pairs from the left end of HSV-1 EcoRI fragment D.     

ND10 components relocate to sites associated with herpes simplex virus type 1 nucleoprotein complexes during virus infection

Infections with DNA viruses commonly result in the association of viral genomes and replication compartments with cellular nuclear substructures known as promyelocytic leukemia protein (PML) nuclear bodies or ND10. While there is evidence that viral genomes can associate with preexisting ND10, we demonstrate in this study by live-cell microscopy that structures resembling ND10 form de novo and in association with viral genome complexes during the initial stages of herpes simplex virus type 1 (HSV-1) infection. Consistent with previous studies, we found that the major ND10 proteins PML, Sp100, and hDaxx are exchanged very rapidly between ND10 foci and the surrounding nucleoplasm in live cells. The dynamic nature of the individual protein molecule components of ND10 provides a mechanism by which ND10 proteins can be recruited to novel sites during virus infection. These observations explain why the genomes and replication compartments of DNA viruses that replicate in the cell nucleus are so commonly found in association with ND10. These findings are discussed with reference to the nature, location, and potential number of HSV-1 prereplication compartments and to the dynamic aspects of HSV-1 genomes and viral products during the early stages of lytic infection.     

单纯疱疹病毒2型潜伏相关转录体ORF1的表达及其抗凋亡作用

旨在研究单纯疱疹病毒2型潜伏相关转录体 (LAT) 开放读码框1 (ORF1) 对放线菌素D诱导的凋亡作用的影响。以HSV-2 333基因组为模板PCR扩增ORF1片段,构建重组质粒pEGFP-ORF1,转染Vero细胞,RT-PCR鉴定ORF1的表达。放线菌素D诱导Vero细胞凋亡,通过荧光显微镜观察凋亡小体,Hochest33258荧光染色观察细胞形态变化,MTT检测细胞活性,流式细胞术检测细胞凋亡率。双酶切和测序确认pEGFP-ORF1构建成功,RT-PCR表明该真核表达载体能在Vero细胞中高效表达。转染了pEGFP-ORF1的Vero细胞经放线菌素D凋亡诱导后,Hochest33258染色显示细胞形态正常。MTT结果表明转染了重组质粒pEGFP-ORF1的Vero细胞经放线菌素D凋亡诱导后Vero细胞活性与未经任何处理的正常对照组相比,无显著差异 (P＞0.05),但高于放线菌素D诱导凋亡的Vero细胞组及与转染空质粒pEGFP-C2且放线菌素D诱导凋亡的Vero细胞组,差异具有统计学意义 (P＜0.05)。流式结果表明,转染重组质粒pEGFP-ORF1且经放线菌素D诱导凋亡组与正常对照组凋亡率差异不显著 (P＞0.05),而显著低于放线菌素D诱导凋亡组和转染空质粒pEGFP-C2且经放线菌素D诱导凋亡组 (P＜0.05)。HSV-2 LAT ORF1具有抗放线菌素D诱导的Vero细胞的凋亡作用。     

Ribonucleotide reductase of herpes simplex virus type 2 resembles that of herpes simplex virus type 1.

The ribonucleotide reductase (ribonucleoside-diphosphate reductase; EC 1.17.4.1) induced by herpes simplex virus type 2 infection of serum-starved BHK-21 cells was purified to provide a preparation practically free of both eucaryotic ribonucleotide reductase and contaminating enzymes that could significantly deplete the substrates. Certain key properties of the herpes simplex virus type 2 ribonucleotide reductase were examined to define the extent to which it resembled the herpes simplex virus type 1 ribonucleotide reductase. The herpes simplex virus type 2 ribonucleotide reductase was inhibited by ATP and MgCl2 but only weakly inhibited by the ATP X Mg complex. Deoxynucleoside triphosphates were at best only weak inhibitors of this enzyme. ADP was a competitive inhibitor (K'i, 11 microM) of CDP reduction (K'm, 0.5 microM), and CDP was a competitive inhibitor (K'i, 0.4 microM) of ADP reduction (K'm, 8 microM). These key properties closely resemble those observed for similarly purified herpes simplex virus type 1 ribonucleotide reductase and serve to distinguish these virally induced enzymes from other ribonucleotide reductases.     

Shared antigenic determinants between two distinct classes of proteins in cells infected with herpes simplex virus

Guinea pig antisera and mouse monoclonal antibodies against a 40,000-molecular-weight nucleocapsid protein (p40) of herpes simplex virus types 1 and 2 immunoprecipitated 40,000- and 80,000-molecular-weight classes of soluble proteins from infected cell extracts. The soluble 40,000-molecular-weight protein class (intracellular p40) appeared as a cluster of three to four closely spaced bands of proteins having molecular weights ranging between 39,000 and 45,000, whereas the soluble 80,000-molecular-weight protein class (intracellular p80) appeared as a doublet of bands. The peptide map of intracellular p40 closely resembled the maps of the p40 and p45 proteins of nucleocapsids, but it showed both differences and similarities when compared with the peptide map of intracellular p80. Pulse-chase experiments suggested that intracellular p80 was not a precursor of intracellular p40. We conclude that the intracellular p40 and p80 protein classes share common antigenic determinants, presumably reflecting similar amino acid sequences, although they have distinct differences in protein structure.     

Localization of a type-specific antigenic site on herpes simplex virus type 2 glycoprotein D.

A herpes simplex virus type 1 strain isolated from a recurrent lesion of the nose reacted with monoclonal antibodies recognizing a type 2-specific site on glycoprotein D but not with monoclonal antibodies recognizing other type 2-specific sites. DNA sequence analysis of the glycoprotein D gene of the isolate revealed a single nucleotide alteration which changed the codon for asparagine to one encoding histidine at amino acid 97 in the protein. Histidine is located at this position in glycoprotein of herpes simplex virus type 2; thus, the monoclonal antibody 17 beta A3 recognizes an epitope located at this region of the protein.     

单纯疱疹病毒II型糖蛋白G主要抗原表位的表达和抗原性检测*

利用PCR拼接技术,合成含单纯疱疹病毒II型糖蛋白G(gG2)抗原表位（氨基酸序列第561～578位）的片段,并进一步利用基因工程技术获得该表位的双拷贝片段,克隆入pET-KDO表达载体进行原核表达。经IPTG诱导后,高效表达出分子量大小约为39,000D的融合蛋白,经Western-blot检测具有良好的抗原性。表达的融合蛋白经凝血酶切割和亲和层析纯化,得到双拷贝gG2（561～578aa）目的蛋白,经ELISA检测具有良好的灵敏度和特异性。该重组抗原的构建和表达可用于HSV-2特异性血清学诊断的研究。     

Fine structure analysis of type-specific and type-common antigenic sites of herpes simplex virus glycoprotein D

The fine structure of the antigenic determinants of herpes simplex virus type 1 and 2 glycoprotein D (gD) was analyzed to determine whether structural differences underlie the differential immunogenicity of these glycoproteins. A region common to herpes simplex virus type 1 and 2 gD (amino acid residues 11 to 19) and two sites specific for herpes simplex virus type 2 gD (one determined by proline at position 7, the other determined by asparagine at position 21) were localized within the N-terminal 23 amino acids of gD by synthesis of peptides and comparison of their cross-reactivity with antisera raised to herpes simplex virus type 1 and 2 gD. The secondary structure of these peptides, as predicted by computer analysis, is discussed in relation to their immunogenicity.     

Molecular cloning of herpes simplex virus type 2 DNA

Restriction enzyme HindIII digestion of the whole genome of herpes simplex virus type 2 strain 186 yielded 10 DNA fragments with molecular weights ranging from approximately 22 X 10(6) to 1.2 X 10(6), which were cloned into the HindIII site of bacterial plasmid pACYC 184. The cloned fragments were identified by hybridization to HSV-2 virus DNA and by double digestion with restriction endonucleases. The recombinant plasmids, even if they carried DNA sequences with molecular weights of more than 10(7), were efficiently replicated in E. coli HB101.     

Hydrophobic alpha-helices 1 and 2 of herpes simplex virus gH interact with lipids, and their mimetic peptides enhance virus infection and fusion

Entry of herpes simplex virus into cells occurs by fusion and requires four glycoproteins. gD serves as the receptor binding glycoprotein. Of the remaining glycoproteins, gH carries structural and functional elements typical of class 1 fusion glycoproteins, in particular alpha-helix 1 (alpha-H1), with properties of a candidate fusion peptide, and two heptad repeats. Here, we characterized alpha-H2 and compared it to alpha-H1. alpha-H2 (amino acids 513 to 531) is of lower hydrophobicity than alpha-H1. Its deletion or mutation decreased virus infection and cell fusion. Its replacement with heterologous fusion peptides did not rescue infection and cell fusion beyond the levels exhibited by the alpha-H2-deleted gH. This contrasts with alpha-H1, which cannot be deleted and can be functionally replaced with heterologous fusion peptides (T. Gianni et al., J. Virol. 79:2931-2940, 2005). Synthetic peptides mimicking alpha-H1 and alpha-H2 induced fusion of nude lipid vesicles. Importantly, they increased infection of herpes simplex virus, pseudorabies virus, bovine herpesvirus 1, and vesicular stomatitis virus. The alpha-H1 mimetic peptide was more effective than the alpha-H2 peptide. Consistent with the findings that gH carries membrane-interacting segments, a soluble form of gH, but not of gD or gB, partitioned with lipid vesicles. Current findings highlight that alpha-H2 is an important albeit nonessential region for virus entry and fusion. alpha-H1 and alpha-H2 share the ability to target the membrane lipids; they contribute to virus entry and fusion, possibly by destabilizing the membranes. However, alpha-H2 differs from alpha-H1 in that it is of lower hydrophobicity and cannot be replaced with heterologous fusion peptides.     

Physical mapping of herpes simplex virus type 1 mutations by marker rescue.

Thirty temperature-sensitive mutants of encephalomyocarditis virus have been isolated and partially characterized. Fifteen of these mutants are phenotypically RNA+ thirteen are RNA-, and two are RNA +/-. Six RNA + mutants, one RNA- mutants, and one RNA +/- mutant have virions which are more thermosensitive at 56 degree C than the wild-type virions. Hela cells infected at the nonpermissive temperature with any of the RNA+ mutants produced neither infective nor noninfective viral particles. The cleavage of the precursor polypeptides in cells infected with 11 of the RNA+ mutants was defective at the nonpermissive temperature. This defect in cleavage occurred only in those precursor polypeptides leading to capsid proteins.     

Physical mapping of paar mutations of herpes simplex virus type 1 and type 2 by intertypic marker rescue.

Mutations (paar) in herpes simplex virus (HSV) which confer resistance to phosphonoacetic acid involve genes associated with virus-induced DNA polymerase activity. Two mutants of HSV (HSV-1 tsH and HSV-2 ts6) produce a thermolabile DNA polymerase activity. In this study, the ts lesions present in these mutants and those present in two independent phosphonoacetic acid-resistant mutants of HSV-1 and HSV-2 (paar-1 and paar-2) have been physically mapped by restriction endonuclease analysis of recombinants produced between HSV-1 and HSV-2 by intertypic marker rescue. All four mutations mapped within a 3.3-kilobase pair region around map unit 40. The accuracy of the method is reflected by the mapping results for tsH and paar-2, which were found to lie in the same 1.3-kilobase pair region. paar-1 was found to lie to the right of ts6. Virus-induced DNA polymerase is thought to have a molecular weight of 150,000, necessitating a gene with a coding capacity of 4.6 kilobase pairs. The four mutations mapped in this study all lie within a region smaller than this, but the results do not yet prove that all four lesions reside in this or any single gene.     

Identification of mar mutations in herpes simplex virus type 1 glycoprotein B which alter antigenic structure and function in virus penetration.

Analysis of six monoclonal antibody-resistant (mar) mutants in herpes simplex virus type 1 glycoprotein B identified two type-common (II and III) and two type-specific (I and IV) antigenic sites on this molecule. To derive additional information on the location of these sites, mar mutations were mapped and nucleotide alterations were identified by DNA sequencing. Each mutant carried a single amino acid substitution resulting from a G-to-A base transition. Alterations affecting antibody neutralization were identified at residues 473, 594, 305, and 85 for mutants in sites I through IV, respectively. Two clonally distinct site II antibodies each selected mar mutants (Gly to Arg at residue 594) that exhibited a reduction in the rate of entry (roe) into host cells. A site II mar revertant that regained sensitivity to neutralization by site II antibodies also showed normal entry kinetics. DNA sequencing of this virus identified a single base reversion of the site II mar mutation, resulting in restoration of the wild-type sequence (Arg to Gly). This finding demonstrated that the mar and roe phenotypes were the result of a single mutation. To further define structures that contributed to antibody recognition, monoclonal antibodies specific for all four sites were tested for their ability to immune precipitate a panel of linker-insertion mutant glycoprotein B molecules. Individual polypeptides that contained single insertions of 2 to 28 amino acids throughout the external domain were not recognized or were recognized poorly by antibodies specific for sites II and III, whereas no insertion affected antibody recognition of sites I and IV. mar mutations affecting either site II or III were previously shown to cause temperature-sensitive defects in glycoprotein B glycosylation, and variants altered in both these sites were temperature sensitive for virus production. Taken together, the data indicate that antigenic sites II and III are composed of higher-order structures whose integrity is linked with the ability of glycoprotein B to function in virus infectivity.