Genetic analysis of temperature-sensitive mutants of HSV-1: the combined use of complementation and physical mapping for cistron assignment

Characterization of major recognition sequences for a herpes simplex virus type 1 origin-binding protein

To investigate early initiation events in the replication of herpes simplex virus type 1, we analyzed interactions of proteins from infected cell extracts with the small origin of herpes simplex virus type 1 (oris1). Using the mobility shift assay, we detected two origin-specific binding interactions. We characterized the more prominent interaction on both strands of the DNA duplex with DNase I protection and methylation interference assays. Protein binding protects 17 bases of DNA on each strand from DNase I. These sequences are located at the left end of the central palindrome and are shifted four bases relative to one another. On the basis of the DNase protection pattern, we believe this protein to be related to the origin-binding protein defined by Elias et al. (P. Elias, M.E. O'Donnell, E.S. Mocarski, and I.R. Lehman, Proc. Natl. Acad. Sci. 83:6322-6326, 1986). Our DNase I footprint shows both strong and weak areas of protection. The regions strongly protected from DNase I align with the essential contact residues identified by interference footprinting. Methylation interference defines a small binding domain of 8 base pairs: 5'-GTTCGCAC-3'/3'-CAAGCGTG-5'. This recognition sequence contains two inverted 5'-GT(T/G)CG-3' repeats which share a 2-base overlap; thus, the origin-binding protein probably binds to the inverted repeats as a dimer.

Herpes simplex virus glycoprotein D is sufficient to induce spontaneous pH-independent fusion in a cell line that constitutively expresses the glycoprotein

Spontaneous small polykaryocytes were detected in a cell line designated BJ-o that harbors the BamHI J fragment of herpes simplex virus 1 DNA and expresses constitutively glycoprotein D (gD). The fusion activity of BJ-o cells correlated with gD production and was drastically reduced following exposure of the cells to monoclonal antibody HD1 to gD. Studies on the characteristics and requirements of cell fusion dependent on gD led to the conclusion that the characteristics and requirements for gD-mediated fusion activity of BJ-o cells are similar to those previously reported for cell fusion induced by the virus in that (i) polykaryocytosis was not augmented by exposure to medium of low pH with or without prior exposure to trypsin, (ii) the number of polykaryocytes was reduced following removal of terminal sialic acid residues by neuraminidase, and (iii) the number of polykaryocytes was augmented by masking of high-mannose N-linked oligosaccharides with concanavalin A or with its reduced form, succinyl concanavalin A. This effect was reversed by competition with mannose.

UL5, a protein required for HSV DNA synthesis: genetic analysis, overexpression in Escherichia coli, and generation of polyclonal antibodies

The mutations in two DNA-negative ts mutants of herpes simplex virus type 1 (HSV-1), tsK13 and tsM19, have been previously mapped to a 2.0-kb fragment (coordinates 0.095-0.108) at the left end of the genome (S. Weller, D. Aschman, W. Sacks, D. Coen, and P. Schaffer, 1983, Virology 130, 290-305). Sequence analysis of the HSV-1 genome has revealed the existence of two open reading frames, UL5 and UL6, within this fragment (D. McGeoch, M. Dalrymple, A. Dolan, D. McNab, L. Perry, P. Taylor, and M. Challberg, 1988, J. Virol. 62, 444-453). In this paper we report fine mapping and sequence analysis of the mutations in tsK13 and tsM19 which unambiguously localize the mutations to UL5, predicted to encode a 99-kDa polypeptide. The mutation in tsK13 was shown to result in a single amino acid substitution, Pro236 to Leu, whereas tsM19 contains two substitutions, Pro236 to Ser and Ala249 to Val. Thus, both mutants are altered in Pro236. Temperature-shift experiments indicated that the UL5 gene product is required continuously during viral DNA synthesis, suggesting a direct role for the 99K protein in viral DNA synthesis. The UL5 gene product was overexpressed in Escherichia coli and used to generate polyclonal antibodies which detected proteins in HSV-1-infected cell extracts from 4 hr postinfection. Although a faint band of the predicted size (99 kDa) was observed, the majority of the immunoreactive material migrated as smaller bands which represent either proteolytic degradation during extraction or post-translational proteolytic modification of the UL5 gene product. Indirect immunofluorescence staining revealed that the UL5 gene product localizes to the nucleus in two patterns: diffuse staining throughout the nucleus and in discrete globules which appear at the periphery of the nucleus. Sequence analysis of the UL5 gene predicts that the 99-kDa protein contains a consensus sequence for an ATP binding site. Possible roles of this protein in viral DNA synthesis are discussed.

A DNA helicase induced by herpes simplex virus type 1

We have identified and partially purified a DNA-dependent ATPase that is present specifically in herpes simplex virus type 1-infected Vero cells. The enzyme which has a molecular weight of approximately 440,000 differs from the comparable host enzyme in its elution from phosphocellulose columns and in its nucleoside triphosphate specificity. The partially purified DNA-dependent ATPase is also a DNA helicase that couples ATP or GTP hydrolysis to the displacement of an oligonucleotide annealed to M13 single-stranded DNA. The enzyme requires a 3' single-stranded tail on the duplex substrate, suggesting that the polarity of unwinding is 5'----3' relative to the M13 DNA. The herpes specific DNA helicase may therefore translocate on the lagging strand in the semidiscontinuous replication of the herpes virus 1 genome.

Analysis of the transcript of the herpes simplex virus DNA polymerase gene provides evidence that polymerase expression is inefficient at the level of translation

We have mapped the termini and determined the relative abundance and ribosome density of the major cytoplasmic transcript of the DNA polymerase (pol) gene of herpes simplex virus type 1. Nuclease protection and primer extension analyses located the 5' end of the major pol transcript at two closely spaced sites 51 and 57 nucleotides to the left of a BamHI site at map position 0.413. S1-sensitive sites corresponding to additional minor transcripts were found to map further upstream within a palindromic sequence that contains a viral replication origin. The major 3' end was found to map 90 nucleotides upstream of a KpnI site at map position 0.439. Quantitative S1 nuclease assays revealed that pol transcripts were nearly as abundant as transcripts encoded by the viral thymidine kinase gene. However, relatively few pol transcripts were found on large polysomes at 5.5 h after infection, when pol transcripts were most abundant. This was in marked contrast to the polyribosome distribution of transcripts from the thymidine kinase gene and the major DNA-binding protein gene. These results and sequence features of the pol transcript suggest that pol expression is regulated, in part, at the level of translation.

Induction of antibodies to the Epstein-Barr virus glycoprotein gp85 with a synthetic peptide corresponding to a sequence in the BXLF2 open reading frame

Epstein-Barr virus codes for at least three envelope glycoproteins, one of which, gp85, has not yet been mapped to the viral genome. The publication and analysis of the entire Epstein-Barr virus DNA sequence has allowed identification of open reading frames with potential for encoding membrane glycoproteins. To determine whether one of these candidate open reading frames, BXLF2, codes for gp85, an antibody was made to a 17-residue peptide derived from positions 518 to 533 of the predicted BXLF2 protein. The reactivity of the antipeptide antibody was then compared with that of the monoclonal antibody F-2-1, which was originally used to define and characterize gp85. Antipeptide antibody and F-2-1 immunoprecipitated glycosylated molecules with identical electrophoretic mobilities; digestion of the two immunoprecipitated proteins with V8 protease generated comparable peptides; and the antipeptide antibody reacted in Western immunoblots with the gp85 glycoprotein that had been immunoprecipitated by F-2-1 before transfer to nitrocellulose. In addition, a monospecific rabbit antibody, made against native gp85, reacted with the peptide used for immunization. These results are compatible with the hypothesis that the BXLF2 open reading frame codes for gp85.

Identification of the Epstein-Barr virus gp85 gene

The Epstein-Barr virus glycoprotein gp85 has been mapped to the Epstein-Barr virus DNA open reading frame BXLF2 (R. Baer, A. Bankier, M. Biggin, P. Deininger, P. Farrell, T. Gibson, G. Hatfull, G. Hudson, S. Stachwell, C. Sequin, P. Tufnell, and B. Barrell, Nature [London] 310:207-211, 1984). A gp85-specific monoclonal antibody reacts with the BXLF2 in vitro transcription-translation product. The monoclonal antibody also precipitates an 85-kilodalton protein from rodent cells transfected with the BXLF2 open reading frame DNA. In these cells, gp85 localizes to the cytoplasm and nuclear rim rather than to the plasma membrane as in lymphocytes. Northern (RNA) blot hybridization and analysis of a cDNA clone containing BXLF2 indicate that gp85 is translated from an unspliced, late, 2.5-kilobase transcript. Similarities between the predicted amino acid sequences of gp85 and herpes simplex virus gH (D. McGeoch and A. Davison, Nucleic Acids Res. 14:4281-4292, 1986) are noted.

Characterization of intranuclear capsids made by ts morphogenic mutants of HSV-1

We have characterized capsids made by seven temperature-sensitive (ts) mutants of HSV-1 previously shown to be defective in viral DNA processing and packaging at the nonpermissive temperature (NPT). The empty capsids isolated from mutant-infected cells at the NPT were devoid of DNA, cosedimented in sucrose with wt B capsids, and contained the same structural proteins found in wt B capsids (W. Gibson and B. Roizman (1972). J. Virol. 10, 1044-1052). The presence of VP22a in empty capsids suggests that the processing of this protein from higher-molecular-weight precursors and its association with capsids is required, but not sufficient, for DNA encapsidation. Mutants made no detectable A capsids at the NPT, but did so at the permissive temperature (PT), suggesting that A particles are generated during or subsequent to, rather than prior to, encapsidation. In temperature-shift experiments, it was demonstrated that capsids of one of the mutants, F18, made at the NPT did not participate in DNA encapsidation when cells were subsequently shifted to the PT. Only those capsids made after temperature shift to the PT acquired viral DNA, implying that the ts mutation in F18 may lie in a gene coding for a structural protein, or in a protein involved in the processing of viral DNA.

Localization of a herpes simplex virus neurovirulence gene dissociated from high-titer virus replication in the brain

Previous studies with the herpes simplex virus type 1 X type 2 intertypic recombinant RS6 suggested that the genomic region from 0.11 to 0.14 map units is involved in neurovirulence (R. T. Javier, R. L. Thompson, and J. G. Stevens, J. Virol. 61:1978-1984, 1987). To study this further, we isolated an RS6-derived herpes simplex virus intertypic recombinant (R13-1) which has a genetic defect within this area. After inoculation into mouse brains, R13-1 was found to be approximately 10,000-fold less neurovirulent than either the wild-type type 1 or type 2 parental virus. However, R13-1 replicated in the mouse brain to titers resembling those of the wild-type parents. Further comparisons with wild-type counterparts indicated that R13-1 expressed equivalent levels of the enzyme thymidine kinase and replicated to intermediate levels in primary mouse embryo fibroblasts maintained at the normal body temperature for mice. Using marker rescue techniques combined with in vivo selection, we found that recombination between unit-length R13-1 DNA and a cloned type 1 DNA fragment spanning the region from 0.11 to 0.14 map units (EcoRI-d, 0.079 to 0.192 map units) generated viruses with a wild-type neurovirulence phenotype. To further refine the genomic region of interest, we performed marker rescue experiments using two EcoRI-d subclones, EcoRI/BamHI dc (0.079 to 0.143 map units) and BamHI/EcoRI and (0.143 to 0.192 map units), representing the left and right halves of the EcoRI d fragment, respectively. In these experiments the EcoRI/BamHI dc clone, but not the BamHI/EcoRI ad clone, yielded recombinant viruses exhibiting wild-type neurovirulence. These results show that at least one herpes simplex virus gene function associated with neurovirulence is located within a 9.1-kilobase region at 0.079 to 0.143 map units of the viral genome. Perhaps more significantly, the results indicate that this neurovirulence property functions independently of high-titer virus replication in the brain.

Identification of herpes simplex virus type 1 genes required for origin-dependent DNA synthesis

The herpes simplex virus (HSV) genome contains both cis- and trans-acting elements which are important in viral DNA replication. The cis-acting elements consist of three origins of replication: two copies of oriS and one copy of oriL. It has previously been shown that five cloned restriction fragments of HSV-1 DNA together can supply all of the trans-acting functions required for the replication of plasmids containing oriS or oriL when cotransfected into Vero cells (M. D. Challberg, Proc. Natl. Acad. Sci. USA, 83:9094-9098, 1986). These observations provide the basis for a complementation assay with which to locate all of the HSV sequences which encode trans-acting functions necessary for origin-dependent DNA replication. Using this assay in combination with the data from large-scale sequence analysis of the HSV-1 genome, we have now identified seven HSV genes which are necessary for transient replication of plasmids containing either oriS or oriL. As shown previously, two of these genes encode the viral DNA polymerase and single-stranded DNA-binding protein, which are known from conventional genetic analysis to be essential for viral DNA replication in infected cells. The functions of the products of the remaining five genes are unknown. We propose that the seven genes essential for plasmid replication comprise a set of genes whose products are directly involved in viral DNA synthesis.

Entry of herpes simplex virus 1 in BJ cells that constitutively express viral glycoprotein D is by endocytosis and results in degradation of the virus

The BJ cell line which constitutively expresses herpes simplex virus 1 glycoprotein D is resistant to infection with herpes simplex viruses. Analysis of clonal lines indicated that resistance to superinfecting virus correlates with the expression of glycoprotein D. Resistance was not due to a failure of attachment to cells, since the superinfecting virus absorbed to the BJ cells. Electron microscopic studies showed that the virions are juxtaposed to coated pits and are then taken up into endocytic vesicles. The virus particles contained in the vesicles were in various stages of degradation. Viral DNA that reached the nucleus was present in fewer copies per BJ cell than that in the parental BHKtk- cells infected at the same multiplicity. Moreover, unlike the viral DNA in BHKtk- cells which was amplified, that in BJ cells decreased in copy number. The results suggest that the glycoprotein D expressed in the BJ cell line interfered with fusion of the virion envelope with the plasma membrane but not with the adsorption of the virus to cells and that the viral proteins that mediate adsorption to and fusion of membranes appear to be distinct.

Isolation and characterization of herpes simplex virus type 1 host range mutants defective in viral DNA synthesis

Cell lines were generated by cotransfection of Vero cells with pSV2neo and a plasmid containing the herpes simplex virus type 1 (HSV-1) EcoRI D fragment (coordinates 0.086 to 0.194). One such cell line (S22) contained the genes for alkaline exonuclease and several uncharacterized functions. Three mutant isolates of HSV-1 strain KOS which grew on S22 cells but not on normal Vero cells were isolated and characterized. All three mutants (hr27, hr48, and hr156) were defective in the synthesis of viral DNA and late proteins when grown in nonpermissive Vero cells. Early gene expression in cells infected with these host range mutants appeared to be normal at the nonpermissive condition. The mutations were mapped by marker rescue to a 1.5-kilobase fragment (coordinates 0.145 to 0.155). The mutation of one of these mutants, hr27, was more finely mapped to an 800-base-pair region (coordinates 0.145 to 0.151). This position of these mutations is consistent with the map location of a putative 94-kilodalton polypeptide as determined by sequence analysis (D. McGeoch, personal communication). Complementation studies demonstrated that these mutants formed a new complementation group, designated 1-36. The results presented in this report indicate that the 94-kilodalton gene product affected by these mutations may have a direct role in viral DNA synthesis.

Genetic and phenotypic characterization of mutants in four essential genes that map to the left half of HSV-1 UL DNA

Several HSV-1 proteins including the major capsid protein (VP5), two minor capsid proteins (VP11-12 and VP18.8), the alkaline nuclease and glycoprotein gH have been reported to be encoded by the left-most one-third of HSV-1 UL DNA. In this paper, we present physical mapping data and phenotypic analysis of six ts mutants whose mutations lie within this region and which collectively represent four functional complementation groups (1-6, 1-7, 1-10, and 1-26). In this study, mutants in complementation group 1-10 were found to be defective in the synthesis of viral DNA, late viral polypeptides, and the formation of mature capsid-like structures--properties characteristic of other ts mutants defective in functions required for viral DNA synthesis. Two DNA-positive mutants in complementation group 1-7 fail to induce capsid formation and probably possess mutations in coding sequences for VP5. Mutants in two other complementation groups (1-6 and 1-26) synthesize significant levels of viral DNA, late polypeptides, and capsids. The functions of the gene products represented by these mutants remain to be determined.

Alkaline nuclease activity in cells infected with herpes simplex virus type 1 (HSV-1) and HSV-1 temperature-sensitive mutants

An in situ assay has been adapted to the herpes simplex virus type 1 (HSV-1) system which can detect alkaline nuclease activity in infected cell lysates following sodium dodecylsulfate polyacrylamide gel electrophoresis. Lysates of cells infected with HSV-1 temperature-sensitive (ts) mutants possessing mutations in the genes for an immediate-early transcriptional regulatory protein (ICP4), viral DNA polymerase (pol), and the major HSV-1 DNA binding protein (ICP8) exhibited altered alkaline nuclease profiles relative to that of wild-type virus-infected cells at 39 degrees C. Infections with a control mutant defective in the gene for glycoprotein B yielded wild-type nuclease profiles. The diverse effects on alkaline nuclease expression of mutants with lesions in different viral proteins involved directly in viral DNA synthesis provides evidence for the cooperative interaction between HSV-encoded viral DNA replication components.

Amplification of acidic endothelial cell growth factor (ECGF) gene sequences in hamster DDT1-MF2 tumor cells

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DNA processing in temperature-sensitive morphogenic mutants of HSV-1

The anatomy of DNA synthesized by five HSV-1 mutants previously shown to accumulate predominantly empty capsids at the nonpermissive temperature (NPT) was analyzed with Bg/II restriction digestion. At the NPT, all five generated DNA lacking termini, indicating that in the absence of packaging, viral DNA is not processed to unit length. One mutant, F18, was able to process DNA made at the NPT to unit length molecules during a 6-hr period after shift to the permissive temperature. The appearance of unit length molecules correlated with the appearance of staphylococcal nuclease-resistant F18 DNA.

Effects of Bloom's syndrome fibroblasts on genetic recombination and mutagenesis of herpes simplex virus type 1

The effects of Bloom's syndrome (BS) fibroblasts on genetic recombination and the mutation frequency of herpes simplex virus type 1 (HSV-1) was determined by employing two factor crosses of selected temperature-sensitive (ts) mutants. A significant increase in the recombination frequency (RF) was observed in seven of nine crosses when multiple BS fibroblast lines were compared to normal human fibroblasts. The RF of HSV-1 ts mutants increased following 12-O-tetradecanoylphorbol-13-acetate (TPA) treatment of normal, but not BS fibroblasts, suggesting that BS fibroblasts express higher constitutive levels of genetic recombination activity. HSV-1 ts mutants demonstrated significantly higher reversion frequencies to the nontemperature sensitive (ts+) phenotype following growth in BS rather than normal fibroblasts, indicating that exogenous viral DNA encoding many of the enzymes necessary for its own replication is affected by the mutator phenotype of BS.

Physical mapping of two herpes simplex virus type 1 host shutoff loci: rescue of each ts mutation occurs with two unique cloned regions of the viral genome

Two complementing temperature-sensitive (ts) herpes simplex virus type 1 (HSV-1) mutants, PAA1rts1 and ts199, were defective in viral DNA synthesis and in the shutoff of cellular macromolecular synthesis at 39.5 degrees C, the nonpermissive temperature. PAA1sts1 and PAA1rts1+ recombinants and PAA1rts1+ revertants were used to examine the contributions of the PAA1r mutation and the ts1 mutation of PAA1rts1 in affecting the levels of viral and cellular DNA synthesized at 34 and 39.5 degrees C. The results of this study suggests an interaction between the viral DNA polymerase and the ts1+ gene product during HSV-1 DNA replication and possibly in the inhibition of host DNA synthesis by HSV-1. Physical mapping of the ts mutations present in ts199 and the PAA1sts1 recombinant ts1-8 were performed by intratypic marker rescue experiments. Surprisingly, both the ts1-8 and ts199 mutations were rescued by two cloned fragments: ts1-8 by BglII-K (map coordinates 0.095 to 0.163) and BglII-I (map coordinates 0.314 to 0.417), while ts199 was rescued by BglII-K and BglII-O (map coordinates 0.163 to 0.197). In more refined mapping experiments, the regions between coordinates 0.347 to 0.378 and 0.126 to 0.163 were able to rescue the ts1-8 mutation. Southern hybridization analysis confirmed that the fragments that rescued ts1-8 and those that rescued ts199 had homology, as predicted by the physical mapping results.

Herpes simplex virus gene products involved in the induction of chromosomal aberrations

The effect of short-term herpes simplex virus type 1 (HSV-1) infection on chromosomes of human diploid fibroblasts was examined. In addition to chromosomal breaks, gaps and pulverization, three kinds of cytogenetic damage (double minutes, polyploidy and endoreduplication) not yet reported following productive infection with HSV or other animal viruses were frequently observed. Consistent with previous studies suggesting that the expression of immediate-early and/or early viral gene products is required for the induction of chromosomal damage, was the observation that cells infected at the nonpermissive temperature with HSV-1 temperature-sensitive mutants defective in the gene for the immediate-early transcriptional regulatory protein, ICP4, and three early viral gene products--DNA polymerase (pol), the major HSV DNA-binding protein (ICP8) and an HSV-2 mutant defective in alkaline nuclease--exhibited altered patterns of chromosomal damage relative to the effects of wild-type virus on infected cells. These findings suggest a direct or indirect role for all four gene products in the induction of chromosomal damage. In cells infected with wild-type virus for 4 h or longer, HSV proved to be a more potent mitotic arresting agent than colcemid. Moreover, studies with selected mutants indicate that HSV pol specifically may be involved in mitotic arrest. Additionally, in cells infected at the non-permissive temperature with a pol mutant, the number of polyploid metaphases was reduced 4-fold relative to that seen in wild-type virus-infected cells suggesting a role for HSV pol in the amplification of cellular DNA.

Activation of immediate-early, early, and late promoters by temperature-sensitive and wild-type forms of herpes simplex virus type 1 protein ICP4

To better define the activities on herpes simplex virus type 1 gene expression of temperature-sensitive and wild-type forms of the transcriptional regulatory protein ICP4, regulatory sequences from immediate-early, early, and late herpes simplex virus genes were fused to the gene for chloramphenicol acetyltransferase (CAT). These constructs were used in trans induction and cotransfection experiments with wild-type and temperature-sensitive mutant alleles of ICP4. The ICP4 genes used in this study were cloned from the KOS strain (wild type) and two phenotypically distinct temperature-sensitive ICP4 mutants, tsB32 and tsL14 (DeLuca et al., J. Virol. 52:767-776, 1984), both alone and in conjunction with three other immediate-early genes. The latter series of plasmids was used to assess the influence of additional immediate-early gene products on gene expression in the presence of a given ICP4 allele. The results of this study demonstrate that the phenotypes of these ICP4 mutants observed in cell culture at the nonpermissive temperature were determined in part by activities associated with the mutant ICP4 polypeptides and that these activities differed from those of wild-type ICP4. Low levels of wild-type ICP4 had a marginal but reproducible stimulatory effect on immediate-early CAT gene expression, especially the pIE4/5CAT chimera. This effect was diminished with increasing quantities of ICP4, suggesting an inhibitory role for the wild-type form of the protein. The ICP4 mutants had a strong stimulatory effect on immediate-early CAT expression, consistent with their phenotypes at 39 degrees C. The mutant forms of the ICP4 polypeptide differed in their ability to induce CAT activity from an early chimeric gene. Thus, the tsL14 form of ICP4 was effective in early gene induction (i.e., ptkCAT was induced), whereas the ICP4 derived from tsB32 was slightly inhibitory. Cotransfection of tsB32 ICP4 simultaneously with other immediate-early genes resulted in a marginal increase in ptkCAT induction. This induction was enhanced when the gene for ICP4 was inactivated by restriction enzyme cleavage, substantiating the inhibitory effect of the tsB32 form of ICP4. The two mutant ICP4 genes (tsB32 and tsL14) were unable to trans-activate either of the late CAT constructs (p5CAT and pL42CAT) tested. Cotransfecting tsL14 ICP4 with the other immediate-early genes resulted in activation of p5CAT but not pL42CAT. Taken together, these studies demonstrate that (i) low levels of wild-type ICP4 have stimulatory effect on immediate-early promoters and that higher concentrations of wild-type ICP4 have an inhibitory effect on these promoters, (ii) isolated mutant form of ICP4 exhibit activities that reflect the phenotypes of the mutants from which they were isolated, and (iii) immediate-early gene products other than ICP4 are involved in determining the distinct phenotypes of the two mutants at 39 degrees Celsius.

The properties and sequence of glycoprotein H of herpes simplex virus type 1

The map position of the coding sequence of glycoprotein H of herpes simplex virus type 1 was determined by marker transfer studies in which DNA fragments cloned from a virus resistant to neutralisation by an anti-gH monoclonal antibody were used to transfer antibody resistance to wild type virus DNA following cotransfection. The gH coding sequence was mapped to the BglII "m" fragment of HSV-1 DNA (map coordinates 0.27-0.312), confirming the map position previously determined by intertypic recombinant analysis (Buckmaster et al., 1984). The complete nucleotide sequence of the BglII "m" fragment revealed two large open reading frames in addition to the thymidine kinase gene. The open reading frame lying immediately 3' of the thymidine kinase gene has a predicted translation product with the features of a large glycoprotein. This open reading frame translates to an amino acid sequence of 90,323 mol wt with a signal peptide, a membrane anchor sequence, a large external domain containing potential N-glycosylation sites, and a charged C- terminal cytoplasmic domain. We suppose that this amino acid sequence corresponds to gH of HSV-1, and A. Davison (personal communication) has noted the existence of homologous glycoproteins predicted from the nucleotide sequences of Varicella-zoster virus and Epstein-Barr virus. The properties of monoclonal antibody LP11, directed against gH show remarkable similarities to the properties for gD antibodies. LP11 efficiently neutralizes virus infectivity, blocks cell fusion by syncytial virus strains, and inhibits the formation of plaques when added to cell monolayers after infection. These similarities in antibody activity imply functional relatedness between gH and gD of herpes simplex virus.

Structural organization and unusual codon usage in the DNA polymerase gene from herpes simplex virus type 1

We have analyzed the protein and nucleic acid sequences of the DNA polymerase from herpes simplex virus type 1 (HSV-1) to provide insight into the expression and possible structure of this enzyme. Extensive similarity between the amino acid sequence and that of the Epstein Barr virus DNA polymerase is reported. We describe probable structural similarities between these proteins and the use of these similarities to define structural and functional domains within the polymerase. Analysis of base composition and codon usage reveals that several genes from HSV-1, including DNA polymerase, exhibit a strong preference for guanine or cytosine at the third codon position. This preference may result from the high guanine + cytosine content of the virus and produces a highly restricted codon usage, different from that of the host cell. Consequences of the unusual codon usage for viral expression include the potential for extensive mRNA secondary structure.

DNA sequence of the herpes simplex virus type 1 gene encoding glycoprotein gH, and identification of homologues in the genomes of varicella-zoster virus and Epstein-Barr virus

We have determined the sequence of herpes simplex virus type 1 DNA around the previously mapped location of sequences encoding an epitope of glycoprotein gH, and have deduced the structure of the gH gene and the amino acid sequence of gH. The unprocessed polypeptide is predicted to contain 838 amino acids, and to possess an N-terminal signal sequence and a C-terminal transmembrane sequence. Temperature-sensitive mutant tsQ26 maps within the predicted gH coding sequence. Homologous genes were identified in the genomes of two other herpesviruses, namely varicella-zoster virus and Epstein-Barr virus.

Sequence and mapping analyses of the herpes simplex virus DNA polymerase gene predict a C-terminal substrate binding domain

The herpes simplex virus DNA polymerase provides an excellent model for studies of eukaryotic replicative polymerases. We report here the nucleotide sequence of the gene which encodes this enzyme. The gene includes a 3705-base-pair major open reading frame capable of encoding a Mr 136,519 polypeptide, in rough agreement with previous estimates of the size of the major polypeptide found in partially purified viral polymerase preparations. The predicted polymerase polypeptide shares extensive sequence homology with the Epstein-Barr virus open frame predicted to encode DNA polymerase and with a 13-amino acid segment of adenovirus 2 DNA polymerase. Mutations conferring altered sensitivity to antiviral deoxynucleoside triphosphate analogs, pyrophosphate analogs, or aphidicolin from eight different mutants map within the region encoding the carboxyl-terminal portion of the predicted polymerase polypeptide. Two of these are separated by a distance corresponding to at least 228 amino acids. We propose that this region of the gene encodes a polypeptide domain that contains the binding sites for deoxynucleoside triphosphates and pyrophosphate.

Herpes simplex virus type 1 ICP27 is an essential regulatory protein

The five immediate-early genes of herpes simplex virus are expressed during the initial stages of the infectious cycle, and certain immediate-early proteins have been shown to play a regulatory role in subsequent viral gene expression. Until recently, the functional properties of only one immediate-early protein, ICP4, had been examined in any detail, primarily because mutants had been isolated only in the gene for ICP4. We report herein the genetic and phenotypic characterization of four temperature-sensitive mutants of herpes simplex virus type 1 (tsY46, tsE5, tsE6, and tsLG4) that have begun to elucidate the function(s) of a second immediate-early protein, ICP27. The four mutants complemented each other inefficiently or not at all, indicating that they are defective in the same function. Marker rescue tests placed the mutations in tsY46 and tsE5 in sequences that encode the transcript for ICP27; the mutations in tsE6 and tsLG4 lie in or near these sequences. The ability of wild-type ICP27 expressed from a cloned gene to complement tsY46 and tsLG4 constitutes additional evidence that these mutants are defective in an ICP27-associated function. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of mutant-infected cell polypeptides showed that certain immediate-early (alpha) polypeptides were overproduced, whereas significant levels of early (beta) and drastically reduced levels of several late (gamma) proteins were synthesized at the nonpermissive temperature. Interestingly, the mutants were observed to form a spectrum with regard to their relative abilities to induce the expression of a number of polypeptides, especially those of the delayed-early (beta gamma) class. Consistent with their ability to induce expression of early polypeptides, all of the mutants induced the synthesis of substantial levels of viral DNA at the nonpermissive temperature. Taken together, the results of these studies demonstrate that ICP27 plays an essential regulatory function in virus replication, that this function is required after the onset of early gene expression and viral DNA synthesis, and that the inability of the mutants to induce the synthesis of late proteins is independent of viral DNA synthesis.

Mutations in the herpes simplex virus major DNA-binding protein gene leading to altered sensitivity to DNA polymerase inhibitors

Five herpes simplex virus mutants containing temperature-sensitive mutations in the gene for the major DNA-binding protein were assayed for their sensitivities to the DNA polymerase inhibitors aphidicolin and phosphonoacetic acid (PAA). Four of the mutants (tsA1, tsA15, tsA24, and tsA42) exhibited altered sensitivity to one or both of the inhibitors relative to the wild-type parent. In tsA1, a mutation or mutations conferring aphidicolin and PAA hypersensitivity were mapped by corescue with the temperature-sensitivity marker of tsA1 to a region of the DNA-binding protein locus, between map coordinates 0.385 and 0.398. The mutation conferring PAA hypersensitivity in tsA24 similarly corescued with the tsA24 temperature-sensitivity marker, mapping to the DNA-binding protein locus between coordinates 0.398 and 0.413. Thus, mutations outside the DNA polymerase locus and within the DNA-binding protein locus can confer altered sensitivity to certain DNA polymerase inhibitors. Assays of the aphidicolin and PAA sensitivities of ts+ recombinants derived by marker rescue of the DNA-binding protein mutants revealed the presence of additional mutations, separable from the ts mutations, in each of three mutants examined. One such mutation, which contributed to the aphidicolin-hypersensitivity phenotype of tsA1, mapped between coordinates 0.422 and 0.448, and resides, most probably, within the DNA polymerase locus. These additional mutations possibly confer compensating modifications to the DNA polymerase such that functional interaction with altered DNA-binding protein is restored. These findings provide strong evidence that the major DNA-binding protein and the DNA polymerase of herpes simplex virus interact in infected cells.

Activation of immediate-early, early, and late promoters by temperature-sensitive and wild-type forms of herpes simplex virus type 1 protein ICP4

To better define the activities on herpes simplex virus type 1 gene expression of temperature-sensitive and wild-type forms of the transcriptional regulatory protein ICP4, regulatory sequences from immediate-early, early, and late herpes simplex virus genes were fused to the gene for chloramphenicol acetyltransferase (CAT). These constructs were used in trans induction and cotransfection experiments with wild-type and temperature-sensitive mutant alleles of ICP4. The ICP4 genes used in this study were cloned from the KOS strain (wild type) and two phenotypically distinct temperature-sensitive ICP4 mutants, tsB32 and tsL14 (DeLuca et al., J. Virol. 52:767-776, 1984), both alone and in conjunction with three other immediate-early genes. The latter series of plasmids was used to assess the influence of additional immediate-early gene products on gene expression in the presence of a given ICP4 allele. The results of this study demonstrate that the phenotypes of these ICP4 mutants observed in cell culture at the nonpermissive temperature were determined in part by activities associated with the mutant ICP4 polypeptides and that these activities differed from those of wild-type ICP4. Low levels of wild-type ICP4 had a marginal but reproducible stimulatory effect on immediate-early CAT gene expression, especially the pIE4/5CAT chimera. This effect was diminished with increasing quantities of ICP4, suggesting an inhibitory role for the wild-type form of the protein. The ICP4 mutants had a strong stimulatory effect on immediate-early CAT expression, consistent with their phenotypes at 39 degrees C. The mutant forms of the ICP4 polypeptide differed in their ability to induce CAT activity from an early chimeric gene. Thus, the tsL14 form of ICP4 was effective in early gene induction (i.e., ptkCAT was induced), whereas the ICP4 derived from tsB32 was slightly inhibitory. Cotransfection of tsB32 ICP4 simultaneously with other immediate-early genes resulted in a marginal increase in ptkCAT induction. This induction was enhanced when the gene for ICP4 was inactivated by restriction enzyme cleavage, substantiating the inhibitory effect of the tsB32 form of ICP4. The two mutant ICP4 genes (tsB32 and tsL14) were unable to trans-activate either of the late CAT constructs (p5CAT and pL42CAT) tested. Cotransfecting tsL14 ICP4 with the other immediate-early genes resulted in activation of p5CAT but not pL42CAT. Taken together, these studies demonstrate that (i) low levels of wild-type ICP4 have stimulatory effect on immediate-early promoters and that higher concentrations of wild-type ICP4 have an inhibitory effect on these promoters, (ii) isolated mutant form of ICP4 exhibit activities that reflect the phenotypes of the mutants from which they were isolated, and (iii) immediate-early gene products other than ICP4 are involved in determining the distinct phenotypes of the two mutants at 39 degrees Celsius.

An unusual spliced herpes simplex virus type 1 transcript with sequence homology to Epstein-Barr virus DNA

High-resolution transcription mapping localized a spliced 2.7-kilobase herpes simplex virus type 1 mRNA. The 4-kilobase intron of this transcript encodes a nested set of transcripts on the opposite DNA strand. The nucleotide sequence of the DNA encoding the left-hand and right-hand exons of the spliced transcript was determined, and the salient features are presented here. Of major interest is that both exons contained regions within several hundred bases of the splice donor and acceptor sites which showed homology to two regions of the Epstein-Barr virus genome, which are themselves 3 kilobases apart. The spliced herpes simplex virus transcript encoded a translational reading frame which could encode a protein with an approximate size of 75,000 daltons. This value is in agreement with in vitro translation data. The predicted amino acid sequence of the herpes simplex virus protein had significant homology with putative amino acid sequences encoded by the homologous Epstein-Barr virus DNA sequences.

Sensitivity of arabinosyladenine-resistant mutants of herpes simplex virus to other antiviral drugs and mapping of drug hypersensitivity mutations to the DNA polymerase locus

Seven herpes simplex virus mutants which have been previously shown to be resistant to arabinosyladenine were examined for their sensitivities to four types of antiviral drugs. These drugs were a pyrophosphate analog, four nucleoside analogs altered in their sugar moieties, two nucleoside analogs altered in their base moieties, and one altered in both. The seven mutants exhibited five distinct phenotypes based on their sensitivities to the drugs relative to wild-type strain KOS. All mutants exhibited resistance to acyclovir and arabinosylthymine, as well as marginal resistance to iododeoxyuridine, whereas all but one exhibited resistance to phosphonoformic acid. The mutants exhibited either sensitivity or hypersensitivity to other drugs tested--2'-nor-deoxyguanosine, 5-methyl-2'-fluoroarauracil, 5-iodo-2'-fluoroarauracil, and bromovinyldeoxyuridine--some of which differed only slightly from drugs to which the mutants were resistant. These results suggest ways to detect and treat arabinosyladenine-resistant isolates in the clinic. Antiviral hypersensitivity was a common phenotype. Mutations conferring hypersensitivity to 2'-nor-deoxyguanosine in mutant PAAr5 and to bromovinyldeoxyridine in mutant tsD9 were mapped to nonoverlapping regions of 1.1 and 0.8 kilobase pairs, respectively, within the herpes simplex virus DNA polymerase locus. Thus, viral DNA polymerase mediates sensitivity to these two drugs. However, we could not confirm reports of mutations in the DNA polymerase locus conferring resistance to these two drugs. All of the mutants exhibited altered sensitivity to two or more types of drugs, suggesting that single mutations affect recognition of the base, sugar, and triphosphate moieties of nucleoside triphosphates by viral polymerase.

Temperature-sensitive mutants in herpes simplex virus type 1 ICP4 permissive for early gene expression

A large number of temperature-sensitive (ts) mutants of herpes simplex virus type 1 (HSV-1) in the gene encoding the immediate-early transcriptional regulatory protein, ICP4, have been isolated and characterized with respect to expression of the immediate-early, early, and late viral gene products. The hallmark of these mutants is the overproduction of immediate-early gene products and the underproduction of early and late gene products. The present study involves the preliminary genetic and molecular characterization of two unique regulatory mutants of HSV-1, ts48 and ts303. Genetically, both mutants exhibit inefficient complementation with eight ts mutants in complementation group 1-2, which defines the gene for ICP4, and marker rescue experiments place the mutations in both mutants in the 3' portion of the coding sequence for ICP4. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of ts48- and ts303-infected cell polypeptides synthesized at the nonpermissive temperature demonstrates that immediate-early polypeptides ICP4 and ICP27 are overproduced, with the simultaneous production of early polypeptides ICP6, ICP8, gB, and others. Immediate-early polypeptides are resynthesized upon temperature shift-up early in infection; however, shift-up late in infection does not result in the resynthesis of immediate-early polypeptides. Late gene products are either absent or underrepresented under long-term labeling conditions. To examine the effects of the mutations in ts48, ts303, and other ICP4 mutants specifically on early gene expression, trans-induction experiments were performed in cells transfected with the gene for chloramphenicol acetyltransferase under early gene control (tk) and superinfected with KOS, tsB32, ts48, and ts303. Mutant tsB32 did not induce chloramphenicol acetyltransferase activity above the basal level; however, ts48 and ts303 induced chloramphenicol acetyltransferase activity nearly equal to wild-type levels. Fifteen to fifty percent of wild-type levels of viral DNA are synthesized at the nonpermissive temperature in ts48- and ts303-infected cells, indicating that immediate-early and early gene functions are intact (or nearly so) and that the block in ts48 and ts303 is in a regulatory event subsequent to that exhibited by other mutants in complementation group 1-2 which are DNA-.

Herpes simplex virus mutants resistant to arabinosyladenine in the presence of deoxycoformycin

Herpes simplex virus mutants PAAr5, AraAr6, AraAr7, AraAr9, and AraAr13, which previously had been shown to be resistant to arabinosyladenine (araA) alone, were found to be resistant to araA in the presence of high concentrations of the adenosine deaminase inhibitor, deoxycoformycin. The marker conferring resistance to araA and deoxycoformycin in mutant PAAr5 was mapped finely to an 0.8-kilobase-pair region in the herpes simplex virus DNA polymerase locus. These results indicate that the mutants are resistant to araA itself rather than to its deamination product and confirm the importance of the viral polymerase in the antiviral action of araA.

Genetics of herpes simplex virus

The most direct approach to elucidating the roles of herpes simplex virus (HSV) proteins in the viral replicative cycle has been to isolate temperature-sensitive, cytolysis-resistant, and drug-resistant mutants that exhibit alterations in the synthesis or activity of these proteins. The development of procedures for the introduction of temperature-sensitive mutations into physically defined regions of the viral genome and for fine mapping of these mutations has proven especially valuable. Thus, (1) hydroxylamine mutagenesis of the HSV-1 BglII I fragment (coordinates 0.312-0.415) has facilitated the genetic and functional characterization of the gene for the major viral DNA-binding protein of 130 K molecular weight; (2) the selection of a mutant conditionally able to render infected cells resistant to immune cytolysis has led to identification of an HSV gene involved in the processing of viral glycoproteins; and (3) the combined use of temperature-sensitive and drug-resistant mutants has led to a better definition of the physical limits and functional domains of the gene for HSV DNA polymerase.

Transcriptional and genetic analyses of the herpes simplex virus type 1 genome: coordinates 0.29 to 0.45

We have constructed a map of the genes encoded by a 23,000-nucleotide-pair region of herpes simplex virus type 1. This region, defined by the three adjacent EcoRI fragments N (map coordinates 0.298 to 0.315), F (0.315 to 0.421), and M (0.421 to 0.448), has previously been shown by genetic analysis to contain the genes for thymidine kinase, nucleocapsid protein p40, glycoprotein B, DNA-binding protein, and DNA polymerase. We report the identification and mapping of RNAs defining 13 viral genes encoded by the region 0.298 to 0.448. The transcriptional pattern shows families of overlapping messages, similar to those observed in other regions of the viral genome. We also isolated mutants representing four distinct complementation groups and physically mapped several of the mutations to regions within EcoRI fragment F by marker rescue. Mutations representing complementation groups 1-9 (glycoprotein B), 1-1 (DNA-binding protein), and 1-3 (DNA polymerase) were mapped to coordinates 0.361 to 0.368 to 0.411, and 0.411 to 0.421, respectively. A fourth previously undefined complementation group was mapped to the region between glycoprotein B and DNA-binding protein. Comparing the transcription mapping with marker rescue data suggests that the genes for glycoprotein B, DNA-binding protein, DNA polymerase, and nucleocapsid protein p40 are expressed as 3.3-, 4.2-, 4.3- or 4.2- or both, and 2.4-kilobase mRNAs, respectively.