Efficient herpes simplex virus type 1 (HSV-1) capsid formation directed by the varicella-zoster virus scaffolding protein requires the carboxy-terminal sequences from the HSV-1 homologue

The scaffolding protein and associated protease of the human herpesvirus varicella-zoster virus (VZV), encoded by genes 33.5 and 33 respectively, were synthesized in insect cells using a baculovirus expression system. The expressed 33.5 product formed numerous long, flexible, hollow rods, and in this respect different from the herpes simplex virus type 1 (HSV-1) homologue which forms large aggregates consisting mainly of fibrous material interspersed with scaffold-like particles. Removal of 27 amino acids from the carboxy terminus of the VZV scaffolding protein by the gene 33 protease or expression of the cleaved product did not result in any discernible change in the morphology of the scaffolding protein. Again, this was in marked contrast to the situation in HSV-1 where removal of the 25 carboxy-terminal amino acids from the scaffolding protein by the associated protease or expression of VP22a results in the formation of large numbers of scaffold-like particles. Despite these differences, when cells were multiply infected with baculoviruses expressing the HSV-1 capsid shell proteins and the VZV scaffolding protein complete capsids were observed, suggesting that the VZV protein could act as a scaffold for the assembly of the HSV-1 capsid shell. The efficiency of capsid assembly was increased substantially by exchanging the 23 carboxy-terminal amino acids of the VZV scaffolding protein for the corresponding 22 carboxy-terminal amino acids of the HSV-1 homologue, supporting previous work which showed that this region was critical for the formation of intact capsids.

Na, an autoproteolytic product of the herpes simplex virus type 1 protease, can functionally substitute for the assembly protein ICP35

The herpes simplex virus type 1 (HSV-1) protease and its substrate, the assembly protein ICP35, are involved in virion maturation. Both proteins are encoded by a single open reading frame but are translated independently from 3'-coterminal mRNAs of different sizes and are in frame. The herpesvirus shell assembles around an internal scaffold which is subsequently lost during packaging of the viral genome. The scaffold is composed of ICP35, which is the major component, and autoproteolytically processed forms of the viral protease containing sequences common to ICP35 (Nb). In the baculovirus system, HSV-1 intact capsids can be formed in the presence of the protease or ICP35, indicating that the protease may substitute for ICP35 (Thomsen et al., J. Virol. 68:2442-2457, 1994). This is further supported by the fact that ICP35, in contrast to the protease, is not absolutely essential for viral growth. The processed intermediate of the protease analogous to ICP35 is the 388-amino-acid (aa) protein, Na, which is an N-terminal 59-aa extension of the 329-aa ICP35. To directly examine whether Na can functionally substitute for ICP35 during viral replication, we first constructed a mutant virus, Na delta35, in which 35 aa from the N terminus of Na were deleted. Phenotypic analysis of the mutant showed that this deletion had no effect on protease function. The function of Na was further examined by construction of a plasmid expressing Na alone and testing its ability to complement the growth of the mutant Prb virus in the absence of ICP35. Our results demonstrate that Na can functionally substitute for ICP35 during viral replication.

Multiple interactions control the intracellular localization of the herpes simplex virus type 1 capsid proteins

Herpes simplex virus type 1 (HSV-1) capsid assembly takes place in the nucleus of infected cells. However, when each of the outer capsid shell proteins, VP5, VP23 and VP26, is expressed in the absence of any other HSV-1 proteins, it does not localize to the nucleus but is distributed throughout the cell. We have previously shown that the HSV-1 capsid scaffolding protein, preVP22a, can relocate VP5 into the nucleus but does not influence the distribution of VP23. We now demonstrate that the outer capsid shell protein, VP19C, is able to relocate both VP5 and VP23 separately into the nucleus. However, nuclear localization of VP26 is only observed when VP5 is present together with either VP19C or preVP22a. Thus, pair-wise interactions involving all of the abundant capsid proteins have now been identified. Electron microscope examination of insect cells coinfected with recombinant baculoviruses expressing VP19C and VP5 reveals the presence of 70 nm diameter 'capsid-like' structures, suggesting that these two proteins can form the basic capsid shell.

The 25 amino acid residues at the carboxy terminus of the herpes simplex virus type 1 UL26.5 protein are required for the formation of the capsid shell around the scaffold

Herpes simplex virus type 1 (HSV-1) polypeptides specified by overlapping genes UL26 and UL26.5 form a scaffold around which the icosahedral capsid shell is assembled. In a series of cleavage events catalysed by the UL26-encoded protease, the full-length UL26 product is processed into capsid proteins VP24 and VP21 and the UL26.5 protein is converted into the capsid protein VP22a by the loss of 25 amino acids from its carboxy terminus. The roles of the UL26 and UL26.5 products were investigated using the baculovirus expression system, focusing on the function of the 25 residues cleaved from the UL26.5 protein. A key conclusion from electron microscopic analysis and protein expression studies is that the 25 amino acids at the carboxy terminus of the full-length UL26.5 protein are required for the interaction of the capsid shell proteins with the scaffold in the formation of intermediate capsids. When cells were multiply infected with baculoviruses expressing a truncated form of the UL26.5 product corresponding to VP22a and the essential components of the capsid shell, no capsids were detected, whereas large numbers of capsids were observed when the full-length UL26.5 product was used as a scaffold. The results are consistent with the proposal that cleavage of the UL26.5 product occurs after capsid assembly or when the UL26.5 protein is in a complex with one or more capsid shell proteins. Expression of VP22a in the absence or presence of capsid shell proteins resulted in the formation of large numbers of 60 nm scaffold-like particles. Since VP22a expressed from baculovirus was unable to participate in capsid assembly, these particles cannot be intermediates in the capsid assembly pathway but may be similar in structure to the protein cores present in HSV-1 immature (B) capsids.

The herpes simplex virus gene UL26 proteinase in the presence of the UL26.5 gene product promotes the formation of scaffold-like structures

The herpes simplex virus type 1 (HSV-1) polypeptides encoded by genes UL26 and UL26.5 are thought to form a scaffold around which the capsid shell assembles. The UL26 gene specifies a proteinase that cleaves both itself and the UL26.5 gene product. To study the structure and function of the UL26 and UL26.5 gene products, the proteins were expressed in cells infected with recombinant baculoviruses containing the genes under the control of the polyhedrin promoter. Both polypeptides were made in large amounts, approaching the levels of polyhedrin protein expressed in wild-type baculovirus. The UL26 polypeptide behaved in a similar manner to the protein made in HSV-1-infected cells, cleaving itself rapidly into the capsid proteins VP21 and VP24 and converting the UL26.5 product more slowly into the capsid protein VP22a. The results of immunoblot analysis using antisera specific for the amino-terminal region of the UL26 polypeptide suggested that both the first and second ATGs in the UL26 open reading frame were recognized as translational start signals but the first ATG was the preferred initiation codon as is the case in HSV-1-infected cells. Electron microscopic examination of thin section preparations of cells infected with both the UL26.5- and UL26-recombinant baculoviruses revealed the presence of large numbers of small spherical particles, often arranged in a semi-crystalline array. These clusters of scaffold-like particles were not present in cells infected with UL26-recombinant baculovirus but were observed occasionally in UL26.5-recombinant baculovirus-infected cells. The results suggest that the proteinase, in the absence of other HSV capsid proteins, stimulates the formation of large numbers of scaffold-like particles present either as semi-crystalline arrays or as dispersed structures.

Localization of the herpes simplex virus type 1 major capsid protein VP5 to the cell nucleus requires the abundant scaffolding protein VP22a

The intracellular distributions of three herpes simplex virus type 1 (HSV-1) capsid proteins, VP23, VP5 and VP22a, were examined using vaccinia virus and plasmid expression systems. During infection of cells with HSV-1 wild-type virus, all three proteins were predominantly located in the nucleus, which is the site of capsid assembly. However, when expressed in the absence of any other HSV-1 proteins, although VP22a was found exclusively in the nucleus as expected, VP5 and VP23 were distributed throughout the cell. Thus nuclear localization is not an intrinsic property of these proteins but must be mediated by one or more HSV-1-induced proteins. Co-expression experiments demonstrated that VP5 was efficiently transported to the nucleus in the presence of VP22a, but the distribution of VP23 was unaffected by the presence of either or both of the other two proteins.

Assembly of herpes simplex virus type 1 capsids using a panel of recombinant baculoviruses

Immature or B capsids of herpes simplex virus type 1 (HSV-1) are composed of seven proteins encoded by six viral genes. The proteins encoded by UL18 (VP23), UL19 (VP5), UL35 (VP26) and UL38 (VP19C) are components of the outer capsid shell whereas those specified by UL26 (VP21 and VP24) and UL26.5 (VP22a), are involved in scaffold formation. We have used a panel of recombinant baculoviruses, each expressing one of the capsid protein genes, to examine the requirements for capsid assembly. Coexpression of the six genes in insect cells resulted in the formation of capsids that were indistinguishable in appearance and protein composition from those made during HSV-1 infection of mammalian cells. This demonstrates that the proteins encoded by the known capsid genes contain all the structural information necessary for capsid assembly and that other virus-encoded proteins are not required for this process. Omission of single recombinant baculoviruses from this system allowed the role of individual HSV-1 proteins in capsid assembly to be determined. Thus, capsid assembly did not take place in the absence of VP23, VP5 or VP19C, whereas lack of VP26 had no discernible effect on capsid formation. Capsids assembled in the absence of the UL26 gene products had a large-cored phenotype resembling that previously described for the HSV-1 mutant ts1201 which has a lesion in this gene. Some apparently intact capsid shells were also made in the absence of the major scaffolding protein, VP22a, whereas the omission of both UL26 and UL26.5 resulted in the appearance of large numbers of partial and deformed capsid shells.

Processing of the herpes simplex virus assembly protein ICP35 near its carboxy terminal end requires the product of the whole of the UL26 reading frame

The herpes simplex virus (HSV) type 1 assembly protein ICP35 consists of a family of polypeptides, ranging in molecular weight from about 45,000-39,000. The lower molecular weight forms of ICP35 are derived from the higher molecular weight species by slow post-translational modification. The reading frame of gene UL26 and the region within this gene which exhibited homology to the cytomegalovirus assembly protein, the analogous protein to ICP35, were expressed separately under immediate-early (IE) gene regulation in a HSV vector containing a temperature-sensitive mutation in the major transcriptional regulator Vmw175. Monoclonal antibody specific for ICP35 immunoprecipitated several polypeptides with molecular weights around 75,000 from extracts of cells infected with a recombinant expressing the IE gene UL26 at the nonpermissive temperature (NPT). These results suggested that the UL26 gene specified a protein distinct from ICP35 but which had some antigenic sites in common with ICP35. In extracts of cells infected at the NPT with a recombinant expressing only the carboxy terminal half of UL26 coding sequences, the monoclonal antibody immunoprecipitated large amounts of the high molecular weight forms of ICP35. The lower molecular weight processed forms of ICP35, however, were not detectable. When cells were coinfected with both recombinants ICP35 was processed to its lower molecular weight forms. This processing step, which occurred near the carboxy terminus of ICP35, was not dependent on capsid formation. The work, together with previous information on the processing of the CMV assembly protein, suggests that UL26 product may be a protease.

The herpes simplex virus UL33 gene product is required for the assembly of full capsids

Phenotypic analysis of the herpes simplex virus type 1 temperature-sensitive DNA-positive mutant, ts1233, revealed that the mutant had a structural defect at the nonpermissive temperature (NPT). Cells infected with ts1233 at the NPT contained large numbers of intermediate capsids, lacking dense cores but possessing some internal structure. No full capsids or enveloped virus particles were detected. In contrast to the defect in another packaging-deficient mutant ts1201, the block in the formation of dense-cored, DNA-containing capsids in ts1233-infected cells at the NPT could not be reversed by transferring the cells to the permissive temperature in the presence of a protein synthesis inhibitor. Furthermore, the capsids produced by ts1233 at the NPT had more compact internal structures than those of the gene UL26 mutant ts1201. Southern blot analysis of viral DNA in ts1233-infected cells confirmed that the mutant DNA was not encapsidated at the NPT and showed that the unpackaged DNA was not cleaved into genome-length molecules. The ts1233 mutation was mapped by marker rescue to the vicinity of genes UL32 and UL33. Sequence analysis of the DNA in this region from the mutant and two independently isolated revertants for growth revealed that ts1233 had a single base-pair change at the amino-terminal end of UL33, resulting in the substitution of an isoleucine with an asparagine. The nucleotide sequence of the revertants in this part of the genome was identical to that of wild-type virus.

Herpes simplex virus type 1 UL28 gene product is important for the formation of mature capsids

The herpes simplex virus type 1 temperature-sensitive (ts) DNA-positive mutant ts1203 has been characterized. The ts lesion in ts1203 was located by marker rescue within the coding region of gene UL28. Nuclei of cells infected with ts1203 at the non-permissive temperature (NPT) contained large numbers of capsids with a uniform morphology. These capsids lacked DNA but had a defined internal structure. No full capsids were detected at the NPT, suggesting that ts1203 was unable to package viral DNA. In this respect ts1203 is similar to ts1201 which has a defect in gene UL26. The capsids made by ts1203 at the NPT, however, contained a more compact internal structure than those of ts1201. In addition, ts1203 capsids were dispersed throughout the nucleus whereas ts1201 capsids were frequently found clustered together in large arrays. Southern blot and sedimentation analyses of viral DNA confirmed that ts1203 had an encapsidation defect and showed that most of the mutant DNA at the NPT was of a high Mr. The effect of the ts1203 mutation could not be reversed in the absence of de novo protein synthesis by transferring mutant-infected cells from the NPT to the permissive temperature.

Herpes simplex virus activates expression of a cellular gene by specific binding to the cell surface

The herpes simplex virus (HSV) type 1 mutant ts1204 attaches to the cell surface at 38.5 degrees but fails to penetrate the plasma membrane. A striking feature of human fetal lung cells infected with ts1204 at 38.5 degrees was the presence of enhanced amounts of a 56,000 molecular weight host protein, p56. Studies with protein and RNA synthesis inhibitors suggested that binding of the mutant virus to cells activated expression of the cellular gene encoding p56 and not an intermediary protein. Evidence presented in this paper supports the idea that p56 is induced by a specific interaction between ts1204 virions and the cell surface.

A mutant of herpes simplex virus type 1 immediate early polypeptide Vmw175 binds to the cap site of its own promoter in vitro but fails to autoregulate in vivo

Vmw175, the product of herpes simplex virus type 1 immediate early (IE) gene 3, is essential for viral replication. It is required for the activation of transcription from both early and late gene promoters and also for the repression of IE gene expression. Vmw175 is able to bind specifically to certain DNA sequences, some of which (including that at the cap site of IE gene 3) contain the consensus sequence ATCGTC. The presence of this sequence at the cap site has been correlated with the ability of Vmw175 to autoregulate its own promoter. This report describes the characterization of five viruses with temperature-sensitive (ts) lesions in Vmw175. Four of these mutants express Vmw175 which is ts in its ability to bind to DNA in vitro and to autoregulate IE-3 gene expression in the infected cell. Although Vmw175 produced by the remaining mutant, ts1225, fails to autoregulate IE-3 expression at the non-permissive temperature (NPT) its DNA-binding properties are indistinguishable from those of the wild-type protein. This suggests that the ability of Vmw175 to bind to the IE-3 cap site (as measured in vitro) is insufficient for autoregulation (in vivo). All five newly characterized ts mutants are partially permissive for early gene transcription at the NPT, although Vmw175 expressed by four of them is unable to bind to the IE-3 cap site sequence at elevated temperatures. This suggests that binding to one class of recognition sequences by Vmw175, as measured in vitro, is not absolutely required for the activation of early gene promoters during virus infection. The lesions in these five ts mutants lie in the carboxy-terminal third of the polypeptide; three of the mutations (those in ts1219, ts1221 and ts1225) were identified by DNA sequence analysis and were found to affect amino acid residues that are conserved in the homologous proteins from varicella-zoster virus and pseudorabies virus.

Reconstitution of herpes simplex virus type 1 ribonucleotide reductase activity from the large and small subunits

An assay for the presence of functional large (RR1) and small (RR2) subunits of the herpes simplex virus type 1 (HSV-1) ribonucleotide reductase has been developed. The system utilizes two temperature-sensitive mutants, ts1207, which has a lesion in RR1, and ts1222, which has a lesion in RR2. In cells infected with ts1207 at 39.5 degrees C, the defective RR1 is unable to associate with RR2 to form an active enzyme, and, as a result, a pool of functional RR2 and defective RR1 accumulates. Evidence presented in this paper suggest that cells infected with ts1222 at either 31 degrees C or 39.5 degrees C accumulate a pool of functional RR1, but do not contain detectable RR2. Virus-specific ribonucleotide reductase activity was produced in cells coinfected with both mutants at 39.5 degrees C, each virus contributing one functional subunit to the holoenzyme. No enzyme activity was detected in cells infected with each mutant alone at this temperature. When partially purified extracts of cells infected with ts1207 at the nonpermissive temperature were mixed with those from ts1222-infected cells, a fully functional enzyme was also formed. These results demonstrate that HSV-1 ribonucleotide reductase activity can be reconstituted both in vivo and in vitro from the nondefective subunits produced by ts1222 and ts1207.

The herpes simplex virus type 1 temperature-sensitive mutant ts1222 has a single base pair deletion in the small subunit of ribonucleotide reductase

The herpes simplex virus type 1 (HSV-1) temperature-sensitive (ts) mutant, ts1222, has a defect within the gene specifying the small subunit of ribonucleotide reductase. Sequence determination of the lesion revealed that the mutant DNA had a single base pair deletion at the 3' end of the gene. The mutation altered the translational reading frame such that the codons of all but one of the last 15 amino acids of the protein were changed and the termination codon removed. Although ts1222 did not induce detectable amounts of enzyme activity at both 31 degrees and 39.5 degrees, it replicated as well as wild-type virus at 31 degrees in exponentially growing tissue culture cells under one step growth conditions. At 39.5 degrees, however, ts1222 behaved as a ts mutant. These findings suggest that at low temperatures the virus-coded enzyme is dispensable for virus growth in actively dividing tissue culture cells but at high temperatures the enzyme is essential for virus replication. Under these conditions altered properties of the host cell contribute to the ts phenotype of the mutant. In the presence of hydroxyurea, which inactivates both the cellular and virus ribonucleotide reductases, growth of the mutant at 31 degrees was inhibited more than wild-type virus replication. Growth of the mutant at the permissive temperature was also sensitive to high concentrations of thymidine whereas wild-type virus multiplication was resistant to the nucleoside. It is therefore likely that ts1222 is dependent on the cellular ribonucleotide reductase for growth at this temperature. In serum-starved cells, growth of the mutant virus at 31 degrees was severely impaired. Thus, like thymidine kinase, the HSV-coded ribonucleotide reductase is required for virus multiplication in resting tissue culture cells.

The products of herpes simplex virus type 1 gene UL26 which are involved in DNA packaging are strongly associated with empty but not with full capsids

We report on the properties of a family of related herpes simplex virus type 1 polypeptides (designated p40) of Mr around 40,000. The intracellular localization of these polypeptides has been examined using monoclonal antibodies and their association with viral capsids within the nuclei of infected cells has been demonstrated directly by immunoelectron microscopy. Specific DNA staining and the use of mutants defective for DNA packaging has revealed, in contrast to earlier findings, that p40 is present in empty capsids. Protein p40 is not present as a major component of full capsids or of mature virions indicating that it is transiently associated with capsids and that its removal from capsids is linked with the process of DNA packaging.

Mutational analysis of the herpes simplex virus type 1 trans-inducing factor Vmw65

The herpes simplex virus type 1 (HSV-1) polypeptide Vmw65 is a structural component of the virus particle and is also responsible for trans-induction of immediate early (IE) transcription. Functional domains of this polypeptide were investigated by constructing a series of 10 plasmids each with a 12 bp insertion in the gene encoding Vmw65. Plasmids were analysed for their ability to stimulate IE transcription in short term transfection assays, and the altered Vmw65 polypeptides were assayed for the ability to form an IE-specific protein-DNA complex (IEC) in vitro. A direct correlation was observed between stimulation of transcription and formation of IEC, strongly suggesting that IEC is an important intermediate in transcription activation. Plasmids were also tested for their ability to rescue the temperature-sensitive mutation in the HSV-2 assembly mutant ts2203, since marker rescue analysis indicated that this mutation maps within the gene encoding Vmw65. Five plasmids failed to rescue ts2203, thereby defining regions of Vmw65 required for virus assembly. The results show that distinct domains exist in Vmw65 for activation of transcription and assembly of virus.

Ribonucleotide reductase encoded by herpes simplex virus is a determinant of the pathogenicity of the virus in mice and a valid antiviral target

The role of the herpes simplex virus (HSV)-encoded ribonucleotide reductase (RR) in the pathogenicity of the virus has been examined by use of mutants with lesions in either the large or small subunit of the enzyme. The virulence of the mutants in mice was reduced by about 10(6)-fold when compared with that of the parental virus (HSV type 1 strain 17), while the virulence of a revertant of one of the mutants was restored to within about 100-fold of that of the parent virus. These experiments demonstrate that activity of the HSV RR is essential for virus pathogenicity in mice and suggests that the enzyme is a valid target for specific antiviral compounds.

Cellular gene induction during herpes simplex virus infection can occur without viral protein synthesis

Infection of cultured cells with herpes simplex virus (HSV) results in the transcriptional induction of a small number of cellular genes. Although the majority of such genes are dependent upon viral protein synthesis for their induction, a small minority are not. These genes are induced by events occurring prior to the onset of viral protein synthesis, in particular by binding of the virus to the cell surface and cellular entry of the virion. The significance of such cellular gene induction early in viral infection is discussed in terms of virus-cell interaction in general and the mechanism of transformation by HSV in particular.

Isolation and characterisation of herpes simplex virus type 1 mutants which fail to induce dUTPase activity

The herpes simplex virus (HSV) type 1 dUTPase gene was inactivated by insertion of HindIII oligonucleotide linker sequences into the KpnI site within the coding region of the cloned gene. The mutated gene was introduced into wild type herpes simplex virus by marker rescue and the recombinants were identified by the acquisition of a HindIII site within genome map coordinates 0.69 to 0.70 and the failure to induce virus-specific dUTPase activity. A spontaneous dUTPase deficient mutant, which had an identical restriction endonuclease DNA pattern to wild type virus, was also isolated from this transfection experiment. Both types of dUTPase-negative mutants failed to induce a virus-specific 39,000 mol wt polypeptide. Cells infected with the insertional mutant contained instead a novel polypeptide about 40,000 mol wt. No abnormal virus specific polypeptide was detected in cells infected with the spontaneous mutant. We conclude that the 39,000 mol wt polypeptide induced by wild type HSV-1 is the virus-coded dUTPase. Since both types of mutants grew well in exponentially growing and serum-starved tissue culture cells in the absence of wild type helper virus, the dUTPase is not required for virus replication under these conditions. Thymidine kinase deficient, dUTPase deficient double mutants were constructed by recombination of a thymidine kinase insertional mutation into dUTPase deficient virus. These mutants also grew as well as wild type virus both in normal tissue culture cells and cells lacking the cellular thymidine kinase.

Characterisation of a herpes simplex virus type 1 mutant which has a temperature-sensitive defect in penetration of cells and assembly of capsids

A herpes simplex virus type 1 (HSV-1) mutant, ts1204, which has a temperature-sensitive (ts) mutation located within genome map coordinates 0.318 to 0.324, close to but outside the coding sequences of the glycoprotein gB gene, has been characterised. Although this mutant adsorbed to the cell surface at the nonpermissive temperature (NPT), it failed to penetrate the cell membrane. As a consequence of this defect, high multiplicities of infection of ts1204 blocked subsequent infection of cells by wild-type HSV-1. By contrast, at the NPT, superinfection of cells with HSV-2 was not inhibited by prior infection with ts1204. The penetration defect could be overcome either by brief incubation of mutant virus-infected cells at the permissive temperature, or by treatment of the cells with polyethylene glycol, a compound which promotes fusion of membranes. Upon continued incubation of ts1204-infected cells at the NPT, low numbers of capsids were assembled. Although these capsids all had some internal structure, they did not contain DNA. Another mutant, ts1208, which lies in the same complementation group as ts1204, penetrated cells normally at the NPT, but like ts1204, had a defect in the formation of functional capsids. Evidence presented in this paper suggests that the gene in which the ts1204 and ts1208 lesions map encodes a structural polypeptide.

Identification of the herpes simplex virus type 1 gene encoding the dUTPase

The dUTPase gene of herpes simplex virus has been identified using a novel approach. The upstream regulatory sequences, or the promoter and upstream regulatory sequences, of the immediate-early gene Vmw175 (ICP4) were inserted in front of genes mapping in the region 0.69 to 0.70 map units of the virus genome to enhance transient gene expression in a transfection assay. One clone, containing a gene specifying a 1.5-kb mRNA, induced significant amounts of virus-specific dUTPase activity. The enzyme activity was abolished by insertion of a HindIII linker into the KpnI site within the coding sequences of this gene. The results show that the enzyme is virus coded and that 1.5-kb mRNA specifies the dUTPase.

Identification of a herpes simplex virus type 1 polypeptide which is a component of the virus-induced ribonucleotide reductase

We have characterized a temperature-sensitive mutant of herpes simplex virus type 1 (HSV-1), 17tsVP1207, that induces a thermolabile ribonucleotide reductase activity. This mutant was derived from the multiple mutant tsG. Fine-structure mapping studies showed that the defect in 17tsVP1207 lies within an 800 bp sequence between genome map coordinates 0.580 and 0.585 in the gene encoding a polypeptide of 140 000 mol. wt. (Vmw136, ICP6). Since the mutation in this polypeptide produced a temperature-sensitive ribonucleotide reductase activity, Vmw136 must be a component of the herpes simplex virus-induced ribonucleotide reductase. The mRNA of Vmw136 has a common 3' terminus with an mRNA encoding a 38 000 mol. wt. polypeptide (Vmw38). Although the polypeptide-coding sequences of these mRNAs do not overlap, monoclonal antibodies against Vmw136 immunoprecipitated Vmw38 as well as Vmw136 from wild-type HSV-1-infected cells. Our data do not exclude the possibility that Vmw38 is part of the ribonucleotide reductase complex but suggest that this species on its own is not responsible for the HSV-induced enzyme activity.

Determination of the sequence alteration in the DNA of the herpes simplex virus type 1 temperature-sensitive mutant ts K

The alteration in the DNA sequence responsible for the mutant phenotype of the herpes simplex virus type 1 temperature-sensitive mutant ts K has been determined. A single C:G base pair present in the wild-type Vmw 175 immediate-early polypeptide-coding sequence has been replaced by T:A in the mutant gene. This results in the substitution of an alanine by a valine codon. In two revertants the mutant T:A base pair has been resubstituted by C:G.

Physical mapping of temperature-sensitive mutations of herpes simplex virus type 1 using cloned restriction endonuclease fragments

Sequences from the whole of the HSV-1 strain 17 genome were cloned into bacterial plasmid vectors, with the exception of part of BamHI v which was deleted in all cloned DNAs spanning this region of the virus DNA. The cloned DNAs were used in intratypic marker rescue experiments to map temperature-sensitive (ts) mutations on to the virus genome. Since the sequences of these DNAs overlapped, any mutation could be rapidly assigned a physical map position. This approach is particularly useful for mapping spontaneous mutations and lesions induced by mutagenesis of whole virus DNA. In this study, we mapped ten ts mutations comprising eight different complementation groups. Five lesions, representing three different cistrons, were located within BglII k (map units 0.098 to 0.166), and three mapped within EcoRIf (map units 0.321 to 0.414), two of which were in previously unidentified cistrons of HSV-1 strain 17. One mutation analysed had a defect within the short repeat region and another had a mutation within EcoRI i (map units 0.632 to 0.720).

Identification and characterization of a herpes simplex virus gene product required for encapsidation of virus DNA

A mutant of herpes simplex virus type 1, 17tsVP1201, has a temperature-sensitive processing defect in a late virus polypeptide. Immunoprecipitation studies with monoclonal antibodies showed that the aberrant polypeptide in mutant virus-infected cells was the nucleocapsid polypeptide known as p40. Since a revertant, TS(+) for growth, processed the polypeptide normally under conditions restrictive for the mutant, the processing event must be essential for virus replication. Electron microscopic analysis of mutant virus-infected cells grown at the nonpermissive temperature revealed that the nuclei contained large aggregations of empty nucleocapsids possessing some internal structure. Therefore, although the mutant synthesized virus DNA at the nonpermissive temperature, the DNA was not packaged into nucleocapsids. When mutant virus-infected cells were shifted from 39 to 31 degrees C in the presence of cycloheximide, the polypeptide p40 was processed to lower-molecular-weight forms, and full nucleocapsids were detected in the cell nuclei. The aberrant polypeptide of the mutant, however, was not processed in cells mixedly infected with 17tsVP1201 and a revertant at the nonpermissive temperature, suggesting that the defect of the mutant was in the gene encoding p40 rather than in a gene of a processing enzyme.

Fine-structure mapping of herpes simplex virus type 1 temperature-sensitive mutations within the short repeat region of the genome

Cloned herpes simplex virus type 1 (HSV-1) DNA fragments were used to fine-structure map the temperature-sensitive (ts) lesions from four mutants, ts T, D, c75, and K, by marker rescue. These mutants all overproduced immediate-early viral polypeptides at the nonpermissive temperature. Although one of these viruses, ts K, gave a more restricted infected-cell polypeptide profile under these conditions than the other three, no complementation was detected between pairwise crosses of these mutants in the yield test. Recombination, however, was obtained between all mutant pairs except ts T and D. In physical mapping experiments, ts+ virus was recovered from cells coinfected with DNA of ts T, D, or c75 and BamHI fragment k from wild-type strain 17 HSV-1 DNA cloned in pAT153, whereas ts K was rescued by cloned HSV-1 BamHI-y. Both of these cloned DNA fragments contained sequences from the short repeat region of the HSV-1 genome. The ts mutations were more precisely mapped by marker rescue, using restriction enzyme fragments within BamHI-k and -y from cloned DNA. The smallest fragment able to rescue a mutant was 320 base pairs long. The order of the four mutations derived from these studies was consistent with the assignment by genetic recombination. All four lesions mapped within the coding sequences of the immediate-early polypeptide Vmw IE 175 (ICP4) which lie outside the "a" sequence. The results showed that mutations in different regions of the gene encoding Vmw IE 175 could produce similar phenotype effects at the nonpermissive temperature.

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.

Physical mapping of herpes simplex virus-induced polypeptides

Analysis of the polypeptides induced by 29 herpes simplex virus type 1/type 2 intertypic recombinants and correlation of the data with the crossover points in the recombinant DNAs have enabled the map positions of many polypeptides to be deduced. These include 25 polypeptides which label with [35S]methionine, 11 which label with [32P]orthophosphate, and 4 which label with [14C]glucosamine. Together with the data of Preston et al. (J. Virol., in press) on the mapping of five immediate-early polypeptides, the results show that representatives of four groups of proteins--immediate-early, late, phosphorylated, and glycosylated--map in both long and short regions. The functional organization of the herpes simplex virus genome does not therefore restrict any of these four groups to either the long or the short region.