The catalytic subunit of herpes simplex virus type 1 DNA polymerase contains a nuclear localization signal in the UL42-binding region.

The herpes simplex virus type 1 DNA polymerase consists of a catalytic subunit (POL or UL30) and a processivity factor (UL42). The POL/UL42 interaction, which occurs through the extreme C-terminus of POL, is essential for HSV-1 replication and thus represents a valid target for drug inhibition. We recently showed (A. Loregian et al. (1999) Proc. Natl. Acad. Sci. USA 96, 5221-5226) that an oligopeptide corresponding to the 27 C-terminal amino acids of POL, when delivered into herpes simplex virus type 1-infected cells by a protein carrier, was able to localize into the nucleus and to inhibit viral replication by disruption of the POL/UL42 interaction. In this report, to further characterize the 27 mer (Pol peptide), we investigated whether its nuclear localization was due to the presence of a nuclear localization signal. By testing the ability of the Pol peptide to localize the beta-galactosidase, a normally cytoplasmic protein, to the nucleus, we confirmed that the Pol peptide contained a functional nuclear localization signal, corresponding to the RRMLHR motif. This sequence proved not only necessary but also sufficient for nuclear localization, because its substitution with a six-alanine stretch prevented nuclear translocation of the beta-galactosidase-Pol peptide fusion. Site-directed mutagenesis experiments on this revealed that both the three basic arginines and the two hydrophobic residues Met and Leu were crucial for nuclear targeting. Finally, functionally equivalent sequences were also found in the C-terminus of the catalytic subunits of human cytomegalovirus (RRLHL) and of equine herpesvirus-1 DNA polymerase (RRILH).

Peptide based enzyme-linked immunoassays for detection of anti-HSV-2 IgG in human sera.

Glycoprotein G of HSV-2 (gG2) and a peptide, corresponding to a previously recognised immunodominant epitope spanning residues 561-578 of the protein, were compared directly for type-specific serodiagnosis of HSV-2. The protein was affinity purified and obtained in a commercially available EIA kit while the peptide, previously designated as peptide 55, was made as a multiple antigenic peptide. A panel of 100 characterised serum samples (60 HSV-2 positive, 20 HSV-1 positive and 20 HSV negative) was screened using the two antigens. The intact protein and peptide 55 showed the same sensitivity for antibodies in the serum of HSV-2 infected individuals, reacting with 96.7% (58/60) of the samples. The peptide did not react with any of the HSV-1 positive or HSV negative sera. In contrast, gG2 gave a number of false positive results, reacting with 20% (4/20) of the HSV-1 positive sera and 10% (2/20) of the HSV negative sera. The superior performance of peptide 55, together with the very much lower costs of its production, compared with gG2 suggest that the peptide will become the antigen of choice in enzyme immunoassays for type-specific serodiagnosis of HSV-2.

Intranuclear delivery of an antiviral peptide mediated by the B subunit of Escherichia coli heat-labile enterotoxin.

We report an intracellular peptide delivery system capable of targeting specific cellular compartments. In the model system we constructed a chimeric protein consisting of the nontoxic B subunit of Escherichia coli heat-labile enterotoxin (EtxB) fused to a 27-mer peptide derived from the DNA polymerase of herpes simplex virus 1. Viral DNA synthesis takes places in the nucleus and requires the interaction with an accessory factor, UL42, encoded by the virus. The peptide, designated Pol, is able to dissociate this interaction. The chimeric protein, EtxB-Pol, retained the functional properties of both EtxB and peptide components and was shown to inhibit viral DNA polymerase activity in vitro via disruption of the polymerase-UL42 complex. When added to virally infected cells, EtxB-Pol had no effect on adenovirus replication but specifically interfered with herpes simplex virus 1 replication. Further studies showed that the antiviral peptide localized in the nucleus, whereas the EtxB component remained associated with vesicular compartments. The results indicate that the chimeric protein entered through endosomal acidic compartments and that the Pol peptide was cleaved from the chimeric protein before being translocated into the nucleus. The system we describe is suitable for delivery of peptides that specifically disrupt protein-protein interactions and may be developed to target specific cellular compartments.

Identification of an immunodominant sequential epitope in glycoprotein G of herpes simplex virus type 2 that is useful for serotype-specific diagnosis.

A series of 67 oligopeptides that spanned the open reading frame of herpes simplex virus type 2 (HSV-2) glycoprotein G (gG2) were synthesized and tested for reactivity with 173 serum specimens collected from 117 individuals. The oligopeptides were made as multiple antigenic peptides consisting of four copies of a unique sequence attached to a branched lysine core and separated from the core by four glycine residues. The sera included HSV antibody-negative samples as well as sera from individuals from whom HSV had been isolated. Isolated viruses were typed by indirect fluorescence using a panel of type-specific monoclonal antibodies. One peptide, corresponding to residues 561 to 578 of gG2, did not react with any sera lacking HSV-specific antibodies of with sera from HSV-1-infected individuals, but did react with sera from HSV-2-infected individuals. For sera taken seven or more days after initialclinical lesions, the detection rate of the peptide was 92% (47/51), comparable with the 98% (50/51) of truncated glycoprotein D, a sensitive type-common reagent. We conclude that this peptide, of structure (PEEFEGAGDGEPPEDDDSG4)K3A, is an immunodominant type-specific epitope for human antibodies and should be useful for type-specific serodiagnosis of HSV-2. Surprisingly, the epitope lies within one of the most conserved regions of gG1 and gG2. The test can distinguish an initial HSV-2 infection in the presence of a preexisting HSV-1 infection.

The UL4 gene of herpes simplex virus type 1 is dispensable for latency, reactivation and pathogenesis in mice.

The UL4 gene of herpes simplex virus type 1 is predicted to encode a 21.5 kDa protein of 199 amino acids. Although UL4 is dispensable for growth in cell culture, its function is not known. In the present study, the promoter of UL4 was examined and found to contain a cAMP-response element which bound the transcription factor CREB, and was strongly activated by cAMP. A recombinant virus, termed UL4HS, was constructed with a nonsense linker inserted into the UL4 open reading frame, to make a truncated UL4 protein of 60 amino acids. In addition, a marker-rescued virus, UL4HSMR, was constructed. Western immunoblot analysis revealed a 23 kDa band in extracts of wild-type and marker-rescued virus infected cells which was missing for UL4HS. Only modest differences were observed in the abilities of wild-type and UL4-mutant viruses to grow in Vero cells or in contact-inhibited mouse C3H/10T1/2 cells. In addition, there were only modest differences between the ability of UL4HS to replicate in murine corneas and trigeminal ganglia relative to wild-type viruses, and reactivation of UL4HS from latency was unaffected. Taken together, these data demonstrate that UL4 is dispensable for latency and pathogenesis in mice.

Identification of the UL4 protein of herpes simplex virus type 1.

Herpes simplex virus type 1 gene UL4 is predicted to encode a 199-amino-acid protein with a molecular mass of 21 5 kDa. We report here identification of this protein and its localization in the nuclei of infected cells. Antisera raised against oligopeptides corresponding to the C terminus of the predicted UL4 protein were used for identification of a 25 kDa protein as the product of the UL4 gene. This protein was not detected in cells infected with a UL4 defective mutant virus, but was synthesized by coupled in vitro transcription-translation of the UL4 gene. Synthesis of the 25 kDa protein was blocked by phosphonoacetic acid, an inhibitor of DNA synthesis, indicating that the UL4 gene is expressed with gamma kinetics. Subcellular fractionation showed the protein to be localized in the nucleus. It was not detected in virions or light particles.

The catalytic subunit of the DNA polymerase of herpes simplex virus type 1 interacts specifically with the C terminus of the UL8 component of the viral helicase-primase complex.

The herpes simplex virus type 1 (HSV-1) UL8 DNA replication protein is a component of a trimeric helicase-primase complex. Sixteen UL8-specific monoclonal antibodies (MAbs) were isolated and characterized. In initial immunoprecipitation experiments, one of these, MAb 804, was shown to coprecipitate POL, the catalytic subunit of the HSV-1 DNA polymerase, from extracts of insect cells infected with recombinant baculoviruses expressing the POL and UL8 proteins. Coprecipitation of POL was dependent on the presence of UL8 protein. Rapid enzyme-linked immunosorbent assays (ELISAs), in which one protein was bound to microtiter wells and binding of the other protein was detected with a UL8- or POL-specific MAb, were developed to investigate further the interaction between the two proteins. When tested in the ELISAs, five of the UL8-specific MAbs consistently inhibited the interaction, raising the possibility that these antibodies act by binding to epitopes at or near a site(s) on UL8 involved in its interaction with POL. The epitopes recognized by four of the inhibitory MAbs were approximately located by using a series of truncated UL8 proteins expressed in mammalian cells. Three of these MAbs recognized an epitope near the C terminus of UL8, which was subjected to fine mapping with a series of overlapping peptides. The C-terminal peptides were then tested in the ELISA for their ability to inhibit the POL-UL8 interaction: the most potent exhibited a 50% inhibitory concentration of approximately 5 microM. Our findings suggest that the UL8 protein may be involved in recruiting HSV-1 DNA polymerase into the viral DNA replication complex and also identify a potential new target for antiviral therapy.

Use of Vibrio spp. for expression of Escherichia coli enterotoxin B subunit fusion proteins: purification and characterization of a chimera containing a C-terminal fragment of DNA polymerase from herpes simplex virus type 1.

The nontoxic B subunit of Escherichia coli heat-labile enterotoxin (EtxB) is a convenient carrier molecule for the attachment and delivery of heterologous peptides into eukaryotic cells. To evaluate the properties of such EtxB-based fusion proteins an efficient method for their production and purification is required. High-level production and purification of native EtxB has been achieved using heterologous expression and secretion in a marine Vibrio (Amin, T., and Hirst, T. R., 1994, Protein Expression Purif. 5, 198-204). However, the use of this method to isolate EtxB fusion proteins has been precluded because of their susceptibility to degradation by extracellular proteases secreted by members of the Vibrionaceae. In this paper a method is described for production of EtxB-pol, comprising the enterotoxin B subunit linked to a 27-residue C-terminal fragment of Pol, the catalytic subunit of DNA polymerase of herpes simplex virus type 1 (HSV-1). Following assessment of the relative efficacy of different Vibrio strains as hosts for EtxB-pol expression, the chimera was produced at the highest level of 3.5 mg/liter by cultures of Vibrio sp.60. Addition of 0.3 mM EDTA to the growth medium blocked proteolysis of the secreted EtxB-pol fusion protein, which was then purified to homogeneity using ammonium sulfate fractionation and hydrophobic interaction chromatography, with a yield of 57%. Purified EtxB-pol reacted with both anti-EtxB and anti-Pol peptide antibodies, and was able to specifically bind UL42, a processivity factor which normally binds to the C-terminal region of HSV-1 Pol. This modified method for expression and purification of EtxB-pol should be of general utility for the preparation of other EtxB-based fusion proteins.

The herpes simplex virus type 1 UL8 protein influences the intracellular localization of the UL52 but not the ICP8 or POL replication proteins in virus-infected cells.

We have developed a panel of 14 monoclonal antibodies (MAbs) to POL, the catalytic subunit of herpes simplex virus type 1 (HSV-1) DNA polymerase encoded by gene UL30, and one MAb to the UL52 protein, another of the seven proteins essential for replication of HSV DNA. The approximate locations of the epitopes of the polymerase-specific MAbs were identified using truncated polymerase molecules, and the antibodies were characterized in a number of immunological assays allowing eight different specificities to be recognized. These MAbs, together with a polyclonal antibody raised in rabbits against a third DNA replication protein, ICP8, were used to localize the respective proteins by immunofluorescence in cells infected with wild-type HSV-1 or the DNA replication-defective mutants ambUL8 or 2-2. In BHK cells infected with ambUL8, a mutant with an amber termination codon within the coding region of gene UL8, the UL52 protein did not enter the nucleus, although ICP8 and POL entered the nucleus in a normal fashion. The failure of the UL52 protein to be correctly transported to the nucleus was also observed in both HFL and Vero cells infected with ambUL8. In contrast, UL52 protein was transported to the nucleus in BHK cells infected with wild-type HSV-1 or with 2-2, a mutant lacking a functional UL9 protein.

Suppression of amber nonsense mutations of herpes simplex virus type 1 in a tissue culture system.

We have investigated the ability of monkey kidney cell lines (SupD3 and SupD12) inducibly expressing an amber suppressor tRNA(ser) to suppress amber nonsense mutations in three genes of herpes simplex virus type 1 (HSV-1). HSV-1 mutant TK4, which contains a nonsense mutation in the non-essential viral thymidine kinase (TK) gene, synthesized a full-length TK polypeptide at about 30% of the wild-type (wt) level in induced SupD3 cells but not in the parental non-suppressor (Sup0) cells. Using complementing cells, we constructed HSV-1 mutants carrying nonsense mutations in an essential gene, UL8, encoding a protein essential for viral DNA replication (ambUL8) or in a partially dispensable gene, UL12, encoding alkaline nuclease (ambUL12). The growth of the mutants in Vero or Sup0 cells was either totally (ambUL8) or severely (ambUL12) impaired, whereas in cells expressing suppressor tRNA the mutants produced infectious virus. However, the yields were much lower than obtained with wt HSV-1. In Vero or Sup0 cells the mutants ambUL8 and ambUL12 failed to synthesize full-length UL8 and UL12 protein products, respectively. Western immunoblotting showed that the virus ambUL12 produced full-length UL12 protein in SupD12 cells which yielded a level of 25.9% of the alkaline nuclease activity of the wt HSV-1 control. Our results show that the levels of suppression of the nonsense mutations in ambUL8 and ambUL12 are insufficient to allow their continuing propagation in the available Sup+ cells. Possible reasons are discussed.

The distinction of serologically related ruminant alphaherpesviruses by the polymerase chain reaction (PCR) and restriction endonuclease analysis.

The amplification and analysis of a 468bp fragment from the gB gene of the serologically related ruminant alphaherpesviruses bovine herpesvirus-1.1 and 1.2 (BHV-1.1 and BHV-1.2), caprine herpesvirus-1 (CapHV-1), cervine herpesvirus-1 (CerHV-1) and rangiferine herpesvirus-1 (RanHV-1) by PCR and restriction endonuclease analysis is described. As primers, 22bp oligomers selected from the BHV-1 gB gene sequences were used for the amplification of the DNA from the five viruses. The amplification product from each virus was analysed by the restriction endonuclease enzymes BglI, HinfI, SmaI and AvaI. The specific amplification obtained demonstrate the existence of the gB gene sequences for each of the five alphaherpesviruses. However, sequences from some of the fragments were found to be different from those predicted from the gB gene following restriction endonuclease analysis. All five amplification products generated the same number of fragments after digestion with HinfI except for two additional bands evident in CapHV-1. The CerHV-1 and RanHV-1 fragments contained slightly different BglI restriction sites from those of the other three. While BHV-1.1, BHV-1.2, CapHV-1 and CerHV-1 contained SmaI and AvaI restriction sites, the RanHV-1 amplification product lacked both SmaI and AvaI restriction sites.

Intracellular localisation of herpes simplex virus type 1 ribonucleotide reductase subunits during infection of cultured cells.

We have analysed the intracellular localisation of herpes simplex virus type 1 ribonucleotide reductase during infection of cultured cells by indirect immunofluorescence using polyclonal and monoclonal antibodies specific for the R1 and R2 subunits. Three different viruses were used to infect cells, wild-type strain 17+ and two temperature-sensitive mutants, ts 1222, which produces R1 only, and ts 1207, which expresses a normal R2 and an altered R1 that fails to interact with R2 at the nonpermissive temperature because of an amino acid substitution in R1. R1 was detected 2 hr postinfection with all three viruses and remained evenly distributed throughout the cytoplasm. R2 was not observed until 4 hr postinfection and, in contrast to the even distribution of R1, was localised in discrete cytoplasmic foci close to the nucleus. In double-labelling experiments both R1 and R2 were found in these foci where they presumably associate to form the active enzyme. As expected R2 was not detectable in cells infected with ts 1222. In ts 1207-infected cells it formed wild-type-like foci, indicating that interaction with R1 is not required for R2 focus formation. R1 was present in a twofold excess over R2 in wild-type-infected cells. We suggest that the uncomplexed R1 could perform a role associated with the protein kinase present in the N-terminal domain.

Role of the carboxy terminus of herpes simplex virus type 1 DNA polymerase in its interaction with UL42.

Several recent reports implicate sequences at or near the C terminus of the catalytic subunit (POL) of herpes simplex virus type 1 (HSV-1) DNA polymerase in its interaction with the accessory protein UL42. We have investigated further the involvement of this region by three different approaches: anti-idiotype antibodies, a competition ELISA and inhibition of the interaction by peptides. Antibodies raised in rabbits to peptides corresponding to regions of POL all reacted in Western blots with POL. Surprisingly, the sera raised against C-terminal peptides (amino acids 1221 to 1235 and 1224 to 1235) also reacted with UL42. The UL42 reactivity was shown to be due to the presence of anti-idiotype antibodies, providing direct evidence for complementarity of the structure of the extreme C terminus of POL to a region of UL42. To measure the contribution of the C terminus of POL to UL42 binding we developed a competition ELISA using POL, a truncated polymerase lacking the carboxyl-terminal 27 amino acids (POLd1) and UL42. UL42 binding to immobilized POL was inhibited approximately four times more effectively by competition, in solution, with POL than with POLd1, indicating that the C-terminal 27 amino acids of POL are responsible for at least 75% of the binding energy. A peptide corresponding to these 27 amino acids (residues 1209 to 1235) inhibited both the POL-UL42 interaction and the stimulation of POL by UL42 and did so more effectively than peptides corresponding to amino acids just away from the C terminus (residues 1195 to 1223 and 1177 to 1195).

The herpes simplex virus type 1 origin-binding protein interacts specifically with the viral UL8 protein.

The products of herpes simplex virus type 1 (HSV-1) genes UL5, UL8 and UL52 form a complex in virus-infected cells that exhibits both DNA helicase and DNA primase activities. UL8 protein was purified from insect cells infected with a recombinant baculovirus and used to generate monoclonal antibodies (MAbs). MAb 0811 was shown to recognize the UL8 protein in both Western blots and immunoprecipitation assays and to co-precipitate the other two proteins in the complex from insect cells triply infected with recombinants expressing the UL5, UL8 and UL52 polypeptides. Experiments performed using extracts from doubly infected cells indicated that UL8 could interact separately with both the UL5 and UL52 proteins. Similar experiments using a recombinant virus that expressed the HSV-1 origin-binding protein (OBP), UL9, demonstrated a direct physical interaction between the helicase-primase complex and OBP which involved the UL8 subunit. The C-terminal DNA-binding domain of OBP is dispensable for this interaction, as evidenced by the ability of MAb 0811 to co-precipitate a truncated UL9 protein, containing only the N-terminal 535 amino acids, with UL8.

The herpes simplex virus type 1 strain 17 open reading frame RL1 encodes a polypeptide of apparent M(r) 37K equivalent to ICP34.5 of herpes simplex virus type 1 strain F.

The region between the 'a' sequence and the 5' end of the IE1 gene within the long repeat sequence of the herpes simplex virus (HSV) genome plays an important role in the neurovirulence of both HSV-1 strain F and HSV-1 strain 17. However, there has been controversy over the protein-coding potential of this region. Although an open reading frame (ORF) was predicted in HSV-1(F) and shown to encode a polypeptide called ICP34.5, only recently has a corresponding ORF, designated RL1, been recognized in HSV-1(17). To determine whether the HSV-1(17) ORF is expressed, we raised antipeptide sera against predicted amino acid sequences from RL1; one serum specifically recognized a 37K protein in HSV-1(17)-infected cell extracts. Compared with the corresponding HSV-1(F) polypeptide the HSV-1(17) protein has a lower apparent M(r), shows similar kinetics of accumulation and intracellular localization but may accumulate to lower levels than the HSV-1(F) protein. The non-neurovirulent HSV-1(17) deletion variant 1716 fails to synthesize detectable levels of ICP34.5. Thus we have established that HSV-1(17), like HSV-1(F), expresses ICP34.5, a protein important for HSV neurovirulence.

Epitope mapping identifies an exposed loop between the unique amino- and conserved carboxy-domains of the large subunit of herpes simplex virus type 1 ribonucleotide reductase.

The large subunits of herpes simplex virus types 1 and 2 ribonucleotide reductases contain unique amino-terminal regions comprising 311 and 318 residues respectively, which are not found in ribonucleotide reductases from other sources. We report the mapping of the epitope recognized by monoclonal antibody 1026, which is specific for the large subunit (R1) of HSV-1, and then deduce the structural relationship of the amino-terminal region of R1 with the rest of the protein. A panel of 10 fusion proteins containing sequences spanning the entire R1 subunit were constructed. They were used together with proteolytic fragments of R1 and several synthetic peptides to show that the epitope is discontinuous and appears to be a loop structure centered on a previously located trypsin-sensitive site at residue 305. The existence of the loop was suggested by the observation that reactivity of the antibody with R1 could be blocked by peptides corresponding to residues 289 to 303 and 308 to 313 which flank the trypsin-sensitive site. Our results suggest that the unique amino-terminal region of R1 consists of a structurally distinct domain which is linked to the conserved carboxy region by an exposed loop.

Purification and properties of the herpes simplex virus type 1 UL8 protein.

A rapid and simple two-step scheme for the purification of herpes simplex virus type 1 UL8 protein from insect cells infected with a recombinant baculovirus has been developed. The scheme involves DEAE-Sepharose and phenyl-Sepharose chromatography and yields approximately 1.5 mg of protein from 2.4 x 10(8) infected cells. The protein remains intact during purification as judged by its reactivity with amino and carboxy termini-specific antisera. Gel filtration chromatography showed that the protein exists as a monomer in solution. No binding of the protein to ssDNA or dsDNA or to a DNA/RNA hybrid could be demonstrated using a gel mobility shift assay.

Inhibition of herpes simplex virus type 1 DNA polymerase activity by peptides from the UL42 accessory protein is largely nonspecific.

To identify regions in the UL42 protein of herpes simplex virus type 1 which affect viral DNA polymerase activity, a series of 96 overlapping pentadecapeptides spanning the entire 488 amino acids of the UL42 protein were synthesized and tested for their ability to inhibit polymerase activity on a primed single-stranded M13 DNA template. Two assays were used: formation of full-length double-stranded M13 molecules and rate of incorporation of deoxyribonucleoside triphosphates. Peptides from five noncontiguous regions of the UL42 protein were found to inhibit herpes simplex virus type 1 polymerase activity in both the presence and absence of UL42 protein. The most active peptides from each region correspond to amino acids 23 to 38 (peptide 6), 64 to 78 (peptide 14), 89 to 102 (peptide 19), 229 to 243 (peptide 47), and 279 to 293 (peptide 57). By two different methods (DNA mobility shift and DNA precipitation), peptides 14, 19, 47, and 57 were found to bind DNA; they most probably inhibit enzyme activity by this mechanism. Peptide 6 did not bind DNA and must act by some mechanism other than competing for DNA. The inhibitory peptides were also tested for activity against mammalian polymerase alpha and the Klenow fragment of Escherichia coli polymerase. Although some limited specificity was demonstrated (up to 10-fold for peptide 6), all the peptides showed significant activity against both polymerase alpha and E. coli polymerase.

Maternal antibodies to gp120 V3 sequence do not correlate with protection against vertical transmission of human immunodeficiency virus.

A retrospective study of sera from mothers infected with human immunodeficiency virus (HIV-1) was undertaken to investigate whether the titers or affinities of antibodies against the third hypervariable region (V3 loop) of gp120 correlated with transmission of the virus from mother to child. The cohort comprised 7 mothers who transmitted HIV-1 to their children and 20 who did not. Sera were screened for reactivity against two synthetic peptides, one encompassing the entire V3 loop of gp120 (amino acids 297-330) and the other containing an immunodominant epitope from gp41 (amino acids 596-614). Doubling dilutions of sera were tested to obtain antibody titers against both peptides: Anti-gp41 titers were used to normalize the anti-V3 titers. Maternal sera were also screened for the presence of high-affinity antibodies against the V3 peptide. No differences were observed in either titers or affinities of maternal antibodies to the V3 sequence from transmitters and nontransmitters.