Bovine herpesvirus 1 attachment to permissive cells is mediated by its major glycoproteins gI, gIII, and gIV

Identification of cell surface molecules that interact with pseudorabies virus

The alphaherpesvirus pseudorabies virus (PrV) has been shown to attach to cells by interaction between the viral glycoprotein gC and cell membrane proteoglycans carrying heparan sulfate chains (HSPGs). A secondary binding step requires gD and presumably another, hitherto unidentified cellular receptor. By use of a virus overlay protein binding assay (VOPBA), cosedimentation analyses, and affinity chromatography, we identified three species of cell membrane constituents that bind PrV. By treatment with EDTA, peripheral HSPGs of very high apparent molecular mass (>200 kDa) could be extracted from Madin-Darby bovine kidney cells. Binding of PrV to these HSPGs in the VOPBA was sensitive to enzymatic digestion with heparinase or papain. Cosedimentation analyses indicated that binding between PrV and high-molecular-weight HSPG depended on the presence of gC in the virion. In addition, adsorption of radiolabeled PrV virions to cells could be inhibited by the addition of purified high-molecular-weight HSPG. By using urea extraction buffer, a second species of HSPG of approximately 140 kDa could be solubilized. Binding of PrV to this HSPG in the VOPBA was also dependent on the presence of heparan sulfate, since reactivity was abolished after suppression of glycosaminoglycan biosynthesis with NaClO3 and after heparinase treatment. In addition to HSPG, in cellular membrane extracts obtained by treatment with mild detergent, a 85-kDa membrane protein was demonstrated to bind PrV in the VOPBA and affinity chromatography. In summary, we identified three species of cell membrane constituents that bind PrV: a peripheral HSPG of high molecular weight, an integral HSPG of approximately 140 kDa, and an integral membrane protein of 85 kDa. It is tempting to speculate that interaction between PrV and the two species of HSPG mediates primary attachment of PrV and that the 85-kDa protein is involved in a subsequent attachment step.

Glycoprotein Bb, the N-terminal subunit of bovine herpesvirus 1 gB, can bind to heparan sulfate on the surfaces of Madin-Darby bovine kidney cells

The present study confirms our previous findings made by using heparin affinity chromatography that bovine herpesvirus 1 gB can bind to heparin-like structures. In order to locate the functional domain for heparin binding, we expressed the extracellular portion of gB (gBt) and the large subunit of gB (gBb) in Madin Darby bovine kidney (MDBK) cells under the control of the bovine heat shock protein 70A gene promoter. The recombinant gBt and gBb were both efficiently secreted from the transfected cells. They were shown to have structural and antigenic properties similar to those of authentic gB. Like authentic gB, both gBt and gBb were able to bind heparin-Sepharose as well as heparan sulfates on MDBK cells. Thus, we suggest that at least one heparin-binding domain is localized in gBb, the N-terminal portion of gB, which agrees with the presence of clusters of prolines and basic residues, thought to be essential for heparin binding.

Bovine herpesvirus 1 UL49.5 homolog gene encodes a novel viral envelope protein that forms a disulfide-linked complex with a second virion structural protein

We previously reported that the genome of bovine herpesvirus 1 (BHV-1) contains an open reading frame (ORF) homologous to the herpes simplex virus UL49.5 ORF, and as with the herpes simplex virus UL49.5 ORF, the deduced amino acid sequence of the BHV-1 UL49.5 homolog (UL49.5h) contains features characteristic of an integral membrane protein, implying that it may constitute a functional gene encoding a novel viral envelope protein. This communication reports on the identification of the BHV-1 UL49.5h gene product. By employing an antibody against a synthetic BHV-1 UL49.5h peptide and an UL49.5h gene deletion mutant, the primary product of BHV-UL49.5h gene was identified as a polypeptide with a size of approximately 9 kDa; in both infected cells and isolated virions, the UL49.5h products were found to exist in three forms; monomer, disulfide-linked homodimer, and disulfide-linked heterodimer containing a second viral protein with a size of about 39 kDa. O-Glycosidase digestion and [3H]glucosamine labelling experiments showed that the UL49.5h protein is not glycosylated. Although the deduced amino acid sequence contains putative sites for myristylation and phosphorylation, we were unable to detect either modification. Surface labelling and trypsin digestion protection experiments showed that the BHV-1 UL49.5h protein was present on the surface of infected cells and on the surface of mature virions. Nonionic detergent partition of isolated virions revealed that the UL49.5h protein is more tightly associated with the virion tegument-nucleocapsid structure than envelope protein gD. The results from this study demonstrate that the BHV-1 UL49.5h gene encodes a nonglycosylated virion envelope protein which may associate with virion internal structures by forming a complex with the 39-kDa virion structural protein.

Characterization of cell-binding properties of bovine herpesvirus 1 glycoproteins B, C, and D: identification of a dual cell-binding function of gB

Previous studies have suggested that the attachment of bovine herpesvirus 1 (BHV-1) to permissive cells is mediated by its major glycoproteins B (gB), C (gC), and D (gD). In order to gain further insight into the mechanism of the BHV-1 attachment process, we purified authentic gB, gC, and gD from BHV-1-infected cells and membrane anchor-truncated, soluble gB, gC, and gD from stably transfected cell lines by affinity chromatography and examined their cell-binding properties on Madin-Darby bovine kidney cells. All of the glycoproteins tested exhibited saturable binding to Madin-Darby bovine kidney cells. All of the glycoproteins tested exhibited saturable binding to Madin-Darby bovine kidney cells. Addition of exogenous heparin or treatment of cells with heparinase to remove cellular heparan sulfate (HS) prevented both gC and gB from binding to cells but had no effect on gD binding. An assessment of competition between gB, gC, and gD for cell binding revealed that gC was able to inhibit gB binding, whereas other combinations showed no effect. Cell-bound gC could be dissociated by heparin or heparinase treatment. The response of bound gB to heparin and heparinase treatments differed for the authentic and soluble forms; while soluble gB was susceptible to the treatment, a significant portion of cell-bound authentic gB was resistant to the treatment. Binding affinity analysis showed that soluble gB and both forms of gC and gD each had single binding kinetics with comparable dissociation constants (Kds), ranging from 1.5 x 10(-7) to 5.1 x 10(-7) M, whereas authentic gB exhibited dual binding kinetics with Kd1 = 5.2 x 10(-7) M and Kd2 = 4.1 x 10(-9) M. These results demonstrate that BHV-1 gC binds only to cellular HS, gD binds to a non-HS component, and gB initially binds to HS and then binds with high affinity to a non-HS receptor. Furthermore, we found that while authentic gB was able to inhibit viral plaque formation, soluble gB, which retains the HS-binding property but lacks the high-affinity binding property, was defective in this respect. These results suggest that the interaction between gB and its high-affinity receptor may play a critical role in the virus entry process.

Interaction of herpes simplex virus glycoprotein gC with mammalian cell surface molecules

The entry of herpes simplex virus (HSV) into mammalian cells is a multistep process beginning with an attachment step involving glycoproteins gC and gB. A second step requires the interaction of glycoprotein gD with a cell surface molecule. We explored the interaction between gC and the cell surface by using purified proteins in the absence of detergent. Truncated forms of gC and gD, gC1(457t), gC2(426t), and gD1(306t), lacking the transmembrane and carboxyl regions were expressed in the baculovirus system. We studied the ability of these proteins to bind to mammalian cells, to bind to immobilized heparin, to block HSV type 1 (HSV-1) attachment to cells, and to inhibit plaque formation by HSV-1. Each of these gC proteins bound to conformation-dependent monoclonal antibodies and to human complement component C3b, indicating that they maintained the same conformation of gC proteins expressed in mammalian cells. Biotinylated gC1(457t) and gC2(426t) each bind to several cell lines. Binding was inhibited by an excess of unlabeled gC but not by gD, indicating specificity. The attachment of gC to cells involves primarily heparan sulfate proteoglycans, since heparitinase treatment of cells reduced gC binding by 50% but had no effect on gD binding. Moreover, binding of gC to two heparan sulfate-deficient L-cell lines, gro2C and sog9, both of which are mostly resistant to HSV infection, was markedly reduced. Purified gD1 (306t), however, bound equally well to the two mutant cell lines. In contrast, saturating amounts of gC1(457t) interfered with HSV-1 attachment to cells but failed to block plaque formation, suggesting a role for gC in attachment but not penetration. A mutant form of gC lacking residues 33 to 123, gC1(delta 33-123t), expressed in the baculovirus system, bound significantly less well to cells than did gC1(457t) and competed poorly with biotinylated gC1(457t) for binding. These results suggest that residues 33 to 123 are important for gC attachment to cells. In contrast, both the mutant and wild-type forms of gC bound to immobilized heparin, indicating that binding of these proteins to the cell surface involves more than a simple interaction with heparin. To determine that the contribution of the N-terminal region of gC is important for HSV attachment, we compared several properties of a mutant HSV-1 which contains gC lacking amino acids 33 to 123 to those of its parental virus, which contains full-length gC. The mutant bound less well to cells than the parental virus but exhibited normal growth properties.(ABSTRACT TRUNCATED AT 400 WORDS)

Characterization of bovine herpesvirus 1 UL49 homolog gene and product: bovine herpesvirus 1 UL49 homolog is dispensable for virus growth

The sequence of the bovine herpesvirus 1 (BHV-1) gene that is homologous to the herpes simplex virus UL49 gene was determined. The BHV-1 UL49 homolog open reading frame consists of 774 bp and is capable of encoding 258 amino acids. Northern (RNA) blot analysis showed that the BHV-1 UL49 homolog is transcribed into a 1.1-kb RNA which is coterminal with the transcripts of an upstream UL49.5 homolog gene. Rabbit antisera produced against synthetic peptides of the predicted UL49 homolog gene product recognized a polypeptide of 33 to 35 kDa in both virus-infected cells and isolated virions. Further analysis by unionic-detergent partition of isolated virions suggested that the UL49 homolog gene product is a virion tegument protein. Indirect immunofluorescence assay revealed that the UL49 homolog gene product was predominantly localized in the nuclei of BHV-1-infected cells. A mutant virus with the UL49 homolog gene deleted was produced, and it was able to replicate in noncomplementing cells. Nevertheless, the yield of mutant virus was significantly reduced. The results from this study suggest that the BHV-1 UL49 homolog gene encodes a nuclear protein which constitutes a tegument component in mature virions and that it is dispensable for virus growth in cell culture.

The role of the major tegument protein VP8 of bovine herpesvirus-1 in infection and immunity

The tegument of bovine herpesvirus-1 (BHV-1) carries an abundant protein of 96 kDa, termed VP8. Immunolabeling using VP8-specific antiserum and colloidal gold-labeled protein A as the electron-dense marker was used to identify VP8 in the virions and virus-infected cells. VP8 was confirmed to be a tegument protein that, like the herpes simplex virus-1 homologue VP13/14, contains O-linked carbohydrates. VP8 was found in the nucleus of virus-infected cells as early as 2 hr postinfection. Since VP8 is a gamma2 protein, this protein cannot be newly synthesized at this time and must be acquired from the inoculum. This supports the hypothesis that early during infection, VP8 has a function in modulation of alpha gene expression. Later during infection, VP8 was observed in the cytoplasm around nucleocapsids and in dense inclusions, which accumulated in the cisternae of the Golgi. In addition, de novo-synthesized VP8 continued to accumulate in the nucleus in dense areas and around nucleocapsids. In calves, VP8 stimulated T cell proliferation and antibody production, both after BHV-1 challenge and after immunization with purified VP8. These results suggest a role for VP8 in the induction of humoral and specifically cell-mediated immunity to BHV-1.

Mapping, cloning and sequencing of a glycoprotein-encoding gene from bovine herpesvirus type 1 homologous to the gE gene from HSV-1

In order to map and identify the glycoprotein-encoding gene from bovine herpesvirus type 1 (BHV-1), homologous to the gE glycoprotein from herpes simplex virus type 1 (HSV-1), a region of the unique short sequence from the BHV-1 genome has been sequenced. The sequenced region contains an ORF coding for a polypeptide of 575 amino acids (aa). The aa sequence presents substantial similarity to that of the glycoprotein gE from HSV-1 and to homologous proteins of related viruses such as pseudorabies virus, equine herpesvirus type 1 and varicella zoster virus. The aa sequence presents additional characteristics compatible with the structure of a viral glycoprotein: signal peptide, putative glycosylation sites and a long C-terminal transmembrane alpha-helix.

A subunit gIV vaccine, produced by transfected mammalian cells in culture, induces mucosal immunity against bovine herpesvirus-1 in cattle

A truncated version of bovine herpesvirus-1 (BHV-1) glycoprotein IV (tgIV) was produced in a novel, non-destructive expression system based upon regulation of gene expression by the bovine heat-shock protein 70A (hsp70) gene promoter in Madin Darby bovine kidney (MDBK) cells. In this system, up to 20 micrograms ml-1 of secreted tgIV, which is equivalent to the yield from 4 x 10(6) cells, was produced daily over a period of up to 18 days. Different doses of tgIV were injected intramuscularly into seronegative calves. Virus-neutralizing antibodies were induced by all doses of tgIV, both in the serum and in the nasal superficial mucosa. However, the low dose (2.3 micrograms) induced significantly (p < 0.05) lower antibody titres than the medium (7 micrograms) and high (21 micrograms) doses. The medium and high doses of tgIV conferred protection from BHV-1 infection, as demonstrated by a significant (p < 0.05) reduction in clinical signs of respiratory disease and virus shedding in the nasal secretions postchallenge. However, the 2.3 micrograms group, although partially protected, was not significantly (p > 0.05) different from the placebo group. This study demonstrated the potential of an intramuscularly administered tgIV subunit vaccine to induce mucosal immunity to BHV-1 using an economic protein production system and an acceptable vaccine formulation. In addition, a strong correlation was observed between neutralizing antibodies in the serum and nasal superficial mucosa, virus shedding and clinical disease. Thus, serum neutralizing antibody levels in tgIV-immunized animals may be a good prognosticator of protection from BHV-1 infection and disease.

Truncated bovine herpesvirus-1 glycoprotein I (gpI) initiates a protective local immune response in its natural host

Current modified live and killed BHV-1 vaccines have not reduced the incidence of bovine herpesvirus-1 (BHV-1), the principal viral agent in bovine respiratory disease complex. The requirement for production of viral proteins for immune study has resulted in the establishment of a cell line which constitutively expresses BHV-1 gpI. A truncated BHV-1 envelope gpI protein was secreted into the culture supernatant of D17 cells transfected with the gpI gene lacking the coding sequence for the transmembrane region (TMR). The transmembrane domain is essential for gpI stability in the envelope, virus infectivity and, most probably, natural killer cell recognition; however, we have tested the possibility that this domain is not required for inducing an adaptive, protective immune response. Immunization of calves with this truncated gpI protein induced gpI-specific nasal IgA, IgG1, serum neutralizing antibodies and gpI-specific peripheral lymphocyte proliferation. All immunized calves were protected from clinical disease after BHV-1 challenge. Further, nine of ten immunized calves had no intranasal viral shedding. One animal shed a minimal amount of virus following challenge, but produced no antibodies to other viral proteins as evidenced by immunoprecipitation of 35S-labelled viral proteins by sera from virus-challenged animals. This study represents the first evidence that a recombinant truncated gpI subunit vaccine can confer local mucosal immunity and establish a strong protective barrier against disease caused by BHV-1 in the natural host. Also, these data demonstrate the feasibility of preventing initial viral replication in the host and distinguishing vaccinated from wild-type virus-infected animals.

Development of a rapid and sensitive polymerase chain reaction assay for detection of bovine herpesvirus type 1 in bovine semen

We developed a polymerase chain reaction (PCR) assay to detect bovine herpesvirus type 1 (BHV-1) in bovine semen. Since bovine semen contains components that inhibit PCR amplification, a protocol was developed to purify BHV-1 DNA from bovine semen. To identify failures of PCR amplification, we used an internal control template that was coamplified by the same PCR primers. When separated fractions of BHV-1-contaminated semen were analyzed by the PCR, we found that more than 90% of the BHV-1 DNA was present in a pooled fraction consisting of seminal fluid, nonsperm cells, and virus adsorbed to spermatozoa. By using this fraction, three to five molecules of BHV-1 DNA in 50 microliters of bovine semen could be detected. A pilot study to compare this PCR assay with the routinely used virus isolation method showed that this PCR assay is 2- to 100-fold more sensitive. In addition, the results of the PCR assay are available in 1 day, whereas the virus isolation method takes 7 days. Therefore, the PCR assay may be a good alternative to the virus isolation method.

Efficacy of a deletion mutant bovine herpesvirus-1 (BHV-1) vaccine that allows serologic differentiation of vaccinated from naturally infected animals

Fifteen bovine herpesvirus-1 (BHV-1)-negative calves were vaccinated intramuscularly with 10(7.4) plaque-forming units of a double-deletion BHV-1 mutant (IBRV(NG)dltkdlgIII), and 6 remained as nonvaccinated controls. Thirty days after vaccination, the animals were challenged by nasal instillation of 10(8.2) CCID50 of a virulent BHV-1 strain (Cooper). The vaccinated calves were protected against wildtype virus challenge as demonstrated by clinical evaluation. Most of the vaccinates developed only a mild rhinitis (lasting an average of 6.5 days) with almost no systemic symptoms, whereas the controls developed a serious illness characterized by rhinitis (mean = 11.5 days), conjunctivitis, hyperthermia, apathy, loss of appetite, and dyspnea. The vaccinates also shed significantly less virus and for a shorter period of time (mean = 5.5 days) than the controls (mean = 9 days). Thirty days after vaccination, the vaccinates were negative in an anti-gIII specific blocking enzyme-linked immunosorbent assay (ELISA), despite the fact that most of them had developed neutralizing antibodies (serum neutralization titers ranging from 1:2 to 1:16). Seroconversion to gIII was detected as early as 7 days postinfection (dpi). Fourteen days after the challenge, all the animals exposed to wildtype BHV-1 had developed anti-gIII antibodies and were positive in this differential serologic test. Six controls plus 8 vaccinates kept in isolation were still positive to gIII when tested at 75 dpi. The use of the IBRV(NG)dltkdlgIII strain in conjunction with an anti-gIII specific blocking ELISA kit represents a powerful tool for BHV-1 control/eradication programs.

Expression of glycoprotein gIII-human decay-accelerating factor chimera on the bovine herpesvirus 1 virion via a glycosyl phosphatidylinositol-based membrane anchor

Mutants of bovine herpesvirus 1 that express a truncated envelope glycoprotein gIII or a gIII-human decay-accelerating factor (hDAF) chimeric protein (gIII.hDAF) were employed to evaluate the function of the transmembrane and cytoplasmic domains of the gIII molecule. Truncated gIII (i.e., lacking the transmembrane and cytoplasmic region) was readily released from infected cells and was not detected on mature virus particles. In contrast, replacement of the transmembrane and cytoplasmic domains with the carboxyl-terminal portion of hDAF restored the expression of gIII on the membranes of infected cells as well as on virion surfaces. The presence of the gIII.hDAF chimera on virus particles was also associated with normal gIII function, i.e., the mediation of virus attachment and penetration. The gIII-hDAF chimera, which is present on both infected cell surfaces and virions, could be cleaved by a phosphatidylinositol-specific phospholipase C, indicating that it was anchored in the membrane via glycosyl phosphatidylinositol. Our results from this study suggest that the transmembrane and cytoplasmic regions of the gIII molecule serve as a general membrane anchor, but they do not contain structural signals required for the specific assembly of envelope proteins into mature virions.

Resistance of herpes simplex virus type 2 to neomycin maps to the N-terminal portion of glycoprotein C

Entry of herpes simplex virus (HSV) into cells is believed to be mediated by specific binding of envelope proteins to a cellular receptor. Neomycin specifically blocks this initial step in infection by HSV-1 but not HSV-2. Resistance of HSV-2 to this compound maps to a region of the genome encoding glycoprotein C (gC-2). We have studied the function of gC-2 in the initial interaction of the virus with the host cell, using HSV-2 mutants deleted for gC-2 and gC-2-rescued recombinants. Resistance to neomycin was directly linked to the presence of gC-2 within the viral genome. In addition, deletion of the gC-2 gene caused a marked delay in adsorption to cells relative to the wild-type virus. HSV-1 recombinants containing chimeric gC genes composed of HSV-1 and HSV-2 sequences were used to localize neomycin resistance within the N-terminal 223 amino acids of gC-2. This region of the glycoprotein comprises an important domain responsible for binding of HSV-2 to cell receptors in the presence of neomycin. A gC-2-negative mutant is still infectious, indicating that HSV-2 also has an alternative pathway of adsorption.

Analysis of bovine herpesvirus 1 glycoprotein gIV truncations and deletions expressed by recombinant vaccinia viruses

Glycoprotein gIV is an envelope component of bovine herpesvirus type 1 and appears to be involved in attachment, penetration, and cell fusion. Four antigenic domains which include both continuous and discontinuous epitopes have been previously defined by competition binding assays using gIV-specific monoclonal antibodies (MAbs). Here we describe the construction of C-terminal truncations and internal deletions in the gIV-encoding gene and analyses of the effects of these mutations on the synthesis, processing, transport, and antigenicity of glycoprotein gIV as expressed by recombinant vaccinia viruses. Wild-type gIV expressed by recombinant vaccinia virus STgIV was indistinguishable from authentic gIV produced in bovine herpesvirus 1-infected cells with respect to molecular weight, processing, transport, and antigenicity. Analysis of the mutant proteins showed that the binding sites for MAbs 9D6 and 3D9S, which recognize linear epitopes, lie between amino acids 164 and 216 and amino acids 320 and 355, respectively. Discontinuous epitopes recognized by MAbs 3E7, 4C1, 2C8, and 3C1 were located between amino acids 19 and 320, whereas amino acids 320 to 355 were critical for binding of MAb 136. All mutant proteins containing amino acids 245 to 320 were processed, possess endo-beta-N-acetylglucosaminidase H-resistant oligosaccharides, and were transported to the cell surface or secreted into the medium. In contrast, mutant proteins missing amino acids 245 to 320 were retained in the rough endoplasmic reticulum. These findings suggest that residues 245 to 320 are important for proper processing and transport of gIV to the cell surface.

Role of N-linked glycans in antigenicity, processing, and cell surface expression of bovine herpesvirus 1 glycoprotein gIV

Glycoprotein gIV, a structural component of bovine herpesvirus type 1, stimulates high titers of virus-neutralizing antibody. The protein contains three potential sites for the addition of N-linked carbohydrates. Three mutants were constructed by oligonucleotide-directed mutagenesis, in each case changing one N-linked glycosylation site from Asn-X-Thr/Ser to Ser-X-Thr/Ser. A fourth mutant was altered at two sites. The altered forms of the gIV gene were cloned into a vaccinia virus transfer vector to generate recombinant vaccinia viruses expressing mutant proteins. Analysis of these mutants revealed that only two (residues 41 and 102) of the three (residues 41, 102, and 411) potential sites for the addition of N-linked glycans are actually utilized. Absence of glycans at residue 41 (gN1) showed no significant effect on the conformation of the protein or induction of a serum neutralizing antibody response. However, mutant proteins lacking glycans at residue 102 (gN2) or residues 41 and 102 (gN1N2) showed altered reactivity with conformation-dependent gIV-specific monoclonal antibodies. These mutants also induced significantly lower serum neutralizing antibody responses than wild-type gIV. Nonetheless, each of the mutant proteins were modified by the addition of O-glycans and transported to the cell surface. Our results demonstrate that absence of N-linked glycans at one (residue 102) or both (residues 41 and 102) utilized N-linked glycosylation sites alters the conformation but does not prevent processing and transport of gIV to the cell surface.

Identification of different target glycoproteins for bovine herpes virus type 1-specific cytotoxic T lymphocytes depending on the method of in vitro stimulation

Vaccinia virus recombinants expressing the three major bovine herpes virus-1 (BHV-1) glycoproteins gI, gIII and gIV were used to identify the major target antigens for BHV-1-specific CTL isolated from immune cattle. Peripheral blood mononuclear cells (PBMC) expanded in vitro in the presence of interleukin-2 (IL-2) and lysed both gIII- and gIV-infected target cells. Secondary in vitro stimulation of PBMC was also performed in the presence of either fixed BHV-1-infected autologous fibroblasts or ultraviolet (UV)-inactivated virus. Both methods of antigen presentation allowed the proliferation of BHV-1-specific CTL but the target glycoprotein for these CTL differed depending on the method of stimulation. Vaccinia-gIV-infected targets were lysed predominantly when PBMC were stimulated by fixed infected fibroblasts, whilst PBMC stimulated by UV-inactivated virus lysed mostly vaccinia-gIII-infected targets. This observation could be explained by a different processing pathway of BHV-1 antigens in each cell type involved.

Interactions of bovine and caprine herpesviruses with the natural and the foreign hosts

Bovine herpesvirus 1 (BHV1) and caprine herpesvirus 1 (CapHV1) are useful models to study virus-host interactions, as well as pathogenicity and latency, when comparing the outcome of infection in the natural and the foreign hosts. Molecular seroepidemiological analyses revealed that cross-reacting antibodies were mainly induced by glycoprotein gI (gB analogue), by the major capsid protein and by nonstructural proteins, whereas the most virus-specific antibodies were elicited by glycoproteins gIII and gIV. These glycoproteins, especially gIII (gC analogue), might therefore play an important role in the virus-host-interactions. As a basis for further studies, we re-evaluated observations concerning experimental infections with BHV1 and CapHV1 in the natural and the foreign hosts. All parameters indicated that both viruses were able to infect either host, but that the pathogenicity was restricted to the natural host. Latent virus could be reactivated exclusively from cows infected with BHV1. It was possible neither to reactivate BHV1 from goats, nor to reactivate CapHV1 from either species. The experiments indicated that the outcome of infection in the natural and the foreign host is dependent on host and viral factors, whereby gIII is only one important virus component involved. Further investigations in the host and host cell range of BHV1 and CapHV1 will help to clarify the role of factors responsible for virus-host-interactions.

Structural, functional, and immunological characterization of bovine herpesvirus-1 glycoprotein gl expressed by recombinant baculovirus

The major glycoprotein complex gl of bovine herpesvirus-1 was expressed at high levels (36 micrograms per 1 x 10(6) cells) in insect cells using a recombinant baculovirus. The recombinant gl had an apparent molecular weight of 116 kDa and was partially cleaved to yield 63-kDa (glb) and 52-kDa (glc) subunits. This processing step was significantly less efficient in insect cells than the analogous step in mammalian cells, even though the cleavage sites of authentic and recombinant gl were shown to be identical. The oligosaccharide linkages were mostly endoglycosidase-H-sensitive, in contrast to those of authentic gl, which has mostly endoglycosidase-H-resistant linkages and an apparent molecular weight of 130/74/55 kDa. Despite the reduced cleavage and altered glycosylation, the recombinant glycoprotein was transported and expressed on the surface of infected insect cells. These surface molecules were biologically active as demonstrated by their ability to induce cell-cell fusion. Fusion was inhibited by three monoclonal antibodies specific for antigenic domains I and IV on gl. Domain I maps to the extracellular region of the carboxy terminal fragment glc and domain IV to the very amino terminus of the glb fragment, indicating that domains mapping in two distinct regions of gl function in cell fusion. Monoclonal antibodies specific for eight different epitopes recognized recombinant gl, indicating that the antigenic characteristics of the recombinant and authentic glycoproteins are similar. In addition, the recombinant gl was as immunogenic as the authentic gl, resulting in the induction of gl-specific antibodies in cattle.

An in vivo study of a glycoprotein gIII-negative bovine herpesvirus 1 (BHV-1) mutant expressing beta-galactosidase: evaluation of the role of gIII in virus infectivity and its use as a vector for mucosal immunization

We constructed a recombinant BHV-1 in which the glycoprotein gIII gene was replaced by the Escherichia coli lacZ gene. The resultant virus mimics the simple gIII deletion mutant in its growth characteristics in cell culture; however, it expresses beta-galactosidase in virus-infected cells. Further characterization of its virulence and the immune responses elicited by it was conducted in cattle. The mutant virus retained the ability to establish an infection when administered intranasally. Infected animals were also capable of transmitting virus to sentinel penmates. However, the mutant virus showed a reduced replication efficiency in the respiratory tract of cattle, as manifested by significantly lower virus shedding and a shorter duration of shedding when compared to wild-type (wt) BHV-1 infections. The mutant virus induced an efficient anti-BHV-1 antibody response and convalescent cattle were fully protected from subsequent wt virus challenge. In addition, cattle infected with the lacZ-expressing virus developed antibodies to beta-galactosidase. Our results demonstrate that the presence of gIII is not a prerequisite for BHV-1 infection; however, gIII does play an important role in maintaining virus replication efficacy in its natural host. With respect to developing BHV-1 as a vaccine vector, our results indicate that deletion of the gIII gene, which partially attenuates the virus and serves as a vaccine virus marker, does not compromise immunogenicity to BHV-1. Most importantly, this vector is effective in delivering foreign antigens to mucosal surfaces of the respiratory tract.

Induction of a mucosal barrier to bovine herpesvirus 1 replication in cattle

Current vaccines for human and animal herpesviruses engender an immunity that may ameliorate disease but generally fails to prevent infection, latency, reactivation from latency, or spread through a population. By administering intranasally to cattle bovine herpesvirus type 1 virion envelope proteins combined with the potent mucosal immune system adjuvant, cholera toxin B subunit, we engendered a local antibody response that acted as a barrier to infection of mucosal epithelial cells and thereby prevented viral replication, consequently precluding disease, latency, and spread.

Glycoprotein IV of bovine herpesvirus 1-expressing cell line complements and rescues a conditionally lethal viral mutant

Glycoprotein IV (gIV) of bovine herpesvirus 1 (BHV-1), a homolog of herpes simplex virus glycoprotein D, represents a major component of the viral envelope and a dominant immunogen. To analyze the functional role of gIV during BHV-1 replication, cell line BUIV3-7, which constitutively expresses gIV, was constructed and used for the isolation of gIV- BHV-1 mutant 80-221, in which the gIV gene was replaced by a lacZ expression cassette. On complementing gIV-expressing cells, the gIV- BHV-1 replicated normally but was unable to form plaques and infectious progeny on noncomplementing cells. Further analysis showed that gIV is essential for BHV-1 entry into target cells, whereas viral gene expression, DNA replication, and envelopment appear unchanged in both noncomplementing and complementing cells infected with phenotypically complemented gIV- BHV-1. The block in entry could be overcome by polyethylene glycol-induced membrane fusion. After passaging of gIV- BHV-1 on complementing cells, a rescued variant, BHV-1res, was isolated and shown to underexpress gIV in comparison with its wild-type parent. Comparison of the penetration kinetics of BHV-1 wild type, phenotypically complemented gIV- BHV-1, and BHV-1res indicated that penetration efficiency correlated with the amount of gIV present in virus particles. In conclusion, we show that gIV of BHV-1 is an essential component of the virion involved in virus entry and that the amount of gIV in the viral envelope modulates the penetration efficiency of the virus.

Pseudorabies virus gIII and bovine herpesvirus 1 gIII share complementary functions

The gIII glycoproteins of bovine herpesvirus 1 (BHV-1) and of pseudorabies virus (PRV) are structurally homologous. Both proteins also play preeminent roles in mediating virus attachment to permissive cells. To directly compare the functional relation between these glycoproteins, we constructed a recombinant BHV-1 in which the BHV-1 gIII coding sequence was replaced by the PRV gene homolog. The resultant recombinant virus efficiently expressed PRV gIII and then incorporated it into its envelope. The levels of PRV gIII expression and incorporation were equivalent to those achieved by the wild-type virus for BHV-1 gIII. The recombinant virus was fully susceptible to neutralization by anti-PRV gIII neutralizing antibody. In addition, the virus attachment and penetration functions, as well as the virus replication efficiency, which were lost by deleting the BHV-1 gIII gene, were restored by expressing the PRV gIII homolog in its place. These results demonstrated that PRV gIII and BHV-1 gIII share complementary functions.