Characterization of the major glycoproteins of equine herpesviruses 4 and 1 and asinine herpesvirus 3 using monoclonal antibodies.

A panel of 14 monoclonal antibodies (MAbs) was used to characterize the high abundance glycoproteins of equine herpesviruses 4 (EHV-4) and 1 (EHV-1), and asinine herpesvirus 3 (AHV-3). The specificities of the MAbs, which had been determined previously for strains of EHV-4 and -1 from the U.S.A., in general were confirmed by ELISA for Australian strains of these viruses. Of the 14 MAbs seven were EHV-4 and -1 type-common and cross-reacted with AHV-3. Of the five MAbs that were EHV-1 type-specific, four cross-reacted with AHV-3, whereas neither of the EHV-4 type-specific MAbs reacted with AHV-3, providing further evidence for a closer evolutionary relationship between EHV-1 and AHV-3 than that between either of these viruses and EHV-4. By Western blot and immunoprecipitation analyses, the identity of the six major glycoproteins, gp2, gp10, gp13, gp14, gp18 and gp21/22a, of an Australian EHV-1 isolate was verified, and it was shown that AHV-3 had cross-reactive glycoproteins of very similar Mr to those of EHV-1; five homologous glycoproteins of EHV-4 were also identified. It was determined that the EHV-4 gp13 homologue had a much reduced Mr (67K) when the virus was grown in a continuous cell line than when grown in equine foetal kidney cells (95K). It is suggested that altered glycosylation by the cell line is responsible for this change in Mr. Those glycoproteins acting as major immunogens in the naturally infected host, at least in their ability to elicit antibody, were identified. It was found that gp2, gp13, gp14, gp18 and a glycoprotein at 120K (EHV-1) or 116K (EHV-4) were all important immunogens in mares following EHV-1-induced abortion, and in a specific pathogen-free foal experimentally infected with EHV-1 and later cross-challenged with EHV-4. Gp2, gp14 and gp18 were the major immunogens in the donkey in response to AHV-3 infection. The type specificity associated with these glycoproteins was also examined and it was found that although most if not all contain type-specific epitopes, gp2 and a glycoprotein at 120K, and to a lesser extent gp13 and gp18, were significantly type-specific in the serum from a mare following natural EHV-1 infection and abortion.

Characterization of the high Mr glycoprotein (gP300) of equine herpesvirus type 1 as a novel glycoprotein with extensive O-linked carbohydrate.

The high Mr glycoprotein (gp300) of equine herpesvirus type 1 was found to have an Mr, estimated by SDS-PAGE, of over 400,000 and was confirmed as being a surface glycoprotein by 125I-labelling. In contrast to [3H]glucosamine, gp300 showed very low levels of [3H]glucosamine, gp300 showed very low levels of [3H]mannose incorporation. The Mr of gp300 showed no detectable change upon treatment of purified virus with N-glycanase, and showed only a small change in virus-infected cells treated with tunicamycin. In addition, gp300 failed to bind the lectin concanavalin A. Taken together, these results indicate a lack of N-linked carbohydrate on gp300. The major carbohydrate species were found to be composed primarily of O-linked chains, as indicated by the sensitivity of the protein to monensin, to exoglycanase enzymes specific for sugars present in O-linked chains and to mild alkaline borohydride treatment, which revealed three species of carbohydrate of Mr of greater than 10,000, 2400 and 1100, respectively. Neuraminidase treatment and binding of Helix pomatia lectin indicated the presence of alpha-N-acetylglucosamine and sialic acid as terminal sugars. Immunological cross-reactivity of gp300 with a high Mr protein of equine herpesvirus type 4 was shown and it also exhibited a marked Mr variation in the vaccine strain Rhinomune.

Identification of the gB homologues of equine herpesvirus types 1 and 4 as disulphide-linked heterodimers and their characterization using monoclonal antibodies.

Equine herpesvirus types 1 and 4 (EHV-1 and EHV-4) labelled with [14C]glucosamine were purified from infected cell culture medium and profiles of their structural proteins were obtained that enabled identification of the major glycoproteins. Nine glycosylated polypeptides were identified for each virus. Preparations of the purified viruses each contained a glycoprotein which was linked by disulphide bonds, as determined by diagonal gel electrophoresis under reducing/non-reducing conditions. High Mr forms of this glycoprotein were detected for EHV-1 when the sample was not heated. The EHV-1 protein consisted of three polypeptides of Mr 108K, 76K and 58K and the EHV-4 protein consisted of three polypeptides of Mr 112K, 74K and 61K. Western blotting and immunoprecipitation with monoclonal antibodies confirmed that the EHV-1 gB homologue migrates with an apparent Mr of 108K (140K under non-reducing conditions) but is cleaved to give glycoproteins of 76K and 58K which are held together by disulphide bonds. The EHV-4 gB homologue consists of a 112K glycoprotein which is cleaved to give glycoproteins of 74K and 61K which are also linked by disulphide bonds.

Further biological, serological and biochemical characterization of North American, European and Southeast Asian strains of bovine herpesvirus 1 compared with other alphaherpesvirinae members.

Hemagglutination activity, structural protein profiles and neutralization assays were used in a comparative study of bovine herpesvirus 1 strains from the U.S.A., Canada, Great Britain, Denmark and Malaysia with equine, feline and human herpesviruses in order to further characterize the bovine herpesvirus 1 hemagglutinin. Bovine herpesvirus 1 strains of different geographical origins all showed hemagglutinating activity for mouse erythrocytes; furthermore, feline herpesvirus 1 was also shown to hemagglutinate mouse erythrocytes. Analyses of partly purified viruses showed that a distinctive and specific polypeptides profile is associated with each species of herpesviruses used in our study; strains of bovine herpesvirus 1 from North America, Europe and Southeast Asia however, presented a remarkable similarity as to their electrophoretic protein patterns. A protein similar to the 97-kDa bovine viral hemagglutinin was not identified with the hemagglutinating feline herpesvirus. An important neutralization epitope on the bovine viral hemagglutinin was also not found on feline, equine and human herpesviruses but was identified on all bovine strains tested from North America, Europe and Southeast Asia stressing the importance of the bovine hemagglutinin for eventual prophylactic purposes.

Application of cloned fragments of equine herpesvirus type-1 DNA for detection of virus-specific DNA in equine tissues.

Tissue specimens obtained from equine herpesvirus-1 (EHV-1), subtype 1-infected aborted foetuses were analysed for the presence of virus DNA by means of Southern blot and dot blot hybridisations. The specificity of the methods was confirmed although the sensitivity was inferior to classical techniques such as virus isolation. However, the possibility of detecting the state of the virus DNA and the ability to distinguish between subtypes were important features, and the dot blot method was shown to have potential for a rapid diagnostic test. This report demonstrates some potential practical applications of hybridisation methods for studying the pathogenesis and epidemiology of EHV-1 but also reveals limitations of the techniques.

Characterization of equine herpesvirus type 1 immediate early proteins.

EHV-1 immediate early (IE) gene expression in lytic infection results in the production of four high mol wt immediate early polypeptides (IEPs), designated IE1, IE2, IE2, and IE4; however, IE transcription is limited to the synthesis of a single 6-kb mRNA. Together, these findings raised questions as to whether the four IEPs were related products of the same gene. In the present study the IEPs were characterized with respect to their structural similarities, antigenic relatedness, and postsynthetic modifications. IE1 was the most abundant IEP, in that it accounted for approximately 80% of the IEP-incorporated radiolabel in infected rabbit kidney cells labeled under IE conditions with [35S]methionine or 14C-labeled amino acid mixtures. IE1 also was the major phosphorylated species. Limited proteolytic digestion of isolated radiolabeled IEP bands with Staph V8 protease yielded virtually identical fragment profiles in SDS-PAGE, as did digestions with chymotrypsin and N-chlorosuccinimide. Monospecific rabbit antisera raised against each of the four isolated IEPs reacted with all the IEP species in immunoblotting assays. Pulse-chase experiments indicated that all the IEPs were detectable immediately after a 15-min pulse and that several alterations in the IEP profile occurred during subsequent chase periods. Thus, the EHV-1 IEPs are closely related structurally and antigenically and appeared to be either produced simultaneously or processed to yield the individual forms immediately.

A comparison of the acid-soluble polypeptides of five herpesviruses.

The polypeptides soluble in 0.25 M-HCl were extracted from the nuclei of BHK cells infected with herpes simplex virus type 1 or type 2 and separated by SDS-PAGE. Seventeen polypeptides were detectable in each extract of which 10 type 1 and nine type 2 polypeptides were reproducibly effectively extracted. In cells infected with bovine mammillitis virus, pseudorabies virus or equine herpesvirus type 1, at least 12, 13 and eight polypeptides respectively were acid-soluble. In addition to histones, three other cellular polypeptides were present in sizeable quantities in the acid extracts and could obscure other acid-soluble viral polypeptides. Possible relationships between some polypeptides of the five herpesviruses are discussed.

Antigenic and biochemical analysis of gB of herpes simplex virus type 1 and type 2 and of cross-reacting glycoproteins induced by bovine mammillitis virus and equine herpesvirus type 1.

An antiserum was produced to the oligomeric form of glycoprotein B (gB) induced by herpes simplex virus type 1 (HSV-1) strain 17. This antiserum gave a single common precipitin line in agar gel immunodiffusion with HSV-1, HSV-2, bovine mammillitis virus (BMV) and equine herpesvirus type 1 (EHV-1). It also neutralized HSV-1, HSV-2 and BMV but not EHV-1. Absorption of the antiserum with excess HSV-2 or BMV antigen resulted in an HSV-1-specific neutralizing antiserum. In immunoprecipitation, two proteins, gB and pgB, were precipitated from HSV-1- and HSV-2-infected cells and at least three from BMV- and EHV-1-infected cells. Glycoprotein B and pgB of three HSV-1 and three HSV-2 strains and the corresponding antigenically related glycoproteins of BMV- and EHV-1-infected cells were labelled with 125I, digested with trypsin and the resulting peptides separated by two-dimensional thin-layer chromatography or high-pressure liquid chromatography. The resulting profiles were found to be almost identical, suggesting considerable structural conservation of the peptide backbone of the antigenically related glycoproteins of these four viruses.

A new field strain of equine abortion virus (equine herpesvirus-1) among Kentucky horses.

From restriction endonuclease characterization of the DNA of 317 isolates of equine abortion virus (equine herpesvirus-1; EHV-1) from 176 epizootically unrelated outbreaks of equine virus abortion occurring over 24 years in Kentucky, an epizootic pattern and variation of the virus have emerged. Two electropherotypes of EHV-1 (1P and 1B) accounted for greater than 90% of the nonvaccine-related abortion isolates examined. From 1960 to 1981, EHV-1 1P was the predominant isolate circulating in the central Kentucky area and the cause of greater than 80% of EHV-1-related abortions. In 1981, the occurrence of isolate 1B-related abortions began to increase and since 1982, 1B has become the most frequently recovered isolate of EHV-1 from aborted fetuses.

Molecular epidemiology and pathogenesis of some equine herpesvirus type 1 (equine abortion virus) and type 4 (equine rhinopneumonitis virus) isolates.

Representative strains of EHV isolated from an aborted foetus and from a horse with rhinopneumonitis in New Zealand had restriction endonuclease DNA fingerprints typical of those usually associated with these syndromes elsewhere and now designated EHV1 and 4 respectively. EHV1 was isolated from the brain and spinal cord of a 4-year-old gelding that died of myeloencephalitis. A mare on the same farm, at about the same time as the gelding developed myeloencephalitis, aborted and EHV1 was isolated from the tissues of the aborted foetus. Restriction endonuclease DNA fingerprints of the viruses isolated from myeloencephalitis and abortion were indistinguishable by Bam HI but were distinguishable using Bgl I, Pvu II, Xho I and Hind III. The restriction endonuclease DNA fingerprints of 3 EHV1 strains known to cause myeloencephalitis were compared with each other and with EHV1 strains not known to be associated with myeloencephalitis. The Bgl I Pvu II and Hind III DNA fingerprints of the 3 myeloencephalogenic strains appear distinguishable from non-myeloencephalogenic strains. Abortion was induced in a mare by intrauterine inoculation of EHV4. The Bam HI, Bgl I, Pvu II, Xho I and Hind III restriction endonuclease DNA fingerprints of the inoculum virus were indistinguishable from virus recovered from the foetus. It was concluded that passage of the virus through the foetus did not detectably alter the restriction endonuclease DNA fingerprint.

Restriction endonuclease DNA fingerprinting of respiratory, foetal and perinatal foal isolates of equine herpesvirus type 1.

DNA was prepared from 43 equine herpesvirus type 1 (EHV 1) isolates, 11 of which were from horses with respiratory disease, 22 from aborted equine foetuses, and 10 from foals that died perinatally. The restriction endonuclease DNA fingerprints of 10 of the 11 respiratory isolates, known with certainty to have been recovered from horses with respiratory disease, were entirely different from all but 3 of the 32 foetal or perinatal foal isolates. The exceptional respiratory isolate, EHV 1 Army 183, had a foetal (F) strain fingerprint but this virus cannot be said with certainty to have been isolated from the respiratory tract. The 3 exceptional foetal isolates, had respiratory (R) strain fingerprints, and were recovered from single sporadic abortions. There are no exceptions to the view that only R strains have been isolated from naturally occurring respiratory disease. Also it is clear that major epizootics of abortion (abortion storms) and of perinatal foal mortality are caused by F strains. The data together with an analysis of the epidemiological patterns, particularly in Australia, strongly support the view that F and R strains be regarded as separate species, EHV 1 and 4 respectively.

Identification of the envelope surface glycoproteins of equine herpesvirus type 1.

The structural polypeptides of purified enveloped virions of the Army 183 strain of equine herpesvirus type 1 (EHV-1) were examined by different analytical techniques to identify the envelope glycoproteins. Glycoproteins were identified by electrophoretic analysis in polyacrylamide slab gels of virus labelled in vivo with [3H]glucosamine or labelled enzymically in vitro with either UDP-[14C]galactose or sodium [3H]borohydride. Fluorograms revealed eleven glycoproteins (mol. wt. 260000, 150000, 138000, 90000, 87000, 65000, 62000, 60000, 50000, 46000, and 24000). These glycoproteins probably correspond to virion protein (VP) 1-2, 9b, 10, 13, 14, 16, 17, 18, 21, 22a and 25 respectively, as designated in two other EHV-1 strains. In addition, a poorly resolved glucosamine-rich region (mol. wt. 250000 to 200000) corresponded to VP 3 to 8. The two isotopic surface labelling methods revealed that all the virus glycoproteins were exposed on the envelope surface.

Serologic and molecular comparisons of several equine herpesvirus type 1 strains.

The molecular and serologic relatedness of 2 recent respiratory tract isolates of equine herpesvirus type 1, designated T1 and T2, were compared with the Army 183, Kentucky-A hamster-adapted (KyA-ha), and L-M cell-adapted (KyA-LM) strains. Electrophoresis in polyacrylamide gels revealed differences in virion structural proteins among 4 purified strains. Seven envelope glycoproteins (molecular weight of 93,000, 65,000, 62,000, 60,000, 36,000, 20,000, and 18,000) corresponding to virion proteins 13, 16, 17, 18, 23, 25, and 26a, respectively, found in both the Army 183 and KyA-ha strains had slightly different molecular weight counterparts in both the T1 and T2 isolates, which had identical structural protein profiles. virion protein 19 (58,000 daltons), a nonglycosylated protein, was present in reduced amounts in the respiratory tract isolates, whereas virion protein 8a (200,000 daltons) was absent. Virion protein 8a, an envelope glycoprotein, was only present in the KyA-ha strain. The T1 and T2 isolates were not neutralized by equine herpesvirus type 2 antiserum and revealed little cross-neutralizatio with the Army 183 and KyA-ha strains in plaque-reduction neutralization tests. Restriction endonuclease cleavage maps of viral DNA revealed a similar, but not identical, number and size of DNA fragments between T1 and T2 isolates. Likewise, DNa profiles of Army 183, KyA-ha, and KyA-LM were also similar to each other, but vastly different from the respiratory tract isolates.

Antigenic and structural conservation of herpesvirus DNA-binding proteins.

Previously, we have shown a common antigen of several herpesviruses (pseudorabies virus, equine abortion virus and bovine mammillitis virus) to be antigenically related to the major DNA-binding proteins of herpes simplex virus types 1 and 2. In this study we have purified the cross-reacting polypeptide from cells infected with pseudorabies virus, equine abortion virus and bovine mammillitis virus and shown the cross-reacting protein to be a major DNA-binding protein for each virus. Tryptic peptide analysis of the cross-reacting DNA-binding proteins of all five viruses has shown structural similarities. The proteins thus were shown to share common antigenic sites, to have similar biological properties and to have a highly conserved amino acid sequence. This unexpected similarity between proteins from diverse herpes viruses suggests an essential and fundamental role of the major DNA-binding protein in herpes virus replication.