Gene mapping and sequence analysis of the unique short region of the simian herpesvirus SA 8 genome

In vitro characterization of EHV-4 gG-deleted mutant

Equine herpesvirus 4 (EHV-4) is an important pathogen that causes respiratory tract disease in horse populations worldwide. Glycoprotein G (gG) homologs have been identified in several alphaherpesviruses as minor non-essential membrane-anchored glycoproteins. In this study, EHV-4 gG deletion mutant has been generated by using bacterial artificial chromosome technology to investigate the role of gG in viral pathogenesis. Our findings reported here revealed no significant difference between parental EHV-4 and gG-negative strain in their replication cycle in cell culture. Furthermore, virus titers and plaque formation were comparable in both viruses. It is noteworthy that these findings disagree with the previously published study describing gG deletion in another EHV-4 strain.

Equine herpesvirus 4: recent advances using BAC technology

The equine herpesviruses are major infectious pathogens that threaten equine health. Equine herpesvirus 4 (EHV-4) is an important equine pathogen that causes respiratory tract disease, known as rhinopneumonitis, among horses worldwide. EHV-4 genome manipulation with subsequent understanding of the viral gene functions has always been difficult due to the limited number of susceptible cell lines and the absence of small-animal models of the infection. Efficient generation of mutants of EHV-4 would significantly contribute to the rapid and accurate characterization of the viral genes. This problem has been solved recently by the cloning of the genome of EHV-4 as a stable and infectious bacterial artificial chromosome (BAC) without any deletions of the viral genes. Very low copy BAC vectors are the mainstay of present genomic research because of the high stability of inserted clones and the possibility of mutating any gene target in a relatively short time. Manipulation of EHV-4 genome is now feasible using the power of BAC technology, and should aid greatly in assessing the role of viral genes in the virus-host interaction.

Complete genome sequence of cercopithecine herpesvirus 2 (SA8) and comparison with other simplexviruses

We have obtained the complete sequence of the herpesvirus simian agent 8 (SA8; cercopithecine herpesvirus 2) a baboon simplexvirus closely related to the monkey B virus and herpes simplex virus types 1 and 2. The genome of SA8 is 150,715 bp long, with an overall G/C content of 76%, the highest among the simplexviruses sequenced so far. The sequencing has confirmed that the genomic arrangement of SA8 is similar to that of other simplexviruses: unique long and unique short regions bordered by two sets of inverted repeats. All genes identified in SA8 are homologous and collinear with those of the monkey B virus, including the lack of the RL1 open reading frame, a gene responsible for neurovirulence in human herpes simplex viruses. This latter finding supports the hypothesis that a different pathogenetic mechanism may have developed in human simplexviruses, after their divergence from monkey simplexviruses.

Efficacy of a B virus gD DNA vaccine for induction of humoral and cellular immune responses in Japanese macaques

It is desirable to prevent dissemination of B virus (BV) in macaque colonies because transmission of BV to humans causes deadly encephalomyelitis. Vaccination of monkeys is one method that could confine spread of BV within macaque colonies. Availability of a BV DNA vaccine for use in macaques would eliminate the risk of working with infectious BV. Toward this end, we constructed a plasmid expressing the BV glycoprotein D (gD). Immunogenicity of this construct as a DNA vaccine was assessed in adult Japanese macaques by four intracutaneous injections at a dose of 500 microg per head. Results of enzyme-linked immunosorbent assay (ELISA) using a recombinant herpes simplex virus type 1 (HSV1) gD, a homologue of BV gD, showed that significant levels of antibody was induced in all vaccinated animals following each booster injection. Western blot of sera from vaccinated macaques confirmed the specific recognition of authentic BV gD. Immune sera were also demonstrated to contain neutralizing activity against infectious BV. Weak lymphoproliferative responses were also observed in vaccinated macaques using recombinant HSV1 gD as a stimulating antigen and flow cytometry analysis of one individual revealed the presence of HSV1 gD-responsive effector T cells. Thus, the BV gD DNA vaccine was demonstrated to induce both humoral and cellular immune responses in macaques which recognized BV gD.

Sequence and genetic arrangement of the U(S) region of the monkey B virus (cercopithecine herpesvirus 1) genome and comparison with the U(S) regions of other primate herpesviruses

The sequence of the unique short (U(S)) region of monkey B virus (BV) was determined. The 13 genes identified are arranged in the same order and orientation as in herpes simplex virus (HSV). These results demonstrate that the BV U(S) region is entirely colinear with that of HSV type 1 (HSV-1), HSV-2, and simian agent 8 virus.

Bovine herpesvirus 1 glycoprotein G is required for prevention of apoptosis and efficient viral growth in rabbit kidney cells

In rabbit kidney (RK13) cells, gG-negative BHV-1 exhibited significant defects in plaque formation and growth compared to that of gG-positive BHV-1. RK13 cells infected with gG-negative BHV-1 exhibited a distinctive CPE and contained a larger number of cells stained with trypan blue dye compared to those infected with gG-positive strains, suggesting that gG-negative BHV-1 inflicted more damage to the infected cells than gG-positive BHV-1. Apoptotic cell death was induced in RK13 cells infected with gG-negative BHV-1 within 8 h. In contrast, the onset of apoptosis in gG-positive BHV-1-infected RK13 cells was around 12-16 h postinfection. In the presence of caspase inhibitor Z-Asp-CH2-DCB, multiplication of gG-negative minus BHV-1 was significantly increased. These results demonstrate that BHV-1 gG is involved in stabilizing the cell structure, postponing apoptotic process, and efficient BHV-1 replication in infected RK13 cells.

Bovine herpesvirus 1 glycoprotein G is required for viral growth by cell-to-cell infection

The bovine herpesvirus 1 (BHV-1) US4 gene encodes glycoprotein G (gG), which is conserved in the majority of alphaherpesviruses. In order to identify the role of BHV-1 gG in the viral infection cycle, a gG minus BHV-1 mutant and its gG-positive revertant were constructed and their growth characteristics in Madin-Darby bovine kidney (MDBK) cells were compared. The gG minus mutant formed smaller plaques than the gG-positive BHV-1 in MDBK cells. When a monolayer culture of MDBK cells was infected with BHV-1 at a low multiplicity of infection and overlaid with semi-solid growth medium, under which adsorption of the mature virion released in the medium was inhibited, gG-positive BHV-1 multiplied, while the growth of the gG negative BHV-1 was severely inhibited. These data suggest that BHV-1 gG functions in direct cell-to-cell transmission mechanism of BHV-1 in tissue culture.

The genome sequence of herpes simplex virus type 2

The genomic DNA sequence of herpes simplex virus type 2 (HSV-2) strain HG52 was determined as 154,746 bp with a G+C content of 70.4%. A total of 74 genes encoding distinct proteins was identified; three of these were each present in two copies, within major repeat elements of the genome. The HSV-2 gene set corresponds closely with that of HSV-1, and the HSV-2 sequence prompted several local revisions to the published HSV-1 sequence (D. J. McGeoch, M. A. Dalrymple, A. J. Davison, A. Dolan, M. C. Frame, D. McNab, L. J. Perry, J. E. Scott, and P. Taylor, J. Gen. Virol. 69:1531-1574, 1988). No compelling evidence for the existence of any additional protein-coding genes in HSV-2 was identified.

Bovine herpesvirus 1 U(s) open reading frame 4 encodes a glycoproteoglycan

Sequence analysis of the short unique (Us) segment of the bovine herpesvirus 1 (BHV-1) genome predicted that the Us open reading frame (ORF) 4 encodes a protein with homology to glycoprotein G (gG) of other alpha-herpesviruses (P. Leung-Tack, J.-C. Audonnet, and M. Riviere, Virology 199:409-421, 1994). RNA analysis showed that the Us ORF4 is contained within two transcripts of 3.5 and 1.8 kb. The 3.5 kb RNA represents a structurally bicistronic RNA which encompasses the Us ORF3 and Us ORF4, whereas the 1.8-kb RNA constitutes the monocistronic Us ORF4 mRNA. To identify the predicted BHV-I gG, recombinant vaccinia virus expressing the Us ORF4 was used to raise specific antibodies in rabbits. The antiserum recognized a 65-kDa polypeptide and a very diffusely migrating species of proteins with an apparent molecular mass of between 90 and greater than 240 kDa in supernatants of BHV-1-infected cells which was also precipitated together with 61- and 70-kDa polypeptides from cell-associated proteins. The specificity of the reaction was demonstrated by the absence of these proteins from the supernatant of cells infected with the Us ORF4 deletion mutant BHV-l/gp1-8. Treatment of the immunoprecipitated proteins with glycosidases and chondroitinase AC showed that the 65-kDa protein constitutes gG, which contains both N- and O-linked carbohydrates, and that the high-molecular-mass proteins contain glycosaminoglycans linked to a 65-kDa glycoprotein that is antigenically related to gG. These molecules were therefore named glycoproteoglycan C (gpgG). Pulse chase experiments indicated that gG and gpgG were processed from a common precursor molecule with an apparent molecular mass of 61 kDa via a 70-kDa intermediate. Both gG and gpgG could not be found associated with purified virions. In summary, our results identify the BHV-I gG protein and demonstrate the presence of a form of posttranslational modification, glycosamino-glycosylation, that has not yet been described for a herpesvirus-encoded protein.

Molecular evolution of infectious laryngotracheitis virus (ILTV; gallid herpesvirus 1): an ancient example of the Alphaherpesviridae?

An analysis of two essential genes of infectious laryngotracheitis virus (ILTV), glycoprotein D (gD) and the immediate early gene, herpes simplex virus homologue ICP27, was performed with the equivalent gene homologues from several alphaherpesviruses. Amino acid (aa) sequence analysis revealed that these ILTV genes shared limited homology to other alphaherpesvirus equivalents and were distinct from the two other avian herpesviruses, Marek's disease virus (MDV) and herpesvirus of turkeys (HVT). Simplex and varicella group viruses are clearly separate from the avian group. The amino acid sequences of these ILTV genes will be presented with comparisons to the homologues from other alphaherpes viruses, contributing further evidence of the evolution of this group of viruses from a common progenitor and that ILTV could be an ancient example of the Alphaherpesvirinae.

Herpesvirus papio 2, an SA8-like alpha-herpesvirus of baboons

Several SA8 isolates obtained from baboons were compared to the prototype SA8 herpesvirus of African green monkeys. SDS-PAGE and restriction enzyme analyses revealed definite differences between green monkey and baboon isolates. DNA and amino acid sequences of the gB, gD and gJ glycoprotein genes exhibited substantial differences in variable regions. For the gB and gD, the amount of amino acid substitutions between SA8 and the baboon viruses was comparable to levels observed between analogous genes of SA8 & B virus or HSV1 & HSV2. Although a high degree of antigenic cross-reactivity was apparent, virus-specific antigenic determinants were also readily detected. Phylogenetic analyses supported separation of the baboon isolates and SA8 as distinct viruses. Taken together these results suggest that although closely related to SA8, the baboon viruses represent a distinct simian alpha-herpesvirus which we propose be designated Herpesvirus papio 2.

Glycoprotein E of pseudorabies virus and homologous proteins in other alphaherpesvirinae

This paper reviews biological properties of glycoprotein E (gE) of pseudorabies virus (Aujeszky's disease virus) and homologous proteins in other alphaherpesvirinae. It focuses on the gene encoding gE, conserved regions in the gE protein and its homologs, the complex of gE and gI, biological functions of gE in vitro and in vivo, the role of gE in latency and the role of gE in the induction of humoral and cellular immune responses. Special emphasis is placed on the use of gE as a marker protein in the control and eradication of pseudorabies virus.