Physical mapping of a genome of equine herpesvirus 2 (equine cytomegalovirus)

Genetic diversity of equine gammaherpesviruses (γ-EHV) and isolation of a syncytium forming EHV-2 strain from a horse in Iceland

The horse population in Iceland is a special breed, isolated from other equines for at least one thousand years. This provides an exceptional opportunity to investigate old and new pathogens in a genetically closed herd. Both types of equine gammaherpesviruses, EHV-2 and EHV-5, are common in Iceland. Genetic variation was examined by sequencing four genes, glycoprotein B (gB), glycoprotein H (gH), DNA polymerase and DNA terminase for 12 Icelandic and seven foreign EHV-2 strains. One Icelandic virus isolate, gEHV-Dv, induced syncytium formation, an uncharacteristic cytopathy for EHV-2 in equine kidney cells. When sequenced, the glycoprotein genes were different from both EHV-2 and EHV-5, but the polymerase and terminase genes had 98-99% identity to EHV-2. Therefore the gEHV-Dv strain can be considered a variant of EHV-2. Substantial genetic variability was seen within the EHV-2 glycoprotein genes but limited in the polymerase and terminase genes. The Icelandic EHV-2 strains do not seem to differ phylogenetically from the foreign viruses, despite isolation for over a thousand years.

Equine herpesvirus 2 (EHV-2) infection in thoroughbred horses in Argentina

Background

Equine herpesvirus 2 is a gamma-herpesvirus that infects horses worldwide. Although EHV-2 has been implicated in immunosuppression in foals, upper respiratory tract disease, conjunctivitis, general malaise and poor performance, its precise role as a pathogen remains uncertain. The purpose of the present study was to analyse the incidence of EHV-2 in an Argentinean horse population and correlate it with age and clinical status of the animals.

Results

A serological study on 153 thoroughbred racing horses confirmed the presence of EHV-2 in the Argentinean equine population. A virus neutralization test showed a total of 79.7 % animals were sero-positive for EHV-2. An increase in antibodies titre with age as well as infection at earlier ages were observed.

EHV-2 was isolated from 2 out of 22 nasal swabs from horses showing respiratory symptoms. The virus grew slowly and showed characteristic cytopathic effect after several blind passages on RK13 cells. The identity of the isolates was confirmed by nested PCR and restriction enzyme assay (REA).

Conclusion

This is the first report on the presence of EHV-2 in Argentina and adds new data to the virus distribution map. Though EHV-2 was isolated from foals showing respiratory symptoms, further studies are needed to unequivocally associate this virus with clinical symptoms.

A single 13-kilobase divergent locus in the Kaposi sarcoma-associated herpesvirus (human herpesvirus 8) genome contains nine open reading frames that are homologous to or related to cellular proteins

Two small fragments of a novel human gammaherpesvirus genome known as Kaposi's sarcoma (KS)-associated herpesvirus or human herpesvirus 8 (HHV-8) have been shown to be present in virtually all AIDS and non-AIDS KS lesions, as well as in body cavity-based lymphomas (BCBL) and in multicentric Castleman's disease. We have extended those studies by identifying and sequencing a third fragment of HHV-8 DNA encoding a viral thymidylate synthetase (TS) gene. Use of this viral TS fragment as a probe led to the identification and mapping of a cluster of overlapping phage lambda clones from a BCBL tumor DNA genomic library that spanned 48 kb on the left-hand side of the HHV-8 genome between the equivalents of open reading frame 6 (ORF6) and ORF31 of herpesvirus saimiri (HVS). DNA sequencing of a 17-kb segment encompassing a gammaherpesvirus divergent locus (DL-B) between ORF11 and ORF17 revealed the presence of nine viral ORFs with predicted gene products related to cellular proteins. These include the complete TS gene and a dihydrofolate reductase (DHFR) gene, four novel cytokine genes (encoding viral interleukin-6, viral MIP-1A, viral MIP-1B, and BCK) that have not previously been found to be encoded by a virus, and a bcl-2 homolog. This region in HHV-8 also contains the T1.1 abundant lytic cycle nuclear RNA gene and encompasses two genes (or exons) encoding proteins with C4HC3 zinc finger domains of the PHD/leukemia-associated protein subtype. The latter are related to the spliced immediate-early IE1 protein of the gamma-2 class herpesvirus bovine herpesvirus type 4 and a similar motif found in HVS ORF12. Although genes for TS and DHFR enzymes are also encoded by HVS (ORF70 and ORF2), both occur at different genomic loci than in HHV-8, and the HHV-8 DHFR protein is much farther diverged from human DHFR than is the HVS version, implying that they were probably acquired as host cell cDNAs by independent evolutionary events. Transcripts from the IE1-A, IE1-B, DHFR, and MIP-1B genes were all detected by Northern blot hybridization analysis in a BCBL cell line at 12 h after induction with butyrate but were not present before induction, indicating that these are all primarily lytic cycle genes. We conclude that the DL-B locus of gammaherpesviruses displays considerably more variability that previously appreciated and that expression of many of these genes is likely to have important implications for HHV-8 biology and therapy.

Molecular characterization and determination of the coding capacity of the genome of equine herpesvirus type 2 between the genome coordinates 0.235 and 0.258 (the EcoRI DNA fragment N; 4.2 kbp)

The complete DNA nucleotide sequence of the EcoRI DNA fragment N (0.235 to 0.258 viral map units) of equine herpes virus type 2 (EHV-2) strain T400/3 was determined. This DNA fragment comprises 4237 bp with a base composition of 55.23% G+C and 44.77% A+T. Nineteen open reading frames (ORFs) of 50-287 amino acid (aa) residues were detected. ORF number 10 is located between the nucleotide position 2220 and 2756 coding for a protein of 179 amino acid residues. This protein shows significant homology to the cytokine synthesis inhibitory factor (CSIF; interleukin 10) of human (76.4%) and mouse (68.5%), and to the Epstein-Barr virus (EBV) protein BCRF1 (70.6%). The existence of an interleukin 10 (IL-10) analogous gene within the genome of the EHV-2 was confirmed by screening the genome of nine EHV-2 strains using specific oligonucleotide primers corresponding to the 5' and 3' region of this particular gene by polymerase chain reaction. In all experiments an 870 bp DNA product was amplified. The specifity of the amplified DNA fragments obtained from individual EHV-2 strains was confirmed by DNA-DNA hybridization experiments. The DNA sequence analysis of the amplified DNA products of the EHV-2 strain LK was carried out. This analysis revealed the identity of the corresponding IL-10 gene (540 bp) of this strain to the IL-10 gene of EHV-2 strain T400/3. The presented data indicate that the EHV-2 genome harbors a viral interleukin 10-like gene. This is further evidence that the IL-10 gene can be present in the genomes of members of the Herpesviridae family.

Structure and heterogeneity of the a sequences of human herpesvirus 6 strain variants U1102 and Z29 and identification of human telomeric repeat sequences at the genomic termini

The unit-length genome of human herpesvirus 6 (HHV-6) consists of a single unique component (U) bounded by direct repeats DRL and DRR and forms head-to-tail concatemers during productive infection. cis-elements which mediate cleavage and packaging of progeny virions (a sequences) are found at the termini of all herpesvirus genomes. In HHV-6, DRL and DRR are identical and a sequences may therefore also occur at the U-DR junctions to give the arrangement aDRLa-U-aDRRa. We have sequenced the genomic termini, the U-DRR junction, and the DRR.DRL junction of HHV-6 strain variants U1102 and Z29. A (GGGTTA)n motif identical to the human telomeric repeat sequence (TRS) was found adjacent to, but did not form, the termini of both strain variants. The DRL terminus and U-DRR junction contained sequences closely related to that of the well-conserved herpesvirus packaging signal Cn-Gn-Nn-Gn (pac-1), followed by tandem arrays of TRSs separated by single copies of a hexanucleotide repeat. HHV-6 strain U1102 contained repeat sequences not found in HHV-6 Z29. In contrast, the DRR terminus of both variants contained a simple tandem array of TRSs and a close homolog of a herpesvirus pac-2 signal (GCn-Tn-GCn). The DRR.DRL junction was formed by simple head-to-tail linkage of the termini, yielding an intact cleavage signal, pac-2.x.pac-1, where x is the putative cleavage site. The left end of DR was the site of intrastrain size heterogeneity which mapped to the putative a sequences. These findings suggest that TRSs form part of the a sequence of HHV-6 and that the arrangement of a sequences in the genome can be represented as aDRLa-U-a-DRRa.

Cross-hybridization of equid herpesvirus-2 (EHV-2) and herpes simplex virus-1 (HSV-1) genes to equid herpesvirus-1 (EHV-1)

In contrast to previous findings, the Ab4 isolate of equid herpesvirus-1 (EHV-1) was shown to share homology with the G9 isolate of equid herpesvirus-2 (EHV-2). Using Southern blotting and stringent hybridization conditions, a significant proportion of this cross-hybridization was identified by the immediate-early gene-3 (IE-3) probe from herpes simplex virus-1 (HSV-1). The HSV-1 UL48 gene probe (encoding the IE gene transactivating protein VmW65, which is also known as alpha-TIF or VP16) was used to identify and isolate its counterpart in EHV-1. The relevance of shared homology to transactivation is being investigated.

The genome of equine herpesvirus type 2 harbors an interleukin 10 (IL10)-like gene

A gene was identified within the DNA sequences of the EcoRI DNA fragment N (4.3 kbp) of the genome of equine herpesvirus type 2 (EHV-2) coding for a protein (179 amino acid residues) homologous to the cytokine synthesis inhibitory factor (CSIF; interleukin 10) of the human and mouse, and to the Epstein-Barr virus (EBV) protein BCRF1. This finding is further significant evidence that the interleukin 10 (IL-10) and/or IL-10-like gene can indeed be present in the genomes of members of the herpesviral family.

Equine herpesvirus 5: comparisons with EHV2 (equine cytomegalovirus), cloning, and mapping of a new equine herpesvirus with a novel genome structure

A new equine herpesvirus, provisionally designated equine herpesvirus 5 (EHV5; Browning and Studdert (1987) J. Gen. Virol. 68, 1441-1447), was examined for the degree of genomic difference from equine herpesvirus 2 (EHV2) by Southern hybridizations. EHV5 and EHV2 whole genomic DNA probes were highly specific for homologous DNA only, indicating that significant genomic difference exists between the two viruses. Restriction endonuclease analysis of EHV5 strain 2-141 (EHV5.2-141) revealed that the genome is 179 kb and exists as a single isomer. Clones representing 82% of the genome were obtained and used to construct restriction maps for four restriction endonucleases. Hybridization experiments indicated that the EHV5.2-141 genome does not contain large terminal or internal repeats, although some evidence for very short repeated sequences in the genomic termini was obtained. Such a genome structure makes EHV5 unique among the equine herpesviruses but similar to the mouse, rat, and guinea pig cytomegaloviruses and the tupaiid herpesvirus. Sequence analysis of one of the genomic termini of EHV5.2-141 revealed the presence of a 30-bp sequence (pac-1; Deiss et al. (1986) J. Virol. 59, 605-618) which is highly conserved among herpesviruses.

[Herpesviridae: classification and structure in 1991]

In 1981, herpesviruses were classified by the International Committee of Taxonomy of Viruses (ICTV, 1) inside the herpesviridae family. Progress in biotechnology and molecular biology during the last 10 yr, has permitted the characterization of new viruses and genomic structures. The objective of this paper is to collect the data found in the literature since 1981, to actualize the description of herpesviridae family.

Gallid herpesvirus 1 (infectious laryngotracheitis virus): cloning and physical maps of the SA-2 strain

Clones representing 90% of the genome of Gallid herpesvirus 1 (infectious laryngotracheitis virus; ILTV) were obtained and used in hybridization experiments to construct EcoRI, KpnI amd SmaI physical maps. The genome was 155 kilobase pairs (kbp) and comprised of a long unique sequence (120 kbp) and a short unique sequence (17 kbp) bounded by repeat sequences each of 9 kbp. An unrelated second pair of repeat sequences was located at 0.67 and 0.88 map untis. A terminal repeat of the unique long region (UL) was also detected, but no isomerization of UL was detected.

Properties of the human herpesvirus 6 strain Z29 genome: G + C content, length, and presence of variable-length directly repeated terminal sequence elements

We have studied the structure of the human herpesvirus 6 (HHV-6) genome. The density of genomic DNA is approximately 1.702 g/cm3 as determined by isopycnic density gradient centrifugation, from which a mean G + C content of 43% was calculated. The genomic termini were examined by exonuclease digestion and DNA/DNA hybridization; relative molarities of restriction fragments were determined by quantitative densitometry. The results indicate that the HHV-6(Z29) genome has two unique termini and consists of a long unique segment bounded by a directly repeated sequence element found in one copy at each end of the genome. We estimated the length of the genome by pulsed-field gel electrophoresis and by summation of restriction endonuclease fragment lengths. We observed two forms of HHV-6(Z29) DNA of approximately 162 and 168 kb in length. The length heterogeneity was localized within the terminal repeat element, each copy of which is approximately 10.1 kb in length in the shorter form of the genome and 13.2 kb in length in the longer form of the genome.

The diversity and unity of Herpesviridae

The family herpesviridae contains over 100 viruses endogenous to humans and to a wide variety of eukaryotic organisms. Inclusion in the family is based on architecture of the virion. The viruses differ significantly with respect to base composition and sequence arrangements of their DNAs, but share many biologic properties including the ability to remain latent in their hosts. On the basis of their biologic properties the herpesviruses have been classified into three subfamilies, i.e. alphaherpesvirinae, betaherpesvirinae and gammaherpesvirinae. The members of each subfamily share many properties including greater conservation and colinear arrangements of their genes. As a rule, more than one herpesvirus has been isolated from animals of economic importance and both humans have yielded viruses belong to all three subfamilies of the herpesviridae.

Animal cytomegaloviruses

Cytomegaloviruses are agents that infect a variety of animals. Human cytomegalovirus is associated with infections that may be inapparent or may result in severe body malformation. More recently, human cytomegalovirus infections have been recognized as causing severe complications in immunosuppressed individuals. In other animals, cytomegaloviruses are often associated with infections having relatively mild sequelae. Many of these sequelae parallel symptoms associated with human cytomegalovirus infections. Recent advances in biotechnology have permitted the study of many of the animal cytomegaloviruses in vitro. Consequently, animal cytomegaloviruses can be used as model systems for studying the pathogenesis, immunobiology, and molecular biology of cytomegalovirus-host and cytomegalovirus-cell interactions.

Physical mapping of the genomic heterogeneity of isolates of equine herpesvirus 2 (equine cytomegalovirus)

The BamHI, EcoRI, and HindIII physical maps of the genomes of 14 isolates of equine herpesvirus 2 (EHV 2) were determined by Southern blot analysis using DNA fragments of a previously mapped EHV 2 strain 86/67. No two isolates had identical maps for all 3 enzymes, the number of differing cleavage sites between pairs of isolates varying from 3 to 21. Overall 75 cleavage sites were mapped, of which 40 were variable. Cleavage sites occurred throughout the genome, including within the terminal repeat regions. Additionally, fragment length polymorphisms, independent of cleavage site loss or gain, were mapped to 5 regions of the genome, 4 of which occurred within the terminal repeat regions.