Martin Schwyzer

Infectious bovine rhinotracheitis/vulvovaginitis (BHV1)

The present review relies upon articles published previously (1–10). Basing upon this it was the authors’ intention to consider above all additional newer literature.

Molecular virology of ruminant herpesviruses.

Molecular virology has served to establish bovine herpesvirus 1 (BHV-1) as the prototype member of ruminant herpesviruses. Based on the genomic sequence of the virus, we aim to identify and characterize virus-specified components, to explain their concerted action, and to predict how the chain of events during the lytic and latent phases of the viral life cycle may be interrupted. The nucleotide sequence of the BHV-1 genome (136 kb) has just been completed by international cooperation (July 1995; except for a small gap in UL36). It comprises 67 unique genes and 2 genes, both duplicated, in the inverted repeats. In general, these genes exhibit strong homology at the amino acid sequence level to those of other alphaherpesviruses (HSV-1, VZV, EHV-1) and are arranged in similar order. A few genes are peculiar to only one or two herpesviruses, e.g. in BHV-1 the circ, UL0.5, UL3.5 and US1.5 genes. Not long ago, the repertoire of BHV-1 proteins under study was restricted to the three major glycoproteins (gB, gC, and gD) and thymidine kinase. The repertoire is now growing rapidly and includes 7 additional glycoproteins (gE, gI, gH, gL, gG, gK and gM), a number of enzymes (e.g. ribonucleotide reductase, DNA Polymerase, dUTPase), and a group of regulatory proteins (BICPO, 4, 22, and 27, alpha TIF). Investigations into the functions of these proteins and comparison with their counterparts in other herpesviruses should reveal which are useful targets for diagnosis, prevention or antiviral treatment. Recombinant viruses containing deletions or replacements of individual genes are being created, aiming at vaccine development and insights into pathogenesis, notably latency, neurotropism, and interference with host functions. Molecular analysis of other ruminant herpesviruses is much less advanced. Over a dozen virus species have been described; most share basic properties with BHV-1 and may be classified as alphaherpesviruses. The gammaherpesviruses are represented by the proposed agent of malignant catarrhal fever, alcelaphine herpesvirus 1, and by bovine herpesvirus 4, whose partial sequences exhibit similarity to herpesvirus saimiri.

BICP22 of bovine herpesvirus 1 is encoded by a spliced 1.7 kb RNA which exhibits immediate early and late transcription kinetics

Kinetic analysis of the two divergent immediate early (IE) transcription units of bovine herpesvirus 1 (BHV-1) revealed an unexpected behaviour. The IE1.7 promoter was not turned off at the end of the IE period but acted as a late promoter, unlike the adjacent IE4.2/2.9 promoter which was active only under IE conditions. The genome region specifying the IE1.7 gene was sequenced (0.814 to 0.839 map units). The IE1.7 promoter was found to overlap with duplicated sequence elements bearing close similarity to herpesvirus origins of replication, which may explain the biphasic transcription kinetics. Exons 1 and 2 of the spliced IE1.7 transcript were non-coding. Exon 3 was found to contain a single open reading frame encoding a protein of 300 amino acids that was designated BICP22 because of its homology to ICP22 (Vmw68) of herpes simplex virus type 1 and related proteins from other herpesviruses. The protein probably represents IEP-55, the most abundant BHV-1 phosphoprotein observed under IE conditions.

Immediate-early protein BICP22 of bovine herpesvirus 1 trans-represses viral promoters of different kinetic classes and is itself regulated by BICP0 at transcriptional and posttranscriptional levels

SummaryBovine herpesvirus 1 (BHV-1) encodes four immediate-early (IE) proteins. The transactivators BICP0 and BICP4 are key regulatory elements in viral replication, and circ is a myristylated virion component, whereas BICP22 – originating from a spliced 1.7-kb transcript synthesized with dual IE and late kinetics – has not yet been characterized as a protein. In this study, Western blot and immunofluorescence analysis using antisera against a C-terminal oligopeptide revealed major 50-kDa and minor 35-kDa species of BICP22, predominantly located in the nuclei of BHV-1 infected cells. In transient expression assays, BICP22 acted as transrepressor protein on viral promoters of different kinetic classes, e.g. the IE promoter of the BICP4/BICP0 gene, early promoter of the BICP0 gene, and late promoter of the gC gene. The BICP22 gene promoter itself was not repressed by BICP22; it could be dissected into a proximal region stimulated by BICP0 and a distal region stimulated by BHV-1 alpha-transinducing factor. Replacement of the BICP22 promoter by cytomegalovirus IE promoter revealed an additional posttranscriptional level of regulation whereby more BICP22 accumulated in cells when functional BICP0 was present. Interplay of BICP22 and BICP0 might involve the recently described nuclear domains (ND10) and ubiquitin-dependent pathway.

Nucleotide sequence of the pseudorabies virus immediate early gene, encoding a strong transactivator protein

We report the complete DNA sequence of the pseudorabies virus (PRV) immediate early (IE) gene and its flanking nucleotide sequences, together comprising 5091 base pairs. An open reading frame starts with an ATG codon in position 263 from the transcription-initiation site and ends with a TGA codon in position 4601, thus encoding a predicted protein of 1446 amino acids (150 kD). The PRV IE protein exhibits significant homology with the functionally related transactivator proteins, ICP4 of herpes simplex virus-1 (HSV-1) and p140 of varicella zoster virus (VZV). The extent of homology varies widely along the three sequences: Two regions of the PRV IE protein extending from amino acids 482 to 659 and 959 to 1350 exhibit 50% to 60% identity with the cognate sequences, whereas the remaining sequence reveals little homology apart from a common polyserine stretch. The base composition of the PRV IE coding region is 80% G+C, compared with 81.5% for HSV-1 and 64.1% for VZV. Yet the PRV IE protein appears to be as closely related to VZV p140 as to HSV-1 ICP4. The regions of strong homology are also apparent in plots predicting secondary structure.

Gene contents in a 31-kb segment at the left genome end of bovine herpesvirus-1

We report the nucleotide sequence of a 31-kb segment at the left genome end of bovine herpesvirus-1 (BHV-1) and show that it comprises 19 different open reading frames (ORFs), including seven which have been described previously (circ, dUTPase, UL49.5, alpha TIF, VP8, glycoprotein C, and ribonucleotide reductase small subunit). The new sequence resulted in a correction at the C-terminus of glycoprotein C. All 19 ORFs exhibited strong amino acid sequence homology to the gene products of other alphaherpesviruses. The BHV-1 ORFs were arranged colinearly with the prototype sequence of herpes simplex virus 1 (HSV-1) in the range of the UL54 to UL37 genes. No BHV-1 homologs of the HSV-1 UL56, UL55, and UL45 genes were identified. The BHV-1 circ gene was the only gene without a HSV-1 counterpart. The additional ORFs 1 and 2 found at the left genome end of equine herpesvirus-1 (EHV-1) were absent in BHV-1. Among the newly sequenced BHV-1 ORFs are homologs of ICP27 (UL54), glycoprotein K (UL53), helicase-primase (UL52), DNA polymerase accessory protein (UL42), ribonucleotide reductase large subunit (UL39), and several virion proteins (UL49, UL46, UL43, UL41, UL38, UL37), most of which are strongly conserved in all herpesviruses. The possible functions of the proteins encoded within the sequenced region are assessed and features found are discussed.

Sequence analysis of the bovine herpesvirus type 1 genes homologous to the DNA polymerase (UL30), the major DNA-binding protein (UL29) and ICP18.5 assembly protein (UL28) genes of herpes simplex virus

SummaryThe nucleotide sequence of a 10.5 kb region (map position 0.332 to 0.410) of bovine herpesvirus type 1 (BHV-1) was determined. This region contained three open reading frames (ORFs) homologous to herpes simplex virus DNA polymerase catalytic subunit (DNApol, UL30), major DNA-binding protein (MDBP, UL29) and ICP18.5 assembly protein (ICP18.5, UL28). The BHV-1 DNApol, MDBP and ICP18.5 ORFs were 1 246, 1 203 and 826 amino acids long with a calculated molecular mass of 134.2 kDa, 124.4 kDa and 86.9 kDa, respectively. They showed a high homology with alphaherpesvirus homologs despite large differences in the G+C content of the UL30-UL28 segment ranging from 44.4% for varicella zoster virus to 71.5% for BHV-1. Particularly well conserved among Alphaherpesvirinae are the putative functional domains of the DNApol and MDBP proteins which are discussed. Phylogenetic analysis revealed that BHV-1 clustered in the Varicellovirus genus with the animal D-type viruses. In this group, the BHV-1 position was shown to vary according to the investigated genes. Indeed, pseudorabies virus clustered with BHV-1 in the DNApol tree but with equine herpesvirus 1 in the ICP18.5 tree.

Update and comparison of the immediate-early gene DNA sequences of two pseudorabies virus isolates.

Differences between the immediate-early gene DNA sequences of two pseudorabies virus isolates (Indiana-Funkhauser and Ka) were resolved and confirmed. The deduced amino acid sequences showed that regions 2 and 4 have fewer changes than the rest of the molecules. These two conserved regions may be functionally important.

Transduction of Vero cells and bovine monocytes with a herpes simplex virus-1 based amplicon carrying the gene for the bovine herpesvirus-1 Circ protein.

Herpes simplex virus-1 (HSV-1) based amplicon vectors are promising gene delivery vehicles because they have a large transgene capacity and can efficiently transduce many different cell types, including non-dividing cells, of various animal species. The Circ protein of bovine herpesvirus-1 (BHV-1) is a myristylated virion component of unknown function. Preliminary experiments with a circ gene deletion mutant indicated that Circ may influence the hosts immune response by downregulating MHC-II expression in bovine monocytes. To get more insight into the function of Circ, amplicon vectors were constructed with various open reading frames (ORFs) under the control of the HSV-1 IE4/5 promoter: (i) the Circ ORF alone, (ii) a fusion ORF encoding an N-terminal Circ fused to the enhanced green fluorescent protein (eGFP), (iii) the eGFP ORF alone, and (iv) the Circ ORF in the inverted orientation. Upon helpervirus-free packaging into HSV-1 amplicon particles and transduction of Vero cells, both Circ alone and the Circ-eGFP fusion protein produced a punctate pattern within the cytoplasm, suggesting membrane association of the myristylated protein. In contrast, eGFP alone was evenly distributed over the cytoplasm of transduced cells. Upon infection of bovine buffy-coat cells, it was observed that cells of the monocyte lineage but not lymphocytes were transduced. Transgene expression reached a peak around 20h after transduction and lasted for at least 90h. Transduced monocytes underwent specific morphological changes, which may be attributed to Circ synthesis.

Transactivator protein BICP0 of bovine herpesvirus 1 (BHV-1) is blocked by prostaglandin D2 (PGD2), which points to a mechanism for PGD2-mediated inhibition of BHV-1 replication.

ABSTRACT The immediate-early protein, BICP0, of bovine herpesvirus 1 (BHV-1) transactivates a variety of viral and cellular genes. In a yeast two-hybrid cDNA library screening, we found that lipocalin-type prostaglandin D synthase, which catalyzes the production of prostaglandin D2 (PGD2), is a cellular target of BICP0. We observed that, during wild-type BHV-1 infection, PGD2 levels were increased intracellularly and decreased in the medium. These effects were absent upon infection with recombinant BHV-1 expressing β-galactosidase instead of BICP0 (A2G2). Transient-expression assays showed that BICP0 alone caused a significant increase in PGD2 levels in the cell. PGD2 repressed BHV-1 replication in cultured cells. Antiviral activities of prostaglandins have been documented long ago, but their mode of action remains to be clarified. Here we provide evidence that PGD2 impairs the transactivation ability of BICP0 that is necessary for efficient virus replication.