Characterization of the bovine herpesvirus 4 major immediate-early transcript.

The major immediate-early (IE) RNA of bovine herpesvirus 4 (BHV-4) has been identified and characterized by analyzing cytoplasmic polyadenylated RNA isolated from Madin-Darby bovine kidney cells infected with BHV-4(DN-599) in the presence of cycloheximide. Hybridization of cDNA to Southern blots of viral DNA, Northern (RNA) blot analysis, and S1 nuclease analyses showed that the major BHV-4 IE RNA is a spliced, 1.7-kb RNA, which is transcribed from right to left on the restriction map of the BHV-4 genome from DNA contained in the 8.3-kb HindIII fragment E. The major IE RNA contains three small exons at its 5' end, spliced to a 1.3-kb 3' exon. This RNA is present in much-reduced amounts when cells are infected in the absence of cycloheximide. However, late in infection, the major IE RNA gene region encodes abundant RNAs which differ in structure from the major IE RNA. Nucleotide sequence analysis of the gene encoding the major IE RNA revealed an open reading frame encoding 284 amino acids. A homology search of amino acid sequence data bases showed that a 141-amino-acid region near the amino terminus of the predicted amino acid sequence is similar to sequences near the amino terminus of herpes simplex virus type 1 IE110. This region of homology includes CXXC pairs, which could be involved in zinc finger structures. The region encoding this putative zinc finger domain is also found in RNAs transcribed from this IE region late in infection, but it is spliced to different sequences than those used in IE RNA. Thus, the major IE region of the BHV-4 genome could encode a family of proteins sharing a zinc finger domain.     

Complete sequence and genomic analysis of murine gammaherpesvirus 68.

Murine gammaherpesvirus 68 (gammaHV68) infects mice, thus providing a tractable small-animal model for analysis of the acute and chronic pathogenesis of gammaherpesviruses. To facilitate molecular analysis of gammaHV68 pathogenesis, we have sequenced the gammaHV68 genome. The genome contains 118,237 bp of unique sequence flanked by multiple copies of a 1,213-bp terminal repeat. The GC content of the unique portion of the genome is 46%, while the GC content of the terminal repeat is 78%. The unique portion of the genome is estimated to encode at least 80 genes and is largely colinear with the genomes of Kaposi's sarcoma herpesvirus (KSHV; also known as human herpesvirus 8), herpesvirus saimiri (HVS), and Epstein-Barr virus (EBV). We detected 63 open reading frames (ORFs) homologous to HVS and KSHV ORFs and used the HVS/KSHV numbering system to designate these ORFs. gammaHV68 shares with HVS and KSHV ORFs homologous to a complement regulatory protein (ORF 4), a D-type cyclin (ORF 72), and a G-protein-coupled receptor with close homology to the interleukin-8 receptor (ORF 74). One ORF (K3) was identified in gammaHV68 as homologous to both ORFs K3 and K5 of KSHV and contains a domain found in a bovine herpesvirus 4 major immediate-early protein. We also detected 16 methionine-initiated ORFs predicted to encode proteins at least 100 amino acids in length that are unique to gammaHV68 (ORFs M1 to 14). ORF M1 has striking homology to poxvirus serpins, while ORF M11 encodes a potential homolog of Bcl-2-like molecules encoded by other gammaherpesviruses (gene 16 of HVS and KSHV and the BHRF1 gene of EBV). In addition, clustered at the left end of the unique region are eight sequences with significant homology to bacterial tRNAs. The unique region of the genome contains two internal repeats: a 40-bp repeat located between bp 26778 and 28191 in the genome and a 100-bp repeat located between bp 98981 and 101170. Analysis of the gammaHV68, HVS, EBV, and KSHV genomes demonstrated that each of these viruses have large colinear gene blocks interspersed by regions containing virus-specific ORFs. Interestingly, genes associated with EBV cell tropism, latency, and transformation are all contained within these regions encoding virus-specific genes. This finding suggests that pathogenesis-associated genes of gammaherpesviruses, including gammaHV68, may be contained in similarly positioned genome regions. The availability of the gammaHV68 genomic sequence will facilitate analysis of critical issues in gammaherpesvirus biology via integration of molecular and pathogenetic studies in a small-animal model.     

Identification and characterization of the bovine herpesvirus 1 UL7 gene and gene product which are not essential for virus replication in cell culture.

The UL7 gene of bovine herpesvirus 1 (BHV-1) strain Schönböken was found at a position and in a context predicted from the gene order in the prototype alphaherpesvirus herpes simplex virus type 1. The gene and flanking regions were sequenced, the UL7 RNA and protein were characterized, and 98.3% of the UL7 open reading frame was deleted from the viral genome without destroying productive virus replication. Concomitant deletion of nine 3' codons from the BHV-1 UL6 ORF and 77 amino acids from the carboxy terminus of the predicted BHV-1 UL8 protein demonstrated that these domains are also not essential for function of the respective proteins. The UL7 open reading frame encodes a protein of 300 amino acids with a calculated molecular mass of 32 kDa. Comparison with UL7 homologs of other alphaherpesviruses revealed a high degree of homology, the most prominent being to the predicted UL7 polypeptide of varicella-zoster virus, with 43.3% identical amino acids. A monospecific anti-UL7 serum identified the 33-kDa (apparent-molecular-mass) UL7 polypeptide which is translated from an early-expressed 1.7-kb RNA. The UL7 protein was localized in the cytoplasm of infected cells and could not be detected in purified virions. In summary, we describe the first identification of an alphaherpesviral UL7-encoded polypeptide and demonstrate that the UL7 protein is not essential for replication of BHV-1 in cell culture.     

Identification of the R1 oncogene and its protein product from the rhadinovirus of rhesus monkeys

Rhesus monkey rhadinovirus (RRV) is a gamma-2 herpesvirus that is most closely related to the human Kaposi's sarcoma-associated herpesvirus (KSHV). We have identified a distinct open reading frame at the left end of RRV and designated it R1. The position of the R1 gene is equivalent to that of the saimiri transforming protein (STP) of herpesvirus saimiri (HVS) and of K1 of KSHV, other members of the gamma-2 or rhadinovirus subgroup of herpesviruses. The R1 sequence revealed an open reading frame encoding a product of 423 amino acids that was predicted to contain an extracellular domain, a transmembrane domain, and a C-terminal cytoplasmic tail reflective of a type I membrane-bound protein. The predicted structural motifs of R1, including the presence of immunoreceptor tyrosine-based activation motifs, resembled those in K1 of KSHV but were distinct from those of STP. R1 sequences from four independent isolates from three different macaque species revealed 0.95 to 7.3% divergence over the 423 amino acids. Variation was located predominantly within the predicted extracellular domain. The R1 protein migrated at 70 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and was extensively glycosylated. Tagged R1 protein was localized to the cytoplasmic and plasma membranes of transfected cells. Expression of the R1 gene in Rat-1 fibroblasts induced morphologic changes and focus formation, and injection of R1-expressing cells into nude mice induced the formation of multifocal tumors. A recombinant herpesvirus in which the STP oncogene of HVS was replaced by R1 immortalized T lymphocytes to interleukin-2-independent growth. These results indicate that R1 is an oncogene of RRV.     

Kaposi's sarcoma-associated herpesvirus encodes a functional cyclin.

Kaposi's sarcoma-associated herpesvirus (KSHV) (also called human herpesvirus 8) is consistently found in Kaposi's sarcoma lesions and in body-cavity-based lymphomas. A 17-kb KSHV lambda clone was obtained directly from a Kaposi's sarcoma lesion. DNA sequence analysis of this clone identified an open reading frame which has 32% amino acid identity and 53% similarity to the virus-encoded cyclin (v-cyclin) of herpesvirus saimiri (HVS) and 31% identity and 53% similarity to human cellular cyclin D2. This KSHV open reading frame was shown to encode a 29- to 30-kDa protein with the properties of a v-cyclin. KSHV v-cyclin protein was found to associate predominantly with cdk6, a cellular cyclin-dependent kinase known to interact with cellular type D cyclins and HVS v-cyclin. The KSHV v-cyclin was also found to associate weakly with cdk4. KSHV v-cyclin-cdk6 complexes strongly phosphorylated glutathione S-transferase-Rb fusion protein and histone H1 as substrates in vitro. Thus, KSHV v-cyclin resembles the v-cyclin of the T-lymphocyte-transforming HVS in its specificity for association with cdk6 and in its ability to strongly activate cdk6 protein kinase activity.     

Molecular cloning, sequencing, and expression of functional bovine herpesvirus 1 glycoprotein gIV in transfected bovine cells.

The gene encoding bovine herpesvirus 1 (BHV-1) glycoprotein gIV was mapped, cloned, and sequenced. The gene is situated between map units 0.892 and 0.902 and encodes a predicted protein of 417 amino acids with a signal sequence cleavage site between amino acids 18 and 19. Comparison of the BHV-1 amino acid sequence with the homologous glycoproteins of other alphaherpesviruses, including herpes simplex virus type 1 glycoprotein gD, revealed significant homology in the amino-terminal half of the molecules, including six invariant cysteine residues. The identity of the open reading frame was verified by expression of the authentic recombinant BHV-1 gIV in bovine cells by using eucaryotic expression vectors pRSDneo (strong, constitutive promoter) and pMSG (weak, dexamethasone-inducible promoter). Constitutive expression of gIV proved toxic to cells, since stable cell lines could only be established when the gIV gene was placed under the control of an inducible promoter. Expression of gIV was cell associated and localized predominantly in the perinuclear region, although nuclear and plasma membrane staining was also observed. Radioimmunoprecipitation revealed that the recombinant glycoprotein was efficiently processed and had a molecular weight similar to that of the native form of gIV expressed in BHV-1-infected bovine cells. Recombinant gIV produced in the transfected bovine cells induced cell fusion, polykaryon formation, and nuclear fusion. In addition, expression of gIV interfered with BHV-1 replication in the transfected bovine cells.     

Transactivation of a human cytomegalovirus early promoter by gene products from the immediate-early gene IE2 and augmentation by IE1: mutational analysis of the viral proteins.

Expression from a human cytomegalovirus early promoter (E1.7) has been shown to be activated in trans by the IE2 gene products (C.-P. Chang, C. L. Malone, and M. F. Stinski, J. Virol. 63:281-290, 1989). Using wild-type and mutant viral proteins, we have defined the protein regions required for transactivation of the E1.7 promoter in IE2 and for augmentation of transactivation in the IE1 protein. Two regions of the IE2 proteins were found to be essential for transactivation. One near the amino terminus is within 52 amino acids encoded by exon 3. The second comprises the carboxyl-terminal 85 amino acids encoded by exon 5. The IE2 protein encoded by an mRNA which lacks the intron within exon 5 and the IE2 protein encoded by exon 5 had no activity for transactivation of the E1.7 promoter. Although the IE1 gene product alone had no effect on this early viral promoter, maximal early promoter activity was detected when both IE1 and IE2 gene products were present. The IE1 protein positively regulated its enhancer-containing promoter-regulatory region. The IE1 protein alone increased the steady-state level of IE2 mRNA; therefore, IE1 and IE2 are synergistic for expression from the E1.7 promoter. Like the IE2 proteins, the IE1 protein requires for activity 52 amino acids encoded by exon 3. IE1 also requires amino acids encoded by exon 4. Since the IE1 and IE2 proteins have 85 amino acids in common at the amino-terminal end encoded by exons 2 and 3, the difference between these specific transactivators resides in their carboxyl-terminal amino acids encoded by exons 4 and 5, respectively.