Origin-independent assembly of Kaposi's sarcoma-associated herpesvirus DNA replication compartments in transient cotransfection assays and association with the ORF-K8 protein and cellular PML.

Six predicted Kaposi's sarcoma virus herpesvirus (KSHV) proteins have homology with other well-characterized herpesvirus core DNA replication proteins and are expected to be essential for viral DNA synthesis. Intact Flag-tagged protein products from all six were produced from genomic expression vectors, although the ORF40/41 transcript encoding a primase-helicase component proved to be spliced with a 127-bp intron. The intracellular localization of these six KSHV replication proteins and the mechanism of their nuclear translocation were investigated. SSB (single-stranded DNA binding protein, ORF6) and PPF (polymerase processivity factor, ORF59) were found to be intrinsic nuclear proteins, whereas POL (polymerase, ORF9), which localized in the cytoplasm on its own, was translocated to the nucleus when cotransfected with PPF. PAF (primase-associated factor, ORF40/41), a component of the primase-helicase tripartite subcomplex together with PRI (primase, ORF56) and HEL (helicase, ORF44), required the presence of all five other replication proteins for efficient nuclear translocation. Surprisingly, even in the absence of a lytic cycle replication origin (ori-Lyt) and any known initiator or origin binding protein, the protein products of all six KSHV core replication genes cooperated in a transient cotransfection assay to form large globular shaped pseudo-replication compartments (pseudo-RC), which excluded cellular DNA. These pseudo-RC structures were confirmed to include POL, SSB, PRI, and PAF but did not contain any newly synthesized DNA. Similar to the human cytomegalovirus system, the peripheries of these KSHV pre-RC were also found to be surrounded by punctate PML oncogenic domains (PODs). Furthermore, by transient cotransfection, the six KSHV core replication machinery proteins successfully replicated a plasmid containing EBV ori-Lyt in the presence of the Epstein-Barr virus-encoded DNA binding initiator protein, ZTA. The KSHV-encoded K8 (ORF-K8) protein, which is a distant evolutionary homologue to ZTA, was incorporated into pseudo-RC structures formed by transient cotransfection with the six core KSHV replication genes. However, unlike ZTA, K8 displayed a punctate nuclear pattern both in transfected cells and at early stages of lytic infection and colocalized with the cellular PML proteins in PODs. Finally, K8 was also found to accumulate in functional viral RC, detected by incorporation of pulse-labeled bromodeoxyuridine into newly synthesized DNA in both tetradecanoyl phorbol acetate-induced JSC-1 primary effusion lymphoblasts and in KSHV lytically infected endothelial cells.

Comparison of genetic variability at multiple loci across the genomes of the major subtypes of Kaposi's sarcoma-associated herpesvirus reveals evidence for recombination and for two distinct types of open reading frame K15 alleles at the right-hand end.

Kaposi's sarcoma (KS)-associated herpesvirus or human herpesvirus 8 (HHV8) DNA is found consistently in nearly all classical, endemic, transplant, and AIDS-associated KS lesions, as well as in several AIDS-associated lymphomas. We have previously sequenced the genes for the highly variable open reading frame K1 (ORF-K1) protein from more than 60 different HHV8 samples and demonstrated that they display up to 30% amino acid variability and cluster into four very distinct evolutionary subgroups (the A, B, C, and D subtypes) that correlate with the major migrationary diasporas of modern humans. Here we have extended this type of analysis to six other loci across the HHV8 genome to further evaluate overall genotype patterns and the potential for chimeric genomes. Comparison of the relatively conserved ORF26, T0.7/K12, and ORF75 gene regions at map positions 0. 35, 0.85, and 0.96 revealed typical ORF-K1-linked subtype patterns, except that between 20 and 30% of the genomes analyzed proved to be either intertypic or intratypic mosaics. In addition, a 2,500-bp region found at the extreme right-hand side of the unique segment in 45 HHV8 genomes proved to be highly diverged from the 3,500-bp sequence found at this position in the other 18 HHV8 genomes examined. Furthermore, these previously uncharacterized "orphan" region sequences proved to encompass multiexon latent-state mRNAs encoding two highly diverged alleles of the novel ORF-K15 protein. The predominant (P) and minor (M) forms of HHV8 ORF-K15 are structurally related integral membrane proteins that have only 33% overall amino acid identity to one another but retain conserved likely tyrosine kinase signaling motifs and may be distant evolutionary relatives of the LMP2 latency protein of Epstein-Barr virus. The M allele of ORF-K15 is also physically linked to a distinctive M subtype of the adjacent ORF75 gene locus, and in some cases, this linkage extends as far back as the T0.7 locus also. Overall, the results suggest that an original recombination event with a related primate virus from an unknown source introduced exogenous right-hand side ORF-K15(M) sequences into an ancient M form of HHV8, followed by eventual acquisition into the subtype C lineage of the modern P-form of the HHV8 genome and subsequent additional, more recent transfers by homologous recombination events into several subtype A and B lineages as well.

High-level variability in the ORF-K1 membrane protein gene at the left end of the Kaposi's sarcoma-associated herpesvirus genome defines four major virus subtypes and multiple variants or clades in different human populations.

Infection with Kaposi's sarcoma (KS)-associated herpesvirus (KSHV) or human herpesvirus 8 (HHV8) is common in certain parts of Africa, the Middle East, and the Mediterranean, but is rare elsewhere, except in AIDS patients. Nevertheless, HHV8 DNA is found consistently in nearly all classical, endemic, transplant and AIDS-associated KS lesions as well as in some rare AIDS-associated lymphomas. The concept that HHV8 genomes fall into several distinct subgroups has been confirmed and refined by PCR DNA sequence analysis of the ORF-K1 gene encoding a highly variable glycoprotein related to the immunoglobulin receptor family that maps at the extreme left-hand end of the HHV-8 genome. Among more than 60 different tumor samples from the United States, central Africa, Saudi Arabia, Taiwan, and New Zealand, amino acid substitutions were found at a total of 62% of the 289 amino acid positions. These variations defined four major subtypes and 13 distinct variants or clades similar to those found for the HIV ENV protein. The B and D subtype ORF-K1 proteins differ from the A and C subtypes by 30 and 24%, respectively, whereas A and C differ from each other by 15%. In all cases tested, multiple samples from the same patient were identical. Examples of the B subtype were found almost exclusively in KS patients from Africa or of African heritage, whereas the rare D subtypes were found only in KS patients of Pacific Island heritage. In contrast, C subtypes were found predominantly in classic KS and in iatrogenic and AIDS KS in the Middle East and Asia, whereas U.S. AIDS KS samples were primarily A1, A4, and C3 variants. We conclude that this unusually high diversity, in which 85% of the nucleotide changes lead to amino acid changes, reflects some unknown powerful biological selection process that has been acting preferentially on this early lytic cycle membrane signalling protein. Two distinct levels of ORF-K1 variability are recognizable. Subtype-specific variability indicative of long-term evolutionary divergence is both spread throughout the protein as well as concentrated within two 40-amino-acid extracellular domain variable regions (VR1 and VR2), whereas intratypic variability localizes predominantly within a single 25-amino-acid hypervariable Cys bridge loop and apparently represents much more recent changes that have occurred even within specific clades. In contrast, numerous extracellular domain glycosylation sites and Cys bridge residues as well as the ITAM motif in the cytoplasmic domain are fully conserved. Overall, we suggest that rather than being a newly acquired human pathogen, HHV8 is an ancient human virus that is preferentially transmitted in a familial fashion and is difficult to transmit horizontally in the absence of immunosuppression. The division into the four major HHV8 subgroups is probably the result of isolation and founder effects associated with the history of migration of modern human populations out of Africa over the past 35,000 to 60,000 years.

Novel endotheliotropic herpesviruses fatal for Asian and African elephants.

A highly fatal hemorrhagic disease has been identified in 10 young Asian and African elephants at North American zoos. In the affected animals there was ultrastructural evidence for herpesvirus-like particles in endothelial cells of the heart, liver, and tongue. Consensus primer polymerase chain reaction combined with sequencing yielded molecular evidence that confirmed the presence of two novel but related herpesviruses associated with the disease, one in Asian elephants and another in African elephants. Otherwise healthy African elephants with external herpetic lesions yielded herpesvirus sequences identical to that found in Asian elephants with endothelial disease. This finding suggests that the Asian elephant deaths were caused by cross-species infection with a herpesvirus that is naturally latent in, but normally not lethal to, African elephants. A reciprocal relationship may exist for the African elephant disease.

Novel organizational features, captured cellular genes, and strain variability within the genome of KSHV/HHV8.

Strong serologic and molecular probe correlations indicate that the newly discovered gamma herpesvirus KSHV or HHV8 is the likely etiologic agent of all forms of Kaposi's sarcoma as well as BCBL/PEL and MCD in patients with acquired immunodeficiency syndrome (AIDS). Two large segments of HHV8 DNA from an AIDS-associated BCBL tumor covering genomic positions 0-52 kilobase [kb] and 108-140 kb have been cloned, mapped, and partially sequenced. Our studies have focused on novel viral proteins encoded within a 13-kb divergent locus (DL-B) by nine captured homologues of cellular genes, including vIL-6, vDHFR, vTS, vBcl-2, three C-C beta chemokines (vMIP-1A, vMIP-1B, and vBCK), and two LAP/PHD subclass zinc finger proteins (IE1A and IE1B). The HHV-8 vIL-6, vDHFR, vTS, and vBcl-2 proteins have all been shown to be active in a variety of appropriate functional assays, and transcripts from vIL-6, vMIP-1B, vIE1-A, vIE1-B, and vDHFR genes are all expressed as abundant single messenger RNA species after butyrate or phorbol ester (TPA) induction of the lytic cycle in HHV8-positive BCBL cell lines. All of these genes lie within a divergent transcriptional domain that contains a single central enhancer and associated untranslated leader region plus seven distinct proximal promoters, some of which are negatively regulated through AP-1 and ZRE motifs by the EBV ZTA transactivator. This region also encompasses a predicted complex oriLyt domain of 1050 bp that is duplicated in inverted orientation adjacent to the T0.7 latency RNA in another large divergent locus (DL-E). We have previously described three distinct subtypes of the HHV8 genome that differ by 1.0%-1.5% at the nucleotide level within the ORF26 and ORF75 genes. Certain strains or clades appear to have preferential geographic distributions, but it is not known as yet whether there are any specific disease associations. Interestingly, the A, B, and C subtypes of HHV-8 also proved to differ dramatically in coding content at both the extreme left and right ends of the unique segment of the genome as well as in the positions of the junctions with the terminal repeats. On the left-hand side, the receptor-like ORF-K1 protein is highly variable with A-strain subtypes displaying 15% amino acid differences from C strains and up to 30% differences from B strains. On the right-hand side, two unrelated alternative types of the putative multiple membrane spanning ORF-K15 protein are found.

Distinguishing baboon cytomegalovirus from human cytomegalovirus: importance for xenotransplantation.

The severe shortage of human organs for transplantation is the driving force behind xenotransplant research. Nonhuman primates, particularly baboons, are potential sources of organs and tissues. Human cytomegalovirus (HCMV) is the most common donor-associated infection after allotransplantation. Baboon cytomegalovirus (BCMV) is endemic in baboon populations and therefore is a potential cause of donor-associated disease after xenotransplantation. Accordingly, the ability for BCMV to grow in human cells was determined and a sensitive method to distinguish BCMV from HCMV was developed. Human fibroblasts were permissive for BCMV, isolates exhibited cytopathology characteristic of HCMV, and herpesvirus-like virions were observed by electron microscopy. BCMV and HCMV could be distinguished by restriction fragment length polymorphism patterns and by polymerase chain reaction with primers targeting the BCMV major immediate-early gene promoter. These methods can be used to evaluate BCMV pathogenicity in laboratory and clinical xenotransplant trials.

Nucleotide sequence and molecular analysis of the rhesus cytomegalovirus immediate-early gene and the UL121-117 open reading frames.

Cytomegalovirus (CMV) has been isolated from many nonhuman primates, including rhesus macaques (Macaca mulatta). To better understand the molecular biology of rhesus CMV (RhCMV), a 9.2-kb DNA restriction fragment spanning the immediate-early (IE) gene has been molecularly cloned and sequenced. Open reading frames (ORF) have been identified and transcripts mapped for regions corresponding to exons 1, 2, 3, and 4 of the IE1 protein of human CMV (HCMV) and to exons 1, 2, 3, and 5 of IE2. The predicted RhCMV IE1 protein was 29 and 40% identical with the HCMV and African green monkey (AGM) CMV IE1 proteins, respectively, and the predicted RhCMV IE2 protein was 48 and 65% identical with the HCMV and AGM CMV IE2 proteins, respectively. Five additional ORF 3' to the RhCMV IE gene were identified which contained significant homologies with the HCMV UL121-UL117 ORF. The predicted translation products ranged from 29 to 47% identical with, and 52 to 66% similarity to the corresponding ORF of HCMV. Conservation of nucleic and amino acid sequences, and colinearity of genes, between primate CMV genomes contribute to a better understanding of primate CMV evolution, regulation, and pathogenesis.

Isolation, sequencing and expression of the superoxide dismutase-encoding gene (sod) of Nocardia asteroides strain GUH-2.

Nocardia asteroides (Na) superoxide dismutase (SOD) has been implicated as a virulence factor that allows the organism to survive intracellular killing by phagocytic cells. A full-length Na sod gene from a pathogenic strain of Na (strain GUH-2) was cloned from a recombinant phage library using the Mycobacterium tuberculosis (Mt) sod gene (Mt sod) as a probe. The promoter region and structural gene (624 bp) of Na sod was sequenced and nucleotide sequence comparisons reveal 77% homology with Mt sod. The Na sod gene also shares considerable sequence homology with sod of other mycobacterial species. In addition, conserved amino acid (aa) sequences important for metal binding indicate that Mn2+ is the preferred metal ion ligand for Na SOD. An Na sod expression plasmid, pYEX1, under transcriptional control of the Mt hsp70 promoter (pY6013), produced a 25-kDa protein product which showed SOD activity when stained in a native polyacrylamide gel and reacted with rabbit polyclonal antibody specific for Na SOD by Western blot. pYEX1, via transformation, was able to complement an Escherichia coli double sodAB mutant deficient in SOD production in the presence of paraquat (methyl viologen) which stimulates the production of superoxide radicals.

Analysis of the rhesus cytomegalovirus immediate-early gene promoter.

A cytomegalovirus (CMV) isolate has been recovered from a rhesus macaque (Macaca mulatta) experimentally infected with simian immunodeficiency virus. The full-length immediate-early gene (IE) was cloned from a genomic library of this primary rhesus CMV isolate (RhCMV) using the African green monkey (AGM) CMV IE gene as probe. The promoter region and the first non-coding exon of the RhCMV IE gene have been sequenced. Nucleotide sequence comparisons from positions -733 to +625 (relative to the start site of transcription at +1) reveal 70 and 48% sequence homology with the AGM CMV IE and the human CMV (HCMV) IE genes, respectively. A region that includes the TATA box, the cis repression signal and the first exon in the RhCMV IE gene sequence is 91 and 76% homologous with the AGM CMV and HCMV IE genes, respectively. In permissive MRC-5 cells infected with RhCMV, synthesis of RNA from the IE gene peaks at 4-8 hr post infection. These studies provide a basis for elucidating molecular mechanisms regulating expression of the RhCMV IE gene and viral replication.

Molecular interactions of cytomegalovirus and the human and simian immunodeficiency viruses.

In HuT 78 cells chronically infected with SIV, super-infection with rhesus cytomegalovirus (rhCMV) stimulated an increase in SIV replication. Utilizing transient expression assays with the SIV long terminal repeat (LTR) driving expression of the chloramphenicol acetyltransferase (CAT) reporter gene, the increase in SIV replication, by coinfection with CMV, was due to transactivation of the SIV LTR by the immediate early gene products (IE) of rhesus CMV. Similarly, IE of human CMV stimulated expression from both the SIV and HIV LTRs.