Optimal lengths for DNAs encapsidated by Epstein-Barr virus.

We measured the efficiency of DNA packaging by Epstein-Barr virus (EBV) as a function of the length of the DNA being packaged. Plasmids that contain oriP (the origin of latent EBV DNA replication), oriLyt (the origin of lytic EBV DNA replication), the viral terminal repeats (necessary for cleavage and packaging by EBV), and various lengths of bacteriophage lambda DNA were introduced into EBV-positive cells. Upon induction of the resident EBV's lytic phase, introduced plasmids replicated as concatemers and were packaged. Plasmid-derived concatemers of DNA with certain lengths were found to predominate in isolated virion particles. We measured the distribution of lengths of plasmid concatemers found within cells supporting the lytic phase of the viral life cycle and found that this distribution differed from the distribution of lengths of concatemers found in mature virion particles. This finding indicates that the DNA packaged into mature virions represents a selected subset of those present in the cell during packaging. These observations together indicate that the length of DNA affects the efficiency with which that DNA is packaged by EBV. Finally, we measured the length of the packaged B95-8 viral DNA and found it to be approximately 165 kbp, or 10 kbp shorter than the originally predicted size for B95-8 based on its sequence. Together with the results of other studies, these findings indicate that the packaging of DNAs by EBV is dependent on two imprecisely recognized elements: the viral terminal repeats and the length of the DNA being packaged by the virus.     

DNA of herpesvirus pan, a third member of the Epstein-Barr virus-Herpesvirus papio group

The DNA of herpesvirus pan, a primate B-lymphotropic herpesvirus, shares about 40% well-conserved sequence relatedness with Epstein-Barr virus (EBV) and herpesvirus papio DNAs. Labeled cloned fragments from the EBV recombinant DNA library were cross hybridized to blots of EcoRI, XbaI, and BamHI restriction endonuclease fragments of herpesvirus pan DNA to identify and map homologous sequences in the herpesvirus pan genome. Regions of colinear homology were demonstrated between 6 x 10(6) daltons and 108 x 10(6) daltons in the DNAs. The structural organization of herpesvirus pan DNA was similar to the format of Epstein-Barr virus and herpesvirus papio DNAs. The DNA consists of two domains of largely unique sequence complexity, a segment US of 9 x 10(6) daltons and a segment UL of 88 x 10(6) daltons. US and UL are separated by a variable number of tandem repetitions of a sequence IR (2 x 10(6) daltons). There was homology between DNA which mapped at 26 to 28 x 10(6) daltons and 93 to 95 x 10(6) daltons in UL. The terminal reiteration component, TR, of herpesvirus pan DNA and sequences which mapped to the left of 6 x 10(6) daltons and to the right of 108 x 10(6) daltons had no detectable homology with the corresponding regions of Epstein-Barr virus DNA.     

Herpesvirus papio DNA is similar in organization to Epstein-Barr virus DNA.

EcoRI, HindII, SalI, nd XbaI restriction endonuclease maps of herpesvirus papio (HVPapio) DNA were derived by determining the fragment sizes and the linkage relationships between fragments generated by the different enzymes. The data indicate that HVPapio DNA has a single molecular arrangement which is similar to that of Epstein-Barr virus DNA. The size of the DNA was 110 X 10(6) to 114 X 10(6) daltons. Restriction fragments from both ends varied in the number of repeats of a 4 X 10(5)-dalton sequence, TR, and hybridized to each other. This suggests that there is an identical repeating unit, TR, at both ends of the DNA. There were usually six tandem repetitions (range, 1 to 11) of a 2 X 10(6)-dalton sequence, IR, within the DNA. IR separated the DNA into two domains of largely unique sequence complexity, a 9 X 10(6)-dalton segment, Us, and an 88 X 10(6)-dalton segment, UL. There was homology between DNA fragments which mapped at 25 X 10(6) to 29 X 10(6) to 91 X 10(6) to 95 X 10(6) daltons in UL.     

Activation of the Epstein-Barr virus replicative cycle by human herpesvirus 6.

One common attribute of herpesviruses is the ability to establish latent, life-long infections. The role of virus-virus interaction in viral reactivation between or among herpesviruses has not been studied. Preliminary experiments in our laboratory had indicated that infection of Epstein-Barr virus (EBV) genome-positive human lymphoid cell lines with human herpesvirus 6 (HHV-6) results in EBV reactivation in these cells. To further our knowledge of this complex phenomenon, we investigated the effect of HHV-6 infection on expression of the viral lytic cycle proteins of EBV. Our results indicate that HHV-6 upregulates, by up to 10-fold, expression of the immediate-early Zebra antigen and the diffuse and restricted (85 kDa) early antigens (EA-D and EA-R, respectively) in both EBV producer and nonproducer cell lines (i.e., P3HR1, Akata, and Raji). Maximal EA-D induction was observed at 72 h post-HHV-6 infection. Furthermore, expression of late EBV gene products, namely, the viral capsid antigen (125 kDa) and viral membrane glycoprotein gp350, was also increased in EBV producer cells (P3HR1 and Akata) following infection by HHV-6. By using dual-color membrane immunofluorescence, it was found that most of the cells expressing viral membrane glycoprotein gp350 were also positive for HHV-6 antigens, suggesting a direct effect of HHV-6 replication on induction of the EBV replicative cycle. No expression of late EBV antigens was observed in Raji cells following infection by HHV-6, implying a lack of functional complementation between the deleted form of EBV found in Raji cells and the superinfecting HHV-6. The susceptibility of the cell lines to infection by HHV-6 correlated with increased expression of various EBV proteins in that B95-8 cells, which are not susceptible to HHV-6 infection, did not show an increase in expression of EBV antigens following treatment with HHV-6. Moreover, UV light-irradiated or heat-inactivated HHV-6 had no upregulating effect on the Zebra antigen or EA-D in Raji cells, indicating that infectious virus is required for the observed effects of HHV-6 on these EBV products. These results show that HHV-6, another lymphotropic human herpesvirus, can activate EBV replication and may thus contribute to the pathogenesis of EBV-associated diseases.     

Linkage map of the fragments of herpesvirus papio DNA.

Herpesvirus papio (HVP), an Epstein-Barr-like virus, causes lymphoblastoid disease in baboons. The physical map of HVP DNA was constructed for the fragments produced by cleavage of HVP DNA with restriction endonucleases EcoRI, HindIII, SalI, and PvuI, which produced 12, 12, 10, and 4 fragments, respectively. The total molecular size of HVP DNA was calculated as close to 110 megadaltons. The following methods were used for construction of the map; (i) fragments near the ends of HVP DNA were identified by treating viral DNA with lambda exonuclease before restriction enzyme digestion; (ii) fragments containing nucleotide sequences in common with fragments from the second enzyme digest of HVP DNA were examined by Southern blot hybridization; and (iii) the location of some fragments was determined by isolating individual fragments from agarose gels and redigesting the isolated fragments with a second restriction enzyme. Terminal heterogeneity and internal repeats were found to be unique features of HVP DNA molecule. One to five repeats of 0.8 megadaltons were found at both terminal ends. Although the repeats of both ends shared a certain degree of homology, it was not determined whether they were identical repeats. The internal repeat sequence of HVP DNA was found in the EcoRI-C region, which extended from 8.4 to 23 megadaltons from the left end of the molecule. The average number of the repeats was calculated to be seven, and the molecular size was determined to be 1.8 megadaltons. Similar unique features have been reported in EBV DNA (D. Given and E. Kieff, J. Virol. 28:524-542, 1978).     

Conservation of gene organization in the lymphotropic herpesviruses herpesvirus Saimiri and Epstein-Barr virus.

By analyses of short DNA sequences, we have deduced the overall arrangement of genes in the (A + T)-rich coding sequences of herpesvirus saimiri (HVS) relative to the arrangements of homologous genes in the (G + C)-rich coding sequences of the Epstein-Barr virus (EBV) genome and the (A + T)-rich sequences of the varicella-zoster virus (VZV) genome. Fragments of HVS DNA from 13 separate sites within the 111 kilobase pairs of the light DNA coding sequences of the genome were subcloned into M13 vectors, and sequences of up to 350 bases were determined from each of these sites. Amino acid sequences predicted for fragments of open reading frames defined by these sequences were compared with a library of the protein sequences of major open reading frames predicted from the complete DNA sequences of VZV and EBV. Of the 13 short amino acid sequences obtained from HVS, only 3 were recognizably homologous to proteins encoded by VZV, but all 13 HVS sequences were unambiguously homologous to gene products encoded by EBV. The HVS reading frames identified by this method included homologs of the major capsid polypeptides, glycoprotein H, the major nonstructural DNA-binding protein, thymidine kinase, and the homolog of the regulatory gene product of the BMLF1 reading frame of EBV. Locally as well as globally, the order and relative orientation of these genes resembled that of their homologs on the EBV genome. Despite the major differences in their nucleotide compositions and in the nature and arrangements of reiterated DNA sequences, the genomes of the lymphotropic herpesviruses HVS and EBV encode closely related proteins, and they share a common organization of these coding sequences which differs from that of the neurotropic herpesviruses, VZV and herpes simplex virus.     

Epstein-Barr virus DNA. IX. Variation among viral DNAs from producer and nonproducer infected cells.

A comparative analysis of three Epstein-Barr virus DNAs from American patients with infectious mononucleosis (B95-8, Cherry, and Lamont) and four Epstein-Barr virus DNAs from African patients with Burkitt lymphoma (AG876, W91, Raji, and P3HR-1) indicated that the usual format of Epstein-Barr virus DNA includes a variable number of direct repeats of a 0.35 X 10(6)-dalton sequence (TR) at both ends of the DNA, a 9 X 10(6)-dalton sequence of largely unique DNA (Us), a variable number of repeats of a 2 X 10(6)-dalton sequence (IR), and a 89 X 10(6)-dalton sequence of largely unique DNA (UL). Within UL there was homology between DNA at 26 X 10(6) to 28 X 10(6) daltons and DNA at 93 X 10(6) to 95 X 10(6) daltons. The relative sequence order (TR, US, IR, UL, TR) did not vary among "standard" Epstein-Barr virus DNA molecules of each isolate. B95-8 DNA had an unusual deletion extending from 91 X 10(6) to 100 X 10(6) daltons, and P3HR-1 DNA had an unusual deletion extending from 23.5 X 10(6) to 26 X 10(6) daltons. There was sufficient variability among the EcoRI and BamHI fragments of the DNAs to identify each isolate specifically. However, we discerned no distinguishing features for the two geographic or pathogenic origins of the seven isolates. Three intracellular DNAs (Raji, Lamont, and Cherry) and one virion DNA (P3HR-1) were heterogenous in molecular organization and had subpopulations of rearranged or defective molecules. Some regions, particularly 59 X 10(6) to 63 X 10(6) daltons and sequences around TR, frequently participated in rearrangements. Restriction endonuclease maps of the standard and rearranged DNAs of the seven isolates are presented.     

Comparison of Epstein-Barr virus strains of different origin by analysis of the viral DNAs

Epstein-Barr virus (EBV) originating from Burkitt's lymphoma (P3HR-1 and CC34-5), nasopharyngeal carcinoma (M-ABA), transfusion mononucleosis (B95-8), and a patient with acute myeloblastic leukemia (QIMR-WIL) was isolated from virus-carrying lymphoid cell lines after induction with the tumor promoter 12-O-tetradecanoylphorbol-13-acetate. Viral DNA was analyzed by partial denaturation mapping and by use of the restriction endonucleases EcoRI, HindIII, and SalI and separation of fragments in 0.4% agarose. By using the restriction enzyme data of B95-8 (EBV) and W91 (EBV) obtained by Given and Kieff (D. Given and E. Kieff, J. Virol. 28:524-542, 1978), maps were established for the other virus strains. Comigrating fragments were assumed to be identical or closely related among the different strains. Fragments of different strains migrating differently were isolated, purified, radioactively labeled, and mapped by hybridization against blots of separated viral fragments. The results were as follows. (i) All strains studied were closely related. (ii) The number of internal repeats was variable among and within viral strains. (iii) B95-8 (EBV) was the only strain with a large deletion of about 12,000 base pairs at the right-hand side of the molecule. At the same site, small deletions of about 400 to 500 base pairs were observed in P3HR-1 (EBV) and M-ABA (EBV) DNA. (iv) P3HR-1 (EBV), the only nontransforming EBV strain, had a deletion of about 3,000 to 4,000 base pairs in the long unique region adjacent to the internal repeats carrying a HindIII site. (v) Small inserted sequences of 150 to 400 base pairs were observed in M-ABA (EBV) and B95-8 (EBV) at identical sites in the middle of the long unique region. (vi) Near this site, an insertion of about 1,000 base pairs was found in P3HR-1 (EBV) DNA. (vii) The cleavage patterns of P3HR-1 virus DNA and the results of blot hybridizations with P3HR-1 virus fragments are not conclusive and point to the possibility that in addition to the normal cleavage pattern some viral sequences may be arranged differently. Even though it is possible that small differences in the genome organization may have significant biological effects, the great similarity among different EBV strains does not favor the hypothesis that disease-specific subtypes exist.     

Heterogeneity of Epstein-Barr virus. III. Comparison of a transforming and a nontransforming virus by partial denaturation mapping of their DNAs.

The DNAs of a transforming and a nontransforming Epstein-Barr virus strain, B95-8 AND P3HR-1, were compared by partial denturation mapping. B95-8 viral DNA showed a homogeneous denaturation pattern. In contrast, P3HR-1 viral DNA was heterogeneous, containing at least two classes of molecules, classified into groups A and B and present in a ratio of about 2:1 to 3:1. No evidence could be obtained that molecules from both groups A and B contain identical sequences present in different orientations as described for herpes simplex viral DNA. The majority of sequences present in B95-8 and in P3HR-1 viral DNA group A could be correlated by assuming that different sequences, about 12,000 base pairs long, were inserted or deleted, respectively, at different position of both viral genomes.     

Cytoplasmic RNA from normal and malignant human cells shows homology to the DNAs of Epstein-Barr virus and human adenoviruses.

Cytoplasmic RNA prepared from several human cell lines and tissues was hybridised to DNA from Epstein-Barr virus, human adenovirus types 2, 3 and 12 and human papovaviruses BK and JC. RNA from all the cells, regardless of whether or not they were virally infected, hybridised to specific regions of the Epstein-Barr virus or adenovirus genomes but not to papovavirus DNA. The cellular cross-hybridising species appear to be repetitive sequences which are conserved in higher eukaryotes. Mismatch estimations indicate a high degree of homology between the viral and host sequences. Detailed analysis of selected regions of viral DNA failed to reveal any primary-structural peculiarities.     

Selective switch between latency and lytic replication of Kaposi's sarcoma herpesvirus and Epstein-Barr virus in dually infected body cavity lymphoma cells.

The BC-1 cell line, derived from a body cavity-based, B-cell lymphoma, is dually infected with Epstein-Barr virus (EBV) and Kaposi's sarcoma-associated herpesvirus (KSHV). In these studies, the relationships between these two gammaherpesviruses and BC-1 cells were characterized and compared. Single-cell cloning experiments suggested that all BC-1 cells contain both genomes. In more than 98% of cells, both viruses were latent. The two viruses could be differentially induced into their lytic cycles by chemicals. EBV was activated into DNA replication and late-gene expression by the phorbol ester tetradecanoyl phorbol acetate (TPA). KSHV was induced into DNA replication and late-gene expression by n-butyrate. Amplification of both EBV and KSHV DNAs was inhibited by phosphonoacetic acid. Induction of the KSHV lytic cycle by n-butyrate was accompanied by the disappearance of host-cell beta-actin mRNA. Induction of EBV by TPA was not accompanied by such an effect on host-cell gene expression. Induction of the KSHV lytic cycle by n-butyrate was associated with the expression of several novel polypeptides. Recognition of one of these, p40, served as the basis of development of an assay for antibodies to KSHV in the sera of infected patients. BC-1 cells released infectious EBV; however, there was no evidence for the release of encapsidated KSHV genomes by BC-1 cells, even though n-butyrate-treated cells contained numerous intranuclear nucleocapsids. The differential inducibility of these two herpesviruses in the same cell line points to the importance of viral factors in the switch from latency to lytic cycle.     

Characterization of a bovine herpesvirus 4 immediate-early RNA encoding a homolog of the Epstein-Barr virus R transactivator.

Immediate-early (IE) RNA 2, the less abundant of two bovine herpesvirus 4 (BHV-4) RNAs detected in Madin-Darby bovine kidney cells infected in the presence of cycloheximide, is a 1.8-kb cytoplasmic polyadenylated RNA transcribed from the 8.3-kb HindIII fragment F. The structure of IE RNA 2 has been determined by S1 nuclease and exonuclease VII mapping, primer extension analysis, and sequencing of a partial cDNA. IE RNA 2 consists of a short, approximately 60-nucleotide 5' exon spliced to a 1.8-kb 3' exon. DNA sequence analysis revealed an open reading frame encoding 551 amino acids with sequence homology to the Epstein-Barr virus (EBV) R transactivator and its homolog in herpesvirus saimiri, HVS.R.IE 2 and HVS.R show higher homology to each other than to the EBV R transactivator. The homology is highest in the approximately 320 amino-terminal amino acids. All three proteins have acidic carboxyl termini but have little amino acid sequence homology in this region. In transient expression cotransfection assays, IE 2 activated expression from the BHV-4 early promoter-regulatory region of the major DNA-binding protein homolog over 100-fold in bovine turbinate cells. IE 1 was not necessary for this transactivation and did not augment it. However, IE 2 did not transactivate EBV or herpesvirus saimiri early promoter-regulatory regions that are transactivated by the EBV R transactivator or HVS.R.