Replication of baboon endogenous virus in human cells. Kinetics of DNA synthesis and integration

For the baboon endogenous virus to infect human cells a specific region on chromosome 6 is required for viral DNA replication and integration. In studying the kinetics of baboon endogenous virus DNA replication we show that linear DNA was synthesized as the predominant species after infection and that unintegrated DNA persisted after many cell passages. Examination of integrated DNA revealed the failure of the virus to integrate at early passages. With continuous replication, however, virus integration was observed, but at multiple sites in the host cell.     

Monoclonal antibodies against baboon endogenous virus and against host cell antigens.

Monoclonal antibodies were produced by murine hybridomas after immunization with semipurified baboon endogenous virus. In a solid-phase radioimmunoassay, two antibodies (F12-9 and B9-18) reacted with viral antigen only. The antibodies A6-8 and C9-12 also reacted with virus-producing cells but not with control cells, whereas antibodies E4-6 and D12-2 bound to virus-free cells as well. The cytofluorometry technique confirmed these results and showed a competition between antibodies A6-8 and C9-12 for binding to virus-producing cells as well as a competition between antibodies D12-2 and E4-6 for binding to virus-free human cells. An immune precipitation assay with disrupted virions indicated that antibodies A6-8, B9-18, and C9-12 were directed against the gp70 glycoprotein, and that antibody F12-9 reacted with a viral antigen with a molecular weight of 18,000. The syncytia induced in RSa cells by baboon molecular weight of 18,000. The syncytia induced in RSa cells by baboon endogenous virus could be inhibited either when antibody A6-8 or C9-12 was combined to the virus or when the RSa cells were treated with the anticellular antibody D12-2 or E4-6. These two effects were not observed with Mason-Pfizer virus. Thus, of three antibodies with specificities for viral gp70, two (A6-8 and C9-12) were directed at viral sites responsible for syncytium formation. Another antiviral antibody (F12-9) reacted with a protein of unknown function with a molecular weight of 18,000. The two anticellular antibodies were directed at similar or neighboring epitopes, which may be situated within the receptor to the virus.     

Requirement of human chromosomes 19, 6 and possibly 3 for infection of hamster x human hybrid cells with baboon M7 type C virus.

The replication pattern of the endogenous baboon type C virus M7 was studied in 29 primary Chinese hamster × human hybrid clones generated with leukemic cells from two different patients with acute lymphoblastic or myeloblastic leukemia. There was no evidence of viral particulate RDDP or M7 antigen before viral infection. M7 virus replicated in human and some hybrid cells but not in Chinese hamster cells, indicating that M7 requires dominantly expressed human gene(s) for replication. Enzyme and cytogenetic analyses show that a gene(s) coded for by human chromosome 19 is necessary for M7 infection of these hybrids. Detailed cytogenetic correlations revealed, however, that the chromosome 19+/M7 + hybrid clones with intact chromosomes also had copies of chromosomes 3 and 6. Previously, Bevi, the putative integration site for M7 virus, has been assigned to human chromosome 6. Many clones with various combinations of chromosomes 3 and 6 lacked chromosome 19, however, and failed to replicate exogenously applied M7 virus, while tests of 27 secondary clones showed that M7 markers co-segregated with chromosome 19 markers. These findings all confirm the need for a chromosome 19-coded function in Chinese hamster × human hybrids. In addition, the yield of viral particulate RDDP produced into the culture fluid was 50–100 fold less per viral antigen-positive cell in the hybrids compared with human cells. Thus some form of regulation of viral components exists in the hybrid cells. When the virus replicating in hybrid cells was transferred back to human cells, this regulation was relaxed and the yield of RDDP per FA(+) cell greatly increased. We conclude that human chromosomes 6 and 19 code for functions involved in M7 virus metabolism, and we cannot exclude a function coded for by chromosome 3.     

A new genetic locus, Bevi, on human chromosome 6 which controls the replication of baboon type C virus in human cells.

Somatic cell hybrids derived from seven independent fusions between mouse X human and hamster X human parental cells were examined for their ability to support the replication of the baboon endogenous type C virus. These hybrids preferentially segregated human chromosomes while retaining rodent chromosomes, as demonstrated by karyotypic and isozyme analysis. A total of 41 primary colonies and 33 secondary subclones were analyzed for viral replication, as well as for the presence of enzyme structural gene markers for 19 of 23 human chromosomes. A syntenic association was seen between the ability of the baboon type C virus to infect and replicate in hybrid cultures and the expression of human malic enzyme-1 (assigned to human chromosome 6). Analysis of 86 highly segregated subclones derived from cells preinfected with baboon type C virus showed that the continued production of baboon type C virus segregated concordantly with the expression of three enzyme genes assigned to human chromosome 6 (malic enzyme-1, phosphoglucomutase-3 and superoxide dismutase-2). Subclones of infected hybrids which lost chromosome 6 and failed to release virus also failed to synthesize the virus-coded major structural protein p30. No syntenic association between baboon virus expression and any of 18 other human chromosomes was observed. These studies define a new gene (designated Bevi) on human chromosome 6 which dominantly controls the replication of baboon type C virus. The data suggest that Bevi may be a preferred integration site for the baboon type C DNA provirus in the human genome.     

Rescue of endogenous 30S retroviral sequences from mouse cells by baboon type C virus.

Mus musculus SC-1 cells were infected with M7 baboon type C virus. The progeny of this infection included viral pseudotypes that contained M7 helper virus and endogenous 30S retrovirus-associated sequences derived from SC-1 cells (RAS). The RAS sequences are unrelated by nucleic acid hybridization criteria to previously described types of murine retroviruses and do not code for known murine viral structural proteins. The RAS genome is present in multiple copies in the DNA of laboratory (M. musculus) and Asian (M. caroli and M. cervicolor) mice, is expressed in the RNA of uninfected mouse cells, and can be efficiently rescued by type C, but not type B, viruses. RAS is closely related to 30S virus-associated RNA in NIH/3T3 and BALB/c JLSV-9 cells and may be analogous to the defective 30S RNA sequences found in rats.     

Complete nucleotide sequence of simian endogenous type D retrovirus with intact genome organization: evidence for ancestry to simian retrovirus and baboon endogenous virus.

A complete endogenous type D viral genome has been isolated from a baboon genomic library. The provirus, simian endogenous retrovirus (SERV), is 8,393 nucleotides long and contains two long terminal repeats and complete genes for gag, pro, pol, and env. The primer binding site is complementary to tRNA(Lys)3, like in lentiviruses. The env GP70 protein is highly homologous to that of baboon endogenous virus (BaEV). PCR analysis of primate DNA showed that related proviral sequences are present in Old World monkeys of the subfamily Cercopithecinae but not in apes and humans. Analysis of virus and host sequences indicated that the proviral genomes were inherited from a common ancestor. Comparison of the evolution of BaEV, exogenous simian retrovirus types 1 to 3 (SRV1 to SRV3), and SERV suggests that SERV is ancestral to both BaEV and the SRVs.     

Endogenous mink (Mustela vison) type C virus isolated from sarcoma virus-transformed mink cells.

A previously described type virus stock (designated PP-1R), isolated by cocultivating baboon cells with mink cells transformed by Kirsten sarcoma virus (64J1), has been further cloned and characterized. End point-diluted stocks of PP-1R have been obtained that are free of focus-forming activity and lack both Kirsten sarcoma and primate type C viral sequences. Nucleic acid hybridization experiments show that the cloned virus (MiLV) is an endogenous, genetically transmitted virus of the mink (Mustela vison). MiLV replicates in canine, feline, and 64J1 mink cells but not in an untransformed mink cell line. Multiple viral gene copies can be detected in the DNA of normal mink cells in culture and in normal mink tissues; related endogenous viral genes are also detected in several related Mustela species. The virus codes for a p30 protein very closely related antigenically to that of feline leukemia virus but contains p15 and p12 proteins that are antigenically distinct. The mink cell line, Mv1Lu, and its Kirsten sarcoma-transformed derivatives, 64J1, express relatively low levels of type C viral RNA related to MiLV and normally do not produce detectable levels of MiLV p30 protein or complete, infectious viral particles. Infection of sarcoma virus-transformed mink cells with baboon type C virus, however, can augment the level of expression of endogenous mink viral RNA and can result in the synthesis and packaging of mink viral RNA and p30 antigen in extracellular virions. Since the Mv1Lu cell line and its tranformed derivatives have become widely used in studies of retroviruses, the possibility of activating endogenous mink viral genes should be considered by investigators working with these cells.     

Cell receptors for baboon endogenous virus recognized by monoclonal antibodies.

Hybridomas from mice immunized with baboon endogenous virus (BaEV) from A204(M7) cells produced several antiviral monoclonal antibodies and, in addition, antibodies D-12 and E-4, which appeared to be virus specific because they reacted with BaEV but not with Mason-Pfizer virus or RD-114 virus. However, they also bound to human virus-free cells, and they did not recognize BaEV from bat or canine host cells. Cell membrane targets for these antibodies comigrated with an 18,000-dalton protein, which may contain specific determinants of BaEV receptors since antibody masking of these cell sites prevented BaEV but not Mason-Pfizer virus or RD-114 virus adsorption. However, RD-114 virus interfered with BaEV adsorption. Thus, the two viral receptors must be adjacent, but the antibody D-12 and E-4 targets are not within the active site of RD-114 virus receptor. Conversely, cell coating with BaEV from bat or canine hosts inhibited antibody D-12 binding. Noncultivated human lymphocytes and cells from fetal organs bound much less antibody D-12 than did cells from established cell lines, with a correlation between amounts of antibody D-12 acceptor sites and BaEV receptors. Thus, in vivo, BaEV infection of human cells may be inefficient. In vitro, antibody D-12 treatment of chronically infected A204(M7) cells caused intracellular accumulation of viral proteins and decreased virus release, with no such effect on RD-114 virus-producing cells. Canine cells bound antibody D-12 only if coated with BaEV from A204(M7) cells, indicating that the human determinant coadsorbed with the virions to animal cells. Possibly, determinants of cell receptors participate in BaEV maturation and become associated with the virions.     

The baboon endogenous virus genome. II. Provirus sequence variations in baboon cell DNA.

Restriction analysis of the approximately 100 integrated baboon endogenous virus (BaEV) proviruses in baboon cells and tissues has revealed two major sequence variations, both in the gag gene region of the genome. One, a 150 nucleotide pair insert, is present in a small proportion of the proviral DNAs and some baboons, but is present in the majority of the proviral DNAs of other baboons. The second, a Bam HI recognition sequence located 2.25 kb from the proviral 5' end, is missing or modified in approximately one-half of the integrated genomes. We consider the possibility that accumulation of proviruses not containing the 0.15 kb insert is correlated with viral activation and expression since it is this form that is a replication intermediate in freshly infected permissive cells. It is evident from these initial studies that the organization of the multiple BaEV proviruses in baboon DNA has undergone modification during evolution.     

A sodium-dependent neutral-amino-acid transporter mediates infections of feline and baboon endogenous retroviruses and simian type D retroviruses

The type D simian retroviruses cause immunosuppression in macaques and have been reported as a presumptive opportunistic infection in a patient with AIDS. Previous evidence based on viral interference has strongly suggested that the type D simian viruses share a common but unknown cell surface receptor with three type C viruses: feline endogenous virus (RD114), baboon endogenous virus, and avian reticuloendotheliosis virus. Furthermore, the receptor gene for these viruses has been mapped to human chromosome 19q13.1-13.2. We now report the isolation and characterization of a cell surface receptor for this group of retroviruses by using a human T-lymphocyte cDNA library in a retroviral vector. Swiss mouse fibroblasts (NIH 3T3), which are naturally resistant to RD114, were transduced with the retroviral library and then challenged with an RD114-pseudotyped virus containing a dominant selectable gene for puromycin resistance. Puromycin selection yielded 12 cellular clones that were highly susceptible to a beta-galactosidase-encoding lacZ(RD114) pseudotype virus. Using PCR primers specific for vector sequences, we amplified a common 2.9-kb product from 10 positive clones. Expression of the 2.9-kb cDNA in Chinese hamster ovary cells conferred susceptibility to RD114, baboon endogenous virus, and the type D simian retroviruses. The 2.9-kb cDNA predicted a protein of 541 amino acids that had 98% identity with the previously cloned human Na+-dependent neutral-amino-acid transporter Bo. Accordingly, expression of the RD114 receptor in NIH 3T3 cells resulted in enhanced cellular uptake of L-[3H]alanine and L-[3H]glutamine. RNA blot (Northern) analysis suggested that the RD114 receptor is widely expressed in human tissues and cell lines, including hematopoietic cells. The human Bo transporter gene has been previously mapped to 19q13.3, which is closely linked to the gene locus of the RD114 receptor.     

Heteroduplex study of the sequence relations between RD-114 and baboon viral RNAs.

The regions of sequence homology and nonhomology between the RNA genomes of RD-114 and baboon endogenous type C viruses have been mapped by an electron microscope heteroduplex study. Short complementary DNA (cDNA) copies (approximately 150 to 200 nucleotides in length) of RD-114 RNA were prepared by an endogenous synthesis; labels of polydeoxythymidylic acid [poly(dT)] were attached to the 3' ends of the cDNA molecules by a reaction catalyzed by deoxynucleotidyl terminal transferase. The cDNA-poly(dT) was hybridized to RD-114 RNA and to baboon viral RNA dimer (50 to 70S) units, and the position- of the poly(dT) labels were observed by electron microscopy. With RD-114, labels were distributed uniformly along the genome. With baboon virus RNA (monomer length, 9.5 kilobases [kb]), the regions of high homology with RD-114 cDNA were observed to lie in the intervals from 1.5 to 2.5 kb and from 3.7 to 5.5 kb from the 5' end. The relations of these heteroduplex maps to the known antigenic similarities and differences among the several viral proteins and to the genetic maps of the viruses are discussed.     

Purification and characterization of baboon endogenous virus DNA polymerase.

An RNA-directed DNA polymerase was purified from baboon endogenous type-C virus by successive column chromatography on DEAE cellulose, phosphocellulose and hydroxyapatite. The purified DNA polymerase has a molecular weight of 68 000, a pH optimum of 8.0, a Mn2+ optimum of 1 mM, and a KCl optimum of 40 mM. The purified enzyme transcribes heteropolymeric regions of viral 60--70 S RNA isolated from different type-C viruses. The purified enzyme is immunologically related to a similarly purified polymerase from the cat endogenous type-C virus RD114.     

RD-114, baboon, and woolly monkey viral RNA's compared in size and structure.

The molecular weights, subunit compositions, and secondary structure patterns of the RNAs from an endogenous baboon virus and from a woolly monkey sarcoma virus were examined and compared to the properties of the RNA of RD-114, an endogenous feline virus. The high molecular weight RNA extracted from each of these three viruses has a sedimentation coefficient of 52S, and a molecular length, measured by electron microscopy, of 16-20 kb (kb=kilobase, 1000 nucleotides). Each such RNA is a dimer, containing two monomer subunits of 8-10 kb in length (molecular weight 3 X 10(6) daltons). The two monomer subunits are joined at their non-poly(A) ends in a structure called the dimer linkage structure. The appearance of this structure is somewhat different for the different viruses. The dimer linkage dissociates at temperature estimated to be 87 degrees C in aqueous 0.1M Na+ for RD-114 and baboon viral RNAs, but at the lower temperature of 66 degrees C for woolly monkey RNA. All three viral RNAs have two large loops of similar size and position symmetrically placed on either side of the dimer linkage structure. Since the baboon virus is partially related to RD-114, and the woolly monkey virus is unrelated to either of the other two, the dimer linkage and symmetrical loops are surprisingly similar and may well be common features of type C virus RNAs.     

Baboon endogenous virus genome. I. Restriction enzyme map of the unintegrated DNA genome of a primate retrovirus

A detailed restriction map was deduced for the genome of an endogenous retrovirus of a higher primate, that of baboon. The cleavage sites for 12 restriction enzymes were mapped. The unintegrated linear viral DNA intermediate that is produced by infection of permissive cells with baboon endogenous virus was isolated. Hybridization with a strong-stop complementary DNA probe demonstrated presence of a terminal repetition in the linear viral DNA. The positions of restriction sites for two particular enzymes, SmaI and XhoI, near each end were consistent with this result and indicated that the length of the repetition is 0.55 +/- 0.01 kilobase. The linear viral DNA had a unique restriction map indicating that it is not a set of random circular permutations of the RNA genome. From hybridization with a 3'-specific probe, the DNA restriction map was aligned relative to the 5'-to-3' orientation of the viral RNA. We observed a minor heterogeneity in a BamHI recognition site 1.95 kilobases from the right end of the linear map.     

Sodium-dependent neutral amino acid transporter type 1 is an auxiliary receptor for baboon endogenous retrovirus

The baboon endogenous retrovirus (BaEV) belongs to a large, widely dispersed interference group that includes the RD114 feline endogenous virus and primate type D retroviruses. Recently, we and another laboratory independently cloned a human receptor for these viruses and identified it as the human sodium-dependent neutral amino acid transporter type 2 (hASCT2). Interestingly, mouse and rat cells are efficiently infected by BaEV but only become susceptible to RD114 and type D retroviruses if the cells are pretreated with tunicamycin, an inhibitor of protein N-linked glycosylation. To investigate this host range difference, we cloned and analyzed NIH Swiss mouse ASCT2 (mASCT2). Surprisingly, mASCT2 did not mediate BaEV infection, which implied that mouse cells might have an alternative receptor for this virus. In addition, elimination of the two N-linked oligosaccharides from mASCT2 by mutagenesis, as substantiated by protein N-glycosidase F digestions and Western immunoblotting, did not enable it to function as a receptor for RD114 or type D retroviruses. Based on these results, we found that the related ASCT1 transporters of humans and mice are efficient receptors for BaEV but are relatively inactive for RD114 and type D retroviruses. Furthermore, elimination of the two N-linked oligosaccharides from extracellular loop 2 of mASCT1 by mutagenesis enabled it to function as an efficient receptor for RD114 and type D retroviruses. Thus, we infer that the tunicamycin-dependent infection of mouse cells by RD114 and type D retroviruses is caused by deglycosylation of mASCT1, which unmasks previously buried sites for viral interactions. In contrast, BaEV efficiently employs the glycosylated forms of mASCT1 that occur normally in untreated mouse cells.     

An encephalomyocarditis virus epizootic in a baboon colony.

Approximately 80 baboon deaths were caused by encephalomyocarditis virus (EMCV) infection in a 3060 member research and production colony. The epizootic extended over a 9-month period and occurred in baboons ranging from 1 day to 22 years of age. Acute death was the most common history. When clinical disease was detected, it was characterized by labored respiration associated with acute congestive heart failure. The salient necropsy findings were pulmonary congestion and edema, hydropericardium, hydrothorax, ascites, lymph node and splenic hypertrophy, and pale white-to-tan mottled hearts. The most significant histologic lesion was nonsuppurative necrotizing myocarditis. Placental infection with fetal loss occurred. Diagnosis was confirmed by light microscopy, transmission electron microscopy, virus culture, and serology. Rarely, EMCV-induced antibody persisted in surviving baboons for more than 24 months. EMCV-infected feral rats were the probable source of the virus and their control stopped the epizootic. No EMCV neutralizing antibody was detected in colony support personnel or chimpanzees.     

Organization of type C viral DNA sequences endogenous to baboons: analysis with cloned viral DNA.

Unintegrated linear and circular forms of baboon endogenous type C virus M7 DNA were prepared from M7-infected cells by chromatography on hydroxyapatite columns, and the circular DNAs were purified in cesium chloride-ethidium bromide equilibrium density gradients. The circular DNAs were linearized by digestion with EcoRI, which had a unique site on the viral DNA. The linearized DNA was then inserted into lambda gtWES. lambda B at the EcoRI site and cloned in an approved EK2 host. Molecularly cloned full-length M7 DNA was restricted with BamHI, and the resulting five subgenomic fragments were then subcloned individually in plasmid pBR322. The organization and sites of integration of the approximately 100 copies of M7 DNA sequences endogenous to baboons were investigated by digesting the DNA with restriction enzymes and identifying the virus-specific fragments by hybridization to labeled probes made by using the molecularly cloned full-length and subgenomic fragments of the viral DNA. We found that most of the endogenous sequences had sizes and organizations similar to those of the unintegrated viral DNA and therefore approximately similar to the RNA of the infectious virus. A few of the multiple sequences had deletions in the 3' end (envelope region), and some of the sequences either lacked or contained modified BamHI restriction sites on the 5' end of the viral DNA. The endogenous viral DNA sequences were nontandem, uninterrupted, and colinear with the DNA of the infectious virus, and they were integrated at different sites in the baboon DNA, like the M7 proviral DNA sequences acquired upon infection.     

Structure of the baboon endogenous virus genome: cloning of circular virus DNA in bacteriophage lambda.

Linear, small and large circular forms of unintegrated viral DNAs were detected in Hirt supernatant fraction of human cultured cells infected with baboon endogenous virus M7. The circular M7 DNAs were cloned in bacteriophage lambda, Charon 28. Seventeen independent clones were isolated and analyzed by restriction endonuclease mapping. Nine clones were carrying a viral sequence of 8.6 kilobase pairs (kb) with two tandem repeats of 0.6 kb, which correspond to the large circular form of the unintegrated M7 DNA. Eight other clones had the viral insert of 8.0 kb, i. e., the small circular form, and were deleted one of the repeated sequences. The repeated sequences correspond to the long terminal repeats of 0.6 kb, located at both ends of the linear M7 DNA of 8.6 kb. One of the recombinants of the large circular M7 DNA had an inversion of 2.5 kb. One end of the inverted sequence was near the terminus of the long terminal repeats and the other in the gag gene region. The inversion seems to be occurred by integration of a viral DNA within itself during early periods of infection. The mechanism of the processes leading to integration is discussed from the structure of these unintegrated M7 DNAs as the precursors.