Molecular diversity among five different endogenous primate retroviruses.

Genetically transmitted retroviruses of Old and New World monkeys include type C viruses isolated from baboons (M7), macaque (MAC-1), and owl monkeys (OMC-1) and type D viruses from langurs (PO-1-Lu) and squirrel monkeys (SMRV, M534). Each of these isolates is unrelated to the others by nucleic acid hybridization criteria and contains a unique array of virion-associated proteins which can be resolved by agarose gel filtration and polyacrylamide gel electrophoresis under denaturing conditions. The major structural protein of each virus has a distinct primary structure, as determined by two-dimensional tryptic peptide analysis, and is antigenically different from the others. The major virion phosphoproteins of endogenous primate type C viruses (pp15) are also different from those of type D viruses (pp13-pp14). Immunological and structural analyses show that the endogenous langur virus and the horizontally transmitted Mason-Pfizer virus of rhesus monkeys are closely related to one another, consistent with the sequence homology detected in their RNA genomes. Although certain radioimmunoassays detect interspecies antigenic determinants common to either the p30 or gp70 proteins of some of these viruses, no one assay has yet been designed which can detect all groups of endogenous primate retroviridae. The data lead to the conclusion that primates contain a minimum of three different sets of genetically transmitted type C and type D retroviral genes.     

Two distinct endogenous type C viruses isolated from the asian rodent Mus cervicolor: conservation of virogene sequences in related rodent species.

The cocultivation of a lung cell line from the Southeast Asian mouse Mus cervicolor with cells from heterologous species has resulted in the isolation of two new distinct type C viruses. Both viruses are endogenous to M. cervicolor and are present in multiple copies in the cellular DNA of these mice. One of the viruses, designated M. cervicolor type CI, replicates readily in the SIRC rabbit cell line and is antigenically related to the infectious primate type C viruses isolated from a woolly monkey (simian sarcoma-associated virus) and gibbon apes (gibbon ape leukemia virus). This virus is also closely related by both immunological and nucleic acid hybridization criteria to a type C virus previously isolated from a second Asian murine species, Mus caroli. The isolation of the M. cervicolor type C I virus thus provides further evidence that the infectious primate type C viruses originated by trans-species infection of primates by an endogenous virus of mice. The second virus, designated M. cervicolor type C II, replicates well in various cell lines derived from the laboratory mouse Mus musculus. While antigenically related to type C viruses derived from M. musculus, the M. cervicolor type C II virus isolate can be readily distinguished from standard murine leukemia viruses. Both new type C viruses from M. cervicolor are unrelated to the previously described retrovirus (M432) isolated from the same Mus species. The DNA of M. cervicolor therefore contains multiple copies of at least three distinct classes of endogenous viral genes. An examination of the cellular DNA of other rodent species for nucleic acid sequences related to the genomes of both M. cervicolor type C I and II reveals that both viruses have been highly conserved evolutionarily, and that other species of rodents, such as laboratory mice and rats, contain endogenous virogenes related to those in the DNA of M. cervicolor.     

Genetic transmission of retroviral genes and cellular oncogenes

Several different families of retrovirus genome have been found to exist, each in multiple copies, in the cellular DNA of rodents and primates. There are at least four distinct families of genome in rodents: two type C families, the MTV family and another related to mouse type A particles. In primates there are also at least two families of endogenous type C virogenes and a third type D virogene family. Both in rodents and in primates, the virus-related sequences constitute almost 0.1% of the cellular genome. We have been able to generate transforming viruses, starting with endogenous mouse 'helper' type C viruses by passing them through chemically transformed mouse cells and selecting for variant viruses that have acquired the ability to induce normal cells to display anchorage-independent growth. These viruses produce both sarcomas and carcinomas in the animal; clones that produce only pulmonary carcinomas have also been selected. These presumably have arisen by recombination between the helper and 'transforming' sequences derived from the cells. Moloney sarcoma virus-transformed cells produce a new peptide, called sarcoma growth factor (SGF), that makes normal cells take on some of the properties of transformed cells. Studies with temperature-sensitive viral mutants show that the production of SGF is under the control of the transforming genes of the sarcoma virus.     

Skunks have gene sequences in their cellular DNA related to squirrel monkey retrovirus: transmission between species of a new world primate endogenous type D retrovirus.

The squirrel monkey ($\text{Saimiri}$,$\text{sciureus}$), a New World primate, contains multiple copies of endogenous type D retroviral gene sequences in the cellular DNA of all its tissues. Gene sequences partially homologous to these type D virus genes are also found in the cellular DNA of normal tissues of the New World carnivore, the skunk ($\text{Mephitis}$,$\text{mephitis}$ and $\text{Spilogale}$,$\text{putorius}$). We there-fore conclude that this class of viruses has, under natural conditions, been transmitted between the germ lines of these evolutionarily distant species. The example of interspecies transmission described here is the first that has been described among New World species and also the first that has been demonstrated for retroviruses other than type C viruses.     

Endogenous type C RNA virus of Odocoileus hemionus, a mammalian species of New World origin.

Type C RNA viruses have been isolated from several Old World vertebrates, and an even larger number of Old World species have been shown to contain endogenous viral genetic sequences. The present report describes the first isolation of type C virus endogenous to a species originating in the New World. This virus, isolated from cells of the Columbian black-tailed deer, Odocoileus hemionus, is shown to possess genetic sequences in common with DNA of its species of origin. While it shares biochemical and immunologic characteristics with other mammalian type C viruses, its immunologic properties readily distinguish it from known endogenous viruses.     

Simian homologues of Epstein-Barr virus

Gamma-herpesviruses closely related to the Epstein-Barr virus (EBV) are known to naturally infect Old World non-human primates and are classified in the same lymphocryptovirus (LCV) genera. LCV infecting humans and Old World primates share similar biology, and recent studies have demonstrated that these viruses share a similar repertoire of viral genes. Surprisingly, the latent infection genes associated with cell growth transformation demonstrate the most striking sequence divergence, but the functional mechanisms for these genes are generally well conserved. The recent discovery of LCVs naturally infecting New World primates has rewritten the old paradigm of LCV host range restriction to humans and Old World non-human primates, so that these viruses are more widespread than previously believed. However, the New World LCV genome has significant and interesting differences from EBV and other Old World LCVs despite similar biological properties. Thus, the simian homologues of EBV can provide an important animal model for studying LCV pathogenesis, and the similarities and differences that have evolved among these related viruses can provide a unique perspective towards a better understanding of EBV.     

Characterizatiion of rat genetic sequences of Kirsten sarcoma virus: distinct class of endogenous rat type C viral sequences.

The nucleic acid sequences found in DNA and RNA from rat cells which are homologous to Kirsten sarcoma virus have been characterized. The homologous sequences are present in multiple copies per diploid rat cellular genome in a variety of different rat cellular dna's. In certain cells that constitutively express only low levels of sequences homologous to Kirsten sarcoma virus, bromodeoxyuridine treatment leads to the expression of high levels of these sequences in RNA. Supernatants from cell lines producing the sequences homologous to Kirsten sarcoma virus contain high levels of these sequences which are purified to the same degree as the previously known rat type C viral nucleic acid sequences by type C particles being released from such cells. The results indicate that the sequences in rat cells homologous to Kisten sarcoma virus have three characteristics of known mammalian type C viruses, and suggest that at least part of Kirsten sarcoma virus rat-derived sequences represent a distinct class of endogenous rat type C virus that has no detectable homology to the other known class of endogenous rat type C virus.     

Analysis of the virogenes related to the rhesus monkey endogenous type C retrovirus in monkeys and apes.

Molecular hybridization studies were carried out by using a [3H]complementary DNA (cDNA) probe to compare the endogenous type C retrovirus of rhesus monkeys (MMC-1) with other known retroviruses and related sequences in various primate DNAs. The genomic RNA of the endogenous type C retrovirus of stumptail monkeys (MAC-1) was found to be highly related to the MMC-1 cDNA probe, whereas the other retroviral RNAs tested showed no homology. Related sequences were found in Old World monkey DNAs and to a lesser extent in gorilla dn chimpanzee DNAs. No homology was detected between MMC-1 cDNA and DNA of gibbon, orangutan, or human origin. Restriction endonuclease analysis of genomic DNA indicated that many of the several hundred sequences related to MMC-1 in rhesus monkey DNA differed from that integrated into DNA of infected canine cells. Gorilla and chimpanzee DNAs contained a specific restriction endonuclease fragment of the MMC-1 genome.     

Rate of divergence of cellular sequences homologous to segments of Moloney sarcoma virus.

The RNA genome of the Moloney isolate of murine sarcoma virus (M-MSV) consists of two parts--a sarcoma-specific region with no homology to known leukemia viral RNAs, and a shared region present also in Moloney murine leukemia virus RNA. Complementary DNA was isolated which was specific for each part of the M-MSV genome. The DNA of a number of mammalian species was examined for the presence of nucleotide sequences homologous with the two M-MSV regions. Both sets of viral sequences had homologous nucleotide sequences present in normal mouse cellular DNA. MSV-specific sequences found in mouse cellular DNA closely matched those nucleotide sequences found in M-MSV as seen by comparisons of thermal denaturation profiles. In all normal mouse cells tested, the cellular set of M-MSV-specific nucleotide sequences was present in DNA as one to a few copies per cell. The rate of base substitution of M-MSV nucleotide sequences was compared with the rate of evolution of both unique sequences and the hemoglobin gene of various species. Conservation of MSV-specific nucleotide sequences among species was similar to that of mouse globin gene(s) and greater than that of average unique cellular sequences. In contrast, cellular nucleotide sequences that are homologous to the M-MSV-murine leukemia virus "common" nucleotide region were present in multiple copies in mouse cells and were less well matched, as seen by reduced melting profiles of the hybrids. The cellular common nucleotide sequences diverged very rapidly during evolution, with a base substitution rate similar to that reported for some primate and avian endogenous virogenes. The observation that two sets of covalently linked viral sequences evolved at very different rates suggests that the origin of M-MSV may be different from endogenous helper viruses and that cellular sequences homologous to MSV-specific nucleotide sequences may be important to survival.     

Molecular evidence for a type C retrovirus etiology of the lymphoproliferative disease of turkeys.

Recently, we isolated from the blood of lymphoproliferative disease (LPD)-affected turkeys a type C retrovirus distinct from the avian leukosis-sarcoma virus complex and the reticuloendotheliosis virus group. We present molecular evidence for the implication of this virus in the LPD of turkeys. Using complementary DNA of LPD viral RNA, we found that the LPD viral genome is specifically and efficiently transcribed (2,500 copies per cell) in LPD tumor cells. Moreover, the LPD tumor cells contained newly inserted LPD viral information (5 to 10 copies per haploid genome), which was not present before the infection. From the absence of LPD virus-specific sequences in the normal cell genome of turkeys, it was concluded that the LPD virus is not an endogenous virus of turkeys. DNA-DNA annealing experiments revealed that the degree of sequence homology between LPD viral complementary DNA and cellular DNA of turkeys was not higher than that between LPD viral complementary DNA and cellular DNA of other species, thus indicating that the virus does not originate from turkeys.     

Reduced prevalence of Epstein-Barr virus-related lymphocryptovirus infection in sera from a new world primate

The recent discovery of an Epstein-Barr virus (EBV)-related lymphocryptovirus (LCV) naturally infecting common marmosets demonstrated that gamma-1 herpesviruses are not limited to human and Old World nonhuman primate hosts. We developed serologic assays to detect serum antibodies against lytic- and latent-infection marmoset LCV antigens in order to perform the first seroepidemiologic study of LCV infection in New World primates. In three different domestic colonies and in animals recently captured from the wild, we found that the seroprevalence of marmoset LCV infection was not as ubiquitous as with EBV or Old World LCV. These biologic differences in LCV infection of New World versus human and Old World primate hosts correlate with the evolution of the LCV viral gene repertoire.     

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.     

Etiological aspects of leukemias in primates including man

Attempts have been made to induce viral leukemia in monkeys (Papio hamadryas and Macaca arctoides) by inoculating them with blood from humans with different types of leukemias. In hamadryas baboons, the disease spread horizontally. By today 218 P. hamadryas and 5 M. arctoides monkeys had died of malignant lymphoma. The following viruses have been isolated from sick monkeys: lymphotropic baboon herpes virus (HVP), endogenous baboon C type viruses--xenotropic (BILN), and ecotropic (EVPG). C type oncovirus called "plasmic", which differs immunologically from the endogenous one, was also detected in the blood of sick animals. Altogether 165 sera from baboons, different species of macacas and chimpanzee were examined by the immunofluorescent technique for antibodies to HTLV virus isolated recently from sick humans with T cell leukemia/lymphoma. Antibodies to HTLV virus were detected only in monkeys (P. hamadryas and M. arctoides) with malignant lymphomas or in those which had been in close contact with them. Possible origin of simian HTLV-like virus is discussed. It originates either from leukemic patients or there is a family of primate HTLV like viruses related to the occurrence of leukemia.     

Infection of Human B Lymphocytes with Lymphocryptoviruses Related to Epstein-Barr Virus

Lymphocryptoviruses (LCVs) naturally infecting Old World nonhuman primates are closely related to the human LCV, Epstein-Barr virus (EBV), and share similar genome organization and sequences, biologic properties, epidemiology, and pathogenesis. LCVs can efficiently immortalize B lymphocytes from the autologous species, but the ability of a given LCV to immortalize B cells from other Old World primate species is variable. We found that LCV from rhesus monkeys did not immortalize human B cells, and EBV did not immortalize rhesus monkey B cells. In this study, baboon LCV could not immortalize human peripheral blood B cells but could readily immortalize rhesus monkey B cells. Thus, efficient LCV-induced B-cell immortalization across distant Old World primate species appears to be restricted by a species-specific block. To further characterize this species restriction, we first cloned the rhesus monkey LCV major membrane glycoprotein and discovered that the binding epitope for the EBV receptor, CD21, was highly conserved. Stable infections of human B cells with recombinant amplicons packaged in rhesus monkey or baboon LCV envelopes were also consistent with a species-restricted block occurring after virus binding and penetration. Transient infections of human B cells with simian LCV resulted in latent LCV EBNA-2 gene expression and activation of cell CD23 gene expression. EBV-immortalized human B cells could be coinfected with baboon LCV, and the simian virus persisted and replicated in human B cells. Thus, several lines of evidence indicate that the species restriction for efficient LCV-induced B-cell immortalization occurs beyond virus binding and penetration. This has important implications for the study of LCV infection in Old World primate models and for human xenotransplantation where simian LCVs may be inadvertently introduced into humans.     

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.