Major Group-Specific Protein of Rat Type C Viruses

The major internal protein of a rat type C virus pseudotype of murine sarcoma virus, MSV(RaLV), was purified by isoelectric focusing (pI = 8.6) and used to prepare antibody in guinea pigs. The protein was identified by its reaction with antisera reactive with the mammalian type C virus group-specific (gs) antigenic determinant, gs-3. The guinea pig antisera mainly contained species-specific (gs-1) antibody for reactions in gel diffusion with other type C viruses were limited to those of rat origin, whereas in complement fixation tests heterologous reactions could be eliminated by use of appropriate antiserum concentrations without affecting homologous reactions. Guinea pig antisera against mouse, hamster, or cat gs-1 determinants did not react with MSV(RaLV) purified gs protein or with any of several other rat type C viruses.     

Species and Interspecies Radioimmunoassays for Rat Type C Virus p30: Interviral Comparisons and Assay of Human Tumor Extracts

The major internal protein, p30, of rat type C virus (RaLV) was purified and utilized to establish intra- and interspecies radioimmunoassays. Three rat viruses were compared in homologous and heterologous intraspecies assays with no evidence of type specificity. The only heterologous viruses to give inhibition in these species assays were the feline (FeLV) and hamster (HaLV) type C viruses; these reactions were incomplete and required high virus concentrations. An interspecies assay using a goat antiserum prepared after sequentially immunizing with FeLV, RD 114, and woolly monkey virus p30's and labeled RaLV p30 was inhibited by all mammalian type C viruses, although preferentially by RaLV, FeLV, and HaLV. Thus, as in a previously reported assay developed with HaLV p30, rat, hamster, and cat p30's seem more closely related to each other than to mouse type C virus p30. High levels of specific antigen were found in all cell lines producing rat virus, whereas embryonic tissues from several rat strains and cell lines considered virus-free based on other tests were negative for p30. Rats bearing tumors containing Moloney murine sarcoma virus (RaLV) did not contain free circulating antibody to RaLV p30. Fifty-one human tumor extracts (including two tumor cell lines) were tested for activity in the RaLV species and 47 in the interspecies assays after Sephadex gel filtration and pooling of material in the 15,000- to 40,000-molecular-weight range. At a sensitivity level of 7 ng/ml (0.7 ng/assay) in the interspecies assay, all human tissues, with one exception, were negative. The one positive result is considered nonspecific based on proteolysis of the labeled antigen. Input tissue protein of the purified tumor extracts averaged 1.9 mg/ml with a range of < 0.025 to 22 mg/ml. Tissues from NIH Swiss mice processed in the same manner were positive in the interspecies assay but negative in the intraspecies RaLV assay.     

Species and interspecies radioimmunoassays for rat type C virus p30: interviral comparisons and assay of human tumor extracts.

The major internal protein, p30, of rat type C virus (RaLV) was purified and utilized to establish intra- and interspecies radioimmunoassays. Three rat viruses were compared in homologous and heterologous intraspecies assays with no evidence of type specificity. The only heterologous viruses to give inhibition in these species assays were the feline (FeLV) and hamster (HaLV) type C viruses; these reactions were incomplete and required high virus concentrations. An interspecies assay using a goat antiserum prepared after sequentially immunizing with FeLV, RD 114, and woolly monkey virus p30's and labeled RaLV p30 was inhibited by all mammalian type C viruses, although preferentially by RaLV, FeLV, and HaLV. Thus, as in a previously reported assay developed with HaLV p30, rat, hamster, and cat p30's seem more closely related to each other than to mouse type C virus p30. High levels of specific antigen were found in all cell lines producing rat virus, whereas embryonic tissues from several rat strains and cell lines considered virus-free based on other tests were negative for p30. Rats bearing tumors containing Moloney murine sarcoma virus (RaLV) did not contain free circulating antibody to RaLV p30. Fifty-one human tumor extracts (including two tumor cell lines) were tested for activity in the RaLV species and 47 in the interspecies assays after Sephadex gel filtration and pooling of material in the 15,000- to 40,000-molecular-weight range. At a sensitivity level of 7 ng/ml (0.7 ng/assay) in the interspecies assay, all human tissues, with one exception, were negative. The one positive result is considered nonspecific based on proteolysis of the labeled antigen. Input tissue protein of the purified tumor extracts averaged 1.9 mg/ml with a range of less than 0.025 to 22 mg/ml. Tissues from NIH Swiss mice processed in the same manner were positive in the interspecies assay but negative in the intraspecies RaLV assay.     

Retention of Antigen Specificity of Murine Sarcoma Viruses grown in Hamster Cells <Emphasis Type="Italic">in vitro</Emphasis>

TUMOURS can be induced in hamsters by the various strains of murine sarcoma virus (MSV)^1–6. Tumours differ, however, in the antigens which are expressed. Whereas the cell line HT-1, derived from early passages of a hamster tumour induced by the Moloney strain of MSV (M-MSV), contains no trace of infectious virus or virion antigen^2,7, tumours induced by the Harvey (H), Kirsten (Ki) and later passages of the M-MSV-(GLV) viruses have yielded sarcoma viruses with a hamster-specific host range^3–6,8 which do not share envelope^4–6,9 or group specific¹⁰ antigens with murine viruses. The HT-1 cell does retain the MSV genome which can be rescued by murine leukaemia viruses². Such rescued viruses are termed pseudo-types and contain the envelope and group-specific antigens of the rescuing virus. The virus preparation from tumours induced by M-MSV(GLV) differed from the other hamster-specific viruses in that a non-sarcomagenic C-type virus could be isolated from cultures infected beyond the cell transformation end point⁶. This virus was also hamster-specific in host range and antigenic properties and specifically interfered with cell transformation by the various hamster-specific virus strains⁹. This virus also shared an ether-stable virion-antigen with a C-type virus found in a lymphoma which occurred spontaneously in a hamster¹⁰. This shared antigen seems to be the principal structural polypeptide of hamster C-type viruses and is structurally similar but antigenically distinct from its mouse homologue (unpublished work of S. O., C. Foreman, G. K. and R. V. G.). These findings led us to propose that the hamster-specific non-sarcomagenic C-type virus was a hamster leukaemia virus (in the generic but not necessarily the pathological sense) and the virus is therefore designated HaLV^9,10. The hamster-specific sarcoma viruses are considered to be pseudotypes of MSV rescued in vivo by HaLV and are abbreviated accordingly; for example, M-MSV(HaLV) represents the hamster-specific sarcoma virus rescued from M-MSV induced tumours. This is plausible because HaLV is able to rescue the MSV genome from HT-1 cells⁶. (This change in the nomenclature has been made in order to reflect the antigenic composition of the hamster-specific virus more accurately. In addition, to indicate the virus rescued from M-MSV(GLV)-induced hamster tumours, a terminal G is added after the parentheses. This has been done only to distinguish it from the virus obtained from M-MSV induced hamster tumours, for there is no evidence of residual activity from GLV.)     

Characterization of Gazdar murine sarcoma virus by nucleic acid hybridization and analysis of viral expression in cells.

Gazdar murine sarcoma virus (Gz-MSV) and Moloney murine sarcoma virus (M-MSV) are closely related. The complete M-MSV-specific nucleic acid sequences constituted a major portion of Gz-MSV-specific sequences. The MSV-specific sequences in both Gz-MSV and M-MSV genomes shared homology with hamster leukemia virus nucleic acid sequences. Both rat cells (S+L+) and hamster (S+L-) cells expressed two viral proteins of 68,000 and 70,000 daltons. These proteins were immunologically related to p60 purified from m1 virions of M-MSV.     

Serological Identification of Hamster Oncornaviruses

CATS, mice and chickens have indigenous oncornaviruses (oncogenic RNA viruses) which induce leukaemias and sarcomas^1,2. Mouse sarcoma virus (MuSV), like avian sarcoma virus, can induce sarcomas in the hamster^3,4 but some of these MuSV hamster sarcomas release virus that differs both antigenically and with regard to its host range from the original⁵—it can be neutralized by antisera prepared against isolates of virus released from MuSV-transformed cells but not by antisera against murine leukaemia virus (MuLV) and it is sarcomagenic in hamsters but not in mice. Such a virus could be: (a) an indigenous hamster sarcoma virus “activated” by the inoculation of MuSV; (b) an MuSV genome that has acquired a new viral envelope from an indigenous hamster leukaemia virus (HaLV) during its sojourn in hamsters; or (c) a recombinant between HaLV and the sarcomagenic portion of the MuSV genome. In fact, it is known that the hamster possesses a virus (HaLV) which is morphologically similar to MuLV^6,7. This virus lacks⁸ the group-specific (gs) internal MuLV-gs1 antigen characteristic of MuLV^9,10 although it does have the gs antigen (MuLV-gs3) which is common to all mammalian leukaemia viruses investigated so far⁸.     

Studies on the Nucleic Acid Sequences of Kirsten Sarcoma Virus: a Model for Formation of a Mammalian RNA-Containing Sarcoma Virus

The genetic information contained in the Kirsten and Moloney strains of mammalian RNA-containing sarcoma viruses has been analyzed by RNA . (3)H-DNA hybridization. Kirsten sarcoma virus has been found to possess two distinct sets of nucleic acid sequences. One set of sequences is contained in murine type C helper virus, and the other set is contained in rat type C helper virus. Moloney sarcoma virus contains sequences of murine type C helper virus but not of rat type C helper virus. The results indicate that Kirsten sarcoma virus arose through a process of recombination between Kirsten murine leukemia virus and nucleic acid sequences found in rat cells. A model is suggested for the formation of transforming type C viruses involving the transduction of oncogenic information.     

Comparative ultrastructural study of four reticuloendothelias viruses.

The morphology and development of four members of the reticuloendotheliosis virus group were studied by transmission electron microscopy. Virions of duck spleen necrosis virus, duck infectious anemia virus, chicken syncytial virus, and reticuloendotheliosis virus strain T are sperical with a diameter of approximately 110 nm. They are covered with surface projections about 6 nm long and 10 nm in diameter. The center-to-center distance of surface projections is about 14 nm. The budding virions contain crescent-shaped electron-dense cores 73 nm in diameter with electron-lucent centers. After release of the virions the cores apparently become condensed to 67 nm in diameter. Virions were found budding at the plasma membrane and into smooth-walled, intracytoplasmic vesicles of productively infected cells. The distribution of budding reticuloendotheliosis viruses on cells appeared random over the cell surface, and occasionally aberrant multiple forms of budding virions were observed. The virions appear to resemble mammalian leukemia and sarcoma viruses more closely than avian leukosis-sarcoma viruses.     

FBJ osteosarcoma virus in tissue culture. III. Isolation and characterization of non-virus-producing FBJ-transformed cells.

Hamster and rat cell lines have been established that have been transformed by FBJ murine sarcoma virus (FBJ-MuSV) but that do not produce virus. The hamster cell line originated from an osteosarcoma that appeared in a hamster inoculated at birth with an extract of a CFNo1 mouse FBJ-osteosarcoma. The rat cell line was obtained by transferring the FBJ-MuSV genome to normal rat kidney cells in the absence of the FBJ type C virus (FBJ-MuLV), which, usually in high concentration, accompanies the FBJ-MuSV. Both transformed hamster and rat cell lines contain the FBJ-MuSV genome, which can be rescued by ecotropic and xenotropic murine type C viruses. This rescued genome produces characteristic FBJ-MuSV foci in tissue culture and, in appropriate animal hosts, induces osteosarcomas typical of those induced by FBJ-MuSV. FBJ-MuSV was isolated originally from a parosteal osteosarcoma that occurred naturally in a mouse. Since there was no previous history of passage of the agent through any other animal species, these non-virus-producing hamster and rat cells transformed by FBJ-MuSV should be very helpful in molecular studies examining the origin of spontaneous sarcoma genomes in mice.     

Serological analysis of an oncornavirus (PMF virus) detected in malignant permanent human cell lines.

Immunodiffusion analysis of the PMF virus which was detected in malignant permanent human cell lines revealed positive reactions with antisera against the Mason-Pfizer monkey virus (MPMV). No cross-reactivity was demonstrated with murine leukemia virus (MuLV), rat leukemia virus (RaLV), hamster leukemia virus (HaLV), feline leukemia virus (FeLV), simian (woolly monkey) sarcoma virus (SSV-1) and mouse mammary tumor virus (MTV). The cross-reactive antigens of the PMF virus and the MPMV are considered as evidence for the human origin of the PMF virus.     

Size of virus-specific RNA in B-34, a hamster tumor cell producing nucleic acids of type C viruses from three species.

B-34 is the designation of a hamster tumor-derived cell line induced by the Harvey sarcoma virus. This cell line produces virions which contain structural proteins common to edogenous hamster viruses and nucleic acid sequences of hamster, mouse, and rat origin. The sedimentation characteristics of the intracellular virus-specific RNA was determined in sucrose gradients after treatment with dimethylsulfoxide by molecular hybridization using complementary DNA of strict virus specificity. Hamster virus-specific RNA sedimented at 35S (major peak) as is characteristic of productive infection by type C leukemia viruses of other species. Rat virus-specific RNA sedimented at 30S which is characteristic of the sarcoma virus-related genome found in nonproducer cells transformed by Kirsten sarcoma virus. Both Harvey and Kirsten sarcoma viruses contain a related but not necessarily identical 30S rat-specific component which is also found in normal cultured rat cells. Mouse cells producing Harvey sarcoma virus also contain a rat-specific 30S RNA. Mouse virus-derived sequences also sedimented at 30S in B-34 cells and in a similar size range in Harvey virus-infected mouse cells. The possibility that the mouse and rat-derived sequences are present on a single 30S RNA species which would then be related to sarcomagenic potential is one attractive hypothesis suggested by these data.     

Production of Virus by Mammalian Cells Transformed by Rous Sarcoma and Murine Sarcoma Viruses

Cultured cells of mammalian tumors induced by ribonucleic acid (RNA)-containing oncogenic viruses were examined for production of virus. The cell lines were established from tumors induced in rats and hamsters with either Rous sarcoma virus (Schmidt-Ruppin or Bryan strains) or murine sarcoma virus (Moloney strain). When culture fluids from each of the cell lines were examined for transforming activity or production of progeny virus, none of the cell lines was found to be infectious. However, electron microscopic examination of the various cell lines revealed the presence of particles in the rat cells transformed by either Rous sarcoma virus or murine sarcoma virus. These particles, morphologically similar to those associated with murine leukemias, were found both in the extracellular fluid concentrates and in whole-cell preparations. In the latter, they were seen budding from the cell membranes or lying in the intercellular spaces. No viruslike particles were seen in preparations from hamster tumors. Exposure of the rat cells to (3)H-uridine resulted in the appearance of labeled particles with densities in sucrose gradients typical of virus (1.16 g/ml.). RNA of high molecular weight was extracted from these particles, and double-labeling experiments showed that this RNA sedimented at the same rate as RNA extracted from Rous sarcoma virus. None of the hamster cell lines gave radioactive peaks in the virus density range, and no extractable high molecular weight RNA was found. These studies suggest that the murine sarcoma virus produces an infection analogous to certain "defective" strains of Rous sarcoma virus, in that particles produced by infected cells have a low efficiency of infection. The control of the host cell over the production and properties of the RNA-containing tumorigenic viruses is discussed.     

Spontaneous Release of Endogenous Ecotropic Type C Virus from Rat Embryo Cultures

Type C viruses were isolated from embryo cultures of two different rat strains, Sprague-Dawley and Fischer. Both viruses (termed rat leukemia virus, RaLV) were released spontaneously from rat embryo cells, have a density of 1.14 to 1.15 g/cm(3) based on equilibrium sedimentation in sucrose gradients, contain 60-70S RNA, RNA-directed DNA polymerase, and rat type C virus-specific 30,000 molecular-weight-protein determinants. Molecular hybridization studies using the Sprague-Dawley RaLV 60-70S RNA show that the virus-specific nucleotide sequences are present in the DNA of rat embryos. Both Sprague-Dawley and Fischer RaLV can rescue the murine sarcoma virus genome from Kirsten murine sarcoma virus-transformed nonproducer cells and are neutralized by antisera to the RPL strain of RaLV. In contrast to previous RaLV's, these viruses propagate in their own cells of origin as well as in cells of heterologous rat strains.     

Structure of and alterations to defective murine sarcoma virus particles lacking envelope proteins and core polyprotein cleavage.

HTG2 hamster cells produce a defective murine sarcoma virus lacking gp70 and, consequently, viral surface projections (knobs), but the lack of knobs appears to have no effect on intramembrane particle distribution. In addition, it has been noted that the core of the virus remains in the "immature" form as a result of the failure of the polyprotein precursor (p65) to undergo cleavage. However, incubation of HTG2 virus with avian myoblastosis virus was found to yield specific cleavage products of p65.     

Murine Virus-Induced Proteins Synthesized by Hamster Tumor Cells Transformed by, But Not Producing, Murine Sarcoma Virus

The 8303 hamster tumor cells transformed by Moloney strain of murine sarcoma virus (M-MSV), but which do not produce virus, do contain murine virus-induced proteins. The virus-induced proteins within the cell were identified either as free proteins or in association with membranous material, including the plasma membrane. In addition, some were excreted by the 8303 hamster tumor cells into the growth medium. Most virus-induced proteins were larger than 68,000 daltons, and they did not dissociate into components of smaller size in the presence of detergent and a reducing agent. A small amount of virus-induced protein with a molecular weight of less than 20,000 was also found in the hamster tumor cells. No virus-specific proteins with the identical antigenic specificity or size of the major internal group specific antigen (molecular weight about 30,000) of the murine leukemia viruses were present in these cells. There is a common cell surface antigen present in three other tumor cell lines, both virus-producing and non-virus-producing, identical in reactivity to that of the murine virus-induced antigen of the 8303 hamster tumor cell. This antigen is not present on the cell surface of normal mouse embryo cells.     

Feline Leukaemia Viral Antigens and Antisera to the Group Specific Antigens of the Murine Leukaemia Viruses

GEERING et al.¹ reported that feline leukaemia viruses shared one of the group specific antigens of the murine leukaemia viruses, gs-3, as detected by immunoprecipitation in agar gels with broadly reactive rat antisera to the group specific antigens of the murine leukaemia viruses (MuLV). Subsequently, they found that this shared group specific antigen was also present in the hamster and rat C-type viruses². Work by Schafer³ and our own immunodiffusion⁴ and complement fixation studies have confirmed the immunological reactivity between the feline leukaemia viral antigens and broad-reacting murine leukaemia group specific antisera. We have now applied this interspecies immunological reaction between the murine and feline C-type viruses to quantitative studies of the feline leukaemia viruses. Broad-reactive murine leukaemia-sarcoma group specific antisera prepared in rats by the induction of murine sarcoma virus (MSV) tumours^{5, 6} were found to be as useful and nearly as sensitive as a feline leukaemia-sarcoma specific, group specific antiserum for the in vitro detection and assay of the noncytopathogenic feline leukaemia virus (FeLV).     

A generalized method of subcloning DNA fragments by restriction site reconstruction: application to sequencing the amino-terminal coding region of the transforming gene of Gazdar murine sarcoma virus

The technique of restriction site reconstruction was generalized so as to allow the subcloning of any DNA fragment and its subsequent reexcision with EcoRI, XbaI, XhoI or HindIII. After excision, the 3' terminus of each strand will be derived from the starting nucleic acid, permitting the use of such fragments as primers for nucleotide sequencing by primer extension methods. The technique was used to subclone a 56 base pair BstNI-DdeI fragment of Moloney murine sarcoma virus (Mo-MSV) as a unique HindIII-HindIII fragment. This fragment then served as a primer to sequence a portion of the RNA genome of Gazdar murine sarcoma virus (Gz-MSV). The nucleotide sequence which was obtained indicated that the transforming gene of Gz-MSV arose by at least two recombination events involving murine leukemia virus (MLV) and the cellular homologue c-mos. This analysis suggests that a virus indistinguishable from Mo-MSV was an intermediate in the formation of Gz-MSV.