Leukemogenicity and cell transformation mechanisms in vitro by Gross murine leukemia virus: analysis of virus subpopulations.

The leukemogenic activity of Gross murine leukemia virus adapted to rats was tested in W/Fu rats and NIH/Swiss mice. All animals infected with this virus developed thymic and nonthymic T-cell leukemia with a short latency period. It was observed that cell-free extracts from thymic lymphoma tissue of mice and rats, induced by either Gross murine leukemia virus or Gross murine leukemia virus adapted to rats, consisted of both small-plaque-forming and large-plaque-forming viruses, as determined by the XC plaque test. MCF-type virus was found in these virus complexes. Transformed cell foci were induced in SC-1 cell layers by double infection of the cloned MCF-type virus and an ecotropic virus. SC-1 cells containing transformed cell foci were shown to be tumorigenic upon inoculation into nude mice. The formation of transformed cell foci in mink lung cells was also observed after double infection with the cloned MCF-type virus and a xenotropic virus. The possible mechanism of leukemogenesis by endogenous viruses is discussed.     

Mechanism of restriction of ecotropic and xenotropic murine leukemia viruses and formation of pseudotypes between the two viruses.

Ecotropic and xenotropic murine leukemia viruses (MuLV's) constitute separate interference groups; within each group there is cross-interference, but between the groups there is no detectable interference. Interference is manifest against pseudotypes in which the vesicular stomatitis virus genome is contained within the coat of one of the murine leukemia viruses. The pseudotypes display the cell specificity of the leukemia viruses: pseudotypes with an ecotropic MuLV coat infect mouse cells but not rabbit or mink cells; pseudotypes with a xenotropic MuLV coat infect rabbit or mink cells well but mouse cells very poorly. Efficient pseudotype formation also occurs between the two MuLV classes, and both the interference patterns and the cell specificity of these pseudotypes are entirely determined by their envelope. Using these pseudotypes, ecotropic MuLV infection could be established in xenogeneic cells, and the resulting progeny could be scored by using a conventional XC cell assay. Also, xenotropic MuLV infection could be established in a mouse cell, showing that no absolute intracellular barrier against xenotropic virus growth exists in murine cells. The major barriers against both xenotropic and ecotropic MuLV therefore are cell surface barriers. Xenogeneic cells probably lack receptors for ecotropic MuLV, but murine cells may either lack receptors for xenotropic MuLV or have receptors that are blocked by endogenous expression of the glycoprotein of endogenous xenotropic MuLV.     

Cell surface expression of the env gene polyprotein of dual-tropic mink cell focus-forming murine leukemia virus.

Differences have been observed in the kinetics of processing of the env gene polyprotein of ecotropic, xenotropic, and dual-tropic mink cell focus-forming (MCF) murine leukemia virus. In pulse-chase experiments, the env gene polyprotein of the dural-tropic MCF virus exhibits a marked increase in stability relative to that of either ecotropic or xenotropic virus. A comparison of cell surface expression of env gene products of ecotropic, xenotropic, and dual-tropic MCF murine leukemia virus has been made. Only gp70 is accessible to lactoperoxidase-catalyzed radioiodination of fibroblasts infected by ecotropic or xenotropic virus, whereas both gp70 and the env gene polyprotein are expressed on the surface of dual-tropic MCF virus-infected cells.     

Characterization of infectious oncornaviruses from MOPC-460 plasmacytomas: their relation to A-type particles.

MOPC-460 mouse plasmacytoma cells produce intracellular A-type particles and extracellular oncornavirus-like particles ("myeloma-associated virus," abbreviated MAV). The genomes of these two particles are closely related. During attempts to establish infections with MOPC-460 extracellular particles, we isolated ecotropic and xenotropic infectious forms of murine leukemia virus. We have investigated the relation of these isolates to A-type particles and to MAV by nucleic acid hybridization. Using complementary DNA probes prepared from the two isolates, we found that these infectious murine leukemia viruses differ from A-type particles and from MAV. Moreover, we found that MAV is the predominant extracellular component: the ecotropic and xenotropic forms of murine leukemia virus were present at only low levels (less than 5%) in MAV preparations. Neither the SC-1 cells infected with ectropic murine leukemia virus nor the mink cells infected with xenotropic murine leukemia virus showed any A-type particles in their cytoplasm when examined by electron microscopy. Our inability to demonstrate infection by the A-type particle-related component, MAV, suggests that these may be defective.     

Analysis of integrated proviral DNA sequences with an octadecanucleotide probe designed for specific identification of spleen focus-forming virus in the mouse genome.

The Friend spleen focus-forming virus (SFFV) is an envelope gene recombinant between the ecotropic Friend murine leukemia virus and the endogenous xenotropic mink cell focus-forming retroviral sequences. We synthesized an octadecanucleotide complementary to the 3' end of the SFFV env gene designed for discriminating the SFFV proviruses from the xenotropic mink cell focus-forming virus and ecotropic exogenous or endogenous viral sequences. Under appropriate hybridization conditions this probe allowed the identification, in addition to few endogenous DNA fragments, of multiple SFFV proviruses integrated in the genome of Friend malignant cells. Therefore this probe should be of interest in further characterizing the SFFV integration sites and possibly the SFFV ancestor gene.     

Nucleotide sequence of the env-specific segment of NFS-Th-1 xenotropic murine leukemia virus.

The sequence of 863 contiguous nucleotides encompassing portions of the pol and env genes of NFS-Th-1 xenotropic proviral DNA was determined. This region of the xenotropic murine leukemia virus genome contains and env-specific segment that hybridizes exclusively to xenotropic and mink cell focus-forming but not to ecotropic proviral DNAs (C. E. Buckler et al., J. Virol. 41:228-236, 1982). The unique xenotropic env segment contained several characteristic deletions and insertions relative to the analogous region in AKR and Moloney ecotropic murine leukemia viruses. Portions of an endogenous env segment cloned from a BALB/c mouse embryo gene library that had a restriction map and hybridization properties typical of xenotropic viruses (A. S. Khan et al., J. Virol. 44:625-636, 1982) were also sequenced. The sequence of the endogenous env gene was very similar to the comparable region of the NFS-Th-1 xenotropic virus containing the characteristic deletions and insertions previously observed and could represent a segment of an endogenous xenotropic provirus.     

Association of endogenous retroviruses with radiation-induced leukemias of BALB/c mice.

X-irradiation of BALB/c mice in the second month of life induced a high incidence of generalized lymphatic leukemia of T-cell origin, beginning at 7 months of age. Infectious ecotropic murine leukemia virus (B-tropic predominant over N-tropic) was isolable from all tumor extracts but exhibited a wide titer range among individual leukemias. Detection of infectious xenotropic virus usually required extensive amplification on indicator cells. Dual-tropic (mink cell focus-forming) virus has not been found in the leukemias. Expression of ecotropic virus in tail extracts prepared at 6.5 months of age, although greatly enhanced compared with unirradiated controls, was not found to be prognostic of tumor development in individual mice. We conclude that leukemogenesis does not show a simple dependence on infectious murine leukemia virus expression in these mice.     

Comparison of the restriction endonuclease maps of unintegrated proviral DNAs from four xenotropic murine leukemia viruses.

From purified linear and superhelical DNAs, the restriction endonuclease maps of four xenotropic murine leukemia virus DNAs from NFS, NZB, BALB/c, and AKR mice were determined with ten restriction endonucleases. Each xenotropic proviral DNA was found to be a unique restriction endonuclease map, with differences in the gag, pol, env, and terminal repeated sequence regions. However, type-specific SacI and EcoRI sites in the env region were identical in all four xenotropic murine leukemia virus DNAs and were not found in ecotropic murine leukemia virus DNA. Comparison of the xenotropic murine leukemia virus DNA maps with maps of ecotropic murine leukemia virus DNA showed that the pol and terminal repeated sequence regions were highly conserved. Other similarities in ecotropic and some xenotropic viral DNAs suggest common origins.     

Susceptibility of wild mouse cells to exogenous infection with xenotropic leukemia viruses: control by a single dominant locus on chromosome 1.

Although xenotropic murine leukemia viruses cannot productively infect cells of laboratory mice, cells from various wild-derived mice can support replication of these viruses. Although the virus-sensitive wild mice generally lack all or most of the xenotropic proviral genes characteristic of inbred strains, susceptibility to exogenous infection is unrelated to inheritance of these sequences. Instead, susceptibility is controlled by a single dominant gene, designated Sxv, which maps to chromosome 1. Sxv is closely linked to, but distinct from Bxv-1, the major locus for induction of xenotropic murine leukemia viruses in laboratory mice. Genetic experiments designed to characterize Sxv show that this gene also controls sensitivity to a wild mouse virus with the interference properties of mink cell focus-forming murine leukemia viruses, and that Sxv-mediated susceptibility to xenotropic murine leukemia viruses is restricted by the mink cell focus-forming virus resistance gene Rmcf. These data, together with genetic mapping of the mink cell focus-forming virus cell surface receptor locus to this same region of chromosome 1, suggest that Sxv may encode a wild mouse variant of the mink cell focus-forming virus receptor that allows penetration by xenotropic murine leukemia viruses.     

Evidence the pp60src, the product of the Rous sarcoma virus src gene, undergoes autophosphorylation.

F/St mice are unique in producing high levels of both ecotropic and xenotropic murine leukemia virus. The high ecotropic virus phenotype is determined by three or more V (virus-inducing) loci. A single locus for inducibility of xenotropic murine leukemia virus was mapped to chromosome 1 close to, but possibly not allelic to, Bxv-1. Although the high ecotropic virus phenotype is phenotypically dominant, the high xenotropic virus phenotype was recessive in all crosses tested. Suppression of xenotropic murine leukemia virus is governed by a single gene which is not linked to the xenotropic V locus.     

Induction of GIX antigen and gross cell surface antigen after infection by ecotropic and xenotropic murine leukemia viruses in vitro.

A number of ecotropic and xenotropic murine leukemia viruses were examined for their ability to induce the GIX antigen and Gross cell surface antigen (GCSA) in tissue culture fibroblasts. GIX appears to be a constituent of murine leukemia virus gp70; a molecular characterization of GCSA has not yet been reported. Antigen induction was measured by the ability of productively infected cells to absorb cytotoxic activity from the standard GIX- and GCSA-typing antisera. Cells infected by ecotropic viruses displayed four distinct phenotypes GIX:+/GCSA++, GIX-/GCSA++, GIX++/GCSA+, and GIX-/GSCA+; cells infected by xenotropic viruses were either GIX-/GCSA+ or GIX-/GCSA-. GIX induction appeared to be a type-specific property of some but not all Gross-AKR type ecotropic viruses. Differences in the degree of absorption of the GCSA antiserum by ecotropic virus- and xenotropic virus-infected cells indicated that GCSA may comprise multiple antigenic determinants.     

Envelope and long terminal repeat sequences of a cloned infectious NZB xenotropic murine leukemia virus

An infectious NZB xenotropic murine leukemia virus (MuLV) provirus (NZB was molecularly cloned from the Hirt supernatant of NZB-IU-6-infected mink cells, and the nucleotide sequence of its env gene and long terminal repeat (LTR) was determined. The partial nucleotide sequence previously reported for the env gene of NFS-Th-1 xenotropic proviral DNA (Repaske, et al., J. Virol. 46:204-211, 1983) is identical to that of the infectious NZB xenotropic MuLV DNA reported here. Alignment of nucleotide or deduced amino acid sequences, or both, of xenotropic, mink cell focus-forming, and ecotropic MuLV proviral DNAs in the env region identified sequence differences among the three host range classes of C-type MuLVs. Major differences were confined to the 5' half of env; a high degree of homology was found among the three classes of MuLVs in the 3' half of env. Alignment of the nucleotide sequence of the LTR of NZB xenotropic MuLV with those of the LTRs of NFS-Th-1 xenotropic, mink cell focus-forming, and ecotropic MuLVs revealed extensive homology between the LTRs of xenotropic and MCF247 MuLVs. An inserted 6-base-pair repeat 5' to the TATA box was a unique feature of both NZB and NFS-Th-1 xenotropic LTRs.     

The co-carcinogenic activity of 4-nitropyridine-1-oxide (4-NPO) and prevention of transformation by type-specific anti-viral antibodies.

Fischer rat embryo cells chronically infected with Rauscher murine leukemia virus, and known to be sensitive to transformation by potent chemical carcinogens, were transformed by the weak carcinogen 4-nitropyridine-1-oxide. Transformed cells grew in semi-solid agar and produced tumors in newborn Fischer rats. Transformation was inhibited by antisera specific for the ecotropic Rauscher murine leukemia virus, but not by antisera of equal toxicity specific for xenotropic Swiss mouse AT-124 virus.     

Biological, Chemical, and Immunological Studies of Rauscher Ecotropic and Mink Cell Focus-Forming Viruses from JLS-V9 Cells

Two murine leukemia viruses were isolated from JLS-V9 cells which had been infected with Rauscher plasma virus. One virus was XC positive and failed to grow on mink or cat cells and thus was an ecotropic virus. The other virus formed cytopathic foci on mink cells, was XC negative, and fell into the mink cell focus-forming (MCF) viral interference group and was thus an MCF virus. The glycoproteins of the two viruses could be distinguished immunologically, by peptide mapping, and by size in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The MCF virus produced gp69, and the ecotropic virus produced gp71, explaining the origin of the heterogeneous glycoprotein (gp69 and gp71) of Rauscher leukemia virus. Amino-terminal sequences of gp69 and gp71 were determined. The MCF sequence was distinct from the ecotropic sequence, but retained partial homology to it. The data show that the glycoproteins are encoded by related yet distinct genes. The protein structural data support the proposal that MCF virus gp70 molecules have nonecotropic sequences at the amino terminus, with ecotropic sequences occurring at the 3' end of the gene. The Rauscher MCF virus glycoprotein lacks a glycosylation site found at position 12 of the ecotropic sequence.     

Genetic analysis of myeloproliferative leukemia virus, a novel acute leukemogenic replication-defective retrovirus.

The myeloproliferative leukemia virus (MPLV) is a new acute leukemogenic, nonsarcomatogenic retroviral complex that is generated during the in vivo passage of a molecularly cloned Friend ecotropic helper virus. Examination of viral RNA expression in MPLV-producing cells revealed the presence of two distinct molecular species that hybridized with a long terminal repeat or an ecotropic env-specific probe but not with a xenotropic mink cell focus-forming virus env-specific probe derived from a spleen focus-forming virus: an 8.2-kilobase species corresponding to a full-length Friend murine leukemia virus (F-MuLV) and a deleted species with a genomic size of 7.4 kilobases. This deleted virus was biologically cloned by limiting dilutions and single cell cloning in Mus dunni fibroblasts. Three nonproducer clones with normal morphologies and containing one single integrated copy of the deleted virus were superinfected with F-MuLV, Moloney murine leukemia virus, Gross murine leukemia virus, mink cell focus-forming virus (HIX), or the amphotropic 1504 murine leukemia virus. All pseudotypes caused macroscopic and microscopic abnormalities in mice that were similar to those seen in the parental stock. A comparison of the physical maps of F-MuLV and MPLV, which was deduced from the restriction enzyme digests of unintegrated proviral DNAs, indicated that the MPLV-defective genome (i) is probably derived from F-MuLV, (ii) has conserved the F-MuLV gag and pol regions, and (iii) is deleted and rearranged in the env region in a manner that is clearly distinct from that of Friend or Rauscher spleen focus-forming 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.     

Biochemical characterization of cells transformed via transfection by feline sarcoma virus proviral DNA.

Murine fibroblasts transformed by transfection with DNA from mink cells infected with the Snyder-Theilen strain of feline sarcoma virus and subgroup B feline leukemia virus were analyzed for the presence of integrated proviral DNA and the expression of feline leukemia virus- and feline sarcoma virus-specific proteins. The transformed murine cells harbored at least one intact feline sarcoma virus provirus, but did not contain feline leukemia virus provirus. The transformed murine cells expressed an 85,000-dalton protein that was precipitated by antisera directed against feline leukemia virus p12, p15, and p30 proteins. No feline oncornavirus-associated cell membrane antigen reactivity was detected on the surfaces of the transformed murine cells by indirect membrane immunofluorescence techniques. The 85,000-dalton feline sarcoma virus-specific protein was also found in feline cells transformed by transfection. However, these cells also contained env gene products. The results of this study demonstrate that the feline sarcoma virus genome is sufficient to transform murine cells and that expression of the 85,000-dalton gag-x protein is associated with transformation of both murine and feline cells transformed by transfection.     

Isolation and Characterization of Mink Cell Focus-Inducing Murine Leukemia Viruses with Xenotropic Host Range from Mouse Strain SL

A new type of mink cell focus-inducing virus was persistently isolated from the leukemic tissues of SL mice. In contrast to the dual tropic mink cell focus-inducing viruses reported to date, the new virus has the host range of the xenotropic murine leukemia virus. Analysis of RNase T(1) fingerprints of genomic RNAs suggested that the mink cell focus-inducing virus with the xenotropic host range isolated from SL mice is a recombinant virus deriving from xenotropic murine leukemia virus.     

Replication of Radiation-Induced Murine Leukemia Virus in Normal and Transformed Mouse Cells

Autonomous radiation-induced leukemia virus (RadLV) replication could be detected in mouse 3T3 cells by the development of interference with murine sarcoma virus (MSV), the appearance of covert helper activity for defective MSV, and by the induction of cytopathic effect type foci in MSV-transformed, leukemia virus-negative (S+L-) cells. A chronic infection of either 3T3 or S+L- cells with RadLV could be established. Both RadLV infectivity and helper activity were demonstrated in the same peak at a buoyant density of 1.16 g/cm(3). Additionally a soluble inhibitor of MSV focus formation was found which could be separated from infectious RadLV. Examination of cell clones derived from chronically infected 3T3 cells showed that essentially every cell was infected and produced both infectious RadLV and low levels of inhibitor. Quantitative comparisons of autonomously replicating RadLV in normal 3T3 and S+L- cells suggested that RadLV may consist of several populations of virus of varying replicative potential. Apparently 99% of RadLV can be assayed only as helper units in normal cells or as replicative units in S+L- cells. To explain the atypical results, a model for RadLV deficiency is proposed.