Spleen focus-forming Friend virus: identification of genomic RNA and its relationship to helper virus RNA

Isolation of replicative forms of 3' terminal subgenomic RNAs of tobacco necrosis virus

Three double-stranded RNAs of molecular weights 2.6 x 10(6), 1.05 x 10(6), and 0.94 x 10(6) are found to be synthesized during TNV infection of tobacco leaves. These double-stranded RNAs, isolated by LiCl fractionation and polyacrylamide gel electrophoresis, have been studied using RNA-RNA hybridization and RNase T(1)-resistant oligonucleotide finger-printing techniques. By these methods all three double-stranded RNAs are shown to be viral in origin and the smaller double-stranded RNA subsets of the larger RNAs. RNase T(1) oligonucleotide mapping of the viral RNA shows that both smaller double-stranded RNAs are derived from the 3' end of the viral genome. The possible role of these small double-stranded RNAs as replicative forms for mRNA synthesis and the organization and expression of the TNV genome is discussed.

Characterization of a novel murine retrovirus mixture that facilitates hematopoiesis

A new virus previously arose in BALB/c females mated repeatedly to C57BL/6 (B6) males and then injected with fixed, activated B6 male spleen cells (V. S. Ter-Grigorov, O. Krifuks, E. Liubashevsky, A. Nyska, Z. Trainin, and V. Toder, Nat. Med. 3:37-41, 1997). In the present study, BALB/cJ mice inoculated with virus-containing plasma from affected mice developed splenomegaly, which was caused by increased numbers of Sca-1(+) Lin(-) hematopoietic stem cells (HSC) and their differentiated progeny. Biological and molecular analyses of a new virus revealed a mixture of murine leukemia viruses (MuLVs). These MuLVs comprised ecotropic and mink lung cell focus-forming (MCF) virus classes and are termed Rauscher-like MuLVs because they bear numerous similarities to the ecotropic and MCF viruses of the Rauscher MuLV complex but do not include a spleen focus-forming virus. The ecotropic virus component alone transferred some disease characteristics, while MCF virus alone did not. Thus, we have described a novel virus mixture, termed Rauscher-like MuLV, that causes an increase in hematopoiesis due to activation of pluripotent HSC. Experiments using mice and a protocol that replicated the pregnancy and immunization strategy of the original experiment demonstrated that endogenous BALB/c mouse ecotropic and xenotropic MuLVs are activated by these treatments. Emv1 was expressed in the spleens of multiparous mice but not in those of virgin mice, and Bxv1Emv1-pseudotyped MuLVs were recovered following injection of fixed, activated B6 cells. Thus, multiple pregnancies and allostimuli appear to have provided the signals required for activation of and recombination among endogenous viruses and could have resulted in generation of the Rauscher-like MuLV mixture.

A multistep process of leukemogenesis in Moloney murine leukemia virus-infected mice that is modulated by retroviral pseudotyping and interference

Mixed retroviral infections frequently exhibit pseudotyping, in which the genome of one virus is packaged in a virion containing SU proteins encoded by another virus. Infection of mice by Moloney murine leukemia virus (M-MuLV), which induces lymphocytic leukemia, results in a mixed viral infection composed of the inoculated ecotropic M-MuLV and polytropic MuLVs generated by recombination of M-MuLV with endogenous retroviral sequences. In this report, we describe pseudotyping which occurred among the polytropic and ecotropic MuLVs in M-MuLV-infected mice. Infectious center assays of polytropic MuLVs released from splenocytes or thymocytes of infected mice revealed that polytropic MuLVs were extensively pseudotyped within ecotropic virions. Late in the preleukemic stage, a dramatic change in the extent of pseudotyping occurred in thymuses. Starting at about 5 weeks, there was an abrupt increase in the number of thymocytes that released nonpseudotyped polytropic viruses. A parallel increase in thymocytes that released ecotropic M-MuLV packaged within polytropic virions was also observed. Analyses of the clonality of preleukemic thymuses and thymomas suggested that the change in pseudotyping characteristics was not the result of the emergence of tumor cells. Examination of mice infected with M-MuLV, Friend erythroleukemia virus, and a Friend erythroleukemia virus-M-MuLV chimeric virus suggested that the appearance of polytropic virions late in the preleukemic stage correlated with the induction of lymphocytic leukemia. We discuss different ways in which pseudotypic mixing may facilitate leukemogenesis, including a model in which the kinetics of thymic infection, modulated by pseudotyping and viral interference, facilitates a stepwise mechanism of leukemogenesis.

Loss of pathogenicity of spleen focus-forming virus after pseudotyping with Akv

Friend virus complex (FV), which comprises replication-competent Friend murine leukemia virus (FMuLV) plus replication-defective spleen focus-forming virus (SFFV), induces a multistage erythroleukemia. We have examined the role of replication-competent helper virus in the early and late stages of FV disease by replacing FMuLV, the native helper, with Akv, the endogenous ecotropic MuLV of AKR mice. SFFVP/FRE, an established fibroblast line nonproductively infected with the polycythemic strain of SFFV, was superinfected with FMuLV or with Akv. Although supernatants from these cells showed similar titers in the XC plaque assay, supernatants from Akv-infected SFFVP/FRE cells showed 100- to 5,000-fold less activity than did those from FMuLV-infected cells with respect to spleen focus induction in vivo. Since virions isolated from these two supernatants contained similar ratios of SFFV to helper virus genomic RNA, it did not appear that the difference was due to a relative inability of Akv to package SFFV. Although FMuLV- and Akv-rescued SFFV are equally infectious in a mouse fibroblast cell line (NIH 3T3), FMuLV-rescued SFFV was far more efficient in inducing erythroid bursts in cultured primary bone marrow cells. Adding Akv to preparations of FMuLV-rescued SFFV did not significantly interfere with burst induction. Helper-free SFFV induced 50- to 500-fold more spleen foci when coinjected with FMuLV than it did with Akv. Helper virus also affected mortality rates that reflect the late stage of the disease. When FMuLV- or Akv-rescued SFFV was injected into NIH Swiss mice at dosage levels adjusted to give equal numbers of spleen foci, all mice receiving FMuLV-rescued SFFV developed splenomegaly and died, whereas no mice receiving Akv-rescued SFFV died or developed detectable splenomegaly. When FMuLV was coinjected with Akv-rescued SFFV, the mortality rate rose from 0 to 100%. Injection of helper-free SFFV alone did not induce mortality, but coinjection of helper-free SFFV with FMuLV resulted in 100% mortality. Thus, the helper virus used to rescue SFFV plays at least a quantitatively important role in the early stage of FV disease and a crucial role in the late stage of the disease in vivo.

Role of the host immune response in selection of equine infectious anemia virus variants

Equine infectious anemia virus was isolated from peripheral blood leukocytes collected during two early febrile cycles of an experimentally infected horse. RNase T1-resistant oligonucleotide fingerprint analyses indicated that the nucleotide sequences of the isolates differed by approximately 0.25% and that the differences appeared randomly distributed throughout the genome. Serum collected in the interval between virus isolations was able to distinguish the isolates by membrane immunofluorescence on live cells. However, no neutralizing antibody was detected in the interval between virus isolations. In fact, multiple clinical cycles occurred before the development of a neutralizing antibody response, indicating that viral neutralization might not be the mechanism for selection of antigenic variants. The ability of early immune sera to recognize variant specific antigens on the surface of infected cells suggested that immune selection occurs through recognition and elimination of certain virus-infected cells. Alternately, the random distribution of the genomic differences observed between the two isolates may indicate that equine infectious anemia virus variants emerge as a result of nonimmunological selection processes.

Friend virus-specific cytotoxic T lymphocytes recognize both gag and env gene-encoded specificities

We have constructed a series of "synthetic" target cell lines for an analysis of the specificity of anti-Friend virus (FV) CTL. Our results show that murine H-2 genes and individual retroviral genes can be stable expressed in Fisher rat embryo (FRE) cells, and that their products have the potential to form target structures recognized by mouse CTL. Cells expressing H-2Db and either the env or gag genes of one component of FV, helper Friend murine leukemia virus (FMuLV), were lysed by anti-FV CTL and by CTL generated against FMuLV alone. Experiments with Db-transfected FRE clones infected only with the replication-defective spleen focus-forming virus (SFFV) component of FV indicate that the SFFV genome also provides specificities recognized by both anti-FV and anti-FMuLV CTL, thus demonstrating the existence of a crossreactive CTL population. An unexpected finding was that anti-FMuLV CTL, but not anti-FV CTL were also able to lyse FRE clones that expressed H-2Kb in either the presence or absence of FV. The use of heterologous cell lines for the construction of synthetic target cells thus offers a useful approach for the analysis of T cell specificity.

The pathophysiology of murine retrovirus-induced leukemias

Murine leukemia viruses (MuLVs) are retroviruses which induce a broad spectrum of hematopoietic malignancies. In contrast to the acutely transforming retroviruses, MuLVs do not contain transduced cellular genes, or oncogenes. Nonetheless, MuLVs can cause leukemias quickly (4 to 6 weeks) and efficiently (up to 100% incidence) in susceptible strains of mice. The molecular basis of MuLV-induced leukemia is not clear. However, the contribution of individual viral genes to leukemogenesis can be assayed by creating novel viruses in vitro using recombinant DNA techniques. These genetically engineered viruses are tested in vivo for their ability to cause leukemia. Leukemogenic MuLVs possess genetic sequences which are not found in nonleukemogenic viruses. These sequences control the histologic type, incidence, and latency of disease induced by individual MuL Vs.

Different murine cell lines manifest unique patterns of interference to superinfection by murine leukemia viruses

Interference to superinfection by murine leukemia viruses (MuLV) was analyzed in cells chronically infected with other MuLVs. A new sensitive focal immunofluorescence assay employing monoclonal antibodies was used to detect foci of virus infection in live cell monolayers. Monoclonal antibodies were chosen which reacted with the challenge virus but not with the interfering virus. The results obtained confirmed some of the findings of previous workers using Moloney sarcoma virus pseudotypes as challenge viruses on mouse and nonmouse cells. In addition, SC-1 mouse cells nonproductively infected with defective spleen focus-forming virus were found to be resistant to superinfection by recombinant dual-tropic viruses. Furthermore, results indicated that interference patterns between some pairs of viruses differed in different cell types. Thus, xenotropic MuLV blocked superinfection by recombinant dual-tropic viruses in SC-1 feral mouse cells, but not in two lines of NZB mouse cells. Also, in a Mus dunii tail fibroblast cell line some unique patterns of interference were observed. One ecotropic MuLV blocked infection by two xenotropic viruses and three recombinant dual-tropic viruses. Two other ecotropic viruses blocked infection by only one of the two xenotropic viruses tested. These two ecotropic viruses also differed from each other in their ability to block the three recombinant viruses. In addition, two strains of amphotropic MuLV also differed in their interference capacity. As expected, strain 1504A did not block any viruses tested, whereas strain 4070A surprisingly blocked one xenotropic and one ecotropic MuLV. The lack of homogeneity in interference patterns seen in the Mus dunii cells suggested either that a large number of heterogeneous virus receptors were present on this cell line or that interference in these cells might operate through a mechanism other than blocking of virus receptors by the envelope protein of the interfering virus.

Generation of mink cell focus-forming viruses by Friend murine leukemia virus: recombination with specific endogenous proviral sequences

A family of recombinant mink cell focus-forming viruses (MCF) was derived by inoculation of NFS mice with a Friend murine leukemia virus, and their genomes were analyzed by RNase T1-resistant oligonucleotide fingerprinting. The viruses were obtained from the thymuses and spleens of preleukemic and leukemic animals and were evaluated for dualtropism and oncogenicity. All these isolates induced cytopathic foci on mink cells but could be classified into two groups based on their relative infectivities for SC-1 (mouse) or mink (ATCC CCL64) cells. One group of Friend MCFs (F-MCFs) (group I) exhibited approximately equal infectivities for SC-1 and mink cells, whereas a second group (group II) infected mink cells 1,000- to 10,000-fold more efficiently than SC-1 cells. Structural analyses of the F-MCFs revealed that group I and group II viruses correlated with recombination of Friend murine leukemia virus with two distinct, but closely related, endogenous NFS proviral sequences. No correlation was found between the type of F-MCF and the tissue of origin or the disease state of the animal. Furthermore, none of the F-MCF isolates were found to be oncogenic in NFS/N or AKR/J mice. F-MCFs of both groups underwent extensive substitution of ecotropic sequences, involving much of the gag and env genes of group I F-MCFs and most of the gag, pol, and env genes of group II F-MCFs. All F-MCF isolates retained the 3' terminal U3 region of Friend murine leukemia virus. Comparison of the RNAs of the F-MCFs with RNAs of MCFs derived from NFS.Akv-1 or NFS.Akv-2 mice indicated that the F-MCFs were derived from NFS proviral sequences which are distinct from the sequences contained in NFS.Akv MCF isolates. This result suggested that recombination with particular endogenous proviral sequences to generate MCFs may be highly specific for a given murine leukemia virus.

Tripartite structure of the avian erythroblastosis virus E26 transforming gene

Only two avian oncogenic viruses specifically cause acute leukaemias yet do not transform chicken fibroblasts in culture: E26, which causes erythroblastosis and a low level of concomitant myeloblastosis in chickens, and avian myeloblastosis virus (AMV), which causes myeloblastosis exclusively. Both viruses are replication-defective and share a sequence termed myb (also known as amv) which is unrelated to essential virion genes and is therefore thought to be part of the transforming onc genes of these viruses. However, the genetic structure of the two viruses differs. E26 has a genomic RNA of 5.7 kilobases (kb) and encodes a 135,000 molecular weight gag-related protein (p135) with probable transforming function. We show here by in vitro translation that the 5.7-kb E26 RNA directs the synthesis of p135. Oligonucleotide analysis indicates that E26 RNA contains an internal 0.8-kb subset of the 1.2-kb AMV-related sequence (mybA), termed mybE. A 2.46-kb molecular clone prepared from cDNA transcribed in vitro from E26 RNA contained an E26 transformation-specific (ets) sequence flanked by mybE and an env-related sequence. A complete DNA sequence of this clone indicates that the 1.5-kb ets sequence extends the open reading frame of mybE for 491 amino acids. Thus, the p135 gene of E26 is a genetic hybrid of three distinct elements, approximately 1.2 kb derived from the 5' region of the retroviral gag gene, mybE and the ets sequence, linked in the order 5'-delta gag-mybE-ets-3'. The myeloid leukaemogenicity shared by E26 and AMV correlates with the common myb sequence, while the distinct erythroid leukaemogenicity of E26 correlates with ets and the E26-specific linkage of myb to delta gag.

An immunological focus assay for murine leukemia viruses on viable attached cell lines

An assay is described for the detection and isolation of murine leukemia virus (MuLV)-infected cells in viable monolayers. The procedure utilizes antisera or monoclonal antibodies which specifically bind cell surface viral antigens of infected cells. Bound antibodies are subsequently detected by binding with 125I-labeled Staphylococcus aureus protein A followed by autoradiography of the tissue culture vessel. Focal areas of infection can be identified from the autoradiograph and infected cells can subsequently be isolated and subcultured as MuLV-producing cell lines. With appropriate antibodies the procedure should be useful for the direct isolation of minor components, including mutants, in complex virus mixtures.

Envelope gene of the Friend spleen focus-forming virus: deletion and insertions in 3' gp70/p15E-encoding region have resulted in unique features in the primary structure of its protein product

A nucleotide sequence was determined for the envelope (env) gene of the polycythemia-inducing strain of the acute leukemia-inducing Friend spleen focus-forming virus (SFFV) and from this the amino acid sequence of its gene product, gp52, was deduced. All major elements of the gene were found to be related to genes of other retroviruses that code for functional glycoproteins. Although the carboxyl terminus of gp52 is encoded by sequences highly related to sequences in its putative parent, ecotropic Friend murine leukemia virus, the majority of the protein (69%), including the amino terminus, is encoded by dualtropic virus-like sequences. Nucleotide sequence comparisons suggest that the nonecotropic region may be more closely related to the 5' substitution in dualtropic mink cell focus-inducing viruses that it is to the 5' end of xenotropic virus env genes. A large deletion and two unique insertions have been located in the env gene of polycythemia-inducing SFFV and may account for some of the unusual structural characteristics, aberrant processing, and pathogenic properties of gp52. As a consequence of the deletion, amino-terminal gp70 and carboxyl-terminal p15E-encoding sequences are juxtaposed and it appears that translation from the p15E region, 3' to the deletion, continues in the standard reading frame used by other retroviruses. Insertions of six base pairs and one base pair at the very 3' end of the gp52-encoding region results in a SFFV-unique amino acid sequence and a premature termination codon.

Complete nucleotide sequence of the gene for the specific glycoprotein (gp55) of Friend spleen focus-forming virus

The complete nucleotide sequence of the gene for the specific glycoprotein (gp55) of the polycythemic strain of Friend spleen focus-forming virus (SFFV) was derived from the cloned SFFV DNA intermediate. The gp55 gene is present within 1.4 kilobases of the 5' side of the 3'long terminal repeat sequence. The open reading frame predicts the primary translation product has a total of 409 amino acids with a Mr of 44,752. Comparisons of the deduced amino acid sequence of gp55 with those of the envelope (env) gene products of murine leukemia viruses (MuLVs) revealed that gp55 is composed of three distinct regions. The amino-terminal 80% of the molecule has a high degree of sequence homology with the amino-terminal portion of the gp70 of the Moloney mink cell focus-forming virus (BALB/Mo-MCFV). This portion of the BALB/Mo-MCFV gp70 is known to be coded for by the acquired xenotropic env-like sequence. The sequence of the following 66 amino acids of gp55 is highly homologous to that of the middle portion of the p15E of Moloney MuLV (Mo-MuLV). The sequence of the Carboxyl-terminal 12 amino acids is specific to gp55 and a comparison of the nucleotide sequence showed that this specific amino acid sequence is due to the presence of seven extra nucleotides compared with the sequence of the Mo-MuLV.

Characterization of monoclonal antibodies reactive with murine leukemia viruses: use in analysis of strains of friend MCF and Friend ecotropic murine leukemia virus

Sixteen mouse and rat monoclonal antibodies reactive with gag or env proteins of Friend murine leukemia virus (F-MuLV) or recombinant MCF viruses related to F-MuLV were derived. Specificity of these was determined by immunofluorescence, immunoprecipitation, and reactivity with viral proteins blotted onto nitrocellulose paper. Seven antibodies reacted with envelope protein antigens of certain nonecotropic viruses only. Nine antibodies reacted with both ecotropic and nonecotropic viruses. Of this latter group, three were antienvelope, four were anti-p15, one was anti-p12, and one was anti-p30 in specificity. When tested as a panel against 10 strains of F-MuLV, these antibodies could distinguish seven different antigenic patterns. However, all 10 strains retained reactivity for three anti-gp70 antibodies uniquely specific for Friend and Rauscher MuLVs. Our antibody panel could also identify MCF viruses isolated from mice neonatally inoculated with F-MuLV as recombinants related to a particular F-MuLV strain based on identity of p15 gag antigenic profiles. However, recombinant viruses lacked several envelope antigens always associated with F-MuLV and instead had new envelope reactivities. These anti-MCF monoclonal antibodies detected no shared envelope antigens between MCF and xenotropic viruses isolated from mice inoculated with F-MuLV, however many of them did react with MCF viruses derived from AKR mice and NFS mice congenic for endogenous ecotropic virus loci.

Glycosylation and intracellular transport of spleen focus-forming virus glycoproteins

We have investigated the pattern of glycosylation of the membrane glycoproteins encoded by a polycythemic strain of spleen focus-forming virus (SFFV). These include a major species designated gp52 and its processed form which is designated gp65. The SFFV glycoproteins were found to be predominantly intracellular, although a portion of gp65 is expressed on the cell surface. gp65 was observed to be highly sialylated and resistant to digestion with endoglycosidase-H (endo-H). In contrast, gp52 was endo-H sensitive and the polyacrylamide gel electrophoresis profile of the endo-H digests suggested the presence of four glycosylation sites. Analysis of tryptic glycopeptides from gp52 by reverse-phase high-performance liquid chromatography also suggested the presence of four glycosylation sites. Glycopeptide analysis of Pronase digests of gp52 revealed two major size classes with molecular weights of 2200 and 1500, which correspond to two of the four oligosaccharide size classes reported previously for MuLV gp70's (M.C. Kemp, N.G. Famulari, P.V. O'Donnell, and R.W. Compans, 1980, J. Virol. 34, 154). Both glycopeptide size classes were sensitive to digestion with endo-H. The glycopeptide profile of gp65 was found to be very heterogeneous and the predominant form was a 2900-dalton size class. In addition a fucosyl glycopeptide of 2500 daltons was observed in gp65, but not in F-MuLV or F-MCF glycoproteins. In the presence of the sodium ionophore monensin, the processing of gp52 to gp65 was inhibited. Instead a smaller protein of about 60,000 daltons was observed, which did not arrive at the cell surface, a situation analogous to the processing and post-translational modification reported for gp52 from anemic isolates of SFFV (S.K. Ruscetti, J.A. Field, and E.M. Scolnick, 1981, Nature (London) 294, 663).

Abelson murine leukemia virus: effect of helper virus from regressing Friend virus on leukemia development

Replication defective Abelson murine leukemia virus (A-MuLV) induces a non-thymic lymphoma in vivo and transforms both hematopoietic and fibroblastic cells in vitro. In vivo leukemogenicity and the efficiency of in vitro transformation of hematopoietic cells by A-MuLV are known to be affected by the replication competent helper virus present in A-MuLV stocks. The helper virus isolated from the regressing strain of Friend virus (RF-MuLV) is responsible for the spontaneous regression of erythroleukemia induced by replication defective spleen-focus forming virus and itself induces a lymphocytic leukemia which spontaneously regresses. The diseases produced by A-MuLV stocks containing either RF-MuLV or Moloney leukemia virus, the helper virus associated with the original isolate of A-MuLV, were compared to determine if RF-MuLV can influence the disease produced by a replication defective virus with a discrete transforming gene. Both virus stocks induced leukemias with similar efficiency and gross pathology. Spontaneous regression was not observed when RF-MuLV was used as the helper virus. Examination of the leukemic cells and cell lines derived from leukemic tissues indicated that the target cell for A-MuLV transformation was not affected by the helper virus. Both transformed lymphoid and monocytic cells were cultured from leukemic tissues and established as cell lines. The lymphoid cells were phenotypically similar to pre-B cells or null cells, while the monocytic cell lines resemble promonocytes. The frequency with which promonocytic cell lines were isolated from leukemic mice suggests that A-MuLV leukemogenesis may often involve transformation of monocytic series cells as well as lymphoid cells. Thus, RF-MuLV can serve as an efficient helper virus for A-MuLV and does not appear to alter the in vivo target cell for transformation. It is unable, however, to alter the progressive course of Abelson virus induced disease.

Monoclonal antibody to spleen focus-forming virus-encoded gp52 provides a probe for the amino-terminal region of retroviral envelope proteins that confers dual tropism and xenotropism

Monoclonal antibodies which recognize a region common to Friend spleen focus-forming virus encoded gp52 and Friend mink cell focus-inducing viral gp70 were isolated. One such antibody from hybridoma 7C10 was tested extensively in immune precipitation and was found to react with a determinant on envelope gp70s of all mink cell focus-inducing, xenotropic, and amphotropic mouse retroviruses tested, but not with envelope gp70s of ecotropic viruses, including Friend, Moloney, and AKR murine leukemia viruses. Monoclonal antibody from hybridoma 7C10 precipitated a 23,000-molecular-weight fragment, derived by V8 protease digestion of Friend mink cell focus-inducing gp70. This 23,000-molecular-weight peptide was determined to derive from the amino terminus of the molecule. These results correlate well with other genetic data which indicate that endogenously acquired sequences of mink cell focus-inducing viruses are found at the 5' end of the envelope gene.

Envelope gene sequences which encode the gp52 protein of spleen focus-forming virus are required for the induction of erythroid cell proliferation

A series of insertion-deletion mutants was constructed in a molecularly cloned DNA copy of the Friend strain of spleen focus-forming virus (SFFV). The mutants were produced by inserting a synthetic oligonucleotide linker containing the recognition sequence of SalI endonuclease into several different locations of the SFFV DNA. Three classes of mutants were isolated: insertion-deletion mutants in the 5' half of the SFFV genome, in the long terminal repeat of the SFFV genome, and in the env gene of the SFFV genome. The env gene mutant has a deletion of sequences shared in common between the env gene of SFFV and the env genes of mink cell focus-inducing murine leukemia viruses. From analyses of the biological activity of the various mutants and a biologically active subgenomic SFFV DNA fragment described herein, we can deduce that the coding sequence encompassing the env gene of SFFV is required for the biological activity. This region, required for the pathogenic phenotype, cannot be larger than 1.5 kilobase pairs, a size only slightly more than that sufficient to encode the nonglycosylated precursor of the gp52 env gene product.

Isolation of a transformation-defective deletion mutant of Moloney murine sarcoma virus

A transformation-defective (td) deletion mutant of Moloney murine sarcoma virus (td Mo-MSV) and a transforming component termed Mo-MSV 3 were cloned from a stock of clone 3 Mo-MSV. To define the defect of the transforming function, the RNA of td Mo-MSV was compared with those of Mo-MSV 3 and of another transforming variant termed Mo-MSV 124 and with helper Moloney murine leukemia virus (Mo-MuLV). The RNA monomers of td Mo-MSV and Mo-MSV 3 comigrated on polyacrylamide gels and were estimated to be 4.8 kilobases (kb) in length. In agreement with previous analyses, the RNA of Mo-MSV 124 measured 5.5 kb and that of Mo-MuLV measured 8.5 kb. The interrelationships among the viral RNAs were studied by fingerprinting and mapping of RNase T(1)-resistant oligonucleotides (T(1)-oligonucleotides) and by identification of T(1)-oligonucleotides present in hybrids formed by a given viral RNA with cDNA's made from another virus. The nontransforming td Mo-MSV RNA lacked most of the Mo-MSV-specific sequence, i.e., the four 3'-proximal T(1)-oligonucleotides of the six T(1)-oligonucleotides that are shared by the Mo-MSV-specific sequences of Mo-MSV 3 and Mo-MSV 124. The remaining two Mo-MSV-specific oligonucleotides identified td Mo-MSV as a deletion mutant of MSV rather than a deletion mutant of Mo-MuLV. td Mo-MSV and Mo-MSV 124 exhibited similar deletions of gag, pol, and env sequences which were less extensive than those of Mo-MSV 3. Hence, td Mo-MSV is not simply a deletion mutant of Mo-MSV 3. In addition to their MSV-specific sequences, all three MSV variants, including td Mo-MSV, shared the terminal sequences probably encoding the proviral long terminal repeat, which differed from their counterpart in Mo-MuLV. This may indirectly contribute to the oncogenic potential of MSV. A comparison of td Mo-MSV sequences with either Mo-MSV 124 or Mo-MSV 3 indicated directly, in a fashion similar to the deletion analyses which defined the src gene of avian sarcoma viruses, that Mo-MuLV-unrelated sequences of Mo-MSV are necessary for transformation. A definition of transformation-specific sequences of Mo-MSV by deletion analysis confirmed and extended previous analyses which have identified Mo-MuLV-unrelated sequences in Mo-MSV RNA and other studies which have described transformation of mouse 3T3 fibroblasts upon transfection with DNAs containing the Mo-MSV-specific sequence.

Abelson leukemia virus induces lymphoid and erythroid colonies in infected fetal cell cultures

An examination of Abelson murine leukemia virus (A-MuL V)-hematopoietic cell interaction in cultures of fetal tissues reveals that A-MuLV can stimulate the formation of two different types of colonies. One type of colony is white and composed of A-MuLV-transformed lymphoid cells that can develop into established cell lines. These cells are indistinguishable in morphology from typical adult-derived lymphoid transformants. The second type of colony is pink or red and composed of erythroid cells in various stages of differentiation. Although A-MuLV is required to induce the erythroid colonies, and at least some cells in all of these colonies are infected with the virus, no permanently growing cell lines have been established from the cells in these colonies. The frequency of the two types of colonies varies depending upon the tissue and the gestational age of the embryo. Erythroid colonies are found following infection of early and mid gestation tissues while lymphoid colonies are found following infection of mid and late gestation tissues. Mixing experiments indicate that the two types of colonies arise from distinct target cells. Because A-MuLV mutants that are defective for lymphoid cell transformation are also defective for erythroid colony induction, expression of a functional Abelson protein is probably required for colony induction. Thus A-MuLV is capable of stimulating the cells of two distinct hematopoietic lineages. In one case, infection leads to transformation, while in the second, it leads to growth and differentiation. Both types of interaction are mediated, at least in part, by the same A-MuLV gene product, a molecule previously considered to induce transformation in all stably infected cells.

src Genes of ten Rous sarcoma virus strains, including two reportedly transduced from the cell, are completely allelic; putative markers of transduction are not detected

The src genes of different Rous sarcoma virus (RSV) strains have been reported to be highly conserved by some investigators using RNA-cDNA hybridization, whereas others using oligonucleotide, peptide, and serological analyses have judged src genes to be variable in 30 to 50% of the respective markers. Moreover, distinctive src oligonucleotides and peptides of so-called recovered RSVs (rRSV's) whose src genes were reported to be experimentally transduced from the cell are thought to represent specific markers of host-derived src sequences. By contrast, we have pointed out previously that these markers may represent point mutations of parental equivalents. Here we have compared the src-specific sequences of eight RSV strains and of two rRSV's to each other and to a molecular clone of the src-related chicken locus. Our comparisons are based on RNase T(1)-resistant oligonucleotides of RNA hybridized to src-specific cDNA, which was prepared by hybridizing RSV cDNA with RNA of isogenic src deletion mutants, or to a cloned cellular src-related DNA. All of the approximately 20 src-oligonucleotides of a given RSV strain were recovered by src-specific cDNA's of all other RSV strains or by cellular src-related DNA. The number of oligonucleotides varied slightly with the length of the src deletion used to prepare src-specific cDNA, thus providing a measure for src deletion mutants. Our data indicate that the src genes of all RSV strains tested, including the two reportedly transduced from the cell, are about 98% conserved and completely allelic with only scattered single nucleotide differences in certain variable regions which are subject to point mutations. Hence, based on the src oligonucleotide markers analyzed by us and others, we cannot distinguish between a cellular and viral origin of rRSV's. However, the following are not compatible with a cellular origin of rRSV's. (i) The only putative oligonucleotide marker which is exclusively shared by the two rRSV's studied and which differs from a parental counterpart in a single base was not detectable in cellular src-related DNA. (ii) The number of different allelic src markers observed by us and others in rRSV's was too large to derive from one or two known cellular src-related loci. (iii) The known absence of linkage of the cellular src-related locus with other virion sequences was extended to all non-src oligonucleotides, including some mapping directly adjacent to src. This is difficult to reconcile with the claim that transformation-defective, partial src deletion mutants of RSV which contain both, one, or, as we show here, possibly no src termini nevertheless transduce at the same frequencies, even though homologous, single or double illegitimate recombinations would be involved. Given (i) our evidence that src genes are subject to point mutation under selective conditions similar to those prevailing when rRSV's were generated and (ii) the lack of absolute evidence for the clonal purity of the transformation-defective, partial src deletion mutants of RSV used to generate rRSV's, we submit that the src genes of rRSV's could have been generated by cross-reactivation of nonoverlapping src deletions or mutation of src variants possibly present in transformation-defective, partial src deletion mutants of RSV. To prove experimental transduction, unambiguous markers need to be identified, or it would be necessary to generate rRSV's with molecularly cloned transformation-defective, partial src deletion mutants of RSV. Although our evidence casts doubt on the idea that specific src sequences of rRSV's originated by transduction, the close relationship between viral src and cellular src-related sequences argues that src genes originated at one time in evolution from the cell by events that involved illegitimate recombination and deletion of non-src sequences that interrupt the cellular src locus.

Biological activity of the spleen focus-forming virus is encoded by a molecularly cloned subgenomic fragment of spleen focus-forming virus DNA

A biologically active subgenomic DNA fragment of a polycythemia-inducing strain of the replication-defective spleen focus-forming virus (SFFV) has been molecularly cloned. The SFFV DNA fragment includes 2.0 kilobase pairs (kbp) from the 3' end of SFFV, the long terminal repeat sequences of SFFV, and 0.4 kbp from the 5' end of SFFV. The fragment contains the previously described env-related gene of SFFV. All the properties associated with SFFV can be assigned to this SFFV DNA fragment by using a two-stage DNA transfection assay with infectious helper virus DNA. The virus recovered from the transfection assays can induce erythroblastosis, splenic foci, and polycythemia in infected mice. Fibroblast cultures transfected with the SFFV DNA fragment synthesize gp52, the known intracellular product of the env-related gene of SFFV. gp52 can also be detected in spleens from diseased mice infected with the virus recovered in the two-stage transfection. The results are consistent with the hypothesis that the env-related gene sequences of SFFV and their product gp52 are required for the initiation of SFFV-induced disease.

Genetic structure of avian myeloblastosis virus, released from transformed myeloblasts as a defective virus particle

Chicken myeloblasts transformed by avian myeloblastosis virus (AMV) in the absence of nondefective helper virus (termed nonproducer cells) were found to release a defective virus particle (DVP) that contains avian tumor viral gag proteins but lacks envelope glycoprotein and a DNA polymerase. Nonproducer cells contain a Pr76 gag precursor protein and also a protein that is indistinguishable from the Pr180 gag-pol protein of nondefective viruses. The RNA of the DVP is 7.5 kilobases (kb) long and is 0.7 kb shorter than the 8.2-kb RNAs of the helper viruses of AMV, MAV-1 and MAV-2. Comparisons based on RNA.cDNA hybridization and mapping of RNase T1-resistant oligonucleotides indicated that DVP RNA shares with MAV RNAs nearly isogenic 5'-terminal gag and pol-related sequences of 5.3 kb and a 3'-terminal c-region of 0.7 kb that is different from that found in other avian tumor viruses. Adjacent to the c-region, DVP RNA contains a contiguous specific sequence of 1.5 kb defined by 14 specific oligonucleotides. Except for two of these oligonucleotides that map at its 5' end, this sequence is unrelated to any sequences of nondefective avian tumor viruses of four different envelope subgroups as well as to the specific sequences of fibroblast-transforming avian acute leukemia and sarcoma viruses of four different RNA subgroups. The specific sequence of the DVP RNA is present in infectious stocks of AMV from this and other laboratories in an AMV-transformed myeloblast line from another laboratory, and it is about 70% related to nucleotide sequences of E26 virus, an independent isolate of an AMV-like virus. Preliminary experiments show DVP to be leukemogenic if fused into susceptible cells in the presence of helper virus. We conclude that DVP RNA is the leukemogenic component of infectious AMV and that its specific sequence, termed AMV, may carry genetic information for oncogenicity. Thus we have found here a transformation-specific RNA sequence, unrelated to helper virus, in a highly oncogenic virus that does not transform fibroblasts.

Plasma membrane glycoproteins encoded by cloned Rauscher and Friend spleen focus-forming viruses

Rauscher spleen focus-forming virus (SFFV) was cloned free of its helper virus into normal rat kidney and mouse fibroblasts, and the resulting nonproducer fibroblast clones were analyzed. Our results suggested that Rauscher SFFV encodes a glycoprotein with an apparent Mr of 54,000 (gp54) that reacts with antisera made to the envelope glycoprotein (gp70) of ecotropic murine leukemia viruses, as well as with a rat antiserum that reacts with the gp70's of dual-tropic mink cell focus-inducing and HIX viruses but not with the gp70's of ecotropic viruses. In these respects and in its tryptic peptide map, Rauscher SFFV-encoded gp54 is nearly identical to the gp55 glycoprotein which we previously reported to be encoded by Friend SFFV (Dresler et al., J. Virol. 30:564--575, 1979). However, gp54 is slightly smaller, and it lacks one methionine-containing tryptic peptide that occurs in gp55. Studies with cytotoxic antiserum in the presence of complement and with a rosetting technique which employed sheep erythrocytes coupled to protein A suggested that the gp54 and gp55 glycoproteins are weakly expressed on the surface membranes of SFFV-infected cells. In addition, the Rauscher SFFV genome also encodes gag polyproteins which appear to be identical to the gag polyproteins encoded by helper Rauscher murine leukemia virus, but differ from the antigenically related polyproteins encoded by some but not all clones of Friend SFFV. Furthermore, the glycosylated gag polyproteins encoded by Rauscher SFFV and by some Friend SFFVs also appear to be expressed on the surface membranes of infected cells. These results suggest that similar env gene recombination and partial deletion events were involved in the independent origins of two different strains of acute erythroleukemia virus.

Recovery of biologically active spleen focus-forming virus from molecularly cloned spleen focus-forming virus-pBR322 circular DNA by cotransfection with infectious type C retroviral DNA

The genome of the Lilly-Steeves strain of spleen focus-forming virus (SFFV) was molecularly cloned in the plasmid vector pBR322. Infectious SFFV could be recovered by releasing the SFFV DNA from the vector, transfecting the released DNA onto NIH 3T3 cells, and rescuing the SFFV either by superinfection with helper virus or by cotransfection with molecularly cloned infectious helper viral DNA. By using transfections with SFFV DNA still attached to the plasmid vector, infectious SFFV activity could also be recovered with either method of rescue. Studies performed with these latter types of transfections indicated that only a portion of the SFFV genome was required for biological activity. Since gp52, a marker protein for SFFV, could be detected in all cultures from which adequate titers of biologically active SFFV were recovered, the results are consistent with the hypothesis that gp52 is necessary for SFFV-induced erythroblastosis and polycythemia.

Analysis of spleen focus-forming virus-specific RNA sequences coding for spleen focus-forming virus-specific glycoprotein with a molecular weight of 55,000 (gp55)

The 32S RNA of the Friend strain of spleen focus-forming virus (SFFV) contains two sets of sequences: about half is specific to SFFV, and the other half is in common with the sequence of the helper lymphatic leukemia virus. Fingerprinting analysis of RNase T1 oligonucleotides showed that the SFFV-specific sequences were located in two distinct regions: in the 3' half and near the 5' terminus of the genome. Translation of SFFV RNA in a cell-free system yielded three SFFV-specific polypeptides: two main products with molecular weights of about 47,000 (P47) and 16,000 (P16) and a variable amount of a product with a molecular weight of 40,000 (P40). P47 was translated from polyadenylic acid-containing fragments of 1,500 to 3,000 nucleotides with SFFV-specific sequences from the 3' half of the genome, whereas P16, which contained peptides in common with those of P47, was synthesized by smaller RNA. P47 formed in vitro was found to be structurally related to the protein portion of a glycoprotein, gp55, specifically found in SFFV-infected cells in vitro. It is concluded from the results that a defective env gene containing SFFV-specific sequences in the 3' half of the genome codes for SFFV-specific gp55.

Three laboratory strains of spleen focus-forming virus: comparison of their genomes and translational products

The molecular properties of three laboratory strains of the spleen focus-forming virus were compared. All strains contain genetic sequences related to the env gene of mink cell focus-inducing murine type C leukemia viruses, and each strain codes for a glycoprotein of 50,000 to 52,000 daltons which shares specific immunological properties with the gp70's of mink cell focus-inducing viruses. In contrast to this constancy, gag gene products coded for by these strains vary significantly. The gag and env gene products are synthesized from separate mRNA's, and the mRNA for the env gene product is approximately 18S. Unlike other acute leukemia viruses, which can transform various undifferentiated cells, have large unique sequence cellular gene inserts fused to helper virus gag genes, and have one known genome-length intracellular mRNA, the spleen focus-forming virus transforms only specific hematopoietic stem cells, is an env gene rather than a gag gene recombinant virus, and has a second distinct and smaller class of intracellular mRNA. Our data therefore indicate that the Friend strain of the spleen focus-forming virus is a unique replication-defective acute leukemia virus.

Structure and specific sequences of avian erythroblastosis virus RNA: evidence for multiple classes of transforming genes among avian tumor viruses

Two major RNA species were found in several clonal isolates of avian erythroblastosis virus (AEV) and avian erythroblastosis-associated helper virus (AEAV) complexes: one of 8.7 kilobases (kb), the other of 5.5 kb. The 5.5-kb species was identified as AEV RNA because (i) it was absent from non-transforming AEAV isolated from the same virus complex, (ii) it was present in complexes of AEV and different helper viruses, and (iii) its structure is similar to that of avian acute leukemia viruses of the MC29 group. Molecular hybridization indicated that 54% of AEV RNA is specific and 46% is related to other viruses of the avian tumor virus group, particularly to AEAV, therefore termed group-specific. The genetic structure of AEV RNA was deduced by mapping oligonucleotides representing specific and group-specific sequences and by comparing the resulting map to maps of AEAV and of other avian tumor viruses derived previously. AEV RNA contains a gag gene-related, 5' group-specific section of 1 kb, an internal AEV-specific section of 3 kb unrelated to any other viral RNA tested, and a 3' group-specific section of 1.5 kb. The 5' section of AEV RNA is closely related to analogous 5' sections of the MC29 group viruses and is homologous with a 5' RNA section that is part of the gag gene of AEAV. The 3' section is also shared with AEAV RNA and includes a variant C-oligonucleotide near the 3' end that is different from the highly conserved counterparts of all other exogenous avian tumor viruses. By analogy with Rous sarcoma virus and the acute leukemia viruses of the MC29 group, the internal specific section of AEV RNA is thought to signal a third class of onc genes in avian tumor viruses. Comparisons with AEAV and the MC29 group viruses suggest that both the 5' gag-related and the internal specific RNA sections of AEV are necessary for onc gene function.