Molecular cloning and characterization of a leukemia-inducing myeloproliferative sarcoma virus and two of its temperature-sensitive mutants

Retroviral insertional mutagenesis implicates E3 ubiquitin ligase RNF168 in the control of cell proliferation and survival

The E3 ubiquitin ligase RNF168 is a ring finger protein that has previously been identified to play an important regulatory role in the repair of double-strand DNA breaks.  In the present study, an unbiased forward genetics functional screen in mouse granulocyte/ macrophage progenitor cell line FDCP1 has identified E3 ubiquitin ligase RNF168 as a key regulator of cell survival and proliferation. Our data indicate that RNF168 is an important component of the mechanisms controlling cell fate, not only in human and mouse haematopoietic growth factor-dependent cells, but also in the human breast epithelial cell line MCF-7. These observations therefore suggest that RNF168 provides a connection to key pathways controlling cell fate, potentially through interaction with PML nuclear bodies and/or epigenetic control of gene expression. Our study is the first to demonstrate a critical role for RNF168 in the in the mechanisms regulating cell proliferation and survival, in addition to its well-established role in DNA repair.

Studies on the pathology, especially brain lesions, induced by R7, a spontaneous mutant of Moloney murine sarcoma virus 124

We have recently isolated R7, a spontaneous Moloney murine sarcoma virus (MoMuSV) 124 variant. Molecular cloning and sequence analysis showed that, relative to MoMuSV 124, R7 has an extra repeat in each enhancer and a truncated mos gene in frame with the truncated gag coding sequence. This report presents a detailed study on the pathology induced by R7. R7 induced not only sarcomas with well developed angiomatous components but also brain lesions. Brain lesions were observed in all less-than-48-hour-old BALB/c mice inoculated with greater than 2 x 10(5) R7 focus-forming units (FFUs). R7 was detected in all brains examined by day 9 after inoculation, and brain lesions were observed in two of four mice examined by day 14 after inoculation. Light microscopy of brains revealed that approximately 15% of the lesions were unenclosed blood pools of varying sizes containing red blood cells and inflammatory cells spreading into surrounding brain tissues. The remainder of the brain lesions had tumor cells. These lesions ranged from a few enlarged vascular endothelial cells intermixed with blood cells to large circumscribed lesions consisting of well developed tangled masses of vessels surrounded by blood pools. Activated astrocytes surrounded and infiltrated the tumors. In addition, the thymus of R7-infected mice regressed significantly and precipitously due to apoptosis (especially of cortical thymocytes) at the end stage of the disease.

Increased probability of expression from modified retroviral vectors in embryonal stem cells and embryonal carcinoma cells

Gene expression from the Moloney murine leukemia retrovirus (Mo-MuLV) is highly restricted in embryonic carcinoma (EC) and embryonic stem (ES) cells. We compared levels of expression in PA317 fibroblasts, F9 (EC) cells, and CCE (ES) cells by Mo-MuLV-based vectors and vectors based on our previously reported MND backbone, which has alterations to address three viral elements implicated as repressors of expression by Mo-MuLV: the enhancer, the primer binding site, and the negative-control region. Expression was evaluated with three reporter genes, the chloramphenicol acetyltransferase (CAT) gene, whose expression was measured by enzymatic assay and by Northern blotting; a truncated nerve growth factor receptor (tNGFR), whose expression was measured by fluorescence-activated cell sorting (FACS) as a cell surface protein; and the enhanced green fluorescent protein (EGFP), whose expression was measured intracellularly by flow cytometry. We found significantly higher levels of CAT activity (5- to 300-fold) and greater quantities of vector-specific transcripts in ES and EC cells transduced with the modified MND-CAT-SN vector than in those transduced with L-CAT-SN. Northern blot analysis indicated that long terminal repeat transcripts from MND-CAT-SN are >80 times more abundant than the L-CAT-SN transcripts. FACS analysis of tNGFR expression from a pair of vectors, L-tNGFR-SN and MND-tNGFR-SN, indicated that only 1.04% of the CCE cells containing the L-tNGFR-SN vector expressed the cell surface reporter, while the MND-tNGFR-SN vector drove expression in 99.54% of the CCE cells. Of the F9 cells containing the L-tNGFR-SN vector, 13.32% expressed tNGFR, while 99.89% of the F9 cells transduced with MND-tNGFR-SN showed expression. Essentially identical results were produced with an analogous pair of vectors encoding EGFP. In unselected pools of F9 cells 48 h posttransduction, the L-EGFP-SN vector drove expression in only 5% of the population while the MND-EGFP-SN vector drove expression in 88% of the cells. After more than 3 weeks in culture without selection, the proportion of cells showing expression from L-EGFP-SN decreased slightly to 3% while expression from the MND-EGFP-SN vector persisted in 80% of the cells. Interestingly, in the few ES and EC cells which did show expression from the L-tNGFR-SN or L-EGFP-SN vectors, the magnitude of reporter expression was similar to that from the MND-tNGFR-SN or MND-EGFP-SN vector in nearly all cells, suggesting that the MND vectors are far less susceptible to position-dependent variegation of expression than are the Mo-MuLV-based vectors. Therefore, the modified retroviral vector, MND, achieves higher net levels of expression due to a greater frequency of expression, which may be useful for the expression of exogenous genes in EC and ES cells.

Genomic rearrangements of retroviral vectors carrying two genes in F9 EC cells

We have used two classes of double-expression retroviral vectors for the expression of foreign genetic information in embryonal carcinoma cell lines. The splice-vector pM5neo takes advantage of mutated sequences that mediate an LTR-driven expression in F9 EC cells. The second vector (pXT1 type) uses an internal HSV-tk promoter as the control element for the transcription of the second gene. Genomic analysis of DNA from infected F9 cell lines revealed that most of the proviruses have rearranged upon integration into the host genome. This reorganization always included the nonselected gene and is sequence independent, but depends on the selective pressure applied. No retroviral genomic rearrangements were observed in F9 cells infected with pM5 proviruses carrying only the neo resistance gene. On the contrary, gross rearrangements were found in cells infected with parental pXT1 retroviruses. In both vectors the transcriptional activity was very low. A direct correlation between selective pressure, proviral reorganization, and transcription was observed.

SV7, a molecular clone of Moloney murine sarcoma virus 349, transforms vascular endothelial cells

SV7, a progeny of Moloney murine sarcoma virus 349 cells, was molecularly cloned. SV7 induced sarcomas consisting of vascular and fibrous components. The large blood-filled vascular dilatations appeared grossly as dark red spots in the tumors and constituted up to 50% of the tumor volume. These vascular structures, ranging from small capillaries to cavernous vascular dilatations, were lined by one to several layers of neoplastic endothelial cells. Thick papillary outgrowths of the neoplastic endothelium extended into and often occluded the vessel lumens. The fibrous component consisted mostly of spindle cells and granulocytes, which provided the stroma for the vascular structures. The vascular and fibrous components appeared to have arisen independently. Lymphopenia accompanied by myeloid metaplasia was observed in the spleen of both SV7- and myeloproliferative sarcoma virus (MPSV)-infected mice. The blood of SV7-infected mice had a much higher level of circulating granulocytes than did that of MPSV-infected mice. The latter manifested a more advanced myeloid metaplasia, characterized by aggregates of myelomonocytic blast cells in the spleen.

Derivatives of Moloney murine sarcoma virus capable of being transcribed in embryonal carcinoma stem cells have gained a functional Sp1 binding site

The long terminal repeat (LTR) sequences of Moloney murine leukemia virus and its closely related derivative Moloney murine sarcoma virus (Mo-MSV) are incapable of directing transcription in embryonal carcinoma (EC) stem cells. The myeloproliferative sarcoma virus, a derivative of Mo-MSV, has several point mutations in the LTR and is transcribed more efficiently to allow productive infection of F9 EC cells. One of these mutations, at -166 with respect to the transcriptional start, creates a consensus binding site for the well-characterized mammalian transcription factor Sp1. We used gel retardation assays to demonstrate that F9 EC cell extracts form several complexes with the myeloproliferative sarcoma virus sequence around -166. One of these complexes involves a murine Sp1-like protein, which has immunoreactivity, DNA binding specificity, and electrophoretic mobility equivalent to those of purified human Sp1 protein. An equivalent complex forms on the corresponding Mo-MSV sequence but with a fivefold-lower affinity. Consistent with these observations, introduction of the single point mutation at -166 into the Mo-MSV LTR, creating a consensus Sp1 binding site, increases expression in F9 EC cells sixfold.

The prokaryotic neomycin-resistance-encoding gene acts as a transcriptional silencer in eukaryotic cells

The gene encoding neomycin resistance (neo) mediates a cis-acting negative effect on expression from promoters in transient and stable transfectants of mammalian cell lines. Inserting the neo gene either into retroviral vectors or into plasmids containing reporter genes results in a five- to tenfold decrease of expression from proximal promoters like the simian virus 40 early or the retroviral myeloproliferative sarcoma virus promoter. The silencing effect is not dependent on the insertion site or the orientation of the fragment. The neo gene is frequently used in eukaryotic vectors as a dominant selectable gene. Other selectable genes were tested for potential cis-activity. We found that the gene conferring resistance to puromycin from Streptomyces alboniger does not influence adjacent promoters.

Moloney murine sarcoma virus 349 induces Kaposi's sarcomalike lesions in Balb/c mice

Moloney murine sarcoma virus (MoMuSV349) is produced by MuSV349 cells in at least eight-fold excess over the replication-competent helper virus. Less than 48-hours-old Balb/c mice inoculated intraperitoneally with supernatant from MuSV349 cells containing approximately 10(4) MuSV349 infectious units developed clinical symptoms, including severe generalized wasting, 15 to 20 days after inoculation. These infected mice became moribund 35 to 45 days after inoculation. Gross examination of the bodies revealed the presence of cutaneous and subcutaneous 0.2-cm to 1.5-cm macules, plaques, or nodules located predominantly on the ventral abdomen and legs. Nodules also were found in the spleen, liver, ovaries, testes, meninges, nerves, and skin. The nodules were semisoft, cystic, or solid and some expressed variable amounts of blood. Histologic examination of the macules, plaques, and nodules showed spindlelike cells intermingled with tortous, jagged vascular channels lined by plump and normal endothelial cells and unlined slitlike spaces filled with erythrocytes. These angiomatous lesions were infiltrated extensively with neutrophils, lymphocytes, macrophages, and some plasma cells. In some cases the lesions also included foci of densely packed eosinophils. These angiomatous lesions are clearly distinguishable from the fibrosarcomas induced by the myeloproliferative sarcoma virus (MPSV), and resemble the sarcomas induced in mice by Gz-MSV and Balb MSV, the sarcomas induced in rats by MPSV and Ha-MSV, and the acute generalized form of Kaposi's sarcoma (KS) associated with acquired immune deficiency syndrome (AIDS) in humans. Electron microscopy also revealed the presence of numerous extracellular type C virions and virions budding from the plasma membrane of endothelial and spindlelike cells. Erythrophagocytosis by the endothelial and spindlelike cells was demonstrated by light and electron microscopy. The widely disseminated lesions appear to have developed simultaneously as a consequence of viremia rather than metastasis.

Two blocks in Moloney murine leukemia virus expression in undifferentiated F9 embryonal carcinoma cells as determined by transient expression assays

Transient expression assays were used to investigate the restriction of Moloney murine leukemia virus (MoMuLV) expression in undifferentiated mouse F9 embryonal carcinoma (EC) cells. We previously reported that the MoMuLV long terminal repeat (LTR) is inactive in undifferentiated F9EC cells due to inactivity of the tandemly repeated MoMuLV transcriptional enhancers. Others suggested that the inactivity was due to the presence of negative regulatory elements that interact with the MoMuLV tandem repeats. Two heterologous enhancer sequences that are active in undifferentiated F9 EC cells were inserted into the MoMuLV LTR: the B enhancers from the F101 variant of polyomavirus and a cellular enhancer sequence isolated from EC cells that we previously identified. The chimeric LTRs were then fused to the bacterial chloramphenicol acetyltransferase gene and tested for expression by transfection into F9 EC or NIH 3T3 cells. Insertion of these enhancers either upstream or downstream of the MoMuLV tandem repeats resulted in transcriptionally active LTRs in undifferentiated EC cells, which did not support the existence of negative regulatory elements interacting with the tandem repeats. In our previous MoMuLV enhancer deletion constructs, the GC-rich sequences downstream from the tandem repeats were also deleted, which might have contributed to the inactivity in EC cells. However, restoration of the GC-rich sequences did not yield an active LTR. The experiments also suggested that the EC cellular enhancer was preferentially active in undifferentiated EC cells and inactive in NIH 3T3 cells. The possibility of negative regulatory sequences in the vicinity of the MoMuLV primer-binding site was tested by inserting MoMuLV sequences from +30 to +419 base pairs into the LTR-chloramphenicol acetyltransferase gene constructs downstream of the transcriptional start site. Transient expression assays confirmed that these sequences reduced expression from functional LTRs in undifferentiated F9 EC cells but reduced expression significantly less in NIH 3T3 cells. Moreover, equivalent sequences from myeloproliferative sarcoma virus did not exhibit this effect. These results supported restriction of MoMuLV expression in undifferentiated F9 EC cells at two levels, inactivity of the MoMuLV enhancers and interaction of negative regulatory factors in the vicinity of the primer-binding site.

Comparison of expression in hemopoietic cells by retroviral vectors carrying two genes

In order to identify factors that influence expression by retroviral vectors in hemopoietic cells, we have compared viral RNA levels in cells infected with several different recombinant viruses. All of the vectors tested carry the neomycin resistance gene and provide for the insertion of a second gene which, in these studies, comprised sequences from the myc or myb oncogenes or the gene encoding granulocyte-macrophage colony-stimulating factor. The vectors utilize two different strategies for the coexpression of the two genes: alternate splicing and the use of a separate internal promoter. We found that expression in hemopoietic cells could be increased by substituting sequences from the myeloproliferative sarcoma virus long terminal repeat for those of the Moloney murine leukemia virus long terminal repeat. However, none of the vectors examined was able to express a second gene at levels equivalent to those achieved by the parental vectors carrying only the neomycin resistance gene. The reasons for this varied with the different vectors and included inefficient splicing and/or a reduction in the level of unspliced transcripts upon insertion of a second gene. Although the basis of the latter phenomenon is not clear, it is probably related to the position--near the 5' long terminal repeat--at which the second gene was inserted, since insertion of the same genes near the 3' end of another vector had no effect on viral RNA levels. In an attempt to circumvent some of these problems, we constructed a vector that employs an internal beta-actin promoter. Although this vector could express granulocyte-macrophage colony-stimulating factor sequences in a responsive hemopoietic cell line, the level of granulocyte-macrophage colony-stimulating factor produced was disappointingly low. The results from these studies suggest approaches to the design of improved vectors for effective expression of genes in hemopoietic cells.

Identification of genes involved in growth autonomy of hematopoietic cells by analysis of factor-independent mutants

The factor-dependent myeloid precursor cell line D35 mutates spontaneously at a frequency greater than 2.4 x 10(-7) to growth factor autonomy. This frequency could be increased at least 20-fold by retrovirus insertional mutagenesis. The isolation and characterization of factor-independent mutants allowed the identification of genes involved in growth autonomy. Mutants could be subdivided into two sets: those that secreted a stimulating factor (10/11) and those that did not (1/11). In one case, the factor released was distinct from previously characterized growth factors. In most mutants (6/9), the activation of a growth factor gene was associated with rearrangement that could be attributed to the insertion of a transposable-like element either 5' or 3' of the factor coding region in all cases examined, excluding oncogene involvement. All factor-independent mutants were tumorigenic, consistent with the hypothesis that growth-factor independence initiated by aberrant growth factor gene activation is an important and early step in tumorigenesis.

Histopathologic studies on myeloproliferative sarcoma virus (MPSV) induced leukemias and hemangiosarcoma in Jar-2 rats

It is well known that MPSV induces myeloproliferative syndrome (MPS) in mice. Intravenous one shot inoculation of myeloproliferative sarcoma virus (MPSV) with Friend murine leukemia virus (F-MuLV) as a helper in newborn Jar-2 rats (on the second neonatal day) yielded hematopoietic malignancies in all the treated rats (25/25 rats) after 2 weeks' latency. MPS appeared from the 14th day in 14 rats. In the midst of the myeloproliferative field of the spleen and bone marrow, myeloblastic or myeloblastic-erythroblastic foci were observed. From 19th day, acute myeloblastic leukemia occurred in 3 rats and erythroleukemia in 8 rats. MPSV induced first MPS which remained as such or later developed into acute leukemia. Myelofibrosis as seen in mice was not observed. In addition, hemangiosarcoma of the brain, spinal cord and spleen appeared in 15 rats from the 24th day, and were often multiple. MPSV can yield the tumor only in newborn rats, and target cells of MPSV are not only hematopoietic cells but also endothelial cells of the brain, spinal cord and occasionally spleen.

Autocrine stimulation after transfer of the granulocyte/macrophage colony-stimulating factor gene and autonomous growth are distinct but interdependent steps in the oncogenic pathway

Autocrine stimulation of cells by aberrant synthesis of growth factor may lead to malignant transformation, either as a direct consequence of endogenous factor production or as a first step of a series of successive events. Introduction of the granulocyte/macrophage colony-stimulating factor (GM-CSF) cDNA clone into a vector based on the myeloproliferative sarcoma virus allowed efficient transfer and expression of GM-CSF in factor-dependent myeloid cell lines (FDC-P1 and FDC-P2). Factor-independent growth was acquired when the vector was introduced into the GM-CSF-responsive FDC-P1 cell line but not the multi-CSF-dependent FDC-P2 line. Nonlinear clonability in the absence of exogenous growth factor and growth inhibition by GM-CSF antiserum support a model of autocrine stimulation that requires interaction of factor and receptor at the outer membrane. However, many, but not all, infected FDC-P1 cells acquired subsequently a second mutation that abrogated the requirement of GM-CSF secretion and external interaction. The nature of the second step, which presumably leads to tumorigenicity of these cells, is not well understood, but its frequency could be correlated with the level of GM-CSF released by an individual cell clone.

Rescue of type I collagen-deficient phenotype by retroviral-vector-mediated transfer of human pro alpha 1(I) collagen gene into Mov-13 cells

A full-length cDNA clone corresponding to the human pro alpha 1(I) collagen gene was isolated and inserted into a retrovirus vector. Cell lines were obtained which produced recombinant viruses transducing the collagen cDNA (HUC virus). To test whether the transduced cDNA was functional, Mov-13 mouse cells were infected with the virus. These cells do not produce any type I collagen due to an insertional mutation of the pro alpha 1(I) gene which blocks transcription. While normal amounts of pro alpha 2(I) RNA were synthesized, no alpha 2(I) collagen chains were detectable in the mutant Mov-13 cells. Infection with HUC virus, however, resulted in the production of stable type I collagen, which was secreted into the medium. Analysis of pepsin-resistant proteins indicated that interspecies heterotrimers consisting of human alpha 1(I) and mouse alpha 2(I) collagen chains were secreted by the infected Mov-13 cells. Our results show that pro alpha (I) collagen chains from species as distant as human and mouse can associate to form stable type I collagen. The availability of a retrovirus vector transducing a functional pro alpha 1(I) collagen gene combined with the Mov-13 mutant system should enable us to study the effect of specific mutations on the synthesis, assembly, and function of type I collagen, not only in tissue culture but also in the animal.

Murine gamma interferon inhibits v-mos-induced fibroblast transformation via down regulation of retroviral gene expression

Expression of the retroviral vector Neor myeloproliferative sarcoma virus (MPSV), which contains the v-mos oncogene and the neomycin resistance gene, leads to neoplastic transformation of mouse fibroblasts. Murine recombinant gamma interferon (IFN-gamma) could revert the neoplastic properties of established Neor MPSV-transformed cell lines to an apparently untransformed phenotype. In the presence of IFN-gamma, the Neor MPSV transformants showed a greater than 97% reduction of cloning efficiency in soft agar, strongly reduced proliferative capacity, and morphological changes. The IFN-gamma-induced phenotypic reversion was preceded by a rapid and selective reduction of all retroviral RNA species, apparently due to IFN-gamma action on the long terminal repeat of Neor MPSV. The mRNA levels of cellular genes either remained unaffected (beta-actin) or were even enhanced (H-2) in IFN-gamma-treated Neor MPSV-transformed cells. Upon removal of IFN-gamma, retroviral gene expression was fully recovered and a gradual reappearance of the transformed phenotype of these cells within 3 weeks was noted. These data show that IFN-gamma can cause a virtually complete, but reversible, inhibition of v-mos-induced neoplastic properties in transformed fibroblasts by selective down regulation of retroviral RNA levels.

Functional analysis of a retroviral host-range mutant: altered long terminal repeat sequences allow expression in embryonal carcinoma cells

A retroviral host-range neomycin-resistant myeloproliferative sarcoma virus mutant, which is expressed in the embryonal carcinoma cell lines F9 and PCC4aza1R, was molecularly cloned and analyzed. This mutant virus, PCMV, differs from myeloproliferative sarcoma virus by two major deletions, one of which spans exactly a 75-base-pair repeat of the long terminal repeat. Functional analysis of recombinant viruses shows that the host-range expansion of PCMV is a property of nucleotide changes within the U3 region of the long terminal repeat. Furthermore, expression assays of chimeric long terminal repeats show that the enhancer region of PCMV joined to the promoter region of Moloney murine leukemia virus is sufficient to direct the synthesis of chloramphenicol acetyltransferase in F9 and PCC4 cells.

Stable expression of a selectable myeloproliferative sarcoma virus in murine T lymphocyte and monocyte cell lines

We have investigated whether a retroviral vector based on the myeloproliferative sarcoma virus (MPSV) can be expressed in murine T cells and macrophages. This vector (neoR MPSV) carries the dominant selection marker for neomycin resistance (neoR) and the mos oncogene. The murine T cell line BW5147 and the monocytic cell line P388D1 were either transfected with neoR MPSV DNA or infected with neoR MPSV virus. From both lines, neoR cell clones could be established by retroviral infection, but not by calcium-phosphate precipitation-mediated DNA transfection. The efficiency of infection could be increased 60- to 200-fold upon cocultivation of target cells with irradiated neoR MPSV virus-producing cells. All neoR clones showed neoR MPSV specific sequences as revealed by dot blot and Southern blot analysis. The integration and expression of neoR MPSV was stable over a period of now more than 4 months, even in the absence of selection for neomycin resistance. Northern blot analysis showed that neoR clones express full length neoR MPSV. Further, clones of both T cell and monocyte origin were capable to produce infectious virus particles as revealed by focus formation on fibroblasts and conversion of neomycin sensitive fibroblasts to a neomycin resistant phenotype.

A temperature-sensitive mutant of the myeloproliferative sarcoma virus, altered by a point mutation in the mos oncogene, has been modified as a selectable retroviral vector

The myeloproliferative sarcoma virus (MPSV) is a mos-oncogenic retrovirus which induces an acute myeloproliferative disease in adult mice. The isolation and molecular cloning of two mutants of MPSV temperature sensitive (ts) for mos transformation (Kollek et al., J. Virol. 50:717-724, 1984) have been described previously. In this report, we describe the biological activity of these clones, the molecular basis of the ts lesion of one clone, and the construction of a selectable vector based on the MPSV ts genome. Both molecular clones, ts159 and ts124, proved to have retained the ts phenotype, the former being tighter for the induction and maintenance of the transformed phenotype. A single transition (G----A) at position 1888 in the mos coding region, resulting in the change of Gly to Arg at position 307, was responsible for the ts phenotype of clone ts159. Substitution of sequences carrying this mutation with the corresponding sequences of the wild-type virus generated a virus that was ts for transformation. Insertion of the dominant selectable marker gene for geneticin resistance (neor) into ts159 did not disrupt mos expression or its ts phenotype. neor-ts159 facilitates the study of mos action by allowing the selection of infected cells at the nonpermissive temperature before mos transformation has been induced. Furthermore, infected cells which show no obvious phenotype alteration due to mos expression can be identified by their Neor phenotype.

Viral transfer, transcription, and rescue of a selectable myeloproliferative sarcoma virus in embryonal cell lines: expression of the mos oncogene

A derivative of the myeloproliferative sarcoma virus (Neor-MPSV) carrying the mos oncogene and dominant selection marker for neomycin resistance (Neor) was introduced into embryonal carcinoma and embryo-derived cell lines by transfection and infection using pseudotypes with Friend helper virus (Friend murine leukemia virus [F-MuLV]). Cells resistant to G418 (a neomycin analog) were cloned and expanded. Transductants retained an undifferentiated phenotype as judged by morphology, tumorigenicity, and cell-surface antigen analyses. Nucleic acid analysis of infectants revealed both Neor-MPSV and F-MuLV proviruses, although no virus was released. G418-resistant transductants remained nonpermissive for the expression of other proviruses and for subsequent superinfection. Northern analysis showed expression of full-length Neor-MPSV, as well as mos-specific subgenomic RNA. mos sequences were deleted from Neor-MPSV (Neor mos-1), and pseudotypes were used to infect embryonal carcinoma cells. No morphological differences were observed in either mos+ or mos- transductants as compared with parental cell lines. However, mos+ transductants showed an enhanced anchorage-independent growth compared with that of mos- transductants in agar cloning. PCC4 transductants were induced to differentiate with retinoic acid and superinfected with F-MuLV. Infection with viral supernatant in fibroblasts and in mice confirmed the rescue of biologically active Neor-MPSV.

Point mutations in the U3 region of the long terminal repeat of Moloney murine leukemia virus determine disease specificity of the myeloproliferative sarcoma virus

The myeloproliferative sarcoma virus (MPSV) is made up entirely of sequences derived from the Moloney murine leukemia virus (Mo-MuLV) and the cellular mos oncogene. As other members of the Moloney murine sarcoma virus (Mo-MuSV) family, MPSV transforms fibroblasts in vitro and causes sarcomas in vivo. In addition, however, MPSV also causes an acute myeloproliferative disease in adult mice. The mos oncogene is essential for its transforming capacity, but sequences specific to the long terminal repeat (LTR) U3 region of MPSV account for its expanded target specificity as compared to Mo-MuSV (C. Stocking, R. Kollek, U. Bergholz, and W. Ostertag, Proc. Natl. Acad. Sci. USA 82, 5746-5750 (1985)). The U3 region of the LTR of MPSV is, however, closely related to that of the Mo-MuLV, and it appeared likely that the difference between MPSV and Mo-MuSV was caused by a divergent evolution of Mo-MuSV LTRs. In this paper, we show that this is not the case. The few nucleotide differences in the LTR between Mo-MuLV and MPSV are crucial for the expanded host range of MPSV. Moreover, Mo-MuLV-related gag sequences retained in MPSV are not essential for the distinctive biological properties of MPSV.

Retroviral mutants efficiently expressed in embryonal carcinoma cells

The myeloproliferative sarcoma virus (MPSV) is a unique member of the Moloney murine sarcoma virus family. Due to mutations in the U3 region of its long terminal repeat, MPSV has an expanded host range that includes cells of the hematopoietic compartment. Using a MPSV recombinant containing the gene for neomycin-resistance (NeoR-MPSV), we demonstrate that the host range of MPSV also includes undifferentiated F9 embryonal carcinoma cells. Transfer of G418-resistance with NeoR-MPSV to F9 cells is almost as efficient as G418-resistance transfer to fibroblasts, in contrast to G418-resistance transfer to PCC4 embryonal carcinoma cells, which is at least 3 orders of magnitude lower. To isolate NeoR-MPSV mutants that are efficiently expressed in PCC4 cells, G418-resistant PCC4 cell lines were induced to differentiate, and the provirus was rescued by superinfection with murine leukemia virus. Viral isolates (PCMV-5 and -6; PCMV = PCC4 cell-passaged NeoR-MPSV) were obtained and assayed for expression in embryonal carcinoma cells. The efficiency of NeoR transfer was equally as high in both F9 and PCC4 as in fibroblasts. mos oncogene expression was unaltered as judged by transformation capability. No gross alteration in the coding region and in the long terminal repeat was detectable by restriction enzyme analysis. NeoR-MPSV and its mutants PCMV-5 and -6 can thus be utilized as vectors for the efficient transduction of genes into embryonic cells.

Viral transfer, transcription, and rescue of a selectable myeloproliferative sarcoma virus in embryonal cell lines: expression of the mos oncogene

A derivative of the myeloproliferative sarcoma virus (Neor-MPSV) carrying the mos oncogene and dominant selection marker for neomycin resistance (Neor) was introduced into embryonal carcinoma and embryo-derived cell lines by transfection and infection using pseudotypes with Friend helper virus (Friend murine leukemia virus [F-MuLV]). Cells resistant to G418 (a neomycin analog) were cloned and expanded. Transductants retained an undifferentiated phenotype as judged by morphology, tumorigenicity, and cell-surface antigen analyses. Nucleic acid analysis of infectants revealed both Neor-MPSV and F-MuLV proviruses, although no virus was released. G418-resistant transductants remained nonpermissive for the expression of other proviruses and for subsequent superinfection. Northern analysis showed expression of full-length Neor-MPSV, as well as mos-specific subgenomic RNA. mos sequences were deleted from Neor-MPSV (Neor mos-1), and pseudotypes were used to infect embryonal carcinoma cells. No morphological differences were observed in either mos+ or mos- transductants as compared with parental cell lines. However, mos+ transductants showed an enhanced anchorage-independent growth compared with that of mos- transductants in agar cloning. PCC4 transductants were induced to differentiate with retinoic acid and superinfected with F-MuLV. Infection with viral supernatant in fibroblasts and in mice confirmed the rescue of biologically active Neor-MPSV.

Long terminal repeat sequences impart hematopoietic transformation properties to the myeloproliferative sarcoma virus

The myeloproliferative sarcoma virus not only transforms fibroblasts but also causes extensive expansion of the hematopoietic stem cell compartment on infection of adult mice. Similar to the Moloney sarcoma virus, it carries the mos oncogene. Moloney sarcoma virus, however, does not induce myeloproliferation and leukemia in adult mice. The difference between the two viruses was explored by using their molecularly cloned genomes and the cellular mos oncogene to construct recombinant genomes. It was shown that the U3 region of the viral long terminal repeat (LTR) has a decisive function in determining the target cell specificity of the myeloproliferative sarcoma virus. Any mos gene, whether of cellular or viral origin, is sufficient in conjunction with the proper LTR to induce myeloproliferation. Our results indicate that the pathogenicity of acutely transforming viruses is determined not only by the oncogene but also by sequences in the viral LTR.

Comparison of myeloproliferative sarcoma virus with Moloney murine sarcoma virus variants by nucleotide sequencing and heteroduplex analysis

The myeloproliferative sarcoma virus (MPSV) was derived by passage of Moloney sarcoma virus (Mo-MuSV) in adult mice. Mo-MuSV variants transform fibroblasts. However, MPSV also affects erythroid, myeloid, and hematopoietic stem cells. The MPSV proviral genome, two temperature-sensitive mutants derived from it, Mo-MuSV variant M1, and Moloney murine leukemia virus (Mo-MuLV) were compared by heteroduplex mapping. MPSV wild type was found to have 1 kilobase pair deleted from the pol gene and to contain v-mos-related sequences. The 3' end of MPSV, including the oncogene-helper junctions, the v-mos gene, and the 3' long terminal repeat, was sequenced and compared with sequences of Mo-MuLV, MSV-124, and the mouse oncogene c-mos. From these data, MPSV appears to be either closely related to the original Mo-MuSV or an independent recombinant of Mo-MuLV and c-mos. Five possible explanations of the altered specificity of MPSV are considered. (i) The MPSV mos protein has properties inherent in c-mos but lost by other Mo-MuSV mos proteins. (ii) The MPSV mos protein has altered characteristics due to amino acid changes. (iii) Due to a frameshift, MPSV codes for a mos protein truncated at the amino terminal and also a novel peptide. (iv) A second novel peptide may be encoded from the 3' env region. (v) MPSV has long terminal repeats and an enhancer sequence more like Mo-MuLV than Mo-MuSV, with a consequently altered target cell specificity.