Moloney Murine Leukemia Virus-Induced Preleukemic Thymic Atrophy and Enhanced Thymocyte Apoptosis Correlate with Disease Pathogenicity

Moloney murine leukemia virus (M-MuLV) is a replication-competent, simple retrovirus that induces T-cell lymphoma with a mean latency of 3 to 4 months. During the preleukemic period (4 to 10 weeks postinoculation) a marked decrease in thymic size is apparent for M-MuLV-inoculated mice in comparison to age-matched uninoculated mice. We were interested in studying whether the thymic regression was due to an increased rate of thymocyte apoptosis in the thymi of M-MuLV-inoculated mice. Neonatal NIH/Swiss mice were inoculated subcutaneously (s.c.) with wild-type M-MuLV (approximately 10⁵ XC PFU). Mice were sacrificed at 4 to 11 weeks postinoculation. Thymic single-cell suspensions were prepared and tested for apoptosis by two-parameter flow cytometry. Indications of apoptosis included changes in cell size and staining with 7-aminoactinomycin D or annexin V. The levels of thymocyte apoptosis were significantly higher in M-MuLV-inoculated mice than in uninoculated control animals, and the levels of apoptosis were correlated with thymic atrophy. To test the relevance of enhanced thymocyte apoptosis to leukemogenesis, mice were inoculated with the Mo+PyF101 enhancer variant of M-MuLV. When inoculated intraperitoneally, a route that results in wild-type M-MuLV leukemogenesis, mice displayed levels of enhanced thymocyte apoptosis comparable to those seen with wild-type M-MuLV. However, in mice inoculated s.c., a route that results in attenuated leukemogenesis, significantly lower levels of apoptosis were observed. This supported a role for higher levels of thymocyte apoptosis in M-MuLV leukemogenesis. To examine the possible role of mink cell focus-forming (MCF) recombinant virus in raising levels of thymocyte apoptosis, MCF-specific focal immunofluorescence assays were performed on thymocytes from preleukemic mice inoculated with M-MuLV and Mo+PyF101 M-MuLV. The results indicated that infection of thymocytes by MCF virus recombinants is not required for the increased level of apoptosis and thymic atrophy.     

Appearance of Mink Cell Focus-Inducing Recombinants during In Vivo Infection by Moloney Murine Leukemia Virus (M-MuLV) or the Mo+PyF101 M-MuLV Enhancer Variant: Implications for Sites of Generation and Roles in Leukemogenesis

One hallmark of murine leukemia virus (MuLV) leukemogenesis in mice is the appearance of env gene recombinants known as mink cell focus-inducing (MCF) viruses. The site(s) of MCF recombinant generation in the animal during Moloney MuLV (M-MuLV) infection is unknown, and the exact roles of MCF viruses in disease induction remain unclear. Previous comparative studies between M-MuLV and an enhancer variant, Mo+PyF101 MuLV, suggested that MCF generation or early propagation might take place in the bone marrow under conditions of efficient leukemogenesis. Moreover, M-MuLV induces disease efficiently following both intraperitoneal (i.p.) and subcutaneous (s.c.) inoculation but leukemogenicity by Mo+PyF101 M-MuLV is efficient following i.p. inoculation but attenuated upon s. c. inoculation. Time course studies of MCF recombinant appearance in the bone marrow, spleen, and thymus of wild-type and Mo+PyF101 M-MuLV i.p.- and s.c.-inoculated mice were carried out by performing focal immunofluorescence assays. Both the route of inoculation and the presence of the PyF101 enhancer sequences affected the patterns of MCF generation or early propagation. The bone marrow was a likely site of MCF recombinant generation and/or early propagation following i.p. inoculation of M-MuLV. On the other hand, when the same virus was inoculated s.c., the primary site of MCF generation appeared to be the thymus. Also, when Mo+PyF101 M-MuLV was inoculated i.p., MCF generation appeared to occur primarily in the thymus. The time course studies indicated that MCF recombinants are not involved in preleukemic changes such as splenic hyperplasia. On the other hand, MCFs were detected in tumors from Mo+PyF101 M-MuLV s. c.-inoculated mice even though they were largely undetectable at preleukemic times. These results support a role for MCF recombinants late in disease induction.     

Characterization of lymphoid tumors induced by a recombinant murine retrovirus carrying the avian v-myc oncogene. Identification of novel (B-lymphoid) tumors in the thymus

Lymphoid tumors induced by a recombinant murine retrovirus carrying the v-myc oncogene of avian MC29 virus were characterized. The Moloney murine leukemia virus myc oncogene (M-MuLV (myc], carried by an amphotropic MuLV helper, induced tumors in NIH Swiss and NFS/N mice after a relatively long latency (8 to 24 wk). Tumor masses appeared in the thymus, spleen, and lymph nodes. Flow cytometry of the tumor cells indicated that approximately 50% were positive for Thy 1.2. Most of these tumors also expressed one or more other cell surface markers of thymocytes and mature T cells (CD4, CD8). Southern blot hybridization revealed genomic rearrangements for the TCR beta genes. The TCR beta analysis suggested that the M-MuLV(myc)-induced Thy 1.2+ tumors were derived from somewhat less mature cells than tumors induced by M-MuLV, which is a classical non-acute retrovirus lacking an oncogene. The remainder of the M-MuLV(myc)-induced tumors were Thy 1.2-, but they were positive for Ly-5 (B220) and also for MAC-2. The Thy 1.2- tumors were characteristically located in the thymus. However, they were negative for TCR beta gene rearrangements. Some, but not all, of the Thy 1.2- tumors contained rearrangements for Ig genes. Additionally, they typically expressed mRNA specific for B but not for T cells. Thus, these thymic tumors had characteristics of the B cell lineage. Tumor transplantation experiments demonstrated that the Thy 1.2- tumor cells could reestablish in the thymus and spleen of irradiated hosts, and low level expression of the Thy 1 molecule was observed in the thymus but not the spleen on the first passage. After serial passage, one Thy 1- tumor altered its cell surface phenotype to Thy 1low B220-.     

Human thymic epithelial cells are frequently transformed by retroviral vectors encoding simian virus 40.

The thymic microenvironment contains a mixture of phenotypically distinct epithelial cells of varied functions, some of which are unknown. In an attempt to understand their relevance to T cell differentiation in the thymus, human thymic epithelial cell clones from both fetal (SM3-SM5) and postnatal (SM6) thymus were produced by using a defective recombinant retroviral vector encoding the simian virus 40 large T antigen and the neomycin resistance gene. The presence of keratins 8 and 18, desmosomes, and tonofilaments confirmed the epithelial origin of the cell strains. The cells expressed Thy-1 and HLA-Class I at high levels, showed weak-expression antigens defined by TE3B and A2B5, and low to negligible levels of the MR19-defined molecule. When compared with the phenotype of thymic epithelial cells in situ, the cell strains appear to be derived from neuroendocrine components in the outer cortical region of the human thymus. The use of retroviral vectors to transform human thymic epithelium was considerably more efficient than transfection with a plasmid carrying the origin of replication-defective SV40 large T gene. In the latter case, only two cell strains with subcapsular epithelial phenotypes were derived from fetal thymus. With the retroviral vectors, epithelial cell strains could, for the first time, be generated from human postnatal thymus as well as from fetal thymus.     

C-type virus-lymphocyte interactions in developing mouse thymus.

The appearance of C-type virus particles in thymus cells of Swiss mouse embryos, 11.5 to 15.5 days post-conception age (PCA), was studied with the electron microscope. In thymic rudiments of all specimens examined, virus particles were seen in epithelial cytoplasm, budding from epithelial cell surfaces and in extracellular spaces. Lymphoid cells were first seen in thymic rudiments of 13.5 days PCA, and did not display virus particles at this stage. At 14.5 days PCA, thymic lymphocytes had localized plasmalemmal thickenings of high electron-density which were adjacent to extracellular virus particles. Viruses appeared to be penetrating thymic lymphocytes by viropexis in embryos of 15.5 days PCA. At this stage, many lymphocytes also had cytoplasmic virus-containing vesicles and viral buds at their surfaces. These observations suggest the possibility that, in embryos, C-type viruses are transmitted horizontally from thymic epithelium to early populations of thymic lymphocytes.     

AKR leukemogenesis: identification and biological significance of thymic lymphoma receptors for AKR retroviruses.

We have previously demonstrated that in vitro cell lines of mouse thymic lymphomas express surface receptors specific for the retrovirus that induced them. This study extends these observations to an analysis of receptor-bearing cells in the preleukemic and leukemic phases of spontaneous AKR thymic lymphomagenesis. AKR mice regularly begin expressing N-tropic retroviruses (as assayed on NIH fibroblasts by the XC plaque assay) in several tissues early in life; thymic lymphocytes also express these viruses, but are not autonomously transformed. Later thymic lymphomas emerge which are capable of metastasizing in the host of origin or transplanting leukemias into syngeneic hosts. Just prior to the appearance of thymic lymphomas, these mice also begin producing xenotropic retroviruses [as assayed in xenogeneic (For example, mink) fibroblasts], and concomitant with the appearance of the leukemias is the appearance of "recombinant" retroviruses which cause mink fibroblast foci (MCF); these viruses express elements of both N- and X-tropic virus envelopes and N-tropic viral gene products in their cores. Spontaneous AKR leukemias also produce other retroviruses which do not cause XC plaques or mink fibroblast foci; these are called SL viruses. The subject of this study was to test whether in vivo thymocytes in the preleukemic and leukemic periods also bear receptors specific for N-tropic, recombinant MCF and SL AKR retroviruses. We demonstrated that each spontaneous thymic lymphoma does bear receptors that bind viruses produced by the lymphomas and MCF-247 to a high degree and that bind N-ecotropic AKR retroviruses less well. Thymic lymphocytes predominating in the preleukemic period do not express detectable levels of receptors for either of the viruses. In some mice, receptor-positive cells co-exist with receptor-negative cells; only the receptor-positive cells are capable of transplanting leukemia to syngeneic hosts. We conclude that the presence of specific cell surface receptors for lymphoma cell-produced and recombinant AKR retroviruses is a marker for leukemia in these hosts.     

Stable loss of global DNA methylation in the radiation-target tissue--a possible mechanism contributing to radiation carcinogenesis?

Radiation-induced lymphomagenesis and leukemogenesis are complex processes involving both genetic and epigenetic changes. Although genetic alterations during radiation-induced lymphoma- and leukemogenesis are fairly well studied, the role of epigenetic changes has been largely overlooked. Rodent models are valuable tools for identifying molecular mechanisms of lymphoma and leukemogenesis. A widely used mouse model of radiation-induced thymic lymphoma is characterized by a lengthy "pre-lymphoma" period. Delineating molecular changes occurring during the pre-lymphoma period is crucial for understanding the mechanisms of radiation-induced leukemia/lymphoma development. In the present study, we investigated the role of radiation-induced DNA methylation changes in the radiation carcinogenesis target organ--thymus, and non-target organ--muscle. This study is the first report on the radiation-induced epigenetic changes in radiation-target murine thymus during the pre-lymphoma period. We have demonstrated that acute and fractionated whole-body irradiation significantly altered DNA methylation pattern in murine thymus leading to a massive loss of global DNA methylation. We have also observed that irradiation led to increased levels of DNA strand breaks 6 h following the initial exposure. The majority of radiation-induced DNA strand breaks were repaired 1 month after exposure. DNA methylation changes, though, were persistent and significant radiation-induced DNA hypomethylation was observed in thymus 1 month after exposure. In sharp contrast to thymus, no significant persistent changes were noted in the non-target muscle tissue. The presence of stable DNA hypomethylation in the radiation-target tissue, even though DNA damage resulting from initial genotoxic radiation insult was repaired, suggests of the importance of epigenetic mechanisms in the development of radiation-related pathologies. The possible role of radiation-induced DNA hypomethylation in radiation-induced genome instability and aberrant gene expression in molecular etiology of thymic lymphomas is discussed.     

Tissue distribution and timing of appearance of polytropic envelope recombinants during infection with SL3-3 murine leukemia virus or its weakly pathogenic SL3DeltaMyb5 mutant

A time course analysis was performed to identify the sites of formation and timing of appearance of polytropic recombinant viruses following infection of NIH/Swiss mice with the murine retrovirus SL3-3 murine leukemia virus (SL3) or with a weakly pathogenic mutant termed SL3DeltaMyb5. The results indicated that (i) polytropic recombinant viruses occur initially in the thymus of SL3-infected animals, (ii) the timing of appearance of polytropic recombinants in bone marrow is not consistent with their participation in the previously reported formation of transplantable tumor-forming cells at 3 to 4 week postinoculation, and (iii) the efficient generation of recombinant virus is correlated with efficient tumor induction.     

Immortalization of macrophages from mouse bone marrow and fetal liver

Fresh bone marrow (BM)-derived cells infected with the J2 recombinant retrovirus (carrying v-myc and v-raf/mil oncogenes) grow as immortal cell lines belonging to the monocytic lineage. BM cells cultured for 24 h in conventional medium are no longer able to grow following infection with the J2 virus. We investigated whether specific growth factors affected the proliferative response of BM cells to the J2 virus. If the BM cells were cultured for 24 h in the presence of concanavalin A or CSF-1 and then infected with the J2 virus, immortalization of BM cells was observed. Under these conditions, the cell lines that we obtained were shown to belong to the monocytic lineage. We investigated whether target cells for the J2 virus existed in other hematopoietic organs. We observed J2-induced proliferation in fetal liver (FL) but not in spleen or thymus. The cells proliferating in the FL had macrophage characteristics during the early passages. However, some macrophage markers were lost upon extensive in vitro culture. We conclude that we have identified conditions in which J2 virus consistently and selectively stimulates the growth of macrophages from murine bone marrow and a wider range of hematopoietic cells from fetal liver.     

Thymic Dendritic Cells Are Primary Targets for the Oncogenic Virus SL3-3

The murine retrovirus SL3-3 causes malignant transformation of thymocytes and thymic lymphoma in mice of the AKR and NFS strains when they are inoculated neonatally. The objective of the present study was to identify the primary target cells for the virus in the thymuses of these mice. Immunohistochemical studies of the thymus after neonatal inoculation of the SL3-3 virus showed that cells expressing the viral envelope glycoprotein (gp70⁺ cells) were first seen at 2 weeks of age. These virus-expressing cells were found in the cortex and at the corticomedullary junction in both mouse strains. The gp70⁺ cells had the morphology and immunophenotype of dendritic cells. They lacked macrophage-specific antigens. Cell separation studies showed that bright gp70⁺ cells were detected in a fraction enriched for dendritic cells. At 3 weeks of age, macrophages also expressed gp70. At that time, both gp70⁺ dendritic cells and macrophages were found at the corticomedullary junction and in foci in the thymic cortex. At no time during this 3-week period was the virus expressed in cortical and medullary epithelial cells or in thymic lymphoid cells. Infectious cell center assays indicated that cells expressing infectious virus were present in small numbers at 2 weeks after inoculation but increased at 5 weeks of age by several orders of magnitude, indicating virus spread to the thymic lymphoid cells. Thus, at 2 weeks after neonatal inoculation of SL3-3, thymic dendritic cells are the first cells to express the virus. At 3 weeks of age, macrophages also express the virus. In subsequent weeks, the virus spreads to the thymocytes. This pathway of virus expression in the thymus allows the inevitable provirus integration in a thymocyte that results in a clonal lymphoma.     

Free and integrated recombinant murine leukemia virus DNAs appear in preleukemic thymuses of AKR/J mice.

We studied the appearance and structure of murine leukemia viral genomes in preleukemic AKR/J mice by Southern hybridization. Up to an average of one to two copies per thymocyte of unintegrated murine leukemia virus DNA appears in the thymuses of preleukemic mice beginning at 4 to 5 months of age and disappears in leukemic thymuses. The free viral genomes are absent in the spleens, livers, and brains of preleukemic mice. Using a series of ecotropic and nonecotropic murine leukemia virus hybridization probes, we showed that the unintegrated viral genomes are structurally analogous to those of recombinant mink cell focus-forming viruses that appear as proviruses in leukemic AKR thymocytes, suggesting that these free viral DNAs are the direct precursors to the leukemia-specific proviruses. The mosaic of ecotropic and nonecotropic sequences within these unintegrated viral DNAs varies from one preleukemic thymus to another but often appears structurally homogeneous within individual thymuses, indicating that often each thymus was being infected by a unique mink cell focus-forming virus. Analysis of high-molecular-weight DNA shows that recombinant proviruses reside in the chromosomal DNA of thymocytes within the preleukemic thymus, with the number rising to an average of several copies per thymocyte, but we do not detect any preferred integration sites. These results suggest that, in general, before the development of thymic leukemias in AKR mice there is a massive infection by a unique mink cell focus-forming virus which then integrates into many different sites of individual thymocytes, one of which grows out to become a tumor.     

Pathogenesis of feline leukemia virus T17: contrasting fates of helper, v-myc, and v-tcr proviruses in secondary tumors.

A naturally occurring feline thymic lymphosarcoma (T17) provided the unique observation of a T-cell antigen receptor beta-chain gene (v-tcr) transduced by a retrovirus. The primary tumor contained three classes of feline leukemia virus (FeLV) provirus, which have now been characterized in more detail as (i) v-tcr-containing recombinant proviruses, (ii) v-myc-containing recombinant proviruses, and (iii) apparently full-length helper FeLV proviruses. The two transductions appear to have been independent events, with distinct recombinational junctions and no sequence overlap in the host-derived inserts. The T17 tumor cell line releases large numbers of FeLV particles of low infectivity; all three genomes are encapsidated, but passage of FeLV-T17 on feline fibroblast and lymphoma cells led to selective loss of the recombinant viruses. The oncogenic potential of the T17 virus complex was, therefore, tested by infection of neonatal cats with virus harvested directly from the primary T17 tumor cell line. A single inoculation of FeLV-T17 caused persistent low-grade infection culminating in thymic lymphosarcoma and acute thymic atrophy, which was accelerated by coinfection with the weakly pathogenic FeLV subgroup A (FeLV-A)/Glasgow-1 helper. Molecularly cloned FeLV-tcr virus (T-31) rescued for replication by a weakly pathogenic FeLV-A/Glasgow-1 helper virus was similarly tested in vivo and induced thymic atrophy and thymic lymphosarcomas. Most FeLV-T17-induced tumors manifested either v-myc or an activated c-myc allele and had undergone rearrangement of endogenous T-cell antigen receptor beta-chain genes, supporting the proposition that the oncogenic effects of c-myc linked to the FeLV long terminal repeat are targeted to a specific window in T-cell differentiation. However, neither the FeLV-T17-induced tumors nor the T-31 + FeLV-A-induced tumors contained clonally represented v-tcr sequences. Only one of the FeLV-T17-induced tumors contained detectable v-tcr proviruses, at a low copy number. While v-tcr does not have a readily transmissible oncogenic function, a more restricted role is not excluded, perhaps involving antigenic peptide-major histocompatibility complex recognition by the T-cell receptor complex. Such a function could be obscured by the genetic diversity of the outbred domestic cat host.     

The leukemogenic potential of an enhancer variant of Moloney murine leukemia virus varies with the route of inoculation.

We previously showed that the Mo+PyF101 variant of Moloney murine leukemia virus (M-MuLV) is poorly leukemogenic when inoculated subcutaneously (s.c.) into neonatal mice. We recently found that intraperitoneal (i.p.) inoculation of neonatal mice with the same virus significantly enhanced its leukemogenicity. In this study, infections of neonatal mice by the two different routes of inoculation were compared. We studied replication of the virus in vivo to identify critical preleukemic events. These would be observed in mice inoculated i.p. by Mo+PyF101 M-MuLV but not when inoculation was s.c. Infectious center assays indicated that regardless of the route of inoculation, Mo+PyF101 M-MuLV showed delayed infection of the thymus compared with wild-type M-MuLV. On the other hand, i.p.-inoculated mice showed more rapid appearance of infectious centers in the bone marrow than did s.c.-inoculated animals. Thus, the enhanced leukemogenicity of i.p. inoculation correlated with efficient early infection of the bone marrow and not with early infection of the thymus. These results suggest a role for bone marrow infection for efficient leukemogenesis in Mo+PyF101 M-MuLV-infected mice. Consistent with this notion, if bone marrow infection was decreased by injecting 10- to 12-day-old animals i.p., leukemogenicity resembled that of s.c. inoculation. Thus, two cell types that are critical for the induction of efficient leukemia were implicated. One cell delivers virus from the site of s.c. inoculation (the skin) to the bone marrow and is apparently restricted for Mo+PyF101 M-MuLV replication. The second cell is in the bone marrow, and its early infection is required for efficient leukemogenesis.     

Changes in thymocyte proliferation at different stages of viral leukemogenesis in AKR mice

Proliferation in total populations of thymocytes from control AKR mice or AKR mice injected intrathymically with MCF 69L1 virus was measured by flow cytometry of acridine orange-stained cells. Cell sorting experiments showed that the majority subpopulations of small cortical and medullary thymocytes in control mice were noncycling and were predominantly in the Go phase of the cell cycle. Of the 15 to 20% cycling thymic lymphoblasts, approximately 50% were in the G1 phase, 35% were in the S phase, and 15% were in the G2 + M phases of the cell cycle. Cycling cells appeared to consist of a major subpopulation with low RNA content and a minority subpopulation with high RNA content. In virus-injected mice, no changes in cell cycling were observed at stage I of leukemogenesis (30 to 40 days postinjection), at which time infection of thymocytes by MCF virus is maximum and constant but no clonality is evident. Thus, MCF virus infection of thymocytes per se does not appear to alter cell proliferation. Increased cell cycling and a shift in cell cycle distribution to more cells in G1 was observed at stage II of leukemogenesis (50 to 60 days postinjection), at which time a clonally expanded cell population is known to emerge in thymuses of injected mice. Acridine orange staining resolved these novel cycling cells from subpopulations of normal thymic lymphoblasts on the basis of intermediate RNA content. The transition from stage II to stage III (50 to 60 days postinjection) was accompanied by the outgrowth of a major cycling population with a distinct, often increased, RNA content. As a result, the residual "normal" background of cycling cells often observed in stage II was markedly reduced or completely absent by stage III. Populations of cycling blasts from mice with frank leukemia differed from those at stage III by a variability in mean RNA content and in cell cycle distribution indicative of individual tumor heterogeneity. In addition, thymomas often contained multiple populations of cycling blasts that could be resolved by their discrete RNA distributions. Simultaneous staining of DNA and RNA by acridine orange appears particularly well-suited for studying a heterogeneous population of cycling and noncycling cells represented by mouse thymus. This method has permitted a rapid and quantitative analysis of cell cycle parameters at progressive stages of viral leukemogenesis in AKR mice.     

Comparison of endogenous murine leukemia virus proviral organization and RNA expression in 3-methylcholanthrene-induced and spontaneous thymic lymphomas in RF and AKR mice.

3-Methylcholanthrene-induced T-cell thymic lymphomas in RF mice were examined for involvement of murine leukemia virus (MuLV)-related sequences in leukemogenesis. Both the expression of MuLV-related RNA species and the organization of endogenous MuLV proviral DNA were analyzed. Of 27 primary tumors examined, only 5 exhibited elevated MuLV-related RNA species homologous to xenotropic specific env DNA. None of these RNA species hybridized with ecotropic p15E DNA sequences. Only two of these five tumors contained MuLV-like RNA species that hybridized with ecotropic MuLV long terminal repeat sequences, despite the probe's ability to detect both ecotropic MuLV and mink cell focus-inducing viral RNA. No muLV resembling mink cell focus-inducing virus whose expression could be correlated with lymphomagenesis was detected in either preleukemic thymocytes, primary 3-methylcholanthrene-induced thymic tumors, tumors passaged in vivo, or cell lines derived from tumors. Restriction endonuclease analysis of DNA from both primary tumors and cell lines failed to reveal either proviral DNA with recombinant env genes or rearrangement of endogenous MuLV proviruses. Therefore, chemically induced lymphomagenesis in RF mice appears different from the spontaneous lymphomagenic process in AKR mice with respect to the involvement of endogenous MuLV sequences.     

Generation of murine stromal cell lines supporting hematopoietic stem cell proliferation by use of recombinant retrovirus vectors encoding simian virus 40 large T antigen.

The bone marrow is a complex microenvironment made up of multiple cell types which appears to play an important role in the maintenance of hematopoietic stem cell self-renewal and proliferation. We used murine long-term marrow cultures and a defective recombinant retrovirus vector containing the simian virus 40 large T antigen to immortalize marrow stromal cells which can support hematopoiesis in vitro for up to 5 weeks. Such cloned cell lines differentially supported stem cells which, when transplanted, allowed survival of lethally irradiated mice, formed hematopoietic spleen colonies in vivo, and stimulated lymphocyte proliferation in vitro. Molecular and functional analyses of these cell lines did not demonstrate the production of any growth factors known to support the proliferation of primitive hematopoietic stem cells. All cell lines examined produced macrophage colony-stimulating factor. The use of immortalizing retrovirus vectors may allow determination of unique cellular proteins important in hematopoietic stem cell proliferation by the systematic comparison of stromal cells derived from a variety of murine tissues.     

Subgenomic fragment of molecular cloned Friend murine leukemia virus DNA contains the gene(s) responsible for Friend murine leukemia virus-induced disease.

Friend murine leukemia virus (G-MuLV) is a helper-independent, type C retrovirus isolated from stocks of Friend virus complex (spleen focus-forming virus plus MuLV). In cell culture, F-MuLV has an ecotropic and NB-tropic host range and causes XC cells to fuse. When injected into newborn NIH Swiss mice, F-MuLV produces hepatosplenomegaly, severe anemia, and numerous circulating hematopoietic precursors in the peripheral blood with normal thymus and lymph nodes after 3 to 6 weeks. Recently, we molecularly cloned an 8.5-kilobase pair (kbp) form of F-MuLV DNA from which we could recover the pathogenic F-MuLV virus by DNA transfection of NIH 3T3 cells. From this molecularly cloned F-MuLV DNA, we have now subcloned in pBR322 a 4.1-kbp HindIII fragment which contains in continuity 3.0 kbp from the 3' terminus (env and c region), 0.6 kbp of the terminal repeat sequences, and 0.5 kbp from the 5'terminus of the viral RNA (genome). NIH 3T3 fibroblasts were transfected with this DNA fragment an then infected with the wild mouse amphotropic retrovirus (cl 1504-A). In cell culture, 1504-A is a helper-independent type C virus which has an N-tropic host range and does not cause fusion of XC cells. When injected into newborn NIH Swiss mice, 1504-A does not produce splenomegaly or thymic enlargement in mice held for up to 8 months. The transfection with the F-MuLV fragment and the infection with 1504-A consistently yielded virus preparations that were XC positive. From such virus stocks we were able to isolate both helper-independent and replication-defective XC-positive viruses. The helper-independent virus was shown to be a recombinant virus since it contains a gp70 molecule derived at least in part from F-MuLV and a specific gag precursor derived from 1504-A as determined by radioactive immune precipitation assays. When injected into newborn Swiss mice, the recombinant helper-independent virus caused hepatosplenomegaly in approximately 50% of the mice in 6 to 8 weeks. The histology of the diseased splenic tissue was indistinguishable from that seen in the disease caused by the whole F-MuLV. The replication-defective virus could be pseudotyped with new 1504-A virus, and this viral complex also caused the F-MuLV disease picture when the complex was injected into newborn Swiss mice. We conclude that the genetic information responsible for the pathogenicity of F-MuLV is contained within the 4.1-kbp DNA fragment, which includes env gene sequences, the terminal repeat sequences, and the c region sequences of the F-MuLV genome.     

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.