Coinfection with viruses carrying the v-Ha-ras and v-myc oncogenes leads to growth factor independence by an indirect mechanism

bcr/abl and src but not myc and ras replace v-abl in lymphoid transformation

Lymphoid cells transformed by temperature-sensitive Abelson virus die at the nonpermissive temperature. This property was exploited to show that bcr/abl and v-src but not myc and ras can replace the transforming signal of v-abl, a result suggesting that the former but not the latter oncogenes transform lymphoid cells via a similar pathway.

bcr/abl and src but not myc and ras replace v-abl in lymphoid transformation

Lymphoid cells transformed by temperature-sensitive Abelson virus die at the nonpermissive temperature. This property was exploited to show that bcr/abl and v-src but not myc and ras can replace the transforming signal of v-abl, a result suggesting that the former but not the latter oncogenes transform lymphoid cells via a similar pathway.

Tyrosine kinase oncogenes abrogate interleukin-3 dependence of murine myeloid cells through signaling pathways involving c-myc: conditional regulation of c-myc transcription by temperature-sensitive v-abl

Retroviral expression vectors carrying the tyrosine kinase oncogenes abl, fms, src, and trk abrogate the requirements of murine myeloid FDC-P1 cells for interleukin-3 (IL-3). Factor-independent clones constitutively express c-myc in the absence of IL-3, whereas in parental cultures c-myc transcription requires the presence of the ligand. To directly test the effect of a tyrosine kinase oncogene on c-myc expression, retroviral constructs containing three different temperature-sensitive mutants of v-abl were introduced into myeloid IL-3-dependent FDC-P1 and 32D cells. At the permissive temperature, clones expressing temperature-sensitive abl behaved like wild-type abl-containing cells in their growth properties and expressed c-myc constitutively. Temperature shift experiments demonstrated that both IL-3 abrogation and the regulation of c-myc expression correlated with the presence of functional v-abl. Induction of c-myc expression by reactivation of temperature-sensitive v-abl mimicked c-myc induction by IL-3 in that it did not require protein synthesis and occurred at the level of transcription, with effects on both initiation and a transcription elongation block. However, v-abl-regulated FDC-P1 cell growth differed from IL-3-regulated growth in that c-fos and junB, which are normally induced by IL-3, were not induced by activation of v-abl.

Tyrosine kinase oncogenes abrogate interleukin-3 dependence of murine myeloid cells through signaling pathways involving c-myc: conditional regulation of c-myc transcription by temperature-sensitive v-abl

Retroviral expression vectors carrying the tyrosine kinase oncogenes abl, fms, src, and trk abrogate the requirements of murine myeloid FDC-P1 cells for interleukin-3 (IL-3). Factor-independent clones constitutively express c-myc in the absence of IL-3, whereas in parental cultures c-myc transcription requires the presence of the ligand. To directly test the effect of a tyrosine kinase oncogene on c-myc expression, retroviral constructs containing three different temperature-sensitive mutants of v-abl were introduced into myeloid IL-3-dependent FDC-P1 and 32D cells. At the permissive temperature, clones expressing temperature-sensitive abl behaved like wild-type abl-containing cells in their growth properties and expressed c-myc constitutively. Temperature shift experiments demonstrated that both IL-3 abrogation and the regulation of c-myc expression correlated with the presence of functional v-abl. Induction of c-myc expression by reactivation of temperature-sensitive v-abl mimicked c-myc induction by IL-3 in that it did not require protein synthesis and occurred at the level of transcription, with effects on both initiation and a transcription elongation block. However, v-abl-regulated FDC-P1 cell growth differed from IL-3-regulated growth in that c-fos and junB, which are normally induced by IL-3, were not induced by activation of v-abl.

A v-H-ras-dependent hemopoietic tumor model involving progression from a clonal stage of transformation competence to autocrine interleukin 3 production

Autocrine interleukin 3 (IL-3)-secreting tumors were generated from an IL-3-dependent mouse mast cell line (PB-3c) after introduction of the v-H-ras oncogene. Tumor progression was characterized by four distinct phenotypes. The first corresponded to immortalized mast cells unresponsive to the oncogenic effect of v-H-ras. The second was expressed in a clonable subpopulation of PB-3c cells and was marked by the competence to form v-H-ras-dependent tumors (immortalized transformation competence). The third was a direct effect of v-H-ras expression on all PB-3c cells and was characterized in vitro by a reduced IL-3 requirement. Upon injection of v-H-ras-expressing, transformation-competent cells into mice, the final, fully malignant phenotype developed with a long latency period and was marked in vitro by independence of exogenous IL-3 and by autocrine IL-3 stimulation. Northern (RNA) blot analysis and an RNase A-T1 protection assay showed that IL-3 production was strictly associated with the tumor phenotype. Two of six tumors showed an alteration at the 5' region of the IL-3 gene. We conclude that v-H-ras required complementation by IL-3 gene rearrangement or an alternate event to generate autocrine mastocytomas.

Oncogene cooperation in lymphocyte transformation: malignant conversion of E mu-myc transgenic pre-B cells in vitro is enhanced by v-H-ras or v-raf but not v-abl

Although transgenic mice bearing a c-myc gene controlled by the immunoglobulin heavy-chain enhancer (E mu) eventually develop B-lymphoid tumors, B-lineage cells from preneoplastic bone marrow express the transgene but do not grow autonomously or produce tumors in mice. To determine whether other oncogenes can cooperate with myc to transform B-lineage cells, we compared the in vitro growth and tumorigenicity of normal and E mu-myc bone marrow cells infected with retroviruses bearing the v-H-ras, v-raf, or v-abl oncogene. The v-H-ras and v-raf viruses both generated a rapid polyclonal expansion of E mu-myc pre-B bone marrow cells in liquid culture and 10- to 100-fold more pre-B lymphoid colonies than normal in soft agar. The infected transgenic cells were autonomous, cloned efficiently in agar, and grew as tumors in nude mice. While many pre-B cells from normal marrow could also be induced to proliferate by the v-raf virus, these cells required a stromal feeder layer, did not clone in agar, and were not malignant. Most normal cells stimulated to grow by v-H-ras also cloned poorly in agar, and only rare cells were tumorigenic. With the v-abl virus, no more cells were transformed from E mu-myc than normal marrow and the proportion of tumorigenic pre-B clones was not elevated. These results suggest that both v-H-ras and v-raf, but apparently not v-abl, collaborate with constitutive myc expression to promote autonomous proliferation and tumorigenicity of pre-B lymphoid cells.

A v-H-ras-dependent hemopoietic tumor model involving progression from a clonal stage of transformation competence to autocrine interleukin 3 production

Autocrine interleukin 3 (IL-3)-secreting tumors were generated from an IL-3-dependent mouse mast cell line (PB-3c) after introduction of the v-H-ras oncogene. Tumor progression was characterized by four distinct phenotypes. The first corresponded to immortalized mast cells unresponsive to the oncogenic effect of v-H-ras. The second was expressed in a clonable subpopulation of PB-3c cells and was marked by the competence to form v-H-ras-dependent tumors (immortalized transformation competence). The third was a direct effect of v-H-ras expression on all PB-3c cells and was characterized in vitro by a reduced IL-3 requirement. Upon injection of v-H-ras-expressing, transformation-competent cells into mice, the final, fully malignant phenotype developed with a long latency period and was marked in vitro by independence of exogenous IL-3 and by autocrine IL-3 stimulation. Northern (RNA) blot analysis and an RNase A-T1 protection assay showed that IL-3 production was strictly associated with the tumor phenotype. Two of six tumors showed an alteration at the 5' region of the IL-3 gene. We conclude that v-H-ras required complementation by IL-3 gene rearrangement or an alternate event to generate autocrine mastocytomas.

Oncogene cooperation in lymphocyte transformation: malignant conversion of E mu-myc transgenic pre-B cells in vitro is enhanced by v-H-ras or v-raf but not v-abl

Although transgenic mice bearing a c-myc gene controlled by the immunoglobulin heavy-chain enhancer (E mu) eventually develop B-lymphoid tumors, B-lineage cells from preneoplastic bone marrow express the transgene but do not grow autonomously or produce tumors in mice. To determine whether other oncogenes can cooperate with myc to transform B-lineage cells, we compared the in vitro growth and tumorigenicity of normal and E mu-myc bone marrow cells infected with retroviruses bearing the v-H-ras, v-raf, or v-abl oncogene. The v-H-ras and v-raf viruses both generated a rapid polyclonal expansion of E mu-myc pre-B bone marrow cells in liquid culture and 10- to 100-fold more pre-B lymphoid colonies than normal in soft agar. The infected transgenic cells were autonomous, cloned efficiently in agar, and grew as tumors in nude mice. While many pre-B cells from normal marrow could also be induced to proliferate by the v-raf virus, these cells required a stromal feeder layer, did not clone in agar, and were not malignant. Most normal cells stimulated to grow by v-H-ras also cloned poorly in agar, and only rare cells were tumorigenic. With the v-abl virus, no more cells were transformed from E mu-myc than normal marrow and the proportion of tumorigenic pre-B clones was not elevated. These results suggest that both v-H-ras and v-raf, but apparently not v-abl, collaborate with constitutive myc expression to promote autonomous proliferation and tumorigenicity of pre-B lymphoid cells.

Lability of leukosis virus enhancer-binding proteins in avian hematopoeitic cells

Bursal lymphomas induced by avian leukosis virus (ALV) are characterized by integration of long terminal repeat (LTR) enhancer sequences next to the myc proto-oncogene and by subsequent myc hyperexpression. Nuclear runoff transcription analyses have shown that protein synthesis inhibition specifically decreases transcription of LTR-enhanced genes in bursal lymphoma cell lines (M. Linial, N. Gunderson, and M. Groudine, Science 230:1126-1132, 1985). Here, we show that LTR-enhanced transcription is also labile in nontransformed bursa, bone marrow, and spleen but not in other ALV-infected tissues from lymphoma-susceptible chickens. The bursal cells demonstrated this lability of LTR-enhanced transcription only at an early stage of development, when chickens are susceptible to ALV-induced lymphomagenesis. Mature bursal cells show stable LTR transcription enhancement (unaffected by inhibition of protein synthesis) and are not susceptible to lymphomagenesis. In lymphoma-resistant chicken strains, LTR-enhanced transcription was stable in all tissues during development. These data suggest that lability of LTR transcription enhancement in hematopoietic cells is involved in susceptibility to lymphomagenesis, and we propose a model for the action of these labile enhancing factors. Gel shift analysis of nuclear proteins from lymphoma cells indicated that four or more binding proteins specifically interact with the three LTR enhancer regions. These proteins can be separated by their differential sensitivity to heat treatment or protein synthesis inhibition. The lability of a subset of these binding proteins correlates with lability of LTR-enhanced transcription in certain lymphoid cell types, suggesting that these proteins are essential for LTR transcription enhancement.

Partial reversion of the transformed phenotype in HRAS-transfected tumorigenic cells by transfer of a human gene

The transformed phenotype of rat FE-8 cells transfected by an activated human HRAS gene was suppressed upon fusion with normal cells. An experimental approach was developed to identify and isolate a human gene capable of suppressing the transforming activity of the HRAS oncogene in FE-8 cells. Genomic DNA from human placenta was introduced into FE-8 cells by cotransfection with the plasmid pY3 conferring hygromycin B resistance. Transfectants were selected in medium containing hygromycin B. HRAS-transformed FE-8 cells showed an increased sensitivity toward ouabain when compared to their normal counterparts. Therefore, the population of transfected hygromycin B-resistant cells was treated with ouabain to eliminate cells with a transformed phenotype. Ouabain selection resulted in a small number of cell clones exhibiting a more normal phenotype. The clones had lost the morphology of transformed cells and required anchorage for growth. The tumorigenicity of transfectants in nude mice was reduced but not completely abolished. FE-8 revertants continued to express the p21 RAS protein. Human repetitive sequences contained in the DNA of a secondary transfectant were used for isolation of the suppressor gene from reverted FE-8 cells. The cloned DNA fragment was transfected into tumorigenic FE-8 cells and conferred a partial reversion of the transformed phenotype.

Nature and specificity of lymphokine independence induced by a selectable retroviral vector expressing v-src

A murine retroviral vector, LSNLsrc, has been constructed and examined for its ability to induce growth factor independence in cells normally dependent on interleukin 2 (IL-2) or interleukin 3 (IL-3) for growth. The LSNLsrc vector coexpressed the v-src gene of Rous sarcoma virus and the neo gene from transposon Tn5, allowing infected cells to be selected on the basis of G418 resistance. The murine cell lines CTLL-2 and FD.C/1, which are dependent for growth on IL-2 and IL-3, respectively, were both readily infected with the LSNLsrc virus. LSNLsrc-infected, G418-resistant cultures of FD.C/1 cells were able to give rise to IL-3-independent progeny, but all G418-resistant CTLL-2 cells retained normal IL-2 dependence. The induction of IL-3 independence by v-src was not a direct event, since limiting dilution analysis of the LSNLsrc-infected FD.C/1 cells showed that most of them were IL-3 dependent, despite expression of v-src mRNA and active pp60v-src kinase. However, clones selected from this population in the presence of IL-3 were able to undergo a subsequent progression event and generate IL-3-independent progeny. The generation of factor-independent variants in the clonal cultures was a rare event, as witnessed by the death of most of the cells in each clone when IL-3 was withdrawn. Together, these data indicate that a secondary event, in addition to v-src expression, was required to generate IL-3-independent growth. No evidence was found for an autocrine mechanism of transformation involving IL-2, IL-3, interleukin 4, or granulocyte-macrophage colony-stimulating factor.

Nature and specificity of lymphokine independence induced by a selectable retroviral vector expressing v-src

A murine retroviral vector, LSNLsrc, has been constructed and examined for its ability to induce growth factor independence in cells normally dependent on interleukin 2 (IL-2) or interleukin 3 (IL-3) for growth. The LSNLsrc vector coexpressed the v-src gene of Rous sarcoma virus and the neo gene from transposon Tn5, allowing infected cells to be selected on the basis of G418 resistance. The murine cell lines CTLL-2 and FD.C/1, which are dependent for growth on IL-2 and IL-3, respectively, were both readily infected with the LSNLsrc virus. LSNLsrc-infected, G418-resistant cultures of FD.C/1 cells were able to give rise to IL-3-independent progeny, but all G418-resistant CTLL-2 cells retained normal IL-2 dependence. The induction of IL-3 independence by v-src was not a direct event, since limiting dilution analysis of the LSNLsrc-infected FD.C/1 cells showed that most of them were IL-3 dependent, despite expression of v-src mRNA and active pp60v-src kinase. However, clones selected from this population in the presence of IL-3 were able to undergo a subsequent progression event and generate IL-3-independent progeny. The generation of factor-independent variants in the clonal cultures was a rare event, as witnessed by the death of most of the cells in each clone when IL-3 was withdrawn. Together, these data indicate that a secondary event, in addition to v-src expression, was required to generate IL-3-independent growth. No evidence was found for an autocrine mechanism of transformation involving IL-2, IL-3, interleukin 4, or granulocyte-macrophage colony-stimulating factor.