Transformation of murine pre-B-lymphocytes by v-erb-B: progression to growth factor independence and tumorigenicity.

v-erb-B is the principal transforming gene of avian erythroblastosis virus, a replication defective retrovirus that transforms erythroid and fibroblast cells in vitro and causes erythroleukemia and fibrosarcoma in vivo. We have used a recombinant murine retrovirus, based on the truncated genome of Moloney murine leukemia virus and containing a chimeric gag-v-erb-B gene, to determine the murine hematopoietic cells transformed by v-erb-B. Infection of day 16.5 murine embryonal cells in liquid culture with this virus resulted in the outgrowth of foci of loosely to non-adherent hematopoietic cells which grew in close association with an adherent monolayer. After several weeks in culture a clonal population of transformed pre-B-lymphocytes emerged from this transformation initiated, though still growth factor dependent, population. These transformed cells were growth factor independent, and were tumorigenic in syngeneic mice. The results indicate that although v-erb-B can initiate transformation of murine hematopoietic cells, additional events are required for establishment of the fully transformed growth factor independent, tumorigenic phenotype. This v-erb-B induced progression from growth factor dependence to independence provides an in vitro model system for analysing events involved in the initiation and maintenance of leukemia.

Transformation of early erythroid precursor cells (BFU-E) by a recombinant murine retrovirus containing v-erb-B.

Avian erythroblastosis virus (AEV) is a replication-defective retrovirus that transforms erythroid and fibroblast cells in vitro and in vivo. The transforming ability of AEV is due primarily to the oncogene v-erb-B. A recombinant murine retrovirus has been constructed by inserting a chimeric gag-v-erb-B gene into a Moloney murine leukemia virus based vector. This retrovirus was used to examine v-erb-B-induced transformation of murine hematopoietic cells. Infection of murine primary fetal liver, adult bone marrow or adult spleen cells with the recombinant virus generated large hemoglobinized erythroid colonies in the absence of exogenous growth factors. Generation of such colonies usually requires the presence of erythropoietin (Epo) and interleukin-3 (IL-3). These growth-factor independent colonies were shown to be derived from early (BFU-E) and not late (CFU-E) erythroid progenitor cells, and the effect was not attributable to growth factors elicited by the virus-producing cell lines. In order to confirm that the recombinant virus was responsible for this transformation of BFU-E to growth factor independence, bone marrow cells from post 5-fluorouracil treated mice were infected and used to repopulate lethally-irradiated mice. Growth factor-independent BFU-E were obtained in up to 30% of day-13 spleen colonies and it was shown by DNA analysis that cells from these colonies contained integrated provirus. Our results indicate that v-erb-B transforms early erythroid progenitors to growth factor independent growth and subsequent differentiation to erythrocytes -a process that normally requires Epo plus either IL-3 or granulocyte-macrophage colony stimulating factor (GM-CSF).

Transformation of murine myelomonocytic cells by myc: point mutations in v-myc contribute synergistically to transforming potential.

The v-myc oncogenes of chicken retroviruses (including MC29) bear point mutations relative to chicken c-myc. These mutations result in several amino acid differences in the encoded proteins. We have used recombinant murine retroviruses containing various myc alleles to analyse the myelomonocytic transforming potential of the myc oncogene. The myc alleles used were MC29 v-myc, chicken c-myc, chimeric genes combining 5' sections of v- or c-myc with 3' sections of c- or v-myc, and mouse c-myc. The same retroviral vector (based on the genome of Moloney leukemia virus) was used for each allele and the genes were translated from genomic message. By infecting the primary mouse tissues, bone marrow, peritoneal-derived macrophages and mixed embryonic tissue with the recombinant viruses, variation was found in the transforming efficacy of these alleles: v-myc was most effective, followed by the two chimeric genes, whereas c-myc (chicken or mouse) was least effective in eliciting myelomonocytic transformation. Viral gag sequences were not necessary for this transformation. In each case, the transformed monocytes were growth factor-dependent and non-immortal. However, v-myc transformed monocytes (though not monocytes transformed by other myc alleles) were able to progress to an immortal, growth factor-independent phenotype. Our results indicate that v-myc is far more effective than c-myc in eliciting myelomonocytic transformation; that this is due to combinatorial effects of 5' and 3' mutations in the v-myc gene; and that secondary events in addition to these mutations are required for transformation of myelomonocytic cells to an immortal, tumorigenic phenotype.