Carlo Moscovici

Continuous tissue culture cell lines derived from chemically induced tumors of Japanese quail

Several continuous tissue culture cell lines were established from methylcholanthrene-induced fibrosarcomas of Japanese quail. The lines consist either of fibroblastic elements, round refractile cells or polygonal cells. They show transformed characteristics in agar colony formation and hexose uptake, and most are tumorigenic. Their cloning efficiency in plastic dishes is not increased over that of normal quail embryo fibroblasts. The quail tumor cell lines do not produce endogenous avian oncoviruses and fail to complement the Bryan high titer strain of Rous sarcoma virus; those tested lack the p27 protein of avian oncoviruses. Most of the cell lines are susceptible to subgroup A avian sarcoma viruses, but are relatively resistant to viruses of subgroups C, E and F as compared to normal quail embryo fibroblasts.

The product of the retroviral transforming gene v-myb is a truncated version of the protein encoded by the cellular oncogene c-myb

Avian myeloblastosis virus (AMV) is an oncogenic retrovirus that rapidly causes myeloblastic leukemia in chickens and transforms myeloid cells in culture. AMV carries an oncogene, v-myb, that is derived from a cellular gene, c-myb, found in the genomes of vertebrate species. We constructed a plasmid vector that allows expression of a portion of the coding region for v-myb in a procaryotic host. We then used the myb-encoded protein produced in bacteria to immunize rabbits. The antisera obtained permitted identification of the proteins encoded by both v-myb and chicken c-myb. The molecular weights of the products of v-myb and c-myb (45,000 and 75,000 respectively) indicate that the v-myb protein is an appreciably truncated version of the c-myb protein.

Leukemic Transformation with Avian Myeloblastosis Virus: Present Status

Many RNA and DNA tumor viruses induce neoplastic transformation in vitro, but few of these are leukemia viruses acting on hematopoietic target cells. The virus of avian myeloblastosis (AMV) is such an agent, capable of producing morphological changes in hematopoietic tissues grown in vitro, and thus provides an excellent model to study leukemia induction at the cellular level.

Site-specific mutagenesis of avian erythroblastosis virus: erb-B is required for oncogenicity

Avian erythroblastosis virus (AEV) induces both erythroblastosis and fibrosarcomas in susceptible birds. Two domains within its replication-defective genome, erb-A and erb-B, have been implicated in AEV-mediated oncogenesis. An efficient transfection system for generating infectious, transforming virus from molecular clones of AEV and RAV-1 (helper virus) was combined with the techniques of site-specific mutagenesis to investigate the contribution of erb-B to the two forms of oncogenesis induced by AEV. Deletion and frameshift mutations were constructed in the erb-B locus of cloned AEV DNA in vitro. Infectious retroviruses harboring these mutations were recovered and their ability to transform fibroblasts in vitro or induce erythroleukemia in vivo was assessed. The presence of mutant viral genomes in chick embryo fibroblasts or erythroblasts of infected birds was confirmed by suitable biochemical analyses. Expression of viral genes in cells infected with AEV mutants was examined by immunoprecipitation with antisera to erb-A and erb-B proteins. It was found that the product of erb-B is necessary for transformation of fibroblasts and induction of erythroblastosis by AEV, although a small portion of this protein at the carboxy terminus is dispensable.

The defectiveness of Mill Hill 2, a carcinoma-inducing avian oncovirus.

Abstract The avian carcinoma virus Mill Hill 2 (MH2) transforms fibroblasts and macrophages in tissue culture. It is defective in replication and dependent on a helper virus, MH2 AV, for the production of infectious progeny. MH2 AV contains both subgroup C and A envelope determinants; its helper functions are required by MH2 in the env, pol, and probably also the gag genes. The defects of MH2 can be complemented only by helper viruses of the chicken leukosis group, further suggesting that MH2 is defective in gag or pol , or both. MH2 transformed nonproducer cells synthesize an aberrant viral polyprotein of 100,000 daltons. This MH2p100 carries antigenic determinants of the gag protein p27, but not of the env protein gp85. It is not cleaved into smaller, functional proteins and is not glycosylated.

EGF-R as a hemopoietic growth factor receptor: The c-erbB product is present in chicken erythrocytic progenitors and controls their self-renewal

c-erbB, encoding the EGF receptor (EGF-R), was originally identified as the cellular homolog of a chicken leukemia oncogene. In humans, EGF-R is distributed widely except in hemopoietic tissues, and its amplification is associated with epidermal and glial malignancies. Here we show that c-erbB is present in normal chicken erythrocytic progenitors and transmits the mitogenic signal induced by TGF alpha. Cells that contain high affinity EGF-R are at approximately the BFU-E stage, and their long-term renewal can be induced by TGF alpha. Upon addition of insulin and erythropoietin, they can be induced to terminally differentiate into red cells. We previously demonstrated that v-erbA blocks differentiation of chicken erythrocytic progenitors but does not abrogate their growth factor dependence for proliferation. These data indicate that proliferation and differentiation are not necessarily coupled in these cells. They also demonstrate a direct role of c-erbB in the control of self-renewal of normal chicken erythrocytic progenitors and could account for the predominant leukemogenic potential of the chicken erbB gene.

Characterization of the hemopoietic target cells for the avian leukemia virus E26

The dual leukemogenic response, involving both the erythroid and myeloid hemopoietic systems in chickens infected with E26 virus, has previously been described (C. Moscovici, J. Samarut, L. Gazzolo, and M. G. Moscovici, 1981. Virology 113, 765-768; K. Radke, H. Beug, S. Kornfeld, and T. Graf, 1982. Cell 31, 643-653). Similarly, the in vitro response of the two lineages resulted in the concomitant transformation and proliferation of erythroblast and myeloblast leukemic cells. The present study, using embryonic tissues at very early stages of development, was valuable in implying that E26 target cells are recruited among uncommitted erythroid-myeloid stem cells as well as myeloid- or erythroid-committed progenitor cells. Therefore, E26 may be the first avian retrovirus capable of interacting with uncommitted hemopoietic precursor cells.

Expression of the v-erbA product, an altered nuclear hormone receptor, is sufficient to transform erythrocytic cells in vitro

We investigated the effect of the v-erbA oncogene product, an altered thyroid hormone receptor, in chicken erythrocyte progenitor cells. Bone marrow cells were infected with a retrovirus vector (XJ12) carrying the v-erbA gene in association with the neoR gene. XJ12-infected erythrocyte progenitor cells gave rise to G418-resistant clones. Some were composed of blast cells identified as transformed CFU-Es blocked in their differentiation. These cells could be grown in culture for at least 25 generations and required anemic chicken serum as a source of erythropoietic growth factors. XJ12 can infect erythrocyte progenitor cells in vivo but is not sufficient to induce erythroleukemia. These data suggest that the activation of a nuclear hormone receptor might represent one step toward the development of neoplasms.

Response of hemopoietic cells to avian acute leukemia viruses: Effects on the differentiation of the target cells

Chicken bone marrow cells were infected with three avian acute leukemia viruses (ALV)--avian myeloblastosis virus (AMV), myelocytomatosis virus strain MC29 and Mill Hill 2 virus (MH2)--and then cultured in agar in the presence of conditioned medium. Under these conditions, it was found that very few cells served as target cells for these three viruses. Density gradient separation showed that ALV target cells were found primarily in the light density fractions and might be represented by cells committed to the mononuclear phagocyte pathway. Separation of bone marrow cells on the basis of their sedimentation velocity at unit gravity suggested that MC29 and AMV did not share the same target cells. In addition, the analysis of surface receptors and functional markers characteristic of macrophages (Fc and complement receptors, phagocytosis and immune phagocytosis) indicated that the ALV-transformed cells were blocked during their differentiation. These results indicate that the transforming ability of ALV interferes with the differentiation of their target cells.

Myeloid and erythroid neoplastic responses to avian defective leukemia viruses in chickens and in quail

Abstract A comparative study of the oncogenic potential of two avian defective leukemia viruses (DLVs) shows that avian erythroblastosis virus induces myeloid leukemia in quail and confirms that E26 causes erythroid leukemia in chickens. These results indicate that the response of birds to these two DLVs depends on the host species and suggest that classification of DLVs based only on in vitro studies may not be definitive.