Induction of erythropoietin responsiveness in murine hematopoietic cells by the gag-myb-ets-containing ME26 virus

Erythroblast transformation by the friend spleen focus-forming virus is associated with a block in erythropoietin-induced STAT1 phosphorylation and DNA binding and correlates with high expression of the hematopoietic phosphatase SHP-1

Infection of mice with Friend spleen focus-forming virus (SFFV) results in a multistage erythroleukemia. In the first stage, the SFFV envelope glycoprotein interacts with the erythropoietin receptor and a short form of the receptor tyrosine kinase sf-Stk, resulting in constitutive activation of signal transducing molecules and the development of erythropoietin (Epo)-independent erythroid hyperplasia and polycythemia. The second stage results from the outgrowth of a rare virus-infected erythroid cell that expresses nonphysiological levels of the myeloid transcription factor PU.1. These cells exhibit a differentiation block and can be grown as murine erythroleukemia (MEL) cell lines. In this study, we examined SFFV MEL cells to determine whether their transformed phenotype was associated with a block in the activation of any Epo signal-transducing molecules. Our studies indicate that Epo- or SFFV-induced activation of STAT1/3 DNA binding activity is blocked in SFFV MEL cells. The block is at the level of tyrosine phosphorylation of STAT1, although Jak2 phosphorylation is not blocked in these cells. In contrast to Epo, alpha interferon can induce STAT1 phosphorylation and DNA binding in SFFV MEL cells. The SFFV-transformed cells were shown to express elevated levels of the hematopoietic phosphatase SHP-1, and treatment of the cells with a phosphatase inhibitor restored STAT1 tyrosine phosphorylation. MEL cells derived from Friend murine leukemia virus (MuLV) or ME26 MuLV-infected mice, which do not express PU.1, express lower levels of SHP-1 and are not blocked in STAT1/3 DNA-binding activity. Our studies suggest that SFFV-infected erythroid cells become transformed when differentiation signals activated by STAT1/3 are blocked due to high SHP-1 levels induced by inappropriate expression of the PU.1 protein.

Manipulation of mouse hematopoietic progenitors by specific retroviral infection

Previous studies have identified an enhancer 3' of the scl gene that can direct transgene expression to hematopoietic progenitors and stem cells. Here we use this enhancer to restrict expression of the avian leukosis virus receptor, TVA, to hematopoietic stem cells and progenitors in bone marrow and fetal liver and demonstrate that retroviral infection can be used to specifically introduce exogenous sequences. We show that a majority of CFU-S12 multipotential progenitor cells can be transduced in vitro. Uniquely, transduction of TVA+ progenitors with a retrovirus encoding a puromycin resistance gene allows selection and expansion of a multipotential hematopoietic progenitor population that can be superinfected with high efficiency. Using this system we show for the first time that v-Myb oncoproteins expressed from avian viruses can induce a leukemic transformation in the mouse. The phenotype of the transformed cells is similar to that which is seen in the chicken and is likewise dependent on the particular structure of v-Myb. This implies that the basic mechanisms of action of mutated transcription factors in the etiology of leukemia are conserved between birds and mammals.

Ets and retroviruses - transduction and activation of members of the Ets oncogene family in viral oncogenesis

Studies of retroviral-induced oncogenesis in animal systems led to the initial discovery of viral oncogenes and their cellular homologs, and provided critical insights into their role in the neoplastic process. V-ets, the founding member of the ETS oncogene family, was originally identified as part of the fusion oncogene encoded by the avian acute leukemia virus E26 and subsequent analysis of virus induced leukemias led to the initial isolation of two other members of the ETS gene family. PU.1 was identified as a target of insertional activation in the majority of tumors induced by the murine Spleen Focus Forming virus (SFFV), while fli-1 proved to be the target of Friend murine leukemia virus (F-MuLV) in F-MuLV induced erythroleukemia, as well as that of the 10A1 and Graffi viruses. The common features of the erythroid and myeloid diseases induced by these viruses provided the initial demonstration that these and other members of the ETS family play important roles in hematopoietic development as well as disease. This review provides an overview of the role of ETS genes in retrovirally induced neoplasia, their possible mechanisms of action, and how these viral studies relate to current knowledge of the functions of these genes in hematopoiesis.

High-efficiency identification of genes by functional analysis from a retroviral cDNA expression library

Retroviral gene transfer efficiently delivers genes of interest stably into target cells, and expression cDNA cloning has been shown to be highly successful. Considering these two advantages, we now report a method by which one can identify genes stimulating cell growth through functional analysis. The first step requires the construction of a retroviral cDNA expression library and the optimization of transfection of vector DNA into virus packaging cells. The second step involves the cocultivation of target cells with libraries of retrovirus-producing cells, resulting in the amplification of target cells transduced with a gene(s) stimulating cell growth. Under standardized conditions of transfection, we detected an average of 4,000 independent clones per dish, among which expression of a retroviral beta-galactosidase gene at an abundance of 0.2% could be detected. Next, we demonstrated the augmentation of the sensitivity of the assay by retroviral infection and functional analysis. We did this by cocultivating factor-dependent (FD) cells with dishes of GP/E cells transfected with plasmids containing various molar ratios of pN2-IL3 DNA and retroviral library cDNA and by determining the highest dilution of pN2-IL3 which still resulted in the conversion of FD cells to factor independence. The retroviral interleukin-3 gene at an abundance as low as 0.001% could be detected. Indeed, we were able to detect from FD cells the development of factor-independent colonies with different phenotypes after retroviral transfer of cDNAs from an immortalized hemopoietic stem cell line. Thus, the combination of a standardized high-efficiency DNA transfection and retrovirus-mediated gene transfer should facilitate the identification of genes capable of conferring to target FD cells a detectable new function or phenotype. By scaling up the size of the experiment realistically during screening, the assay can detect cDNA at an abundance of lower than 0.0001%.

In vivo cooperation of two nuclear oncogenic proteins, P135gag-myb-ets and p61/63myc, leads to transformation and immortalization of chicken myelomonocytic cells

To investigate a possible in vivo cooperation between the p61/63myc and P135gag-myb-ets proteins, we used a previously constructed retrovirus, named MHE226, which contains the fused v-myb and v-ets oncogenes of the E26 retrovirus and the v-myc oncogene of MH2. For that purpose, chicken neuroretina cells producing MHE226 and pseudotyped with the Rous associated virus-1 (RAV-1) helper virus were injected in 1-day-old chickens. In control experiments, we also injected chicken neuroretina cells producing E26 (RAV-1), RAV-1 alone, or constructs lacking one of the oncogenes of MHE226. The average life span of MHE226-infected chickens is half that of E26-infected chickens. MHE226-infected chickens harbor tumors scattered in many organs, but compared with E26, MHE226 induced a weak leukemia. Study of integration sites suggests that the majority of the tumors results from clonal or oligoclonal events. Cell cultures were derived from the tumors of MHE226-infected chickens and grown in standard medium without addition of exogenous chicken myelomonocytic growth factor. These cells still divide at high rate after more than 100 passages and can thus be considered immortalized. By using several criteria, these cells were characterized as precursors of the myelomonocytic lineages.

The Ets-related transcription factor PU.1 immortalizes erythroblasts

In vivo studies of Friend virus erythroleukemia have implied that proviral integrations adjacent to the gene for the Ets-related transcription factor PU.1 may inhibit the commitment of erythroblasts to differentiate and cause their capability for indefinite transplantation (C. Spiro, B. Gliniak, and D. Kabat, J. Virol. 62:4129-4135, 1988; R. Paul, S. Schuetze, S. L. Kozak, C. Kozak, and D. Kabat, J. Virol. 65:464-467, 1991). To test this hypothesis, we ligated PU.1 cDNA into a retroviral vector and studied its effects on cultured cells. Infection of fibroblasts with PU.1-encoding retrovirus resulted in PU.1 synthesis followed by nuclear pyknosis, cell rounding, and degeneration. In contrast, in long-term bone marrow cultures, erythroblasts were efficiently and rapidly immortalized. The resulting cell lines were polyclonal populations that contained PU.1, were morphologically blast-like, required erythropoietin and bone marrow stromal cells for survival and proliferation, and spontaneously differentiated at low frequency to synthesize hemoglobin. After 9 months in culture, erythroblasts became stroma independent, and they then grew as clonal cell lines. We conclude that PU.1 perturbs the pathway(s) that controls potential for indefinite proliferation and that it can be used to generate permanent erythroblast cell lines.

The Ets-related transcription factor PU.1 immortalizes erythroblasts

In vivo studies of Friend virus erythroleukemia have implied that proviral integrations adjacent to the gene for the Ets-related transcription factor PU.1 may inhibit the commitment of erythroblasts to differentiate and cause their capability for indefinite transplantation (C. Spiro, B. Gliniak, and D. Kabat, J. Virol. 62:4129-4135, 1988; R. Paul, S. Schuetze, S. L. Kozak, C. Kozak, and D. Kabat, J. Virol. 65:464-467, 1991). To test this hypothesis, we ligated PU.1 cDNA into a retroviral vector and studied its effects on cultured cells. Infection of fibroblasts with PU.1-encoding retrovirus resulted in PU.1 synthesis followed by nuclear pyknosis, cell rounding, and degeneration. In contrast, in long-term bone marrow cultures, erythroblasts were efficiently and rapidly immortalized. The resulting cell lines were polyclonal populations that contained PU.1, were morphologically blast-like, required erythropoietin and bone marrow stromal cells for survival and proliferation, and spontaneously differentiated at low frequency to synthesize hemoglobin. After 9 months in culture, erythroblasts became stroma independent, and they then grew as clonal cell lines. We conclude that PU.1 perturbs the pathway(s) that controls potential for indefinite proliferation and that it can be used to generate permanent erythroblast cell lines.

The functional form of the erythropoietin receptor is a 78-kDa protein: correlation with cell surface expression, endocytosis, and phosphorylation

An abundant 70- to 78-kDa form of the erythropoietin receptor (EPOR) was observed in HC-D57 murine erythroleukemia cells deprived of erythropoietin (EPO). In contrast to the 64- and 66-kDa EPOR proteins, these high molecular mass forms of EPOR (hmm-EPOR) correlated well with the number of binding sites and endocytosis of EPO. The hypothesis that hmm-EPOR are more highly glycosylated forms of the EPOR, appear on the cell surface, and represent at least one component of the biologically active EPOR was tested. Consistent findings were as follows. (i) Only hmm-EPOR increased following withdrawal of EPO from HC-D57 cells, correlating with a 10-fold increase in binding of 125I-labeled EPO. In addition, the EPO-dependent downregulation of 125I-EPO binding and disappearance of hmm-EPOR occurred in parallel while the amount of 66-kDa EPOR did not change. (ii) The 78-kDa EPOR was detected in COS cells expressing EPOR cDNA. (iii) Probing of the intact surface of these cells with anti-NH2-terminal antibody recovered only the 78-kDa EPOR. (iv) Enzymatic deglycosylation and dephosphorylation showed that hmm-EPOR apparently resulted from additional N-linked glycosylation of a 62-kDa EPOR. (v) The hmm-EPOR turnover in HC-D57 cells was accelerated 12-fold in the presence of EPO (half-life changed from 3 hr to 15 min). (vi) Anti-phosphotyrosine antiserum detected an EPO-dependent phosphorylation of the 78-kDa EPOR. The kinetics of tyrosine phosphorylation of a 97-kDa protein correlated with the occupancy and internalization of hmm-EPOR. In summary, we suggest that the 78-kDa EPOR is directly involved in the initial biological actions of EPO.

Chicken "erythroid" cells transformed by the Gag-Myb-Ets-encoding E26 leukemia virus are multipotent

The E26 avian leukemia virus encodes a transcriptional activator-type oncoprotein consisting of Gag, Myb, and Ets domains, and transforms early erythroid cells as well as myeloblasts. Surprisingly, we have found that "early erythroid" transformants obtained in culture are multipotent, since they can be induced to differentiate into myeloblasts and eosinophils after superinfection with retroviruses containing kinase-type or ras oncogenes. In addition, TPA is an efficient inducer that generates predominantly eosinophils at low concentrations and myeloblasts at high concentrations. The determination process involves the complete extinction of erythroid/thrombocytic markers and the subsequent activation of myelomonocytic/eosinophilic properties, including the acquisition of specific growth factor requirements. "Erythroleukemic" cells from virus-infected animals were likewise found to be multipotent, making this a unique system to study the genesis of stem cell leukemias and the molecular basis of lineage commitment during hematopoiesis.

Transactivation of erythroid transcription factor GATA-1 by a myb-ets-containing retrovirus

ME26 virus is a recombinant mouse retrovirus construct homologous to the avian E26 virus. Both encode a 135-kDa gag-myb-ets fusion protein which is localized in the nucleus. We have recently shown that ME26 virus can induce erythropoietin (Epo) responsiveness in hematopoietic cells. Mice infected with ME26 virus develop a hyperplasia of Epo-dependent hematopoietic precursor cells from which permanent cell lines can be established. In vitro, ME26 virus specifically induces Epo responsiveness in the interleukin-3-dependent myeloid cell line FDC-P2 by enhancing expression of the Epo receptor (EpoR). In the present study we demonstrate that ME26 virus infection of FDC-P2 cells also results in enhanced expression of beta-globin and the erythroid-specific transcription factor GATA-1, a protein which can transactivate both the EpoR promoter and globin genes. In addition, these cells exhibit a down-regulation of c-myb expression similar to that seen in differentiating erythroid cells. To determine the molecular basis for activation of erythroid genes in ME26 virus-infected cells, we carried out transient expression assays with DNA constructs of either the EpoR promoter of the GATA-1 promoter linked to reporter genes. Our results indicate that while ME26 virus did not directly enhance expression from the EpoR promoter, both it and its avian parent, E26, transactivated the GATA-1 promoter. Furthermore, ME26 virus cooperates with the GATA-1 protein to enhance expression of the EpoR gene. We propose that the mechanism by which ME26 virus induces erythroleukemia involves transactivation of the GATA-1 gene, thus positively regulating the expression of the EpoR and leading to the proliferation of a unique population of Epo-responsive cells. By specifically inducing Epo responsiveness in hematopoietic cells via transactivation of a transcription factor, ME26 virus utilizes a novel mechanism for retrovirus pathogenesis.