A chimeric receptor/oncogene that can be regulated by a ligand in vitro and in vivo

A new model to evaluate Raf signaling in hematopoietic cells

The Raf/MEK/ERK pathway is thought to be critical in mediating cell survival and proliferation by cytokine receptors. However, the exact contribution of Raf is complex and not well understood. A better understanding of Raf signaling is important because of the recent observation that B-Raf is frequently mutated in various human cancers. We have generated a new model system that activates Raf directly by linking the extracytoplasmic and transmembrane domains of the erythropoietin receptor (EPOR) with the catalytic domain of Raf (CR3). This synthetic oncogene in which dimerization can be controlled by an exogenous ligand, is fixed at the cellular membrane, while the endogenous Raf is normally activated by binding with Ras. The chimeric receptor EPOR/CR3 was stably expressed in Ba/F3 cells which lack EPO receptors. Although the lines remained dependent on IL-3 for proliferation, EPO treatment reduced the rate of cell death in the absence of IL-3. Also, EPO was synergistic with sub-optimal concentrations of IL-3 in inducing long-term cell proliferation, but did not augment proliferation of cells cultured with full concentrations of IL-3. EPO induced a rapid activation of ERK and also phosphorylation of endogenous Raf. It also induced tyrosine phosphorylation of several cellular proteins. The MEK1 inhibitor PD98059 reduced EPO-induced tyrosine phosphorylation, suggesting these substrates are downstream of MEK kinase. Interestingly, PD98059 also reduced the phosphorylation of endogenous Raf, indicating there is a positive feedback mechanism in Raf activation. We conclude that Raf can be activated by a mechanism that induces clustering at the cell membrane, and that this leads directly to activation of MEK and ERK. This EPOR/CR3 system may serve as a useful model to evaluate the unknown Raf kinase pathway and the effects of signal transduction inhibitors for Raf as a target.

The TEL/ARG Leukemia Oncogene Promotes Viability and Hyperresponsiveness to Hematopoietic Growth Factors

The TEL/ARG oncogene associated with acute myeloid leukemia is formed by the t(1;12)(q25;p13) reciprocal translocation, which fuses part of the TEL gene to the tyrosine kinase, c-ARG. In an effort to determine the biological effects and investigate signaling of the TEL/ARG fusion protein, multiple sublines of Ba/F3 cells were generated in which a TEL/ARG complementary DNA was expressed under the control of a tetracycline-inducible promoter. Treatment of these cells with doxycycline, a tetracycline analogue, rapidly induced expression of the TEL/ARG protein. TEL/ARG was heavily phosphorylated on tyrosine residues and was also found to rapidly induce tyrosine phosphorylation of multiple cellular proteins, including rasGAP, CBL, STAT5, PI3K, SHP2, Dok, and SHC. The Ba/F3-tet-TEL/ARG cells remained interleukin (IL)-3 dependent without doxycycline but with doxycycline displayed a marked reduction in cell death in the absence of IL-3. TEL/ ARG cells also displayed an enhanced proliferative response to IL-3 and to insulin-like growth factor 1. At least in Ba/F3 cells, although the growth rate was much lower compared to that with IL-3, TEL/ARG appeared to induce some cell proliferation as an immediate consequence. Nonetheless, the hyperresponsiveness to growth factors reported here is more likely to contribute to the pathogenesis of leukemia.

Activation of c-Abl kinase activity and transformation by a chemical inducer of dimerization

c-Abl is a non-receptor tyrosine kinase that is activated in human leukemias by the fusion of Bcr or Tel sequences to the Abl NH(2) terminus. Although Bcr and Tel have little in common, both contain oligomerization domains. To determine whether oligomerization alone is sufficient to activate c-Abl, we have generated and characterized an Abl protein that can be activated selectively with the chemical inducer of dimerization, AP1510. Mutant Abl proteins with one (c4F1) or two (c4F2) copies of the AP1510 binding motif (FKBP) transformed NIH 3T3 cells in a ligand-dependent manner with the c4F2 protein 60-fold more potent than c4F1. Both chimeric proteins exhibited ligand-dependent dimerization in vivo, suggesting that the increased transformation efficiency of the c4F2 mutant reflects more effective dimerization rather than formation of higher order oligomers. In the absence of ligand, c4F2-expresssing fibroblasts morphologically reverted and arrested in G(1). In Ba/F3 cells, the c4F2 chimera exhibited ligand-dependent kinase activation, transformation to interleukin 3-independent growth, and relocalization of the fusion protein from nucleus to cytoplasm. These results demonstrate that dimerization alone is sufficient to activate the Abl kinase and provide a method to regulate conditionally c-Abl activity that will be useful for studying the normal physiological role of c-Abl and the mechanism of transformation and leukemogenesis.

The C-Terminus of c-Abl Is Required for Proliferation and Viability Signaling in a c-Abl/Erythropoietin Receptor Fusion Protein

Activated ABL oncogenes cause B-cell leukemias in mice and chronic myelogenous leukemia in humans. However, the mechanism of transformation is complex and not well understood. A method to rapidly and reversibly activate c-ABL was created by fusing the extra-cytoplasmic and transmembrane domain of the erythropoietin (EPO) receptor with c-ABL (EPO R/ABL). When this chimeric receptor was expressed in Ba/F3 cells, the addition of EPO resulted in a dose-dependent activation of c-ABL tyrosine kinase and was strongly antiapoptotic and weakly mitogenic. To evaluate the contributions of various ABL domains to biochemical signaling and biological effects, chimeric receptors were constructed in which the ABL SH3 domain was deleted (▵SH3), the SH2 domain was deleted (▵SH2), the C-terminal actin-binding domain was deleted (▵ABD), or kinase activity was eliminated by a point mutation, K290M (KD). The mutant receptors were stably expressed in Ba/F3 cells and analyzed for signaling defects, proliferation, viability, and EPO-induced leukemia in nude mice. When compared with the ability of the full-length EPO R/ABL receptor to induce proliferation and support viability in vitro, the ▵SH3 mutant was equivalent, the ▵SH2 mutant was moderately impaired, and the ▵ABD and KD mutants were profoundly impaired. None of these cell lines caused leukemia in mice in the absence of pharmacological doses of EPO. However, in mice treated with EPO (10 U/d), death from leukemia occurred rapidly with wild-type and ▵SH3. However, time to death was prolonged by at least twofold for ▵SH2 and greater than threefold for ▵ABD. This inducible model of ABL transformation provides a method to link specific signaling defects with specific biological defects and has shown an important role for the C-terminal actin-binding domain in proliferation and transformation in the context of this receptor/oncogene.

The C-Terminus of c-Abl Is Required for Proliferation and Viability Signaling in a c-Abl/Erythropoietin Receptor Fusion Protein

Activated ABL oncogenes cause B-cell leukemias in mice and chronic myelogenous leukemia in humans. However, the mechanism of transformation is complex and not well understood. A method to rapidly and reversibly activate c-ABL was created by fusing the extra-cytoplasmic and transmembrane domain of the erythropoietin (EPO) receptor with c-ABL (EPO R/ABL). When this chimeric receptor was expressed in Ba/F3 cells, the addition of EPO resulted in a dose-dependent activation of c-ABL tyrosine kinase and was strongly antiapoptotic and weakly mitogenic. To evaluate the contributions of various ABL domains to biochemical signaling and biological effects, chimeric receptors were constructed in which the ABL SH3 domain was deleted (▵SH3), the SH2 domain was deleted (▵SH2), the C-terminal actin-binding domain was deleted (▵ABD), or kinase activity was eliminated by a point mutation, K290M (KD). The mutant receptors were stably expressed in Ba/F3 cells and analyzed for signaling defects, proliferation, viability, and EPO-induced leukemia in nude mice. When compared with the ability of the full-length EPO R/ABL receptor to induce proliferation and support viability in vitro, the ▵SH3 mutant was equivalent, the ▵SH2 mutant was moderately impaired, and the ▵ABD and KD mutants were profoundly impaired. None of these cell lines caused leukemia in mice in the absence of pharmacological doses of EPO. However, in mice treated with EPO (10 U/d), death from leukemia occurred rapidly with wild-type and ▵SH3. However, time to death was prolonged by at least twofold for ▵SH2 and greater than threefold for ▵ABD. This inducible model of ABL transformation provides a method to link specific signaling defects with specific biological defects and has shown an important role for the C-terminal actin-binding domain in proliferation and transformation in the context of this receptor/oncogene.