Activated Fes protein tyrosine kinase induces terminal macrophage differentiation of myeloid progenitors (U937 cells) and activation of the transcription factor PU.1.

The c-fps/fes proto-oncogene encodes a 92-kDa protein tyrosine kinase that is preferentially expressed in myeloid and endothelial cells. Fes is believed to play a role in vascular development and myelopoiesis and in the inflammatory responses of granulocytes and macrophages. To help define the biological role of this kinase and identify its downstream targets, we have developed a gain-of-function allele of Fes that has potent biological activity in myeloid cell progenitors. Introduction of constitutively active Fes into bipotential U937 cells induced the appearance of fully differentiated macrophages within 6 to 12 days. The Fes-expressing differentiated cells became adherent, had distinctive macrophage morphology, and exhibited increased expression of myelomonocytic differentiation markers, including CD11b, CD11c, CD18, CD14, and the macrophage colony-stimulating factor receptor. These cells acquired phagocytic properties and exhibited NADPH oxidase and nonspecific esterase activities, confirming that they were functionally active macrophages. Concomitantly, there was downregulation of the granulocytic marker granulocyte colony-stimulating factor receptor, indicating that the biological activity of Fes was coordinated in a lineage-specific manner. A constitutively active Src did not induce macrophage morphology or upregulation of myelomonocytic markers in U937 cells, suggesting that the biological activity we observed was not a general consequence of expression of an activated nonreceptor tyrosine kinase. Analysis of possible downstream targets of Fes revealed that this kinase activated the ets family transcription factor PU.1, which is essential for macrophage development. Our results strongly implicate Fes as a key regulator of terminal macrophage differentiation and identify PU.1 as a transcription factor that may mediate some of its biological activities in myeloid cells.

Transforming ability of Gag-Myc fusion proteins correlates with Gag-Myc protein stability and transcriptional repression.

Avian retroviruses that have transduced c-myc are useful tools to study the conditions necessary for cellular transformation. FH3, one such retrovirus which encodes a Gag-Myc fusion protein, is not transforming in quail embryonic fibroblasts, but a late variant of FH3 that arose after passaging FH3-infected cells is transforming. Mutational analysis of FH3 revealed that the presence of a portion of the retroviral protease in FH3 inhibited transformation and that this inhibition was transferable to a more highly transforming retrovirus, MC29. Transforming and non-transforming FH3-derived and MC29-derived Gag-Myc proteins were used to further explore characteristics of Myc necessary for transformation. Gag-Myc proteins which were transforming were found to be the most stable in the cell. To distinguish whether transactivation and/or repression is correlated to transformation, the various Gag-Myc fusion proteins were tested for their ability to activate or repress c-Myc targets. Results indicated that a correlation exists between transforming Gag-Myc proteins and their ability to repress, whereas all Gag-Myc proteins could transactivate, regardless of their ability to transform. Taken together, these results suggest that protein stabilization of Myc and repression of target genes by Myc are important for cellular transformation.

Phosphatidylcholine-specific phospholipase D activity is elevated in v-Fps-transformed cells.

Activating the protein-tyrosine kinase of v-Fps results in a rapid increase in diglyceride (DG) in rat fibroblasts. The v-Fps-induced increases in DG were detected only when phospholipids were prelabeled with [3H]-myristate, which is incorporated primarily into phosphatidylcholine (PC). Inhibition of phosphatidic acid (PA) phosphatase (PAP), which converts PA to DG, blocked v-Fps-induced DG production. PA is a primary metabolite of type D phospholipases (PLD). Consistent with these observations, PLD activity was activated in response to the kinase activity of v-Fps. The increased PLD activity was detected only when the cells were prelabeled with the PC-specific [3H]-myristate. These data support the hypothesis that v-Fps-induced DG is derived from PC via the PLD/PAP pathway.

Ha-Ras functions downstream from protein kinase C in v-Fps-induced gene expression mediated by TPA response elements.

v-Fps activates promoters under the control of the 12-O-tetradecanoyl phorbol 13-acetate (TPA) response element (TRE). The induction of TRE-mediated transcription by v-Fps was sensitive to a dominant-negative mutant of Ha-Ras. An activated derivative of Ha-Ras, v-Ha-Ras, also activated TRE-mediated transcription. v-Fps-induced TRE-mediated gene expression was sensitive to depleting cells of protein kinase C (PKC), whereas v-Ha-Ras-induced TRE-mediated transcription was insensitive to PKC depletion, suggesting that Ha-Ras functions downstream from PKC in v-Fps-induced TRE-mediated gene expression. Consistent with this hypothesis, the induction of TRE-mediated gene expression by phorbol esters that activate PKC directly was blocked by the dominant-negative Ha-Ras mutant. Thus, v-Fps-induced activation of TRE-mediated gene expression is via an intracellular signaling mechanism that is dependent upon both PKC and Ha-Ras and Ha-Ras functions downstream from PKC.