Erythropoietin mediates terminal granulocytic differentiation of committed myeloid cells with ectopic erythropoietin receptor expression.

OBJECTIVES: The precise role of hematopoietic cytokine/cytokine receptor interactions in lineage-restricted hematopoietic differentiation giving rise to mature blood cells of diverse function is incompletely defined. To study lineage-specific effects of cytokines during terminal hematopoietic differentiation, we examined the ability of erythropoietin (Epo) to mediate terminal granulocytic differentiation and induction of myeloid gene expression in committed myeloid cells, engineered to ectopically express Epo receptor (EpoR). METHODS: A cell culture model for granulocyte-macrophage colony stimulating factor (GM-CSF)-mediated granulocytic differentiation was used. EpoR was introduced by retrovirus-mediated gene transfer into multipotential, hematopoietic murine cell line EML, from which GM-CSF-responsive, promyelocytic EPRO cells were generated. In EPRO cells ectopically expressing EpoR, we examined the ability of Epo to mediate granulocytic differentiation and determined whether Epo-mediated neutrophil differentiation is associated with a pattern of myeloid gene expression comparable to that induced by GM-CSF. RESULTS: Studies of EpoR function in myeloid EPRO cells revealed that Epo/EpoR interaction can mediate terminal granulocytic differentiation of committed myeloid cells. In EPRO cells expressing EpoR, Epo-mediated neutrophil differentiation was associated with surface CD11b/CD18 (Mac-1) expression and induction of mRNA expression of specific myeloid genes including lactoferrin, gelatinase and C/EBPepsilon, in a manner similar to GM-CSF-mediated differentiation. CONCLUSIONS: These results indicate that Epo can deliver differentiative signals along a non-erythroid lineage, providing evidence for interchangeable cytokine receptor signals that mediate terminal differentiation of committed myeloid cells.

Purification and properties of a Ca(2+)-independent barbed-end actin filament capping protein, CapZ, from human polymorphonuclear leukocytes.

In human polymorphonuclear leukocytes (PMN), changes in the actin architecture are critical for the shape changes required for chemotaxis and phagocytosis. Barbed-end capping proteins are likely to regulate actin assembly in PMN. The previously identified barbed-end blocking proteins in PMN, gelsolin and CapG, require Ca(2+) to initiate capping of actin filaments. Because chemoattractants can stimulate PMN actin assembly by a calcium-independent signal transduction pathway, we sought to purify a calcium-independent barbed-end capping activity from PMN cytoplasmic extracts. A Ca(2+) -insensitive actin polymerization inhibitory activity was partially purified from human PMN [Southwick & Stossel (1981) J. Biol. Chem 256, 3030]. Using five column chromatography steps, we purified the protein to homogeneity as assessed by silver staining. Purification was associated with an increase in specific activity of greater than 40 X. Western blot analysis identified the protein as the nonmuscle isoform of the heterodimeric capping protein capZ. Human PMN capZ has an apparent disassociation constant of 3 nM for capping in the presence or absence of micromolar Ca(2+), as assessed by both pyrenylactin elongation and depolymerization assays. Similar to the activity reported for the actin polymerization inhibitor, activity of PMN capZ was inhibited by increasing the KC1 concentration from 0.1 M to 0.6 M. The capping function was also inhibited by phosphatidylinositol 4,5-bisphosphate (PIP(2)) micelles, with half-maximal inhibition occurring at 5.5 micrograms mL(-1). PMN capZ did not nucleate actin assembly, sequester actin monomers, or sever actin filaments. Quantitative Western blot analysis revealed that capZ levels corresponded to 0.7-1.0% of the total human PMN cytoplasmic protein. Given its abundance and high affinity for barbed filament ends, capZ is likely to play an important role in the calcium-independent regulation of actin filament assembly associated with PMN chemotaxis.