Sphingosine kinase regulates the rate of endothelial progenitor cell differentiation.

Circulating endothelial progenitor cells (EPCs) are incorporated into foci of neovascularization where they undergo differentiation to mature endothelial cells (ECs). We show here that the enzyme sphingosine kinase-1 (SK-1) regulates the rate and direction of EPC differentiation without effect on the hematopoietic compartment. EPCs have high levels of SK-1 activity, which diminishes with differentiation and is, at least partially, responsible for maintaining their EPC phenotype. EPCs from SK-1 knockout mice form more adherent EC units and acquire a mature EC phenotype more rapidly. Conversely, EPCs from mice overexpressing SK-1 in the EC compartment are retarded in their differentiation. Exogenous regulation of SK-1 levels in normal EPCs, by genetic and pharmacologic means, including the immunomodulating drug FTY720, recapitulates these effects on EC differentiation. SK-1 knockout mice have higher levels of circulating EPCs, an exaggerated response to erythropoietin-induced EPC mobilization, and, in a mouse model of kidney ischemia reperfusion injury, exhibit a recovery similar to that of ischemic mice administered exogenous EPCs. Thus, SK-1 is a critical player in EPC differentiation into EC pointing to the potential utility of SK-1 modifying agents in the specific manipulation of endothelial development and repair.

Heme oxygenase-1 increases endothelial progenitor cells.

OBJECTIVE: Induction of heme oxygenase-1 (HO-1) protects against atherosclerotic disease in part by promoting reendothelialization. As endothelial progenitor cells (EPCs) contribute to reendothelialization, we examined the role of HO-1 on bone marrow and circulating EPCs. METHODS AND RESULTS: In a rabbit model of aortic balloon injury, pharmacological induction of HO-1 enhanced reendothelialization at sites with and without adjacent blood vessels, the latter indicative of a contribution by EPCs. Coinciding with maximal HO-1 induction in the injured vessel, plasma concentrations of bilirubin and the numbers of circulating progenitor cells were elevated. Both processes were abolished by cotreatment of the animals with an inhibitor of HO-1. Inducers of HO-1 promoted bone marrow cells to form progenitor cell colonies, and Flk1(+)/Sca-1(+)-cells to adhere to the luminal surface of the injured vessel. In noninjured mice, HO-1 inducers also increased bone marrow and circulating EPCs, and the ability of these cells to differentiate and form colonies. Compared to wild-type mice, bone marrow cells from HO-1(-/-) mice generated fewer endothelial colony-forming cells, and HO-1 inducers failed to promote CFU-Hill colony formation. CONCLUSIONS: These findings suggest that HO-1 contributes to vascular repair by increasing circulating EPCs derived from the bone marrow.

Cladribine and Fludarabine Nucleoside Change the Levels of CD Antigens on B-Lymphoproliferative Disorders.

The purine analogs, fludarabine nucleoside (FdA), and cladribine (CdA) (1 µM, 24 hours), significantly changed the levels of some surface antigens on the human B-cell lines MEC2 and Raji. Changes in the surface proteins were identified using a Cluster of Differentiation (CD) antibody microarray that captures live cells and confirmed by flow cytometry. For Raji cells, CdA up-regulated CD10, CD54, CD80, and CD86, with repression of CD22, while FdA up-regulated CD20, CD54, CD80, CD86 and CD95. For MEC2 cells, CdA up-regulated CD11a, CD20, CD43, CD45, CD52, CD54, CD62L, CD80, CD86, and CD95, but FdA had no effect. Up-regulation of particular CD antigens induced on a B-cell lymphoproliferative disorder by a purine analog could provide targets for therapeutic antibodies with synergistic cell killing.