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. 1993 Sep 15;294(Pt 3):699–703. doi: 10.1042/bj2940699

Regulation of sphingosine-activated protein kinases: selectivity of activation by sphingoid bases and inhibition by non-esterified fatty acids.

Pushkareva MYu 1, A Bielawska 1, D Menaldiv 1, D Liotta 1, Y A Hannun 1
PMCID: PMC1134519  PMID: 8379926

Abstract

Sphingosine has been shown to activate protein kinases in Jurkat T cell cytosol [Pushkareva, Khan, Alessenko, Sahyoun and Hannun (1992) J. Biol. Chem. 267, 15246-15251]. In this study, two sphingosine-activated protein kinases were distinguished by their substrate specificity, their dose-response to sphingosine and the specificity of their activation by sphingosine and dihydrosphingosine stereoisomers. A p32-sphingosine-activated protein kinase responded to low concentrations of D-erythrosphingosine with an initial activation observed at 2.5 microM and a peak activity at 10-20 microM. This kinase showed a modest specificity for D-erythro-sphingosine over other sphingosine stereoisomers, and a preference for sphingosines over dihydrosphingosines. Phosphorylation of a p18 substrate required higher concentrations of sphingosine (20-100 microM) and showed a significant preference for the erythro isomers of sphingosine and dihydrosphingosine over the threo isomers. The ability of other lipids to modulate sphingosine activation of these kinases was also examined. Oleic acid, but not oleic alcohol or the methyl ester, induced the phosphorylation of a distinct set of substrates (probably through the activation of protein kinase C), and inhibited sphingosine-induced phosphorylation with an IC50 of approximately 20 microM. Oleic anhydride failed to induce changes in basal protein phosphorylation but inhibited sphingosine-activated protein kinases, thus distinguishing the effects of fatty acids on protein kinase C from the inhibition of sphingosine-induced phosphorylation. These studies define two distinct sphingosine-activated protein kinases and reveal an important interaction between two classes of putative lipid second messengers.

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Selected References

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