Abstract
Crosslinking of surface-exposed domains on certain Chlamydomonas flagellar membrane glycoproteins induces their movement within the plane of the flagellar membrane. Previous work has shown that these membrane glycoprotein movements are dependent on a critical concentration of free calcium in the medium and are inhibited reversibly by calcium channel blockers and the protein kinase inhibitors H-7, H-8, and staurosporine. These observations suggest that the flagellum may use a signaling pathway that involves calcium-activated protein phosphorylation to initiate flagellar membrane glycoprotein movements. In order to pursue this hypothesis, we examined the calcium dependence of phosphorylation of flagellar membrane-matrix proteins using an in vitro system containing [γ- 32P]ATP or [ 35S]ATPγS. Using only endogenous enzymes and endogenous substrates found in the membrane-matrix fraction obtained by extraction of flagella with 0.05% Nonidet P-40, we observed both calcium-independent protein phosphorylation and calcium-dependent protein phosphorylation in addition to an active protein dephosphorylation activity. Addition of micromolar free calcium increased the amount of protein phosphorylation severalfold. Calcium-activated protein kinase activity was inhibited by H-7, H-8, and staurosporine, the same protein kinase inhibitors that inhibit the calcium-dependent glycoprotein redistribution in vivo. A small group of polypeptides in the 26–58 kDa range exhibited a dramatic increase in phosphorylation in the presence of 20 μ M free calcium. We suggest that Chlamydomonas utilizes the intraflagellar free calcium concentration to regulate the phosphorylation of specific flagellar proteins in the membrane-matrix fraction, one or more of which may be involved in regulating the machinery responsible for flagellar membrane glycoprotein redistribution.
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