Fatty acyl-CoA–acyl-CoA-binding protein complexes activate the Ca2+ release channel of skeletal muscle sarcoplasmic reticulum

Abstract

We previously reported that fatty acyl-CoA esters activate ryanodine receptor/Ca²⁺ release channels in a terminal cisternae fraction from rabbit skeletal muscle [Fulceri, Nori, Gamberucci, Volpe, Giunti and Benedetti (1994) Cell Calcium 15, 109–116]. Skeletal muscle cytosol contains a high-affinity fatty acyl-CoA-binding protein (ACBP) [Knudsen, Hojrup, Hansen, H. O., Hansen, H. F. and Roepstorff (1989) Biochem. J. 262, 513–519]. We show here that palmitoyl-CoA (PCoA) in a complex with a molar excess of bovine ACBP causes a discrete Ca²⁺ efflux or allows Ca²⁺ release from the Ca²⁺-preloaded terminal cisternae fraction by sub-optimal caffeine concentrations. Both effects were abolished by elevating the free [Mg²⁺] in the system, which inhibits the Ca²⁺ release channel activity. Sensitization towards caffeine was a function of both the concentration of the complex and the [PCoA]-to-[ACBP] ratio. In all experimental conditions the calculated free [PCoA] was no more than 50 nM, and such concentrations by themselves were inactive on Ca²⁺ release channels. The K_D for PCoA binding was approx. 2 nM for bovine and yeast ACBP, and slightly higher (8 nM) for rat ACBP. The PCoA–rat ACBP complex behaved in the same manner as the PCoA–bovine ACBP complex, whereas the ester complexed with yeast ACBP was more active in activating/sensitizing Ca²⁺ efflux. A non-hydrolysable analogue of PCoA bound to (bovine) ACBP also sensitized the Ca²⁺ release channel towards caffeine. These findings indicate that fatty acyl-CoA–ACBP complexes either interact directly with one or more components in the terminal cisternae membranes or, through interaction with the component(s), donate the fatty acyl-CoA esters to high-affinity binding sites of the membrane, thus affecting (and possibly regulating) Ca²⁺ release channel activity.