Reversible inactivation of the sarcoplasmic reticulum Ca(2+)-ATPase coupled to rearrangement of cytoplasmic protein domains as revealed by changes in trypsinization pattern.

Abstract

Repetitive homogenization of skeletal muscle sarcoplasmic reticulum (SR) membranes in the presence of chelating agents at low ionic strength leads to the loss of the Ca-ATPase activity. This inactive state of the enzyme is coupled to an extensive rearrangement of the cytosolic domains as visualized by a completely different trypsinization pattern of the enzyme. In addition to the primary cleavage site (Arg 505), a novel trypsinization site (Arg 334), just N-terminal of the phosphorylation domain and localized on the primary tryptic fragment A, becomes exposed. Cleavage at the latter site yields a soluble fragment of M(r) 20,117 and the membrane-bound N-terminal one-third of the ATPase of M(r) 35,279. Two additional trypsinization sites C-terminal of the nucleotide binding domain become exposed in the inactive Ca(2+)-ATPase conformation. Rapid cleavage at these sites yields two soluble fragments of about 15 and 10 kDa. All together, the three soluble fragments comprise most of the large cytosolic loop of the Ca(2+)-ATPase. The inactivation and the change in trypsinization pattern can be reversed by rehomogenization of the extracted membranes in the presence of divalent cations. The results suggest the presence of an occluded site for divalent cations which can be depleted or refilled during application of sheer forces. Occupation of this site is essential to confer to the enzyme an active conformation.