Identification of the Minimum Essential Region in the II-III Loop of the Dihydropyridine Receptor α1 Subunit Required for Activation of Skeletal Muscle-Type Excitation−Contraction Coupling

Abstract

We have previously shown that among several peptides encompassing various regions of the II−III loop of the dihydropyridine receptor α₁ subunit, only one peptide corresponding to the Thr⁶⁷¹-Leu⁶⁹⁰ region (designated as peptide A) activated ryanodine binding to and induced calcium release from the sarcoplasmic reticulum [El-Hayek et al. (1995) J. Biol. Chem. 270, 22116−22118]. To further localize within peptide A the minimum unit essential for activating the sarcoplasmic reticulum calcium release channel, we synthesized variously truncated forms of peptide A and examined their ability to activate ryanodine binding. We found that the carboxy-terminal 10-residue region of peptide A encompassing Arg⁶⁸¹-Leu⁶⁹⁰ (peptide As-10; s, skeletal muscle-type sequence) activated ryanodine binding in a RyR1-specific manner and induced calcium release even more efficiently than the 20-residue peptide A. Further truncation of one or more residue(s) of peptide As-10 virtually abolished both functions of activating ryanodine binding and inducing Ca²⁺ release. The activating ability of As-10 seems to be determined by at least two factors: (1) the distribution of the positively charged residues, and (2) the skeletal muscle-type amino acid sequence, as deduced from the comparison of various peptides with modified structures. These results provide evidence that the minimum essential unit for the in situ trigger of skeletal muscle excitation−contraction coupling is localized in the Arg⁶⁸¹-Leu⁶⁹⁰ region of the II−III loop of the α₁ subunit of the dihydropyridine receptor.