The skeletal muscle Ca 2؉ release channel (RYR1), which plays a critical role in excitation-contraction coupling, is a homotetramer with a subunit molecular mass of 565 kDa. Oxidation of the channel increases its activity and produces intersubunit cross-links within the RYR1 tetramer (Aghdasi, B., Zhang, J., Wu, Y., Reid, M. B., and Hamilton, S. L. (1997) J. Biol. Chem. 272, 3739 -3748). Alkylation of hyperreactive sulfhydryls on RYR1 with N-ethylmaleimide (NEM) inhibits channel function and blocks the intersubunit cross-linking. We used calpain and tryptic cleavage, two-dimensional SDS-polyacrylamide gel electrophoresis, N-terminal sequencing, sequence-specific antibody Western blotting, and [ 14 C]NEM labeling to identify the domains involved in these effects. Our data are consistent with a model in which 1) diamide, an oxidizing agent, simultaneously produces an intermolecular cross-link between adjacent subunits within the RYR1 tetramer and an intramolecular cross-link within a single subunit; 2) all of the cysteines involved in both cross-links are in either the region between amino acids ϳ2100 and 2843 or the region between amino acids 2844 and 4685; 3) oxidation exposes a new calpain cleavage site in the central domain of the RYR1 (in the region around amino acid 2100); 4) sulfhydryls that react most rapidly with NEM are located in the N-terminal domain (between amino acids 426 and 1396); 5) alkylation of the N-terminal cysteines completely inhibits the formation of both inter-and intrasubunit cross-links. In summary, we present evidence for interactions between the N-terminal region and the putatively cytoplasmic central domains of RYR1 that appear to influence subunit-subunit interactions and channel activity.In skeletal muscle, the Ca 2ϩ release channel (RYR1) of the sarcoplasmic reticulum (SR) 1 responds to T tubule depolarization by releasing lumenal Ca 2ϩ into the myoplasmic space (1), triggering the sequence of events that leads to muscle contraction. Single amino acid changes in RYR1 (2-8) are thought to produce the human diseases malignant hyperthermia and central core disease. Based on a hydropathy analysis of the primary amino acid sequence of RYR1, the monomeric subunit is predicted to have a short cytoplasmic C terminus and between 4 and 10 membrane-spanning regions in the C-terminal onefifth of the molecule (9, 10). The transmembrane regions of the monomers may combine to form the pore of the homotetrameric Ca 2ϩ release channel. The large N-terminal part of the molecule is thought to extend into the cytoplasm as a "foot" structure (11), and this region of the protein plays an important role in regulation of the channel activity of RYR1. Most of the mutations in RYR1 that produce malignant hyperthermia and central core disease have been found in this region and cluster in two cytoplasmic locations (2-8). Also, most modulators of the channel are thought to interact with cytoplasmic domains of RYR1 (12-16).Reactive oxygen intermediates are produced in resting muscle and their production increa...
