This review provides a summary of current concepts about the structure and single-channel properties of ryanodine receptor calcium release channels and counter ion channels that facilitate Ca2+ release and reuptake by the sarcoplasmic reticulum. Some recent results, obtained with single ryanodine receptor ion channels incorporated into lipid bilayers from terminal cisternae vesicles of rabbit skeletal muscle and sheep ventricular myocardium, are described. The ryanodine receptor is the major Ca2+ release channel in skeletal and cardiac muscle and has been studied in far greater detail than other sarcoplasmic reticulum ion channel proteins. Several ryanodine receptor genes have been cloned and sequenced, and isoforms of the protein have been detected in muscle and in endoplasmic reticulum of brain and many other tissues from mammals, lower vertebrates, nematodes and drosophila. The proteins from all species are tetramers of a peptide with a molecular mass of approximately equal to 560 kDa, containing approximately equal to 5000 amino acids, with a similar maximum single-channel conductance of 500-800 row S for monovalent cations at 250mM. Results presented here include: Ca2+ activation and adaptation of activity in skeletal ryanodine receptors with rapid changes in [Ca2+] controlled by perfusion; activation by FK506 and regulation of cooperative gating of skeletal ryanodine receptor channel activity by FK506-binding proteins; activation and block of cardiac ryanodine receptors by addition of reactive disulphides and by bilayer voltage. Effects of phosphorylation, calmodulin, triadin, calsequestrin and interactions with the alpha 1 subunit of the dihydropyridine receptor on ryanodine receptor activity are summarized. Potassium and chloride channels in skeletal muscle sarcoplasmic reticulum, are described.