Terminal cisternae

Abstract: The mechanism of Ca2+ release from sarcoplasmic reticulum, which triggers contraction in skeletal muscle, remains the key unresolved problem in excitation-contraction coupling. Recently, we have described the isolation of purified fractions referable to terminal and longitudinal cisternae of sarcoplasmic reticulum. Junctional terminal cisternae are distinct in that they have a low net energized Ca2+ loading, which can be enhanced 5-fold or more by addition of ruthenium red. The loading rate, normalized for calcium pump protein content, then approaches that of longitudinal cisternae of sarcoplasmic reticulum. We now find that the ruthenium red-enhanced Ca2+ loading rate can be blocked by the previous addition of ryanodine. The inhibition constant is in the nanomolar range (20-180 nM). Ryanodine and ruthenium red have no effect on the Ca2+ loading rate of longitudinal cisternae. Direct binding studies with [3H]ryanodine localized the receptors to the terminal cisternae and not to longitudinal cisternae. Scatchard analysis of the binding data gives a dissociation constant for ryanodine in the range of the drug action on the terminal cisternae (approximately 100 nM range) with approximately 4 to 20 pmol bound per mg of protein. Ryanodine is known to be toxic in animals, leading to irreversible muscle contractures. These studies provide evidence on the mode of action of ryanodine and its localization to the terminal cisternae. The low concentration at which the drug is effective appears to account for its toxicity. Ryanodine locks the Ca2+ release channels in the "open state," so that Ca2+ is not reaccumulated and the muscle fiber cannot relax.

Abstract: THE calcium channel responsible for the release of Ca2+ from the sarcoplasmic reticulum of skeletal muscle during excitation–contraction coupling has recently been identified and purified1–4,21. The isolated calcium channel has been identified morphologically with the 'foot' structures1,2 which are associated with the junctional face membrane of the terminal cisternae of sarcoplasmic reticulum. In situ, the foot structure extends across the gap of the triad junction from the terminal cisternae of the reticulum to the trans-verse tubule5. We describe here the three-dimensional architecture (3.7 nm resolution) of the calcium channel/foot structure from fast-twitch rabbit skeletal muscle, which we determined from electron micrographs of isolated, non-crystalline structures that had been tilted in the electron microscope. The reconstruction reveals two different faces and an internal structure in which stain accumulates at several interconnected locations, which could empty into the junctional gap of the triad junction. The detailed architecture of the channel complex is relevant to understanding both the physical path followed by calcium ions during excitation–contraction coupling and the association of the terminal cisternae and the transverse tubules in the triad junction.