Junctional Sarcoplasmic Reticulum in Excitation-Contraction-Coupling

The junctional sarcoplasmic reticulum (JSR, syn. terminal cisterna) is implicated in Ca++storage and release for muscle contraction. Its discrete ultrastructure permits distinction from the rest of the SR (free SR) even when it occurs without plasmalemmal contact, e.g. as extended JSR (EJSR) in bird, and corbular SR (CSR) in mammalian cardiac cells. The close apposition of JSR to plasmalemma via junctional processes is central to proposed mechanisms of translating voltage-dependent charge transfers at the plasmalemma during the action potential into Ca++release from the JSR. These hypotheses are put into question by the existence of EJSR (and CSR) which in birds constitutes 70-80% of the total JSR. An alternate hypothesis proposes, at least for cardiac cells, that Ca++entering the cell during excitation causes additional Ca++to be freed intracellularly. The notion of a chemical transmitter acting by diffusion is attractive because it will allow for the anomalous topography of EJSR, especially since bird cardiac cells have only about half the diameter of their mammalian relatives and have no transverse tubules.

The Anatomy of the Sarcoplasmic Reticulum in Vertebrate Skeletal Muscle: Its Implications for Excitation Contraction Coupling

The sarcoplasmic reticulum in situ is an intricate tubular network that surrounds the contractile material in striated muscle cells. Its topographical relationship to other intracellular components, especially the myofibrils, is rather rigidly mainiained by a cytoskeleton which enmeshes Z line material and sarcoplasmic reticulum and, ultimately, is anchored at the plasmalemma. As a result, the two main components of the sarcoplasmic reticulum, the junctional SR and the free SR, retain their typical location in the A band region and in the I band region, respectively. The junc­tional SR, which is thought to be the site for calcium storage and release for contraction, is, thus, always well within one micron of the regulatory proteins associated with the actin filaments. The junctional SR, a synonym for terminal cisterna applying to both skeletal and cardiac muscle, is generally held to be involved in the translation of the action potential into calcium release, mainly because of the close topographic apposition between the junctional SR and the plasmalemma, especially in skeletal muscle. This attractive structure-function correlation is challenged by the observation that in bird cardiac muscle 80% of the junctional SR is spacially far removed from plas­malemma, the site of electrical activity. This anomalous topography is not in conflict with the notion that translation of the action potential into calcium release may be accomplished by a dif­fusible transmitter substance, e.g. calcium. Any hypothesis dealing with this problem must ac­ count for the anatomy of the bird heart.

Filipin-Sterol-Complexes in Finch and Mouse Cardiac Muscle

We have recently reported that in frog skeletal muscle the plasma membranes, including the transverse tubules, are densely populated by filipin-sterol-complexes (FC), and that in the sarcoplasmic reticulum (SR) the FC are found much less commonly than in the plasma membrane, but that they have a predilection for the junctional SR (terminal cisterna) which in skeletal muscle are very large cisternae that are in close proximity to the plasma membrane. The analogous junctional SR of cardiac muscle shares all anatomical and topographic features with the junctional SR of skeletal muscle, except that in the latter the junctional SR is much larger. Ue have considered the possibility that the proximity of the junctional SR to the plasma membrane, the latter being replete with FC, may be related to the predilection of the FC for junctional SR in skeletal muscle.

Bridging structures spanning the junctioning gap at the triad of skeletal muscle.

The membrane systems of skeletal muscle were examined after tannic acid fixation. A new structure consisting of bridges spanning the junctional gap is described, and a model is proposed in which the cytoplasmic but not the luminal membrane leaflets of the transverse tubule and of the junctional sarcoplasmic reticulum (SR) are continuous. The globular particles (presumably the Ca-binding proteins) within the terminal cisternae were arranged in longitudinal rows and appeared adherent to the junctional membrane. The junctional gap was present in negatively stained, frozen thin sections of fixed muscles. Negatively staining material occured within the junctional gap. The cytoplasmic leaflets of the longitudinal, intermediate, and terminal cisterna regions of the SR exhibited a thick coat of densely staining material compatible with the presence of the Ca-ATPase. Similar bridges were also observed at the surface membrane-SR close coupling sites of vascular smooth muscle.