Calcium Release Units Research Articles

Functional implications of RyR-DHPR relationships in skeletal and cardiac muscles

Dihydropyridine receptors (DHPRs) and ryanodine receptors (RyRs) interact during EC coupling within calcium release units, CRUs. The location of the two channels and their positioning are related to their role in EC coupling. alphals DHPR and RyR1 of skeletal muscle form interlocked arrays. Groups of four DHPRs (forming a tetrad) are located on alternate RyR1s. This association provides the structural framework for reciprocal signaling between the two channels. RyR3 are present in some skeletal muscles in association with RyR1 and in ratios up to 1:1. RyR3 neither induce formation of tetrads by DHPRs nor sustain EC coupling. RyR3 are located in a parajunctional position, in proximity of the RyR1-DHPR complexes, and they may be indirectly activated by calcium liberated via the RyR1 channels. RyR2 have two locations in cardiac muscle. One is at CRUs that contain DHPRs and RyRs. In these cardiac CRUs, RyR2 and alpha1c DHPR are in proximity of each other, but not closely linked, so that they may not have a direct molecular interaction. A second location of RyR2 is on SR cisternae that are not attached to surface membrane/T tubules. The RyR2 in these cisternae, which are often several microns away from any DHPRs, must necessarily be activated indirectly.

The velocity of calcium waves is expected to depend non-monotoneously on the density of the calcium release units.

In this paper we develop a reaction-diffusion system describing the calcium dynamics in an agarose gel system with resuspended vesicles from the sarcoplasmic reticulum (SR vesicles). We focus on a simple model: compared with living cells (e.g. cardiac myocytes) an important property of the agarose gel system is the absence of the sarcolemma and the spatial separation of the calcium release units (CRUs). Our model includes the kinetics of ryanodine sensitive receptors (RyRs), the activity of the SERCA pumps and the diffusion of free calcium. We describe numerical simulations which show a biphasic relationship between the density of the CRUs and the propagation velocity of spreading waves. The non-monotony can be explained by changes in the amplitude of the local calcium concentration. We formulate implications for the in vitro system which could be verified in future experiments.

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Excitation-contraction coupling (E-C coupling) is thought to be based on elementary calcium release units (CRUs) in which clusters of ryanodine receptors (RyRs) localized on the sarcoplasmic reticulum (SR) are in close apposition to L-type Ca2+ channels (LCCs) on the transverse tubules (TTs). However, a fraction of LCC-RyR structure may be uncoupled due to the remodelling of TTs, which would tend to destroy the E-C coupling in the failing heart. Here we proposed a multiscale model of the ventricular myocyte to investigate the relationship between LCC-RyR structure and cardiac electro-mechanical function. The mathematical model consisted of a two-dimensional (2D) subcellular Ca2+ reaction-diffusion sub-model, a cellular electrophysiological sub-model and a cardiomyocyte contraction sub-model. The simulation results showed that the remodelling of CRU microstructure would disturb Ca2+ homeostasis, leading to a dyssynchronous Ca2+ transient, and postpone the generation of isometric force. Our study suggests that structural remodelling is an important mechanism for dysfunction of Ca2+ handling, cellular electrophysiology and contractility in failing heart.

Morphology and Molecular Composition of Sarcoplasmic Reticulum Surface Junctions in the Absence of DHPR and RyR in Mouse Skeletal Muscle

Calcium release during excitation-contraction coupling of skeletal muscle cells is initiated by the functional interaction of the exterior membrane and the sarcoplasmic reticulum (SR), mediated by the “mechanical” coupling of ryanodine receptors (RyR) and dihydropyridine receptors (DHPR). RyR is the sarcoplasmic reticulum Ca 2+ release channel and DHPR is an L-type calcium channel of exterior membranes (surface membrane and T tubules), which acts as the voltage sensor of excitation-contraction coupling. The two proteins communicate with each other at junctions between SR and exterior membranes called calcium release units and are associated with several proteins of which triadin and calsequestrin are the best characterized. Calcium release units are present in diaphragm muscles and hind limb derived primary cultures of double knock out mice lacking both DHPR and RyR. The junctions show coupling between exterior membranes and SR, and an apparently normal content and disposition of triadin and calsequestrin. Therefore SR-surface docking, targeting of triadin and calsequestrin to the junctional SR domains and the structural organization of the two latter proteins are not affected by lack of DHPR and RyR. Interestingly, simultaneous lack of the two major excitation-contraction coupling proteins results in decrease of calcium release units frequency in the diaphragm, compared with either single knockout mutation.

Type 3 ryanodine receptors of skeletal muscle are segregated in a parajunctional position.

A key event in skeletal muscle activation is the rapid release of Ca(2+) from the sarcoplasmic reticulum (SR), the Ca(2+) storage organelle in the muscle cell. The surface membrane/transverse tubules and the SR form functional units (calcium release units containing one or two couplons or junctions), where the voltage-sensing dihydropyridine receptor of the surface membrane interacts with the SR Ca(2+) release channel [ryanodine receptor (RyR)] and depolarization of the cell membrane is converted into Ca(2+) release from the SR. Although RyR1 is the most important isoform in skeletal muscle, some muscles also express high levels of RyR3, an isoform with a wide tissue distribution. The cytoplasmic domains of RyRs are visible in the electron microscope as periodically disposed feet. We find that, in muscles containing only RyR1, feet are exclusively located over the junctional SR surface facing the surface membrane/transverse tubule. In muscles containing RyR1 as well as RyR3, additional feet are located in lateral parajunctional regions immediately adjacent to junctional SR. Biochemical content of RyR3 and content of parajunctional feet are highly correlated in different muscles and the disposition of parajunctional versus junctional feet are notably different. On the basis of these two observations, we postulate that RyR3s are restricted to the parajunctional region, and thus their activation must be indirect and derivative during excitation-contraction coupling.

Structural interaction between RYRs and DHPRs in calcium release units of cardiac and skeletal muscle cells

Excitation-contraction (e-c) coupling in muscle cells is a mechanism that allows transduction of exterior-membrane depolarization in Ca2+ release from the Sarcoplasmic Reticulum (SR). The communication between external and internal membranes is possible thanks to the interaction between Dihydropyridine Receptors (DHPRs), voltage-gated Ca2+ channels located in exterior membranes, and Ryanodine Receptors (RyRs), the Ca2+ release channels of the SR. In both skeletal and cardiac muscle cells the key structural element that allows DHPRs and RyRs to interact with each other is their vicinity. However, the signal that the two molecules use to communicate is not the same in the two muscle types. In the heart, the inward flux of Ca2+ through DHPRs, that follows depolarization, triggers the opening of RyRs (calcium induced calcium release). In skeletal muscle, on the other hand, Ca2+ is not needed for RyRs activation; instead the coupling between the two molecules involves a direct link between them (mechanical coupling). Ultrastructural studies show that functional differences can be explained by differences in the DHPR/RyR reciprocal association: whereas the two proteins are very close to each other in both muscles, DHPRs form tetrads only in skeletal fibers. Tetrads represent the structural DHPR/RyR link that allows Ca2+ independent coupling in skeletal muscle.

Structural Alterations in Cardiac Calcium Release Units Resulting from Overexpression of Junctin

Junctin is a 26 kDa membrane protein that binds to calsequestrin, triadin, and ryanodine receptors (RyRs) within the junctional sarcoplasmic reticulum of calcium release units. The sequence of junctin includes a short N-terminal cytoplasmic domain a single transmembrane domain, and a highly charged C-terminal domain located in the sarcoplasmic reticulum lumen. Dog and mouse junctins are highly conserved at the transmembrane domains, but the luminal domains are more divergent. To probe the contribution of junctin to the architecture of calcium release units in heart, we engineered transgenic mice overexpressing canine junctin and examined the left ventricular myocardium by electron microscopy. Overall architecture of calcium release units is similar in control myocardium and in myocardium overexpressing junctin by 5–10-fold. In both myocardia, junctional SR cisternae are closely associated with exterior membranes (plasmalemma and transverse tubules). The cisternae are flat; they contain a string of calsequestrin beads and are lined by a row of feet, or RyRs, on the side facing the exterior membranes. T tubule surface density, measured as the perimeter of T tubule profiles v area of section, is the same in transgenic and control myocardia (305 v 289 nm/nm2). Three changes affecting the junctional SR architecture are apparent in the myocardium overexpressing junctin. One is a more tightly zippered appearance of the junctional SR cisternae. The width of the junctional SR is narrower and less variable in overexpressing than in control myocardium and the calsequestrin content is more compact. A second change is the extension of zippered junctional SR domains to non-junctional regions, which we term ««frustrated»» junctional SR. A third change is an increase in the extent of association between SR and T tubules. In junctin overexpressing myocardium junctional SR cisternae cover ≡45% of the surface of all T tubule profiles, while in control myocardium the coverage is ≡30%. Junctional associations between SR and T tubules are increased in size. We conclude that the increase in junctin expression affects the packing of calsequestrin in the junctional SR and facilitates the association of SR and T tubules.

RYR1 and RYR3 Have Different Roles in the Assembly of Calcium Release Units of Skeletal Muscle

Calcium release units (CRUs) are junctions between the sarcoplasmic reticulum (SR) and exterior membranes that mediates excitation contraction (e-c) coupling in muscle cells. In skeletal muscle CRUs contain two isoforms of the sarcoplasmic reticulum Ca 2+release channel: ryanodine receptors type 1 and type 3 (RyR1 and RyR3). 1B5s are a mouse skeletal muscle cell line that carries a null mutation for RyR1 and does not express either RyR1 or RyR3. These cells develop dyspedic SR/exterior membrane junctions (i.e., dyspedic calcium release units, dCRUs) that contain dihydropyridine receptors (DHPRs) and triadin, two essential components of CRUs, but no RyRs (or feet). Lack of RyRs in turn affects the disposition of DHPRs, which is normally dictated by a linkage to RyR subunits. In the dCRUs of 1B5 cells, DHPRs are neither grouped into tetrads nor aligned in two orthogonal directions. We have explored the structural role of RyR3 in the assembly of CRUs in 1B5 cells independently expressing either RyR1 or RyR3. Either isoform colocalizes with DHPRs and triadin at the cell periphery. Electron microscopy shows that expression of either isoform results in CRUs containing arrays of feet, indicating the ability of both isoforms to be targeted to dCRUs and to assemble in ordered arrays in the absence of the other. However, a significant difference between RyR1- and RyR3-rescued junctions is revealed by freeze fracture. While cells transfected with RyR1 show restoration of DHPR tetrads and DHPR orthogonal alignment indicative of a link to RyRs, those transfected with RyR3 do not. This indicates that RyR3 fails to link to DHPRs in a specific manner. This morphological evidence supports the hypothesis that activation of RyR3 in skeletal muscle cells must be indirect and provides the basis for failure of e-c coupling in muscle cells containing RyR3 but lacking RyR1 (see the accompanying report, Fessenden et al., 2000).

RYR1 and RYR3 Have Different Roles in the Assembly of Calcium Release Units of Skeletal Muscle

RYR1 and RYR3 Have Different Roles in the Assembly of Calcium Release Units of Skeletal Muscle

Shape, Size, and Distribution of Ca 2+ Release Units and Couplons in Skeletal and Cardiac Muscles

Excitation contraction (e-c) coupling in skeletal and cardiac muscles involves an interaction between specialized junctional domains of the sarcoplasmic reticulum (SR) and of exterior membranes (either surface membrane or transverse (T) tubules). This interaction occurs at special structures named calcium release units (CRUs). CRUs contain two proteins essential to e-c coupling: dihydropyridine receptors (DHPRs), L-type Ca 2+ channels of exterior membranes; and ryanodine receptors (RyRs), the Ca 2+ release channels of the SR. Special CRUs in cardiac muscle are constituted by SR domains bearing RyRs that are not associated with exterior membranes (the corbular and extended junctional SR or EjSR). Functional groupings of RyRs and DHPRs within calcium release units have been named couplons, and the term is also loosely applied to the EjSR of cardiac muscle. Knowledge of the structure, geometry, and disposition of couplons is essential to understand the mechanism of Ca 2+ release during muscle activation. This paper presents a compilation of quantitative data on couplons in a variety of skeletal and cardiac muscles, which is useful in modeling calcium release events, both macroscopic and microscopic (“sparks”).

Comparative ultrastructure of Ca2+ release units in skeletal and cardiac muscle.

The sarcoplasmic reticulum (SR) of striated muscle fibers interacts with exterior membranes (surface membrane and transverse tubules) to form junctions that are involved in the internal release of calcium during excitation-contraction coupling. Release of calcium through the ryanodine receptors (RyRs) or calcium release channels of the SR is under the control of the L type calcium channels or dihydropyridine receptors (DHPRs) of exterior membranes. Interacting clusters of the two proteins constitute calcium release units. The cytoplasmic domains of RyRs are visible as large electron-dense structures (the feet) with four identical subunits in the junctional gap separating SR from exterior membranes. In freeze-fracture replicas of skeletal muscle, large intramembrane particles are grouped into clusters of tetrads in the exterior membranes, and the tetrads are located in correspondence of the four subunits of the feet. Lack of tetrads in dysgenic muscle fibers with a null mutation for DHPRs and appearance of the tetrads after transfection with cDNA for DHPR indicate identity of tetrads with four DHPRs. In cardiac muscle, DHPRs are located at the sites of SR-surface junctions, but they are not grouped into tetrads. This is consistent with a possible direct DHPR-RyR interaction in skeletal but not in cardiac muscle. The size and distribution of SR-surface junctions in skeletal and cardiac muscles provide further clues to their function.

Structural proximity of mitochondria to calcium release units in rat ventricular myocardium may suggest a role in Ca2+ sequestration.

Structural proximity of mitochondria to calcium release units in rat ventricular myocardium may suggest a role in Ca2+ sequestration.

Role of ryanodine receptors in the assembly of calcium release units in skeletal muscle.

In muscle cells, excitation-contraction (e-c) coupling is mediated by "calcium release units," junctions between the sarcoplasmic reticulum (SR) and exterior membranes. Two proteins, which face each other, are known to functionally interact in those structures: the ryanodine receptors (RyRs), or SR calcium release channels, and the dihydropyridine receptors (DHPRs), or L-type calcium channels of exterior membranes. In skeletal muscle, DHPRs form tetrads, groups of four receptors, and tetrads are organized in arrays that face arrays of feet (or RyRs). Triadin is a protein of the SR located at the SR-exterior membrane junctions, whose role is not known. We have structurally characterized calcium release units in a skeletal muscle cell line (1B5) lacking Ry1R. Using immunohistochemistry and freeze-fracture electron microscopy, we find that DHPR and triadin are clustered in foci in differentiating 1B5 cells. Thin section electron microscopy reveals numerous SR-exterior membrane junctions lacking foot structures (dyspedic). These results suggest that components other than Ry1Rs are responsible for targeting DHPRs and triadin to junctional regions. However, DHPRs in 1B5 cells are not grouped into tetrads as in normal skeletal muscle cells suggesting that anchoring to Ry1Rs is necessary for positioning DHPRs into ordered arrays of tetrads. This hypothesis is confirmed by finding a "restoration of tetrads" in junctional domains of surface membranes after transfection of 1B5 cells with cDNA encoding for Ry1R.

Elementary calcium-release units induced by inositol trisphosphate.

The extent to which inositol 1,4,5-trisphosphate (InsP3)-induced calcium signals are localized is a critical parameter for understanding the mechanism of effector activation. The spatial characteristics of InsP3-mediated calcium signals were determined by targeting a dextran-based calcium indicator to intracellular membranes through the in situ addition of a geranylgeranyl lipid group. Elementary calcium-release events observed with this indicator typically lasted less than 33 milliseconds, had diameters less than 2 micrometers, and were uncoupled from each other by the calcium buffer EGTA. Cellwide calcium transients are likely to result from synchronized triggering of such local release events, suggesting that calcium-dependent effector proteins could be selectively activated by localization near sites of local calcium release.

Coordinated incorporation of skeletal muscle dihydropyridine receptors and ryanodine receptors in peripheral couplings of BC3H1 cells.

Rapid release of calcium from the sarcoplasmic reticulum (SR) of skeletal muscle fibers during excitation-contraction (e-c) coupling is initiated by the interaction of surface membrane calcium channels (dihydropyridine receptors; DHPRs) with the calcium release channels of the SR (ryanodine receptors; RyRs, or feet). We studied the early differentiation of calcium release units, which mediate this interaction, in BC3H1 cells. Immunofluorescence labelings of differentiating myocytes with antibodies against alpha1 and alpha2 subunits of DHPRs, RyRs, and triadin show that the skeletal isoforms of all four proteins are abundantly expressed upon differentiation, they appear concomitantly, and they are colocalized. The transverse tubular system is poorly organized, and thus clusters of e-c coupling proteins are predominantly located at the cell periphery. Freeze fracture analysis of the surface membrane reveals tetrads of large intramembrane particles, arranged in orderly arrays. These appear concomitantly with arrays of feet (RyRs) and with the appearance of DHPR/RyS clusters, confirming that the four components of the tetrads correspond to skeletal muscle DHPRs. The arrangement of tetrads and feet in developing junctions indicates that incorporation of DHPRs in junctional domains of the surface membrane proceeds gradually and is highly coordinated with the formation of RyR arrays. Within the arrays, tetrads are positioned at a spacing of twice the distance between the feet. The incorporation of individual DHPRs into tetrads occurs exclusively at positions corresponding to alternate feet, suggesting that the assembly of RyR arrays not only guides the assembly of tetrads but also determines their characteristic spacing in the junction.

Formation and Maturation of the Calcium Release Apparatus in Developing and Adult Avian Myocardium

Muscle fibers release large amounts of calcium from an internal compartment, the sarcoplasmic reticulum (SR), during activation. Two proteins are involved in this process and its control: plasma membrane calcium channels, or dihydropyridine receptors (DHPRs), and SR calcium release channels, or ryanodine receptors (RyRs). The two proteins form part of a structural complex, perhaps unique to muscle cells, which allows an interaction between plasma membrane and SR, resulting in calcium release from the latter. The surface–SR interaction is a step in the coupling between electrical events in the plasma membrane and contraction (excitation–contraction coupling). The structural complexes have been called calcium release units. One key to further understanding the control of calcium homeostasis in muscle is knowledge of how DHPRs and RyRs assemble into calcium release units. We have studied the development of avian myocardium, using immunocytochemistry to locate DHPRs and RyRs and electron microscopy to follow the formation of calcium release units containing feet (RyRs) and large membrane particles (presumably DHPRs). We find that the initial step is a docking of SR vesicles to the plasma membrane, followed by the appearance of feet in the junctional gap between SR and plasma membrane. Feet aggregate in ordered arrays, and the arrays increase in size until they fill the entire junctional gap. Clustering of membrane particles, presumably DHPRs, is apparently coupled to clustering of feet, since the two junction components assemble within patches of membrane of approximately equal size and containing an approximately constant ratio of particles to feet. Thus, despite the fact that no evidence exists for a direct interaction between DHPRs and RyRs in cardiac muscle, some mechanism exists to ensure that the two molecules are clustered in proximity to each other and in the appropriate proportion.

Development of the excitation-contraction coupling apparatus in skeletal muscle: peripheral and internal calcium release units are formed sequentially.

The development of calcium release units and of transverse tubules has been studied in skeletal muscle fibres from embryonal and newborn chicken. Three constituents of calcium release units: the tetrads, the feet and an internal protein directly associated with junctional surface of the sarcoplasmic reticulum are visualized by various electron microscope techniques. Evidence in the literature indicates that the three components correspond to the voltage sensors, the sarcoplasmic reticulum calcium release channels and the calcium binding protein calsequestrin respectively. We recognize two stages at which important events in membrane morphogenesis occur. The first stage coincides with early myofibrillogenesis (starting at approximately embryonal day E5.5), and it involves the assembly of calcium release units at the periphery of the muscle fibre in which feet and the internal protein are identified. Groups of tetrads also are present at very early stages and their disposition indicates a relation to the feet of peripheral couplings. Thus three major components of the excitation-contraction coupling pathway are in place as soon as myofibrils develop. The density of groups of tetrads in the surface membrane of primary and secondary fibres is similar, despite differences in developmental stages. The second stage involves the formation of a complex transverse tubule network and of internal sarcoplasmic reticulum-transverse tubule junctions, while peripheral couplings disappear. This stage starts abruptly (between E15 and E16) and simultaneously in primary and secondary fibres. It coincides with the myotube-to-myofibre transition. The two stages are separated by a relatively long intervening period (between E9 and E16). During the latter part of this period some primitive transverse tubules appear, and form junctions with the sarcoplasmic reticulum, but they remain strictly located at the periphery of the fibre and are not numerous. Finally, after the second stage there is a prolonged (up to 4 weeks) period of maturation, during which density of free sarcoplasmic reticulum increases, triads acquire a location at the A-I junction and fibre type differences appear. We conclude that a system for calcium uptake, storage and release exists at the periphery of the myotube during early myogenesis. The complexity of the system and its ability to deliver calcium through the entire fibre develop in parallel to the formation of myofibrils.