Isolation of the ryanodine receptor from cardiac sarcoplasmic reticulum and identity with the feet structures

Ryanodine, a highly toxic alkaloid, reacts specifically with the Ca2+ release channels which are localized in the terminal cisternae of sarcoplasmic reticulum (SR). In this study, the ryanodine receptor from cardiac SR has been purified, characterized, and compared with that of skeletal muscle SR. The ryanodine receptor was solubilized with 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS) in the presence of phospholipids. Purification was performed by sequential affinity chromatography followed by gel permeation chromatography in the presence of CHAPS and phospholipids. The enrichment of the receptor from cardiac microsomes was about 110-fold. The purified receptor contained a major polypeptide band of Mr 340,000 with a minor band of Mr 300,000 (absorbance ratio 100/8) on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Electron microscopy of the purified receptor from heart showed square structures of 222 +/- 21 A/side, which is the unique characteristic of feet structures of junctional face membrane of terminal cisternae of SR. Recently, we isolated the ryanodine receptor from skeletal muscle (Inui, M., Saito, A., and Fleischer, S. (1987) J. Biol. Chem. 262, 1740-1747). The ryanodine receptors from heart and skeletal muscle have similar characteristics in terms of protein composition, morphology, chromatographic behavior, and Ca2+, salt, and phospholipid dependence of ryanodine binding. However, there are distinct differences: 1) the Mr of the receptor is slightly larger for skeletal muscle (Mr approximately 360,000); 2) the purified receptor from heart contains two different affinities for ryanodine binding with Kd values in the nanomolar and micromolar ranges, contrasting with that of skeletal muscle SR which shows only the high affinity binding; 3) the affinity of the purified cardiac receptor for ryanodine was 4-5-fold higher than that of skeletal muscle, measured under identical conditions. The greater sensitivity in ryanodine in intact heart can be directly explained by the tighter binding of the ryanodine receptor from heart. The present study suggests that basically similar machinery (the ryanodine receptor and foot structure) is involved in triggering Ca2+ release from cardiac and skeletal muscle SR, albeit there are distinct differences in the sensitivity to ryanodine and other ligands in heart versus skeletal muscle.     

Characterization of junctional and longitudinal sarcoplasmic reticulum from heart muscle

Longitudinal tubules and junctional sarcoplasmic reticulum (SR) were prepared from heart muscle microsomes by Ca2+-phosphate loading followed by sucrose density gradient centrifugation. The longitudinal SR had a high Ca2+ loading rate (0.93 +/- 0.08 mumol.mg-1.min) which was unchanged by addition of ruthenium red. Junctional SR had a low Ca2+ loading rate (0.16 +/- 0.02 mumol.mg-1.min) which was enhanced about 5-fold by ruthenium red. Junctional SR had feet structures observed by electron microscopy and a high molecular weight protein with Mr of 340,000, whereas longitudinal SR was essentially devoid of both. Thus, these subfractions have similar characteristics to longitudinal and junctional terminal cisternae of SR from fast twitch skeletal muscle. Ryanodine binding was localized to junctional cardiac SR as determined by [3H]ryanodine binding. Scatchard analysis of the binding data showed two types of binding (high affinity, Kd approximately 7.9 nM; low affinity, Kd approximately 1 microM), contrasting with skeletal junctional terminal cisternae where only one site with Kd of approximately 50 nM was observed. The ruthenium red enhancement of Ca2+ loading rate in junctional cardiac SR was blocked by pretreatment with low concentrations of ryanodine as reported for junctional terminal cisternae of skeletal muscle SR. The Ca2+ loading rate of junctional cardiac SR was enhanced by preincubation with high concentrations of ryanodine. The apparent inhibition constant (Ki approximately 7 nM) and stimulation constant (Km approximately 1.1 microM) for ryanodine on junctional SR corresponded to the Kd for high affinity binding (Kd approximately 7.9 nM) and low affinity binding (Kd approximately 1.1 microM), respectively. These results suggest that high affinity ryanodine binding locks the Ca2+ release channels in the open state and that low affinity binding closes the Ca2+ release channels of the junctional cardiac SR. The characteristics of the Ca2+ release channels of junctional cardiac SR appear to be similar to that of skeletal muscle SR, but the Ca2+ release channels of cardiac SR are more sensitive to ryanodine.     

Calcium-ryanodine receptor complex. Solubilization and partial characterization from skeletal muscle junctional sarcoplasmic reticulum vesicles

The Ca2+-ryanodine receptor complex is solubilized in functional form on treating sarcoplasmic reticulum (SR) vesicles from rabbit fast skeletal muscle with 3-[(3-cholamidopropyl)dimethylammonio]-1-propane-sulfonate (CHAPS) (1 mg/mg protein) and 1 M NaCl at pH 7.1 by shaking for 30 min at 5 degrees C. The heavy membrane preparations obtained from pyrophosphate homogenates frequently exhibit junctional feet and appear to be derived primarily from the terminal cisternae of the SR. The characteristics of [3H]ryanodine binding are similar for the soluble receptor and the heavy SR vesicles with respect to dependence on Ca2+, pharmacological specificity for inhibition by six ryanoids and ruthenium red, and lack of sensitivity to voltage-dependent Ca2+-channel blockers, inositol 1,4,5-trisphosphate, or doxorubicin. In contrast, the cation sensitivity is decreased on receptor solubilization. The soluble receptor is modulated by cyclic nucleotides and rapidly denatured at 50 degrees C. Saturation experiments reveal a single class of receptors (Kd = 9.6 nM), whereas kinetic measurements yield a calculated association constant of 5.5 X 10(6) min-1 M-1 and a dissociation constant of 5.7 X 10(-4) min-1, suggesting that the [3H]ryanodine receptor complex ages with time to a state which is recalcitrant to dissociation. Sepharose chromatography shows that the receptor complex consists primarily of two protein fractions, one of apparent Mr 150,000-300,000 and a second, the [3H]ryanodine binding component, of approximately Mr 1.2 X 10(6). Preliminary analysis of the soluble receptor preparation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis reveals subunits of Mr greater than 200,000 and major bands of calsequestrin and Ca2+-transport ATPase. These findings indicate that [3H]ryanodine binds to the Ca2+-induced open state of the channel involved in the release of contractile Ca2+.     

Identification and purification of a transverse tubule coupling protein which binds to the ryanodine receptor of terminal cisternae at the triad junction in skeletal muscle

In fast twitch skeletal muscle, the signal for excitation-contraction coupling is transferred from transverse tubule across the triad junction; calcium is thereby released from the terminal cisternae of sarcoplasmic reticulum triggering muscle contraction. Recently, the feet structures of terminal cisternae, which bridge the gap at the triad junction, have been identified as the ryanodine receptor and in turn with the calcium release channels of sarcoplasmic reticulum. The latter consists of an oligomer of a single high molecular weight polypeptide (Mr 360,000). This study attempts to identify the component in the transverse tubule which ligands with the foot structure to form the triad junction. The purified ryanodine receptor, derivatized with sulfosuccinimidyl-2-(p-azidosalicylimido)-1,3'-dithiopropionate (SASD), a thiol-cleavable, 125I-iodinatable, and photoactive probe, was shown to selectively cross-link to a protein with Mr of 71,000 in isolated transverse tubules. This coupling protein was purified from transverse tubule by solubilization with the detergent 3-[(3-cholamidopropyl)dimethylammonio]-1-propane sulfonate (CHAPS) and then purified by sequential column chromatography. In the absence of sulfhydryl agents, the purified polypeptide has an Mr of 61,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A complementary approach using SASD was employed to confirm association of the coupling protein with the ryanodine receptor of terminal cisternae. We conclude that the transverse tubule coupling protein together with the ryanodine receptor (foot structure) is involved in the liganding between transverse tubule and terminal cisternae of sacroplasmic reticulum.     

Preparation and morphology of sarcoplasmic reticulum terminal cisternae from rabbit skeletal muscle

We have developed a procedure to isolate, from skeletal muscle, enriched terminal cisternae of sarcoplasmic reticulum (SR), which retain morphologically intact junctional "feet" structures similar to those observed in situ. The fraction is largely devoid of transverse tubule, plasma membrane, mitochondria, triads (transverse tubules junctionally associated with terminal cisternae), and longitudinal cisternae, as shown by thin-section electron microscopy of representative samples. The terminal cisternae vesicles have distinctive morphological characteristics that differ from the isolated longitudinal cisternae (light SR) obtained from the same gradient. The terminal cisternae consist of two distinct types of membranes, i.e., the junctional face membrane and the Ca2+ pump protein-containing membrane, whereas the longitudinal cisternae contain only the Ca2+ pump protein-containing membrane. The junctional face membrane of the terminal cisternae contains feet structures that extend approximately 12 nm from the membrane surface and can be clearly visualized in thin section through using tannic acid enhancement, by negative staining and by freeze-fracture electron microscopy. Sections of the terminal cisternae, cut tangential to and intersecting the plane of the junctional face, reveal a checkerboardlike lattice of alternating, square-shaped feet structures and spaces each 20 nm square. Structures characteristic of the Ca2+ pump protein are not observed between the feet at the junctional face membrane, either in thin section or by negative staining, even though the Ca2+ pump protein is observed in the nonjunctional membrane on the remainder of the same vesicle. Likewise, freeze-fracture replicas reveal regions of the P face containing ropelike strands instead of the high density of the 7-8-nm particles referable to the Ca2+ pump protein. The intravesicular content of the terminal cisternae, mostly Ca2+-binding protein (calsequestrin), is organized in the form of strands, sometimes appearing paracrystalline, and attached to the inner face of the membrane in the vicinity of the junctional feet. The terminal cisternae preparation is distinct from previously described heavy SR fractions in that it contains the highest percentage of junctional face membrane with morphologically well-preserved junctional feet structures.     

Evidence for a junctional feet-ryanodine receptor complex from sarcoplasmic reticulum

Heavy sarcoplasmic reticulum vesicles, labelled with the Ca2+ release channel probe [3H]ryanodine, were solubilized in detergent, then centrifuged through sucrose gradients. A single peak of ryanodine binding activity was observed with an apparent sedimentation coefficient of 30S. Electron microscopy of the peak fraction showed disk structures of 25-28 nm diameter and 10 nm thickness. Proteins specifically enriched in the peak fraction were the Mr 160,000 and 260,000 and junctional feet proteins (Mr 320,000 and 300,000). This suggests that the feet proteins and ryanodine receptor may be specifically associated into a large oligomeric complex comprising subunits of Mr 160,000-320,000.     

Ultrastructure of the calcium release channel of sarcoplasmic reticulum

This study is concerned with the characterization of the morphology of the calcium release channel of sarcoplasmic reticulum (SR) from fast-twitch skeletal muscle, which is involved in excitation-contraction coupling. We have previously purified the ryanodine receptor and found it to be equivalent to the feet structures, which are involved, in situ, in the junctional association of transverse tubules with terminal cisternae of SR. The receptor is an oligomer of a single high molecular weight polypeptide and when incorporated into phospholipid bilayers, has channel conductance which is characteristic of calcium release in terminal cisternae of SR. The purified channel can be observed by electron microscopy using different methods of sample preparation, with complementary views being observed by negative staining, double staining, thin section and rotary shadowing electron microscopy. Three views can be observed and interpreted: (a) a square face which, in situ, is junctionally associated with the transverse tubule or junctional face membrane; (b) a rectangle equivalent to the side view; and (c) a diamond shape equivalent to the side view, of which the base portion appears to be equivalent to the transmembrane segment. Negative staining reveals detailed substructure of the channel. A computer averaged view of the receptor displays fourfold symmetry and ultrastructural detail. The dense central mass is divided into four domains with a 2-nm hole in the center, and is enclosed within an outer frame which has a pinwheel appearance. Double staining shows substructure of the square face in the form of parallel linear arrays (six/face). The features of the isolated receptor can be correlated with the structure observed in terminal cisternae vesicles. Sections tangential to the junctional face membrane reveal that the feet structures (23-nm squares) overlap so as to enclose smaller square spaces of approximately 14 nm/side. We suggest that this is equivalent to the transverse tubule face and that the terminal cisternae face is smaller (approximately 17 nm/face) and has larger alternating spaces as a consequence of the tapered sides of the foot structures. Image reconstruction analysis appears to be feasible and should provide the three-dimensional structure of the channel.     

Specific association of calmodulin-dependent protein kinase and related substrates with the junctional sarcoplasmic reticulum of skeletal muscle

A systematic study of protein kinase activity and phosphorylation of membrane proteins by ATP was carried out with vesicular fragments of longitudinal tubules (light SR) and junctional terminal cisternae (JTC) derived from skeletal muscle sarcoplasmic reticulum (SR). Following incubation of JTC with ATP, a 170,000-Da glycoprotein, a 97,500-Da protein (glycogen phosphorylase), and a 55,000-60,000-Da doublet (containing calmodulin-dependent protein kinase subunit) underwent phosphorylation. Addition of calmodulin in the presence of Ca2+ (with no added protein kinase) produced a 10-fold increase of phosphorylation involving numerous JTC proteins, including the large (approximately 450,000 Da) ryanodine receptor protein. Calmodulin-dependent phosphorylation of the ryanodine receptor protein was unambiguously demonstrated by Western blot analysis. The specificity of these findings was demonstrated by much lower levels of calmodulin-dependent phosphorylation in light SR as compared to JTC, and by much lower cyclic AMP dependent kinase activity in both JTC and light SR. These observations indicate that the purified JTC contain membrane-bound calmodulin-dependent protein kinase that undergoes autophosphorylation and catalyzes phosphorylation of various membrane proteins. Protein dephosphorylation was very slow in the absence of added phosphatases, but was accelerated by the addition of phosphatase 1 and 2A (catalytic subunit) in the absence of Ca2+, and calcineurin in the presence of Ca2+. Therefore, in the muscle fiber, dephosphorylation of SR proteins relies on cytoplasmic phosphatases. No significant effect of protein phosphorylation was detected on the Ca2(+)-induced Ca2+ release exhibited by isolated JTC vesicles. However, the selective and prominent association of calmodulin-dependent protein kinase and related substrates with junctional membranes, its Ca2+ sensitivity, and its close proximity to the ryanodine and dihydropyridine receptor Ca2+ channels suggest that this phosphorylation system is involved in regulation of functions linked to these structures.     

Localization and partial characterization of the oligomeric disulfide-linked molecular weight 95,000 protein (triadin) which binds the ryanodine and dihydropyridine receptors in skeletal muscle triadic vesicles.

A monoclonal antibody, GE 4.90, has been produced following immunization of mice with the 95-kDa protein (triadin) of terminal cisternae of rabbit fast skeletal muscle isolated in nondenaturing detergent. The antibody binds to a protein of Mr95K in Western blots of microsomal vesicles electrophoresed in the presence of mercaptoethanol. The greatest intensity of the immunoblot reaction is to enriched terminal cisternae vesicles while little binding is seen to longitudinal reticulum and transverse tubules. The content of antigen in different microsomal subfractions has been estimated by immunoassay: terminal cisternae/triads contain 5.6 micrograms/mg of protein while heavy terminal cisternae contain 32 micrograms/mg. The molar content of triadin in vesicles is approximately the same as that of the ryanodine receptor. When Western blots of gels of terminal cisternae are run in nonreducing conditions, little protein of Mr95K is visible. A number of bands, however, forming a ladder of higher molecular weight are discerned, indicating that the 95-kDa protein forms a disulfide-linked homopolymer. A biotinylated aromatic disulfide reagent (biotin-HPDP) labels the 95-kDa protein, the junctional foot protein, and the Mr 106K protein described by others as a Ca(2+)-release channel (SG 106). This latter protein migrates in gel electrophoresis under nonreducing conditions at a molecular weight different from that of the 95-kDa protein. We did not detect any alteration of binding of the 95-kDa protein to the dihydropyridine receptor or junctional foot protein dependent on the state of oxidation of cysteine residues of either triadin or receptor protein used as the overlay probe.     

The Ca2+-release channel/ryanodine receptor is localized in junctional and corbular sarcoplasmic reticulum in cardiac muscle

The subcellular distribution of the Ca(2+)-release channel/ryanodine receptor in adult rat papillary myofibers has been determined by immunofluorescence and immunoelectron microscopical studies using affinity purified antibodies against the ryanodine receptor. The receptor is confined to the sarcoplasmic reticulum (SR) where it is localized to interior and peripheral junctional SR and the corbular SR, but it is absent from the network SR where the SR-Ca(2+)-ATPase and phospholamban are densely distributed. Immunofluorescence labeling of sheep Purkinje fibers show that the ryanodine receptor is confined to discrete foci while the SR-Ca(2+)-ATPase is distributed in a continuous network-like structure present at the periphery as well as throughout interior regions of these myofibers. Because Purkinje fibers lack T- tubules, these results indicate that the ryanodine receptor is localized not only to the peripheral junctional SR but also to corbular SR densely distributed in interfibrillar spaces of the I-band regions. We have previously identified both corbular SR and junctional SR in cardiac muscle as potential Ca(2+)-storage/Ca(2+)-release sites by demonstrating that the Ca2+ binding protein calsequestrin and calcium are very densely distributed in these two specialized domains of cardiac SR in situ. The results presented here provide strong evidence in support of the hypothesis that corbular SR is indeed a site of Ca(2+)-induced Ca2+ release via the ryanodine receptor during excitation contraction coupling in cardiac muscle. Furthermore, these results indicate that the function of the cardiac Ca(2+)-release channel/ryanodine receptor is not confined to junctional complexes between SR and the sarcolemma.     

Ryanodine sensitivity of the calcium release channel of sarcoplasmic reticulum

Ryanodine modulates Ca2+ permeability in isolated terminal cisternae of sarcoplasmic reticulum, suggesting that it is a specific ligand for the calcium release channel. Our laboratory has purified the ryanodine receptor and demonstrated it to be equivalent to the feet structures, which are involved in the junctional association of the transverse tubule with the terminal cisternae. Recently, Smith, Coronado and Meissner have incorporated sarcoplasmic reticulum into bilayers and found a high conductivity channel (approximately .100 pS) which has a number of characteristics expected of the Ca2+ release channels in SR. We now find that the high conductivity channel in the bilayer is sensitive to ryanodine. Low concentrations of ryanodine (sub microM): (1) lock the channels in an open state; (2) prevent the action of ruthenium red (microM) to completely close the channel; and (3) much higher concentrations of ryanodine (300 microM) close the channel. In these three respects ryanodine acts similarly on the channel in the bilayer as in vesicles. Further, the bilayer studies provide new insight into the action of ryanodine on the channel in that: (1) ryanodine locks the channel in the open state, but the conductivity is reduced to about 40%; (2) ryanodine prevents ruthenium red from closing the channel, although there is a further decrease in the open current. These studies provide support that the high conductivity calcium channel in sarcoplasmic reticulum is involved in excitation-contraction coupling. By the same token the pharmacological action of ryanodine is pinpointed to the calcium release channel.     

Functional characterization of junctional terminal cisternae from mammalian fast skeletal muscle sarcoplasmic reticulum

Junctional terminal cisternae are a recently isolated sarcoplasmic reticulum fraction containing two types of membranes, the junctional face membrane with morphologically intact "feet" structures and the calcium pump membrane [Saito, A., Seiler, S., Chu, A., & Fleischer, S. (1984) J. Cell Biol. 99, 875-885]. In this study, the Ca2+ fluxes of junctional terminal cisternae are characterized and compared with three other well-defined fractions derived from the sarcotubular system of fast-twitch skeletal muscle, including light and heavy sarcoplasmic reticulum, corresponding to longitudinal and terminal cisternae regions of the sarcoplasmic reticulum, and isolated triads. Functionally, junctional terminal cisternae have low net energized Ca2+ transport measured in the presence or absence of a Ca2+-trapping anion, as compared to light and heavy sarcoplasmic reticulum and triads. Ca2+ transport and Ca2+ pumping efficiency can be restored to values similar to those of light sarcoplasmic reticulum with ruthenium red or high [Mg2+]. In contrast to junctional terminal cisternae, heavy sarcoplasmic reticulum and triads have higher Ca2+ transport and are stimulated less by ruthenium red. Heavy sarcoplasmic reticulum appears to be derived from the nonjunctional portion of the terminal cisternae. Our studies indicate that the decreased Ca2+ transport is referable to the enhanced permeability to Ca2+, reflecting the predominant localization of Ca2+ release channels in junctional terminal cisternae. This conclusion is based on the following observations: The Ca2+, -Mg2+ -dependent ATPase activity of junctional terminal cisternae in the presence of a Ca2+ ionophore is comparable to that of light sarcoplasmic reticulum when normalized for the calcium pump protein content; i.e., the enhanced Ca2+ transport cannot be explained by a faster turnover of the pump. Ruthenium red or elevated [Mg2+] enhances energized Ca2+ transport and Ca2+ pumping efficiency in junctional terminal cisternae so that values approaching those of light sarcoplasmic reticulum are obtained. Rapid Ca2+ efflux in junctional terminal cisternae can be directly measured and is blocked by ruthenium red or high [Mg2+]. Ryanodine at pharmacologically significant concentrations blocks the ruthenium red stimulation of Ca2+ loading. Ryanodine binding in junctional terminal cisternae, which appears to titrate Ca2+ release channels, is 2 orders of magnitude lower than the concentration of the calcium pump protein. By contrast, light sarcoplasmic reticulum has a high Ca2+ loading rate and slow Ca2+ efflux that are not modulated by ruthenium red, ryanodine, or Mg2+.(ABSTRACT TRUNCATED AT 400 WORDS)     

Isolation of terminal cisternae of frog skeletal muscle. Calcium storage and release properties

Sarcoplasmic reticulum (SR) terminal cisternae (TC) of frog (Rana esculenta) fast-twitch skeletal muscle have been purified by isopycnic sucrose density gradient centrifugation. Biochemical characteristics and Ca2+ release properties have been investigated and compared to those of the homologous fraction of rabbit skeletal muscle TC. The frog SR fraction obtained at the 38/45% sucrose interface appears to be derived from the terminal cisternae region as judged by: (a) thin section electron microscopy showing vesicles containing electron opaque material and squarelike (feet) projections at the outer surface; (b) protein composition (Ca2+-ATPase, calsequestrin, and high Mr proteins); (c) Ca2+ fluxes properties. The content of calsequestrin was higher in frog TC by 50% and the Ca2+ binding capacity (624 or 45 nmol of Ca2+/mg of TC protein, depending upon experimental conditions) was 3-4 times that of rabbit TC. Species-specific antigenic differences were found between junctional SR proteins of frog and rabbit TC. After active Ca2+ preloading in the presence of pyrophosphate (Palade, P. (1987) J. Biol. Chem. 262, 6135-6141), caffeine and doxorubicin elicited Ca2+ release from either TC fraction but with much faster rates in frog TC than in rabbit TC (14 versus 3 mumol of Ca2+/min/mg of protein). The present results provide new evidence for the existence of marked differences in Ca2+ release properties between TC of amphibian and mammalian fast-twitch muscle. Higher Ca2+ binding capacity and faster release rates in frog TC might compensate for the comparably greater diffusion distance being covered by the released Ca2+ from the Z-line to the actomyosin cross-bridges in the A-I overlap region.     

Calcium binding proteins of junctional sarcoplasmic reticulum: detection by 45Ca ligand overlay

In skeletal muscle, the junctional sarcoplasmic reticulum (JFM) plays a crucial role in excitation-contraction coupling and Ca2+ release. In the present report, the sarcoplasmic reticulum (SR) was fractionated into longitudinal SR (LSR), terminal cisternae (TC), and JFM. Each fraction had a unique protein profile as detected by SDS-polyacrylamide gel electrophoresis as well as specific Ca2+ binding proteins as judged by 45Ca ligand overlay of nitrocellulose blots. Ca2+ binding proteins of LSR were the Ca2+ ATPase (Mr of 115K), an 80K polypeptide, and the intrinsic glycoprotein (Mr of 160K); Ca2+ binding proteins of JFM were polypeptides with the following Mr values: 350K and 325K (feet components), 200K, 170K, a doublet of 140K, 118K, 65K (calsequestrin), and 52K. Measurements of Ca2+ binding to SR fractions by equilibrium dialysis indicated that 8-17 nmol Ca2+/mg of protein was specifically bound. After EDTA extraction of calsequestrin, JFM still bound Ca2+ (5-6 nmol/mg of protein), suggesting the existence of specific Ca2+ binding sites. The Ca2+ binding sites of Ca2+-gated Ca2+ release channels might be on two JFM polypeptides (Mr's of 350K and 170K) which are putative channel constituents (F. Zorzato, A. Margreth, and P. Volpe (1986) J. Biol. Chem. 261, 13252-13257).     

Solubilization and separation of Ca2+-ATPase from the Ca2+-ryanodine receptor complex

Heavy sarcoplasmic reticulum (SR) preparations of rabbit skeletal muscle, which are enriched in Ca2+-release vesicles from the terminal cisternae (TC) and [3H]ryanodine receptor density, exhibit 60% of the Ca2+-ATPase activity, 58% of the EP level, and 30% of the steady state Ca2+ loading compared to membrane vesicles from the longitudinal SR. The Ca2+-ATPase of TC SR is solubilized and separated from the Ca2+-ryanodine receptor complex in the insoluble fraction on treatment with the detergent C12E9. However, a 50% decrease in receptor density is observed upon removal of the Ca2+-ATPase, suggesting a significant contribution of this protein to maintaining optimal receptor complex density.     

Ryanodine-affinity chromatography purifies 106 kD Ca release channels from skeletal and cardiac sarcoplasmic reticulum

A 106 kD protein was isolated from skeletal sarcoplasmic reticulum (SR) vesicles and shown to have the properties of SR Ca2+ release channels, including blockade by 5 nM ryanodine. In view of extensive reports that the ryanodine-receptor complex consists of four 565 kD junctional feet proteins (JFPs) and is the 'physiological' Ca2+ release channel, we prepared ryanodine-affinity columns to isolate its receptor site(s). Conditions known to maximize the association and dissociation of ryanodine to SR proteins were respectively used to link, then elute, the receptor(s) from ryanodine-affinity columns. The method purified a protein at about 100 kD from both rabbit skeletal and canine cardiac SR vesicles. The skeletal and cardiac proteins isolated by ryanodine-affinity chromatography were identified as the low molecular weight Ca2+ release channel through their antigenic reaction with an anti-106 kD monoclonal antibody. Upon reconstitution in planar bilayers, both skeletal and cardiac proteins revealed the presence of functional SR Ca2+ release channels. Surprisingly, ryanodine-affinity columns did not retain JFPs but purified 106 kD Ca2+ release channels which are a minor component (0.1-0.3%) of SR proteins.     

Antibodies to junctional sarcoplasmic reticulum proteins: probes for the Ca2+-release channel.

The junctional face membrane plays a key role in excitation-contraction coupling in skeletal muscle. A protein of 350 kDa, tentatively identified as a component of the junctional feet, connects transverse tubules to terminal cisternae of sarcoplasmic reticulum [Kawamoto, Brunschwig, Kim & Caswell (1986) J. Cell Biol. 103, 1405-1414]. The membrane topology and protein composition of sarcoplasmic reticulum Ca2+-release channels of rabbit skeletal muscle were investigated using an immunological approach, with anti-(junctional face membrane) and anti-(350 kDa protein) polyclonal antibodies. Upon preincubation of the terminal cisternae with anti-(junctional face membrane) antibodies, Ca2+-ATPase and Ca2+-loading activities were not affected, whereas anti-(350 kDa protein) antibodies stimulated Ca2+-ATPase activity by 25% and inhibited Ca2+-loading activity by 50% (at an antibody/terminal cisternae protein ratio of 1:1). Specific photolabelling of terminal cisternae proteins with [14C]doxorubicin was prevented by both anti-(junctional face membrane) and anti-(350 kDa protein) antibodies. Stimulation of Ca2+ release by doxorubicin was prevented by both anti-(junctional face membrane) and anti-(350 kDa protein) antibodies. Half-maximal inhibition was obtained at an antibody/terminal cisternae protein ratio of 1:1. Kinetic measurements of Ca2+ release indicated that anti-(350 kDa protein) antibodies prevented Ca2+-induced Ca2+ release, whereas the ATP-stimulation and the inhibition by Mg2+ were not affected. These results suggest that: (i) Ca2+- and doxorubicin-induced Ca2+ release is mediated by Ca2+ channels which are selectively localized in the junctional face membrane; (ii) the 350 kDa protein is a component of the Ca2+-release channel in native terminal cisternae vesicles; and (iii) the Ca2+-activating site of the channel is separate from other allosteric sites.     

Preparation and characterization of longitudinal tubules of sarcoplasmic reticulum from fast skeletal muscle

Sarcoplasmic reticulum (SR) serves a central role in calcium uptake and release, thereby regulating muscle relaxation and contraction, respectively. Recently, we have isolated fractions referable to longitudinal tubules (R2) and terminal cisternae (R4), the two major types of sarcoplasmic reticulum (A. Saito et al. (1984) J. Cell Biol. 99, 875-885). The terminal cisternae contain two types of membranes, the calcium pump membrane and the junctional face membrane. The terminal cisternae are filled with electron-opaque contents which serve as a Ca2+ reservoir. The longitudinal tubules consist mainly of the calcium pump membrane. In this study, we describe a new longitudinal tubule fraction (F2) and characterize it together with the R2 and R4 SR fractions. The calcium pump membrane of the longitudinal tubules is a highly specialized membrane consisting of about 90% calcium pump protein as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Extensive changes in morphology can be observed in the SR fractions referable to osmotic differences during the fixation conditions using either glutaraldehyde-tannic acid or osmium tetroxide fixatives. The changes include swelling or shrinkage and aggregation of the compartmental contents when the fixative contains calcium ions. The two types of SR have different osmotic permeability to the same medium, as indicated by differential swelling or shrinkage. Both longitudinal tubule and terminal cisternae vesicles of SR appear larger and are spherical vesicles when the glutaraldehyde-tannic acid fixative is isotonic as compared with the "standard" fixation method. We have previously reported that the ruthenium red-sensitive calcium release channels are localized to the terminal cisternae. The terminal cisternae as isolated are leaky to Ca2+ since these channels are in the "open state" (S. Fleischer et al. (1985) Proc. Natl. Acad. Sci USA 82, 7256-7259). Thus, the Ca2+, Mg2+-dependent ATPase (Ca2+ ATPase) rate is only slightly enhanced in the presence of a Ca2+ ionophore, which dissipates the Ca2+ gradient across the SR membrane. We now find that preincubation with ruthenium red restores the tight coupling of the Ca2+ ATPase activity to Ca2+ transport. That is to say, ATPase activity is reduced and the addition of ionophore stimulates the Ca2+ ATPase activity 4- to 7-fold. The Ca2+ ATPase activity in longitudinal tubules is already tightly coupled. It is minimal after a Ca2+ gradient has been generated, but can be stimulated 9- to 20-fold when the Ca2+ gradient is dissipated with ionophore. This finding suggests that the Ca2+ ATPase activity in SR is tightly coupled to Ca2+ transport in situ.     

Structural evidence for direct interaction between the molecular components of the transverse tubule/sarcoplasmic reticulum junction in skeletal muscle

The architecture of the junctional sarcoplasmic reticulum (SR) and transverse tubule (T tubule) membranes and the morphology of the two major proteins isolated from these membranes, the ryanodine receptor (or foot protein) and the dihydropyridine receptor, have been examined in detail. Evidence for a direct interaction between the foot protein and a protein component of the junctional T tubule membrane is presented. Comparisons between freeze-fracture images of the junctional SR and rotary-shadowed images of isolated triads and of the isolated foot protein, show that the foot protein has two domains. One is the large hydrophilic foot which spans the junctional gap and is composed of four subunits. The other is a hydrophobic domain which presumably forms the SR Ca2+-release channel and which also has a fourfold symmetry. Freeze-fracture images of the junctional T tubule membranes demonstrate the presence of diamond-shaped clusters of particles that correspond exactly in position to the subunits of the feet protein. These results suggest the presence of a large junctional complex spanning the two junctional membranes and intervening gap. This junctional complex is an ideal candidate for a mechanical coupling hypothesis of excitation-contraction coupling at the triadic junction.     

Structural and functional characterization of the purified cardiac ryanodine receptor-Ca2+ release channel complex

Using density gradient centrifugation and [3H]ryanodine as a specific marker, the ryanodine receptor-Ca2+ release channel complex from Chaps-solubilized canine cardiac sarcoplasmic reticulum (SR) has been purified in the form of an approximately 30 S complex, comprised of Mr approximately 400,000 polypeptides. Purification resulted in a specific activity of approximately 450 pmol bound ryanodine/mg of protein, a 60-70% recovery of ryanodine binding activity, and retention of the high affinity ryanodine binding site (KD = 3 nM). Negative stain electron microscopy revealed a 4-fold symmetric, four-leaf clover structure, which could fill a box approximately 30 x 30 nm and was thus morphologically similar to the SR-transverse-tubule, junctionally associated foot structure. The structural, sedimentation, and ryanodine binding data strongly suggest there is one high affinity ryanodine binding site/30 S complex, comprised of four Mr approximately 400,000 subunits. Upon reconstitution into planar lipid bilayers, the purified complex exhibited a Ca2+ conductance (70 pS in 50 mM Ca2+) similar to that of the native cardiac Ca2+ release channel (75 pS). The reconstituted complex was also found to conduct Na+ (550 pS in 500 mM Na+) and often to display complex Na+ subconducting states. The purified channel could be activated by micromolar Ca2+ or millimolar ATP, inhibited by millimolar Mg2+ or micromolar ruthenium red, and modified to a long-lived open subconducting state by ryanodine. The sedimentation, subunit composition, morphological, and ryanodine binding characteristics of the purified cardiac ryanodine receptor-Ca2+ release channel complex were similar to those previously described for the purified ryanodine receptor-Ca2+ release channel complex from fast-twitch skeletal muscle.