Purification and characterization of two ryanodine-binding protein isoforms from sarcoplasmic reticulum of bullfrog skeletal muscle.

The two ryanodine-binding proteins (RyBPs) have been purified from sarcoplasmic reticulum of bullfrog skeletal muscle by Mono Q column chromatography following solubilization of SR by CHAPS and sucrose density gradient centrifugation. We conclude that the two RyBPs (alpha- and beta-RyBP) are isoforms on the basis (i) that each RyBP is distinguished by a specific polyclonal antibody and (ii) that distinct polypeptides are generated by limited tryptic digestion of the two RyBPs. Monomeric molecular weights for alpha- and beta-RyBP are estimated to be (690 +/- 10) and (570 +/- 10) kDa, respectively, as determined from mobilities on disc SDS-PAGE using the Weber-Osborn buffer system without 6 M urea, which gives an estimate of (590 +/- 10) kDa for RyBP of rabbit skeletal muscle. Similar determination in the presence of 6 M urea gave 630 kDa for alpha-RyBP and unchanged estimates for the other RyBPs. Both RyBPs show [3H]ryanodine-binding activities which are activated by Ca2+, AMPOPCP, and caffeine, and inhibited by ruthenium red, MgCl2, and procaine. beta-RyBP, however, has higher affinity for Ca2+. In the presence of Ca2+ and AMPOPCP, both RyBPs show single homogeneous binding sites for [3H]ryanodine with Kd = 2-5 nM. The values of Bmax for alpha- and beta-RyBP were 320-340 and 320-375 pmol/mg protein, respectively. These results are consistent with the conclusion that a homo-tetramer of each RyBP binds one ryanodine molecule, taking account of the estimated molecular weight.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nonmammalian vertebrate skeletal muscles express two triad junctional foot protein isoforms.

Mammalian skeletal muscles express a single triad junctional foot protein, whereas avian muscles have two isoforms of this protein. We investigated whether either case is representative of muscles from other vertebrate classes. We identified two foot proteins in bullfrog and toadfish muscles on the basis of (a) copurification with [3H]epiryanodine binding; (b) similarity to avian muscle foot proteins in native and subunit molecular weights; (c) recognition by anti-foot protein antibodies. The bullfrog and toadfish proteins exist as homooligomers. The subunits of the bullfrog muscle foot protein isoforms are shown to be unique by peptide mapping. In addition, immunocytochemical localization established that the bullfrog muscle isoforms coexist in the same muscle cells. The isoforms in either bullfrog and chicken muscles have comparable [3H]epiryanodine binding capacities, whereas in toadfish muscle the isoforms differ in their levels of ligand binding. Additionally, chicken thigh and breast muscles differ in the relative amounts of the two isoforms they contain, the amounts being similar in breast muscle and markedly different in thigh muscle. In conclusion, in contrast to mammalian skeletal muscle, two foot protein isoforms are present in amphibian, avian, and piscine skeletal muscles. This may represent a general difference in the architecture and/or a functional specialization of the triad junction in mammalian and nonmammalian vertebrate muscles.     

Foot protein isoforms are expressed at different times during embryonic chick skeletal muscle development

We have investigated the time course of expression of the alpha and beta triad junctional foot proteins in embryonic chick pectoral muscle. The level of [3H]ryanodine binding in muscle homogenates is low until day E20 of embryonic development, then increases dramatically at the time of hatching reaching adult levels by day N7 posthatch. The alpha and beta foot protein isoforms increase in abundance concomitantly with [3H]ryanodine binding. Using foot protein isoform-specific antibodies, the alpha foot protein is detected in a majority of fibers in day E10 muscle, while the beta isoform is first observed at low levels in a few fibers in day E15 muscle. A high molecular weight polypeptide, distinct from the alpha and beta proteins, is recognized by antifoot protein antibodies. This polypeptide is observed in day E8 muscle and declines in abundance with continued development. It appears to exist as a monomer and does not bind [3H]ryanodine. In contrast, the alpha isoform present in day E10 muscle and the beta isoform in day E20 muscle are oligomeric and bind [3H]ryanodine suggesting that they may exist as functional calcium channels in differentiating muscle. Comparison of the intracellular distributions of the alpha foot protein, f-actin, the heavy chain of myosin and titin in day E10 muscle indicates that the alpha foot protein is expressed during myofibril assembly and Z line formation. The differential expression of the foot protein isoforms in developing muscle, and their continued expression in mature muscle, is consistent with these proteins making different functional contributions. In addition, the expression of the alpha isoform during the time of organization of a differentiated muscle morphology suggests that foot proteins may participate in events involved in muscle differentiation.     

Phosphorylation of the cardiac ryanodine receptor by cAMP-dependent protein kinase

The phosphorylation of canine cardiac and skeletal muscle ryanodine receptors by the catalytic subunit of cAMP-dependent protein kinase has been studied. A high-molecular-weight protein (Mr 400,000) in cardiac microsomes was phosphorylated by the catalytic subunit of cAMP-dependent protein kinase. A monoclonal antibody against the cardiac ryanodine receptor immunoprecipitated this phosphoprotein. In contrast, high-molecular-weight proteins (Mr 400,000-450,000) in canine skeletal microsomes isolated from extensor carpi radialis (fast) or superficial digitalis flexor (slow) muscle fibers were not significantly phosphorylated. In agreement with these findings, the ryanodine receptor purified from cardiac microsomes was also phosphorylated by cAMP-dependent protein kinase. Phosphorylation of the cardiac ryanodine receptor in microsomal and purified preparations occurred at the ratio of about one mol per mol of ryanodine-binding site. Upon phosphorylation of the cardiac ryanodine receptor, the levels of [3H]ryanodine binding at saturating concentrations of this ligand increased by up to 30% in the presence of Ca2+ concentrations above 1 microM in both cardiac microsomes and the purified cardiac ryanodine receptor preparation. In contrast, the Ca2+ concentration dependence of [3H]ryanodine binding did not change significantly. These results suggest that phosphorylation of the ryanodine receptor by cAMP-dependent protein kinase may be an important regulatory mechanism for the calcium release channel function in the cardiac sarcoplasmic reticulum.     

Ryanodine and inositol trisphosphate receptors coexist in avian cerebellar Purkinje neurons

Two intracellular calcium-release channel proteins, the inositol trisphosphate (InsP3), and ryanodine receptors, have been identified in mammalian and avian cerebellar Purkinje neurons. In the present study, biochemical and immunological techniques were used to demonstrate that these proteins coexist in the same avian Purkinje neurons, where they have different intracellular distributions. Western analyses demonstrate that antibodies produced against the InsP3 and the ryanodine receptors do not cross-react. Based on their relative rates of sedimentation in continuous sucrose gradients and SDS-PAGE, the avian cerebellar InsP3 receptor has apparent native and subunit molecular weights of approximately 1,000 and 260 kD, while those of the ryanodine receptors are approximately 2,000 and 500 kD. Specific [3H]InsP3- and [3H]ryanodine-binding activities were localized in the sucrose gradient fractions enriched in the 260-kD and the approximately 500-kD polypeptides, respectively. Under equilibrium conditions, cerebellar microsomes bound [3H]InsP3 with a Kd of 16.8 nM and Bmax of 3.8 pmol/mg protein; whereas, [3H]ryanodine was bound with a Kd of 1.5 nM and a capacity of 0.08 pmol/mg protein. Immunolocalization techniques, applied at both the light and electron microscopic levels, revealed that the InsP3 and ryanodine receptors have overlapping, yet distinctive intracellular distributions in avian Purkinje neurons. Most notably the InsP3 receptor is localized in endomembranes of the dendritic tree, in both the shafts and spines. In contrast, the ryanodine receptor is observed in dendritic shafts, but not in the spines. Both receptors appear to be more abundant at main branch points of the dendritic arbor. In Purkinje neuron cell bodies, both the InsP3 and ryanodine receptors are present in smooth and rough ER, subsurface membrane cisternae and to a lesser extent in the nuclear envelope. In some cases the receptors coexist in the same membranes. Neither protein is observed at the plasma membrane, Golgi complex or mitochondrial membranes. Both the InsP3 and ryanodine receptors are associated with intracellular membrane systems in axonal processes, although they are less abundant there than in dendrites. These data demonstrate that InsP3 and ryanodine receptors exist as unique proteins in the same Purkinje neuron. These calcium-release channels appear to coexist in ER membranes in most regions of the Purkinje neurons, but importantly they are differentially distributed in dendritic processes, with the dendritic spines containing only InsP3 receptors.     

Cardiac ryanodine receptor is absent in type I slow skeletal muscle fibers: immunochemical and ryanodine binding studies

Cardiac ryanodine receptor was purified from canine ventricle as a single polypeptide of Mr 400,000 by a stepwise sucrose density gradient centrifugation and heparin-Sepharose CL-4B column chromatography. The [3H]ryanodine binding capacity (Bmax) was 60-fold enriched from cardiac microsomes without a change in affinity for [3H]ryanodine. The purity of the final preparation was determined to be greater than 95% by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Using this purified preparation as an antigen, we produced six monoclonal antibodies which immunoprecipitated the cardiac ryanodine receptor. Three of these antibodies recognized the cardiac receptor on immunoblot analysis. In contrast, no protein in the microsomes isolated from Type I (slow) or Type II (fast) skeletal muscles was recognized by these antibodies. The [3H]ryanodine binding to cardiac and skeletal muscle microsomes was dependent on free Ca2+ concentration. In skeletal muscle microsomes, the [3H]ryanodine binding was remarkably enhanced by the addition of ATP or KCl and inhibited by high free Ca2+, whereas it was less sensitive to these agents in cardiac microsomes. All of these results clearly demonstrate that the cardiac ryanodine receptor is different from the skeletal muscle receptors and is not present even in Type I (slow) skeletal muscle fibers, in which cardiac isoforms of some of the muscle proteins are constitutively expressed.     

Novel ryanodine-binding properties in mammalian retina

The ryanodine receptor (RyR)/Ca2+ release channel mobilizes Ca2+ from internal calcium stores to support a variety of neuronal functions. To investigate the presence of such a protein in mammalian retina, we applied ryanodine binding, PCR and antibodies against known RyRs. Surprisingly, ryanodine-binding properties of retinal endoplasmic reticulum-enriched membrane fraction were vastly different from those of skeletal and cardiac muscles ryanodine-binding proteins. In common with the skeletal and cardiac muscle, ryanodine bound with high-affinity to two or more types of binding site (Kd1 = 20.6 and Kd2 = 114 nM); binding was strongly stimulated by high concentrations of NaCl; it was inhibited by tetracaine and the protein appeared to possess an ATP-binding site. Unlike cardiac and skeletal muscle, RyRs in retina binding was Ca2+-independent; inhibited by caffeine and dantrolene; less sensitive to ruthenium red; and unaffected by La3+. Also, in retina, ryanodine rapidly associated to and dissociated from its binding sites. Furthermore, although the protein bound the ATP analog BzATP, retinal ryanodine binding was not stimulated by nucleotides. Immunostaining of bovine retinal sections with anti-RyR2 showed a strong staining of amacrine, horizontal and ganglion cells. Finally, using RT-PCR, the three known RyR isoforms were identified in retina. However, consistent with the novel binding properties, the peptide maps yielded by trypsin treatment and Western blotting demonstrate different patterns. Together, the results suggest that retina expresses a novel ryanodine-binding protein, likely to be a ryanodine receptor. Its presence in retina suggests that this protein might play a role in controlling intracellular Ca2+ concentration.     

Unique phosphorylation site on the cardiac ryanodine receptor regulates calcium channel activity.

Ryanodine receptors have recently been shown to be the Ca2+ release channels of sarcoplasmic reticulum in both cardiac muscle and skeletal muscle. Several regulatory sites are postulated to exist on these receptors, but to date, none have been definitively identified. In the work described here, we localize one of these sites by showing that the cardiac isoform of the ryanodine receptor is a preferred substrate for multifunctional Ca2+/calmodulin-dependent protein kinase (CaM kinase). Phosphorylation by CaM kinase occurs at a single site encompassing serine 2809. Antibodies generated to this site react only with the cardiac isoform of the ryanodine receptor, and immunoprecipitate only cardiac [3H]ryanodine-binding sites. When cardiac junctional sarcoplasmic reticulum vesicles or partially purified ryanodine receptors are fused with planar bilayers, phosphorylation at this site activates the Ca2+ channel. In tissues expressing the cardiac isoform of the ryanodine receptor, such as heart and brain, phosphorylation of the Ca2+ release channel by CaM kinase may provide a unique mechanism for regulating intracellular Ca2+ release.     

Physiological differences between the alpha and beta ryanodine receptors of fish skeletal muscle.

Two isoforms of the sarcoplasmic reticulum Ca2+ release channel (ryanodine receptor or RYR) are expressed together in the skeletal muscles of most vertebrates. We have studied physiological properties of the two isoforms (alpha and beta) by comparing SR preparations from specialized fish muscles that express the alpha isoform alone to preparations from muscles containing both alpha and beta. Regulation of channel activity was assessed through [3H]ryanodine binding and reconstitution into planar lipid bilayers. Distinct differences were observed in the calcium-activation and -inactivation properties of the two isoforms. The fish alpha isoform, expressed alone in extraocular muscles, closely resembled the rabbit skeletal muscle RYR. Maximum [3H]ryanodine binding and maximum open probability (Po) of the alpha RYR were achieved from 1 to 10 microM free Ca2+. Millimolar Ca2+ reduced [3H]ryanodine binding and Po close to zero. The beta isoform more closely resembled the fish cardiac RYR in Ca2+ activation of [3H]ryanodine binding. The most prominent difference of the beta and cardiac isoforms from the alpha isoform was the lack of inactivation of [3H]ryanodine binding and Po by millimolar free Ca2+. Differences in activation of [3H]ryanodine binding by adenine nucleotides and inhibition by Mg2+ suggest that the beta and cardiac RYRs are not identical, however. [3H]ryanodine binding by the alpha RYR was selectively inhibited by 100 microM tetracaine, whereas cardiac and beta RYRs were much less affected. Tetracaine can thus be used to separate the properties of the alpha and beta RYRs in preparations in which both are present. The distinct physiological properties of the alpha and beta RYRs that are present together in most vertebrate muscles support models of EC coupling incorporating both directly coupled and Ca(2+)-coupled channels within a single triad junction.     

Identification and localization of ryanodine binding proteins in the avian central nervous system

Ryanodine binding proteins of the CNS have been identified using monoclonal antibodies against avian skeletal muscle ryanodine binding proteins. These proteins were localized to intracellular membranes of the dendrites, perikarya, and axons of cerebellar Purkinje neurons using laser confocal microscopy and immunoelectron microscopy. Ryanodine binding proteins were not found in dendritic spines. Immunoprecipitation and [3H]epiryanodine binding experiments revealed that the cerebellar ryanodine binding proteins have a native molecular weight of approximately 2000 kd and are composed of two high molecular weight (approximately 500 kd) polypeptide subunits. A comparable protein having a single high molecular weight polypeptide subunit was observed in the remainder of the brain. If the ryanodine binding proteins in muscle and nerve are similar in function, then the neuronal proteins may participate in the release of calcium from intracellular stores that are mechanistically and spatially distinct from those gated by inositol trisphosphate receptors.     

Triadins are not triad-specific proteins: two new skeletal muscle triadins possibly involved in the architecture of sarcoplasmic reticulum

We have cloned two new triadin isoforms from rat skeletal muscle, Trisk 49 and Trisk 32, which were named according to their theoretical molecular masses (49 and 32 kDa, respectively). Specific antibodies directed against each protein were produced to characterize both new triadins. Both are expressed in adult rat skeletal muscle, and their expression in slow twitch muscle is lower than that in fast twitch muscle. Using double immunofluorescent labeling, the localization of these two triadins was studied in comparison to well-characterized proteins such as ryanodine receptor, calsequestrin, desmin, Ca(2+)-ATPase, and titin. None of these two triadins are localized within the rat skeletal muscle triad. Both are instead found in different parts of the longitudinal sarcoplasmic reticulum. We attempted to identify partners for each isoform: neither is associated with ryanodine receptor; Trisk 49 could be associated with titin or another sarcomeric protein; and Trisk 32 could be associated with IP(3) receptor. These results open further fields of research concerning the functions of these two proteins; in particular, they could be involved in the set up and maintenance of a precise sarcoplasmic reticulum structure.     

Characterization of [(3)H]ryanodine binding sites in mammalian lung

The ryanodine-sensitive calcium channels, also called ryanodine receptors, are intracellular Ca(2+)-release channels that have been shown to bind the neutral plant alkaloid ryanodine with nanomolar affinity. The activity of the skeletal muscle (RyR1), cardiac muscle (RyR2), and brain (RyR3) ryanodine receptor isoforms have been shown to be highly regulated by physiological factors including pH, temperature, and ionic strength; endogenous compounds including Ca(2+), Mg(2+), and adenosine triphosphate (ATP); and pharmacological agents including caffeine, ruthenium red, and neomycin. RyR3 is reportedly expressed in diverse tissues including lung; however, specific [(3)H]ryanodine binding sites in mammalian lung tissue have not been characterized. In this study, hamster lung ryanodine binding proteins were shown to specifically bind [(3)H]ryanodine with an affinity similar to that of RyR isoforms found in other tissues and this binding was shown to be sensitive to Ca(2+) concentration, stimulation by caffeine and spermine, and inhibition by Mg(2+), ruthenium red, and neomycin. The solubilized, intact ryanodine binding protein from hamster lung demonstrated approximately the same 30S sedimentation coefficient as RyR1 and RyR2, but a putative ryanodine receptor subunit from hamster lung was not found to cross-react with antibodies specific for the three known isoforms. We conclude that the hamster lung ryanodine binding protein demonstrates sedimentation and binding characteristics that are similar to those of the known RyR isoforms, but may exhibit antigenic dissimilarity from the typical RyR isoforms found in muscle and brain.     

The ryanodine receptor/junctional channel complex is regulated by growth factors in a myogenic cell line

The ryanodine receptor/junctional channel complex (JCC) forms the calcium release channel and foot structures of the sarcoplasmic reticulum. The JCC and the dihydropyridine (DHP) receptor in the transverse tubule are two of the major components involved in excitation-contraction (E-C) coupling in skeletal muscle. The DHP receptor is believed to serve as the voltage sensor in E-C coupling. Both the JCC and DHP receptor, as well as many skeletal muscle-specific contractile protein genes, are expressed in the BC3H1 muscle cell line. In the present study, we find that during differentiation of BC3H1 cells, induced by mitogen withdrawal, induction of the JCC and DHP receptor mRNAs is temporally similar to that of the skeletal muscle contractile protein genes alpha-tropomyosin and alpha-actin. Our data suggest that there is coordinate regulation of both the contractile protein genes (which have been studied in detail previously) and the genes encoding the calcium channels involved in E-C coupling. Induction of both calcium channels is accompanied by profound changes in BC3H1 cell morphology including the development of many components of mature skeletal muscle cells, despite lack of myoblast fusion. Visualized by electron microscopy, the JCC appears as "foot structures" located in the dyad junction between the plasmalemma and the sarcoplasmic reticulum of the BC3H1 cells. Development of foot structures is concomitant with JCC mRNA expression. Expression of the JCC and DHP receptor mRNAs and formation of the foot structures are inhibited specifically by fibroblast growth factor.     

Inhibition of Ca2+ release channel (ryanodine receptor) activity by sphingolipid bases: mechanism of action

Sphingosine inhibits the activity of the skeletal muscle Ca2+ release channel (ryanodine receptor) and is a noncompetitive inhibitor of [3H]ryanodine binding (Needleman et al., Am. J. Physiol. 272, C1465-1474, 1997). To determine the contribution of other sphingolipids to the regulation of ryanodine receptor activity, several sphingolipid bases were assessed for their ability to alter [3H]ryanodine binding to sarcoplasmic reticulum (SR) membranes and to modulate the activity of the Ca2+ release channel. Three lipids, N,N-dimethylsphingosine, dihydrosphingosine, and phytosphingosine, inhibited [3H]ryanodine binding to both skeletal and cardiac SR membranes. However, the potency of these three lipids and sphingosine was lower in rabbit cardiac membranes when compared to rabbit skeletal muscle membranes and when compared to sphingosine. Like sphingosine, the lipids inhibited [3H]ryanodine binding by greatly increasing the rate of dissociation of bound [3H]ryanodine from SR membranes, indicating that these three sphingolipid bases were noncompetitive inhibitors of [3H]ryanodine binding. These bases also decreased the activity of the Ca2+ release channel incorporated into planar lipid bilayers by stabilizing a long closed state. Sphingosine-1-PO4 and C6 to C18 ceramides of sphingosine had no significant effect on [3H]ryanodine binding to cardiac or skeletal muscle SR membranes. Saturation of the double bond at positions 4-5 decreased the ability of the sphingolipid bases to inhibit [3H]ryanodine binding 2-3 fold compared to sphingosine. In summary, our data indicate that other endogenous sphingolipid bases are capable of modulating the activity of the Ca2+ release channel and as a class possess a common mechanism of inhibition.     

Solubilization and biochemical characterization of the high affinity [3H]ryanodine receptor from rabbit brain membranes

A high affinity [3H]ryanodine receptor has been solubilized from rabbit brain membranes and biochemically characterized. [3H]Ryanodine binding to rabbit brain membranes is specific and saturable, with a Kd of 1.3 nM. [3H]Ryanodine binding is enriched in membranes from the hippocampus but is significantly lower in membranes from the brain stem and spinal cord. Approximately 60% of [3H]ryanodine-labeled receptor is solubilized from brain membranes using 2.5% CHAPS and 10 mg/ml phosphatidylcholine containing 1 M NaCl. The solubilized brain [3H]ryanodine receptor sediments through sucrose gradients like the skeletal receptor as a large (approximately 30 S) complex. Solubilized receptor is specifically immunoprecipitated by sheep polyclonal antibodies against purified skeletal muscle ryanodine receptor coupled to protein A-Sepharose. [3H]Ryanodine-labeled receptor binds to heparin-agarose, and a protein of approximately 400,000 Da, which is cross-reactive with two polyclonal antibodies raised against the skeletal muscle ryanodine receptor, elutes from the column and is enriched in peak [3H]ryanodine binding fractions. These results suggest that the approximately 400,000-Da protein is the brain form of the high affinity ryanodine receptor and that it shares several properties with the skeletal ryanodine receptor including a large oligomeric structure composed of approximately 400,000-Da subunits.     

Ryanodine as a functional probe of the skeletal muscle sarcoplasmic reticulum Ca2+ release channel

Ryanodine is a neutral plant alkaloid which functions as a probe for an intracellular Ca²⁺ release channel (ryanodine receptor) in excitable tissues. Using [³H]ryanodine, a 30 S protein complex comprised of four polypeptides of M_r 565,000 has been isolated and functionally reconstituted into planar lipid bilayers. The effects of salt concentration and divalent cations on skeletal muscle sarcoplasmic reticulum [³H]ryanodine binding and Ca²⁺ release channel activity have been compared. These studies suggest that ryanodine is a good probe for investigating the function of the release channel.     

Abnormal sarcoplasmic reticulum ryanodine receptor in malignant hyperthermia

Previous studies have demonstrated that skeletal muscle from individuals susceptible to malignant hyperthermia (MH) has a defect associated with the mechanism of calcium release from its intracellular storage sites in the sarcoplasmic reticulum (SR). In this report we demonstrate that the [3H]ryanodine receptor of isolated MH-susceptible (MHS) porcine heavy SR exhibits an altered Ca2+ dependence of [3H]ryanodine binding at the low affinity Ca2+ site as well as a lower Kd for ryanodine (92 versus 265 nM) when compared to normal porcine SR. The Bmax of the normal and MHS [3H] ryanodine receptor (9.3-12.6 pmol/mg) was not significantly different, and analysis of MHS and normal SR proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis did not reveal a significant difference in the intensity of Coomassie Blue staining of the spanning protein/ryanodine receptor region of the gels (Mr greater than 300,000). We also find that MHS porcine muscle intact fiber bundles exhibit a 5-10-fold lower ryanodine threshold for twitch and tetanus inhibition, and contracture onset when compared to normal muscle. Since the SR ryanodine receptor is a calcium release channel as well as a component intimately involved in transverse tubule-SR communication, abnormalities in the skeletal muscle ryanodine receptor may be responsible for the abnormal SR calcium release and contractile properties demonstrated by MHS muscle.     

Cardiac Sarcalumenin: Phosphorylation, Comparison with the Skeletal Muscle Sarcalumenin and Modulation of Ryanodine Receptor

Cardiac sarcoplasmic reticulum (SR) contains an endogenous phosphorylation system that under specific conditions phosphorylates two proteins with apparent molecular masses of 150 and 130 kDa. The conditions for their phosphorylation are as for the skeletal muscle sarcalumenin and the histidine-rich Ca²⁺ binding protein (HCP) with respect to: (i) Ca²⁺ and high concentrations of NaF are required; (ii) phosphorylation is obtained with no added Mg²⁺ and shows a similar time course and ATP concentration dependence; (iii) inhibition by similar concentrations of La³⁺; (iv) phosphorylation is obtained with [γ-³²P]GTP; (v) ryanodine binding is inhibited parallel to the phosphorylation of the two proteins. The endogenous kinase is identified as casein kinase II (CK II) based on its ability to use GTP as effectively as ATP, and its inhibition by La³⁺. The association of CK II with the cardiac SR, even after EGTA extraction at alkaline pH, is demonstrated using antibodies against CK II. The cardiac 130 kDa protein is identified as sarcalumenin based on its partial amino acid sequence and its blue staining with Stains-All. Cardiac sarcalumenin is different from the skeletal muscle protein based on electrophoretic mobilities, immunological analysis, peptide and phosphopeptide maps, as well as amino acid sequencing. Preincubation of SR with NaF and ATP, but not with NaF and AMP-PNP caused strong inhibition of ryanodine binding. This is due to decrease in Ca²⁺- and ryanodine-binding affinities of the ryanodine receptor (RyR) by about 6.6 and 18-fold, respectively. These results suggest that cardiac sarcalumenin is an isoform of the skeletal muscle protein. An endogenous CK II can phosphorylate sarcalumenin, and in parallel to its phosphorylation the properties of the ryanodine receptor are modified. Received: 15 December 1998/Revised: 25 March 1999     

Sequential expression during postnatal development of specific markers of junctional and free sarcoplasmic reticulum in chicken pectoralis muscle.

Skeletal muscle sarcoplasmic reticulum comprises two distinct membrane domains, i.e., the Ca(2+)-pump membrane, corresponding mainly to longitudinal tubules, and the junctional membrane of the terminal cisternae containing the ryanodine receptor/Ca(2+)-release channel. Additional minor proteins previously shown in rabbit fast-twitch skeletal muscle to fractionate selectively to each membrane domain comprise 160- and 53-kDa glycoproteins and 170-kDa low-density lipoprotein (LDL)-binding protein, respectively (Damiani and Margreth, 1991, Biochem. J. 277, 825-832). We report evidence in chicken pectoralis, a predominantly fast muscle, on two closely immunologically related glycoproteins, a minor component of 130-kDa and a major 53-kDa protein. In contrast to the seemingly highly conserved structure of this protein, our results show marked differences in mobilities for chicken 125I-LDL that were detected as a 130- to 116-kDa protein doublet after sodium dodecyl sulfate-polyacrylamide gel electrophoresis, although being otherwise indistinguishable from rabbit 170-kDa protein in LDL-binding characteristics, as well as for preferential association to junctional terminal cisternae. Chicken Ca(2+)-ATPase, although being extensively homologous to rabbit Ca(2+)-ATPase, is shown to be less active and to differ slightly in electrophoretic properties. We have investigated the time course of expression of the specific protein components of longitudinal and of junctional sarcoplasmic reticulum in chick pectoralis muscle from late embryonic development up to 2 months after hatching. Coincident with the posthatching increase in membrane density of high-affinity [3H]ryanodine-binding sites in muscle, both calsequestrin and the species-specific LDL-binding protein(s) are detected in increasing amounts, using ligand blot techniques. In contrast, the appearance and steady accumulation in muscle of Ca(2+)-ATPase, like the time-correlated increase of sarcoplasmic reticulum glycoproteins, are relatively delayed, the most striking changes occurring from 1 week after hatching onward. The sequential expression in chick developing muscle of proteins selectively associated with the junctional terminal cisternae and with longitudinal sarcoplasmic reticulum, respectively, argues for a similar morphogenetic program in avian and mammalian species and, to account for that, for the existence of common epigenetic differentiating influences on the expression of sarcoplasmic reticulum protein genes.     

Comparison of properties of Ca2+ release channels between rabbit and frog skeletal muscles

Biochemical investigation of Ca2+ release channel proteins has been carried out mainly with rabbit skeletal muscles, while frog skeletal muscles have been preferentially used for physiological investigation of Ca2+ release. In this review, we compared the properties of ryanodine receptors (RyR), Ca2+ release channel protein, in skeletal muscles between rabbit and frog. While the Ryr1 isoform is the main RyR of rabbit skeletal muscles, two isoforms, - and -RyR which are homologous to Ryr1 and Ryr3 isoforms in mammals, respectively, coexist as a homotetramer in a similar amount in frog skeletal muscles. The two isoforms in an isotonic medium show very similar property in [3H]ryanodine binding activity which is parallel to Ca2+-induced Ca2+ release (CICR) activity, and make independent contributions to the activities of the sarcoplasmic reticulum. CICR and [3H]ryanodine binding activities of rabbit and frog are qualitatively similar in stimulation by Ca2+, adenine nucleotide and caffeine, however, they showed the following quantitative differences. First, rabbit RyR showed higher Ca2+ affinity than the frog. Second, rabbit RyR showed higher activity in the presence of Ca2+ alone with less stimulation by adenine nucleotide than the frog. Third, rabbit RyR displayed less enhancement of [3H]ryanodine binding by caffeine in spite of having a similar magnitude of Ca2+ sensitization than the frog, which may explain the occasional difficulty by researchers to demonstrate caffeine contracture with mammalian skeletal muscles. Finally, but not least, rabbit RyR still showed marked inhibition of [3H]ryanodine binding in the presence of high Ca2+ concentrations in the 1 M NaCl medium, while frog RyR showed disinhibition. Other matters relevant to Ca2+ release were also discussed.