Specific protein-protein interactions of calsequestrin with junctional sarcoplasmic reticulum of skeletal muscle

Minor protein components of triads and of sarcoplasmic reticulum (SR) terminal cisternae (TC), i.e. 47 and 37 kDa peptides and 31-30 kDa and 26-25 kDa peptide doublets, were identified from their ability to bind 125I calsequestrin (CS) in the presence of EGTA. The CS-binding peptides are specifically associated with the junctional membrane of TC, since they could not be detected in junctional transverse tubules and in longitudinal SR fragments. The 31-30 kDa peptide doublet, exclusively, did not bind CS in the presence of Ca2+. Thus, different types of protein-protein interactions appear to be involved in selective binding of CS to junctional TC.     

Targeting of calsequestrin to the sarcoplasmic reticulum of skeletal muscle upon deletion of its glycosylation site

The glycoprotein calsequestrin (CS) is segregated to the junctional sarcoplasmic reticulum (jSR) and is responsible for intraluminal Ca(2+) binding. A chimeric CS-hemoagglutinin 1 (HA1), obtained by adding the nine amino acid viral epitope hemoagglutinin to the carboxy terminal of CS and shown to be correctly segregated to skeletal muscle jSR [A. Nori, K. A. Nadalini, A. Martini, R. Rizzuto, A. Villa, and P. Volpe (1997). Chimeric calsequestrin and its targeting to the junctional sarcoplasmic reticulum of skeletal muscle. Am. J. Physiol. 272, C1420-C1428] lends itself as a molecular tool to investigate the targeting domains of CS. A putative targeting mechanism of CS to jSR implies glycosylation-dependent steps in the endoplasmic reticulum (ER) and Golgi complex. To test this hypothesis, CS-HA1DeltaGly, a mutant in which the unique N-glycosylation site Asn316 was changed to Ile, was engineered by site-directed mutagenesis. The mutant cDNA was transiently transfected in either HeLa cells, myoblasts of rat skeletal muscle primary cultures, or regenerating soleus muscle fibers of adult rats. The expression and intracellular localization of CS-HA1DeltaGly was studied by double-labeling epifluorescence by means of antibodies against either CS, HA1, or the ryanodine receptor calcium release channel. CS-HA1DeltaGly was expressed and retained to ER and ER/sarcoplasmic reticulum of HeLa cells and myotubes, respectively, and expressed, sorted, and correctly segregated to jSR of regenerating soleus muscle fibers. Thus, the targeting mechanism of CS in vivo appears not to be affected by glycosylation-that is, the sorting, docking, and segregation of CS are independent of cotranslational and posttranslational glycosylation or glycosylations.     

Calsequestrin targeting to sarcoplasmic reticulum of skeletal muscle fibers

Calsequestrin (CS) is the low-affinity, high-capacity calcium binding protein segregated to the lumen of terminal cisternae (TC) of the sarcoplasmic reticulum (SR). The physiological role of CS in controlling calcium release from the SR depends on both its intrinsic properties and its localization. The mechanisms of CS targeting were investigated in skeletal muscle fibers and C₂C₁₂ myotubes, a model of SR differentiation, with four deletion mutants of epitope (hemagglutinin, HA)-tagged CS: CS-HA24_NH2, CS-HA2D, CS-HA3D, and CS-HAHT, a double mutant of the NH₂ terminus and domain III. As judged by immunofluorescence of transfected skeletal muscle fibers, only the double CS-HA mutant showed a homogeneous distribution at the sarcomeric I band, i.e., it did not segregate to TC. As shown by subfractionation of microsomes derived from transfected skeletal muscles, CS-HAHT was largely associated to longitudinal SR whereas CS-HA was concentrated in TC. In C₂C₁₂ myotubes, as judged by immunofluorescence, not only CS-HAHT but also CS-HA3D and CS-HA2D were not sorted to developing SR. Condensation competence, a property referable to CS oligomerization, was monitored for the several CS-HA mutants in C₂C₁₂ myoblasts, and only CS-HA3D was found able to condense. Together, the results indicate that 1) there are at least two targeting sequences at the NH₂ terminus and domain III of CS, 2) SR-specific target and structural information is contained in these sequences, 3) heterologous interactions with junctional SR proteins are relevant for segregation, 4) homologous CS-CS interactions are involved in the overall targeting process, and 5) different targeting mechanisms prevail depending on the stage of SR differentiation. protein-protein interactions; oligomerization; intracellular sorting     

A novel method for the isolation of calsequestrin from porcine skeletal muscle sarcoplasmic reticulum

Bovine heart submitochondrial particles depleted of F1 by treatment with urea ("F1-depleted particles') were incubated with soluble F1-ATPase. The binding of F1 to the particles and the concomitant conferral of oligomycin sensitivity on the ATPase activity required the presence of cations in the incubation medium. NH4+, K+, Rb+, Na+ and Li+ promoted reconstitution maximally at 40-74 mM, guanidinium+ and Tris+ at 20-30 mM, and Ca2+ and Mg2+ at 3-5 mM. The particles exhibited a negative zeta-potential, as determined by microelectrophoresis, and this was neutralized by mono- and divalent cations in the same concentration range as that needed to promote F1 binding and reconstitution of oligomycin-sensitive ATPase. It is concluded that the cations act by neutralizing negative charges on the membrane surface, mainly negatively charged phospholipids. These results are discussed in relation to earlier findings reported in the literature with F1-depleted thylakoid membranes and with submitochondrial particles depleted of both F1 and the coupling proteins F6 and oligomycin sensitivity-conferring protein.     

Site-directed mutagenesis and deletion of three phosphorylation sites of calsequestrin of skeletal muscle sarcoplasmic reticulum. Effects on intracellular targeting

Calsequestrin (CS) is segregated to the junctional sarcoplasmic reticulum (jSR) of skeletal muscle fibers and is responsible for intraluminal Ca(2+) binding. A chimeric CS-HA1, obtained by adding the nine-amino-acid viral epitope hemagglutinin (HA1) to the carboxy-terminal of CS and shown to be correctly segregated to skeletal muscle jSR in vivo (A. Nori, K. A. Nadalini, A. Martini, R. Rizzuto, A. Villa, and P. Volpe, 1997, Am. J. Physiol. 272, C1420-C1428), is mutagenized in order to identify domains of CS involved in targeting. Since a putative targeting mechanism of CS implies phosphorylation-dependent steps in the endoplasmic reticulum (ER) and/or Golgi complex, five CS-HA1 mutants disrupting the three phosphorylation sites of CS (Thr(189), Thr(229), and Thr(353)) were engineered by either site-directed mutagenesis or deletion: CS-HA1DeltaP1 (Thr(189) --> Ile); CS-HA1DeltaP2 (Thr(229) --> Asn); CS-HA1DeltaP1,2; in which Thr(189) and Thr(229) were changed to Ile and Asn, respectively; and CS-HA1Delta14(COOH) and CS-HA1Delta49 (COOH), in which 14 residues (Glu(354)-Asp(367)) and 49 residues (Asp(319)-Asp(367)), respectively, were deleted at the carboxy-terminal. Mutant cDNAs were transiently transfected in either HeLa cells, cultured myoblasts of rat skeletal muscle, or regenerating soleus muscle fibers of adult rats. Each CS-HA1 mutant was identified by Western blot as a single polypeptide of the predicted molecular weight. The intracellular localization of CS-HA1 mutants was studied by immunofluorescence using specific antibodies against either CS or HA1. CS-HA1 mutants colocalized with ER markers, e.g., calreticulin, and partially overlapped with Golgi complex markers, e.g., alpha-mannosidase II, in HeLa cells and myotubes. CS-HA1 mutants were expressed and retained in ER and ER/SR of HeLa cells and myotubes, respectively, and correctly segregated to jSR of regenerating soleus muscle fibers. Thus, the targeting mechanism of CS in vivo is not affected by phosphorylation(s); i.e., sorting and segregation of CS appear to be independent of posttranslational phosphorylation(s).     

Distribution of sarcoplasmic reticulum Ca-ATPase and of calsequestrin in rabbit and rat skeletal muscle fibers

Muscle fibers in rabbit extensor digitorum longus (EDL), tibialis anterior (TA) and soleus, and rat soleus, were examined immunohistochemically for two proteins of the sarcoplasmic reticulum. Ca-ATPase and calsequestrin (CaS). Fibers were typed with the histochemical reaction for actomyosin ATPase. In the rabbit EDL and TA, type I fibers clearly reacted less for Ca-ATPase and CaS than type II fibers, but the difference was less with CaS than with Ca-ATPase. Although the differences were relatively small, IIB fibers consistently presented greater amounts of Ca-ATPase than IIA fibers. No type II subgroups could be recognized after incubation with anti-CaS. These findings confirm results from previous immunochemical measurements on whole muscles containing different proportions of IIA and IIB fibers (Leberer and Pette 1986). Type IIA and IIC in the rabbit and rat soleus reacted stronger for Ca-ATPase and for CaS than type I fibers. Small differences in Ca-ATPase, but not in CaS, were recognized within the type I fiber population. Therefore, type I fibers in the rabbit and rat soleus are not a homogeneous population.     

Distribution of sarcoplasmic reticulum Ca-ATPase and of calsequestrin in rabbit and rat skeletal muscle fibers

Summary Muscle fibers in rabbit extensor digitorum longus (EDL), tibialis anterior (TA) and soleus, and rat soleus, were examined immunohistochemically for two proteins of the sarcoplasmic reticulum, Ca-ATPase and calsequestrin (CaS). Fibers were typed with the histochemical reaction for actomyosin ATPase. In the rabbit EDL and TA, type I fibers clearly reacted less for Ca-ATPase and CaS than type II fibers, but the difference was less with CaS than with Ca-ATPase. Although the differences were relatively small, HB fibers consistently presented greater amounts of Ca-ATPase than IIA fibers. No types II subgroups could be recognized after incubation with anti-CaS. These findings confirm results from previous immunochemical measurements on whole muscles containing different proportions of IIA and IIB fibers (Leberer and Pette 1986). Type IIA and IIC in the rabbit and rat soleus reacted stronger for Ca-ATPase and for CaS than type I fibers. Small differences in Ca-ATPase, but not in CaS, were recognized within the type I fiber population. Therefore, type I fibers in the rabbit and rat soleus are not a homogeneous population.     

Assembly of the sarcoplasmic reticulum. Biosynthesis of calsequestrin in rat skeletal muscle cell cultures.

Temporal patterns of biosynthesis of the sarcoplasmic reticulum protein, calsequestrin, were analyzed and compared with rates of ATPase synthesis in primary cultures of rat skeletal muscle cells. Rates of synthesis were measured by the incorporation of radioactive leucine into the isolated proteins. Cells at various stages of differentiation were incubated for 2 h with tritium-labeled leucine and extracted with detergent. The extracts were incubated with antibodies specific against calsequestrin or the ATPase and immunoprecipitates were separated by disc gel electrophoresis. Incorporation of radioactivity into bands identified as calsequestrin or the ATPase was analyzed by counting of gel slices. In Dulbecco's modified Eagles medium (DME medium) containing 0.1 volume of horse serum and 0.005 volume of chick embryo extract, the cells began to fuse after about 50 h in culture, forming multinucleated myotubes. Calsequestrin synthesis was barely detectable after 24 h in culture. After 44 h, before fusion of myoblasts began, the rate of calsequestrin synthesis increased severalfold. The rate of synthesis continued to increase until about 72 h and then diminished. If cells were transferred at 44 h to DME medium containing 0.2 volume of fetal calf serum and 0.08 volume of chick embryo extract, fusion was delayed by about 20 h. In this medium the rate of calsequestrin synthesis diminished after a peak at 44 h but, by contrast, the rate of synthesis of the ATPase increased dramatically following fusion at about 80 h. If cells were transferred at about 40 h to DME medium containing 0.1 volume of horse serum and only 60 muM Ca2+ the cells did not fuse and, again, the rate of calsequestrin synthesis was diminished after a peak at about 40 h. By contrast the rate of ATPase synthesis increased sharply in spite of the lack of fusion. Both proteins were degraded with a half-life of about 20 h. These studies show that the synthesis of calsequestrin, an extrinsic membrane protein, and the ATPase, an intrinsic protein of the same membrane, are synthesized under separate control.     

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)     

Identification of a region of calsequestrin that binds to the junctional face membrane of sarcoplasmic reticulum

The interaction of calsequestrin (CSQ) with the channel-containing region of the sarcoplasmic reticulum (junctional face membrane, jfm) is involved in Ca2+ release, and it seemed of interest to identify the jfm-binding region of the CSQ molecule. For this purpose, CSQ was digested with trypsin, and peptides were screened for jfm binding. Partial amino acid sequencing of selected peptides allowed us to localize a critical site for jfm binding in the stretch encompassing residues 86-191.     

Endoplasmic reticulum of rat liver contains two proteins closely related to skeletal sarcoplasmic reticulum Ca-ATPase and calsequestrin

Rat liver endoplasmic reticulum (ER) membranes were investigated for the presence of proteins having structural relationships with sarcoplasmic reticulum (SR) proteins. Western immunoblots of ER proteins probed with polyclonal antibodies raised against the 100-kDa SR Ca-ATPase of rabbit skeletal muscle identified a single reactive protein of 100 kDa. Also, the antibody inhibited up to 50% the Ca-ATPase activity of isolated ER membranes. Antisera raised against the major intraluminal calcium binding protein of rabbit skeletal muscle SR, calsequestrin (CS), cross-reacted with an ER peptide of about 63 kDa, by the blotting technique. Stains-All treatment of slab gels showed that the cross-reactive peptide stained metachromatically blue, similarly to SR CS. Two-dimensional electrophoresis (Michalak, M., Campbell, K. P., and MacLennan, D. H. (1980) J. Biol. Chem. 255, 1317-1326) of ER proteins showed that the CS-like component of liver ER, similarly to skeletal CS, fell off the diagonal line, as expected from the characteristic pH dependence of the rate of mobility of mammalian CS. In addition, the CS-like component of liver ER was released from the vesicles by alkaline treatment and was found to be able to bind calcium, by a 45Ca overlay technique. From these findings, we conclude that a 100-kDa membrane protein of liver ER is the Ca-ATPase, and that the peripheral protein in the 63-kDa range is closely structurally and functionally related to skeletal CS.     

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+.     

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.     

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.     

Photolabeling of the integral proteins of skeletal muscle sarcoplasmic reticulum: comparison of junctional and nonjunctional membrane fractions

Rabbit skeletal muscle sarcoplasmic reticulum (SR) was fractionated by isopycnic density gradient centrifugation into longitudinal tubules (LSR) and terminal cisternae (TC). Junctional face membranes (JFM) were obtained by Triton X-100 treatment of the TC fraction (Costello, B., Chadwick, C., Saito, A., Chu, A., Maurer, A. and Fleischer, S. (1986) J. Cell Biol. 103, 741-753). Photoactivatable phospholipid analogs were introduced into LSR, TC, and JFM fractions to specifically label integral membrane proteins. Remarkably different labeling patterns were observed. Proteins of the following Mr were labeled and identified in the junctional sarcoplasmic reticulum (JFM): 350,000, 325,000, 80,000, 49,000, 37,000, 32,000, 30,000, and 6000. Polypeptides of Mr 105,000 (Ca2+-dependent ATPase), 77,000, 55,000, 41,000, 22,000, and 9000 (proteolipid) were labeled and found to be selectively localized in the nonjunctional sarcoplasmic reticulum (LSR). Calsequestrin, a key protein responsible for Ca2+ storage within the SR lumen, was never labeled, whether 1 mM CaCl2 was present or absent, and is termed a nonintegral membrane protein.