Characteristics of skeletal muscle calsequestrin: comparison of mammalian, amphibian and avian muscles

Calsequestrins in skeletal and cardiac muscle from adult Danio rerio

Calsequestrin (Casq) is a high capacity, low affinity Ca(2+)-binding protein, critical for Ca(2+)-buffering in cardiac and skeletal muscle sarcoplasmic reticulum. All vertebrates have multiple genes encoding for different Casq isoforms. Increasing interest has been focused on mammalian and human Casq genes since mutations of both cardiac (Casq2) and skeletal muscle (Casq1) isoforms cause different, and sometime severe, human pathologies. Danio rerio (zebrafish) is a powerful model for studying function and mutations of human proteins. In this work, expression, biochemical properties cellular and sub-cellular localization of D. rerio native Casq isoforms are investigated. By quantitative PCR, three mRNAs were detected in skeletal muscle and heart with different abundances. Three zebrafish Casqs: Casq1a, Casq1b and Casq2 were identified by mass spectrometry (Data are available via ProteomeXchange with identifier PXD002455). Skeletal and cardiac zebrafish calsequestrins share properties with mammalian Casq1 and Casq2. Skeletal Casqs were found primarily, but not exclusively, at the sarcomere Z-line level where terminal cisternae of sarcoplasmic reticulum are located.

Calsequestrin distribution, structure and function, its role in normal and pathological situations and the effect of thyroid hormones

Calsequestrin is the main calcium binding protein of the sarcoplasmic reticulum, serving as an important regulator of Ca(2+). In mammalian muscles, it exists as a skeletal isoform found in fast- and slow-twitch skeletal muscles and a cardiac isoform expressed in the heart and slow-twitch muscles. Recently, many excellent reviews that summarised in great detail various aspects of the calsequestrin structure, localisation or function both in skeletal and cardiac muscle have appeared. The present review focuses on skeletal muscle: information on cardiac tissue is given, where differences between both tissues are functionally important. The article reviews the known multiple roles of calsequestrin including pathology in order to introduce this topic to the broader scientific community and to stimulate an interest in this protein. Newly we describe our results on the effect of thyroid hormones on skeletal and cardiac calsequestrin expression and discuss them in the context of available literary data on this topic.

Architecture and regulation of the Ca2+ delivery system in muscle cells

The junctional domain of sarcoplasmic reticulum (jSR) is specialized for receiving signals from the plasmalemma-transverse tubules and for releasing Ca2+ during muscle activation. The junctional face of the jSR, facing the transverse tubules, is occupied by a molecular complex composed of the transmembrane Ca2+ release channels (ryanodine receptors); the luminal protein calsequestrin (CSQ); the 2 membrane proteins, junctin (Jct), and triadin (Tr), which mediate CSQ-ryanodine receptor interactions; and several other components. Under the conditions prevailing within the sarcoplasmic reticulum lumen (physiological ionic strength, mostly due to K+ and Ca2+ ions), CSQ forms long linear polymers and the fixed protein gel is clearly visible in the electron microscope. The luminal domains of Jct and Tr are detectable but, overall, the 2 molecules are not clearly delineated. Cardiac muscles either overexpressing or bearing null mutations for 3 proteins of the junctional complex (CSQ, Jct, and Tr) reveal the contribution of these 3 components to the general architecture of the jSR.

Cloning of the genes encoding mouse cardiac and skeletal calsequestrins: expression pattern during embryogenesis

Calsequestrin is a low-affinity and high-capacity calcium-binding protein in the sarcoplasmic reticulum (SR). In the present study, we have cloned and sequenced mouse cardiac and skeletal calsequestrin cDNAs. The deduced amino acid sequences are highly homologous to those of other mammalian calsequestrins. As expected, the cardiac and skeletal calsequestrins are expressed specifically and exclusively in adult heart and skeletal muscles, respectively. In-situ hybridization was performed to examine the expression pattern of the calsequestrins in the developing mouse and rat embryos. During early organogenesis, the cardiac and skeletal calsequestrin transcripts were detected exclusively in the heart primordium and the myotome of somites, respectively. The cardiac calsequestrin transcripts were later detected in fetal heart and skeletal muscles, whereas the skeletal calsequestrin transcripts were only found in fetal skeletal muscles. These data suggest that the cardiac calsequestrin plays a role in the differentiation and function of heart, and in the function of fetal skeletal muscles in conjunction with the skeletal calsequestrin, but not in the early differentiation of the myotome of somites. The expression of the skeletal calsequestrin in the myotome is regulated probably by myogenin, a myogenic regulatory gene.

Protons induce calsequestrin conformational changes

Calsequestrin, a high-capacity, intermediate-affinity, calcium-binding protein present in the lumen of sarcoplasmic reticulum, undergoes extensive calcium-induced conformational changes at neutral pH that cause distinct intrinsic fluorescence changes. The results reported in this work indicate that pH has a marked effect on these calcium-induced intrinsic fluorescence changes, as well as on calorimetric changes produced by the addition of Ca(2+) to calsequestrin. The addition of Ca(2+) at neutral pH produced a marked and cooperative increase in calsequestrin intrinsic fluorescence. In contrast, at pH 6.0 calsequestrin's intrinsic fluorescence was not affected by the addition of Ca(2+), and the same intrinsic fluorescence as that measured in millimolar calcium at neutral pH was obtained. The magnitude and the cooperativity of the calcium-induced intrinsic fluorescence changes decreased as either [H+] or [K+] increased. The evolution of heat production, determined by microcalorimetry, observed upon increasing the molar ratio of Ca(2+) to calsequestrin in 0.15 M KCl, decreased markedly as the pH decreased from pH 8.0 to pH 6.0, indicating that pH modifies the total heat content changes produced by Ca(2+). We propose that protons bind to calsequestrin and induce protein conformational changes that are responsible for the observed proton-induced intrinsic fluorescence and calorimetric changes.

Luminal calcium regulates calcium release in triads isolated from frog and rabbit skeletal muscle

Triads isolated from frog and rabbit skeletal muscle were equilibrated with different external [Ca2+], ranging from 0.025 to 10 mM. Vesicular calcium increased with external [Ca2+] as the sum of a linear plus a saturable component; the latter, which vanished after calsequestrin removal, displayed Bmax values of 182 and 132 nmol of calcium/mg of protein, with Kd values of 1.21 and 1.14 mM in frog and rabbit vesicles, respectively. The effect of luminal [Ca2+] on release kinetics in triads from frog and rabbit skeletal muscle was investigated, triggering release with 2 mM ATP, pCa 5, pH 6.8. In triads from frog, release rate constant (k) values increased sixfold after increasing luminal [Ca2+] from 0.025 to 3 mM. In triads from rabbit, k values increased 20-fold when luminal [Ca2+] increased from 0.05 to 0.7 mM. In both preparations, k values remained relatively constant (10-12 s-1) at higher luminal [Ca2+], with a small decrease at 10 mM. Initial release rates increased with luminal [Ca2+] in both preparations; in triads from rabbit the increase was hyperbolic, and in triads from frogs the increase was sigmoidal. These results indicate that, although triads from frog and rabbit respond differently, in both preparations luminal [Ca2+] has a distinctive effect on release, presumably by regulating sarcoplasmic reticulum calcium channels.

Characterization study of the ryanodine receptor and of calsequestrin isoforms of mammalian skeletal muscles in relation to fibre types

We have investigated high-affinity ryanodine-binding sites in membrane preparations from representative fast-twitch and slow-twitch muscles of the rabbit and rat, as well as from human mixed muscle. Our results, obtained in high-ionic strength binding buffer, demonstrate extensive similarities in binding affinity for [3H]ryanodine (Kd: about 10 nM) and a two-fold to four-fold difference in membrane density of the ryanodine receptor between fast-twitch and slow-twitch muscle of the rat and rabbit, respectively. The [3H]ryanodine-pCa relationship for the Ca(2+)-activation curve of ryanodine binding was found to be similar for all mammalian muscles, as tested at 20 nM ryanodine. With 10 mM caffeine or 50 microM doxorubicin the pCa for half-maximal activation of [3H]ryanodine binding invariably shifted from an average pCa value of 6.5 to pCa 7.1-7.3. IC50 values for the inhibition of [3H]ryanodine binding by Ruthenium Red, a Ca(2+)-release channel blocker, did not differ significantly (range 0.3-1.0 microM). The Ca(2+)-dependence curve (range 1 nM-10 mM free Ca2+) that we have observed at 5 nM ryanodine, for [3H]ryanodine binding to terminal cisternae from rabbit fast-twitch, as well as slow-twitch muscle, is bell-shaped and differs from that obtained with cardiac terminal cisternae from the same species. Cardiac ryanodine receptor is also clearly distinguishable for electrophoretic mobility, Cleveland's peptide maps, and, most strikingly, for total lack of cross-reactivity with polyclonal antibody to fast skeletal RyR. By the same properties, the ryanodine receptor of fast- and slow-twitch muscle appear to be the same or a similar protein. On investigating the composition of calsequestrin in rat and human skeletal muscles, both in membrane-bound form and after purification by phenyl-Sepharose chromatography, we have been able to show that, independent of the animal species, the cardiac isoform, as characterized by the identical amino-terminal amino-acid sequence, pattern of immunoreactivity, and lack of Ca(2+)-dependent shift in mobility on SDS-PAGE, is exclusively expressed in slow-twitch fibres, together with the main fast-skeletal calsequestrin isoform. While our experimental findings strongly argue for the presence of only one population of skeletal-specific Ca(2+)-release channels in junctional terminal cisternae of mammalian fast-twitch and slow-twitch muscle, they at the same time suggest the existence of differences in calsequestrin modulation of Ca(2+)-release, depending on its isoform composition.

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.

Molecular cloning, functional expression and tissue distribution of the cDNA encoding frog skeletal muscle calsequestrin

We have cloned, sequenced and expressed the cDNA encoding frog skeletal muscle calsequestrin. The processed frog calsequestrin is 398 residues long, with an Mr of 45941 (unglycosylated form), and exhibits 77% sequence similarity with its rabbit counterpart. Consensus sequences for glycosylation and phosphorylation of the protein were conserved. Compared with rabbit calsequestrin, the mature amphibian protein has peculiar structural properties, which include (i) a higher content of negatively charged residues (142 versus 109), and (ii) a striking repeat sequence at the C-terminal region of 44 aspartic acid residues. Furthermore, this is the first report on the expression of calsequestrin cDNA in COS-1 cells; the expressed protein exhibited an Mr and antigenic properties which were indistinguishable from those of the native protein. In addition, it was capable of binding 45Ca in a ligand overlay. Northern blot analysis of frog skeletal muscle, liver, heart and brain RNA showed that the protein is mainly expressed in skeletal muscle. The high density of negative charges at the C-terminus might constitute high-capacity low-affinity Ca(2+)-binding sites, which may account for the higher Ca(2+)-binding capacity of frog calsequestrin compared with other members of the calsequestrin family (56 mol/mol versus 40-44 mol/mol of protein).

Purification and characterization of calsequestrin from chicken cerebellum

Chicken cerebellum microsomal fractions contain a protein tentatively identified as calsequestrin (CS) (Volpe et al., Neuron 5, 713-721, 1990). Here we report, for the first time, the purification of cerebellum CS from whole tissue homogenate by DEAE-Cellulose chromatography and Ca(2+)-dependent elution from phenyl-Sepharose. The purified cerebellum CS displays the shift and increase in intrinsic fluorescence characteristic of skeletal muscle CS, and is shown to be a high-capacity, low-affinity Ca2+ binding protein (Kd = 1 mM).

Subcellular fractionation to junctional sarcoplasmic reticulum and biochemical characterization of 170 kDa Ca(2+)- and low-density-lipoprotein-binding protein in rabbit skeletal muscle

Skeletal-muscle sarcoplasmic reticulum (SR) comprises two distinct domains, corresponding to the free membrane of longitudinal SR (LSR) and the junctional membrane region of the terminal cisternae (TC), respectively. The junctional membrane contains the ryanodine receptor (RyR)/Ca(2+)-release channel and additional minor protein components that still require biochemical investigation, in relation to excitation-contraction coupling. Recent findings suggested the involvement in this process of a 170 kDa protein [Kim, Caswell, Talvenheimo & Brandt (1990) Biochemistry 29, 9281-9289], also characterized as a phosphoprotein in junctional TC in independent studies [Chu, Submilla, Inesi, Jay & Campbell (1990) Biochemistry 29, 5899-5905]. We show that this protein is a specific substrate of exogenous cyclic AMP-dependent protein kinase, that it is exposed to the outer surface of intact TC vesicles, and that it co-localizes with the RyR to the junctional membrane. Comparative analysis of LSR and TC subfractions for the 160 kDa glycoprotein sarcalumenin, using Western-blot techniques and specific monoclonal antibodies or concanavalin A as a ligand, revealed that the distribution of this protein within the SR corresponds inversely to both that of the RyR and of the 170 kDa protein. The 170 kDa protein, like sarcalumenin, stains blue with the cationic dye Stains-All and binds 45Ca2+ on blots, but it is uniquely distinguished by its ability to bind 125I-labelled low-density lipoprotein. The similarity of these properties, as well as the pI and solubility properties, to those described for the SR protein, recently purified and cloned and named histidine-rich Ca(2+)-binding protein [HCP; Hofmann, Brown, Lee, Pathak, Anderson & Goldstein (1989) J. Biol. Chem. 264, 8260-8270], makes it very likely that our protein and HCP may indeed be identical. The protein described in the present study differs from sarcalumenin because its migration in SDS/PAGE is accelerated in the presence of Ca2+, a previously reported property of other Ca(2+)-binding proteins [leMaire, Lund, Viel, Champeil & Moller (1989) J. Biol. Chem. 265, 1111-1123], arguing for Ca(2+)-induced protein-conformational changes. Kinase-dependent phosphorylation of our protein is another distinguishing feature, which, although not previously reported for HCP, is consistent with the presence of potential serine/threonine phosphorylation sites in the middle portion of the cloned HCP molecule. The finding that HCP, contrary to early views, selectively binds to the cytoplasmic side of the junctional membrane, together with its newly characterized properties, seem to provide new clues as to a possible role in electromechanical coupling and/or Ca2+ release.

Altered properties of calsequestrin and the ryanodine receptor in the cardiac sarcoplasmic reticulum of hibernating mammals

A novel isoform of calsequestrin was identified in sarcoplasmic reticulum vesicles from myocardial tissue of two species of hibernating ground squirrel. The protein was identified as calsequestrin by its cross-reactivity with antibodies raised against bovine cardiac calsequestrin, its pH-sensitive mobility in sodium dodecylsulphate-polyacrylamide gels, staining blue with the cationic carbocyanine dye 'Stains-All', binding peroxidase-conjugated concanavalin A, its endoglycosidase F sensitivity. Its NH2-terminal amino acid sequence is similar, but not identical, to that already determined for cardiac calsequestrin. Some of the biochemical properties of this protein distinguish it from the other mammalian isoforms. It has a unique electrophoretic mobility in both alkaline and neutral sodium dodecylsulphate-polyacrylamide gel electrophoresis, it appears to have a molecular weight approximately 7% greater than that of cardiac calsequestrin from other mammalian species, and its glycosylation pattern differs. This novel form of calsequestrin is expressed in cardiac SR vesicles which possess an abnormally high number of Ca2(+)-release channel/ryanodine receptor molecules. This ryanodine receptor also shows an altered Ca2(+)-sensitivity of ryanodine binding. The divergent biophysical properties of this novel form of cardiac calsequestrin, together with the apparently atypical ryanodine receptors in the cardiac sarcoplasmic reticulum membranes may have some functional significance in the adaptive mechanisms which allow the heart to function despite the severely reduced body temperatures (to approx. 0 degree C) encountered during hibernation.

Frog brain expresses a 60 KDa Ca2+ binding protein similar to mammalian calreticulin

The present report was undertaken in an effort to characterize the nature of Ca2+ binding protein(s) in the central nervous system of less evolved vertebrates. In particular we investigated whether the brain microsomal fraction of Rana esculenta expresses calsequestrin, calreticulin and/or other related Ca2+ binding protein(s). We found that a 60 KDa protein having an NH2-terminal amino acid sequence similar to mammalian calreticulin is the major microsomal Ca2(+)-binding protein.

Antibodies as probes for ligand gating of single sarcoplasmic reticulum Ca2(+)-release channels

A large (565 kDa) junctional sarcoplasmic reticulum (SR) protein, the ryanodine receptor (RYR), may play both a structural and a functional role in the mechanism of skeletal muscle excitation-contraction coupling. Recently, the primary amino acid sequence of the RYR has been elucidated. In this paper, we introduce an immunological approach to examine the functional (electrophysiological) properties of the RYR when it is incorporated into planar lipid bilayers. The effects of two polyclonal antibodies against the SR junctional face membrane (JFM) and the RYR (anti-JFM and anti-RYR) were tested on the single-channel gating properties of the RYR SR Ca2(+)-release channel. Junctional SR vesicles were fused into planar lipid bilayers in solutions containing caesium salts. Solutions were designed to minimize the background conductances of the SR K+ and Cl- channels. Three actions of the anti-JFM antibody were distinguished on the basis of single-channel gating and conductance. The anti-RYR antibody had a single action, a simultaneous decrease in single-channel open probability (Po) and conductance. Both antibodies appear to alter single-channel gating by disrupting the Ca2(+)-activation mechanism of the channel. Anti-RYR-antibody-induced gating abnormalities were reversed by ATP, although the ATP-re-activated channels had altered gating kinetics. Two antigenic regions, recognizing the anti-RYR antibody, in the C-terminal end of the RYR primary amino acid sequence contain or are closely associated with putative ligand (Ca2+ and ATP)-binding sites identified previously. Our results demonstrate (1) that the antibodies induced abnormal gating (decreased open probability and stabilization of subconducting states) of SR release channels, and (2) that abnormal gating is not associated with physical obstruction or alteration of the conduction pathway. Thus antibodies directed at specific regions of the RYR (e.g. putative ligand-binding sites) can be used as effective probes with which to study the structural and functional properties of the SR Ca2(+)-release channel gating at the single-channel level.

Purification and characterization of a calsequestrin-like calcium-binding protein from carp (Cyprinus carpio) sarcoplasmic reticulum

1. A calsequestrin-like calcium-binding protein was purified from carp sarcoplasmic reticulum by column chromatographies using DEAE-cellulose and Butyl-Toyopearl 650S. 2. The mol. wt was estimated to be 50 kDa, which was larger than that of rabbit calsequestrin (42 kDa). 3. Carp calsequestrin-like protein bound Ca2+ with a higher affinity (apparent Kd = 400 microM) and lower capacity (25 mol/mol) compared with rabbit calsequestrin (1 mM and 40-50 mol/mol, respectively). 4. Anti-carp calsequestrin-like protein rabbit antiserum reacted with rabbit calsequestrin in immunoblotting analysis. 5. Carp calsequestrin-like protein was rich in acidic amino acids, as was rabbit calsequestrin.

Coexpression of two isoforms of calsequestrin in rabbit slow-twitch muscle

The cardiac and fast-twitch skeletal muscle forms of the Ca2(+)-binding protein calsequestrin (CS) are the products of two different genes, both of which are transcribed in slow-twitch skeletal muscle, though at much different rates (Scott et al., 1988., Fliegel et al., 1989). We have investigated this problem more closely at the protein level, on isolated terminal cisternae (TC) of the sarcoplasmic reticulum (SR) of rabbit slow-twitch muscle, and following purification of two distinct forms of CS from whole tissue by DEAE-Cellulose chromatography and CA2(+)-dependent elution from phenyl-Sepharose. Two electrophoretically (apparent molecular mass of 64 kDa and 54 kDa, respectively), and antigenically distinct forms of CS, here shown to be related to the fast-twitch skeletal muscle and to cardiac-type isoform of CS, respectively, colocalize to junctional TC of slow-twitch muscle. The cardiac-type isoform that is expressed in slow-twitch muscle accounts for about 25% of total CS present in isolated TC, it binds Ca2+ as effectively as the major CS form, using a 45Ca-overlay technique, and it shares extensive similarities with dog cardiac CS, not only in size and antigenically, but also in pl, as well as in the DEAE-elution characteristics. No difference in behaviour with phenyl-Sepharose resin were observed between the two CS isoforms from slow-twitch muscle.(ABSTRACT TRUNCATED AT 250 WORDS)

Amino acid sequence of chicken calsequestrin deduced from cDNA: comparison of calsequestrin and aspartactin

We have previously reported the amino terminal sequence of adult chicken calsequestrin, an intraluminal Ca2(+)-binding protein isolated from fast-twitch skeletal muscle. The partial sequence showed homology with mammalian calsequestrins contained in the PIR data bank and complete identity with the amino terminus of a putative laminin-binding protein of the extracellular matrix, aspartactin. Based on these data, oligonucleotide primers were synthesized for PCR amplification and direct DNA sequencing. We report herein the primary sequence of chicken calsequestrin, deduced from cDNA. The sequence has been verified by amino acid sequencing of internal tryptic peptides. Importantly, the data show the primary structure of calsequestrin to be identical to the amino acid sequence reported for aspartactin, with the exception of a single amino acid difference (ileu vs. val) which may be animal strain-related. Based on these data, calsequestrin and aspartactin are the same protein.

Characterization of calsequestrin of avian skeletal muscle

A calsequentrin (CS)-like glycoprotein is present in the sarcoplasmic reticulum (SR) of chicken pectoralis muscle, which displays unusual properties: it binds relatively low amounts of Ca2+, compared to CS in mammalian skeletal muscle (Yap & MacLennan, 1976), it does not exhibit a marked pH-dependent shift in mobility in sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE), and its metachromatic staining properties with Stains All are likewise peculiar (Damiani et al., 1986). We have now definitively localized the same protein to the junctional terminal cisternae (TC) fraction of the SR of chicken pectoralis muscle and have further characterized it, following purification by crystallization with Ca2+ and by Ca2(+)-dependent elution from phenyl-Sepharose columns. The purified protein (apparent Mr: 51 kDa), isoelectrofocuses at pH 4.5, and is readily identified on blots by a 45Ca overlay technique, similar to CS of rabbit skeletal muscle, but it binds half as much Ca2+ (about 20 moles of Ca2+ per mole of protein), as estimated by equilibrium dialysis. However, the chicken protein shares extensive similarities with mammalian CSs, concerning Ca2(+)-induced changes in maximum intrinsic fluorescence and the Ca2(+)-modulated interaction with phenyl-Sepharose, as well as in being protected by Ca2+ from proteolysis by either trypsin or chymotrypsin. We discuss how the presence of a Ca2(+)-regulated hydrophobic site in the CS molecule appears to be the most invariant property of the CS-family of Ca2(+)-binding proteins.

Calsequestrin, an intracellular calcium-binding protein of skeletal muscle sarcoplasmic reticulum, is homologous to aspartactin, a putative laminin-binding protein of the extracellular matrix

Calsequestrin was isolated from chicken fast-twitch skeletal muscle, and partial amino terminal sequence was determined. The sequence (NH2) EEGLNFPTYDGKDRVIDLNE shows high identity with known mammalian calsequestrins contained in the Protein Identification Resource data bank (1). Most importantly, this 20 amino acid sequence shares complete identity with the amino terminus of aspartactin, a putative laminin-binding protein of the extracellular matrix (2, 3). The possible relationship of aspartactin to calsequestrin is discussed.

Sarcoplasmic reticulum of human skeletal muscle: age-related changes and effect of training

The effect of ageing on human skeletal muscle was investigated using needle biopsies from young and aged subjects and from aged subjects trained with different activity patterns. Histochemical staining for myofibrillar ATPase of ageing m. vastus lateralis demonstrated an unchanged fibre type distribution but a selective atrophy of type IIa and type IIb fibres. Analysis of myosin heavy chain (MHC) composition showed that type I MHC increased with ageing (P less than 0.05). The relative content of the MHC isoforms correlated with the relative area of the respective fibre types. Sarcoplasmic reticulum (SR) proteins were investigated in muscle extracts by electrophoretic and immunoblotting techniques. When compared to a young control group (28 +/- 0.1 years old, n = 7) blots of post-myofibrillar supernatant proteins probed with polyclonal antibodies to the rabbit fast SR Ca-ATPase, a marker of extrajunctional SR, showed that the content of Ca-ATPase was significantly lower (P less than 0.05) in the old control group (68 +/- 0.5 years old, n = 8). On the other hand the content of calsequestrin (CS), the major intraluminal protein of SR terminal cisternae (TC), and of the 350-kDa ryanodine-binding protein, which is localized in the junctional regions of TC, did not show a concomitant decrease. These results suggest that ageing differentially affects extrajunctional and junctional SR of human skeletal muscle. These age-related changes were not observed within a group of old strength-trained subjects.

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.

Biochemical characteristics of free and junctional sarcoplasmic reticulum and of transverse tubules in human skeletal muscle

The microsomal fraction of normal human skeletal muscle was subfractionated by isopycnic sucrose-density centrifugation, using the procedure originally described by Saito et al. for rabbit fast muscle, and specific markers of the junctional face membrane of terminal cisternae (TC) (ryanodine receptor, high-molecular-weight feet proteins and membrane-associated calcium-binding protein calsequestrin), of the sarcoplasmic reticulum (SR) Ca-pump membrane (chicken antibody to rabbit Ca-ATPase), and of transverse tubules (TT) (dihydropiridine receptor, membrane cholesterol), respectively. The results show that isolated TC from human skeletal muscle share extensive morphological characteristics, protein composition, as well as Ca-release properties with rabbit TC, as tested with an inhibitor (Ruthenium red) and an activator (doxorubicin) of SR Ca-release. The Ca-pump membrane of human muscle SR, in distinction to rabbit fast muscle SR, showed a relatively low specific activity of the Ca-ATPase, as expected from the mixed fiber composition of human muscles, but shared the presence of minor protein components, such as a Con A binding protein of about 57 kDa and blue-staining peptides in the 170-120 kDa range of molecular weights. Human muscle TT, as isolated from the same sucrose gradient, demonstrated a high affinity (3H)-dihydropiridine binding activity in the range of previously reported values for purified TT from rabbit skeletal muscle.

Denervation-induced proliferative changes of triads in rabbit skeletal muscle

Protein compositional and functional differences exist between longitudinal and junctional sarcoplasmic reticulum (SR) in relation to Ca transport and to Ca release. In light of this knowledge, we have reinvestigated the effects of denervation on SR of rabbit gastrocnemius, a predominantly fast muscle. Electron microscopy of 2-weeks denervated muscle showed proliferation of transverse tubules (TT), forming junctional contacts with SR terminal cisternae (TC). At coincident periods, the yield of muscle microsomes was increased, and their fractionation by sucrose-density centrifugation demonstrated a relative increase of heavy vesicles. Thin-section electron microscopy of heavy SR from denervated muscle showed an increased number of vesicles containing calsequestrin (CS) as compared with control muscle. Electrophoretic analysis confirmed the relative decrease of Ca-ATPase protein and the striking increase of CS both in total microsomes and in heavy SR vesicles. Calcium loading and Ca-ATPase activity as well as the density of Ca-ATPase protein were decreased to a similar extent (20-30%) in denervated muscle microsomes. Stimulation of Ca-ATPase activity by Ca-ionophore A23187 showed that the vesicles were tightly sealed. When probed by competitive ELISA with antibody to SR Ca-ATPase from pure fast muscle, the Ca-ATPase of denervated microsomes was found to be highly cross reactive. Cleveland's peptide maps of the Ca-ATPase protein after partial digestion with S. aureus V8 protease also showed no significant change after denervation. Changes in cholesterol content and in the ratio of Mg-ATPase to Ca-ATPase activity of denervated muscle microsomes indicated a 4-fold increase of TT protein, i.e., from about 3% to not more than 12% of total protein, at 2 weeks after denervation. All these changes were totally reversed upon reinnervation of muscle fibers, and the consequent muscle recovery, as obtained by nerve crushing instead of nerve sectioning. From these results, we conclude that denervated adult fast muscle, similarly to immature fast muscle, contains more junctional SR. However, the molecular and catalytic properties of the Ca-ATPase are unaffected by denervation.

Properties of a 19-kDa Zn2+-binding protein and sequence of the Zn2+-binding domains

A novel 19-kDa protein has been described recently [Brand, I.A. and Söling, H.-D. (1986) J. Biol. Chem. 261, 5895-5900] which is able to inactivate 6-phosphofructo-1-kinase reversibly in a Zn2+-dependent manner. We present now additional biochemical and physicochemical data concerning this protein. It is extremely acidic with 40% glutamic and 15% aspartic acid residues. It contains no sulfur, aromatic amino acids, histidine or isoleucine. The protein has four binding sites for Zn2+ with an apparent Kd of about 6 microM. Two of these binding sites are called unspecific as Zn2+ is displaced from these binding sites at physiological concentrations of free Mg2+ (0.75 mM) and at high salt concentrations (100 mM NaCl). Whereas Mg2+-binding to the two other so-called specific Zn2+-binding sites occurs only at Mg2+ concentrations at about 5 mM. The four Zn2+-binding sites were detected on a tryptic peptide (T8) of 43 amino acid residues, which still possessed biological activity. This peptide has been sequenced and is characterized by four clusters of acidic amino acids separated by only a few neutral amino acids. The two specific Zn2+-binding sites could be detected in the C-terminal portion of T8, the two unspecific Zn2+-binding sites must therefore be located at the N-terminal portion. The Zn2+-binding domains of the 19-kDa Zn2+-binding protein described here are completely different from those of the 'zinc finger' discovered in several DNA-binding proteins.

Calcium binding protein changes of sarcoplasmic reticulum from rat denervated skeletal muscle

Two Ca2+ sequestering proteins were studied in fast-twitch (EDL) and slow-twitch (soleus) muscle sarcoplasmic reticulum (SR) as a function of denervation time. Ca2+-ATPase activity measured in SR fractions of normal soleus represented 5% of that measure in SR fractions of normal EDL. Denervation caused a severe decrease in activity only in fast-twitch muscle. Ca2+-ATPase and calsequestrin contents were affected differently by denervation. In EDL SR, Ca2+-ATPase content decreased progressively, whereas in soleus SR, no variation was observed. Calsequestrin showed a slight increase in both muscles as a function of denervation time correlated with increased 45Ca-binding. These results indicate first that Ca2+-ATPase activity in EDL was under neural control, and that because of low Ca2+-ATPase activity and content in slow-twitch muscle no variation could be detected, and secondly that greater calsequestrin content might represent a relative increasing of heavy vesicles or decreasing of light vesicles as a function of denervation time in the whole SR fraction isolated in both types of muscles.

Distribution of sarcoplasmic reticulum Ca-ATPase and of calsequestrin at the polar regions of rat, rabbit and cat intrafusal fibers

Sarcoplasmic reticulum (SR) Ca2+-pumping ATPase (Ca-ATPase) and calsequestrin (CaS) were visualized by indirect immunofluorescence at the polar regions of adult rat, rabbit and cat intrafusal fibers. The immunohistochemical reaction products were regarded as histochemical markers of the SR and as valid indicators of the distribution of the two Ca2+-sequestering proteins. Static nuclear bag2 fibers displayed lower levels of both Ca-ATPase and CaS than the other two intrafusal fiber types. Nuclear chain fibers presented the highest Ca-ATPase levels and, together with dynamic nuclear bag1 fibers, they also exhibited relatively high amounts of CaS. The level of Ca-ATPase was lower in bag 1 fibers than in nuclear chain fibers, but not as low as in bag2 fibers. The comparatively high levels of Ca-ATPase and CaS seen in nuclear chain fibers coincided with their reported faster contractile speeds compared to nuclear bag fibers.