A missense mutation in a highly conserved region of CASQ2 is associated with autosomal recessive catecholamine-induced polymorphic ventricular tachycardia in Bedouin families from Israel

Catecholamine-induced polymorphic ventricular tachycardia (PVT) is characterized by episodes of syncope, seizures, or sudden death, in response to physical activity or emotional stress. Two modes of inheritance have been described: autosomal dominant and autosomal recessive. Mutations in the ryanodine receptor 2 gene (RYR2), which encodes a cardiac sarcoplasmic reticulum (SR) Ca(2+)-release channel, were recently shown to cause the autosomal dominant form of the disease. In the present report, we describe a missense mutation in a highly conserved region of the calsequestrin 2 gene (CASQ2) as the potential cause of the autosomal recessive form. The CASQ2 protein serves as the major Ca(2+) reservoir within the SR of cardiac myocytes and is part of a protein complex that contains the ryanodine receptor. The mutation, which is in full segregation in seven Bedouin families affected by the disorder, converts a negatively charged aspartic acid into a positively charged histidine, in a highly negatively charged domain, and is likely to exert its deleterious effect by disrupting Ca(2+) binding.

Calsequestrin binds to monomeric and complexed forms of key calcium-handling proteins in native sarcoplasmic reticulum membranes from rabbit skeletal muscle

Ca(2+)-handling proteins are important regulators of the excitation-contraction-relaxation cycle in skeletal muscle fibres. Although domain binding studies suggest protein coupling between various Ca(2+)-regulatory elements of triad junctions, no direct biochemical evidence exists demonstrating high-molecular-mass complex formation in native microsomal membranes. Calsequestrin represents the protein backbone of the luminal Ca(2+) reservoir and thereby occupies a central position in Ca(2+) homeostasis; we therefore used calsequestrin blot overlay assays in order to determine complex formation between sarcoplasmic reticulum components. Peroxidase-conjugated calsequestrin clearly labelled four major protein bands in one-dimensional (1D) and 2D electrophoretically separated membrane preparations from adult skeletal muscle. Immunoblotting identified the calsequestrin-binding proteins of approximately 26, 63, 94 and 560 kDa as junctin, calsequestrin itself, triadin and the ryanodine receptor, respectively. Protein-protein coupling could be modified by ionic detergents, non-ionic detergents, changes in Ca(2+) concentration, as well as antibody and purified calsequestrin binding. Importantly, complex formation as determined by blot overlay assays was confirmed by differential co-immunoprecipitation experiments and chemical crosslinking analysis. Hence, the key Ca(2+)-regulatory membrane components of skeletal muscle form a supramolecular membrane assembly. The formation of this tightly associated junctional sarcoplasmic reticulum complex seems to underlie the physiological regulation of skeletal muscle contraction and relaxation, which supports the biochemical concept that Ca(2+) homeostasis is regulated by direct protein-protein interactions.

Head-to-tail oligomerization of calsequestrin: a novel mechanism for heterogeneous distribution of endoplasmic reticulum luminal proteins

Many proteins retained within the endo/sarcoplasmic reticulum (ER/SR) lumen express the COOH-terminal tetrapeptide KDEL, by which they continuously recycle from the Golgi complex; however, others do not express the KDEL retrieval signal. Among the latter is calsequestrin (CSQ), the major Ca2+-binding protein condensed within both the terminal cisternae of striated muscle SR and the ER vacuolar domains of some neurons and smooth muscles. To reveal the mechanisms of condensation and establish whether it also accounts for ER/SR retention of CSQ, we generated a variety of constructs: chimeras with another similar protein, calreticulin (CRT); mutants truncated of COOH- or NH2-terminal domains; and other mutants deleted or point mutated at strategic sites. By transfection in L6 myoblasts and HeLa cells we show here that CSQ condensation in ER-derived vacuoles requires two amino acid sequences, one at the NH2 terminus, the other near the COOH terminus. Experiments with a green fluorescent protein GFP/CSQ chimera demonstrate that the CSQ-rich vacuoles are long-lived organelles, unaffected by Ca2+ depletion, whose almost complete lack of movement may depend on a direct interaction with the ER. CSQ retention within the ER can be dissociated from condensation, the first identified process by which ER luminal proteins assume a heterogeneous distribution. A model is proposed to explain this new process, that might also be valid for other luminal proteins.

Native skeletal muscle dihydropyridine receptor exists as a supramolecular triad complex

One of the central elements of excitation-contraction coupling, the voltage-sensing dihydropyridine receptor, is believed to exist as a high-molecular-mass complex in the triad junction. Although freeze-fracture electron microscopical analysis suggests a tetrad complex, no direct biochemical evidence exists demonstrating the actual size of the native membrane complex. Using a combination of various two-dimensional gel electrophoresis techniques, we show here that the principal alpha1-subunit of the dihydropyridine receptor and its auxiliary alpha2-subunit form a triad complex of approximately 2800 kDa under native conditions. Established Ca2+-ATPase tetramers and calsequestrin monomers were employed for the internal standardization of the gel systems used. Thus, the large voltage-sensing complex appears to be tightly associated, since it does not disintegrate during subcellular fractionation and native electrophoresis procedures. Our findings support the cell biological hypothesis that native dihydropyridine receptor units form a tetrad structure within the transverse tubules.

The asp-rich region at the carboxyl-terminus of calsequestrin binds to Ca(2+) and interacts with triadin

Calsequestrin (CSQ) is a high capacity Ca(2+) binding protein in the junctional sarcoplasmic reticulum of striated muscles, and has been shown to regulate the ryanodine receptor (RyR) through triadin and junctin. In order to identify the functional roles of specific regions on CSQ, several CSQ deletion mutants were prepared by molecular cloning and Escherichia coli expression. 45Ca(2+) overlay assay using a native gel system revealed that the major Ca(2+) binding motif of CSQ resides in the asp-rich region (amino acids 354-367). In an in vitro binding assay using a glutathione-S-transferase affinity column, the interaction between CSQ and triadin was found to be Ca(2+)-dependent, and the site of interaction was confined to the asp-rich region of CSQ. Our results suggest that the asp-rich region of CSQ could participate in the RyR-mediated Ca(2+) release process by offering a direct binding site to luminal Ca(2+) as well as triadin.

Calsequestrin, a calcium sequestering protein localized at the sarcoplasmic reticulum, is not essential for body-wall muscle function in Caenorhabditis elegans

Calsequestrin is the major calcium-binding protein of cardiac and skeletal muscles whose function is to sequester Ca(2+)in the lumen of the sarcoplasmic reticulum (SR). Here we describe the identification and functional characterization of a C. elegans calsequestrin gene (csq-1). CSQ-1 shows moderate similarity (50% similarity, 30% identity) to rabbit skeletal calsequestrin. Unlike mammals, which have two different genes encoding cardiac and fast-twitch skeletal muscle isoforms, csq-1 is the only calsequestrin gene in the C. elegans genome. We show that csq-1 is highly expressed in the body-wall muscles, beginning in mid-embryogenesis and maintained through the adult stage. In body-wall muscle cells, CSQ-1 is localized to sarcoplasmic membranes surrounding sarcomeric structures, in the regions where ryanodine receptors (UNC-68) are located. Mutation in UNC-68 affects CSQ-1 localization, suggesting that the two possibly interact in vivo. Genetic analyses of chromosomal deficiency mutants deleting csq-1 show that CSQ-1 is not essential for initiation of embryonic muscle formation and contraction. Furthermore, double-stranded RNA injection resulted in animals completely lacking CSQ-1 in body-wall muscles with no observable defects in locomotion. These findings suggest that although CSQ-1 is one of the major calcium-binding proteins in the body-wall muscles of C. elegans, it is not essential for body-wall muscle formation and contraction.

Localization and characterization of the calsequestrin-binding domain of triadin 1. Evidence for a charged beta-strand in mediating the protein-protein interaction

Triadin is an integral membrane protein of the junctional sarcoplasmic reticulum that binds to the high capacity Ca(2+)-binding protein calsequestrin and anchors it to the ryanodine receptor. The lumenal domain of triadin contains multiple repeats of alternating lysine and glutamic acid residues, which have been defined as KEKE motifs and have been proposed to promote protein associations. Here we identified the specific residues of triadin responsible for binding to calsequestrin by mutational analysis of triadin 1, the major cardiac isoform. A series of deletional fusion proteins of triadin 1 was generated, and by using metabolically labeled calsequestrin in filter-overlay assays, the calsequestrin-binding domain of triadin 1 was localized to a single KEKE motif comprised of 25 amino acids. Alanine mutagenesis within this motif demonstrated that the critical amino acids of triadin binding to calsequestrin are the even-numbered residues Lys(210), Lys(212), Glu(214), Lys(216), Gly(218), Gln(220), Lys(222), and Lys(224). Replacement of the odd-numbered residues within this motif by alanine had no effect on calsequestrin binding to triadin. The results suggest a model in which residues 210-224 of triadin form a beta-strand, with the even-numbered residues in the strand interacting with charged residues of calsequestrin, stabilizing a "polar zipper" that links the two proteins together. This small, highly charged beta-strand of triadin may tether calsequestrin to the junctional face membrane, allowing calsequestrin to sequester Ca(2+) in the vicinity of the ryanodine receptor during Ca(2+) uptake and Ca(2+) release.

Surface plasmon resonance studies prove the interaction of skeletal muscle sarcoplasmic reticular Ca(2+) release channel/ryanodine receptor with calsequestrin

A high affinity molecular interaction is demonstrated between calsequestrin and the sarcoplasmic reticular Ca(2+) release channel/ryanodine receptor (RyR) by surface plasmon resonance. K(D) values of 92 nM and 102 nM for the phosphorylated and dephosphorylated calsequestrin have been determined, respectively. Phosphorylation of calsequestrin seems not to influence this high affinity interaction, i.e. calsequestrin might always be bound to RyR. However, the phosphorylation state of calsequestrin determines the amount of Ca(2+) released from the lumen. Dephosphorylation of approximately 1% of the phosphorylated calsequestrin could be enough to activate the RyR channel half-maximally, as we have shown previously [Szegedi et al., Biochem. J. 337 (1999) 19].

Targeting of calsequestrin to sarcoplasmic reticulum after deletions of its acidic carboxy terminus

Calsequestrin (CS) is the Ca(2+) binding protein of the junctional sarcoplasmic reticulum (jSR) lumen. Recently, a chimeric CS-HA1, obtained by adding the nine-amino-acid viral epitope hemagglutinin (HA1) to the COOH terminus of CS, was shown to be correctly segregated to the sarcoplasmic reticulum [A. Nori, K. A. Nadalini, A. Martini, R. Rizzuto, A. Villa, and P. Volpe. Am. J. Physiol. 272 (Cell Physiol. 41): C1420-C1428, 1997]. A putative targeting mechanism of CS to jSR implies electrostatic interactions between negative charges on CS and positive charges on intraluminal domains of jSR integral proteins, such as triadin and junctin. To test this hypothesis, 2 deletion mutants of chimeric CS were engineered: CS-HA1DeltaGlu-Asp, in which the 14 acidic residues [-Glu-(Asp)(5)-Glu-(Asp)(7)-] of the COOH-terminal tail were removed, and CS-HA1Delta49(COOH), in which the last, mostly acidic, 49 residues of the COOH terminus were removed. Both mutant cDNAs were transiently transfected in HeLa cells, myoblasts of rat skeletal muscle primary cultures, or regenerating soleus muscle fibers of adult rats. The expression and intracellular localization of CS-HA1 mutants were studied by epifluorescence microscopy with use of antibodies against CS or HA1. CS-HA1 mutants were shown to be expressed, sorted, and correctly segregated to jSR. Thus short or long deletions of the COOH-terminal acidic tail do not influence the targeting mechanism of CS.

Complex formation of skeletal muscle Ca2+-regulatory membrane proteins by halothane

In skeletal muscle, halothane affects the functions of several Ca2+-regulatory membrane proteins involved in the excitation-contraction-relaxation cycle. To investigate the mechanism by which this volatile anesthetic interferes with Ca2+-homeostasis, we studied potential changes in protein-protein interactions by halothane. Using comparative immunoblotting of microsomal muscle proteins separated on native and denaturing gels, we show here that halothane induces oligomerization of the terminal cisternae Ca2+-binding protein calsequestrin, the junctional ryanodine receptor Ca2+-release channel and the transverse-tubular alpha1-dihydropyridine receptor. This agrees with previous reports on the modulation of Ca2+-release activity by halothane since interactions between the voltage-sensing alpha1-dihydropyridine receptor, the ryanodine receptor and the luminal Ca2+-reservoir might result in a rapid release of Ca2+-ions. Furthermore, this study supports the idea that specific protein sites are involved in the action of inhalational anesthetics and that halothane might trigger abnormal Ca2+-homeostasis in malignant hyperthermia via oligomerization of the mutated ryanodine receptor.

Influence of various nucleotides on the in situ crystallization of Ca2+-ATPase

A reproducible in situ crystallization of the Ca2+-ATPase in isolated sarcoplasmic reticulum (SR) membranes was studied. The addition of various nucleotides to the washing buffer allowed the formation of tubular crystals, which is induced by vanadate. SR membranes washed with nucleotide-free buffer could not form tubular crystals upon subsequent incubation with vanadate.

Crystal structure of calsequestrin from rabbit skeletal muscle sarcoplasmic reticulum

Calsequestrin, the major Ca2+ storage protein of muscle, coordinately binds and releases 40-50 Ca2+ ions per molecule for each contraction-relaxation cycle by an uncertain mechanism. We have determined the structure of rabbit skeletal muscle calsequestrin. Three very negative thioredoxin-like domains surround a hydrophilic center. Each monomer makes two extensive dimerization contacts, both of which involve the approach of many negative groups. This structure suggests a mechanism by which calsequestrin may achieve high capacity Ca2+ binding. The suggested mechanism involves Ca2+-induced collapse of the three domains and polymerization of calsequestrin monomers arising from three factors: N-terminal arm exchange, helix-helix contacts and Ca2+ cross bridges. This proposed structure-based mechanism accounts for the observed coupling of high capacity Ca2+ binding with protein precipitation.

Oligomerization is an intrinsic property of calsequestrin in normal and transformed skeletal muscle

In skeletal muscle fibers, the high-capacity medium-affinity Ca(2+)-binding protein calsequestrin functions as the major Ca(2+)-reservoir of the sarcoplasmic reticulum. To determine the oligomeric status of calsequestrin, immunoblotting of microsomal proteins following chemical crosslinking was performed. Diagonal non-reducing/reducing two-dimensional gel electrophoresis was employed to unequivocally differentiate between cross-linked species of 63 kDa calsequestrin and calsequestrin-like proteins of higher relative molecular mass. Since chronic low-frequency stimulation has a profound effect on the expression of many muscle-specific protein isoforms, we investigated normal and conditioned muscle fibers. Calsequestrin was found to exist in a wide range of high-molecular-mass clusters in normal and chronically stimulated skeletal muscle fibers. Hence, oligomerization is an intrinsic property of this important Ca(2+)-binding protein and does not appear to be influenced by the fast-to-slow transformation process. Although fiber-type specific differences exist in the physiology of the skeletal muscle Ca(2+)-regulatory system, oligomerization of calsequestrin seems to be essential for proper functioning.

Overexpression of calsequestrin in L6 myoblasts: formation of endoplasmic reticulum subdomains and their evolution into discrete vacuoles where aggregates of the protein are specifically accumulated

Calsequestrin (CSQ), the major low-affinity Ca(2+)-binding glycoprotein of striated muscle fibers, is concentrated to yield aggregates that occupy the lumen of the terminal cisternae of the sarcoplasmic reticulum (SR). When infected or transfected into L6 myoblast, the protein is also concentrated, however, in dense vacuoles apparently separate from the endoplasmic reticulum (ER). CSQ-rich cells appear otherwise normal; in particular, neither other proteins involved in Ca2+ homeostasis nor ER chaperones are increased. The CSQ dense vacuoles are shown herein to be specialized ER subdomains as demonstrated by 1) the endoglycosidase H sensitivity of their CSQ and 2) two markers, calreticulin and calnexin (but not others, protein disulfide isomerase and BiP), intermixed with the vacuole content. Their formation is shown to start with the aggregation of CSQ at discrete sites of the ER lumen. When cells were transfected with both CSQ and calreticulin, only the first gave rise to vacuoles; the second remained diffusely distributed within the ER lumen. The possibility that CSQ aggregation is an artifact of overexpression appears unlikely because 1) within dense vacuoles CSQ molecules are not disulfide cross-linked, 2) their turnover is relatively slow (t = 12 h), and 3) segregated CSQ is bound to large amounts of Ca2+. Transfection of a tagged CSQ into cells already overexpressing the protein revealed the continuous import of the newly synthesized protein into preassembled vacuoles. The tendency to aggregation appears, therefore, as a property contributing to the segregation of CSQ within the ER lumen and to its accumulation within specialized subdomains. The study of L6 cells expressing CSQ-rich vacuoles might thus ultimately help to unravel mechanisms by which the complexity of the sarcoplasmic reticulum is established in muscle fibers.

Luminal pH regulated calcium release kinetics in sarcoplasmic reticulum vesicles

Calcium binding to triads isolated from rabbit skeletal muscle followed a single hyperbolic function in the pH range 5.5-8.0. Maximal binding was obtained at pH 8.0; decreasing the pH decreased the binding capacity and, at pH < or = 6.0, increased Kd 2-fold. These results indicate that lowering the pH diminished calcium binding to calsequestrin, since this protein is the primary source of calcium binding sites in triads. Luminal pH had a marked effect on calcium release induced by 2 mM ATP, at pCa 5.0, pH 6.8. At a constant luminal [Ca2+] of 0.1 mM, release rate constants (k) and initial rates of release increased steadily as a function of decreasing luminal pH; at luminal pH 7.5, values of k < 0.4 s-1 were found, whereas at pH 5.5 values of k approximately 10 S-1 were obtained. Increasing luminal [Ca2+] from 0.05 mM to 0.7 mM had no effect on the k values measured at luminal pH 5.5. In contrast, at pH 6.8, increasing luminal [Ca2+] produced a marked increase in k values, that reached maximal values of k approximately 10 S-1 at 0.7 mM luminal [Ca2+]. Control experiments using fluorescent pH indicators showed that luminal pH did not change significantly during calcium release. It is proposed that luminal protons or calcium induces conformational changes in calsequestrin that in turn promote activation of the calcium release channels.

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.

Zn2+ binding to cardiac calsequestrin

Zn2+ binding to canine cardiac calsequestrin was investigated using the Zn2+ specific fluorescence dye salicylcarbohydrazone (SACH), 65Zn2+ overlay and Zn(2+)-IDA chromatography. Cardiac calsequestrin binds approximately 200 moles of Zn2+/mole of protein with the Kd = 300 microM. Zn2+ binding to calsequestrin was further confirmed by 65Zn2+ overlay and Zn(2+)-dependent aggregation of the protein. However, calsequestrin did not bind to a Zn(2+)-IDA-agarose column, indicating that histidine residues may not be involved in Zn2+ binding to the protein. Circular dichroism revealed only minor Zn(2+)-dependent conformational changes in calsequestrin. We conclude that calsequestrin is a Ca(2+)- and Zn(2+)-binding protein and that Zn2+ may modulate the structure and function of the protein.

Molecular cloning of human calmitine, a mitochondrial calcium binding protein, reveals identity with calsequestrine

The cDNA of a mitochondrial calcium binding protein, "calmitine", has been cloned from a human skeletal muscle cDNA library. One cDNA of 1.8 kb has been isolated and sequenced. It encodes for a protein of 390 amino acid residues of 41,746 KDa and contains a leading peptide of 28 amino acids. The sequencing showed the possibility for 21 phosphorylation sites, 4 myristylation sites, and one N glycosylation site. Sequence comparison with other proteins revealed the identity of calmitine with calsequestrine, the sarcoplasmic reticulum low affinity, but high Ca2+ binding capacity, protein isolated in 1971. Subcellular fractionation showed a marked increase in these Ca2+ binding proteins in mitochondria as compared with the sarcoplasmic reticulum; furthermore the mitochondrial matrix is highly enriched with that protein. Therefore, our data either suggest a bicompartimentation of calmitine or indicate that the localization of calsequestrine should be reconsidered in the light of our data. Calmitine represents the Ca2+ reservoir of mitochondria, the function of which could be similar to what has been reported for calsequestrine in the sarcoplasmic reticulum.

Calsequestrin is a component of smooth muscles: the skeletal- and cardiac-muscle isoforms are both present, although in highly variable amounts and ratios

Expression by smooth-muscle cells of calsequestrin (CS), the low-affinity/high-capacity Ca(2+)-binding protein of striated-muscle sarcoplasmic reticulum (SR), has been investigated in recent years with conflicting results. Here we report the purification and characterization from rat vas deferens of two CS isoforms, the first deemed skeletal muscle, the second cardiac type, on account of their N-terminal amino acids and other relevant biochemical and molecular properties. Compared with vas deferens, the smooth muscles from aorta and stomach, in that order, were found to express lower amounts of CS, whereas in the uterus and bladder the protein was not detectable. The ratio between the two CS isoforms was also variable, with the stomach and aorta predominantly expressing the skeletal-muscle type and the vas deferens expressing the two CSs in roughly similar amount. Because of the property of CSs to localize within the skeletal-muscle SR lumen not uniformly, but according to the distribution of their anchorage membrane proteins, the expression of the protein suggests the existence in smooth-muscle cells of discrete endoplasmic-reticulum areas specialized in the rapidly exchanging Ca2+ storage and release, and thus in the control of a variety of functions, including smooth-muscle contraction.

Crystallization of canine cardiac calsequestrin

Calsequestrin is the major Ca2+ binding protein in the lumen of the sarcoplasmic reticulum membranes. Two X-ray quality crystal forms of canine cardiac calsequestrin were obtained by the hanging drop method using KCl as a precipitant. One form is monoclinic (space group P2(1), a = 73.4 A, b = 104.4 A, c = 60.2 A, beta = 120.4 degrees) with two molecules in the asymmetric unit and a solvent content of approximately 40%. The second form is trigonal (P3(1)21 or P3(2)21, a = b = 99.3 A, c = 89.8 A) with a single molecule in the asymmetric unit and 55% solvent content. Cross rotation function calculations show that despite the different space groups the packing of the molecules in both crystals is likely to be similar suggesting the existence of a stable dimer. The monoclinic crystals diffract beyond 3 A using a laboratory rotating anode source, while under the same conditions the trigonal crystals diffract only to approximately 4.5 A. This is the first report of successful preparation of X-ray quality crystals of a high capacity Ca2+ binding protein.

Purification of calreticulin-like protein(s) from spinach leaves

In a search for the plant equivalent of calsequestrin or calreticulin, the high capacity, low affinity Ca2+ binding proteins of muscle and non-muscle cells thought to play important roles in Ca2+ storage, we purified two Ca(2+)-binding proteins from spinach leaves. The proteins had apparent molecular weights of 55 and 53 kDa. On Western blot, they did not react either with anti-rabbit skeletal muscle, anti-dog cardiac muscle calsequestrin or anti-rabbit or anti-rat liver calreticulin antibodies, indicating that they were antigenically distinct. Periodic acid Schiff staining (PAS) revealed that the larger protein was glycosylated while the 53 kDa one was PAS-negative. When the proteins were subjected to NH2-terminus amino acid sequencing, the 55 and 53 kDa proteins turned out to be identical, thus probably representing different isoforms of the same protein. Comparison with published amino acid sequences of calreticulin reveals regions of similarity indicating that the plant Ca(2+)-binding proteins probably belong to the calreticulin family.

Characterization of a calsequestrin-like protein from sea-urchin eggs

Following our studies on the identification of a calsequestrin-like protein (CSLP) from sea-urchin eggs [Oberdorf, Lebeche, Head & Kaminer (1988) J. Biol Chem. 263, 6806-6809], we have characterized its Ca(2+)-binding properties and identified it as a glycoprotein. The molecule binds 23 mol of Ca2+/mol of protein, as determined by equilibrium dialysis. This is in the range reported for cardiac calsequestrin but is about half the binding capacity of striated muscle calsequestrin. The affinities of the CSLP for Ca2+ are decreased by increasing KCl concentrations (20-250 mM) and the presence of Mg2+ (3 mM) in the medium: the half-maximal binding values varied from 1.62 to 5.77 mM. Hill coefficients indicated mild co-operativity in the Ca2+ binding. Ca2+ (1-8 mM)-induced u.v. difference spectra and intrinsic fluorescence changes suggest a net exposure of aromatic residues to an aqueous environment. C.d. measurements showed minor Ca(2+)-induced changes in alpha-helical and beta-sheet content of less than 10%. These spectral changes are distinctly different from those found in muscle calsequestrin. Immunoblotting studies showed that the CSLP is distinct from calreticulin, a low-affinity Ca(2+)-binding protein.