Chromogranin A, the major catecholamine storage vesicle soluble protein. Multiple size forms, subcellular storage, and regional distribution in chromaffin and nervous tissue elucidated by radioimmunoassay

Chromogranin A (CgA), the major catecholamine storage vesicle (CSV) soluble protein, may index exocytotic sympathoadrenal secretion. To explore CgA in adrenergic tissues, we developed a radioimmunoassay for bovine CgA. Within adrenal medulla CSV, several minor chromogranins had similar amino acid compositions and peptide maps to that of CgA and also showed parallel, partial cross-reactivity in the CgA radioimmunoassay. CgA immunoreactivity represented 7 +/- 1% of total adrenal medulla cell protein and was localized to adrenal CSV, representing 46 +/- 2% of CSV soluble protein. In brain, there was 1000-fold less CgA than in adrenal medulla, with a widespread regional distribution (maximal in neocortex) and an unusual subcellular distribution (maximal in cytosol), both of which differ from reported catecholamine distribution. Brain chromogranin immunoreactivity also had a lower Stokes radius than adrenal CgA. Sympathetic nerve and serum had 6,000-fold and 30,000-fold less CgA than that in adrenal medulla. The results suggest a "family" of adrenal medulla chromogranins, similar structurally and immunoligically. Adrenal medulla and brain chromogranin differ in concentration, subcellular localization, and molecular size. Finally, CgA in serum may provide a useful tool for sympathoadrenal studies in intact organisms.     

High capacity, low affinity Ca2+ binding of chromogranin A. Relationship between the pH-induced conformational change and Ca2+ binding property

Chromogranin A, the major intravesicular protein of adrenal chromaffin granules, bound Ca2+ in a pH-dependent manner. Both the maximal binding and affinity of chromogranin A for Ca2+ were dependent on pH. Chromogranin A bound 670 nmol of Ca2+/mg (32 mol/mol) and 1150 nmol of Ca2+/mg (55 mol/mol) at pH 7.5 and 5.5, respectively, with dissociation constants (Kd) of 2.7 and 4 mM. This pH dependence probably reflects different conformations of the protein at the two pH values. Conformational differences of chromogranin A at two different pH values were demonstrated by limited tryptic digestion patterns confirming previous results obtained by circular dichroism spectroscopy (Yoo, S. H., and Albanesi, J. P. (1990) J. Biol. Chem. 265, 14414-14421). Sedimentation equilibrium studies revealed the native molecular mass of chromogranin A to be 100 kDa at pH 7.5 and 192 kDa at pH 5.5, indicating dimeric and tetrameric states of the protein at the two pH levels. We postulate that the pH- and Ca2(+)-induced conformational changes of chromogranin A may have a role both in the regulation of Ca2+ release of chromaffin granules and in the early stages of secretory vesicle biogenesis.     

Topology of chromogranins in secretory granules of endocrine cells.

Chromogranins A and B are glycoproteins originally detected in the adrenal medulla. These proteins are also present in a variety of neuroendocrine cells. The subcellular distribution of the chromogranins, and particularly their intra-granular topology are of special interest with respect to their putative functions. Endocrine cells of the guinea pig adrenal medulla, pancreas and gastric mucosa were investigated immunoelectron microscopically for the subcellular distribution of both chromogranins. Out of 13 established endocrine cell types in all locations, only two endocrine cell types showed immunoreactivity for both chromogranin A and B, and eight endocrine cell types showed immunoreactivities only for chromogranin A. These immunoreactivities varied inter-cellularly. Three endocrine cell types were unreactive for the chromogranins. Moreover, some hormonally non-identified endocrine cells in the pancreas and the gastric mucosa also contained chromogranin A immunoreactivities. Subcellularly, chromogranin A or B were confined to secretory granules. In most endocrine cells, the secretory granules showed chromogranin immunoreactivities of varying densities. Furthermore, the intra-granular topology of chromogranin A or B in the secretory granules varied considerably: in some endocrine cell types, i.e. chromaffin-, gastrin- and enterochromaffin-like-cells, chromogranin A immunoreactivity was localized in the perigranular and/or dense core region of the secretory granules; in others, i.e. insulin-, pancreatic polypeptide- and bovine adrenal medulla dodecapeptide-cells, it was present preferentially in the electron-opaque centre of the secretory granules; chromogranin B immunoreactivity was localized preferentially in the perigranular region of the secretory granules of chromaffin cells and gastrin-cells. The inter-cellular and inter-granular variations of chromogranin A and B immunoreactivities point to differences in biosynthesis or processing of the chromogranins among endocrine cells and their secretory granules.     

Chromostatin receptors control calcium channel activity in adrenal chromaffin cells.

One of the functions of chromogranin A (CGA), the major soluble component of secretory granules in both adrenal medullary chromaffin cells and many other endocrine cell types appears to be that of a prohormone. CGA is the precursor of several peptides including pancreastatin, a 49-residue peptide, and a 20-residue peptide, chromostatin, which have been identified as biologically active peptides. Chromostatin produces a dose-dependent inhibition (ID50 of 5 nM) of the secretagogue-evoked catecholamine secretion from chromaffin cells. Here we report that chromostatin potently inhibits L-type calcium currents recorded with the nystatin-perforated patch technique in cultured chromaffin cells. This inhibitory effect of chromostatin on calcium currents was not observed in experiments using the classical patch-clamp whole-cell approach which induces the leakage of cytoplasmic components. Using 125I-chromostatin, we show that chromostatin exhibits a fully reversible and saturable binding to the plasma membrane of cultured chromaffin cells. Analysis of binding experiments at equilibrium indicates the existence of one class of binding sites with a Bmax of 2.7 pmol/mg of chromaffin cell proteins and an apparent Kd of 6.5 nM. This high affinity is in good correlation with the half-maximal concentration (ID50 5 nM) of chromostatin inhibiting catecholamine secretion from chromaffin cells. Specificity of the chromostatin binding was further assessed by displacement experiments with unlabeled CGA-related or -unrelated peptides. We found an excellent quantitative correlation between the affinities of the various peptides determined by binding assays and their functional potency tested on catecholamine secretion: bovine chromostatin greater than human chromostatin greater than CGA much greater than rat chromostatin, pancreastatin, CAP-14, substance P, and Leu-enkephalin. Cross-linking experiments reveal that chromostatin associates specifically with an 80-kDa plasma membrane protein. These results together with the patch-clamp experiments support the idea that chromaffin cells possess specific chromostatin receptors and that activation of such receptors leads to the inhibition of L-type voltage-sensitive calcium channels through an intracellular second messenger pathway.     

Calcium-dependence of chromogranin A-catecholamine interaction

Major components of the secretory organelle of bovine adrenal medullary cells, the chromaffin vesicles, are the acidic protein chromogranin A, catecholamines and Ca2+. The binding of Ca2+ to chromogranin A has been established. To study the interaction between chromogranin A and catecholamines and its dependence on Ca2+ we immobilized chromogranin A to a newly raised monoclonal antibody. It is shown that chromogranin A can bind (i) about 0.5 mol catecholamines per mol in a non-calcium-dependent manner and (ii) about 5 mol per mol in the presence of calcium. These results further support the notion that chromogranin A may act as a secretory granule-condensing protein.     

Calcium-binding proteins in the parathyroid gland. Detailed studies of parathyroid secretory protein

In order to identify calcium (Ca2+)-binding proteins in the parathyroid gland, we used electrophoretic blots of proteins separated by a two-dimensional nondenaturing/denaturing gel system and incubated them with 45Ca2+. Parathyroid secretory protein (PSP) and proteins with approximate molecular weights of 98,000, 88,000, 58,000, and 30,000 were noted to bind Ca2+ in cytosolic fractions from bovine parathyroid, adrenal, and pituitary glands. However, differences in the binding affinity and capacity of the various proteins were observed. PSP displayed a low affinity and high binding capacity for Ca2+. In the presence of 5 mM MgCl2 and 60 mM KCl, native PSP (immobilized on nitrocellulose filters) bound 7.5 mol of Ca2+/mol of protein monomer with an apparent Kd of 1.1 mM. Immunoblotting identified the association of PSP with parathyroid cell membranes in a Ca2+-dependent manner. This property, together with its heat stability, distinguished PSP from other cytosolic Ca2+-binding proteins which were identified. There was also evidence for a Ca2+-dependent protein-protein interaction (aggregation) of PSP present in a Nonidet P-40 extract of cell membranes. The high Ca2+ binding capacity of PSP and its Ca2+-dependent membrane association may be features that make PSP a potentially important protein in secretory cells.     

Topology of chromogranins in secretory granules of endocrine cells

Summary Chromogranins A and B are glycoproteins originally detected in the adrenal medulla. These proteins are also present in a variety of neuroendocrine cells. The subcellular distribution of the chromogranins, and particularly their intra-granular topology are of special interest with respect to their putative functions.Endocrine cells of the guinea pig adrenal medulla, pancreas and gastric mucosa were investigated immunoelectron microscopically for the subcellular distribution of both chromogranins. Out of 13 established endocrine cell types in all locations, only two endocrine cell types showed immunoreactivity for both chromogranin A and B, and eight endocrine cell types showed immunoreactivities only for chromogranin A. These immunoreactivities varied inter-cellularly. Three endocrine cell types were unreactive for the chromogranins. Moreover, some hormonally non-identified endocrine cells in the pancreas and the gastric mucosa also contained chromogranin A immunoreactivities.Subcellularly, chromogranin A or B were confined to secretory granules. In most endocrine cells, the secretory granules showed chromogranin immunoreactivities of varying densities. Furthermore, the intra-granular topology of chromogranin A or B in the secretory granules varied considerably: in some endocrine cell types, i.e. chromaffin-, gastrin- and enterochromaffin-like-cells, chromogranin A immunoreactivity was localized in the perigranular and/or dense core region of the secretory granules; in others, i.e. insulin-, pancreatic polypeptide-and bovine adrenal medulla dodecapeptide-cells, it was present preferentially in the electron-opaque centre of the secretory granules; chromogranin B immunoreactivity was localized preferentially in the perigranular region of the secretory granules of chromaffin cells and gastrin-cells. The inter-cellular and inter-granular variations of chromogranin A and B immunoreactivities point to differences in biosynthesis or processing of the chromogranins among endocrine cells and their secretory granules.     

Regulation by divalent cations of 3H-baclofen binding to GABAB sites in rat cerebellar membranes

When investigating the effects of divalent cations (Mg2+, Ca2+, Sr2+, Ba2+, Mn2+ and Ni2+) on 3H-baclofen binding to rat cerebellar synaptic membranes, we found that the specific binding of 3H-baclofen was not only dependent on divalent cations, but was increased dose-dependently in the presence of these cations. The effects were in the following order of potency: Mn2+ congruent to Ni2+ greater than Mg2+ greater than Ca2+ greater than Sr2+ greater than Ba2+. Scatchard analysis of the binding data revealed a single component of the binding sites in the presence of 2.5 mM MgCl2, 2.5 mM CaCl2 or 0.3 mM MnCl2 whereas two components appeared in the presence of 2.5 mM MnCl2 or 1 mM NiCl2. In the former, divalent cations altered the apparent affinity (Kd) without affecting density of the binding sites (Bmax). In the latter, the high-affinity sites showed a higher affinity and lower density of the binding sites than did the single component of the former. As the maximal effects of four cations (Mg2+, Ca2+, Mn2+ and Ni2+) were not additive, there are probably common sites of action of these divalent cations. Among the ligands for GABAB sites, the affinity for (-), (+) and (+/-) baclofen, GABA and beta-phenyl GABA increased 2-6 fold in the presence of 2.5 mM MnCl2, in comparison with that in HEPES-buffered Krebs solution (containing 2.5 mM CaCl2 and 1.2 mM MgSO4), whereas that for muscimol was decreased to one-fifth. Thus, the affinity of GABAB sites for its ligands is probably regulated by divalent cations, through common sites of action.     

Tightly bound magnesium in mitochondrial adenosine triphosphatase from beef heart.

Tightly bound magnesium was found in soluble, purified ATPase (F1) from beef heart mitochondria in the amount of 1 mol/mol of F1. Iron, zinc, cobalt, manganese, calcium, sodium, copper, and potassium were not tightly bound at stoichiometric levels. Removal of magnesium by chelating agents caused loss of ATPase activity. Removal of tightly bound nucleotide by gel filtration in 50% glycerol- or 60 mM K2SO4-containing buffers did not remove magnesium. Cold dissociation did release magnesium when complete denaturation was accomplished. The results suggest that magnesium is an integral part of F1, that it is required for activity, and that magnesium and nucleotides are tightly bound at separate sites. The idea that the tightly bound nucleotides are not complexed with cations suggests certain structural requirements at their binding sites which might account for the unusual properties of the sites.     

Temperature sensitivity of catecholamine secretion and ion fluxes in bovine adrenal chromaffin cells

The effects of temperature on ion fluxes and catecholamine secretion that are mediated by nicotinic acetylcholine receptors (nAChRs), voltage-sensitive calcium channels (VSCCs), and voltage-sensitive sodium channels (VSSCs) were investigated using bovine adrenal chromaffin cells. When the chromaffin cells were stimulated with DMPP, a nicotinic cholinergic agonist, or 50 mM K+, the intracellular calcium ([Ca2+]i) elevation reached a peak and decreased more slowly at lower temperatures. The DMPP-induced responses were more sensitive to temperature changes compared to high K+-induced ones. In the measurement of intracellular sodium concentrations ([Na+]i), it was found that nicotinic stimulation required a longer time to attain the maximal level of [Na+]i at lower temperatures. In addition, the VSSCs-mediated [Na+]i increase evoked by veratridine was also reduced as the temperature decreased. The measurement of [3H]norepinephrine (NE) secretion showed that the secretion within the first 3 min evoked by DMPP or high K+ was greatest at 37 degrees C. However, at 25 degrees C, the secretion evoked by DMPP, but not that by the 50 mM K+, was greater after 10 min of stimulation. This data suggest that temperature differentially affects the activity of nAChRs, VSCCs, and VSSCs, resulting in differential [Na+]i and [Ca2+]i elevation, and in the [3H]NE secretion by adrenal chromaffin cells.     

Calcium and collagen binding properties of osteopontin, bone sialoprotein, and bone acidic glycoprotein-75 from bone.

Calcium binding properties of bone acidic glycoprotein-75, osteopontin, and bone sialoprotein were determined in 10 mM imidazole buffer (pH 6.8), containing either 60 mM KCl or 150 mM NaCl. Proteins assayed were first bound to nitrocellulose to mimic substrate-bound forms in vivo; retention of phosphoproteins was determined through use of radioiodinated tracers. Binding studies were carried out both as a function of calcium concentration and the amount of phosphoprotein. In the presence of 60 mM KCl, bone acidic glycoprotein-75 exhibited the largest calcium binding capacity (139 atoms/molecule at saturation), with bone sialoprotein intermediary (83 atoms/molecule) and osteopontin lowest (50 atoms/molecule). Sites detected for each phosphoprotein exhibited overall binding constants in the 0.5-1.0 mM extracellular range. In 150 mM NaCl and 1-2 mM total calcium, phosphoproteins bound between 72 and 19 mol of calcium/mol with the same relative order. Binding was proportional to amount of phosphoprotein in either salt condition. The presence of 5 mM calcium had a different effect on concentration-dependent binding to type I collagen for each phosphoprotein. Bone acidic glycoprotein-75 alone was found to undergo an unusual calcium-enhanced polymerization reaction, confirmed by light scattering measurements, wherein collagen binding was greatest with polymeric forms. These findings demonstrate that acidic phosphoproteins from bone bind calcium atoms with a range of capacities. Calcium appears to induce conformational changes in bone acidic glycoprotein-75 which influences its self-association and binding to different substrata.     

Chromogranins or chromogranin-like proteins are present in lamellar bodies and pulmonary surfactant of rat alveolar type II cells

Rat alveolar Type II cells were immunostained with antibodies directed against chromogranin A (monoclonal, LK2H10) and chromogranins A and B (polyclonal, LKZM1U). The chromogranins or chromogranin-like proteins were identified in cells in lung tissue sections and isolated Type II cells at the light and electron microscopic levels. We used post-embedding immunoelectron microscopy, with immunogold, to detect the proteins' immunoreactivity in osmicated tissues. Gold particles were distributed over the phospholipid lamellae within the lamellar bodies of alveolar Type II cells and over the lattice structure of tubular myelin. Quantitative analysis of gold labeling densities in the various cell compartments indicated that only the latter two structures were specifically labeled. Controls, which included pre-absorption of both anti-chromogranin antibodies with excess chromogranin A or with native surfactant, resulted in a greater than 60% decrease in gold labeling. A possible role of chromogranins or chromogranin-like proteins as Ca2+ binding proteins in alveolar Type II cells is discussed.     

Functional coupling of chromogranin with the inositol 1,4,5-trisphosphate receptor shapes calcium signaling

Chromogranins A and B are high capacity, low affinity calcium (Ca(2+)) storage proteins that bind to the inositol 1,4,5-trisphosphate-gated receptor (InsP(3) R). Although most commonly associated with secretory granules of neuroendocrine cells, chromogranins have also been found in the lumen of the endoplasmic reticulum (ER) of many cell types. To investigate the functional consequences of the interaction between the InsP(3) R and the chromogranins, we disrupted the interaction between the two proteins by adding a chromogranin fragment, which competed with chromogranin for its binding site on the InsP(3)R. Responses were monitored at the single channel level and in intact cells. When using InsP(3) R type I incorporated into planar lipid bilayers and activated by cytoplasmic InsP(3) and luminal chromogranin, the addition of the fragment reversed the enhancing effect of chromogranin. Moreover, the expression of the fragment in the ER of neuronally differentiated PC12 cells attenuated agonist-induced intracellular Ca(2+) signaling. These results show that the InsP(3)R/chromogranin interaction amplifies Ca(2+) release from the ER and that chromogranin is an essential component of this intracellular channel complex.     

Presence of chromogranin A, B and C in bovine endocrine and nervous tissues: a comparative immunohistochemical study

Summary Antisera against chromogranin A, B and C were used to study the distribution of these acidic proteins in bovine endocrine and nervous tissues. The three chromogranins occur together in several endocrine organs (adrenal medulla, anterior pituitary, endocrine pancreas) and in sympathetic ganglion cells. In the posterior pituitary, only chromogranin C and in the intermediate lobe only A and C are found. The parathyroid gland contains only A, and enterochromaffin cells are immunoreactive for A and B. Cells of the thyroid gland and some cells of the anterior pituitary apparently do not contain any chromogranins. It is concluded that the three chromogranins are not always stored together and that they are not present in all endocrine cells. This distinct localization of the chromogranins indicates some special, although still undiscovered, function for these proteins.     

Ion-binding to phospholipids. Interaction of calcium with phosphatidylserine.

The binding of Ca2+ to monolayers and bilayers of phosphatidylserine has been investigated as a function of pH, ionic strength (NaCl concentration) and Ca2+ concentration using surface and colloid chemical techniques. The molar ratio of lipid to bound calcium decreases to 2 as the Ca2+ concentration is increased to about 0.1 mM. At [Ca2+] greater than 0.1 mM a 1:1 complex is formed. The apparent binding constant Ka ranges from about approximately 10(6) - 10(4) l/mol depending on the Ca2+ concentration. After allowing for electrostatic effects and neighbour group interactions, the intrinsic binding constant Ki of the phosphorylserine polar group at pH 7 (I = 0.01 M), where it carries a net negative charge of one, is approximately 10(4) l/mol; consistent values for Ki were obtained using several independent approaches. Ka for Ca2+ binding decreases with increasing NaCl concentration because the monovalent cations compete with Ca2+ for the same binding site. Na+ and K+ are equally effective in displacing 45Ca2+ adsorbed to monolayers of phosphatidylserine, both with respect to the kinetics and the equilibrium of the displacement. Ka for the reaction between phosphatidylserine and monovalent cations is about 10(3)-fold smaller than that of Ca2+. An investigation of the binding of Mn2+ to phosphatidylserine by both surface chemical and nuclear magnetic resonance methods shows that this cation has a similar binding constant to that of Ca2+. The Ca2+-binding capabilities of monolayers containing only carboxyl groups (i.e. arachidic acid) and phosphodiester groups (i.e. dicetyl phosphate) have also been determined; the apparent pK for the - COOH group in monolayers is larger than or equal to 9 and that for the phosphodiester group is less than 4. Since these groups do not retain the same pK values when they are in close proximity in the phosphorylserine group, the relative contributions of the two groups to the binding of Ca2+ to phosphatidylserine is not obvious.     

Biosynthetic relationship between the major matrix proteins of adrenal chromaffin granules

The matrix of the chromaffin granule contains a family of acidic proteins, collectively known as the chromogranins. It has been suggested that this family results from protease action on the major component, chromogranin A. Evidence for this has now been obtained from in vitro translation of adrenal medullary messenger RNA and immunoprecipitation of translation products using an antiserum directed against chromogranin A, but which also recognises other chromogranins.     

Absorption, fluorescence, and linear dichroism spectra of fluorescein mercuric acetate (FMA) bound to F-actin. Two kinds of effects of divalent cations.

Two kinds of F-actin were prepared; one binds magnesium at the unique divalent cation binding site of actin protomer and the other binds calcium at this site. They were designated as F(Mg)-actin and F(Ca)-actin, respectively. The binding of fluorescein mercuric acetate (FMA) to F(Mg)-actin and F(Ca)-actin was studied spectroscopically. The absorption and fluorescence spectra of bound FMA differed slightly but distinctly between F(Mg)-actin and F(Ca)-actin. Moreover, FMA bound to F(Mg)-actin showed linear dichroism in the presence of 2 mM MgCl2 (or 2mM CaCl2) in the solvent, while the dichroism was abolished by the removal of divalent cations from the solvent. In contrast, FMA bound to F(Ca)-actin did not show any appreciable linear dichroism irrespective of the presence (or absence) of divalent cations in the solvent. These results suggest that the structure of F-actin is characteristically regulated by divalent cations in a dual mode.     

N- and C-terminal domains direct cell type-specific sorting of chromogranin A to secretory granules

Chromogranins are a family of regulated secretory proteins that are stored in secretory granules in endocrine and neuroendocrine cells and released in response to extracellular stimulation (regulated secretion). A conserved N-terminal disulfide bond is necessary for sorting of chromogranins in neuroendocrine PC12 cells. Surprisingly, this disulfide bond is not necessary for sorting of chromogranins in endocrine GH4C1 cells. To investigate the sorting mechanism in GH4C1 cells, we made several mutant forms removing highly conserved N- and C-terminal regions of bovine chromogranin A. Removing the conserved N-terminal disulfide bond and the conserved C-terminal dimerization and tetramerization domain did not affect the sorting of chromogranin A to the regulated secretory pathway. In contrast, removing the C-terminal 90 amino acids of chromogranin A caused rerouting to the constitutive secretory pathway and impaired aggregation properties as compared with wild-type chromogranin A. Since this mutant was sorted to the regulated secretory pathway in PC12 cells, these results demonstrate that chromogranins contain independent N- and C-terminal sorting domains that function in a cell type-specific manner. Moreover, this is the first evidence that low pH/calcium-induced aggregation is necessary for sorting of a chromogranin to the regulated secretory pathway of endocrine cells.     

Channel permeant cations compete selectively with noncompetitive inhibitors of the nicotinic acetylcholine receptor.

Previous work suggests that noncompetitive inhibitor (NCI) ligands and channel permeant cations bind to sites within the nicotinic acetylcholine receptor ion channel. We have used ethidium as a fluorescent probe of the NCI site to investigate interactions between NCI ligands and channel permeant cations. We found that ethidium can be completely displaced from the receptor by a variety of inorganic monovalent and divalent cations. The rank order of monovalent cation affinities was found to be Tl+ greater than Rb+ greater than or equal to K+ greater than Cs+ greater than Na+ greater than Li+. The monovalent cation Kd values vary markedly over a 40-fold range, from 3 to 121 mM. The Kd values and rank order correspond to values determined previously from electrophysiological data. Hill plots of the back titrations yield slopes of 1.0 for all monovalent cations, indicating a single class of independent sites, as shown previously for NCI ligands. Scatchard analysis of ethidium binding in the presence of Tl+ reveals a reduction in affinity and no changes in the maximal number of sites. In the presence of agonist the kinetics of ethidium dissociation induced by the addition of phencyclidine or cations alone or the simultaneous addition of both are nearly identical. The ethidium dissociation rate induced by either phencyclidine or cations is regulated by the occupation of the agonist sites in a similar manner. These results indicate that the effect of cations on NCI ligand binding occurs by mutually exclusive competition. We suggest that NCIs can regulate cation binding at a physiological cation recognition site that is likely part of the cation permeation path through the receptor channel.     

Calcium binding and calcium-sensitivity of heavy meromyosin and subfragment-1 from squid (Todarodes pacificus) mantle and scallop (Patinopecten yessoensis) adductor muscles

1. HMM and S-1 both bind one mol of calcium per mole of head, and a half of the calcium binding was diminished upon magnesium addition (10 mM) at the low affinity site. 2. The Mg-ATPase activity of HMM (without actin) was fully activated by the binding of one mol of calcium bound per mol of HMM. 3. The calcium binding profile to S-1 is the same as that to HMM, however, the Mg-ATPase activity of S-1 is independent of calcium binding. It is suggested that there are two kinds of myosin head (or S-1) in molluscan myosin, functionally different in calcium binding properties.