The effects of chemical modification of calmodulin on Ca2+-induced exposure of a hydrophobic region. Separation of active and inactive forms of calmodulin

Native calmodulin binds four calcium ions per molecule and exhibits strong Ca2+-dependent binding to phenyl-Sepharose. In contrast, calmodulin inactivated by oxidation of methionine residues or by deamidation binds fewer calcium ions (two per molecule) and shows relatively weak interaction with phenyl-Sepharose. Calmodulin inactivated by modification of lysine residues still is able to bind four calcium ions per molecule and shows strong binding to phenyl-Sepharose similar to native calmodulin. The results suggest that complete exposure of calmodulin's hydrophobic region occurs only after the binding of four ions of calcium to the calmodulin molecule. Thus, phenyl-Sepharose hydrophobic interaction chromatography might be used to separate active calmodulin from inactive forms of calmodulin obtained by oxidation or heat treatment for prolonged periods. As an example, phenyl-Sepharose chromatography can be used to separate free iodide and inactivated species of calmodulin readily from the active, iodinated form of calmodulin following iodination.     

Calmodulin interacts with cyclic nucleotide phosphodiesterase and calcineurin by binding to a metal ion-independent hydrophobic region on these proteins

Hydrophobic interaction chromatography is employed to determine if calmodulin might associate with its target enzymes such as cyclic nucleotide phosphodiesterase and calcineurin through its Ca2+-induced hydrophobic binding region. The majority of protein in a bovine brain extract that binds to a calmodulin-Sepharose affinity column also is observed to bind in a metal ion-independent manner to phenyl-Sepharose through hydrophobic interactions. Cyclic nucleotide phosphodiesterase activity that is bound to phenyl-Sepharose can be resolved into two activity peaks; one peak of activity is eluted with low ionic strength buffer, while the second peak eluted with an ethylene glycol gradient. Calcineurin bound tightly to the phenyl-Sepharose column and could only be eluted with 8 M urea. Increasing ethylene glycol concentrations in the reaction mixture selectively inhibited the ability of calmodulin to stimulate phosphodiesterase activity, suggesting that hydrophobic interaction is required for activation. Comparison of the proteins which are bound to and eluted from phenyl- and calmodulin-Sepharose affinity columns indicates that chromatography involving calmodulin-Sepharose resembles hydrophobic interaction chromatography with charged ligands. In this type of interaction, hydrophobic binding either is reinforced by electrostatic attractions or opposed by electrostatic repulsions to create a degree of specificity in the binding of calmodulin to certain proteins with accessible hydrophobic regions.     

Linear multidimensional liquid chromatography in the preparative scale purification of calmodulin from brain extract

Rapid preparative scale purification of calmodulin from crude bovine brain extract is achieved in a single chromatographic run by physically coupling two different liquid chromatography columns which employ different separation mechanisms. In this case columns packed with newly commercialized 40-microns silica-based hydrophobic interaction and 5-microns micron silica-based weak anion-exchange chromatography media were used. The only sample preparation required for conducting this purification procedure is the addition of salt to the crude brain supernatant to promote the initial binding of calmodulin to the hydrophobic interaction chromatography media. Chromatography carried out on such linear arrangements of columns has been referred to as linear multidimensional liquid chromatography.     

Calelectrins are a ubiquitous family of Ca2+-binding proteins purified by Ca2+-dependent hydrophobic affinity chromatography by a mechanism distinct from that of calmodulin

The calelectrins, a heterogeneous group of three new Ca2+-binding proteins of M 67 000, 35 000 and 32 500, copurify with calmodulin during Ca2+-dependent hydrophobic affinity chromatography (Südhof et al., Biochemistry, in press, 1984). This property is exploited for the rapid purification of all three calelectrins including for the first time the Mr 35 000, from commercially available acetone powders from several bovine tissues (heart, liver, brain, pancreas and testis). The nature of the Ca2+-dependent interaction of the calelectrins with hydrophobic affinity matrices has been investigated. As with calmodulin, the Ca2+-binding sites of all three purified calelectrins can be probed with Tb3+ which binds to them in a stoichiometric, saturable and Ca2+-displaceable manner. However, using several hydrophobic fluorescence probes which bind to the proteins, contrary to calmodulin no Ca2+-dependent exposure of hydrophobic sites could be detected in any of the three purified proteins. Therefore the Ca2+-dependent purification of the calelectrins on hydrophobic affinity columns seems not to involve the surface exposure of hydrophobic sites and the calelectrins have in this respect little similarity to calmodulin.     

A Method for the Purification of Phospho(Tyr)calmodulin Free of Nonphosphorylated Calmodulin

Phosphocalmodulin has been shown to have a differential biological activity compared to nonphosphorylated calmodulin when assayed on a variety of calmodulin-dependent systems. However, the phosphocalmodulin preparations used so far in those experiments were not necessarily free of nonphosphorylated calmodulin. Therefore, the results obtained may not unquestionably show the real effect of pure phosphocalmodulin on the systems under study. To solve this problem, we describe here a method for the purification of phospho(Tyr)calmodulin free of nonphosphorylated calmodulin. The procedure consists of the following steps: (i) phosphorylation of calmodulin by a fraction enriched in epidermal growth factor receptor tyrosine kinase from rat liver isolated by calmodulin affinity chromatography, (ii) isolation of a calmodulin/phosphocalmodulin mixture by Ca(2+)-dependent chromatography in phenyl-Sepharose, (iii) purification of phospho(Tyr)calmodulin using an anti-phosphotyrosine antibody immobilized in agarose upon elution with phenyl phosphate, and (iv) removal of phenyl phosphate from the phospho(Tyr)calmodulin preparation by filtration chromatography in a Bio-Gel P-2 column. The obtained phospho(Tyr)calmodulin preparation was highly pure and essentially free of nonphosphorylated calmodulin because of the use of anti-phosphotyrosine affinity chromatography. We demonstrate that this ultrapure phospho(Tyr)calmodulin preparation is totally incapable of activating the calmodulin-dependent cyclic nucleotide phosphodiesterase. In contrast, when a nonpurified phospho(Tyr)calmodulin preparation was used a partial activation of this enzyme was observed.     

A simple purification of calmodulin by reversed phase chromatography with hydrophobic polymer 3520

A new adsorption chromatography procedure for the purification of calmodulin from bovine brain was developed using polymeric adsorbent 3520. Calmodulin was first isolated by DEAE-Cellulose column chromatography and further purified to apparent homogeneity following elution with 50% ethanol from the adsorbent column. Polyacrylamide gel electrophoresis showed one band either in the presence of Ca2+ or EGTA. The polymeric adsorbent 3520 is a non-polar polymer lacking exchangeable groups. The selective adsorption of calmodulin is based on hydrophobic interaction within the matrix, and is Ca2+ independent. Neither high salt (0.5 M NaC1) nor EGTA (5 mM) was able to elute the CaM from the adsorption column whereas ethanol (50%) eluted it completely. This method is simple to use and it provides highly purified calmodulin with high yield.     

Rapid purification of calmodulin and S-100 protein by affinity chromatography with melittin immobilized to sepharose

Melittin-Sepharose was prepared for Ca2+-dependent affinity chromatography of calmodulin and S-100 protein. This matrix exhibits extremely high capacity (approximately 10 mg calmodulin/ml gel), low nonspecific binding, and excellent recovery (greater than 90%) under optimal conditions. Recovery of calmodulin from melittin-Sepharose was related to the degree of saturation of column capacity with lower yields when only partial saturation was achieved. Large-scale, simultaneous purification of calmodulin and S-100 protein from brain was carried out using selective adsorption to organomercurial agarose followed by melittin-Sepharose chromatography; yields were 250-300 mg of calmodulin and 200-300 mg of S-100 per kg tissue. Calmodulin also was purified in a single step from bovine testis supernatant using melittin-Sepharose in yields comparable to those from brain.     

A fluorescent calmodulin that reports the binding of hydrophobic inhibitory ligands.

Ca2+ binding to calmodulin in the pCa range 5.5-7.0 exposes hydrophobic sites that bind hydrophobic inhibitory ligands, including calmodulin antagonists, some Ca2+-antagonists and calmodulin-binding proteins. The binding of these hydrophobic ligands to calmodulin can be followed by the approx. 80% fluorescence increase they produce in dansylated (5-dimethylaminonaphthalene-1-sulphonylated) calmodulin (CDRDANS). In the presence of Ca2+, calmodulin binds the calmodulin inhibitor, R24571, with an affinity of approx. 2-3 nM and hydrophobic ligands, including trifluoperazine (TFP), W-7 [N-(6-aminohexyl)-5-chloronaphthalene-1-sulphonamide], fendiline, felodipine and prenylamine, with affinities in the micromolar range. This binding is strongly Ca2+-dependent and Mg2+-independent. Calmodulin shows a reasonably high degree of specificity in its binding of these ligands over other ligands tested. CDRDANS, therefore, provides a convenient and simple means of monitoring the interaction of a variety of hydrophobic ligands with the Ca2+-dependent regulatory protein, calmodulin. CDRDANS binds to phospholipid vesicles made of (dimyristoyl)phosphatidylcholine (DMPC) or (dipalmitoyl)phosphatidylcholine (DPPC) and produces fluorescence increases only in the presence of Ca2+ and at temperatures above their gel-to-liquid crystalline phase transition. Although the fluorescence changes in CDRDANS accurately report phase transitions in these liposomes, its binding to these vesicles is weak. Calmodulin probably requires a high-affinity lipid-bound receptor protein for its high-affinity binding to natural membranes.     

Calcium/calmodulin inhibits direct binding of spectrin to synaptosomal membranes

Brain spectrin, through its beta subunit, binds with high affinity to protein-binding sites on brain membranes quantitatively depleted of ankyrin (Steiner, J., and Bennett, V. (1988) J. Biol. Chem. 263, 14417-14425). In this study, calmodulin is demonstrated to inhibit binding of brain spectrin to synaptosomal membranes. Submicromolar concentrations of calcium are required for inhibition of binding, with half-maximal effects at pCa = 6.5. Calmodulin competitively inhibits binding of spectrin to protein(s) in stripped synaptosomal membranes, with Ki = 1.3 microM in the presence of 10 microM calcium. A reversible receptor-mediated process, and not proteolysis, is responsible for inhibition since the effect of calcium/calmodulin is reversed by the calmodulin antagonist trifluoperazine and by chelation of calcium with sodium [ethylenebis(oxyethylenenitrilo)]tetraacetic acid. The target of calmodulin is most likely the spectrin attachment protein(s) rather than spectrin itself since: (a) membrane binding of the brain spectrin beta subunit, which does not associate with calmodulin, is inhibited by calcium/calmodulin, and (b) red cell spectrin which binds calmodulin very weakly, is inhibited from interacting with membrane receptors in the presence of calcium/calmodulin. Ca2+/calmodulin inhibited association of erythrocyte spectrin with synaptosomal membranes but had no effect on binding of erythrocyte or brain spectrin to ankyrin in erythrocyte membranes. These experiments demonstrate the potential for differential regulation of spectrin-membrane protein interactions, with the consequence that Ca2+/calmodulin can dissociate direct spectrin-membrane interactions locally or regionally without disassembly of the areas of the membrane skeleton stabilized by linkage of spectrin to ankyrin. A membrane protein of Mr = 88,000 has been identified that is dissociated from spectrin affinity columns by calcium/calmodulin and is a candidate for the calmodulin-sensitive spectrin-binding site in brain.     

Characterization of a novel calmodulin from Dictyostelium discoideum

We have purified calmodulin from the eukaryotic microorganism Dictyostelium discoideum (Clarke, M., Bazari, W. L., and Kayman, S. C. (1980) J. Bacteriol. 141, 397-400) and have compared it to calmodulin purified from bovine brain. The two proteins behaved almost identically during fractionation on ion exchange and gel filtration columns and on isoelectric focusing gels. Dictyostelium calmodulin had one-third the specific activity of brain calmodulin in the Ca2+-dependent activation of brain cyclic nucleotide phosphodiesterase; this activation was inhibited for both proteins by 25 microM trifluoperazine. Dictyostelium calmodulin also activated erythrocyte (Ca2+ + Mg2+)-ATPase and interacted with the inhibitory subunit of skeletal muscle troponin. Competition radioimmune assays showed that Dictyostelium calmodulin could compete with brain calmodulin for antibodies to brain calmodulin. These similarities indicate a close relationship between Dictyostelium and brain calmodulin and suggest that the functional capabilities of the protein have been conserved even among evolutionarily distant species. However, substantial differences in primary structure were detected by amino acid analyses and peptide mapping. Most interesting is the lack of trimethyllysine in Dictyostelium calmodulin. This unusual amino acid, which is commonly found in calmodulins, is therefore not essential for interaction between calmodulin and the calmodulin-regulated proteins tested here.     

Selective affinity chromatography with calmodulin fragments coupled to sepharose

Calmodulin tryptic fragments 78-148, 107-148, and 1-77 coupled to Sepharose 4B were used to test the ability of different calmodulin-regulated enzymes to recognize different domains of calmodulin. Fragment 107-148, which contains a single Ca2+-binding domain, does not interact with any of the calmodulin binding proteins. Fragments 1-77 and 78-148, each of which contains two Ca2+-binding domains, have preserved their ability to interact with several calmodulin-dependent enzymes. Most of the calmodulin-regulated enzymes in brain extracts, such as cAMP phosphodiesterase, cAMP-dependent protein kinase, and the calmodulin-stimulated protein phosphatase (calcineurin) interact with fragment 78-148 in a Ca2+-dependent fashion. An ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid-sensitive, calmodulin-independent, p-nitrophenyl phosphatase does not bind to the affinity column and is resolved from calcineurin at this step. Although calmodulin-stimulated protein kinase(s) can interact with fragment 78-148, their interaction is prevented by increased ionic strength even in the presence of Ca2+. Fragment 1-77 exhibits a higher degree of selectivity than fragment 78-148. Only cAMP-dependent protein kinase and cAMP phosphodiesterase bind to fragment 1-77. These results confirm the multiple modes of interaction of calmodulin with its target proteins and provide the basis for a selective purification of calmodulin-regulated enzymes by affinity chromatography on specific calmodulin fragments coupled to Sepharose.     

Purification of plant calmodulin by fluphenazine-Sepharose affinity chromatography.

The calcium-dependent binding of phenothiazine drugs to calmodulin (Levin, R. M. and Weiss, B. (1977) Mol. Pharmacol. $\text{13}$, 690–697) has been utilized to develop a rapid purification procedure for calmodulin based on fluphenazine-Sepharose affinity chromatography. Calmodulin from plant, a fungus, porcine brain and the coelenterate, $\text{Renilla}\text{reniformis}$, were easily purified by the calcium-dependent binding of calmodulin to fluphenazine-Sepharose.     

Ca2+-dependent regulation of calmodulin binding and adenylate cyclase activation in bovine cerebellar membranes

The binding parameters of ¹²⁵I-labeled calmodulin to bovine cerebellar membranes have been determined and correlted with the activation of adenylate cyclase by calmodulin. In the presence of saturating levels of free Ca²⁺, calmodulin binds to a finite number of specific membrane sites with a dissociation constant (K_d) of 1.2 nM. Furthermore, Scatchard analysis reveals a second population of binding sites with a 100-fold lower affinity for calmodulin. The Ca²⁺-dependence of calmodulin binding and of adenylate cyclase activation varies with the amount of calmodulin present, as can be infered from the model of sequential equilibrium reactions which describes the activation of calmodulin-dependent enzymes. On the basis of this model, a quantitative analysis of the effect of free Ca²⁺ and of free calmodulin concentration on both binding and activation of adenylate cyclase was carried out. This analysis shows that both processes take place only when calmodulin is complexed with at least three Ca²⁺ atoms. The concentration of the active calmodulin ·Ca²⁺ species required for half-maximal activation of adenylate cyclase is very similar to the K_d of the high affinity binding sites on brain membranes. A Hill coefficient of approx. 1 was found for both processes indicating an absence of cooperativity. Phenothiazines and thioxanthenes antipsychotic agents inhibit calmodulin binding to membranes and calmodulin-dependent activation of adenylate cyclase with a similar order of potency. These results suggest that the Ca²⁺-dependent binding of calmodulin to specific high affinity sites on brain membranes regulates the activation of adenylate cyclase by calmodulin.     

Binding of spin-labeled fatty acids and lysophospholipids to hydrophobic region of calmodulin.

In the presence of bovine brain calmodulin activated by calcium, the sharp triplet electron spin resonance (ESR) lines of free doxyl stearic acids decreased, and the broad resonance lines increased concomitantly, suggesting that the doxyl stearic acids bound to calmodulin calcium-dependently. The bound molecules were displaced by a calmodulin inhibitor, W-7, whereas their nitroxide radicals were hardly reduced by ascorbic acid, suggesting that the spin-labeled fatty acids bind to hydrophobic regions of calmodulin, and consequently inhibit calmodulin-dependent phosphodiesterase activity. These binding characteristics to calmodulin were different from those to bovine serum albumin. Moreover, the ESR spectra of two spin-labeled derivatives of lysophospholipid having a spin-labeled acyl group or a spin-labeled polar head group showed that it is the acyl chain of lysophospholipid that interacts with the hydrophobic region of calmodulin. The interactions of fatty acids and lysophospholipids with calmodulin seem to be quite different from those of acidic phospholipids, described previously [Suzuki, T., Katoh, H., & Uchida, M.K. (1986) Biochim. Biophys. Acta, 873, 379-386]. Thus, from the results of ESR study, we can obtain information on the function of fatty acids and lysophospholipids on calmodulin. Instead of enzyme assay, ESR spectroscopy is a useful means to examine lipid-protein interaction.     

Ca2+/calmodulin dependent protein kinase from Mycobacterium smegmatis ATCC 607

A soluble Ca²⁺/calmodulin dependent protein kinase has been partially purified (~400 fold) from Mycobacterium smegmatis ATCC 607 using several purification steps like ammonium sulphate precipitation (30-60%), Sepharose CL-6B gel filtration, DEAE-cellulose and finally calmodulin-agarose affinity chromatography. On SDS-PAGE, this enzyme preparation showed a major protein band of molecular mass 35 kD and its activity was dependent on calcium, calmodulin and ATP when measured under saturating histone IIs (exogenous substrate) concentration. Phosphorylation of histone IIs was inhibited by W-7 (calmodulin inhibitor) and KN-62 (CaM-kinase inhibitor) with IC₅₀ of 1.5 and 0.25 m respectively, but was not affected by inhibitors of PKA (Sigma P5015) and PKC (H-7). All these results confirm that purified enzyme is Ca²⁺/ calmodulin dependent protein kinase of M. smegmatis. The protein kinase of M. smegmatis demonstrated a narrow substrate specificity for both exogenous as well as endogenous substrates. These results suggest that purified CaM-kinase must be involved in regulating specific function(s) in this organism.     

Affinity purification of seminalplasmin and characterization of its interaction with calmodulin.

Bull seminalplasmin antagonizes with high potency and selectivity the activating effect of calmodulin on target enzymes [Gietzen & Galla (1985) Biochem. J. 230, 277-280]. In the present paper we establish that seminalplasmin forms a 1:1, Ca2+-dependent and urea-resistant complex with calmodulin. The dissociation constant equals 1.6 nM. In the absence of Ca2+ a low-affinity complex is formed that is disrupted by 4 M-urea. On the basis of these properties, a fast affinity purification of seminalplasmin was developed. The high specificity of seminalplasmin as a calmodulin antagonist was demonstrated for the multipathway-regulated adenylate cyclase of bovine cerebellum. Far-u.v. c.d. properties are consistent with a random form of seminalplasmin in aqueous solution; 23% alpha-helix is induced on interaction with calmodulin. The fluorescence properties of the single tryptophan residue of seminalplasmin are markedly changed on formation of the complex. These studies allowed us to locate tentatively the peptide segment that interacts with calmodulin, and to ascertain the structural homology between seminalplasmin and other calmodulin-binding peptides. Additional material, showing the inhibition of calmodulin-mediated activation of bovine brain phosphodiesterase by melittin and seminalplasmin and also the near-u.v. spectrum of affinity-purified seminalplasmin, has been deposited as supplement SUP 50135 (4 pages) at the British Library Lending Division, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies may be obtained on the terms indicated in Biochem. J. (1986) 233, 5.     

Interaction of calmodulin with myosin light chain kinase and cAMP-dependent protein kinase in bovine brain

Myosin light chain kinase and a fraction of type II cAMP-dependent protein kinase have been partially purified from bovine brain by affinity chromatography on calmodulin-Sepharose. The myosin kinase was purified approximately 3700-fold and has an estimated molecular weight of 130,000 +/- 10,000 by sodium dodecyl sulfate gel electrophoresis. A fraction of soluble cAMP-dependent protein kinase also bound to calmodulin-Sepharose and was purified 2300-fold. A fraction of this cAMP-dependent protein kinase after purification by glycerol gradient centrifugation was shown to contain the two subunits of calcineurin, a major calmodulin-binding protein in brain, and the two subunits of type II cAMP-dependent protein kinase in a ratio of 1:1:2:2. Its sedimentation coefficient was 8.1 S and 9.0 S when centrifuged in the absence or presence of calmodulin, suggesting the formation of a complex between calmodulin and protein kinase. Our results suggest the possibility that calcineurin may be involved in the interaction between the protein kinase and calmodulin. Furthermore, our studies imply that the regulatory subunit of the cAMP-dependent protein kinase, but not the catalytic subunit, is the site of interaction with calmodulin since the catalytic subunit of protein kinase was partially resolved from the complex by cAMP.     

Identification of an atypical calcium-dependent calmodulin binding site on the C-terminal domain of GluN2A

N-methyl-d-aspartate (NMDA) receptors are calcium-permeable ion channels assembled from four subunits that each have a common membrane topology. The intracellular carboxyl terminal domain (CTD) of each subunit varies in length, is least conserved between subunits, and binds multiple intracellular proteins. We defined a region of interest in the GluN2A CTD, downstream of well-characterized membrane-proximal motifs, that shares only 29% sequence similarity with the equivalent region of GluN2B. GluN2A (amino acids 875–1029) was fused to GST and used as a bait to identify proteins from mouse brain with the potential to bind GluN2A as a function of calcium. Using mass spectrometry we identified calmodulin as a calcium-dependent GluN2A binding partner. Equilibrium fluorescence spectroscopy experiments indicate that Ca²⁺/calmodulin binds GluN2A with high affinity (5.2 ± 2.4 nM) in vitro. Direct interaction of Ca²⁺/calmodulin with GluN2A was not affected by disruption of classic sequence motifs associated with Ca²⁺/calmodulin target recognition, but was critically dependent upon Trp-1014. These findings provide new insight into the potential of Ca²⁺/calmodulin, previously considered a GluN1-binding partner, to influence NMDA receptors by direct association.     

Hydrophobic-interaction chromatography and anion-exchange chromatography in the presence of acetonitrile. A two-step purification method for human prolactin

Described is a two-chromatographic-step preparative-scale technique for the purification of human prolactin from a frozen pituitary homogenate. The method utilizes hydrophobic interaction chromatography on the mildly hydrophobic adsorbent phenyl-Sepharose CL-4B and anion-exchange chromatography on DEAE-cellulose in the presence of acetonitrile. Human prolactin was solubilized at pH10.0 after a prior extraction of pituitaries at pH4.0, the acid pH being ineffective at solubilizing human prolactin but capable of solubilizing large amounts of interfering protein. An 11-fold increase in the potency of the solubilized human prolactin was achieved in this manner. Prolactin could be adsorbed to phenyl-Sepharose at low ionic strengths (I<0.01); few other proteins were adsorbed under these conditions. This is a demonstration of the hydrophobic nature of human prolactin. The amount of phenyl-Sepharose was limited to the minimum (35mg of protein/g of phenyl-Sepharose) necessary to adsorb human prolactin, further reducing the uptake of other pituitary protein. Desorption was achieved by using an acetonitrile gradient (0–30%, v/v), resulting in a purification of human prolactin of 85-fold and recovery of 78%. Acetonitrile (20%, v/v) was also included in all buffers for DEAE-cellulose chromatography, increasing the resolution and recovery of human prolactin, apparently by minimizing non-ionic interactions with the matrix. Prolactin (10mg) was recovered from 63g if pituitaries, an overall recovery of 58%. It was homogeneous by gel filtration and sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, contained less than 0.1% somatotropin (growth hormone), on iodination demonstrated more than 95% binding to excess anti-(human prolactin) serum and could be displaced from anti-(human prolactin) serum in a manner indistinguishable from the serum of a patient with a human prolactin-secreting adenoma.     

Calcium-dependent hydrophobic chromatography of calmodulin, S-100 protein and troponin-C

We have demonstrated calcium-dependent hydrophobic interactions among calmodulin, S-100 protein and troponin-C and a homologous series of omega-aminoalkyl-agaroses. The three Ca2+-binding proteins were retained on the column of agarose substituted with omega- aminooctyl or even longer with alkylamine, in the presence of Ca2+ and 0.15 M NaCl. As these proteins were not retained on the column with shorter alkylamine 'arms' (N = 2, 4), they are probably successively absorbed with a higher affinity to the hydrophobic agarose column. Calmodulin and S-100 protein were eluted from the aminoocytl -agarose column with 1 mM EGTA in the presence of 0.15 M NaCl and the elution of troponin-C was Ca2+-independently carried out with 0.3 M NaCl. On the other hand, S-100 and troponin-C were eluted Ca2+-dependently from aminodecyl -agarose in the presence of 1 M NaCl and half the amount of the calmodulin applied was eluted with 1 M NaCl. As there are obvious differences among the three Ca2+-binding proteins with regard to chromatographic behavior on omega-aminoalkyl-agarose columns, our results suggest that these three proteins expose different hydrophobic regions following Ca2+-induced conformational changes and, if so, such would explain the interaction with aminoalkyl-agaroses.