Calcium effects on calmodulin lysine reactivities

The differential reactivities of individual lysines on porcine testicular calmodulin were determined by trace labeling with high specific activity [3H]acetic anhydride as a function of the molar ratio of Ca2+ to calmodulin. In progressing from the Ca2+-depleted form of the protein to a Ca2+:calmodulin molar ratio of 5:1, six of the seven lysyl residues exhibited a modest 1.5- to 3.0-fold increase in reactivity. Lys 75, in contrast, was enhanced in reactivity greater than 20-fold. When the change in reactivity of each lysine was normalized as a percentage of the maximum change, most of the residues were found to fall into two distinct classes. One class, comprising lysines 94 and 148 from the two carboxy terminal Ca2+-binding domains 3 and 4, respectively, exhibited about 90% of their reactivity change when the Ca2+:calmodulin molar ratio was 2:1, and these residues were perturbed very little upon further addition of Ca2+. The other class, encompassing lysines 13, 21, and 30 from the amino terminal domain 1 and Lys 75 from the extended helix connecting the two globular lobes of calmodulin, underwent most of their overall reactivity change (55-70%) between 2 and 5 equivalents of Ca2+ per mol of calmodulin. Lys 77 was distinct in its pattern of change, undergoing approximately equal changes with each Ca2+ increment. These results are consistent with a model where Ca2+ first binds to the two carboxy terminal sites of calmodulin with no apparent preference, concomitant with minor alterations in the microenvironments of lysines in the unoccupied amino terminal domains. The third and fourth Ca2+ ions then bind to these latter two domains, again with no evidence of preference, with little change in the lysine reactivities at the carboxy terminus of the molecule. The environments of groups in the central helix appear to undergo changes in a manner that reflects their proximity to the amino and carboxy terminal domains. In the course of this work, it was found that Lys 94 in apocalmodulin is specifically perturbed by the addition of EGTA, suggesting that the chelating agent may interact with calmodulin at or near the third Ca2+-binding domain.     

Specific acylation of calmodulin. Synthesis and adduct formation with a fluorenyl-based spin label

The spin-labeling reagent, N4-(9'-fluorenylmethyloxycarbonyl)-4-amino-1-oxyl-4-succinimidyloxyca rbonyl- 2,2,6,6-tetramethylpiperidine, and the same enriched in 14C at the 4-formyl group, were synthesized as new acylating compounds for protein amino groups that can preserve charge. Porcine testicular calmodulin was modified with this reagent at pH 7.8 in the presence of Ca2+ under conditions that yielded a fairly homogeneous derivative as judged by electrophoretic analysis and tryptic digestion patterns. The tryptic peptides were separated by gel filtration and reverse-phase high-performance liquid chromatography, and the resulting, highly purified 14C-labeled peptides were hydrolyzed and their amino acid compositions determined. The results indicate that at least 87% of the modifications occur at lysyl residues 75 and 148, and the former appears to be the most reactive. This bilabeled calmodulin adduct does not activate a bovine brain cyclic nucleotide phosphodiesterase preparation. The fluorenylmethyloxycarbonyl portion of this inactive calmodulin derivative can, however, be removed by conditions that do not diminish native calmodulin activity in the phosphodiesterase assay. The resulting calmodulin adduct is active in the enzymic assay, although with diminished potency compared to calmodulin. The specificity of the reaction of this acylating reagent with calmodulin may be due to recognition of the tricyclic fluorene ring by the phenothiazine-binding sites since it was found that trifluoperazine inhibited the labeling reaction. Also, calmodulin was far more reactive to this reagent than were several other proteins. This is the first report of a specific, characterized lysine modification on calmodulin, and it is possible that other phenothiazine-binding proteins may also exhibit similar selectivity for acylation. Electron paramagnetic resonance spectra of the calmodulin adducts suggest a high degree of spin immobilization in both the Ca2+-free and Ca2+-saturated states.     

Calmodulin is labeled at lysine 148 by a chemically reactive phenothiazine

10-(3-Propionyloxysuccinimide)-2-(trifluoromethyl)phenothiazine (POS-TP) is a chemically reactive calmodulin antagonist: 2 mol are incorporated per mol of calmodulin when excess reagent is used, and only lysyl side chains are modified. Tryptic peptide mapping demonstrated that a single unique site on calmodulin reacts at low molar ratios of POS-TP. Labeled peptides were isolated and analyzed by amino acid composition and sequence analysis. The unique site was identified as Lys148 of calmodulin, the carboxyl-terminal residue. At higher molar ratios of the reagent Lys21, Lys75, and Lys77 are labeled as are several minor peptides that were not characterized.     

Phenothiazine-binding and attachment sites of CAPP1-calmodulin

In the presence of Ca2+ norchlorpromazine isothiocyanate forms a monocovalent complex with calmodulin: CAPP1-calmodulin (Newton et al, 1983). Trypsin digestion of [3H]CAPP1-calmodulin yields as the major radioactive peptide N epsilon-CAPP-Lys-Met-Lys, corresponding to residues 75-77 of calmodulin. Stoichiometric amounts of all other expected tryptic peptides are also found, indicating that norchlorpromazine isothiocyanate selectively acylates Lys 75. A second molecule of CAPP-NCS can react, albeit slowly, with calmodulin to form CAPP2-calmodulin. Fragments 38-74 and 127-148 are completely missing from the trypsin digests of CAPP2-calmodulin without deliberate exposure to UV irradiation. Possibly the lengthy preparation of CAPP2-calmodulin favors photolysis, caused by room lights, of the putative CAPP-binding domains located in these two peptides. Lys 148, the sole lysyl residue in fragment 127-148, is a probable site of attachment of the second molecule of CAPP. UV irradiation of CAPP1-calmodulin, followed by digestion with trypsin, results in the selective loss of 50% each of peptides containing residues 38-74 and 127-148, suggesting that these peptides contain the hydrophobic amino acids that form the phenothiazine-binding sites. The loss of peptides encompassing residues 38-74 and 127-148, located in the amino and carboxyl halves of calmodulin, respectively, suggests that the hydrophobic rings of CAPP can bind at either one of the two phenothiazine sites. Computer modeling of CAPP1-calmodulin with the X-ray coordinates of calmodulin (Babu et al., 1986) indicates that CAPP attached to Lys 75 cannot interact with the carboxyl-terminal phenothiazine-binding site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of modifying individual amino or carboxyl groups on the affinity of calmodulin for calcineurin

The effects of modifying individual lysyl, aspartyl, or glutamyl residues in calmodulin on its ability to bind to the neural phosphatase calcineurin have been investigated using a competitive binding method termed "label selection." Samples of calmodulin were radiochemically labeled at a low level (0.03-0.6 group/molecule) by acetylation of amino groups or coupling carboxyl groups with ethanolamine to produce preparations containing predominantly single-site modified and unmodified molecules. These preparations were incubated in a 5-10-fold molar excess with bovine calcineurin under conditions appropriate for complex formation. The bound population was isolated, and the level of modification of each reactive residue was compared with the level in the corresponding group in the intial unselected preparation to determine if molecules modified at specific sites had been selected for or against during the competition for complex formation. Significant selection was observed against molecules modified at Lys21, Asp64, Glu67, Lys75, Glu84, Glu114, Asp118, or Lys148, whereas modification of Glu83 increased binding. The modification of other groups, including components of the four Ca2+-binding sites, had no effect on the interaction. Glu67, a Ca2+-liganding residue in Ca2+-binding site II that may regulate the orientation of this site in relation to the central helix, had the strongest influence on complex formation. Most of the residues identified form a nearly linear array in the three-dimensional structure of calmodulin and indicate the location of an extended surface for interaction with calcineurin and other enzymes.     

Differential reactivities of lysines in calmodulin complexed to phosphatase

Calmodulin and calmodulin complexed with calcineurin phosphatase were trace labeled with [3H]acetic anhydride and the incorporation of [3H]acetate into each epsilon-amino lysine of calmodulin was measured. The relative reactivities of calmodulin lysines were higher in the presence of Ca2+ than in the presence of EGTA, and the order was: Lys-75 greater than Lys-94 greater than Lys-148 greater than or equal to Lys-77 greater than Lys-13 greater than or equal to Lys-21 greater than Lys-30. The changes in relative reactivity implied a change in conformation. When calmodulin was complexed with the phosphatase, Lys-21, Lys-77, and Lys-148 were most protected, implying that these residues are at or near the interaction sites or are conformationally perturbed by the interaction. Lys-30 and Lys-75 were slightly protected, lysine 13 showed no change, while lysine 94 significantly increased in reactivity. Comparison with results obtained from myosin light chain kinase using a similar technique (Jackson, A. E., Carraway, K. L., III, Puett, D., and Brew, K. (1986) J. Biol. Chem. 261, 12226-12232) reveals that calmodulin may interact with each of the two enzymes similarly at or near Lys-21, Lys-75, and Lys-148; one difference with phosphatase is that complex formation also involved Lys-77. These findings suggest that calmodulin interacts differently with its target enzymes.     

Stimulation of the purified erythrocyte Ca2+-ATPase by tryptic fragments of calmodulin

Highly purified tryptic peptides of calmodulin have been obtained by high-performance liquid chromatography. Tryptic cleavage of calmodulin in the presence of Ca2+ results in two main fragments which have been identified by analysis of the amino acid composition as 1-77 and 78-148. In the absence of Ca2+, trypsin cleavage yields fragments 1-106, 1-90, and 107-148. Only fragments 78-148 and 1-106 are still able to stimulate the purified Ca2+-ATPase of erythrocytes, albeit much less efficiently on a molar basis, than intact calmodulin. On the other hand, the same fragments were unable to stimulate the calmodulin-dependent cyclic nucleotide phosphodiesterase, even at 1000-fold molar excess (shown also by Newton, D.L., Oldewurtel, M.D., Krinks, M.H., Shiloach, J., and Klee, C.B. (1984) J. Biol. Chem. 259, 4419-4426). This points to the importance of the carboxyl-terminal half of calmodulin and especially of Ca2+-binding region III in the interaction of calmodulin with the Ca2+-ATPase and provides clear evidence that calmodulin interacts differently with different targets. Oxidation of methionine(s) of fragment 78-148 with N-chlorosuccinimide removes the ability of this fragment to stimulate the ATPase.     

Association of calmodulin and smooth muscle myosin light chain kinase: application of a label selection technique with trace acetylated calmodulin

A method is described for rapidly surveying the effects of modifying individual amino acid residues of a protein on its ability to interact specifically with another macromolecule. The procedure has been used to examine the individual roles of the seven lysyl residues of calmodulin in its ability to bind to smooth muscle myosin light chain kinase; previous studies by Jackson et al. (J. Biol. Chem. 261:1226-12232, 1986) have suggested that certain lysines may be located close to the interaction site. Trace [3H]-acetylated calmodulin, consisting predominantly of molecules acetylated at single sites together with unmodified protein, was incubated in excess (five- to 20-fold) with smooth muscle MLC kinase to allow the modified and unmodified molecules to compete for binding to the enzyme. Subsequently, the calmodulin-enzyme complex was separated from unbound calmodulin, and the level of acetylation of each of the seven lysines of the bound fraction of calmodulin was determined and compared to that of each corresponding group of the starting preparation. Significant changes were found at only two of the lysines, 21 and 75, where the extent of acetylation in the bound fraction was three- and fivefold lower, respectively, than that in the original preparation. These results were reproducible in three separate selection experiments employing both chicken and turkey gizzard MLC kinase. It is concluded that acetylation of calmodulin at either lysine 21 or 75 markedly reduces its affinity for MLC kinase, but acetylation at any of the other lysines (13, 30, 77, 94, or 148) has only minor effects.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of the Binding and Inhibition Sites in the Calmodulin Molecule for Ophiobolin A by Site-Directed Mutagenesis

Ophiobolin A, a fungal toxin that affects maize and rice, has previously been shown to inhibit calmodulin by reacting with the lysine (Lys) residues in the calmodulin. In the present study we mutated Lys-75, Lys-77, and Lys-148 in the calmodulin molecule by site-directed mutagenesis, either by deleting them or by changing them to glutamine or arginine. We found that each of these three Lys residues could bind one molecule of ophiobolin A. Normally, only Lys-75 and Lys-148 bind ophiobolin A. Lys-77 seemed to be blocked by the binding of ophiobolin A to Lys-75. Lys-75 is the primary binding site and is responsible for all of the inhibition of ophiobolin A. When Lys-75 was removed, Lys-77 could then react with ophiobolin A to produce inhibition. Lys-148 was shown to be a binding site but not an inhibition site. The Lys-75 mutants were partially resistant to ophiobolin A. When both Lys 75 and Lys-77 or all three Lys residues were mutated, the resulting calmodulins were very resistant to ophiobolin A. Furthermore, Lys residues added in positions 86 and/or 143 (which are highly conserved in plant calmodulins) did not react with ophiobolin A. None of the mutations seemed to affect the properties of calmodulin. These results show that ophiobolin A reacts quite specifically with calmodulin.     

Agonist and antagonist properties of calmodulin fragments

Limited proteolysis of calmodulin with trypsin in the presence of ethylene glycol bis(beta-aminoethyl ether)-N, N,N',N'-tetracetic acid (EGTA) or Ca2+ was performed according to a modification of the method of Drabikowski et al. (Drabikowski, W., Kuznicki, J., and Grabarek, Z. (1977) Biochim. Biophys. Acta 485, 124-133). The resulting peptides were purified by reverse-phase high performance liquid chromatography. Tryptic digests in EGTA yielded peptides 1-106, 1-90, and 107-148 with yields of 9, 47, and 61%, respectively. The digests performed with Ca2+ yielded peptides 1-77 and 78-148 in 35 and 45% yield. Analysis by high performance liquid chromatography indicated that the purified fragments contained less than 0.1% contamination by calmodulin, thus allowing a definitive study of the ability of these fragments to activate, or interact with, calmodulin-regulated enzymes and anti-calmodulin drugs. Each of the fragments, except 107-148, bound to a phenothiazine affinity column in a Ca2+-dependent manner. Thus, calmodulin contains two interaction sites for phenothiazines: one on the NH2-terminal half (fragment 1-77) and one on the COOH-terminal half (fragment 78-148). None of the fragments activates the protein phosphatase, calcineurin, or prevents its stimulation by calmodulin, nor does any of the fragments stimulate Ca2+-dependent cAMP phosphodiesterase. A single cleavage in the middle of the calmodulin molecule results in the rapid dissociation of the two resultant fragments and a loss of ability to activate cAMP phosphodiesterase. One fragment, 78-148, interacts with phosphodiesterase and prevents its activation by calmodulin (Ki: 1.5 +/- 0.4 X 10(-6) M). The same fragment, 78-148, can fully activate phosphorylase kinase but with a lower affinity than calmodulin (Kuznicki, J., Grabarek, Z., Brzeska, H., Drabikowski, W., and Cohen, P. (1981) FEBS Lett. 130, 141-145). Thus, peptide 78-148 behaves as a calmodulin agonist or antagonist or as neither, depending on the enzyme under study.     

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.     

Carbon-13 NMR studies of the lysine side chains of calmodulin and its proteolytic fragments

ThepH-titration and dynamic behaviour of the seven lysine side chains in bovine calmodulin were studied by carbon-13 NMR. The amino groups of the calcium saturated protein and its proteolytic fragments TR₁C(1–75) and TR₂C (78–148) were dimethylated with carbon-13 labeled formaldehyde; this modification did not alter the protein's structure or its ability to activate the enzyme cyclic nucleotide phosphodiesterase. Tentative assignments for 5 out of the 7 dimethyl lysine resonances could be obtained by comparing spectra of the fully and partially modified protein, with those of the proteolytic fragments. ThepK_a values measured for calcium saturated calmodulin ranged between 9.5 (Lys 75) and 10.2 (Lys 13); two residues (Lys 94 and Lys 13) showed a biphasic titration curve suggesting their possible involvement in ion-pairs. The dynamic behavior of the lysine side chains was deduced from spin lattice relaxation measurements. All side chains were flexible and this was not influenced by the removal of calcium, or the addition of the calmodulin antagonist trifluoperazine. The latter data suggest that the lysine side chains are not directly involved in calmodulin's target binding sites.     

Calmodulin, a ganglioside-binding protein. Binding of gangliosides to calmodulin in the presence of calcium.

Ca(2+)-dependent ganglioside-binding protein was isolated from a soluble cytosol fraction of mouse brains using a ganglioside affinity column prepared with a mixture of bovine brain gangliosides. It was identified as calmodulin based on the following features identical with those of calmodulin: molecular weight, pI, chromatographic profile and amino acid sequences of lysyl-endopeptidase digests, and ability to activate cyclic nucleotide phosphodiesterase. Bovine brain calmodulin derivatized with 5-dimethylaminonaphthalene-1-sulfonyl (dansyl-calmodulin), tetramethylrhodamine isothiocyanate, or biotin was also shown to bind to the ganglioside affinity column Ca2+ dependently and elute with gangliosides GD1a, GD1b, GT1b, GQ1b, GM1, and GM2, melittin, and trifluoperazine but not with GgOse4Cer and oligosaccharides of GM1, GD1a, and GT1b. Modification of the Lys94 residue of calmodulin by biotinylation drastically reduced the capacity for ganglioside binding. Ganglioside GD1b caused a blue shift and increase in intensity of the fluorescence emission spectrum of dansyl-calmodulin in the presence of Ca2+. The increment in fluorescence was proportional to the amount of GD1b added and was maximal at the molar ratio of GD1b to calmodulin, approximately 7.8. Gangliosides are thus shown to specifically bind to calmodulin, and this binding may be a general mechanism for regulating calmodulin-dependent enzymes with consequent cellular response, such as cell differentiation.     

Localization of a felodipine (dihydropyridine) binding site on calmodulin

The fluorescent dihydropyridine calcium antagonist drug felodipine binds to calmodulin (CaM) in a Ca2+-dependent manner. Its binding can be regulated by the interaction of CaM antagonist drugs through allosteric mechanisms [Mills, J.S., & Johnson, J.D. (1985) Biochemistry 24, 4897]. Here, we have examined the binding of a nonspecific hydrophobic fluorescent probe molecule TNS (toluidinylnaphthalenesulfonate) and of felodipine to CAM and several of its proteolytic fragments. While TNS interacts with sites on both the amino-terminal half of the protein [proteolytic fragment TR1C (1-77)] and carboxy-terminal half [proteolytic fragment TR2C (78-148)], felodipine binding shows more selectivity. It binds in a Ca2+-dependent manner to the proteolytic fragments TM1 (1-106) and TR2E (1-90) but exhibits only weak affinity for TR1C (1-77) and TR2C (78-148). Furthermore, felodipine exhibits selectivity over TNS and trifluoperazine (TFP) in blocking the tryptic cleavage between residues 77 and 78. These studies indicate a selective binding of felodipine to a hydrophobic site existing in residues 1-90 and suggest that productive binding requires amino acids in the region 78-90. Although the felodipine binding site is preserved in fragment 1-106, the allosteric interactions between the prenylamine and the felodipine binding sites that are observed with intact CaM are not observed in this fragment. Rather, prenylamine simply displaces felodipine from its binding site on this fragment. Our results are consistent with calmodulin containing not less than two allosterically related hydrophobic drug binding sites. One of these sites (felodipine) appears to be localized in region 1-90 and the other one in region 78-148.     

Effects of interaction with calcineurin on the reactivities of calmodulin lysines

Calmodulin was trace labeled by acetylation with [3H]acetic anhydride in the presence and absence of a 30% molar excess of the phosphatase calcineurin; phenylalanine was included in the reaction mixtures as an internal standard. The level of 3H acetylation of each of the 7 lysines was determined and corrected for differences arising from reaction conditions using the labeling of the internal standard, following procedures that are closely similar to those used in a previous study of the interaction of calmodulin with myosin light chain kinase (Jackson, A. E., Carraway, K. L., III, Puett, D., and Brew, K. (1986) J. Biol. Chem. 261, 12226-12232). The interaction with calcineurin was found to produce a 10-fold reduction in the acetylation of lysine 75, with lesser but significant effects on lysines 21 and 148. A small but reproducible perturbation of lysine 77 was also observed. The results are similar to those that are produced by the interaction with myosin light chain kinase. However, when they are compared with two recent reports between which there are major discrepancies (Manalan, A. S., and Klee, C. B. (1987) Biochemistry 26, 1382-1390; Winkler, M. A., Fried, V. A., Merat, D. L., and Cheung, W. Y. (1987) J. Biol. Chem. 262, 15466-15471), our results are in good agreement with those obtained in the former study. From the location of the perturbed groups in the three-dimensional structure of calmodulin, it appears that the interaction site on calmodulin for calcineurin, as well as for myosin light chain kinase, is very extended and may include hydrophobic pockets at homologous sites near the carboxyl-terminal ends of the two halves of the molecule.     

Effects of the binding of myosin light chain kinase on the reactivities of calmodulin lysines

The effects of the binding of smooth muscle myosin light chain (MLC) kinase on the microenvironments of different regions of calmodulin (CaM) were investigated by comparing the acylation rate constants of the seven lysine amino groups of free CaM with those of CaM complexed with MLC kinase. Equimolar amounts of CaM and CaM-MLC kinase complex were trace labeled with [3H]acetic anhydride in the presence of phenylalanine as a standard nucleophile. After completion of the reaction, equal amounts of a trace 14C-acetylated CaM sample, together with [14C]acetylphenylalanine, were added to each reaction mixture. The 3H/14C-labeled CaM and acetylphenylalanine were then isolated from each solution. After complete reaction with nonradioactive acetylating reagent, 3H/14C ratios (r) were determined for each epsilon-N-acetyllysine in the two CaM samples. These values were obtained either from isolated peptide fragments containing one lysine or from epsilon-N-acetyl phenylthiohydantoin lysine obtained by Edman degradation of peptide fragments containing two lysines. From the ratios, protection factors (= rfree/rcomplex) were determined as a measure of the perturbation produced by MLC kinase binding. These protection factors were corrected, using the isotope ratios of the internal standard, for differences in the degree of competition for labeling reagent between the two mixtures. In two separate labeling experiments employing different levels of trace labeling, very little change was observed in the reactivities of four lysines on MLC kinase binding (lysines 13, 30, 77, and 94). Small but reproducible decreases (about 2-fold) were observed in the reactivities of lysines 21 and 148, while lysine 75 underwent a major (more then 7-fold) decrease in labeling. In conjunction with previously published data, these results are interpreted as suggesting that the major perturbation in lysine 75 is a direct effect of MLC kinase contact with CaM and that a region in the central helix containing this residue, but not lysine 77, represents or is near the CaM-binding site for MLC kinase. The smaller changes in reactivities at lysines 21 and 148 may reflect a conformational change that occurs in CaM as a result of binding to MLC kinase.     

Ca2+-dependent protein phosphorylation associated with microsomal fraction of rat pancreas

Microsomes isolated from cat pancreas were incubated with [gamma-32P]ATP in the presence or absence of Ca2+. Following fractionation of phosphoproteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis a single microsomal protein with an apparent molecular mass of 77,000 dalton (77K) was found to be phosphorylated in a Ca2+-dependent mechanism. Maximal phosphate incorporation into the 77K protein was observed at 10(-6) mol/l [Ca2+] and was 4-fold higher than in the absence of Ca2+. The 77K phosphoprotein showed characteristic of a stable phosphoester rather than an acyl phosphate. Measurable phosphate incorporation into the 77K protein was noted 5 s following addition of [gamma-32P]ATP and reached maximum at 9-10th min. The lack of effect of exogenous cyclic AMP, cyclic AMP-dependent protein kinase, calmodulin, the calmodulin antagonist trifluoperazine, leupeptin and the suppression of phosphorylation by some phospholipid-interacting drugs suggested that the 77K protein is a substrate for cyclic AMP- and calmodulin-independent, Ca2+-activated phospholipid-sensitive kinase activity. Centrifugation of the pancreatic homogenate in a ficoll-sucrose density gradient indicated that both the 77K protein and enzyme were associated in a fraction enriched in rough endoplasmic reticulum.     

Effect of trifluoperazine, compound 48/80, TMB-8 and verapamil on the rate of calmodulin binding to erythrocyte Ca2+-ATPase

The erythrocyte Ca2+-ATPase shifts reversibly between two states, the calmodulin-deficient A-state and the calmodulin-saturated B-state, dependent on calcium and calmodulin. The effects on this system of the four drugs, trifluoperazine, compound 48/80, TMB-8 and verapamil were studied. All four drugs inhibited the maximum activity of the B -state Ca2+-ATPase and, in addition, trifluoperazine and compound 48/80 in higher doses inhibited the A-state. Furthermore, the four drugs decreased the calmodulin sensitivity of the Ca2+-ATPase in the order of decreasing effect: trifluoperazine greater than compound 48/80 greater than TMB-8 greater than verapamil. In the same order of decreasing effect the drugs increased the time required for full calmodulin activation of the A-state of Ca2+-ATPase, whereas the drugs had only small effects on the rate of deactivation of the B-state, caused by dissociation of calmodulin from the enzyme. It is discussed whether the effects on calmodulin activation were caused by a reduction of free calmodulin due to the formation of drug-calmodulin complexes or whether the drugs, especially trifluoperazine, compound 48/80 and TMB-8, by binding to the Ca2+-ATPase, decreased the rate constants for association of calmodulin and enzyme.     

Amino group environments and metal binding properties of carbon-13 reductively methylated bovine alpha-lactalbumin

13C NMR spectroscopy has been used to study the amino group environments and metal binding properties of 13C reductively methylated bovine alpha-lactalbumin. Bovine alpha-lactalbumin is a Ca2+ metalloprotein containing 12 lysyl amino groups and a free amino terminus. All 13 amino groups can be 13C-dimethylated without altering Ca2+ binding or biological activity. pH titrations (chemical shift vs. pH) of this dimethylated protein reveal unique behavior for each of the 13 amino groups. The pKa values for the lysyl amino groups range from 9.1 to 10.8 while the pKa for the N-terminal amino group is 8.3. This relatively high pKa (by 1 pH unit) for the N-terminal supports its interaction in an ion pair as proposed by Warme et al. [Warme, P. K., Momany, F. A., Rumball, S. V., Tuttle, R. W., & Scheraga, H. A. (1974) Biochemistry 13, 768-782]. Carbon-13 NMR studies further show that the removal of Ca2+ from the high-affinity binding site results in a conformational change, with the disruption of the N-terminal ion pair interaction (pKa decreased to 7.4). The study of Zn2+ binding to Ca2+-saturated protein suggests that Zn2+ binds initially at a low-affinity Ca2+ site while maintaining the N-terminal ion pair interaction. The further addition of Zn2+ leads to the disruption of this ion pair forming a presumed apoprotein-like conformation. Finally on the basis of the specific effects of added Mn2+ on the 13C NMR spectra of the methylated protein, a low-affinity divalent metal binding site is proposed about 7.5 A from the amino terminus.     

The Ca2+-pumping ATPase of heart sarcolemma. Characterization, calmodulin dependence, and partial purification

The (Ca2+ + Mg2+) ATPase of dog heart sarcolemma (Caroni, P., and Carafoli, E. (1980) Nature 283, 765-767) has been characterized. The enzyme possesses an apparent Km (Ca2+) of 0.3 +/- 02 microM, a Vmax of Ca2+ transport of 31 nmol of Ca2+/mg of protein/min, and an apparent Km (ATP) of 30 microM. It is only slightly influenced by monovalent cations and is highly sensitive to orthovanadate (Ki = 0.5 +/- 0.1 microM). The high vanadate sensitivity has been used to distinguish the sarcolemmal and the contaminating sarcoplasmic reticulum Ca2+-dependent ATPase in heart microsomal fractions. Calmodulin has been shown to be present in heart sarcolemma. Its depletion results in the transition of the Ca2+-pumping ATPase to a low Ca2+ affinity; readdition of calmodulin reverses this effect. The Na+/Ca2+ exchange system was not affected by calmodulin. The results of calmodulin extraction can be duplicated by using the calmodulin antagonist trifluoperazine. The calmodulin-depleted Ca2+-ATPase has been solubilized from the sarcolemmal membrane and "purified" on a calmodulin affinity chromatography column. One major (Mr = 150,000) and 3 minor protein bands could be eluted from the column with ethylene glycol bis(beta-aminoethyl ether)N,N,N',N'-tetraacetic acid (EGTA). The major protein band (72%) has Ca2+-dependent ATPase activity and can be phosphorylated by [gamma]32P]ATP in a Ca2+-dependent reaction.