Hepatic microsomal Ca2+-dependent ATPase. Calmodulin-dependence and partial purification.

The hepatic microsomal fraction contains tightly bound calmodulin as demonstrated by affinity chromatography. When this calmodulin was partially removed by EGTA treatment (0.5 mM-EGTA), the uptake of 45Ca2+ by the microsomal vesicles was stimulated by added calmodulin and inhibited by trifluoperazine (TFP). The Ca2+-dependent ATPase was partially purified on a calmodulin column. This partial purification resulted in a 500-fold increase in the specific activity of the enzyme when measured in the presence of added calmodulin. Antibodies prepared against calmodulin prevented this stimulatory effect. The fraction eluted from the calmodulin column contained several protein bands indicating that the specific activity of the Ca2+-dependent ATPase is probably still underestimated. There are likely to be other calmodulin-sensitive processes present in the hepatic microsomal fraction.     

Calmodulin N-methyltransferase. Partial purification and characterization

The distribution, properties, and substrate specificity of S-adenosylmethionine:calmodulin (lysine) N-methyltransferse (EC 2.1.1.60, calmodulin N-methyltransferase) of the rat have been studied. This enzyme is cytosolic and is found at high levels in tissues with high levels of calmodulin and at low levels in tissues with little calmodulin. In liver, heart, and skeletal muscle, which have low levels of calmodulin and very low calmodulin N-methyltransferase activity (a low ratio of calmodulin N-methyltransferase to calmodulin), calmodulin was found to be incompletely methylated, as judged by its ability to act as a substrate for purified calmodulin N-methyltransferase. Calmodulin N-methyltransferase was purified 470-fold with a 33% yield from rat testis cytosol, using ammonium sulfate precipitation and chromatography on DEAE-cellulose, CM-Sepharose, and Sephadex G-100. At pH 7.4, calmodulin N-methyltransferase did not bind to DEAE-cellulose, but bound strongly to CM-Sepharose. The enzyme eluted from Sephadex G-100 with an apparent molecular weight of 55,000. Purified calmodulin N-methyltransferase was incubated with extracts of rat tissues, and [methyl-3H]AdoMet and methylated proteins were resolved by electrophoresis in an attempt to discover substances other than calmodulin, but this enzyme only catalyzed the methylation of calmodulin, indicating a high degree of substrate specificity. Conditions were established for the in vitro preparative methylation of des(methyl)-calmodulin from Dictyostelium discoideum. Three moles of methyl/mol of calmodulin were incorporated into lysine 115 of des(methyl)calmodulin, resulting in the formation of 1 mol of trimethyllysine at the site normally methylated in calmodulins from most species. Activation of cyclic nucleotide phosphodiesterase by des(methyl)calmodulin was indistinguishable from activation by in vitro methylated or sham methylated Dictyostelium calmodulin, indicating that methylation does not affect the ability of calmodulin to activate this enzyme.     

Calmodulin. Production of an antibody in rabbit and development of a radioimmunoassay.

Calmodulin, a heat-stable Ca2+-binding protein (Mr = 16,700) found in all eukaryotes, is a multifunctional modulator, mediating many of the effects of Ca2+ in cellular functions. The protein was derivatized with 1-fluoro-2,4-dinitrobenzene (DNB) to give 3 mol of DNB/mol of calmodulin (DNB3-calmodulin). The dinitrophenylated protein was almost as active as native calmodulin in stimulating bovine brain Ca2+-dependent phosphodiesterase. Incorporation of the dinitrophenyl groups renders calmodulin highly antigenic in the rabbit; native calmodulin is a weak antigen. Rabbits immunized with DNB3-calmodulin produced specific antibody against both DNB3-calmodulin and calmodulin. Using the immunized serum, a radioimmunoassay was developed for calmodulin, the sensitivity for DNB3-calmodulin and calmodulin being approximately 0.2 and 2 pmol, respectively. Although the sensitivity of the radioimmunoassay for calmodulin is comparable to the enzyme assay of calmodulin with Ca2+-dependent phosphodiesterase, the radioimmunoassay affords the detection of calmodulin on the basis of antigenic determinants, and thus measures calmodulin in terms of polypeptide structure instead of its ability to stimulate an enzyme. Further, the accuracy of the radioimmunoassay is not affected by the presence of a heat-labile inhibitor protein, which affects the enzyme assay to give an apparent underestimation.     

Amino acid sequence of calmodulin from Euglena gracilis.

The complete amino acid sequence of calmodulin from Euglena gracilis was determined by isolation and sequence analyses of peptides derived from calmodulin by digestion with trypsin and Staphylococcus aureus V8 protease. Euglena calmodulin consists of 148 amino acid residues; it lacks tryptophan and cysteine and contains one tyrosine, three histidine and two NE-trimethyllysine residues/molecule of the protein. Its N-terminus was blocked with an acetyl group and C-terminal lysine was trimethylated. Euglena calmodulin is the first calmodulin so far examined in which the C-terminal lysine is trimethylated. The comparison of amino acid sequences between Euglena and human brain calmodulins indicated 17 amino acid substitutions in Euglena calmodulin.     

Calmodulin resolution of multiple peaks of activity by preparative electrofocusing.

When the supernatant fractions from rat brain homogenates were subjected to preparative electrofocusing in a bed of Sephadex G75, several peaks of calmodulin were resolved. A minor peak representing free calmodulin migrated with a pI of 3.8 --4.4. Other peaks of calmodulin activity were observed with isoelectric points at pH 4.8, 5.2, 6.0 and 6.8. The peak of calmodulin activity at 5.2 co-migrated with phosphodiesterase activity which was stimulated 1.8-fold by calcium. A second peak of phosphodiesterase activity detected at pH 8.0 was stimulated 1.2-fold by calcium and occurred in an area where no calmodulin activity could be detected. If isoelectric focusing was done in the presence of 8 M urea only one peak of calmodulin activity was observed with a pI of 4.0--4.4. It is suggested that the multiple peaks of calmodulin resolved by electrofocusing represent calmodulin associated with various proteins which are subject to modulation by calmodulin and calcium.     

Cardiac sarcoplasmic-reticulum calmodulin-binding proteins. Modulation of calmodulin binding to phospholamban by phosphorylation.

The gel-overlay technique with 125I-labelled calmodulin allowed the detection of several calmodulin-binding proteins of Mr 280 000, 150 000, 97 000, 56 000, 35 000 and 24 000 in canine cardiac sarcoplasmic reticulum. Only two calmodulin-binding proteins could be identified unambiguously. Among them, the 97 000-Mr protein that undergoes phosphorylation in the presence of Ca2+ and calmodulin, is likely to be glycogen phosphorylase. In contrast, the (Ca2+ + Mg2+)-activated ATPase did not appear to bind calmodulin under our experimental conditions. The second known calmodulin target is dephosphophospholamban, which migrates with an apparent Mr of 24 000. The dimeric as well as the monomeric form of phospholamban was found to bind calmodulin. Phospholamban shifts the apparent Kd of erythrocyte (Ca2+ + Mg2+)-activated ATPase for calmodulin, suggesting thus a tight binding of calmodulin to the proteolipid. Interestingly enough, phospholamban phosphorylation by either the catalytic subunit of cyclic AMP-dependent protein kinase or the Ca2+/calmodulin-dependent phospholamban kinase was found to inhibit calmodulin binding.     

Function of a calmodulin in postsynaptic densities. III. Calmodulin-binding proteins of the postsynaptic density

A method has been developed for binding calmodulin, radioiodinated by the lactoperoxidase method, to denaturing gels and has been used to attempt to identify the calmodulin-binding proteins of cerebral cortex postsynaptic densities (PSDs). Calmodulin primarily bound to the major 51,000 Mr protein in a saturatable manner; secondarily bound to the 60,000 Mr region, 140,000 Mr region, and 230,000 Mr protein; and bound in lesser amounts to a number of other proteins. The major 51,000 Mr calmodulin-binding protein is one of unknown identity. Binding of iodinated calmodulin to these proteins was blocked by EDTA, EGTA, chlorpromazine, and preincubation with unlabeled calmodulin. Calmodulin iodinated by the chloramine-T method, which inactivates calmodulin did not bind to the PSD but bound nonspecifically to histone. Calmodulin did not bind to proteins from a variety of sources for which calmodulin interactions have not been found. Except for three proteins, all of the proteins of synaptic membranes that bind calmodulin could be accounted for by proteins of the PSD which are a part of the synaptic membrane fraction. The major 51,000 M, protein and the corresponding iodinated calmodulin binding were greatly reduced in cerebellar PSDs and this difference between cerebral cortex and cerebellar PSDs is discussed in light of the possible function of calmodulin in synaptic excitatory responses.     

Brush-border calmodulin. A major component of the isolated microvillus core

Calmodulin is present in brush borders isolated from intestinal epithelial cells and is one of the major components of the microvillar filament bundle. Calmodulin was purified from either demembranated brush borders or microvilli by a simple boiling procedure. The boiled supernate derived from the microvillus cores contained one major polypeptide of 20,000 daltons.The supernate from the brush-border preparation contained the 20,000-dalton subunit and a second protein of 30,000 daltons. The 20,000-dalton subunit has been identified as calmodulin by several criteria: (a) heat resistance, (b) comigration with brain calmodulin on alkaline urea gels and SDS gels, both cases in which the 20,000-dalton protein, like calmodulin, exhibits a shift in electrophoretic mobility in the presence of Ca++, and (c) 4--5-fold activation of 3',5'-cyclic nucleotide phosphodiesterase in the presence but not the absence of Ca++. With a cosedimentation assay it was determined that brush-border calmodulin does not bind directly to actin. In the presence of Ca++ (greater than 5 x 10(-7) M) there was a partial release of calmodulin from the microvillus core, along with a substantial conversion of microvillus actin into a nonpelletable from. The dissociation of calmodulin was reversed by removal of Ca++. If microvillus cores were pretreated with phalloidin, the Ca++-induced solubilization of actin was prevented, but the partial dissociation of calmodulin still occurred. The molar ratio of calmodulin:actin is 1:10 in the demembranated brush border and 1:2-3 in the microvillus core. No calmodulin was detected in the detergent-solubilized brush-border membrane fraction.     

Interaction of calmodulin with troponin I and the troponin-tropomyosin-actin complex. Effect of Ca2+ and Sr2+ ions.

In an effort to elucidate the mechanism of calmodulin regulation of muscle contraction, we investigated the interaction between calmodulin and troponin components in the presence of Ca2+ or Sr2+ by the use of ultracentrifugation methods and polyacrylamide-gel electrophoresis. Skeletal-muscle troponin C bound to troponin I and dissociated it from the tropomyosin-actin complex in the presence of Ca2+ or Sr2+. When troponin T was absent, calmodulin bound to troponin I and dissociated it from the tropomyosin-actin complex in the presence of Ca2+ or Sr2+. When troponin T was present, calmodulin hardly bound to troponin I even in the presence of bivalent cations. Trifluoperazine, a calmodulin antagonist, inhibited the bivalent-cation-dependent interaction between calmodulin and troponin I. Calmodulin migrated more slowly in the presence of Sr2+ than it did in the presence of EGTA but faster than it did in the presence of Ca2+ on polyacrylamide-gel electrophoresis under non-denaturing conditions. It is concluded that troponin T is not required in the calmodulin regulation of muscle contraction because troponin T inhibits the bivalent-cation-dependent interaction between calmodulin and troponin I and because calmodulin binds to troponin I and dissociates it from the tropomyosin-actin complex in a bivalent-cation-dependent manner. Sr2+-induced exposure of the hydrophobic region enables calmodulin to bind to troponin I, as is the case with Ca2+.     

Characterization of the calmodulin binding domain of neuromodulin. Functional significance of serine 41 and phenylalanine 42.

Neuromodulin (also designated P-57, GAP-43, B-50) is a major presynaptic substrate for protein kinase C. Phosphorylation of neuromodulin decreases its affinity for calmodulin, suggesting that neuromodulin may function to bind and concentrate calmodulin at specific sites within neurons, releasing calmodulin locally in response to phosphorylation by protein kinase C (Alexander, K. A., Cimler, B. M., Meier, K. E., and Storm, D. R. (1987) J. Biol. Chem. 262, 6108-6113). In the present study, we have constructed and characterized several mutant neuromodulins to demonstrate that the amino acid sequence 39-56 is required for calmodulin binding, and that this domain contains the sole in vitro protein kinase C phosphorylation site at serine 41. We also demonstrate that the adjacent phenylalanine 42, interacts hydrophobically with calmodulin. These hydrophobic interactions may be disrupted by the introduction of negative charge at serine 41, and thereby regulate the neuromodulin/calmodulin binding interactions. The sensitivity of the neuromodulin/calmodulin binding interaction to negative charge at serine 41 was determined by substitution of serine 41 with an aspartate or an asparagine residue. The asparagine mutant retained its affinity for calmodulin-Sepharose while the aspartate mutant did not adsorb to calmodulin-Sepharose. We conclude that protein kinase C phosphorylation of neuromodulin abolishes calmodulin binding by introducing negative charges within the calmodulin binding domain at a position adjacent to the phenylalanine.     

Mutational analysis of calmodulin in Saccharomyces cerevisiae.

Calmodulin is well characterized as an intracellular Ca2+ receptor in nonproliferating tissues such as muscle and brain. Several observations indicate that calmodulin is also required for cellular growth and division. Deletion of the calmodulin gene is a lethal mutation in Saccharomyces cerevisiae, Schizosaccharomyces pombe and Aspergillus nidulans. Expression of calmodulin antisense RNA in mouse C127 cells causes a transient arrest at G1 and metaphase. Although these results indicate calmodulin plays a critical function during proliferation, they do not reveal the function. S. cerevisiae offers an excellent system for identifying calmodulin functions. Because calmodulin mutants can be readily constructed by gene replacement the consequences of mutations in calmodulin can be directly examined in vivo without interference from wild-type calmodulin. The available wealth of information concerning all aspects of the yeast life cycle provides a large framework for interpretation of new results. The recent dissection of cell cycle regulation is just the latest example of the important insights provided by analyzing basic cellular processes in yeast. Whether studies of calmodulin in yeast will reveal a universal function is unknown. One encouraging result is that yeast cells relying on vertebrate calmodulin as their only source of calmodulin survive and grow well, even if the amount of vertebrate calmodulin is equivalent to the normal steady state levels of yeast calmodulin. This review discusses the varied techniques we are using to identify the functions of calmodulin in yeast. As part of the analysis, we are defining the essential elements of calmodulin structure.     

Calmodulin activation of rat lung adenylate cyclase is independent of the cytoplasmic factors modulating the enzyme.

Adenylate cyclase activity in the rat lung membranes washed with 150 microM-EGTA was stimulated by calmodulin in the presence of 100 microM-Ca2+. The calmodulin activation of the enzyme was concentration-dependent; however, at high concentrations the activation was diminished. Activation of adenylate cyclase by calmodulin was immediate, reversible and due to an increase in the Vmax. without apparent effect on the affinity of the enzyme for ATP. The rat lung supernatant produced additive activation of the adenylate cyclase that was already maximally stimulated by calmodulin, indicating that either calmodulin and cytoplasmic factors act at different sites on adenylate cyclase or different adenylate cyclases may be involved. The data further support our previous conclusion that calmodulin is not involved in the activation of adenylate cyclase by cytoplasmic factors in rat lungs.     

Calmodulin in starfish oocytes. I. Calmodulin antagonists inhibit meiosis reinitiation

A heat-stable factor has been found in starfish (Patiria miniata and Marthasterias glacialis) oocytes that activates two calmodulin-dependent enzymes: bovine brain phosphodiesterase (10-fold increase) and sea urchin egg NAD-kinase (10- to 50-fold increase). The dose-response curves for activation of these enzymes were found to be parallel for the starfish egg extract and pure mammalian brain calmodulin. The active factor was purified by chromatography on DE 52 cellulose to which it remained bound and was eluted by 0.225 M ammonium sulfate. Active fractions were pooled, dialyzed, and run on a polyacrylamide gel. The starfish active factor comigrated with pure bovine brain calmodulin. A radioimmunoassay was performed on the purified factor; it cross-reacted with antibodies against pure calmodulin. That calmodulin may play a role in hormonally induced maturation of starfish oocytes is suggested by the fact that two calmodulin antagonists (trifluoperazine and vinblastine), which are also inhibitors of NAD-kinase, were found to block 1-methyladenine-induced oocyte maturation. The inhibition could be reversed by increasing the hormone concentration. Oocytes were sensitive to trifluoperazine only during the hormone-dependent period.     

Human erythrocyte calmodulin. Further chemical characterization and the site of its interaction with the membrane.

Human erythrocyte and bovine brain calmodulins were indistinguishable by tryptic peptide mapping, indicating that the primary sequence of the two proteins is either very similar or identical. Calcium binding determinations of human erythrocyte calmodulin, by equilibrium dialysis and fluorescence titration, were in close agreement with previous studies on other calmodulins. The calcium-activated adenosine triphosphatase which is stimulated by calmodulin was shown to be firmly associated with smooth erythrocyte plasma membranes devoid of spectrin and actin. Kinetic titration demonstrated that there are 4500 calmodulin binding sites per erythrocyte and that the turnover number of this calcium-activated adenosine triphosphatase is 3000 mumol of Pi . (mumol of site)-1 . min-1 which is similar to the turnover numbers of other transport adenosine triphosphatases. Furthermore, calmodulin stimulates calcium-activated adenosine triphosphatase by a simple enzyme-ligand association.     

An extracellular role for calmodulin-like activity in cell proliferation.

1. Addition of extracellular pure pig brain calmodulin was found to modulate DNA synthesis and cell proliferation in K562 human leukaemic lymphocytes. At lower cell densities calmodulin significantly stimulated [3H]thymidine uptake; at higher densities it decreased it. 2. A protein biochemically indistinguishable from calmodulin was detected in the cell-conditioned media of rapidly dividing K562 cells. The concentration of calmodulin-like activity found in the conditioned media of these and a range of other normal and neoplastic cells (250-1636 ng/ml) was of the same order as would stimulate DNA synthesis in subconfluent cells. 3. Amounts of extracellular calmodulin-like activity and immunoreactivity varied during cell growth from low to high density, a peak of extracellular calmodulin preceding DNA synthesis in synchronized K562 cells. Extracellular calmodulin concentrations did not correlate with the presence of lactate dehydrogenase in the medium. 4. Inhibition of extracellular calmodulin activity by calmodulin antagonist immobilized on agarose beads, or by antibody to calmodulin, significantly decreased DNA synthesis. 5. These data strongly suggest that calmodulin or a very closely related protein can influence mitosis through an extracellular mechanism.     

Function of calmodulin in postsynaptic densities. I. Presence of a calmodulin-activatable cyclic nucleotide phosphodiesterase activity

The postsynaptic density (PSD) fraction from canine cerebra cortex was found to contain an endogenous cyclic nucleotide-phosphodiesterase activity that was independent on Mn2+ and/or Mg2+ but not on Ca2+. Maximal activity was obtained at 1 micrometer Mn2+. This cyclic nucleotide phosphodiesterase activity was not decreased upon removal of the calmodulin from the PSD fraction, nor was it increased by the addition of calmodulin to a postsynaptic density fraction deficient in calmodulin. The enzymatic activity could be extracted by sonication, with the soluble enzyme having properties similar to those found in the native structure. Two peaks of cyclic nucleotide phosphodiesterase activities could be obtained after S-300 Sephacryl column chromatography of this soluble fraction: fraction I (excluded peak) and fraction II (215,000 mol wt). The fraction I activity preferred cyclic AMP over cyclic GMP and was not activated by calmodulin. The fraction II activity has an approximately fourfold lower Km for cyclic GMP over cyclic AMP. This fraction II activity was activatable by calmodulin, which increased the Vmax and decreased the Km in the case of both cyclic nucleotides. We conclude that two activities are present in the PSD, one activatable, and one not activatable, by calmodulin.     

Ca2+/calmodulin stimulates GTP binding to the ras-related protein ral-A.

Ral-A is a Ras-related GTP-binding protein that has been suggested to be the downstream target of Ras proteins and is involved in the tyrosine kinase-mediated, Ras-dependent activation of phospholipase D. We reported recently that Ral-A purified from human erythrocyte membrane binds to calmodulin in a Ca2+-dependent manner at a calmodulin binding domain identified near its C-terminal region (Wang, K. L., Khan, M. T., and Roufogalis, B. D. (1997) J. Biol. Chem. 272, 16002-16009). In this study we show the enhancement of GTP binding to Ral-A by Ca2+/calmodulin. The stimulation up to 3-fold by calmodulin was Ca2+-dependent, with half-maximum activation occurring at 180 nM calmodulin and 80 nM free Ca2+ concentration. The present work supports a regulatory role of Ca2+/calmodulin for the activation of Ral-A and suggests a possible direct link between signal transduction pathways of Ca2+/calmodulin and Ral-A proteins.