Calcium-Regulated in Vivo Protein Phosphorylation in Zea mays L. Root Tips

Calcium dependent protein phosphorylation was studied in corn (Zea mays L.) root tips. Prior to in vivo protein phosphorylation experiments, the effect of calcium, ethyleneglycol-bis-(β-aminoethyl ether)-N-N′-tetraacetic acid (EGTA) and calcium ionophore (A-23187) on phosphorus uptake was studied. Calcium increased phosphorus uptake, whereas EGTA and A-23187 decreased it. Consequently, phosphorus concentration in the media was adjusted so as to attain similar uptake in different treatments. Phosphoproteins were analyzed by two-dimensional gel electrophoresis. Distinct changes in phosphorylation were observed following altered calcium levels. Calcium depletion in root tips with EGTA and A-23187 decreased protein phosphorylation. However, replenishment of calcium following EGTA and ionophore pretreatment enhanced phosphorylation of proteins. Preloading of the root tips with ³²P in the presence of EGTA and A-23187 followed by a ten minute calcium treatment, resulted in increased phosphorylation indicating the involvement of calcium, calcium and calmodulin-dependent protein kinases. Calmodulin antagonist W-7 was effective in inhibiting calcium-promoted phosphorylation. These studies suggest a physiological role for calcium-dependent phosphorylation in calcium-mediated processes in plants.     

Phosphorylation of liver plasma membrane-bound calmodulin

In highly purified rat liver plasma membrane preparations, membrane-bound calmodulin was phosphorylated by a membrane-bound protein kinase using [gamma-32P]ATP as phosphate donor. Maximum phosphorylation of calmodulin occurred in the absence of calcium ion, but was significantly decreased in its presence. Plasma membrane-bound calmodulin was identified by the following criteria: (i) extraction from the membrane by EGTA, (ii) stimulation of the activity of the Ca2+-calmodulin-dependent enzyme, (3':5'AMP)-phosphodiesterase, by the EGTA extract, and (iii) electrophoretic comigration of EGTA-extracted protein with standard bovine brain calmodulin, both in the presence and the absence of Ca2+. Phosphorylation of the plasma membrane-bound calmodulin was shown by electrophoretic comigration of the 32P-labelled molecule with bovine brain calmodulin, the absence of phosphorylation of this protein band in calmodulin-depleted membranes, and a Western blot of the phosphorylated band using a calmodulin antibody. Treatment of plasma membrane preparations with sheep anticalmodulin serum prevented the phosphorylation of the calmodulin band. Phosphocalmodulin, which could be partially extracted from the membrane by EGTA, comigrated with bovine brain calmodulin in polyacrylamide gel electrophoresis.     

Calmodulin-binding proteins of bovine thyroid plasma membranes

Calmodulin binding proteins in bovine thyroid plasma membranes were investigated using the ¹²⁵I-labeled calmodulin gel overlay technique. The purified thyroid plasma membranes contained two calmodulin binding proteins with molecular weights of approx. 220 000 and 150 000 respectively. The binding of ¹²⁵I-labeled calmodulin to the calmodulin binding proteins was inhibited by excess unlabeled calmodulin, 100 μM trifluoperazine or 1 mM EGTA, indicating that the binding was calmodulin-specific and calcium-dependent. The calmodulin binding proteins appear to be components of the cytoskeleton since they remained in the pellet after treatment of the thyroid plasma membranes with 1% Triton X-100. Similar calmodulin binding proteins were present in rat liver plasma membranes, but not in human red blood cell plasma membranes. These two calmodulin binding proteins may interact with other components of the cytoskeleton and regulate endocytosis, exocytosis and hormone secretion in thyroid cells.     

Calcium- and Calmodulin-Dependent Phosphorylation of Diphosphoinositide in Acetylcholine Receptor-Rich Membranes from Electroplax of Narke japonica

The phosphorylation of phosphoinositides in the acetylcholine receptor (AChR)-rich membranes from the electroplax of the electric fish Narke japonica has been examined. When the AChR-rich membranes were incubated with [gamma-32P]ATP, 32P was incorporated into only two inositol phospholipids, i.e., tri- and diphosphoinositide (TPI and DPI). Even after the alkali treatment of the membrane, AChR-rich membranes still showed a considerable DPI kinase activity upon addition of exogenous DPI. It is likely that the 32P-incorporation into these lipids was realized by the membrane-bound DPI kinase and phosphatidyl inositol (PI) kinase. Such a membrane-bound DPI kinase was activated by Ca2+ (greater than 10(-6) M), whereas the PI kinase appeared to be inhibited by Ca2+. The effect of Ca2+ on the DPI phosphorylation was further enhanced by the addition of ubiquitous Ca2+-dependent regulator protein calmodulin. Calmodulin antagonists such as chlorpromazine (CPZ), trifluoperazine (TFP), and N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide (W-7) inhibited the phosphorylation of DPI in the AChR-rich membranes. It is suggested that the small pool of TPI in the plasma membrane is replenished by such Ca2+- and calmodulin-dependent DPI kinase responding to the change in the intracellular Ca2+ level.     

Inhibition of platelet factor XIIIa-catalyzed reactions by calmodulin

Calmodulin was found to exhibit an inhibitory effect on platelet factor XIIIa-catalyzed incorporation of pseudodonor amines into dimethylcasein, platelet actin and myosin. The inhibitory action of calmodulin on the calcium-dependent enzyme reactions was analogous to the effects of EGTA and parvalbumin on these reactions. The extent of inhibition of factor XIIIa activity was a function of calmodulin concentration when factor XIII and Ca2+ concentrations were held constant. These results indicate that calmodulin inhibits platelet factor XIIIa-catalyzed reactions by sequestering calcium.     

Depolarization-induced phosphorylation of specific proteins, mediated by calcium ion influx, in rat brain synaptosomes.

Agents known to inphorylation of specific endogenous proteins in intact synaptosomes from rat brain. Synaptosome preparations, preincubated in vitro with 32Pi, incorporated 32P into a variety of specific proteins. Veratridine and high (60 mM) K+, which increase Ca2+ transport across membranes, through a mechanism involving membrane depolarization, as well as the calcium ionophore A23187, each markedly stimulated the incorporation of 32P into two specific proteins (80,000 and 86,000 daltons) as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. All three agents failed to stimulate protein phosphorylation in calcium-free medium containing ethylene glycol bis(beta-aminoethyl ether) N,N'-tetraacetic acid (EGTA). Moreover, the Ca2+-dependent protein phosphorylation could be reversed by the addition of sufficient EGTA to chelate all free extracellular Ca2+. Veratridine, high K+, and A23187 also stimulated 45Ca2+ accumulation by synaptosomes. Tetrodotoxin blocked the stimulation both of protein phosphorylation and of 45Ca2+ accumulation by veratridine but not by high K+ or A23187. Cyclic nucleotides and several putative neurotransmitters were without effect on protein phosphorylation in these intact synaptosome preparations. The absence of any endogenous protein phosphorylation in osmotically shocked synaptosome preparations incubated with 32Pi, and the inability of added [gamma-32P]ATP to serve as a substrate for veratridine-stimulated protein phosphorylation in intact preparations, indicated that the Ca2+-dependent protein phosphorylation occurred within intact subcellular organelles. Fractionation of a crude synaptosome preparation on a discontinuous Ficoll/sucrose flotation gradient indicated that these organelles were synaptosomes rather than mitochondria. The data suggest that conditions which cause an accumulation of calcium by synaptosomes lead to a calcium-dependent increase in phosphorylation of specific endogenous proteins. These phosphoproteins may be involved in the regulation of certain calcium-dependent nerve terminal functions such as neurotransmitter synthesis and release.     

Domoic acid inhibits adenylate cyclase activity in rat brain membranes

Adenylate cyclase activity measured by the formation of cyclic AMP in rat brain membranes was inhibited by a shellfish toxin, domoic acid (DOM). The inhibition of enzyme was dependent on DOM concentration, but about 50% of enzyme activity was resistant to DOM-induced inhibition. Rat brain supernatant resulting from 105,000×g centrifugation for 60 min, stimulated adenylate cyclase activity in membranes. Domoic acid abolished the supernatant-stimulated adenylate cyclase activity. The brain supernatant contains factors which modulate adenylate cyclase activity in membranes. The stimulatory factors include calcium, calmodulin, and GTP. In view of these findings, we examined the role of calcium and calmodulin in DOM-induced inhibition of adenylate cyclase in brain membranes. Calcium stimulated adenylate cyclase activity in membranes, and further addition of calmodulin potentiated calcium-stimulated enzyme activity in a concentration dependent manner. Calmodulin also stimulated adenylate cyclase activity, but further addition of calcium did not potentiate calmodulin-stimulated enzyme activity. These results show that the rat brain membranes contain endogenous calcium and calmodulin which stimulate adenylate cyclase activity. However, calmodulin appears to be present in membranes in sub-optimal concentration for adenylate cyclase activation, whereas calcium is present at saturating concentration. Adenylate cyclase activity diminished as DOM concentration was increased, reaching a nadir at about 1 mM. Addition of calcium restored DOM-inhibited adenylate cyclase activity to the control level. Similarly, EGTA also inhibited adenylate cyclase activity in brain membranes in a concentration dependent manner, and addition of calcium restored EGTA-inhibited enzyme activity to above control level. The fact that EGTA is a specific chelator of calcium, and that DOM mimicked adenylate cyclase inhibition by EGTA, indicate that calcium mediates DOM-induced inhibition of adenylate cyclase activity in brain membranes. While DOM completely abolished the supernatant-, and Gpp (NH)p-stimulated adenylate cyclase activity, it partly blocked calmodulin-, and forskolin-stimulated adenylate cyclase activity in brain membranes. These results indicate that DOM may interact with guanine nucleotide-binding (G) protein and/or the catalytic subunit of adenylate cyclase to produce inhibition of enzyme in rat brain membranes.     

Phosphorylation of membranes from the rat gastric mucosa

Gastric mucosal membranes derived primarily from parietal cells were found to contain endogenous protein kinase systems as well as several phosphate-accepting substrates. One specific membrane protein with a molecular weight of 88 000 was phosphorylated only in the presence of calcium, while the degree of phosphorylation of three other membrane proteins was similarly increased. The activity of the calcium-dependent protein kinase was found to be totally inhibited in the presence of trifluoperazine, a phenothiazine known to specifically inactivate calmodulin. These results suggest that a calmodulin- and calcium-dependent phosphorylation system may be a component of the parietal cell membrane. Phosphorylation of the membrane proteins was not affected by either cyclic AMP or cyclic GMP. The heat-stable inhibitor protein of cyclic AMP-dependent protein kinase did not inhibit the endogenous protein kinase activity suggesting that the membrane enzyme is not similar to the cytosolic protein kinase. However, the catalytic subunit of the soluble enzyme was capable of phosphorylating a number of membrane proteins indicating that after maximal autophosphorylation of the gastric membranes, phosphate-acceptor sites are still available to the cytosolic cyclic AMP-dependent protein kinase.     

A calmodulin dependent protein kinase activity associated with rabbit heart sarcolemma

Summary Sarcolemmal vesicles prepared from rabbit heart muscle by differential and discontinuous sucrose density gradient centrifugation, exhibited high marker enzyme activities: Na⁺ + K⁺ ATPase 22 µMol Pi × mg^–1 × h^–1. Adenylate cyclase 500 pmole CAMP × mg^–1 × min^–1, calcium antagonist receptors 0.7 pmoles × mg^–1. Calmodulin in the presence of calcium and -ATP³² stimulated rapidly and specifically the ³²P incorporation into two membrane proteins of 54 and 44 kDa. Calmodulin stimulated the phosphorylation of the 44 kDa to a greater extent (17.9 pmol ³²P × mg^–1 protein) than the 54 kDa protein (1.3 pmoles ³²P x mg^–1 protein). Removal of endogenous calmodulin from the membrane by EGTA extraction resulted in a 2.5 fold increase in calmodulin dependent ³²P incorporation into the two proteins in the presence of exogenous calmodulin. It is suggested that the calmodulin dependent protein kinase activity in heart sarcolemma may mediate the effects of calmodulin in the regulation of Ca²⁺ transport across the membrane.     

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.     

The association of calmodulin with subcellular fractions isolated from rat liver

Calmodulin associated with rat liver mitochondria has been found to belong to a contaminant membranous fraction which contains different subcellular membranes. The concentration of calmodulin in this fraction is relatively high, about 1.6 micrograms/mg protein, and can not be decreased with EGTA. The calmodulin-rich membranous fraction seems to contain cytoskeletal proteins which could be responsible for the binding of calmodulin.     

A nonradioactive method for isolating complementary DNAs endocing calmodulin-binding proteins

Calmodulin labeled with¹²⁵I or³⁴S has been used to screen expression libraries to isolate cDNAs encoding calmodulin-binding proteins (CBPs) from several eukaryotic systems. The use of radiolabeled calmodulin has, however, several disadvantages. We have developed a nonradiactive method to isolate cDNAs for CBPs using biotinylated calmodulin. Screening of a cDNA library in an expression vector with biotinylated calmodulin resulted in the isolation of cDNAs encoding CBPs. Avidin and biotin blocking steps, prior to incubation of the filters with biotinylated calmodulin, are found to be essential to eliminate the cDNAs that code for biotin-containing polypeptides. The cDNA clones isolated using this nonradioactive method bound calmodulin in a calcium-dependent manner. The binding of biotinylated calmodulin to these clones was completely abolished by ethylene glycolbis(\-aminoethylether)-N,N′-tetraacetic acid (EGTA), a calcium chelator. Furthermore, the isolated cDNAs were confirmed by probing the clones with³⁵S-labeled calmodulin. All the isolated clones bound to radiolabeled calmodulin in the presence of calcium but not in the presence of EGTA. The method described here is simple, fast, and does not involve preparation and handing of radiolabeled calmodulin. All the materials used in this method are commercially available; hence, this procedure should be widely applicable to isolate cDNAs encoding CBPs from any eukaryotic organism.     

Distribution of calmodulin and calmodulin-binding proteins in membranes from bovine epididymal spermatozoa

Reproducible concentrations of calmodulin representing approximately 0.1% of the membrane protein were detected in purified plasma membranes from bovine epididymal spermatozoa. When membranes were isolated in the presence of 1 mM EGTA, the amount of calmodulin associated with the plasma membranes was not reduced. Calmodulin-binding proteins were detected in both purified plasma membranes and in a mixed membrane fraction containing both plasma membranes and cytoplasmic droplet membranes. A calcium-dependent, calmodulin-binding protein of apparent molecular weight 123,000 was detected in both fractions. In the presence of 1 mM EDTA, putative calcium-independent calmodulin-binding proteins of apparent molecular weights 93,000, 32,000, 18,000, and 15,000 were detected in the plasma membrane fraction. The 15,000 Mr polypeptide was also present in the mixed membrane fraction but the three proteins of higher molecular weight were reduced or absent in this fraction.     

The location of calmodulin in the pea plasma membrane

Plasma membrane has been prepared from pea seedlings in the presence of [ethylenebis(oxyethylenenitrilo)]tetraacetic acid (EGTA). Calmodulin has been detected in these plasma membrane preparations using calcium overlay techniques, immunoblots, quantitation with antibodies raised against spinach calmodulin, phosphodiesterase activation, mobility shift, and heat stability. EGTA-stable calmodulin represents 0.5-1% of the total plasma membrane protein, and it is the only detectable calcium-binding protein in plasma membrane isolated under these conditions. The anti-spinach calmodulin reacts only with the N-terminal region of spinach calmodulin representing residues 1-106. The positioning of EGTA-stable calmodulin in the plasma membrane has been probed with trypsin and anti-spinach calmodulin. The data suggest that the calmodulin N-terminal region representing residues 1-106 projects from the membrane and could be available for binding other proteins. Calcium-dependent calmodulin binding to the plasma membrane has also been detected. Calcium-dependent calmodulin-binding proteins have been characterized using calmodulin overlay methods. The exposure of calmodulin-binding domains of most of these proteins from the plasma membrane is further suggested by their reaction with azidoiodinated calmodulin.     

Calmodulin-like activity in mycobacteria.

Calmodulin-like activity has been reported for the first time in mycobacterial species, namely Mycobacterium tuberculosis BCG and M. smegmatis ATCC 14468. The activity was mainly located in the soluble fraction of the mycobacterial cells, Radioimmunoassay revealed maximum levels of calmodulin in young growing cells (early logarithmic phase of growth). Calmodulin-dependent phosphodiesterase activation assay revealed low activity (22%) of partially purified calmodulin either due to insufficient amount of calmodulin to activate phosphodiesterase or due to the presence of some factors interfering with the assay. Calmodulin antagonists, viz. trifluoperazine and phenothiazine, significantly inhibited the 32Pi incorporation into mycobacterial phospholipids. Similar inhibition was observed when EGTA (which removes calcium) was added to the medium. Significant inhibition of 32Pi incorporation in the presence of calmodulin antagonists suggested the involvement of calmodulin in mycobacterial phospholipid metabolism.     

Calmodulin-dependent regulation of Ca,Mg-ATPase activity in plasma membranes of the swine myometrium

Highly purified plasma membrane (PM) preparations of pig myometrium were found to contain 0.91 +/- 0.22 microgram calmodulin per mg of PM protein. Treatment of membranes with 1 mM EGTA in the presence of 0.2 M NaCl causes the diminution of the calmodulin content down to 3% of the original level. The activity of Ca, Mg-ATPase is thereby decreased by 40%. Exogenous calmodulin restores the enzyme activity up to 1.94 +/- +/- 0.30 mumol Pi/mg protein/hour. The maximal activation of Ca, Mg-ATPase is observed with 10(-7) M calmodulin. Calmodulin increases the total ATPase activity of myometrium PM without affecting the Mg-ATPase activity. Trifluoroperazine (20 microM) diminishes the activating effect of exogenous calmodulin on Ca, Mg-ATPase. Calmodulin stimulates Ca, Mg-ATPase at low concentrations of Ca2+(10(-8)-10(-6) M) by decreasing Km for Ca2+ from 0.4.10(-6) M to 2.10(-8) M as well as by increasing Vmax--from 0,8 to 1.42 mumol Pl/mg protein/hour. It is supposed that the activating effect of calmodulin on Ca, Mg-ATPase is based on electrostatic interactions of Ca2+-free calmodulin with the enzyme.     

Identification and characterization of calmodulin-binding proteins in mammalian sperm flagella

A calcium and calmodulin-regulated cyclic nucleotide phosphodiesterase has been shown to be an integral component of both rat and bovine sperm flagella. The calcium-activated enzyme was inhibited by both trifluoperazine (ID50 = 10 microM) and [ethylene-bis(oxyethylenenitrilo)]tetraacetic acid (EGTA), and the basal activity measured in the presence of EGTA was stimulated by limited proteolysis to that observed in the presence of calcium/calmodulin. 125I-Calmodulin binding to purified rat sperm flagella has been characterized and the flagellar-associated calmodulin-binding proteins identified by a combination of gel and nitrocellulose overlay procedures and by chemical cross-linking experiments using dimethyl suberimidate. 125I-Calmodulin bound to demembranated rat sperm flagella in a time- and concentration-dependent manner. At equilibrium, 30-40% of the bound 125I-calmodulin remains associated with the flagella after treatment with EGTA or trifluoperazine. The majority of the bound 125I-calmodulin, both the Ca2+-dependent and -independent, was displaced by excess calmodulin. A 67-kDa calmodulin-binding protein was identified by both the gel and nitrocellulose overlay procedures. In both cases, binding was dependent on Ca2+ and was totally inhibited by trifluoperazine, EGTA, and excess calmodulin. On nitrocellulose overlays, the concentration of calmodulin required to decrease binding of 125I-calmodulin by 50% was between 10(-10) and 10(-11) M. Limited proteolysis resulted in the total loss of all Ca2+-dependent binding to the 67-kDa polypeptide. Chemical cross-linking experiments identified a major calcium-dependent 125I-calmodulin:polypeptide complex in the 84-90-kDa molecular mass range and a minor complex of approximately 200 kDa. Immunoblot analysis showed that the major 67-kDa calmodulin-binding protein did not cross-react with polyclonal antibodies raised against either the calcium/calmodulin-regulated cyclic nucleotide phosphodiesterase or phosphoprotein phosphatase (calcineurin) from bovine brain.     

Calmodulin. An activator of human erythrocyte (Ca2+ + Mg2+)ATPase phosphorylation

The effect of purified calmodulin on the calcium-dependent phosphorylation of human erythrocyte membranes was studied. Under the conditions employed, only one major peak of phosphorylation was observed when solubilized membrane proteins were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The molecular weight of this phosphorylated protein band was estimated to be 130000 and in the presence of purified red blood cell calmodulin, the rate of phosphorylation of this band was increased. These data suggest that calmodulin activation of (Ca2+ + Mg2+)-ATPase could be a partial reflection of an increased rate of phosphorylation of the (Ca2+ + Mg2+)-ATPase of human erythrocyte membranes.     

Interactions between the juxtamembrane domain of the EGFR and calmodulin measured by surface plasmon resonance

One early response to epidermal growth factor receptor (EGFR) activation is an increase in intracellular calcium. We have used surface plasmon resonance (SPR) to study real-time interactions between the intracellular juxtamembrane (JM) region of EGFR and calmodulin. The EGFR-JM (Met⁶⁴⁴–Phe⁶⁸⁸) was expressed as a GST fusion protein and immobilised on a sensor chip surface. Calmodulin specifically interacts with EGFR-JM in a calcium-dependent manner with a high on and high off rate. Chemical modification of EGFR-JM by using arginine-selective phenylglyoxal or deletion of the basic segment Arg⁶⁴⁵–Arg⁶⁵⁷ inhibits the interaction. Phosphorylation of EGFR-JM by protein kinase C (PKC) or glutamate substitution of Thr⁶⁵⁴ inhibits the interaction, suggesting that PKC phosphorylation electrostatically interferes with calmodulin binding to basic arginine residues. Calmodulin binding was also inhibited by suramin. Our results suggest that EGFR-JM is essential for epidermal growth factor (EGF)-mediated calcium–calmodulin signalling and for signal integration between other signalling pathways.     

The role of calmodulin in opioid-induced changes in the phosphorylation of rat striatal synaptic membrane proteins

Chronic morphine treatment of rats decreased the level of phosphorylation of synaptic membrane proteins of the striatum assayed in vitro. Although the patterns of phosphorylated proteins separated on SDS-gel electrophoresis from morphine-tolerant rats resembled patterns produced by lowering Ca²⁺ levels in the assay, supplementation of the protein kinase assay with Ca²⁺ and its binding protein, calmodulin, did not restore full kinase activity. The addition of methadone or etorphine to the protein kinase in vitro however, was able to block the Ca²⁺-calmodulin stimulation of phosphorylation in both synaptic membranes and intact synaptosomes. These data suggest that opioids produce an irreversible (or slowly reversible) defect in the Ca²⁺-dependent protein kinase system of striatal membranes.This paper is dedicated to Dr. Derek Richter on his seventy-fifth birthday.