Regulation of acetylcholine receptor phosphorylation by calcium and calmodulin

Calmodulin and Its Binding Proteins in Parkinson's Disease

Parkinson’s disease (PD) is a neurodegenerative disorder that manifests with rest tremor, muscle rigidity and movement disturbances. At the microscopic level it is characterized by formation of specific intraneuronal inclusions, called Lewy bodies (LBs), and by a progressive loss of dopaminergic neurons in the striatum and substantia nigra. All living cells, among them neurons, rely on Ca²⁺ as a universal carrier of extracellular and intracellular signals that can initiate and control various cellular processes. Disturbances in Ca²⁺ homeostasis and dysfunction of Ca²⁺ signaling pathways may have serious consequences on cells and even result in cell death. Dopaminergic neurons are particularly sensitive to any changes in intracellular Ca²⁺ level. The best known and studied Ca²⁺ sensor in eukaryotic cells is calmodulin. Calmodulin binds Ca²⁺ with high affinity and regulates the activity of a plethora of proteins. In the brain, calmodulin and its binding proteins play a crucial role in regulation of the activity of synaptic proteins and in the maintenance of neuronal plasticity. Thus, any changes in activity of these proteins might be linked to the development and progression of neurodegenerative disorders including PD. This review aims to summarize published results regarding the role of calmodulin and its binding proteins in pathology and pathogenesis of PD.

Fluoride Exposure Induces Inhibition of Sodium-and Potassium-Activated Adenosine Triphosphatase (Na+, K+-ATPase) Enzyme Activity: Molecular Mechanisms and Implications for Public Health

In this study, several lines of evidence are provided to show that Na + , K + -ATPase activity exerts vital roles in normal brain development and function and that loss of enzyme activity is implicated in neurodevelopmental, neuropsychiatric and neurodegenerative disorders, as well as increased risk of cancer, metabolic, pulmonary and cardiovascular disease. Evidence is presented to show that fluoride (F) inhibits Na + , K + -ATPase activity by altering biological pathways through modifying the expression of genes and the activity of glycolytic enzymes, metalloenzymes, hormones, proteins, neuropeptides and cytokines, as well as biological interface interactions that rely on the bioavailability of chemical elements magnesium and manganese to modulate ATP and Na + , K + -ATPase enzyme activity. Taken together, the findings of this study provide unprecedented insights into the molecular mechanisms and biological pathways by which F inhibits Na + , K + -ATPase activity and contributes to the etiology and pathophysiology of diseases associated with impairment of this essential enzyme. Moreover, the findings of this study further suggest that there are windows of susceptibility over the life course where chronic F exposure in pregnancy and early infancy may impair Na + , K + -ATPase activity with both short- and long-term implications for disease and inequalities in health. These findings would warrant considerable attention and potential intervention, not to mention additional research on the potential effects of F intake in contributing to chronic disease.

Ca2+/calmodulin protein kinase II and memory: learning-related changes in a localized region of the domestic chick brain

The role of calcium/calmodulin-dependent protein kinase II (CaMKII) in the recognition memory of visual imprinting was investigated. Domestic chicks were exposed to a training stimulus and learning strength measured. Trained chicks, together with untrained chicks, were killed either 1 h or 24 h after training. The intermediate and medial hyperstriatum ventrale/mesopallium (IMHV/IMM), a forebrain memory storage site, was removed together with a control brain region, the posterior pole of the neostriatum/nidopallium (PPN). Amounts of membrane total alphaCaMKII (tCaMKII) and Thr286-autophosphorylated alphaCaMKII (apCAMKII) were measured. For the IMHV/IMM 1 h group, apCaMKII amount and apCAMKII/tCaMKII increased as chicks learned. The magnitude of the molecular changes were positively correlated with learning strength. No learning-related effects were observed in PPN, or in either region at 24 h. These results suggest that CaMKII is involved in the formation of memory but not in its maintenance.

Characterization of Ca(2+)-dependent endogenous phosphorylation of 160,000- and 150,000-Dalton proteins of sarcoplasmic reticulum

The 160 and 150 kDa proteins of sarcoplasmic reticulum (SR) are phosphorylated endogenously. The phosphorylation of both proteins has a marked requirement for Ca2+. Half-maximal and maximal phosphorylation was obtained at about 1 nM- and 1 microM-Ca2+ respectively, and a Hill coefficient of about 0.5 was calculated. The phosphorylation is also dependent on NaF as an inhibitor of the SR phosphoprotein phosphatase. The phosphorylation of these proteins is very rapid, and maximal phosphorylation is achieved in less than 15 s. The phosphorylation of the 160 kDa and 150 kDa polypeptides is completely inhibited by 5 mM-MgCl2 and by 75 microM-LaCl3, by very low concentrations of different detergents, and by preincubation of the SR for 2 min at 60 degrees C. The inhibition by Mg2+ is due to stimulation of ATP hydrolysis, thereby decreasing ATP concentration. Different phosphorylated peptides were obtained by digestion with protease V8 of the 160 kDa and 150 kDa protein bands, suggesting that the 160 kDa and 150 kDa proteins are distinct. The two phosphorylated proteins are present in different fractions and preparations of SR, with or without [3H]PN200-110 binding capacity. These and other results suggest that the phosphorylated SR proteins are distinct from the alpha 1 and alpha 2 subunits of the voltage-gated Ca2+ channel of the T-system membranes. Different inhibitors and activators of protein kinase C and calmodulin-dependent protein kinase have no effect on the endogenous phosphorylation of both polypeptides, suggesting that the phosphorylation is regulated solely by Ca2+. A possible regulatory function for this phosphorylation system is described in the accompanying paper [Gechtman. Orr & Shoshan-Barmatz (1991) Biochem. J. 276.97-102].

Protein phosphorylation of nicotinic acetylcholine receptors

The nicotinic acetylcholine receptor (nAcChR) is a ligand-gated ion channel found in the postsynaptic membranes of electric organs, at the neuromuscular junction, and at nicotinic cholinergic synapses of the mammalian central and peripheral nervous system. The nAcChR from Torpedo electric organ and mammalian muscle is the most well-characterized neurotransmitter receptor in biology. It has been shown to be comprised of five homologous (two identicle) protein subunits (alpha 2 beta gamma delta) that form both the ion channel and the neurotransmitter receptor. The nAcChR has been purified and reconstituted into lipid vesicles with retention of ion channel function and the primary structure of all four protein subunits has been determined. Protein phosphorylation is a major posttranslational modification known to regulate protein function. The Torpedo nAcChR was first shown to be regulated by phosphorylation by the discovery that postsynaptic membranes contain protein kinases that phosphorylate the nAcChR. Phosphorylation of the nAcChR has since been shown to be regulated by the cAMP-dependent protein kinase, protein kinase C, and a tyrosine-specific protein kinase. Phosphorylation of the nAcChR by cAMP-dependent protein kinase has been shown to increase the rate of nAcChR desensitization, the process by which the nAcChR becomes inactivated in the continued presence of agonist. In cultured muscle cells, phosphorylation of the nAcChR has been shown to be regulated by cAMP-dependent protein kinase, a Ca2+-sensitive protein kinase, and a tyrosine-specific protein kinase. Stimulation of the cAMP-dependent protein kinase in muscle also increases the rate of nAcChR desensitization and correlates well with the increase in nAcChR phosphorylation. The AcChR represents a model system for how receptors and ion channels are regulated by second messengers and protein phosphorylation.

Regulation of nicotinic acetylcholine receptors by protein phosphorylation

Neurotransmitter receptors and ion channels play a critical role in the transduction of signals at chemical synapses. The modulation of neurotransmitter receptor and ion channel function by protein phosphorylation is one of the major regulatory mechanisms in the control of synaptic transmission. The nicotinic acetylcholine receptor (nAcChR) has provided an excellent model system in which to study the modulation of neurotransmitter receptors and ion channels by protein phosphorylation since the structure and function of this receptor have been so extensively characterized. In this article, the structure of the nAcChR from the electric organ of electric fish, skeletal muscle, and the central and peripheral nervous system will be briefly reviewed. Emphasis will be placed on the regulation of the phosphorylation of nAcChR by second messengers and by neurotransmitters and hormones. In addition, recent studies on the functional modulation of nicotinic receptors by protein phosphorylation will be reviewed.

Regulation of phosphorylation of nicotinic acetylcholine receptors in mouse BC3H1 myocytes

By using 32P-labeling methods and performing immunoprecipitations with specific antibodies, we have found that three subunits of the nicotinic acetylcholine receptor are phosphorylated in mouse skeletal muscle cells. In nonstimulated cells, the molar ratios of phosphate estimated in alpha, beta, and delta subunits were 0.02, 0.05, and 0.5, respectively. All three subunits contained predominantly phosphoserine with some phosphothreonine; the beta subunit also contained phosphotyrosine. Incubating cells with agents that stimulate cAMP-dependent pathways (isoproterenol, forskolin, 8-Br-cAMP) increased the phosphorylation of the delta subunit by 50%, but phosphate labeling of the beta subunit was depressed by a third. In contrast, when cells were incubated with the divalent cation ionophores A-23187 or ionomycin, phosphorylation of both the delta and beta subunits increased. The results indicate that acetylcholine receptors are phosphorylated to significant levels in skeletal muscle cells and that cAMP-dependent and Ca2+-dependent pathways exist for controlling the phosphorylation state of the receptor subunits.

Iron-transferrin-induced increase in protein kinase C activity in CCRF-CEM cells

Iron transferrin has been found to induce a mean 10-fold increase in the activity of protein kinase C in CCRF-CEM cells. This increase was not detectable up to 45 min after treatment of cells with iron transferrin, although after 60 min, a maximal increase in enzyme activity was observed. Similarly, iron transferrin at concentrations of 0.1-0.5 microgram/ml did not alter protein kinase C activity, while concentrations of iron transferrin of 1-100 micrograms/ml induced a maximal increase in enzyme activity. Apotransferrin and iron in the form of ferric citrate, as well as complexes of transferrin with copper, nickel, zinc, manganese, and cobalt did not increase protein kinase C activity. Additionally, CCRF-CEM cells pretreated with either actinomycin D or cycloheximide and then incubated with iron transferrin did not exhibit increased enzyme activity. Treatment with iron transferrin was found to have no effect on protein kinase C activity in normal human peripheral blood lymphocytes and in HL60, Daudi, and U937 cells. However, normal lymphocytes stimulated with phytohemagglutinin for 48 hr exhibited a 2-fold increase in protein kinase C activity following treatment with iron transferrin. These results indicate a specific effect of iron transferrin on protein kinase C activity in CCRF-CEM cells and in mitogen-stimulated human lymphocytes that may occur through increased synthesis of the enzyme.

Extraction of peripheral proteins is accompanied by selective depletion of certain glycerophospholipid classes and changes in the phosphorylation pattern of acetylcholine-receptor-rich-membrane proteins

The widely used alkaline treatment of acetylcholine-receptor (AChR)-rich membranes from Torpedo marmorata (electric fish) and Discopyge tschudii (a marine ray) results not only in the extraction of non-receptor peripheral proteins but also in that of glycerophospholipids (approximately 13%). Minor acidic phospholipids, notably phosphatidic acid and polyphosphoinositides, are particularly enriched in the NaOH extracts. When electrocytes or receptor-rich membranes are incubated with [32P]Pi or [gamma-32P]ATP, polyphosphoinositides accumulate most of the label (approximately 45% in D. tschudii; 96% in T. marmorata) and exhibit the highest specific radioactivity. Furthermore, more than 50% of these phosphorylated lipids are extracted by NaOH together with the peripheral membrane proteins. NaOH treatment also results in modification of the phosphorylation pattern of AChR membrane proteins. Phosphorylation decreases in the Mr-43,000 group of peripheral proteins and in the gamma-subunit of the receptor. The results indicate that polyphosphoinositides constitute a metabolically very active lipid pool in the postsynaptic membrane, and that a substantial proportion of these phospholipids are preferentially released from the membrane together with other acidic phospholipids upon peripheral-protein extraction. The conclusion is drawn that membranes submitted to the above treatments can no longer be considered equivalent to native ones in terms of their phospholipid composition and phosphorylation characteristics.

Postsynaptic inhibitory effects of phenothiazines at cholinergic synapses may not involve calmodulin

Treatment of frog cutaneous-pectoris nerve-muscle preparations with calmidazolium (R 24571), a calmodulin-inhibitor, at concentrations of 2 X 10(-7) mol/l and 5 X 10(-7) mol/l had no discernable effect on MEPP amplitude. 10(-6) mol/l calmidazolium caused a small (10-35%) increase in MEPP amplitude in most preparations. The phenothiazine calmodulin-inhibitor chlorpromazine (5 X 10(-6) mol/l) caused a clear reduction in MEPP amplitude (20%) after 30 min treatment. Similar experiments carried out with chlorpromazine sulphoxide (a derivative of chlorpromazine that is 60 X less potent in inhibition of calmodulin-activated enzymes) produced data that were very similar to those obtained with chlorpromazine. It is concluded that the postsynaptic inhibitory effect of phenothiazines at cholinergic synapses is unlikely to involve calmodulin.

Phosphorylation of ion channels

The introduction of highly specific reagents such as enzymes and inhibitors directly into living cells has proven to be a powerful tool in studying the modulation of cellular activity by protein phosphorylation. The use of exogenous kinases can be thought of as a pharmacological approach: this demonstrates that phosphorylation can produce modulation, but does not address the question of whether the cell actually uses this mechanism under normal physiological conditions. The complementary approach, the introduction of highly specific inhibitors such as R subunit or PKI, does ask whether endogenous kinase activity is necessary for a given physiological response. Together these two approaches have provided rather compelling evidence that cAMP-dependent and calcium/phospholipid-dependent protein phosphorylations can regulate membrane excitability. In several cases single-channel analysis has allowed the demonstration that an ion channel itself or something very close to the channel is the phosphorylation target, and it seems reasonable to assume that this will also be the case for many if not all of the other systems described above. Have any general principles emerged from the results to date? Certainly it seems clear that protein phosphorylation regulates not one but many classes of ion channels. As summarized in the Table, different channels can be modulated in different cells, some channels are activated while others are inhibited, and in some cells more than one channel is subject to modulation by phosphorylation. The list in the Table is probably not yet complete, and indeed it is not inconceivable that all ion channels can under appropriate conditions be regulated by phosphorylation. What aspect of channel function is altered by phosphorylation? The total membrane current, I, carried by a particular species of ion channel is given by Npi, where N is the number of active channels in the membrane, p is the probability that an individual channel will be open, and i is the single-channel current. In principle a change in I, the quantity measured in whole cell experiments, could be caused by a change in any one (or more) of the parameters, N, p or i (see Fig. 1). In the two cases in which single-channel measurements have allowed this question to be investigated, changes in N (Shuster et al., 1985) and p (Ewald et al., 1985) have been observed. Here again it seems unlikely that any one mechanism operates in all cases, and it would not be surprising to find that phosphorylation of some other channel results in a change in i.(ABSTRACT TRUNCATED AT 400 WORDS)

Protein phosphorylation and neuronal function

Studies in the past several years have provided direct evidence that protein phosphorylation is involved in the regulation of neuronal function. Electrophysiological experiments have demonstrated that three distinct classes of protein kinases, i.e., cyclic AMP-dependent protein kinase, protein kinase C, and CaM kinase II, modulate physiological processes in neurons. Cyclic AMP-dependent protein kinase and kinase C have been shown to modify potassium and calcium channels, and CaM kinase II has been shown to enhance neurotransmitter release. A large number of substrates for these protein kinases have been found in neurons. In some cases (e.g., tyrosine hydroxylase, acetylcholine receptor, sodium channel) these proteins have a known function, whereas most of these proteins (e.g., synapsin I) had no known function when they were first identified as phosphoproteins. In the case of synapsin I, evidence now suggests that it regulates neurotransmitter release. These studies of synapsin I suggest that the characterization of previously unknown neuronal phosphoproteins will lead to the elucidation of previously unknown regulatory processes in neurons.

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.

Phosphorylation of the nicotinic acetylcholine receptor by an endogenous tyrosine-specific protein kinase

Postsynaptic membranes from the electric organ of Torpedo californica, rich in the nicotinic acetylcholine receptor, were shown to contain an endogenous tyrosine protein kinase. This endogenous kinase phosphorylated three major proteins with molecular masses corresponding to 50 kDa, 60 kDa, and 65 kDa. The phosphorylation of these three proteins occurred exclusively on tyrosine residues under the experimental conditions used and was abolished by 0.1% Nonidet P-40 and stimulated by Mn2+. The 50-kDa, and 60-kDa, and 65-kDa phosphoproteins were demonstrated to be the beta, gamma, and delta subunits, respectively, of the nicotinic acetylcholine receptor by purification of the phosphorylated receptor using affinity chromatography. The endogenous tyrosine kinase specifically phosphorylated the beta, gamma, and delta subunits rapidly to a final stoichiometry of approximately equal to 0.5 mol of phosphate per mol of sub-unit. Two-dimensional phosphopeptide mapping of the phosphorylated beta, gamma, and delta subunits, after limit proteolysis with trypsin or thermolysin, indicated that each subunit was phosphorylated on a single site. Locations are proposed for the amino acid residues phosphorylated on the receptor by the tyrosine-specific protein kinase and by two other protein kinases (cAMP-dependent protein kinase and protein kinase C) which phosphorylate the receptor.

Substance P reduces acetylcholine-induced currents in isolated bovine chromaffin cells

Patch-clamp techniques were used to examine the effect of substance P on acetylcholine-induced current in bovine chromaffin cells. Cells had been enzymatically isolated and kept in short-term culture. Experiments were performed at 22 degrees C. Under whole-cell voltage-clamp conditions substance P alone (2-10 microM) did not induce ionic currents. Acetylcholine (ACh, 20 microM) at -60 mV induced an inward current that desensitized in the continued presence of ACh. The time course of desensitization was somewhat variable from cell to cell. In most cases it could be fitted by a single exponential with time constant of 8-10 s. Substance P (2-50 microM) applied simultaneously with ACh induced what appeared to be an acceleration of the desensitization process. The time course in the presence of 10 microM-substance P (20 microM-ACh) was best fitted by the sum of two exponentials with time constants of 0.6 s and 5 s respectively. The effect was reversible. The recovery of ACh-induced current from desensitization was not affected by substance P. The time constant for recovery was approximately 7 s in the presence or absence of substance P. Single-channel records showed that the conductance of individual channels was not changed by substance P. The mean open time of single channels was shortened by substance P both at high (20 microM) and at low (0.5 microM) concentrations of ACh. The inverse mean open time varied linearly with substance P concentration. Single-channel responses appeared in bursts and clusters after almost complete desensitization at 20 microM-ACh, as was previously observed in frog skeletal muscle. Substance P dramatically reduced ACh current by increasing interburst intervals while decreasing burst duration and the number of openings per burst. We conclude that substance P inhibits ACh-induced depolarization of chromaffin cells either by increasing the rate of desensitization or by inducing channel blockade, which indirectly enhances desensitization. Possible models of desensitization in the absence and presence of substance P are discussed.

Sustained rise in ACh sensitivity of a sympathetic ganglion cell induced by postsynaptic electrical activities

Long-term alteration in synaptic efficacy found in several neurones of both vertebrates and invertebrates has been suggested as an important mechanism for learning and memory. In bullfrog sympathetic ganglia, acetylcholine (ACh) release from presynaptic nerve terminals is potentiated for a long time by adrenaline through a cyclic AMP system. We report here a new form of mechanism for long-term synaptic potentiation in sympathetic ganglia, which occurs postsynaptically in a Ca2+-dependent manner. Our results suggest that Ca2+ entry into a ganglion cell during repeated action potentials initiates a long-lasting mechanism for the enhancement of a nicotinic ACh action on the subsynaptic membrane. This, as well as the presynaptic mechanism, may contribute to neuronal plasticity in the peripheral autonomic nervous system.

Effect of oral administration of tri-o-cresyl phosphate on in vitro phosphorylation of membrane and cytosolic proteins from chicken brain

The effects of a single oral dose of 750 mg/kg tri-o-cresyl phosphate (TOCP) on the endogenous phosphorylation of specific brain proteins were assessed in male adult chickens following the development of delayed neurotoxicity. Phosphorylation of crude synaptosomal (P2) membrane and synaptosomal cytosolic proteins was assayed in vitro by using [gamma-32P]ATP as phosphate donor. Following resolution of brain proteins by sodium dodecyl sulfate polyacrylamide gel electrophoresis, specific protein phosphorylation was detected by autoradiography and quantified by microdensitometry. TOCP administration enhanced the phosphorylation of both cytosolic (Mr 65,000 and 55,000) and membrane (20,000) proteins by as much as 146% and 200%, respectively.

Selective phosphorylation of the IgE receptor in antigen-stimulated rat mast cells

Purified rat serosal mast cells were sensitized with mouse immunoglobulin E (IgE) anti-2,4-dinitrophenyl antibody, partially depleted of phosphate, labeled with [32P]orthophosphate, and stimulated with dinitrophenylated bovine serum albumin or control protein. After 15-120 seconds at 37 degrees C, the cells were extracted with nonionic detergent. IgE receptors were purified by repetitive affinity chromatography and were analyzed by NaDodSO4/polyacrylamide gel electrophoresis and radioautography. Antigenic stimulation of intact rat mast cells produced a rapid and marked increase in the phosphorylation of the surface-exposed alpha component of the IgE receptor. However, phosphorylation of the 33,000 Mr beta component of the IgE receptor was not altered significantly by antigen stimulation. This suggests that the selective increase in phosphorylation of the IgE receptor alpha component may be part of the physiologic mediator secretion process triggered by antigen.

Resolution and properties of a protein kinase catalyzing the phosphorylation of a wheat germ cytokinin-binding protein

The major cytokinin binding protein of wheat germ (CBP) was extensively purified employing chromatography on Cibacron F3GA-Sepharose CL6B and concanavalin A-agarose as key purification steps. The major polypeptides present in the purified CBP preparations have molecular weights of 60,000 +/- 4,000, 42,000 +/- 3,000, and 37,000 +/- 3,000, respectively. A protein kinase that catalyzes the phosphorylation of CBP (CBP kinase) was extensively purified from wheat germ by affinity chromatography on casein-Sepharose 4B and CBP-Sepharose 4B. The purification procedure resolves CBP kinase from an abundant casein kinase that does not phosphorylate CBP. CBP kinase catalyzes the phosphorylation of casein, phosvitin, CBP, and the wheat germ cyclic AMP-binding protein cABPII. CBP kinase phosphorylates the major 60,000 dalton subunit of CBP as well as 16,000 to 18,000 dalton polypeptides present in CBP preparations. CBP fractions with differing activities as substrates for CBP kinase were partly resolved by gel filtration and by chromatography on DEAE-Sephacel.

cAMP-dependent protein kinase phosphorylates the nicotinic acetylcholine receptor

Postsynaptic membranes, rich in the nicotinic acetylcholine receptor, were isolated from the electric organ of Torpedo californica and shown to contain a cAMP-dependent protein kinase and a calcium/calmodulin-dependent protein kinase. The cAMP-dependent protein kinase phosphorylated the gamma and delta subunits of the acetylcholine receptor. The phosphorylated subunits were identified after purification of the acetylcholine receptor by affinity chromatography on a choline carboxymethyl affinity gel. In contrast, the calcium/calmodulin-dependent protein kinase phosphorylated proteins that were separated from the acetylcholine receptor by affinity chromatography. Protein kinase inhibitor, a specific inhibitor of the catalytic subunit of cAMP-dependent protein kinase, abolished the basal endogenous phosphorylation of the gamma and delta subunits of the receptor. cAMP activation of the endogenous phosphorylation of the gamma and delta subunits was dose dependent with a half-maximal response at 25 nM. Studies were also carried out with acetylcholine receptor purified from T. californica and catalytic subunit of cAMP-dependent protein kinase purified from bovine heart. The purified acetylcholine receptor was rapidly and specifically phosphorylated on the gamma and delta subunits by the purified catalytic subunit of cAMP-dependent protein kinase to a stoichiometry of 1.0 and 0.89 mol of (32)P per mol of receptor, respectively. The initial rates of phosphorylation of the gamma and delta subunits of the receptor were comparable to those of histone f2B and synapsin I (protein I), two of the most effective substrates for the catalytic subunit. Under the conditions used, the gamma and delta subunits had K(m) values of 4.0 and 3.3 muM and V(max) values of 2.7 and 2.1 mumol/min per mg, respectively. The results are consistent with the idea that the acetylcholine receptor is phosphorylated in vivo by a cAMP-dependent protein kinase.

Solubilization and partial purification of protein kinase systems from brain membranes that phosphorylate calspectin. A spectrin-like calmodulin-binding protein (fodrin)

In brain tissue a spectrin-like calmodulin-binding protein calspectin, or fodrin, is concentrated in a synaptosome fraction, where most of the calspectin is associated with the synaptic membranes. This endogenous calspectin was phosphorylated by protein kinase system(s) associated with the membranes. Here, we report the solubilization and partial purification of the membrane-associated calspectin kinase activity. The activity was resolved on a gel filtration column into two fractions, peaks I and II having estimated Mr of 800 000 and 88 000. The activity of peak I was dependent on the presence of both Ca2+ and calmodulin. Peak II revealed a basal activity in the absence of Ca2+ and calmodulin, which was stimulated 2-fold by addition of Ca2+. Calmodulin had no effect on the peak II activity.

Calmodulin stimulation of 45Ca2+ transport and protein phosphorylation in cholinergic synaptic vesicles

Cholinergic synaptic vesicles isolated from the electric organ of Torpedo californica exhibit ATP-dependent uptake of 45Ca2+ that is stimulated by exogenous calmodulin. ATP-independent uptake also occurs, but it is only weakly stimulated by calmodulin. Saturating calmodulin decreased the Michaelis constant for ATP-dependent 45Ca2+ uptake from 52 +/- 0.4 to 12 +/- 0.2 microM and increased the maximal velocity from 3.4 +/- 0.3 to 5.2 +/- 0.5 nmol/mg of protein per min. The dose-response curve for calmodulin-dependent stimulation showed a maximal increase of 3.5-fold in the uptake rate; 0.2 microM calmodulin gave half-maximal stimulation. The activity of the vesicle-associated ATPase was unaffected. Incubation of vesicles with [gamma-32P]ATP and Ca2+ resulted in phosphorylation of four polypeptides of molecular weights about 64,000, 58,000, 54,000, and 41,000 when calmodulin was added. Vesicles that were previously phosphorylated and purified exhibited 2-fold enhanced ATP-independent uptake of 45Ca2+. Cyclic AMP could not substitute for calmodulin. The calcium transport system of the cholinergic synaptic vesicle is regulated by a calcicalmodulin-dependent protein kinase that is vesicle-associated.

Specificity and localization of the acetylcholine receptor kinase

Acetylcholine receptor-phosphorylation has been compared in sealed and lysed right-side-out membrane vesicles prepared form Torpedo californica electric organ. Phosphorylation was increased 5- to 12-fold in hypotonically lysed vesicles as compared with untreated vesicles. Control experiments confirm that this enhancement is a result of increased permeability of the membrane to ATP. These data suggest that the acetylcholine receptor kinase is located on the cytoplasmic side of the plasma membrane. Results with detergent lysis support this conclusion. Although the acetylcholine receptor constitutes less than 10% of the total protein in these membranes, the kinase was found to be highly specific for polypeptides corresponding in molecular weight to acetylcholine receptor subunits.