Isolation of brain Ca2+-calmodulin tubulin kinase containing calmodulin binding proteins

Calcium-Stimulated Protein Phosphorylation in Synaptic Membranes

Synaptic membranes from rat brain contain several calcium-requiring protein kinase (PK) activities with different substrate specificities: (a) an activity (CaH-PK) effective at high concentrations of Ca2+ ion in the absence of Mg2+ (active on class F substrates); (b) a (Ca + Mg)-PK activity that is mediated by Ca2+ ion in the presence of Mg2+ (active on class B substrates); (c) (Ca-CaM)-PK activities that exhibit simultaneous requirements for both Ca2+ ion and CaM (for class C and D substrates). Also described are three activities (d-f) that do not require Ca2+ ion: (d) a Mg-PK activity in which the presence of Ca2+ causes the inhibition of phosphorylation (active on class A substrates); (e) an activity affecting a diverse group of substrates (class E substrates), the phosphorylation of which occurs in the presence of Mg2+ ion alone (Mg-PK activity) and is unaffected by the addition of Ca2+ ion and CaM, the substrates of which show different responses to several types of inhibitors; and, finally, (f) the previously well characterized cAMP-dependent PK activities. Several of the substrates of these kinases have been identified in a fairly unambiguous manner: among them are P43 (class A), as the alpha subunit of pyruvate dehydrogenase; P54 (class B), as the presynaptic protein B50; and the doublet P75-P80, as proteins IA and IB of Ueda and Greengard. The most interesting activity is that requiring both Ca2+ and CaM. The half-maximal stimulation (K0.5) for Ca2+ in the presence of CaM was found to be 1.0 microM Ca2+F in untreated membranes. There is little change in this value on prior EGTA extraction of the membranes, which removes the bulk of its Ca2+ and reduces its residual CaM by greater than or equal to 50%. The apparent K0.5 for CaM in the presence of excess Ca2+ ion was found to equal 0.4 microgram per reaction mixture (8 micrograms/ml) or 1.35 micrograms per reaction mixture (27 micrograms/ml), for the untreated and EGTA-treated membranes, respectively.

Effect of acute and chronic administration of methamphetamine on calcium-calmodulin dependent protein kinase II activity in the rat brain

Several lines of evidence have implicated Ca2+/calmodulin (CaM)-dependent protein kinase II (CaM-kinase II), a multifunctional protein kinase, in the regulation of signal transduction after chronic administration of psychostimulants. CaM-Kinase II activities were decreased in discrete brain regions after a single methamphetamine (METH) injection to rats. Pretreatment with either SCH 23390 (a dopamine D1 receptor antagonist) or NMK-801 (an N-methyl-D-aspartate receptor antagonist) prevented the acute METH-induced decrease in CaM-kinase II activity in the parietal cortex, nucleus accumbens, and substantia nigra/ventral tegmental area (SN/VTA). Striatal CaM-kinase II activity was significantly lower than that of the chronic saline-treated controls after a one-week, but not a four-week, abstinence from chronic administration of METH. A METH challenge after a four-week abstinence period decreased CaM-kinase II activity in rats chronically injected with METH to a greater extent than in rats chronically injected with saline. Western blot analysis revealed that protein amount of CaM-kinase II was not altered after a single METH injection or after chronic METH injections, as compared with saline-treated controls. However, amounts of phosphorylated (Thr286) CaM-kinase II in the parietal cortex, striatum, and SN/VTA were significantly decreased at 3 h after an acute METH injection compared with saline-treated controls. It is suggested that dephosphorylation of CaM-kinase II may contribute to the decreased enzyme activities induced by acute METH administration, and that chronic treatment with METH leads to an enhanced capacity of METH to decrease CaM-kinase II activity after an extended withdrawal period.

Methamphetamine decreases calcium-calmodulin dependent protein kinase II activity in discrete rat brain regions

A Ca(2+)/calmodulin-dependent signaling cascade has been implicated in the regulation of dopaminergic neurotransmission after chronic administration of amphetamine and methamphetamine (METH). We found a decrease in Ca(2+)/calmodulin-dependent protein kinase II (CaM-kinase II) activity in five regions of the rat brain (parietal cortex; frontal cortex; hippocampus; striatum; and nucleus accumbens) after a single injection of METH. Pretreatment with the selective dopamine D1 receptor antagonist SCH 23390 prevented the acute METH-induced decrease in CaM-kinase II activity in the parietal cortex, striatum, nucleus accumbens, and substantia nigra/ventral tegmental area (SN/VTA). Pretreatment with the N-methyl-D-aspartate receptor antagonist MK-801 significantly restored the acute METH-induced decrease in CaM-kinase II activity in the parietal cortex, nucleus accumbens, and SN/VTA. Striatal CaM-kinase II activity was still significantly lower than that of the chronic saline-treated controls after a 1-week, but not a 4-week, abstinence from chronic administration of METH. A METH challenge after a 4-week abstinence period induced a more pronounced decrease in CaM-kinase II activity in rats chronically injected with METH than in rats chronically injected with saline. Western blot analysis revealed that the amount of CaM-kinase II protein was not altered after a single METH injection or after chronic METH injections, compared with saline-treated controls. However, amounts of phosphorylated (Thr(286)) CaM-kinase II in the parietal cortex, striatum and SN/VTA were significantly decreased at 3 h after an acute METH injection compared with saline-treated controls. These results suggest that dephosphorylation of CaM-kinase II may contribute to the decreased enzyme activities induced by acute METH administration, and that chronic treatment with METH leads to an enhanced capacity of METH to decrease CaM-kinase II activity after an extended withdrawal period.

Effect of zinc on calmodulin-stimulated protein kinase II and protein phosphorylation in rat cerebral cortex

The effect of increasing concentrations of Zn2+ (1 microM-5 mM) on protein phosphorylation was investigated in cytosol (S3) and crude synaptic plasma membrane (P2-M) fractions from rat cerebral cortex and purified calmodulin-stimulated protein kinase II (CMK II). Zn2+ was found to be a potent inhibitor of both protein kinase and protein phosphatase activities, with highly specific effects on CMK II. Only one phosphoprotein band (40 kDa in P2-M phosphorylated under basal conditions) was unaffected by addition of Zn2+. The vast majority of phosphoprotein bands in both basal and calcium/calmodulin-stimulated conditions showed a dose-dependent inhibition of phosphorylation, which varied with individual phosphoproteins. Two basal phosphoprotein bands (58 and 66 kDa in S3) showed a significant stimulation of phosphorylation at 100 microM Zn2+ with decreased stimulation at higher concentrations, which was absent by 5 mM Zn2+. A few Ca2+/calmodulin-stimulated phosphoproteins in P2-M and S3 showed biphasic behavior; inhibition at less than 100 microM Zn2+ and stimulation by millimolar concentrations of Zn2+ in the presence or absence of added Ca2+/calmodulin. The two major phosphoproteins in this group were identified as the alpha and beta subunits of CMK II. Using purified enzyme, Zn2+ was shown to have two direct effects on CMK II: an inhibition of Ca2+/calmodulin-stimulated autophosphorylation and substrate phosphorylation activity at low concentrations and the creation of a new Zn(2+)-stimulated, Ca2+/calmodulin-independent activity at concentrations of greater than 100 microM that produces a redistribution of activity biased toward autophosphorylation and an alpha subunit with an altered mobility on sodium dodecyl sulfate-containing gels.

Autophosphorylation of neuronal calcium/calmodulin-stimulated protein kinase II

A unique feature of neuronal calcium/calmodulin-stimulated protein kinase II (CaM-PK II) is its autophosphorylation. A number of sites are involved and, depending on the in vitro conditions used, three serine and six threonine residues have been tentatively identified as autophosphorylation sites in the alpha subunit. These sites fall into three categories. Primary sites are phosphorylated in the presence of calcium and calmodulin, but under limiting conditions of temperature, ATP, Mg2+, or time. Secondary sites are phosphorylated in the presence of calcium and calmodulin under nonlimiting conditions. Autonomous sites are phosphorylated in the absence of calcium and calmodulin after initial phosphorylation of Thr-286. Mechanisms that lead to a decrease in CaM-PK II autophosphorylation include the thermolability of the enzyme and the activity of protein phosphatases. A range of in vitro inhibitors of CaM-PK II autophosphorylation have recently been identified. Autophosphorylation of CaM-PK II leads to a number of consequences in vitro, including generation of autonomous activity and subcellular redistribution, as well as alterations in conformation, activity, calmodulin binding, substrate specificity, and susceptibility to proteolysis. It is established that CaM-PK II is autophos-phorylated in neuronal cells under basal conditions. Depolarization and/or activation of receptors that lead to an increase in intracellular calcium induces a marked rise in the autophosphorylation of CaM-PK II in situ. The incorporation of phosphate is mainly found on Thr-286, but other sites are also phosphorylated at a slower rate. One consequence of the increase in CaM-PK II autophosphorylation in situ is an increase in the level of autonomous kinase activity. It is proposed that the formation of an autonomous enzyme is only one of the consequences of CaM-PK II autophosphorylation in situ and that some of the other consequences observed in vitro will also be seen. CaM-PK II is involved in the control of neuronal plasticity, including neurotransmitter release and long-term modulation of postreceptor events. In order to understand the function of CaM-PK II, it will be essential to ascertain more fully the mechanisms of its autophosphorylation in situ, including especially the sites involved, the consequences of this autophosphorylation for the kinase activity, and the relationships between the state of CaM-PK II autophosphorylation and the physiological events within neurons.

Purification and characterization of calmodulin-stimulated protein kinase II from two-day and adult chicken forebrain

Soluble calmodulin-stimulated protein kinase II has been purified from 2-day and adult chicken forebrain. At both ages the holoenzyme eluted from a Superose-6B column with an apparent molecular weight of approximately 700,000 daltons and contained three subunits. The subunits were found to be the counterparts of the alpha, beta, and beta' subunits of the enzyme purified from adult rat brain in that they had one-dimensional phosphopeptide maps that were indistinguishable from those of the corresponding subunit in the rat enzyme and they migrated in SDS-polyacrylamide gels with the same apparent molecular weights. However, the doublet formed by the beta subunit was much more clearly resolved in the chicken enzyme and the beta' subunit, which was much more abundant in the adult chicken than in the adult rat, was also found to be a doublet. The ratio of the concentrations of the alpha and beta subunits changed during development. By autoradiography following autophosphorylation, the alpha:beta ratios of the 2-day and adult enzymes were 0.89 +/- 0.07 and 1.92 +/- 0.26, respectively; by silver staining the alpha:beta ratios were 0.95 +/- 0.11 and 1.85 +/- 0.17, respectively. The concentration of the beta' subunit was equal to that of the beta subunit at both ages. Autophosphorylation produced a decrease in the electrophoretic mobility of the alpha and beta subunits in SDS-polyacrylamide gels and a marked decrease in the calcium dependence of the substrate phosphorylation activity of the enzyme at both ages. The purified enzyme from chicken brain appeared to be more stable under standard in vitro assay conditions than the rat enzyme, and this was particularly so for the enzyme from 2-day forebrain.

Developmental changes in protein phosphorylation in chicken forebrain. II. Calmodulin stimulated phosphorylation

The development of calmodulin stimulated protein phosphorylation, with particular reference to calmodulin-stimulated protein kinase II (CMK II), was investigated in 3 subcellular fractions of chicken forebrain: cytosol (S3), crude synaptic plasma membranes (P2-M) and occluded cytosol (P2-S). Changes in the level of calmodulin-stimulated phosphorylation of endogenous proteins occurred over a protracted time course and were not complete until after day 52 post-hatching. By day 15 post-hatching, calmodulin-stimulated phosphoproteins characteristic of embryonic fractions had all disappeared and those characteristic of adult tissue were present but not necessarily at their mature levels. The levels of CMK II were estimated from the autophosphorylation of the alpha-subunit which was the only phosphoprotein present at 53,000 Da in the 3 fractions. Overall, calmodulin-stimulated phosphorylation and CMK II levels were low in embryonic brain and high in adult brain but two specific changes in CMK II were observed during development: (1) although CMK II concentrations increased in both membrane and cytosolic fractions until day 23 the kinase was predominantly cytoplasmic (approximately 75%) until day 23, after which it became increasingly membrane bound so that by day 52 post-hatching the majority of CMK II was present in the synaptic membrane fraction, and (2) the relative concentrations of the alpha- and beta-subunits changed from an alpha:beta-value of approximately 1:1 in the 19 day embryo to approximately 1:2 by 15 days post-hatch after which no further change was seen. The occurrence of major changes in the calmodulin stimulated protein phosphorylation system for up to 6-8 weeks after synapse formation is completed in the forebrain, provides further support for the existence of a synapse maturation phase of neuronal differentiation which is distinct from synapse formation. This phase involves only a specific subset of the developmental changes occurring in the calmodulin-stimulated phosphorylation system.

Calcium and calmodulin-dependent phosphorylation of a 62 kd protein induces microtubule depolymerization in sea urchin mitotic apparatuses

Sea urchin mitotic apparatuses (MAs) were isolated in a microtubule stabilizing buffer that contained detergent. These isolated MAs contain a calcium and calmodulin-dependent protein kinase that phosphorylates one specific MA-associated endogenous substrate with a relative molecular mass of 62 kd. No protein phosphorylation occurs in the presence of calcium or magnesium ion alone, or when magnesium ion is combined with 10 microM cyclic AMP or cyclic GMP. Because in vivo labeling studies showed that the 62 kd protein was also phosphorylated in living cells during mitosis, the effect of protein phosphorylation on MA stability was also studied. When isolated MAs were incubated under conditions that resulted in phosphorylation of the 62 kd protein, substantial depolymerization of MA microtubules occurred within 10 min. MAs incubated under similar conditions but in the absence of 62 kd phosphorylation lost many fewer microtubules and were stable for up to 30 min. The results are discussed with respect to a model for mitosis in which the specific role of protein phosphorylation in the events of anaphase is addressed.

Two developmentally regulated isoenzymes of calmodulin-stimulated protein kinase II in rat forebrain

Soluble calmodulin-stimulated protein kinase II has been purified from adult and 10-day-old rat forebrain. By autoradiography, the alpha/beta subunit ratios of the 10-day and adult enzymes were 0.67 +/- 0.03 and 2.20 +/- 0.15, respectively. By silver staining, the alpha/beta subunit ratios were 1.02 +/- 0.06 and 2.36 +/- 0.10, respectively. The apparent holoenzyme molecular masses of the purified 10-day and adult enzymes were 500,000 daltons and 700,000 daltons. However, varying the purification conditions revealed higher and lower molecular mass forms at both ages and suggested that the form of the kinase that is usually purified is merely that which has the highest affinity for calmodulin-Sepharose and may not be the form of the kinase that exists in vivo. The subunits of the adult and 10-day enzymes were indistinguishable by one- and two-dimensional electrophoresis and one-dimensional proteolytic peptide maps. These results are consistent with the suggestion that at least two developmentally regulated isoenzymes of this kinase exist in rat forebrain.

Nature and immunochemical characteristics of a Ca2+/calmodulin kinase activity endowed in a highly insoluble protein purified from adult rat brain

Using sequential extraction procedure of proteins from adult rat forebrain, a protein of Mr 52,000, insoluble in neutral detergents, capable of binding calmodulin in the presence of Ca2+, was isolated. Antibodies to this antigen had the capacity to inhibit the Ca2+/calmodulin-dependent kinase activity associated with this protein. This protein (52K) (in many respects identical to the major protein of postsynaptic densities) shares by itself the Ca2+/calmodulin-dependent kinase activity, thus differing from soluble Ca2+/calmodulin-dependent kinases isolated by others. Despite its insolubility in most detergents, the 52K protein is not particularly rich in hydrophobic amino acids. Its richness in cysteine and proline residues suggests that the active conformation of the enzyme is sustained by numerous disulfide bridges.

Calcium and neuronal cytoskeletal proteins: alterations with aging

Calcium plays a major role in regulating cellular function. Alterations in calcium systems may underlie some of the physiological changes associated with aging. Calcium activates calmodulin-dependent protein kinase, and this enzyme mediates some effects of calcium on cellular function. Calcium/calmodulin-dependent kinase II may play a significant role in specific cytoskeletal abnormalities of normal aging and selected neurodegenerative diseases.

Neuronal phosphoproteins. Mediators of signal transduction

This article summarizes some of our knowledge concerning intracellular protein phosphorylation pathways in nerve cells. It also summarizes, very briefly, recent direct experimental evidence involving intracellular injection of protein kinases, protein kinase inhibitors, and substrates, indicating that protein phosphorylation mediates the actions of a variety of neurotransmitters on their target cells. Finally, it summarizes in somewhat greater detail the results of studies of three different types of substrate proteins that appear to regulate different types of biological responses in nerve cells: synapsin I, a substrate protein present in virtually all nerve terminals, which appears to regulate neurotransmitter release from those nerve terminals; the acetylcholine receptor, the phosphorylation of which regulates its rate of desensitization in the presence of acetylcholine; and DARPP-32, the phosphorylation of which converts it into a very potent phosphoprotein phosphatase inhibitor that may be involved in the regulation by the neuromodulator dopamine of the effects of the neurotransmitter glutamate. The identification and characterization of additional neuronal phosphoproteins can be expected to lead to the clarification of numerous additional molecular mechanisms by which signal transduction is carried out in nerve cells.

Synapsin I, a phosphoprotein associated with synaptic vesicles: possible role in regulation of neurotransmitter release

The data presented here provide evidence that the study of neuronal phosphoproteins can lead to the identification of previously unknown proteins and that these proteins may play important roles in neuronal communication. Specifically, in the case of synapsin I, direct evidence has been obtained that this phosphoprotein is involved in regulating neurotransmitter release. A tentative explanation of the results obtained in the micro-injection studies is as follows: synapsin I, in the dephosphostate, is bound to the cytoplasmic surface of synaptic vesicles and inhibits the ability of the vesicle to interact with the plasma membrane; increases in intracellular calcium activate calmodulin kinase II which in turn phosphorylates synapsin I and the phosphorylated synapsin I dissociates from the synaptic vesicle thus removing a constraint on the release of neurotransmitter. Clearly, more studies need to be done to rigorously test this hypothesis. Nevertheless these studies of synapsin I suggest that the study of previously unknown phosphoproteins will lead to the elucidation of previously unknown regulatory processes in neurons.

Molecular mechanisms of neuronal excitability: possible involvement of CaM kinase II in seizure activity

A type II calmodulin-dependent protein kinase (CaM kinase II) has been characterized in the synaptic region and may mediate some of the effects of Ca2+ on neuronal excitability. The activity of CaM kinase II is inhibited by anticonvulsant compounds and may be the molecular basis of their neuro-modulatory effects. The direct injection of purified CaM kinase II into invertebrate neurons has demonstrated that this kinase can directly alter specific ion conductances and neuronal activity. A long-lasting decrease in CaM kinase II activity is associated with septal kindling, an experimental model of epilepsy and long-term memory. In summary, CaM kinase II appears to be a central mediator of the effects of Ca2+ on neuronal function. Further investigation of this enzyme and its effects on neuronal activity may provide a molecular insight into an endogenous mechanism for modulating some of the effects of Ca2+ on neuronal excitability and may increase our understanding of the complex regulatory mechanisms that underlie the pathogenesis of seizure discharge and its regulation by anticonvulsant compounds.

Subcellular distribution of a calmodulin-dependent protein kinase activity in rat cerebral cortex during development

The postnatal development of calmodulin-stimulated phosphorylation of endogenous proteins, in particular the autophosphorylated subunits of the calmodulin-stimulated protein kinase II, were investigated in subcellular fractions of rat cerebral cortex. The major subunit had a mol. wt. of 53,000 Da (designated 50 kDa) and the minor one a mol. wt. of 63,000 Da (designated 60 kDa). The 50-kDa subunit was found to be the only significant phosphoprotein in each fraction and throughout development at its molecular weight. However, the 60-kDa subunit was found to comigrate with other phosphoproteins that accounted for up to 15% of the radioactivity at this molecular weight and which differed between the fractions. 50-kDa autophosphorylation was found to be 3-fold greater in cytoplasmic fractions at day 10 and by adults was evenly distributed between membrane and cytoplasmic fractions. A similar pattern was also found for the total calmodulin-stimulated phosphorylation. Changes in autophosphorylation activity of the 50-kDa subunit were found to represent changes in kinase activity rather than alterations in phosphatase activity. In the membrane, this change was shown to be due to changes in the amount of enzyme. Although in the adult autophosphorylation activity is evenly distributed between membrane and soluble fractions, when differences in phosphatase activity and lack of autophosphorylation activity of the majority of post-synaptic density-associated kinase is taken into account, it is clear that the vast majority of the enzyme is membrane-bound. Phosphorylation of endogenous substrates paralleled the development of 50-kDa subunit autophosphorylation, most of which occurred between day 14 and day 30, a period which follows the most rapid phase of synaptogenesis. This pattern was different from that of the phosphorylation of myelin basic protein and two substrates of the calcium-phospholipid-dependent protein kinase. There was also a change in the ratio of autophosphorylation activity of the 50-kDa and 60-kDa subunits during development which appears to be due to a change in the amount of the subunits themselves. This ratio was the same in all fractions at any one age. We suggest that this change is due to the existence of at least two developmentally regulated isoenzymes in the cortex.

Characterization of Ca2+/calmodulin-dependent protein kinase associated with rat cerebral synaptic junction: substrate specificity and effect of autophosphorylation

The Ca2+/calmodulin (CaM)-dependent protein kinase associated with rat cerebral synaptic junction (SJ) was characterized, using the SJ fraction as the enzyme preparation, to clarify the functional significance of the enzyme in situ. The protein kinase was greatly activated in the presence of micromolar concentrations of both Ca2+ and calmodulin (EC50 for Ca2+, 1.0 microM; that for CaM, 100 nM). The Km for ATP was 150 microM. SJ proteins were phosphorylated without a lag time, and the phosphorylation reached its maximum within 2-10 min at 25 degrees C. The endogenous substrates consisted of four major (160K, 120K, 60K, and 51K Mr) and 10 minor proteins. Compared with the endogenous substrate phosphorylation, the phosphorylation of exogenously added proteins (myosin light chains from chicken muscle, casein, arginine-rich histone, microtubule-associated protein-2, tau-protein, and tubulin) was weak, although they are expected to be good substrates for the soluble form of the Ca2+/CaM-dependent protein kinase. Autophosphorylation of the enzyme in SJ inhibited its activity and did not alter the subcellular distribution of the enzyme.

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.

Is Ca2+-calmodulin-dependent protein phosphorylation in rat brain modulated by carboxylmethylation?

Calmodulin stimulation of protein kinase activity in calmodulin-depleted preparations of rat brain cytosol or synaptosomal membranes was attenuated by prior carboxylmethylation of the enzyme source with purified protein-O-carboxylmethyltransferase. Similarly, calmodulin stimulation of highly purified Ca2+-calmodulin-dependent protein kinase was reduced if the kinase was exposed to methylating conditions prior to addition of calmodulin. Biochemical and acidic sodium dodecyl sulfate-gel electrophoretic analyses indicated that all sources of protein kinase activity were substrates for methylation. The specific activity of methyl group incorporation into protein kinase increased with increasing purity of the preparation, reaching values of 1.72 pmol CH3/micrograms protein or 0.15-1.12 mol CH3/mol of holoenzyme. Analysis of ATP binding in cytosol with the use of the photoaffinity probe [32P]8-azido-ATP indicated that carboxylmethylation reduced ATP binding. These results suggest that carboxylmethylation of Ca2+-calmodulin protein kinase may modulate the activity of this enzyme in rat brain.

Identification of endogenous calmodulin-dependent kinase and calmodulin-binding proteins in cold-stable microtubule preparations from rat brain

Calmodulin-dependent kinase activity was investigated in cold-stable microtubule fractions. Calmodulin-dependent kinase activity was enriched approximately 20-fold over cytosol in cold-stable microtubule preparations. Calmodulin-dependent kinase activity in cold-stable microtubule preparations phosphorylated microtubule-associated protein-2, alpha- and beta-tubulin, an 80,000-dalton doublet, and several minor phosphoproteins. The endogenous calmodulin-dependent kinase in cold-stable microtubule fractions was identical to a previously purified calmodulin-dependent kinase from rat brain by several criteria including (1) subunit molecular weights, (2) subunit isoelectric points, (3) calmodulin-binding properties, (4) subunit autophosphorylation, (5) calmodulin-binding subunit composition on high-resolution sodium dodecyl sulfate-polyacrylamide gel electrophoresis, (6) isolation of kinase on calmodulin affinity resin, (7) kinetic parameters, (8) phosphoamino acid phosphorylation sites on beta-tubulin, and (9) phosphopeptide mapping. Endogenous cold-stable calmodulin-dependent kinase activity was isolated from the microtubule fraction by calmodulin affinity resin column chromatography and specifically eluted with EGTA. This kinase fraction contained the calmodulin-binding, autophosphorylating rho and sigma subunits of the previously purified kinase. The rho and sigma subunits of this kinase represented the major calmodulin-binding proteins in the cold-stable microtubule fractions as assessed by denaturing and non-denaturing procedures. These results indicate that calmodulin-dependent kinase is a major calmodulin-binding enzyme system in cold-stable microtubule fractions and may play an important role in mediating some of the effects of calcium on microtubule and cytoskeletal dynamics.

Tubulin-associated calmodulin-dependent kinase: evidence for an endogenous complex of tubulin with a calcium-calmodulin-dependent kinase

A Ca2+ -calmodulin kinase that phosphorylates tubulin and microtubule-associated proteins as major substrates has been purified and characterized from brain cytoplasm. It is important to determine if cytoskeletal proteins are major natural substrates for this kinase system. This report demonstrates that a significant fraction of brain cytosolic calmodulin-dependent kinase activity exists in tight association with tubulin in the form of a stable complex. The tubulin-calmodulin kinase complex displayed an apparent molecular weight on gel filtration of approximately 1.8 X 10(6) daltons. The specific activity of tubulin kinase in the complex was enriched over 20-fold in comparison with brain cytosol. Although purified tubulin alone did not adhere to a calmodulin column, the tubulin associated with the calmodulin kinase complex did bind specifically to the calmodulin affinity resin. The kinase activity was shown to be tightly associated in complex with tubulin by (1) copurification, (2) isolation on gel filtration chromatography, (3) isolation on ion-exchange chromatography, and (4) binding to calmodulin. The kinase complexed with tubulin was identical to the previously purified kinase as judged by several criteria including (1) subunit molecular weights, (2) isoelectric points, (3) autophosphorylation characteristics, (4) calmodulin binding properties, (5) kinetic parameters of tubulin phosphorylation, (6) phosphoamino acid phosphorylation sites on alpha- and beta-tubulin, and (7) identical subunit 125I-tryptic peptide maps. The results indicate that a significant fraction of this previously purified calmodulin kinase is endogenously associated with tubulin in brain cytoplasm and may play a role in mediating some of the effects of calcium on neuronal function.

Calmodulin-dependent protein kinase (kinase II) which is involved in the activation of tryptophan 5-monooxygenase catalyzes phosphorylation of tubulin

Tubulin was shown to be an endogenous substrate of the calmodulin-dependent protein kinase (kinase II), which is involved in the activation of tryptophan 5-monooxygenase [T. Yamauchi and H. Fujisawa (1983) Eur. J. Biochem. 132, 15-21]. Serine and threonine were identified as the phosphate acceptor amino acids of tubulin. The Vmax of the phosphorylation of tubulin and the apparent Km value for tubulin of calmodulin-dependent protein kinase II were 89 nmol phosphate transferred min-1 mg kinase II-1 and 1.7 microM, respectively. The maximum 32P incorporation into tubulin was 0.18 mol Pi/mol alpha-tubulin and 0.13 mol Pi/mol beta-tubulin. The phosphorylation of tubulin was decreased by the denaturation of tubulin. The phosphorylation of tubulin by kinase II did not affect the assembly of microtubules.

Identification of the major postsynaptic density protein as homologous with the major calmodulin-binding subunit of a calmodulin-dependent protein kinase

The major postsynaptic density protein (mPSDp), comprising greater than 50% of postsynaptic density (PSD) protein, is an endogenous substrate for calmodulin-dependent phosphorylation as well as a calmodulin-binding protein in PSD preparations. The results in this investigation indicate that mPSDp is highly homologous with the major calmodulin-binding subunit (p) of tubulin-associated calmodulin-dependent kinase (TACK), and that PSD fractions also contain a protein homologous with the sigma-subunit of TACK. Homologies between mPSDp and a 63,000 dalton PSD protein and the rho- and sigma-subunits of TACK were established by the following criteria: (1) identical apparent molecular weights; (2) identical calmodulin-binding properties; (3) manifestation of Ca2+-calmodulin-stimulated autophosphorylation; (4) identical isoelectric points; (5) identical calmodulin binding and autophosphorylation patterns on two-dimensional gels; (6) homologous two-dimensional tryptic peptide maps; and (7) similar phosphoamino acid-specific phosphorylation of tubulin. The results suggest that mPSDp is a calmodulin-binding protein involved in modulating protein kinase activity in the postsynaptic density and that a tubulin kinase system homologous with TACK exists in a membrane-bound form in the PSD.

Calcium uptake and calcium-dependent phosphorylation during development of rat brain neurons in culture

The emergence of the capacities for calcium uptake and calcium-regulated protein phosphorylation during the development of embryonic brain neurons in tissue culture was examined. In the maturing cells, the enhancement in 45Ca2+-uptake upon stimulation with high K+ increased by 3-4 fold during the second week in vitro, in parallel to an increase in the capacity for high K+-induced Ca2+-dependent release of prelabeled [3H]dopamine. The pattern of incorporation of [32Pi]phosphate into the major phosphoproteins in maturing cells under nonstimulating conditions also changed during cell development: the incorporation of 32Pi into two proteins of apparent molecular weights--55,000 and 43,000 dalton--increased, but decreased in a 45,000 dalton protein. Stimulation of mature cells (after 10-11 days in vitro) resulted in a Ca2+-dependent increase in the amount of 32Pi incorporated into the 43,000 dalton protein and a decrease in the amount incorporated into the 55,000 dalton protein. This calcium-regulated phosphorylation pattern was not observed until 6 days in vitro. Introduction of Ca2+ into the immature cells by means of the Ca2+ ionophore A23187 did not alter the phosphorylation pattern and did not cause neurotransmitter release. The amount of [35S]methionine incorporated into a 43,000 dalton protein which comigrated with the 43,000 dalton phosphoprotein also increased upon cell maturation. The results suggest that this phosphoprotein (which does not comigrate with nonphosphorylated actin on two-dimensional polyacrylamide gels) develops in the cells in parallel to the emerging processes of the stimulation-induced calcium entry and calcium-dependent neurosecretion.

Calmodulin systems in neuronal excitability: a molecular approach to epilepsy

Calmodulin is a major Ca2+ -binding protein that may mediate many Ca2+ -regulated processes in neuronal function. Calmodulin is present in the presynaptic nerve terminal in association with synaptic vesicles and in postsynaptic density fractions. Several calmodulin-regulated synaptic biochemical processes have been identified. These results indicate that calmodulin may modulate some aspects of neuronal excitability. Phenytoin, carbamazepine, and the benzodiazepines inhibit Ca2+ -calmodulin-regulated protein phosphorylation and neurotransmitter release by synaptic vesicles. A saturable, stereospecific membrane binding site has been identified for the benzodiazepines. The potency of the benzodiazepines to bind to these sites correlates with their ability to inhibit maximal electroshock-induced seizures. Phenytoin and carbamazepine can displace benzodiazepine binding from these binding sites. Binding to these "anticonvulsant" sites regulates Ca2+ -calmodulin-stimulated membrane protein phosphorylation and depolarization-dependent Ca2+ uptake in intact synaptosome preparations. These results provide evidence that major anticonvulsant drugs regulate Ca2+ -calmodulin systems at the synapse. Kindling alters Ca2+ -calmodulin protein phosphorylation in brain membrane. In addition, alterations in Ca2+ -calmodulin kinase systems have been associated with some strains of seizure-susceptible mice. Thus, evidence from multiple sources suggests that calmodulin-mediated processes may play a role in the development of altered neuronal excitability and in some forms of seizure disorders.

Properties of a calmodulin-activated Ca2+-dependent protein kinase from wheat germ

A soluble protein kinase that is largely dependent upon Ca2+ for activity was partially purified from wheat germ. The protein kinase (Mr 90 000) catalyzes the phosphorylation of casein, histones and of endogenous proteins. Calmodulin activates the protein kinase with histone as substrate, half-maximal activation being obtained with 1.4 microM sheep brain calmodulin. The rate of casein phosphorylation is half-maximal at 0.3 microM free Ca2+ and maximal at 2.0 microM free Ca2+. Higher Ca2+ is required for histone phosphorylation, namely 80 microM and 500 microM free Ca2+, respectively, for half-maximal and maximal phosphorylation rates. In addition to Ca2+, millimolar Mg2+ is required for maximal activity of the enzyme; millimolar Mn2+ can substitute for the (Ca2+ + Mg2+) requirement. The Km for ATP is 31 microM; other nucleoside 5'-triphosphates and ADP inhibit phosphoryl transfer from ATP to protein. Serine and threonine residues of casein or histones are phosphorylated by the enzyme. The protein kinase is inhibited by relatively high concentrations of chlorpromazine and fluphenazine. The low free Ca2+ required for activation of the enzyme suggests that this type of Ca2+-dependent protein kinase may be involved in Ca2+-mediated stimulus-response coupling in plants.

A multifunctional calmodulin-dependent protein kinase. Similarities between skeletal muscle glycogen synthase kinase and a brain synapsin I kinase

Calmodulin-dependent glycogen synthase kinase isolated from skeletal muscle and synapsin I kinase II isolated from brain have several properties that are very similar. These properties include: substrate and site-specificities, immunological cross-reactivity, and phosphopeptide maps following limited proteolysis. Both enzymes phosphorylate a wide variety of substrate proteins. The two kinases may represent different isozymes of a multifunctional calmodulin-dependent protein kinase that mediates many of the actions of Ca2+ in various tissues. Therefore, we propose the name 'calmodulin-dependent multi-protein kinase' for this broad specificity enzyme.

Calmodulin-stimulated protein kinase activity from rat pancreas

Previous work from our laboratory has demonstrated that neurohumoral stimulation of the exocrine pancreas is associated with the phosphorylation of the Mr 29,000 ribosomal protein S6. In a cell-free system using pancreatic postmicrosomal supernatant as the kinase donor, we found that the following co-factors stimulate the phosphorylation of the Mr 29,000 ribosomal protein: calcium with calmodulin, calcium with phosphatidyl serine, and cAMP. These findings suggest that the pancreas contains a calcium-calmodulin-dependent protein kinase (CaM-PK) that can phosphorylate the Mr 29,000 ribosomal protein. A CaM-PK activity was partially purified sequentially by ion exchange, gel filtration, and calmodulin-affinity chromatography. Phosphorylation of the Mr 29,000 ribosomal protein by the partially purified CaM-PK was dependent on the presence of both calcium and calmodulin and not on the other co-factors. The CaM-PK fraction contained a phosphoprotein of Mr 51,000 whose phosphorylation was also dependent on calcium and calmodulin. When 125I-calmodulin-binding proteins from the CaM-PK fraction were identified using electrophoretic transfers of SDS-polyacrylamide gels, a single Mr 51,000 protein was labeled. The preparation enriched in CaM-PK activity contained an Mr 51,000 protein that underwent phosphorylation in a calcium-calmodulin-dependent manner and an Mr 51,000 calmodulin-binding protein. It is therefore possible that the CaM-PK may comprise a calmodulin-binding phosphoprotein component of Mr 51,000.

Purification and characterization of myosin light-chain kinase from porcine myometrium and its phosphorylation and modulation by cyclic AMP-dependent protein kinase

Myosin light-chain kinase was purified from porcine myometrium to apparent homogeneity at about 262-fold with an Mr of 130 000 as determined by SDS-polyacrylamide gel electrophoresis and a sedimentation coefficient of 4.5 S. The approximate content of the soluble myosin light-chain kinase was estimated to be about 0.85 microM. The purified enzyme exhibited strict substrate specificity only for 20-kDa myosin light chain and Ka values of 0.6 nM and 0.3 microM for calmodulin and Ca2+, respectively. The enzyme was phosphorylated by the catalytic subunit of cyclic AMP-dependent protein kinase, which resulted in a decrease in the affinity for calmodulin of 4-7-fold without effect on the Vmax. The maximal amount of phosphate incorporated into the enzyme was 0.5-0.8 and 1.0-1.4 mol per mol of the enzyme in the presence and absence of Ca2+ and calmodulin, respectively. In the presence of a subsaturating concentration of calmodulin, the enzyme showed a lower sensitivity for Ca2+ by phosphorylation.

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.