Tetanus Toxin Inhibits Depolarization-Stimulated Protein Phosphorylation in Rat Cortical Synaptosomes: Effect on Synapsin I Phosphorylation and Translocation

Synapsin I, a prominent phosphoprotein in nerve terminals, is proposed to modulate exocytosis by interaction with the cytoplasmic surface of small synaptic vesicles and cytoskeletal elements in a phosphorylation-dependent manner. Tetanus toxin (TeTx), a potent inhibitor of neurotransmitter release, attenuated the depolarization-stimulated increase in synapsin I phosphorylation in rat cortical particles and in synaptosomes. TeTx also markedly decreased the translocation of synapsin I from the small synaptic vesicles and the cytoskeleton into the cytosol, on depolarization of synaptosomes. The effect of TeTx on synapsin I phosphorylation was both time and TeTx concentration dependent and required active toxin. One- and two-dimensional peptide maps of synapsin I with V8 proteinase and trypsin, respectively, showed no differences in the relative phosphorylation of peptides for the control and TeTx-treated synaptosomes, suggesting that both the calmodulin- and the cyclic AMP-dependent kinases that label this protein are equally affected. Phosphorylation of synapsin IIb and the B-50 protein (GAP43), a known substrate of protein kinase C, was also inhibited by TeTx. TeTx affected only a limited number of phosphoproteins and the calcium-dependent decrease in dephosphin phosphorylation remained unaffected. In vitro phosphorylation of proteins in lysed synaptosomes was not influenced by prior TeTx treatment of the intact synaptosomes or by the addition of TeTx to lysates, suggesting that the effect of TeTx on protein phosphorylation was indirect. Our data demonstrate that TeTx inhibits neurotransmitter release, the phosphorylation of a select group of phosphoproteins in nerve terminals, and the translocation of synapsin I. These findings contribute to our understanding of the basic mechanism of TeTx action.     

Distribution of Calmodulin- and Cyclic AMP-Stimulated Protein Kinases in Synaptosomes

The subcellular location of calmodulin- and cyclic AMP stimulated protein kinases was assessed in synaptosomes which were prepared on Percoll density gradients. The distribution of the protein kinases between the outside and the inside and between the soluble and membrane fractions was determined by incubating intact and lysed synaptosomes, as well as supernatant and pellet fractions obtained from lysed synaptosomes, in the presence of [gamma-32P]ATP. Protein kinase activity was assessed by the labelling of endogenous proteins, or exogenous peptide substrates, under conditions optimized for either calmodulin- or cyclic AMP-stimulated protein phosphorylation. When assessed by calmodulin-stimulated autophosphorylation of the alpha subunit of calmodulin kinase II, 44% of this enzyme was on the outside of synaptosomes, and 41% was in the 100,000 g supernatant. Using an exogenous peptide substrate, the distribution of total calmodulin-stimulated kinase activity was 27% on the outside and 34% in the supernatant. The high proportion of calmodulin kinase II on the outside of synaptosomes is consistent with its known localization at postsynaptic densities. The proportion of calmodulin kinase II which was soluble depended on the ionic strength conditions used to prepare the supernatant, but the results suggest that a major proportion of this enzyme which is inside synaptosomes is soluble. When assessed by cyclic AMP-stimulated phosphorylation of endogenous substrates, no cyclic AMP-stimulated kinase activity was observed on the outside of synaptosomes, whereas 21% was found with an exogenous peptide substrate. This suggests that if endogenous substrates are present on the outside of synaptosomes, then the enzyme does not have access to them. The cyclic AMP-stimulated protein kinase present inside synaptosomes was largely bound to membranes and/or the cytoskeleton, with only 10% found in the supernatant when assessed by endogenous protein phosphorylation and 25% with an exogenous substrate. The markedly different distribution of the calmodulin- and cyclic AMP-stimulated protein kinases presumably reflects differences in the functions of these enzymes at synapses.     

Synapsin Ia, Synapsin Ib, Protein IIIa, and Protein IIIb, Four Related Synaptic Vesicle-Associated Phosphoproteins, Share Regional and Cellular Localization in Rat Brain

The regional and cellular distribution of four synaptic vesicle-associated proteins, synapsins Ia and Ib (Mr 86,000 and 80,000, collectively referred to as synapsin I) and proteins IIIa and IIIb (Mr 74,000 and 55,000, collectively referred to as protein III), has been compared in selected rat brain regions, using both radioimmunoassays and back-phosphorylation assays. Lesions of several neuronal populations in the basal ganglia (corticostriatal fibers, intrinsic striatal neurons, striatonigral fibers, nigrostriatal fibers) induced decreases in the levels of these various proteins that were highly correlated (r = 0.96-0.97). Moreover, the synaptic vesicle-associated phosphoproteins displayed a similar and widespread distribution throughout the CNS. This evidence for colocalization indicates that the majority of, and possibly all, CNS neurons and nerve terminals may contain both forms of synapsin I and both forms of protein III.     

Protein phosphorylation and synaptic transmission: receptor mediated modulation of protein kinase C in a rat brain fraction enriched in synaptosomes

Aspects of protein phosphorylation related to events occurring during synaptic transmission were briefly reviewed. High resolution two-dimensional electrophoresis was used to study protein phosphorylation catalysed by protein kinase C in a fraction from rat brain enriched in synaptosomes. Incubation of 32P-labelled synaptosomes with 4 beta-phorbol 12 beta-myristate 13 alpha-acetate resulted in an increase in the phosphorylation of a 45 K polypeptide (generally known as B-50) and an 82 K polypeptide; other major phosphoproteins in the preparation were unaffected by this treatment. It appears therefore that the 45 K and 82 K polypeptides are the only significant substrates for protein kinase C in synaptosomes. Depolarisation of labelled synaptosomes by high K+ increased the phosphorylation of the 82 K polypeptide, synapsin I and several unknown phosphoproteins. Incubation of labelled synaptosomes with the cholinergic agonist carbachol resulted in a modest, but statistically significant, increase in the phosphorylation of the 45 K (B-50) and 82 K polypeptides. This effect was blocked by atropine. The results are discussed in relation to a possible role for the B-50 phosphoprotein in regulating the resynthesis of polyphosphoinositides following cholinergic stimulation.     

Ca(2+)-calmodulin-dependent protein kinases Ia and Ib from rat brain I. Identification, purification, and structural comparisons.

Two Ca(2+)-calmodulin (CaM)-dependent protein kinases were purified from rat brain using as substrate a synthetic peptide based on site 1 (site 1 peptide) of the synaptic vesicle-associated protein, synapsin I. One of the purified enzymes was an approximately 89% pure protein of M(r) = 43,000 which bound CaM in a Ca(2+)-dependent fashion. The other purified enzyme was an apparently homogenous protein of M(r) = 39,000 accompanied by a small amount of a M(r) = 37,000 form which may represent a proteolytic product of the 39-kDa enzyme. The 39-kDa protein bound CaM in a Ca(2+)-dependent fashion. Gel filtration analysis indicated that both enzymes are monomers. The 43- and 39-kDa enzymes are named Ca(2+)-CaM-dependent protein kinases Ia and Ib (CaM kinases Ia, Ib), respectively. The specific activities of CaM kinases Ia and Ib were similar (5-8 mumol/min/mg protein). CaM kinase Ia (but not CaM kinase Ib) activity was enhanced by addition of a CaM-Sepharose column wash (non-binding) fraction suggesting the existence of an "activator" of CaM kinase Ia. Both kinases phosphorylated exogenous substrates (site 1 peptide and synapsin I) in a Ca(2+)-CaM-dependent fashion and both kinases underwent autophosphorylation. CaM kinase Ia autophosphorylation was Ca(2+)-CaM-dependent and occurred exclusively on threonine while CaM kinase Ib autophosphorylation showed Ca(2+)-CaM independence and occurred on both serine and threonine. Proteolytic digestion of autophosphorylated CaM kinases Ia and Ib yielded phosphopeptides of differing M(r). These characteristics, as well as enzymatic and regulatory properties (DeRemer, M. F., Saeli, R. J. Brautigen, D. L., and Edelman, A. M. (1992) J. Biol. Chem. 267, 13466-13471), indicate that CaM kinases Ia and Ib are distinct and possibly previously unrecognized enzymes.     

Dephosphorylation of Synaptosomal Proteins P96 and P139 Is Regulated by Both Depolarization and Calcium, but Not by a Rise in Cytosolic Calcium Alone

Depolarization of intact synaptosomes activates calcium channels, leads to an influx of calcium, and increases the phosphorylation of several neuronal proteins. In contrast, there are two synaptosomal phosphoproteins labeled in intact synaptosomes with 32Pi, termed P96 and P139, which appear to be dephosphorylated following depolarization. Within intact synaptosomes P96 was found in the cytosol whereas P139 was present largely in membrane fractions. Depolarization-stimulated dephosphorylation was fully reversible and continued for up to five cycles of depolarization/repolarization, suggesting a physiological role for the phenomenon. The basal phosphorylation of these proteins was at least partly regulated by cyclic AMP, since dibutyryl cyclic AMP produced small but significant increases in P96 and P139 labeling, even in the presence of fluphenazine at concentrations that inhibited calcium-stimulated protein kinases. Depolarization-dependent dephosphorylation was independent of a rise in intracellular calcium, since agents such as guanidine and low concentrations of A23187, which increase intracellular calcium without activating the calcium channel, did not initiate P96 or P139 dephosphorylation. These agents did sustain increases in the phosphorylation of a number of other proteins including synapsin I and protein III. The results suggest that the phosphorylation of these two synaptosomal proteins is intimately linked to the membrane potential and that their dephosphorylation is dependent on both the mechanism of calcium entry and calcium itself, rather than simply on a rise in intracellular free calcium.     

The in vitro phosphorylation of actin from rat cerebral cortex

Actin was phosphorylated by a cyclic AMP-stimulated protein kinase in a lysed synaptosomal fraction incubated with [gamma-32P]ATP, while calcium had no effect on endogenous labeling of the protein. Incubation of an intact synaptosomal fraction with 32P-inorganic phosphate did not lead to any detectable phosphorylation of actin in the presence or absence of dibutyryl-cyclic AMP, or chemical depolarization. It is suggested that actin is not phosphorylated in the physiologically relevant intact synaptosomes but gains access to protein kinases on lysis.     

Depolarisation-Dependent Protein Phosphorylation and Dephosphorylation in Rat Cortical Synaptosomes Is Modulated by Calcium

The effect of calcium on protein phosphorylation was investigated using intact synaptosomes isolated from rat cerebral cortex and prelabelled with 32Pi. For nondepolarised synaptosomes a group of calcium-sensitive phosphoproteins were maximally labelled in the presence of 0.1 mM calcium. The phosphorylation of these proteins was slightly decreased in the presence of strontium and absent in the presence of barium, consistent with the decreased ability of these cations to activate calcium-stimulated protein kinases. Addition of calcium alone to synaptosomes prelabelled in its absence increased phosphorylation of a number of proteins. On depolarisation in the presence of calcium certain of the calcium-sensitive phosphoproteins were further increased in labelling above nondepolarised levels. These increases were maximal and most sustained after prelabelling at 0.1 mM calcium. On prolonged depolarisation at this calcium concentration a slow decrease in labelling was observed for most phosphoproteins, whereas a greater rate and extent of decrease occurred at higher calcium concentrations. At 2.5 mM calcium a rapid and then a subsequent slow dephosphorylation was observed, indicating two distinct phases of dephosphorylation. Of all the phosphoproteins normally stimulated by depolarisation, only phosphoprotein 59 did not exhibit the rapid phase of dephosphorylation at high calcium concentrations. Replacing calcium with strontium markedly decreased the extent of change observed on depolarisation whereas barium decreased phosphorylation changes even further. Taken together these data suggest that an influx of calcium into synaptosomes initially activates protein phosphorylation, but as the levels of intrasynaptosomal calcium rise protein dephosphorylation predominates. Other phosphoproteins were dephosphorylated immediately on depolarisation in the presence of calcium. The fine control of protein phosphorylation levels exerted by calcium supports the idea that the synaptosomal phosphoproteins could play a role in modulating events such as neurotransmitter release in the nerve terminal.     

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.     

Conditions Restricting Depolarization-Dependent Calcium Influx in Synaptosomes Reveal a Graded Response of P96 Dephosphorylation and a Transient Dephosphorylation of P65

Temporal changes in the phosphorylation level of synaptosomal phosphoproteins following depolarization of synaptosomes were investigated under conditions restricting calcium influx. High-K+ depolarization in media of low [Na+]o (32 mM during preincubation and depolarization) at pH 6.5 resulted in a pronounced fall in the cytosolic free calcium concentration transient, and in a reduction in the initial K(+)-stimulated 45Ca2+ uptake and endogenous acetylcholine release relative to the values obtained with control synaptosomes (preincubated and depolarized in Na(+)-based media). This reduction was paralleled by a decrease in the rate of dephosphorylation of the synaptosomal protein P96. A slower dephosphorylation of P96 also was observed on exposure to 20 microM veratridine at 0.5 mM external calcium. Our results indicate that, similar to synapsin I phosphorylation, P96 dephosphorylation shows a graded response to the amount of calcium entering the presynaptic terminal. Depolarization of synaptosomes under conditions restricting the influx of calcium revealed a transient dephosphorylation (reversed within 10 s) of the phosphoprotein P65. The possible significance of this finding to the process of neurotransmitter release is discussed.     

Dephosphin, a 96,000 Da substrate of protein kinase C in synaptosomal cytosol, is phosphorylated in intact synaptosomes

A 96,000 dalton phosphoprotein, called dephosphin, is phosphorylated in intact synaptosomes from rat brain and is rapidly dephosphorylated upon depolarisation-dependent calcium entry. A 96,000 dalton phosphoprotein is also a substrate of protein kinase C in synaptosomal cytosol, and the aim of the study was to determine whether the two proteins may be the same. Dephosphin in intact synaptosomes and the 96,000 dalton protein kinase C substrate comigrated on polyacrylamide gels. Both phosphoproteins had identical phosphopeptide maps after digestion with V8 protease. Both phosphoproteins ran on isoelectric focussing gels with a pI of 6.3-6.7 and focussed as a series of 5-6 spots. Both proteins were phosphorylated exclusively on serine. Both proteins could be resolved into a doublet on longer polyacrylamide gels. The two subunits were of 96 and 93 kDa in both phosphorylation conditions and had dissimilar phosphopeptide maps. However, phosphopeptide maps of either the 96 or 93 kDa subunits were identical in intact synaptosomes compared with synaptosomal cytosol. These results show that a phosphoprotein phosphorylated in intact synaptosomes and a 96,000 dalton protein kinase C substrate from rat brain synaptosomal cytosol are the same, and raise the possibility that protein kinase C is the protein kinase responsible for dephosphin phosphorylation in intact synaptosomes.     

Actin and tubulin binding domains of synapsins Ia and Ib

Synapsins Ia and Ib are neuronal phosphoproteins involved with the regulated clustering of small synaptic vesicles at the presynaptic terminus. In vitro they bind and bundle filaments of both actin and tubulin. Previously, we identified an actin binding domain in the NH2-terminal 25-kDa fragment (N25) generated by 2-nitro-5-thiocyanobenzoic acid (NTCB) cleavage of synapsin I and found that a complementary COOH-terminal 52-kDa portion of the molecule (N52) contained either a second actin binding site or a site of self-association [Petrucci, T. P., & Morrow, J. S. (1987) J. Cell. Biol. 105, 1355]. Using direct binding assays between actin, tubulin, and specific synapsin NTCB-derived peptides, we confirm the ability of purified N25 to bind but not bundle actin and demonstrate that the complementary N52 (or N50) fragments from synapsins Ia and Ib and a 14-kDa fragment derived from the middle of the molecule also associate directly with actin. An antibody specific for N25 inhibits the actin binding activity of N25 and the actin bundling but not the actin binding activity of intact synapsin I. Similar studies conducted with purified tubulin and tubulin immobilized on Sepharose demonstrate that both tubulin and actin bind at approximately the same sites in the NH2-terminal half of synapsin I. Although the fragments derived from the COOH terminus of both synapsin Ia and synapsin Ib (N40b/N34) were devoid of measurable actin binding activity after NTCB cleavage, they were specifically labeled in the intact molecule by a photoactivated cross-linker bound to F-actin. Collectively, these results indicate that synapsins Ia and Ib possess two actin and tubulin binding domains located in the NH2-terminal half of the molecule and suggest that a third actin binding domain is located in the COOH-terminal region. The NH2-terminal sites are found in NTCB peptides N25 and N14, while the third site, apparently of lower affinity, resides in N40b/N34. It is hypothesized that, in the intact molecule, the two NH2-terminal domains contribute to a single high-affinity actin and/or tubulin binding site in the "globular" head region of synapsin I, while the third actin binding domain constitutes the topographically distinct site required for the actin bundling activity of the native molecule. The 45-residue COOH extension that distinguishes synapsin Ia from synapsin Ib appears not to be involved with actin binding, since no differences were found in the ability of N40b and N34 to be photo-cross-linked to actin.(ABSTRACT TRUNCATED AT 400 WORDS)     

Introduction of Impermeant Molecules into Synaptosomes Using Freeze/Thaw Permeabilization

Brief freezing as a means of transiently permeabilizing synaptosomes was explored. Rat brain synaptosomes frozen and thawed in the presence of 5% dimethyl sulfoxide, a cryoprotectant, were shown to release, in a calcium-dependent manner, previously accumulated [3H]norepinephrine and [14C]acetylcholine in response to elevated [K+]. In addition, synaptosomes subjected to freeze/thaw were shown to retain their ability to exhibit resting protein phosphorylation, as well as stimulated protein phosphorylation occurring in response to calcium influx. Brief freezing of synaptosomes in the presence of [gamma-32P]ATP and either the catalytic subunit of cyclic AMP-dependent protein kinase or calcium/calmodulin-dependent protein kinase II rendered the synaptosomal interior accessible to these agents, as reflected by the phosphorylation of substrate proteins, such as synapsin I, which reside within the nerve terminal. Inclusion of inhibitors of these protein kinases during freeze/thaw blocked synaptosomal protein phosphorylation, indicating that the inhibitors were also introduced. After freezing, the synaptosomes resealed rapidly and spontaneously, as shown by the inability of any of the agents to elicit an effect on phosphorylation when added at the end of the freezing period. The permeabilization procedure should contribute to an understanding of the functional roles of phosphoproteins, and of their associated protein kinases and protein phosphatases, in nerve terminals.     

5''-Halogeno-2'',3''-cyclic sulphite isomers in the preparation of 5''-halogeno nucleosides. Synthesis of 5''-deoxyuridine and 5''-deoxy-5-fluorouridine.

When uridine (Ia) is reacted with thionyl chloride in hexamethylphosphoric triamide a mixture of isomeric 5'-chloro-2',3'-sulphites is formed, which can be separated to individual epimers IIa and IIIa, in 45% and 15% yields, respectively. Analogously, crystalline epimers IIb (37%) and IIIb (17%) can be obtained from 5-fluorouridine (Ib). Both isomers IIa, IIIa (or IIb, IIIb) afford a single 5'-chloro derivative IVa (or IVb, respectively) if treated with 0.1N sodium methoxide. From the mixture of sulphites IIa and IIIa (or IIb and IIIb) crystalline 5'-chlorouridine IVa is formed in 84.5% yield, calculated per starting uridine Ia (or crystalline 5'-chloro-5-fluorouridine IVb, 85.5% per starting 5-fluorouridine Ib, respectively). On reduction of 5'-chlorouridine IVa with tributyltin hydride 5'-deoxyuridine (Va) is formed in 79% yield. During the reduction of 5'-chloro-5-fluoro derivative IVb to 5'-deoxy-5-fluorouridine (Vb, 57%) a partial reductive elimination of 5-fluorine takes place under formation of 5'-deoxyuridine (Va, 9%).     

Phosphorylation of B-50 Protein by Calcium-Activated, Phospholipid-Dependent Protein Kinase and B-50 Protein Kinase

B-50 is a brain-specific phosphoprotein, the phosphorylation state of which may play a role in the regulation of (poly)phosphoinositide metabolism. Several kinases were tested for their ability to phosphorylate purified B-50 protein. Only calcium-activated, phospholipid-dependent protein kinase (kinase C) and B-50 protein kinase were able to use B-50 protein as a substrate. Furthermore, kinase C specifically phosphorylates B-50 when added to synaptic plasma membranes. We further characterized the sensitivity of kinase C and B-50 kinase to ACTH (and various fragments), phospholipids, chlorpromazine, and proteolytic activation. Since the sensitivities of both kinases were similar, we conclude that B-50 protein kinase is a calcium-dependent, phospholipid-stimulated protein kinase of the same type as kinase C.     

Phosphorylation of external cell-surface proteins by an endogenous ecto-protein kinase of goat epididymal intact spermatozoa

Intact spermatozoa from goat cauda epididymides possess an ecto-(cyclic AMP-independent protein kinase) activity that causes transfer of the terminal phosphate of exogenously added [gamma-32P]ATP to the serine and threonine residues of several endogenous plasma-membrane phosphoproteins located on the external cell surface. Cyclic AMP, cyclic GMP, calmodulin and muscle cyclic AMP-dependent protein kinases I and II had no appreciable effect on the rate of phosphorylation of ecto-proteins by the intact cells. The ecto-enzyme is not derived from the catalytic subunit of a cyclic AMP-dependent kinase. Sperm ecto-kinase activity is not due to contamination of broken cells or any possible cell damage during incubation and isolation of spermatozoa. The phosphorylation reaction was linear for approx. 1 min and there was no detectable uptake of ATP by these cells. The activity of the ecto-kinase was strongly inhibited by proteinases and by the membrane-nonpenetrating surface probes. The products of the reaction were associated with the intact cells and the 32P of the labelled cells was largely lost when treated with Triton X-100 or proteinases: trypsin and pronase. These data are consistent with the view that the observed protein kinase and the phosphoproteins are located on the external surface of spermatozoa. Vigorously forward-motile whole spermatozoa showed a relatively high capacity to phosphorylate ecto-proteins that undergo rapid turnover. The results suggest the occurrence of a novel coupled-enzyme system (ecto-protein kinase and phosphoprotein phosphatase) on the sperm external surface that may modulate sperm physiology by determining the phosphorylated states of the ecto-proteins.     

Characterization of human blood platelet membrane proteins and glycoproteins by their isoelectric point (pI) and apparent molecular weight using two-dimensional electrophoresis and surface-labelling techniques

Intact human blood platelets were radioactively labelled at the surface by techniques specific for proteins or glycoproteins. Labelled platelet samples were analyzed by a high-resolution two-dimensional separation system involving isoelectric focusing in the first dimension and discontinuous sodium dodecyl sulphate-polyacrylamide gel electrophoresis in the second. The major platelet membrane glycoprotein (GP) bands (Ib, IIb, IIIa and IIIb) were found to be highly heterogeneous even after removal of terminal sialic acid residues. Lactoperoxidase-catalyzed iodination of platelets showed that the major labelled proteins (Ib, IIb, IIIa and IIIb) had altered isoelectric points ($\text{p}\text{I}$) and molecular weights after neuraminidase treatment. A number of membrane glycoproteins previously undetected by one-dimensional gel electrophoresis were demonstrated and good evidence provided that the major platelet surface proteins are glycosylated.     

Regulation of Synaptotagmin I Phosphorylation by Multiple Protein Kinases

Synaptotagmin I has been suggested to function as a low-affinity calcium sensor for calcium-triggered exocytosis from neurons and neuroendocrine cells. We have studied the phosphorylation of synaptotagmin I by a variety of protein kinases in vitro and in intact preparations. SyntagI, the purified, recombinant, cytoplasmic domain of rat synaptotagmin I, was an effective substrate in vitro for Ca2+/calmodulin-dependent protein kinase II (CaMKII), protein kinase C (PKC), and casein kinase II (caskII). Sequencing of tryptic phosphopeptides from syntagI revealed that CaMKII and PKC phosphorylated the same residue, corresponding to Thr112, whereas caskII phosphorylated two residues, corresponding to Thr125 and Thr128. Endogenous synaptotagmin I was phosphorylated on purified synaptic vesicles by all three kinases. In contrast, no phosphorylation was observed on clathrin-coated vesicles, suggesting that phosphorylation of synaptotagmin I in vivo occurs only at specific stage(s) of the synaptic vesicle life cycle. In rat brain synaptosomes and PC12 cells, K+-evoked depolarization or treatment with phorbol ester caused an increase in the phosphorylation state of synaptotagmin I at Thr112. The results suggest the possibility that the phosphorylation of synaptotagmin I by CaMKII and PKC contributes to the mechanism(s) by which these two kinases regulate neurotransmitter release.     

On the disposition of a phosphorylated protein (“synapsin I”) and its associated kinases in synaptosomes from rat brain

Endogenous phosphorylation of synapsin I (protein I), a phosphoprotein located on the surface of synaptic vesicles, was studied in vesicles prepared from synaptosomes lysed in the absence (control) or presence of 50 M-cyclic AMP (cAMP-treated). Compared to synaptic plasma membrane (SPM) fractions prepared in parallel, and confirming previous work, the vesicle fractions were highly enriched on a unit protein basis in Ca²⁺-calmodulin-dependent kinase activity towards synapsin I. In contrast, with control vesicles the magnitude of the total phosphorylation of synapsin I in the presence of cyclic AMP was similar to that observed in SPM, but regulation by cyclic AMP was only partial. In cAMP-treated vesicles, however, synapsin I phosphorylation was highly enriched compared to SPM and the activity was virtually independent of cyclic AMP. The results show that while the free catalytic subunit of the cyclic AMP-dependent kinase remains associated with synapsin I during vesicle isolation the holoenzyme remains bound to membrane fragments, probably through its regulatory subunit.Dedicated to Henry McIlwain.     

Phosphopeptide and phosphoprotein metabolism in brain

Phosphopeptide and phosphoprotein phosphorylation was studied in rat brain microsomes and rat brain slices which were incubated in the presence of [γ-³²P] ATP under various experimental conditions. Radioactive phosphoserine was isolated from phosphopeptides and phosphoproteins.Na⁺, K⁺, Mg²⁺ and cyclic AMP had a stimulating effect on the labelling of phosphopeptides. Ouabain and Ca²⁺ lowered the level of ³²P incorporation into the phosphopeptides.The phosphoproteins behaved similarly to the phosphopeptides except for the potassium effect.Chase experiments showed a faster decrease in the labelling of phosphopeptides than in phosphoproteins. We suggest that both compounds may be involved in active transport phenomena.