Protein phosphorylation in synaptic membranes regulated by adenosine 3':5'-monophosphate: regional and subcellular distribution of the endogenous substrates

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.

Phosphorylation of the neuronal protein kinase C substrate B-50: in vitro assay conditions alter sensitivity to ACTH

We have explored the hypothesis that changes in the in vitro assay conditions alter both the extent of endogenous phosphorylation of B-50 protein in synaptosomal plasma membrane (SPM) and also the ability of the neuropeptide, ACTH-(1-24) to inhibit the phosphorylation of this protein. B-50 phosphorylation is influenced by preincubation, pH and ionic strength. ACTH-(1-24)-induced inhibition of B-50 phosphorylation varies with ionic strength and SPM protein concentration. Reduction of the buffer ionic strength and the SPM protein concentration enhances the ability of ACTH-(1-24) to inhibit B-50 phosphorylation. Furthermore, loss of ACTH-(1-24) by adsorption to plastic pipettes and test tubes reduces the peptide concentration in the assay. Addition of a low concentration of bovine serum albumin (BSA) essentially eliminates this loss without affecting the extent of phosphate incorporation into B-50. These data provide an explanation for the relatively high (and variable) IC50 values for ACTH-(1-24)-induced inhibition of B-50 phosphorylation reported in the literature. Further, these data suggest that in vitro assay conditions must be carefully investigated before modulation of protein phosphorylation can adequately be studied.

Calcium binding to tubulin

Using flow dialysis, we found two classes of calcium-binding sites on tubulin: high-affinity binding sites (1.56 +/- 0.38 per tubulin dimer) with a dissociation constant of (4.86 +/- 0.12).10(-6) M and low-affinity binding sites (5.82 +/- 0.50 per tubulin dimer) with a dissociation constant of (6.4 +/- 0.4).10(-5) M. In the presence of 6.10(-5) M MgSO4, we found 0.64 +/- 0.18 calcium-binding sites per tubulin dimer with a dissociation constant of (4.7 +/- 0.5).10(-6) M and 1.2 +/- 0.2 sites per dimer with a dissociation constant of (3.5 +/- 0.4).10(-5) M. Under controlled conditions, trypsin and chymotrypsin selectively cleaved alpha- and beta-subunits, respectively, forming major fragments of 35 kDa and 20 kDa from the alpha-subunit, and major fragments of 31 kDa and 22 kDa from the beta-subunit. The high-affinity calcium-binding sites were detected in the carboxyl-terminal region of each tubulin subunit. Computer analysis of the subunit amino-acid sequences suggested possible locations of the putative calcium-binding sites.

Demonstration by phase-partitioning in Triton X-114 solutions that phosphoprotein B-50 (F-1) from rat brain is an integral membrane protein

The Triton X-114 phase separation technique was employed to fractionate phosphoproteins present in membrane fragments from rat brain. Membranes were labelled with [gamma-32P]ATP in media containing Ca2+, Ca2+ plus calmodulin or cyclic AMP, and then treated with Triton X-114. Phosphoproteins recovered in the detergent-insoluble fraction, aqueous and detergent phases were detected by SDS-polyacrylamide gel electrophoresis and autoradiography. Of the proteins solubilised by the detergent, a known substrate of protein kinase C, the B-50 phosphoprotein (45 kD; also known as F-1), partitioned quantitatively into the detergent-rich phase, making it very probable that this phosphoprotein is an integral membrane protein. The detergent-rich phase also contained an 80 kD phosphoprotein, which probably corresponds to the widespread acidic 87 kD substrate of protein kinase C.

Demonstration and purification of an endogenous benzodiazepine from the mammalian brain with a monoclonal antibody to benzodiazepines

Four hybridoma lines secreting monoclonal antibodies to benzodiazepines were produced after BALB/c mice were immunized with a benzodiazepine-bovine serum albumin conjugate. The monoclonal antibodies were purified from ascites fluids, and their binding affinities for benzodiazepines and other benzodiazepine receptor ligands were determined. These antibodies have very high binding affinities for diazepam, flunitrazepam, Ro5-4864, Ro5-3453, Ro11-6896, and Ro5-3438 (the Kd values are in the 10(-9) M range). However, these antibodies have very low affinities for the benzodiazepine receptor inverse agonists (beta-carbolines) and antagonists (Ro15-1788 and CGS-8216). One of the monoclonal antibodies (21-7F9) has been used to demonstrate the existence of benzodiazepine-like molecules in the brain and for the purification of these molecules. Immunocytochemical experiments show that these molecules are neuronal and not glial and that they are ubiquitously distributed throughout the brain. Immunoblots indicate the presence of benzodiazepine-like epitopes in several brain peptides. An endogenous substance that binds to the central-type benzodiazepine receptor with agonist properties has been purified to homogeneity from the bovine brain. The purification consisted on immunoaffinity chromatography on immobilized monoclonal anti-benzodiazepine antibody followed by gel filtration on Sephadex G-25 and two reverse phase HPLCs. The purified substance has a small molecular weight and its activity is protease resistant. The endogenous substance blocks the binding of agonists, inverse agonists and antagonists to the central-type benzodiazepine receptor but it does not inhibit the binding of Ro5-4864 to the peripheral-type benzodiazepine receptor. The neurotransmitter gamma-aminobutyric acid increases the affinity of the benzodiazepine receptor for the purified substance. Preliminary evidence indicates that the purified substance is a benzodiazepine with a molecular structure that is identical or very close to N-desmethyldiazepam.

Detection and characterization of some new basic proteins in chicken postsynaptic densities

Chicken brain postsynaptic density (PSD) polypeptides, obtained by treating synaptosomes with 0.5% Triton X-100 and then further purified on a sucrose gradient, are demonstrated to contain four basic proteins of 76K (pI greater than 9.2), 58K (pI 8.1-8.8, heterogeneous), 40K (pI 9.0), and 24K (pI 8.9). Nonequilibrium pH gradient-sodium dodecyl sulfate two-dimensional gels further reveal six more basic proteins with pI values higher than 9.2: 76K, 52K, 47K, 45K, 36K, and 34K. These basic proteins are a major part of the total chicken PSD polypeptides appearing on the gels. Some of these basic proteins (58K, 52K, 47K, 36K, 24K, and two at 76K) are distinguishable from those of brain mitochondria, the major contaminant. The 40K and 34K proteins may be common mitochondrial polypeptides. The 45K protein is probably a mitochondrial contaminant. A number of proteins including 76K (synapsin I-like protein) and 58K, along with some other minor ones, can be phosphorylated by endogenous protein kinase(s) in the presence of Ca2+, Mg2+, and [gamma-32P]ATP. No PSD basic proteins bind Ca2+.

Calcium-binding proteins in whole brain and synaptic subfractions

At least 19 calcium-binding proteins were detected in avian brain subfraction using 45Ca2+ binding to proteins immobilized in polyacrylamide gels. Half of the 45Ca2+ binding proteins were observed in presynaptic cytoplasm. Two-dimensional gel electrophoresis of this material revealed at least 14 45Ca2+ binding polypeptides besides calmodulin. These proteins may be important in brain and nerve terminal function.

Demonstration of benzodiazepine-like molecules in the mammalian brain with a monoclonal antibody to benzodiazepines

An anti-benzodiazepine monoclonal antibody has been used to demonstrate the existence of benzodiazepine-like molecules in the brain. Immunocytochemical experiments show that these molecules are neuronal and not glial and that they are ubiquitously distributed throughout the brain. Immunoblots indicate the presence of benzodiazepine-like epitopes in several brain peptides. Small benzodiazepine-like molecules were isolated from the brain soluble fraction by immunoaffinity chromatography. They block the binding of agonists, inverse agonists, and antagonists to the neuronal-type benzodiazepine receptor. The neurotransmitter gamma-aminobutyric acid increases the affinity of the benzodiazepine receptor for the purified endogenous molecules. The results indicate that the immunoaffinity-purified molecules behave like the neuronal-type benzodiazepine receptor agonists. The purified molecules, however, do not inhibit the binding of tritiated Ro 5-4864 to the "peripheral-type" benzodiazepine receptor. The results demonstrate the existence of benzodiazepine-like molecules in the brain that bind to the benzodiazepine receptor. These molecules are different from the endogenous benzodiazepine receptor ligands reported by others.

The postsynaptic density: a possible role in long-lasting effects in the central nervous system

A theory is proposed that biochemical changes at the synapse that occur as a result of stimulation of specific neuronal circuits can lead to long-term changes only if alterations occur in synaptic structures in these circuits. The main synaptic structure that is thought to undergo this alteration is the postsynaptic density (PSD). There are many reports in the literature of overall structural changes at the synapse, including the PSD, resulting from various neuronal stimuli. These structural changes are here envisaged to include those of concentration and conformation of PSD proteins, changes that could alter the neural physiology of dendritic spines and even that of the presynaptic terminal.

Effects of ATP gamma S in isolated rat brain synaptosomes

The effects of ATP gamma S, a slowly hydrolyzable analogue of ATP, were investigated in the preparation of synaptosomes isolated from rat cerebral cortex. It was found that addition of [35S]ATP gamma S resulted in substantial magnesium-dependent incorporation of 35S into synaptosomal proteins which was prevented completely by ATP. The most prominently labeled polypeptides were those with apparent molecular weights of 100,000; 84,000; 74,000; 62,000; 55,000; 48,000; and 41,000. The rate and extent of thiophosphorylation were unaffected by addition of cAMP, veratridine or sodium fluoride. ATP gamma S at 50-100 microM had no effect on either uptake or release of gamma-aminobutyric acid (GABA) and dopamine; at a concentration of 1 mM it inhibited incorporation of dopamine by about 20%. This inhibition was also seen with 1 mM GTP, beta, gamma-methylene-adenosine 5'-triphosphate and adenylylimidodiphosphate, which suggests that the nucleotide triphosphates themselves, and not membrane protein phosphorylation, were responsible for the effect observed. It is concluded that ATP gamma S is an effective tool for studying the possible role of ATP released in synaptic transmission. The results obtained thus far suggest that neither extrasynaptosomal ATP nor phosphorylation of external proteins of the presynaptic membrane is sufficient for modulation of neurotransmitter uptake or release. They may, however, play a role in combination with other conditions.

Comparison of proteins involved with cyclic AMP metabolism between synaptic membrane and postsynaptic density preparations isolated from canine cerebral cortex and cerebellum

Synaptic membrane and postsynaptic density (PSD) fractions isolated from canine cerebral cortex and cerebellum were assayed for the following proteins: adenylate cyclase and phosphodiesterase (PDE) activities against cyclic AMP and cyclic GMP, the regulatory subunit of the cyclic AMP-dependent protein kinase, and the substrate proteins for this kinase. The results were expressed on the basis of both the protein content of the fractions and the number of synapses in the synaptic membrane fractions. The number of synapses on a constant protein content basis was about three times higher in the cerebral cortex synaptic membrane fraction than in the comparable cerebellar fraction. Adenylate cyclase activity was from 3.4 to 5.6 times higher in the cerebral cortex membrane fraction than in the cerebellar membrane fraction based on protein content but only slightly higher based on synapse counts. PSD fractions had no adenylate cyclase activity. The cyclic AMP-PDE activity was from 17 to 27 times higher in the cerebral cortex membrane fraction than in the cerebellar membrane fraction based on protein content, and about five times higher based on synapse counts. By doing PDE histochemistry at the electron microscopy level it was found that all the cerebral cortex PSDs in the isolated fraction contained PDE activity, none being found associated with the broken-up material in the fraction. The amount of the regulatory subunit of the cyclic AMP-dependent protein kinase was about equal in the two fractions based on protein, but about one-third lower in cerebral cortex fraction than in cerebellar fractions. In the cerebral cortex membrane fraction the primary substrate for the cyclic AMP-dependent protein kinase is synapsin I, with much lower amounts in the cerebellar membrane fraction. The PSD fraction from the two sources also showed these differences in synapsin I content. In the cerebellar membrane fraction, the primary substrate for the enzyme is a approximately 245,000 Mr protein not found in the cerebral cortex membrane fraction. The findings that the turnover of cyclic AMP is much higher in cerebral cortex synapses than in cerebellar synapses, and that differences are found between the cerebral cortex and cerebellum with regard to the substrate proteins for the cyclic AMP-dependent protein kinase indicate a divergence in the effect of cyclic AMP between cerebral cortex and cerebellar synapses.

Mammalian brain antigens defined by monoclonal antibodies

Seventy-two hybridoma lines that produce monoclonal antibodies to molecules of a rat synaptosomal plasma membrane fraction (SPM) were generated. The topographical distribution of the antigens in the cerebellum and other areas of the brain was studied by light microscopy immunocytochemistry. Some of the antibodies recognize exclusively neuronal antigens while others bind to specific glial molecules. Some of the antigens have a distribution limited to certain classes of neurons. There are antigens localized in both the cell bodies and processes while others are present only in the latter. Immunoblots of SPM proteins indicate that some antibodies react specifically with one or few of these proteins while other antibodies react with many. The latter antibodies also generally react with many brain cell types. Particularly interesting is the monoclonal antibody 8-6A2 which binds to many SPM proteins but only recognizes large neurons with long axons. A further characterization of the antigens was done by enzyme-linked immunosorbent assays and immunoblots of known purified proteins. The results indicate that antibody 8-2H5 binds specifically to clathrin, 8-7A5 to actin, 8-1E7 to the glial fibrillary acidic protein and both 8-3A5 and 7-2C12 to collagen. In contrast, the antibodies 4-4C3, 2-4H3, 4-4G7 and 6-6A8 bind to antigenic determinants present in many purified proteins.

Improved detection of calcium-binding proteins in polyacrylamide gels

We refined the method of Schibeci and Martonosi (1980a) to enhance detection of calcium-binding proteins in polyacrylamide gels using 45Ca2+. Our efforts have produced a method which is shorter, has 40-fold greater sensitivity over the previous method, and will detect 'EF hand'-containing calcium-binding proteins in polyacrylamide gels below the 0.5 microgram level. In addition, this method will detect at least one example from every described class of calcium-binding protein, including lectins and gamma-carboxyglutamic acid containing calcium-binding proteins. The method should be useful for detecting calcium-binding proteins which may trigger neurotransmitter release.

Characterization of cyclic AMP-dependent phosphorylation of neuronal membrane proteins

We examined the patterns of cyclic AMP-dependent protein phosphorylation in membranes prepared from rat cortical synaptosomes following gel electrophoresis and autoradiography. We determined the optimum pH (6.2), time (20 s), Mg2+ concentration (10 mM) and cyclic AMP concentration (5 microM) for the reaction. We also found that the detergents Triton X-100 and gramicidin S enhanced cyclic AMP-dependent protein phosphorylation. Inhibitors of the Na+, K+ ATPase (ouabain, NaF, vanadate) enhanced protein phosphorylation. This effect occurred in the presence but not in the absence of detergent. The addition of purified bovine brain cyclic AMP-dependent protein kinase catalytic subunit enhanced membrane protein phosphorylation. The addition of homogeneous neural (bovine brain) and non-neural (bovine skeletal muscle) cyclic AMP-dependent protein kinase type II regulatory subunit partially inhibited protein phosphorylation. Both neural and non-neural regulatory subunits behaved similarly. In addition to cyclic AMP-dependent phosphorylation, the alpha-subunit of pyruvate dehydrogenase (Mr = 41,000) is phosphorylated in a cyclic AMP-independent fashion. We also examined the phosphorylation pattern of membranes prepared from rat heart and found that the number of acceptor substrates was much less than that from the nervous system.

Endogenous protein phosphorylation in chick and rat brain synaptic membranes

The protein kinase activities endogenous to synaptic membranes prepared by an identical procedure from avian (chick) and mammalian (rat) brains were compared. Both species showed similar responses towards both protein kinase effector molecules cyclic adenosine monophosphate and Ca2+. Kapp for cyclic adenosine monophosphate-dependent protein kinase activity occurred at 0.4-0.8 microM cAMP and Kapp for Ca2+-dependent, calmodulin-requiring protein kinase activity occurred at 1-2 microM Ca2+ (free ion concentration) both in the absence or presence of calmodulin added to the reaction mixture. This suggests that endogenous calmodulin in these membranes was able to modulate the Ca2+-dependent, calmodulin requiring protein kinase activity. After EGTA-treatment of the membranes to remove endogenous Ca2+ and calmodulin, no significant response towards Ca2+ on the phosphorylation of the membrane polypeptides was measured unless exogenous calmodulin was added after which the Kapp for Ca2+ was increased to 15 microM Ca2+ (free ion concentration). There was a difference in the maximal levels of kinase activity in these membranes with chick membranes containing 57% less cyclic adenosine monophosphate-dependent protein kinase activity, but 65% more Ca2+-dependent, calmodulin-requiring protein kinase activity than the rat membranes. Similar results were determined when either low (5 microM) or high (5.8 microM) concentrations of adenosine 5'-triphosphate were added to the reaction mixtures. Besides certain species differences in the molecular weights of the resulting phosphoproteins, we observed several major differences with respect to the absence or presence of some of the phosphoproteins. Chick synaptic membranes may lack the cyclic adenosine monophosphate-requiring, microtubule-associated phosphoprotein, MAP2, one of the 2 neurospecific, cyclic adenosine monophosphate-requiring and Ca2+, calmodulin-requiring phosphoproteins (Protein Ib, although Protein Ia apparently is present), and the Ca2+-requiring, calmodulin-independent, ACTH-sensitive phosphoprotein, B50. The phenothiazines, trifluoperazine, fluphenazine and chlorpromazine were found to inhibit the Ca2+-dependent, calmodulin-requiring protein kinase activities of both the chick and rat synaptic membranes. This inhibition appeared to be specific for calmodulin because at the same concentrations the phenothiazine analogue, chlorpromazine-sulfoxide, had no effect on this activity. Also found to inhibit Ca2+-dependent calmodulin-requiring protein kinase activity were dibucaine and adrenocorticotropin. These data suggest that rat forebrain synaptic plasma membranes are activated by cyclic adenosine monophosphate

Detection of antigens on nitrocellulose paper immunoblots with monoclonal antibodies

A very sensitive method for the detection of antigen-antibody complexes on nitrocellulose paper immunoblots is described. The protein antigens are separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by their electrophoretic transfer onto a nitrocellulose sheet ("Western blot"). The protein antigens bound to the nitrocellulose paper are exposed to the monoclonal antibody and the antibody-antigen complexes are detected on the paper by an immunoenzymatic reaction. The improved sensitivity of this method is the result of (i) the use of the detergent Tween 20 in blocking the nonspecific binding of the antibodies to the nitrocellulose paper, (ii) the use of a peroxidase-antiperoxidase (PAP) reaction, and (iii) the intensification of the diaminobenzidine reaction product with nickel and cobalt ions in phosphate buffer.

Synaptic junctional glycoproteins are phosphorylated by cyclic-AMP-dependent protein kinase

Synaptic junctions (SJs) isolated from rat brain are associated with protein kinase activity and a unique complement of high molecular weight gglycoproteins. Incubation of SJs with [gamma-32P]A+ glycoproteins which were retained by concanavalin A agarose (con A+ glycoproteins). Three major (apparent mol. wt. 180 K, 130 K and 110 K) and 2 minor (apparent mol. wt. 230 K and 145 K) glycoproteins were identified in the con A+ fraction. Of these, GP180 incorporated the most 32P and GP145 was not labeled. Peptide mapping experiments showed that each molecular weight class of glycoprotein was associated with a unique set of phosphorylated peptides. Cyclic AMP stimulated the incorporation of 32P into total SJ proteins and con A+ lycoproteins by 38% and 58%, respectively. GP130 showed the greatest increase in labelling in the presence of cyclic AMP (198% of control levels) although incorporation into all 4 glycoproteins was increased. Cyclic AMP selectively stimulated the incorporation of 32P into only 2 of the 6 phosphorylated peptides derived from GP130. These studies demonstrate that endogenous glycoproteins serve as substrates for intrinsic SJ protein kinases and identify this reaction as a potential means of modifying postsynaptic membrane function.

Localization of an endogenous substrate for cyclic AMP-stimulated protein phosphorylation in retina

Incubation of mouse or rabbit whole retina homogenates in the presence of [gamma 32P]-ATP and Mg2+ leads to the phosphorylation of various proteins, as demonstrated using SDS-polyacrylamide gel electrophoresis and autoradiography. The phosphorylation of one protein (ca. approximately equal to 31000 mol. wt) was increased by cyclic AMP in both species, with half-maximal stimulation at 5 x 10(-7)M. Cyclic GMP was also active, but much less potent. Protein phosphorylation patterns were compared in retina homogenates from normal mice (C57BL/6J), from adult C57BL/6J mice homozygous for the retinal degeneration gene (rd/rd) in which rod photoreceptor cells are absent, and from 21-day-old 020/Cpb mice homozygous for the retinal degeneration slow gene (rds/rds) in which only the outer segments of the rod photoreceptors are missing. The 31 K protein was only present in normal and in 21-day-old rds/rds mice. When rabbit retina was microdissected into outer segment, inner segment plus outer nuclear, and inner retina layers, cyclic AMP-stimulated phosphorylation of the 31 K protein was evident only in the inner segment plus outer nuclear layer. These data indicated the presence of a specific, endogenous substrate for a cAMP-dependent protein kinase which is found in the inner portions of rod photoreceptor cells.

Evidence that the synaptic phosphoprotein B-50 is localized exclusively in nerve tissue

The localization of the phosphoprotein B-50 (molecular weight 48,000 isoelectric point 4.5) in the rat has been studied. Inspection of endogenous phosphorylation patterns of the particulate as well as the cytosolic subcellular fractions from a variety of peripheral organs failed to demonstrate phosphorylation of a molecular weight 48,000 protein. Only in the particulate fractions from brain tissue was there endogenous phosphorylation of the B-50 protein. Two-dimensional analysis (isoelectric focusing and sodium dodecyl sulfate polyacrylamide gel electrophoresis) and in immunochemical detection method employing an anti B-50 antiserum revealed the presence of B-50 in particulate material from brain, but not in that of other tissues. Therefore the data were interpreted as pointing to the localization of B-50 in nervous tissue. In addition, the regional distribution of endogenous B-50 phosphorylation was studied using synaptosomal plasma membranes (SPM) obtained from individual rat brain regions. The highest value was found in SPM of septal origin, the lowest in SPM from the medulla spinalis. The relationship of the high value for B-50 phosphorylation in the septum to the sensitivity of that brain area to ACTH1-24 is discussed.

Calcium-stimulated adenosine triphosphatases in synaptic membranes

We have investigated the properties of several ATPases present in synaptic membrane preparations from the cerebral cortex of rat. In addition to the intrinsic (Na+ + K+)-ATPase and a low level of contaminating Mg2+-ATPase of mitochondrial origin, both of which could be controlled by the addition of ouabain and azide, respectively, four activities were studied: (1) a Mg2+-ATPase; (2) a Mg2+-independent activity requiring Ca2+ ions at high concentrations; (3) a (Ca2+ + Mg2+)-ATPase with a high affinity for Ca2+, which were enhanced further (4) by the inclusion of calmodulin (33 nM for half-maximal activity). In the presence of 0.5 mM-EGTA in the buffer used, half saturation for these respective metal ions was observed at 0.9 mM for (1), 1.0 mM for (2), and approximately 0.3 mM for (3) and (4); the latter values correspond to concentrations of free Ca2+ of 0.38 and 0.18 microM for (3) and (4), respectively. The level of activities observed, all in nmol X min-1 X mg-1, under optimal conditions of 37 degrees C, was in a number of preparations (n in parenthesis): for (1) 446 +/- 19 (19); for (2) 362 +/- 18 (3) for (3) 87 +/- 13 (12); and for (4) 161 +/- 29 (12). The (Ca2+ + Mg2+)-ATPase, both in the presence and absence of calmodulin, could be inhibited specifically by a number of agents (approximate I0.5 in parentheses) which, at these concentrations, showed little or no potency against the other activities; among them were vanadate (less than or equal to 10 microM), La3+ (75 microM), trifluoperazine, and other phenothiazines (50 microM). These properties suggest that the (Ca2+ + Mg2+)-ATPase described may be responsible for calcium transport across one (or more) of the several membranes present in nerve endings and contained in the preparation used.

Pre-incubation of subcellular fractions from rat cerebral cortex inactivates protein phosphorylation

Pre-incubation of various subcellular fractions from rat brain caused a significant decrease in the phosphorylation of individual polypeptides. The rate and extent of this loss of labelling was not uniform and polypeptides whose phosphorylation was independent of cyclic AMP were primarily affected, whereas substrate availability remained unaltered. It is recommended that pre-incubation effects must be carefully monitored if valid conclusions are to be made about the physiological relevance of changes in protein phosphorylation observed in vitro.

Estimation of the number of monoclonal hybridomas in a cell fusion experiment. Effect of post-fusion cell dilution on hybridoma survival

A practical method is described for the estimation of the number of monoclonal hybridomas in a cell fusion experiment as a function of the percent of culture dishes showing hybridoma growth. Our method is based on the Poisson probability model. A justification for the method is included. The application of this model to our experimental results indicates that the probability of hybridoma survival decreases with post-fusion cell dilution even in the presence of a constant number of feeder cells.

Endogenous protein phosphorylation in rat brain mitochondria: occurrence of a novel ATP-dependent form of the autophosphorylated enzyme succinyl-CoA synthetase

When rat brain mitochondria are incubated with [gamma-32P]ATP, there is a rapid (10 s) phosphorylation of proteins designated E1 and F of M.W. 42,000 and 32,000, respectively. Although [gamma-32P]ATP was the preferred substrate for protein F, a small amount of labeling did occur with [gamma-32P]GTP. Phosphorylation of E1 was absolutely ATP-dependent. On the other hand, a 32,000 M.W. protein from rat liver mitoplasts (mitochondria devoid of an outer membrane) was highly phosphorylated when [gamma-32P]GTP was used but not at all phosphorylated within short time periods with [gamma-32P]ATP. Both the ATP-labeled brain phosphoprotein F and GTP-labeled liver protein migrated to identical positions on high-resolution two-dimensional polyacrylamide gels, and both contained acid-labile phosphoryl groups. Furthermore, both phosphoproteins were identified as the autophosphorylated subunit of succinyl-CoA synthetase (SCS, EC 6.2.1.4) by using antibody directed against purified GTP-dependent porcine SCS. However, immunotitration experiments with anti-porcine SCS revealed that ATP- and GTP-labeled protein F in brain differed in their interactions with antibody, suggesting that in rat brain mitochondria two different forms of the enzyme exist that are immunologically distinct and differ in substrate specificity. When mitochondrial preparations enriched in particular brain cell or subcellular types were examined, an unequal distribution of E1 and the two forms of protein F were observed. A brain subfraction containing neuronal cell body and glial mitochondria (CM) was found to contain E1 and approximately equal amounts of the ATP- and GTP-dependent forms of protein F. Light synaptic mitochondria (SM1) contained ATP-dependent protein F almost exclusively and were depleted in E1. Dense synaptic mitochondria (SM2) are rich in the ATP form of SCS but also contain low amounts of the GTP enzyme.

Evidence that the 40,000 Mr phosphoprotein influenced by high frequency synaptic stimulation is the alpha subunit of pyruvate dehydrogenase

We have previously shown that brief periods of high frequency synaptic stimulation of the rat hippocampus influence the endogenous phosphorylation of a 40,000 Mr brain protein (Browning et al.). The results of the present study demonstrate that this brain phosphoprotein is enriched in a purified mitochondrial fraction and co-migrates with the alpha-subunit of pyruvate dehydrogenase in sodium dodecyl sulfate polyacrylamide gels. Comparisons of total and partial proteolytic fingerprints indicate that the two proteins are essentially identical. In addition, the phosphorylation of the 40,000 Mr brain protein is sensitive to both dichloroacetate and magnesium as has been reported for pyruvate dehydrogenase. Taken together these data provide persuasive evidence that the brain protein is the alpha-subunit of pyruvate dehydrogenase and thereby raise the possibility that even very short periods of synaptic activity influence an enzyme of particular importance to mitochondrial metabolism in brain.

Presynaptic localization of phosphoprotein B-50

A major phosphoprotein of synaptic membranes, the phosphorylation of which is stimulated by Ca2+ and inhibited by ACTh, appears to be identical with protein B-50 described by Zwiers, Schotman and Gispen [40]. We have investigated its subsynaptic localization by means of a variety of subfractionation techniques and compared it with that of a number of other phosphoproteins found in synaptic membranes. It appears to be predominantly, if not exclusively, associated with presynaptic membranes of low bouyant density. This localization pattern is similar to, but somewhat more extreme than that exhibited by Protein I, as a brain specific phosphoprotein studied by Greengard and his collaborators [11].

In vivo phosphorylation following [32P]orthophosphate injection into neostriatum or hippocampus: selective and rapid labeling of electrophoretically separated brain proteins

Intracranial injections of [32P]orthophosphate readily label a number of brain phosphoproteins as resolved by polyacrylamide gel electrophoresis. The majority of these in vivo labeled phosphoproteins co-migrate with phosphoproteins that are labeled in vitro by incubation of brain membranes with [32P]ATP. Two of the major in vitro labeled phosphoproteins with apparent molecular weights of 47,000 (band F1) and 41,000 (band F2) are rapidly labeled in vivo. Since they are rapidly dephosphorylated in vitro, this suggests a high rate of phosphate turnover. The electrophoretic pattern of in vivo labeled phosphoproteins did not appear to be altered by the method of sacrifice (focused microwave irradiation, decapitation or liquid nitrogen immersion) or by the state of the animal at the time of labeling (awake or lightly anesthetized with pentobarbital). The reduction of phosphatase activity during tissue processing at 0 degree C may account for the similarities observed with different sacrifice methods. Removal of phospholipids or polynucleotides had little effect on the in vivo labeled 32P-containing bands. However, alkaline hydrolysis or protease treatment uniformly reduced the radioactivity in the labeled bands. These findings suggest that the 32P-containing bands consist of phosphoester linkages to serine or threonine residues. The present evidence emphasizes that previously characterized in vitro labeled brain phosphoproteins are, in fact, labeled in the awake, freely-moving animal.

Distribution of six synaptic membrane antigens in subcellular fractions of rat brain cortex

The subcellular distribution in rat brain cortex of six synaptic membrane antigens (56K, 58K, 62K, 63K, 64K, 66K) was studied by rocket immunoelectrophoresis, using antiserum to a highly purified synaptic plasma membrane fraction. Initial analysis of the insoluble portion of subcellular fractions showed that these antigens were also present in smooth microsomes, rough microsomes, and synaptic vesicles; that only traces were present in synaptic junctions; and that none was present in nuclei, mitochondria, and myelin. A trace amount of activity was also present in synaptic vesicle cytosol, but none in whole brain cytosol. Quantitative measurements of synaptic plasma membranes, smooth microsomes, and synaptic vesicles showed that all six antigens were present in synaptic plasma membranes and smooth microsomes, but that the 66K antigen was absent from synaptic vesicles. The 56K, 58K, 62, 63K, and 64K antigens were present in highest concentration in synaptic plasma membranes, whereas the 66K antigen content was highest in smooth microsomes. Only the 58K, 62K, and 63K antigen were detectable in the membrane fraction of whole brain. Their enrichments in synaptic plasma membranes were 10.9, 5.4, and 5.9, respectively. We conclude that the 56K, 58K, 62K, 63K and 64K antigens are primary components of synaptic plasma membranes. The presence of synaptic plasma membrane antigens in smooth microsomes and synaptic vesicles probably represents material being actively transported, consistent with the hypothesis that proteins of synaptic plasma membranes and synaptic vesicles are hypothesis that proteins of synaptic plasma membranes and synaptic vesicles are transported via smooth endoplasmic reticulum.

Attachment of the synapse-specific phosphoprotein protein I to the synaptic membrane: a possible role of the collagenase-sensitive region of protein I

The purified synapse-specific phosphoprotein Protein I was previously shown to be degraded by a bacterial collagenase, through a series of intermediates, to a collagenase-resistant fragment of molecular weight about 48,000 containing a phosphorylated serine residue. In this study, a purified synaptic membrane fraction containing Protein I was treated with Cl. histolyticum collagenase; membrane-bound and membrane-free proteins were then phosphorylated using [gamma-32P]ATP and analyzed by SDS-polyacrylamide gel electrophoresis and autoradiography. It was observed that Protein I bound to the synaptic membrane was susceptible to the collagenase and degraded to fragments of molecular weights about 68,000, 62,000, and 48,000; the 68,000 fragment remained bound to the membrane whereas the 62,000 and 48,000 fragments were dissociated from the membrane. These observations suggest that the peptide moiety of mol. wt. 6000, present in the 68,000 fragment but absent from the 62,000 fragment, may play a crucial role in anchoring Protein I to the synaptic membrane.

Distribution of protein I, a synapse-specific phosphoprotein, and adenylate cyclase in the rat spinal cord

The longitudinal and transverse distributions of the synapse-specific phosphoprotein Protein I and adenylate cyclase in the rat spinal cord were studied. Protein I was found to be enriched in all cervical and midlumbar (L3-L5) segments, and sparse in midthoracic and sacral segments. Adenylate cyclase activity was high in all cervical and lumbosacral segments, and low in mid-thoracic segments. Cross sectionally, both Protein I and adenylate cyclase were more enriched in the dorsal half than in the ventral half in the various segments studied. The similar topographical distributions of Protein I and adenylate cyclase in the spinal cord support the idea that adenylate cyclase may be intimately associated with Protein I in the nervous system, and could thereby regulate the state of in vivo phosphorylation of Protein I through formation of cyclic AMP.

Serotonin stimulates phosphorylation of protein I in the facial motor nucleus of rat brain

Protein I is one of the best candidates for a neuronal protein whose phosphorylation may have a functional role in synaptic activity. It is a substrate for both cyclic AMP-dependent and protein kinases, and these kinases show differential specificity for its multiple phosphorylation sites. Protein I is found exclusively in the central and peripheral nervous systems, and immunohistochemical and subcellular fractionation studies suggest an association primarily with synaptic vesicles. Using slices of rat cerebral cortex incubated in vitro, Protein I was phosphorylated both by agents which increase intracellular cyclic AMP and by agents causing Ca2+ influx, although not by any putative neurotransmitters or neuromodulators. We have now examined the facial motor nucleus and report here that serotonin produces a phosphorylation of Protein I when incubated with facial nucleus slices. Demonstration of a neurotransmitter-dependent alteration in the state of phosphorylation of a synapse-specific protein may be due to the relatively simple neuronal circuitry within the facial motor nucleus.