Protein phosphorylation in nervous tissue: possible involvement in nervous tissue function and relationship to cyclic nucleotide metabolism

Geoffrey Burnstock - An accidental pharmacologist

Geoffrey Burnstock, the founder of the field of purinergic signaling research passed away in Melbourne, Australia on June 3rd, 2020, at the age of 91. With his death, the world of biomedical research lost one of its most passionate, creative and unconventional thought leaders. He was an inspiration to the many researchers he interacted with for more than 50 years and a frequent irritation to those in the administrative establishment. Geoff never considered himself a pharmacologist having being trained as a zoologist and becoming an autonomic neurophysiologist based on his evolving interests in systems and disease-related research. By the end of his life he had: published some 1550 papers; been cited more than 125,000 times; had an h-index of 156 and had supervised over 100 Ph.D. students. His indelible legacy, based on a holistic, data-based, multidisciplinary, unconventional "outside the box" approach to research was reflected in two of the seminal findings in late 20th century biomedical research: the purinergic neurotransmitter hypothesis and the concept of co-neurotransmission, both of which were initially received by his peers with considerable skepticism that at times verged on disdain. Nonetheless, while raising hackles and threatening the status quo, Geoff persevered and prevailed, becoming a mentor for several generations of biomedical researchers. In this review we provide a joint perspective on Geoff Burnstock's legacy in research.

The effect of neurocatin on protein phosphorylation in striatal synaptosomes from rat brain

Neurocatin, a neuroregulatory factor isolated from mammalian brain, is a powerful affector of protein phosphorylation in rat striatal synaptosomes. Two major synaptosomal phosphoproteins of approximately 80 and approximately 60 kDa, possibly synapsin I and tyrosine hydroxylase, were especially sensitive to neurocatin. Immunoprecipitation experiments confirmed that the 60-kDa protein is the enzyme tyrosine hydroxylase. At low concentrations of neurocatin (to approximately 7.5 ng/100 microliters of suspension), incorporation of 32P orthophosphate into these proteins increased with increasing neurocatin concentration. At 7.5 ng of neurocatin, incorporation of the label into the two proteins increased by 22 and 26%, respectively. Concentrations of neurocatin > 7.5 ng/100 microliters caused progressive decrease in incorporation of 32P into many synaptosomal proteins; by a concentration of neurocatin of approximately 45 ng/100 microliters, the level of 32P incorporation into many proteins was < or = 70% of control. The effects of neurocatin on synaptosomal protein phosphorylation were also dependent on the time of incubation. At a constant concentration of approximately 7.5 ng/100 microliters of neurocatin, increased incorporation of 32P into many proteins was measurable within 0.5 min and was maximal by 1 min. Incubation times > 2.0 min, showed progressive decrease in 32P incorporation. Removing extrasynaptosomal Ca2+ with EGTA attenuated the increased 32P incorporation induced by low neurocatin concentrations, suggesting that calcium plays a role in neurocatin-induced phosphorylation of rat striatal synaptosomal proteins. The reduced incorporation of label induced by high neurocatin concentrations, however, was not calcium dependent. The effects of neurocatin on the level of 32P incorporation into proteins were observed only in intact synaptosomes, consistent with this compound acting through receptors on the plasma membrane.

Phosphorylation of synaptic proteins in chick forebrain: changes with development and passive avoidance training

We have used synaptic plasma membranes (SPMs) and postsynaptic densities (PSDs) to study protein phosphorylation at the synapse in the developing chick forebrain and in 1-day-old chick forebrain following training on a passive avoidance task. Endogenous phosphorylation patterns in SPMs and PSDs prepared by extraction with n-octylglucoside isolated from chick forebrain were investigated by labelling with [32P]ATP. The phosphoprotein components of the SPM and PSD fractions were separated using sodium dodecyl sulphate gradient polyacrylamide gel electrophoresis. Autoradiography and densitometry of the Coomassie Blue protein staining pattern revealed phosphate incorporation into several SPM components including those of molecular mass 52, 37, and 29 kilodaltons (kDa). Bands of similar molecular mass were not phosphorylated in PSD fractions. This difference in phosphorylation between SPMs and PSDs was not due to the detergent n-octylglucoside. In a developmental study in which SPM and PSD fractions were prepared from 1-day-old, 14-day-old, and 21-day-old chickens, the phosphorylation patterns of SPMs were similar throughout, but striking differences occurred in PSDs, both in the level of phosphorylation and in the components phosphorylated. A time-course study was carried out in which phosphorylation of SPMs and PSDs from 1-day-old chicks trained on a passive avoidance task was compared with patterns from control chicks trained on a water-coated bead and untrained chicks. In SPMs prepared from forebrains removed 10 mins following training, a consistent but nonsignificant decrease (-21%) in phosphorylation of a 52 kDa band occurred in chicks with passive avoidance training compared with water-trained and untrained chicks.(ABSTRACT TRUNCATED AT 250 WORDS)

Mechanism for amine modulation of the neurogenic Limulus heart: evidence for involvement of cAMP

The role of cyclic nucleotides as intracellular second messengers mediating the excitatory chronotropic and inotropic actions of octopamine (OCT) and dopamine (DA) on the neurogenic Limulus heart was investigated. Tissue levels of cAMP, but not cGMP, were significantly increased in isolated cardiac ganglia and cardiac muscle following 10 min exposure to 10(-5) M OCT or 10(-5) M DA. In both tissues, OCT elicited larger increases in cAMP than did DA. Amine-induced cAMP accumulation in the cardiac ganglion and in the cardiac muscle was prevented by the alpha-adrenergic blocker phentolamine. The adenylate cyclase activator forskolin and the phosphodiesterase inhibitor IBMX produced amine-like chronotropic and inotropic effects when applied to the isolated heart preparation. However, the kinetics of the responses differed for the two agents. Additional pharmacological agents (RO-20-1724, papaverine, SQ 20,009, and 8-parachloro-phenylthio cAMP) also had amine-like effects but to a lesser extent. The chronotropic, but not inotropic, effects of OCT and DA were potentiated in the presence of IBMX. These data suggest that a cAMP-dependent mechanism underlies the excitatory effects of the neuromodulators OCT and DA on the Limulus heart.

Effects of purine nucleotides on the binding of [3H]cyclopentyladenosine to adenosine A-1 receptors in rat brain membranes

Adenine nucleotides displace the binding of the selective adenosine A-1 receptor ligand [3H]cyclopentyladenosine (CPA) to rat brain membranes in a concentration-dependent manner, with the rank order of activity being ATP greater than ADP greater than AMP. Binding was also displaced by GTP, ITP, adenylylimidodiphosphate (AppNHp), 2-methylthioATP, and the beta-gamma-methylene isostere of ATP, but was unaffected by the alpha-beta-methylene isosteres of ADP and ATP, and UTP. At ATP concentrations greater than 100 microM, the inhibitory effects on CPA binding were reversed, until at 2 mM ATP, specific binding of CPA was identical to that seen in controls. Concentrations of ATP greater than 10 mM totally inhibited specific binding. Inclusion of the catabolic enzyme adenosine deaminase in the incubation medium abolished the inhibitory effects of ATP, indicating that these were due to adenosine formation, presumably due to ectonucleotidase activity. The inhibitory effects were also attenuated by the alpha-beta-methylene isostere of ATP, an ectonucleotidase inhibitor. Adenosine deaminase, alpha-beta-methylene ATP (100 microM), and beta-gamma-methylene ATP (100 microM) had no effect on the "stimulatory" phase of binding, although GTP (100 microM) slightly attenuated it. Comparison of the binding of [3H]CPA in the absence and presence of 2 mM ATP by saturation analysis showed that the KD and apparent Bmax values were identical. Examination of the pharmacology of the control and "ATP-dependent" CPA binding sites showed slight changes in binding of adenosine agonists and antagonists. The responses observed with high concentrations of ATP were not observed with GTP, AppNHp, the chelating agents EDTA and EGTA, or inorganic phosphate. The divalent cations Mg2+ and Ca2+ at 10 mM attenuated the stimulatory actions of high (2 mM) concentrations of ATP, whereas EGTA and EDTA (10 mM) enhanced the "stimulatory" actions of ATP. EDTA (10 mM) abolished the inhibitory effects of ATP, indicating a specific dependence on Mg2+ for the inhibitory response. The effects of ATP on [3H]CPA binding were reversible for antagonists but not agonists. The mechanism by which ATP reverses its own inhibitory action on adenosine A-1 radioligand binding is unclear, and from the observed actions of the divalent cations and chelating agents probably does not involve a phosphorylation-dependent process.

Regulation of protein phosphorylation by triiodothyronine (T3) in neural cell cultures. Part I: Astrocytes

Dissociated cells from 2-day-old rat cerebral hemispheres were cultured for 17 days in absence of thyroid hormones using conditions yielding mainly glial cells. Triiodothyronine (10(-8) M) was added for 0-72 h before the end of the incubation and [32P]phosphate was added for the last 4 h. Soluble (105,000 X g supernatant), particulate (105,000 X g pellet) and HMG (high mobility group; 0.75 M perchloric acid-soluble proteins) fractions were prepared and phosphorylated proteins in each fraction were analyzed by polyacrylamide gel electrophoresis. In the soluble fraction a protein (Mr = 19,000) incorporates less [32P]phosphate after only 4 h of T3 treatment. The maximal effect is attained after 7 h (-42%) and remains unchanged up until 72 h. In this fraction, the phosphorylation of some other proteins is increased but the maximal effect is observed 48 and 72 h after T3 administration. In the particulate fraction, exposure to T3 rapidly (4 h) increases the amount of a protein (Mr = 45,000) identified as beta-actin. Protein phosphorylation in this fraction is slightly, or not at all, affected by T3. In contrast, a rapid (between 4 and 7 h) increased phosphorylation of a 17 kDa protein in the HMG fraction is observed following T3 stimulation. This nuclear protein was further characterized as HMG 14. These results show that thyroid hormones can produce direct effects (not mediated by neurons) on the phosphorylation of specific proteins in cultured glial cells. Possible functional implications of the observed protein changes are discussed in this paper.

Regulation of protein phosphorylation by triiodothyronine (T3) in neural cell cultures. Part II: Neurons

Cerebral hemisphere from 16- to 18-day-old rat fetuses were dissociated and cells were cultured in absence of thyroid hormones. Neuron-enriched cultures were obtained either by using cells after 6 days of culture (before extensive glial cell proliferation) or by adding cytosine arabinoside for 48 h after 4 days of culture and using cells on day 9. Cells were incubated with T3 (10(-8) M) for 0-72 h and [32P]phosphate was added for the last 4 h of incubation. HMG (high mobility group; 0.75 M perchloric acid-soluble proteins) were prepared and phosphorylated proteins were analyzed by polyacrylamide gel electrophoresis. T3 rapidly (4-7 h) increased the phosphorylation of histone H1 and of a protein with apparent molecular mass of 17000 Da identified as HMG 14. In addition, in cells not treated with cytosine arabinoside, histone H1 was resolved into 3 subfractions and each of these responded to the hormone with a different time course. These results indicate that thyroid hormones act on the phosphorylation of specific nuclear proteins and therefore may influence chromatin structure and gene expression in primary neuronal cell cultures.

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.

Modulation of the activity of purified phosphatidylinositol 4-phosphate kinase by phosphorylated and dephosphorylated B-50 protein

To investigate the modulation of phosphatidylinositol 4-phosphate kinase activity by the degree of phosphorylation of the B-50 protein, the enzyme was purified from rat brain cytosol by ammonium sulphate precipitation and DEAE-cellulose column chromatography. Purified rat brain B-50 was phosphorylated with protein kinase C and dephosphorylated with alkaline phosphatase. Incubation of the semi-purified phosphatidylinositol 4-phosphate kinase with 1 microgram of the B-50 preparation enriched in the dephospho-form, resulted in a small reduction of phosphatidylinositol 4-phosphate kinase activity (-16%), whereas incubation with the phospho B-50 preparation inhibited the enzyme activity by 40%. The effect of exogenous B-50 was studied in the presence of 10 micrograms albumin to minimize aspecific protein-protein interactions. The present data on the effect of exogenous B-50 protein on phosphatidylinositol 4-phosphate kinase activity, further support our hypothesis that the phosphorylation state of B-50 may be a regulatory factor in phosphoinositide metabolism in rat brain.

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.

A unified theory of presynaptic chemical neurotransmission

The mechanism of neurotransmission and its modulation involves the direct role of calcium on membranes, and calcium's ability to activate synergistically and simultaneously a host of interdependent enzymatic cascades in synaptic and coated vesicles and the presynaptic plasma membrane. Enzymatic products formed can either amplify or depress synaptic vesicle exocytosis and synaptic vesicle regeneration via the coated pit/vesicle system. Rate amplification produced by a series of parallel, multistepped, interconnected enzymatic cascades as well as the optimal geometric spatial orientation of synaptic vesicles induced by presynaptic structures is hypothesized to explain how neurotransmitter is released within 200 musec upon calcium entry into the axon terminal.

Regulation of phosphate incorporation into four brain phosphoproteins that are affected by experience

Various regulators of protein kinase activities were tested for their effects on the in vitro transfer of phosphate from [gamma-32P]ATP to four proteins of rat brain synaptic particulate preparations. One protein, of apparent molecular weight 44,000, accepted 32P in the presence of 8 mM EDTA and no added Mg2+. It was the major phosphoprotein of brain mitochondria. Its phosphorylation was inhibited by pyruvate and stimulated by K+, and it comigrated in electrophoretic gels with authentic alpha-subunit of pyruvate: lipoamide oxidoreductase (decarboxylating) (EC 1.2.4.1) from bovine heart. The major kinase acting on three proteins of apparent molecular weights 24,000, 21,000, and 19,000 was stimulated by Ca2+, by preincubation with phospholipase C, and by 12-tetradecanoyl 4-beta-phorbol 13-acetate. Phosphorylation of these lower-molecular-weight proteins was inhibited by ACTH1-24, by cyclic 3',5'-adenosine monophosphate, and by 50 microM trifluoperazine. The stimulatory effect of Ca2+ was antagonized by calmodulin. The kinase in question appears to be B-50 protein kinase or protein kinase C.

Electrophysiological responses of neurones in the nucleus accumbens to hippocampal stimulation and the attenuation of the excitatory responses by the mesolimbic dopaminergic system

Extracellular single unit recordings were obtained from neurones in the nucleus accumbens of urethane anaesthetized rats. Single pulse stimulation (300-800 microA, 0.15 ms, 0.5-1.5 Hz) of the ventral subiculum of the hippocampus strongly excited silent and spontaneously active (3-6 spikes/s) medial accumbens neurones. The majority of neurones excited by hippocampal stimulation were quiescent and identified only by the elicited action potentials. Neurones on the dorso-medial border of the nucleus accumbens and adjacent lateral septum, with a faster spontaneous discharge rate (8-12 spikes/s), were inhibited by hippocampal stimulation. In the ventral border of the accumbens and the olfactory tubercle, hippocampal stimulation also inhibited the fast-firing (greater than 20 spikes/s) neurones. When trains of 10 conditioning pulses (300-800 microA, 0.15 ms, 10 Hz) were delivered to the ventral tegmental area (VTA) 100 ms before each single-pulse stimulation of the hippocampus, the excitatory responses of the silent and spontaneously active accumbens neurones were attenuated. The possibility of this relatively prolonged attenuation effect being dopamine-mediated was supported by several lines of evidence. Dopamine, applied iontophoretically, reduced markedly the excitatory response of accumbens neurones to hippocampal stimulation. Iontophoretically applied dopamine mimicked the attenuating effect produced by VTA conditioning stimulation in the same neurone. The attenuating effects of VTA conditioning stimulation on the activation of accumbens neurones by hippocampal stimulation was reduced by: (1) administration of 6-hydroxydopamine to the VTA 2 days and 7-9 days prior to the recording session, (2) the intraperitoneal injection of haloperidol 1 h before the recording session, and (3) the iontophoretic application of trifluoperazine to accumbens neurones. These observations support the hypothesis that the attenuating effects of the mesolimbic dopamine system on limbic inputs to the nucleus accumbens may have a role in limbic-motor integration.

In vivo phosphorylation of postsynaptic density proteins

In vivo protein phosphorylation was examined in postsynaptic density-enriched fractions isolated from rat brain. In vivo phosphorylation was carried out by injecting rats intraventricularly with [32P]orthophosphate followed by isolation of postsynaptic densities from pooled cerebral cortices. In vivo 32P-labeled postsynaptic densities were then fractionated by sodium dodecylsulfate-polyacrylamide slab gel electrophoresis and stained with Coomassie Blue. The protein banding pattern was typical for postsynaptic densities. The principal polypeptide component occurred in a single band at an apparent molecular weight of 51,000. Autoradiographs of the dried gels showed a major peak of radioactivity associated with the 51,000 molecular weight component for the in vivo labeled postsynaptic density fraction. Additional minor peaks of radioactivity were also observed. These results represent the first demonstration that proteins associated with the postsynaptic density readily incorporate phosphate in vivo and may represent a major and important class of synaptic phosphoproteins.

Mutual stimulation by phosphatidylinositol-4-phosphate and myelin basic protein of their phosphorylation by the kinases solubilized from rat brain myelin

Myelin basic protein and phosphatidylinositol-4-phosphate are phosphorylated in vitro by ATP and solubilized rat brain myelin. When both substrates are present together, the rate of phosphorylation of each is increased about eight-fold. It appears likely that the phosphate turnover of myelin basic protein and of phosphatidylinositol-4-phosphate are coupled in vivo.

Dopamine-induced changes in protein phosphorylation and polyphosphoinositide metabolism in rat hippocampus

Effects of dopamine (DA) on endogenous phosphorylation of hippocampal proteins and polyphosphoinositides were studied in subcellular fractions from a crude mitocondrial/synaptosomal preparation. DA induced a concentration-dependent decrease in the in vitro phosphorylation of the protein B-50 (-22.1% at 10(-5) M DA), whereas no changes were found in phosphoproteins in other subcellular fractions. Treatment of hippocampal slices with 5 X 10(-4) M DA resulted in a 45.8% increase in post hoc phosphorylation of B-50 in SPM and it affected post hoc phosphorylation of several proteins in a cytosolic fraction. In vitro phosphorylation of SPM with DA (5 X 10(-4) M) increased endogenous TPI phosphorylation (+51.6%), whereas treatment of slices with DA (5 X 10(-4) M) resulted in a 39.4% decrease in post hoc TPI phosphorylation. This decrease could be blocked by haloperidol. Significant changes induced by DA (5 X 10(-4) M) were also found in 32P-incorporation into PA (in vitro: -32.4% and post hoc: +39.3%), but were not found in DPI labeling. The data provide evidence for DA-induced changes in phosphorylation of proteins and polyphosphoinositides in rat hippocampal SPM.

Depolarisation-dependent protein phosphorylation in rat cortical synaptosomes: factors determining the magnitude of the response

The sequence of molecular events linking depolarisation-dependent calcium influx to the release of neurotransmitters from nerve terminals is unknown; however, calcium-stimulated protein phosphorylation may play a role. In this study the incorporation of phosphate into proteins was investigated using an intact postmitochondrial pellet isolated from rat cerebral cortex. The rate and relative incorporation of label into individual phosphoproteins depended on the prelabelling time and buffer concentrations of calcium and phosphate. After prelabelling for 45 min, depolarisation caused a greater than 20% increase in the labelling of 10 phosphoproteins, and this initial increase was maximal with 41 mM K+ for 5 s, or 30 microM veratridine for 15 s, in the presence of 1 mM calcium. Both agents also led to an initial dephosphorylation of four phosphoproteins. Depolarisation for 5 min led to a significant decrease in the labelling of all phosphoproteins. All of the depolarisation-stimulated changes in protein phosphorylation were calcium-dependent. The depolarisation conditions found to optimally alter the phosphorylation of synaptosomal proteins find many parallels in studies on calcium uptake and neurotransmitter release. However, the uniform responses of such a large number of phosphoproteins to the multitude of depolarisation conditions studied suggest that the changes could equally well relate to recovery events such as biosynthesis of neurotransmitters and regulation of intraterminal metabolic activity.

Somatostatin and analogs inhibit endogenous synaptic plasma membrane protein phosphorylation in vitro

The addition of somatostatin to hippocampal synaptic plasma membrane (SPM) preparations in vitro decreased subsequent phosphorylation of specific protein bands. 10(-4)M somatostatin inhibited the phosphorylation of protein bands with apparent molecular weights between 10 000 and 20 000 daltons and, to a lesser extent, 48 000 daltons (B-50) and 52 000. Increasingly greater degrees of inhibition were seen in response to somatostatin-28 and [D-Trp8]somatostatin. Inhibition of B-50 protein phosphorylation in the presence of [D-Trp8]somatostatin was most prominent in SPM preparations from the hippocampus and amygdala, with lesser degrees of inhibition seen in the cortex and hypothalamus. Addition of [D-Trp8]somatostatin to an ammonium sulfate-precipitated fraction (ASP 55-80) from cortex only slightly inhibited endogenous B-50 phosphorylation. The injection of [D-Trp8] somatostatin intracerebroventricularly into rats did not induce excessive grooming behavior but resulted in barrel rotation. These results suggest that somatostatin and congeners affect SPM protein phosphorylation in a manner different from that of ACTH, presumably involving membrane sites that bind somatostatin.

Protein kinase injection reduces voltage-dependent potassium currents

Intracellular iontophoretic injection of the catalytic subunit of cyclic adenosine monophosphate-dependent protein kinase increased input resistance and decreased a delayed voltage-dependent K+ current of the type B photoreceptor in the nudibranch Hermissenda crassicornis to a greater extent than an early, rapidly inactivating K+ current (IA). This injection also enhanced the long-lasting depolarization of type B cells after a light step. These findings suggest the involvement of cyclic adenosine monophosphate-dependent phosphorylation in the differential regulation of photoreceptor K+ currents particularly during illumination. On the other hand, conditioning-induced changes in IA may also be regulated by a different type of phosphorylation (for example, Ca2+-dependent).

Cyclic AMP independent protein kinase activity in rat cerebral cortex synaptic vesicles--partial characterization

The intrinsic protein kinase activity of a highly purified synaptic vesicle preparation was characterized. The time-course of the reaction was found to be rapid and linear for about 1 min, but plateaued after 30 min by which time approximately 1 nmol of 32P per mg protein was incorporated into trichloroacetic acid precipitated vesicular protein. The enzyme was optimally active at pH 6.0 (37 degrees C), and had apparent Km values of 40 and 88 microM for ATP and GTP respectively. The enzyme was not stimulated by cAMP or cGMP. Mg2+ was required for maximal activity. The reaction was inhibited by free Ca2+, and non-selectively by Na+, K+, and NH4+.

Characterization of infant rat cerebral cortical membrane proteins phosphorylated in vivo: identification of the ACTH-sensitive phosphoprotein B-50

This study on the phosphorylation in vivo of membrane proteins in cerebral cortices of infant rats reports the identification of the adrenocorticotropin (ACTH)-sensitive phosphoprotein B-50 as one of the substrate proteins that are rapidly phosphorylated in vivo following intracisternal administration of 2 mCi [32P]orthophosphate. Rats were sacrificed 30 min after isotope injection. A fraction enriched in membranes, designated neural membranes (NM), was isolated from the cerebral cortices according to the procedure used for preparation of synaptic plasma membranes (SPM) from adult brain. This NM fraction was characterized by electron microscopy. The proteins of NM were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. Numerous protein bands of NM in infant rat brain were phosphorylated in vivo. Attention was focussed on the 32P-labeled protein bands in the molecular weight range of 47K-67K. In this region one phosphoprotein band (MW 48K) was more highly labeled than the other bands. The electrophoretic behavior of three of these labeled bands, designated a, c, and e (MW 48K, 55K, and 62K, respectively) was compared with that of protein bands that were phosphorylated in vitro in cerebral membranes isolated from noninjected infant rats. The effects of ACTH1-24 and cyclic AMP in the in vitro system were also studied to probe for the presence of specific membrane proteins known to be sensitive to these modulators. On incubation of NM with [gamma-32P)ATP in the presence and absence of ACTH1-24 in vitro, phosphorylation of a 48K protein band was inhibited in a dose-dependent fashion by the neuropeptide. Two-dimensional electrophoretic separation of NM proteins labeled in vivo indicated that the 48K band had an isoelectric point of 4.5, identical to that of the ACTH-sensitive B-50 protein previously identified. Cyclic AMP stimulated phosphorylation in vitro of two protein bands (MW 55K and 59K) in NM preparations. This result indicates that the in vivo labeled band c may correspond to the cyclic AMP-sensitive 55K protein, whereas phosphoprotein band e, labeled in vivo, appears to be different from the cyclic AMP-sensitive 59K protein band. These observations indicate that neural membranes isolated from infant rat cerebral cortices contain a variety of proteins that can be phosphorylated in vivo. Several of these, for example, the 48K protein band, have the properties of synaptic plasma membrane proteins of adult rat brain that have been characterized by their sensitivity to neuromodulators in endogenous phosphorylating systems in vitro.

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.

Identification of a mitochondrial phosphoprotein in brain synaptic membrane preparations

A 41,000-dalton phosphoprotein in crude synaptosomal membrane fractions is characterized by its unique divalent and monovalent cation regulation. It is identified by two-dimensional gel electrophoresis as the phosphoprotein whose phosphorylation is enhanced by repetitive electrical stimulation of hippocampal brain slices. After sucrose-gradient ultracentrifugation, this phosphoprotein is found in the mitochondrial subfraction. This suggests that the electrically produced changes in the level of phosphorylation of the 41,000-dalton polypeptide are probably effects on cellular energetics rather than on specialized neural membrane function.

Phosphorylation of adrenal medulla cell proteins in conjunction with stimulation of catecholamine secretion

Enhanced phosphorylation of two specific protein bands accompanied catecholamine secretion from cultured bovine adrenal medulla cells stimulated by different secretagogues. Cells preincubated with 32Pi were treated with nicotine, veratridine, Ionomycin, or barium. Each of these secretagogues stimulated the phosphorylation of two protein bands with apparent molecular weights of 60,000 and 95,000. Phosphorylation of the 60,000 M. W. protein band was two- to threefold higher than that of the 95,000 M. W. band on stimulation with nicotine, veratridine, or barium, but Ionomycin stimulated phosphorylation of each protein band to the same extent. In general, the increase in phosphorylation was most rapid during the first minute of stimulation and occurred prior to detectable secretion. Phosphorylation reached a relatively constant level within 5 min after onset of stimulation at a time when catecholamine release was still proceeding at a rapid rate. Nicotine-stimulated phosphorylation and catecholamine secretion were calcium-dependent and blocked by d-tubocurarine, whereas tetrodotoxin inhibited veratridine-stimulated secretion and phosphorylation. We conclude that catecholamine secretion and protein phosphorylation occur under similar conditions and that Ca2+-dependent incorporation of phosphate into specific proteins may be a link in stimulus-secretion coupling.

Testing cyclic AMP mediation of memory: reversal of alpha-methyl-p-tyrosine-induced amnesia

Treatments that increased intracellular cyclic 3',5' adenosine monophosphate (cAMP) levels following catecholamine depletion caused by alpha-methyl-p-tyrosine (AMPT) provided a prophylactic effect against AMPT-induced amnesia. This effect gives evidence that cAMP mediated the formation of memory. In Experiment I, the phosphodiesterase inhibitor papaverine (50 mg/kg), immediately after a one-trial acquisition task, functionally increased cAMP levels and prevented amnesia 3 h after treatment with AMPT (200 mg/kg) for New Zealand A strain (NZ/A) mice tested in a step-through passive avoidance apparatus. Retention test latencies 72 h later were significantly higher for animals that received only saline and for animals that received AMPT and papaverine than for animals that received AMPT and saline (the amnesic group). In a similar task (Experiment II), mice that received an intracerebroventricular injection of either 5 or 10 microgram dibutyryl cAMP immediately after acquisition and 3 h after AMPT administration showed significantly higher retention test latencies than animals that received AMPT and saline. The AMP plus 10 microgram dibutyryl cAMP group showed facilitated performance even compared to the saline plus saline group.

A calcium-stimulated alkaline phosphatase associated with synaptic vesicles

Synaptic vesicles isolated from bovine cerebral cortex were found to contain alkaline phosphatase activity towards p-nitrophenylphosphate and alpha-naphthyl phosphate, but not towards pyridoxal phosphate. The enzyme had an apparent molecular weight of 125,000 and co-purified with the synaptic vesicles in parallel with the specific neurotransmitter content and with the loss of contaminating components, whereas the major phosphatase which was present in the brain homogenate, with an apparent molecular weight of 140,000 purified away. The optimal pH for the enzyme activity on p-nitrophenylphosphate was 9.8. At this pH the activity was 33.4 nmol/mg protein/min, and the apparent Km value was 0.31 +/- 0.05 mM. The pH dependency of the synaptic vesicle phosphatase activity towards p-nitrophenylphosphate differed from that of the Ca2+/Mg2+-dependentt ATP hydrolysis by the synaptic vesicles. Upon mild digestion of lyzed vesicles with trypsin, phosphatase activity was reduced whereas the ATPase activity was retained suggesting that the phosphatase and the ATPase are two different enzymes. The phosphatase was reversibly inhibited by ethyleneglycol bis (aminoethyl ether) N,N'-tetracetic acid (EGTA) and activity was restored by the addition of an equimolar amount of CA2+. Magnesium ions could restore only 30% of the activity. The activity of the synaptic vesicle phosphatase was not affected by o-phenanthroline, zinc ion or by cAMP. Tetranitromethane inactivated the enzyme irreversibly, whereas phenylmethanesulfonylfluoride diisopropylfluorophosphate and p-hydroxymercurybenzoate inhibited the activity partially. The enzyme did not have a diesterase activity. Adenosine mono-, di- and triphosphate inhibited the p-nitrophenylphosphatase activity and were also hydrolyzed by the vesicle preparation. However, the different kinetic parameters obtained with the nucleotide as inhibitors or as substrates suggest that additional enzymes are involved in the hydrolysis of the adenine nucleotides in vesicle preparation.

Specific protein phosphorylation during stimulation of amylase secretion by beta-agonists or dibutyryl adenosine 3',5'-monophosphate in the rat parotid gland

The present study was undertaken in order to examine the possible involvement of protein phosphorylation during beta-adrenergic stimulation in the rat parotid gland. Isolated parotid gland slices were stimulated by either isoproterenol or dibutyryl adenosine 3',5'-monophosphate (Bt2cAMP) in the presence or absence of propranolol. Amylase output was measured as a parameter for the degree of stimulation of secretion. Stimulation of secretion by either isoproterenol or Bt2AMP was associated with phosphorylation of three protein bands as revealed by sodium dodecylsulfate/polyacrylamide gel electrophoresis and autoradiography. The apparent molecular weights of the three proteins were 35,100 (protein I), 25,700 (protein II) and 20,400 (protein III). After cell fractionation by differential and gradient centrifugation, protein I was enriched in a light membrane fraction most likely corresponding to the plasma membrane as revealed by marker enzyme analysis. Proteins II and III were recovered in a denser fraction containing mainly mitochondria and rough microsomes. The effect of isoproterenol but not that of Bt2cAMP on phosphorylation of all three protein bands was completely abolished by propranolol. The different time course in the stimulation of amylase secretion by isoproterenol and Bt2cAMP respectively was reflected by corresponding differences in the time course of protein phosphorylation.

Membrane potentials in cell-free preparations from guinea pig cerebral cortex: effect of depolarizing agents and cyclic nucleotides

The distribution of [3H]triphenylmethylphosphonium ion between the medium and vesicular entities was examined in a cell-free, particulate preparation from guinea pig cerebral cortex. This distribution followed the Nernst relationship with regard to the external potassium ion concentration and, in physiological media, indicated the maintenance of a mean trans-membrane potential ranging from -58 to -78 mV. The neurotoxins batrachotoxin, veratridine, and grayanotoxin I, partially depolarized the preparation. Tetrodotoxin blocked the depolarization by batrachotoxin, veratridine, and gray-anotoxin I. The depolarization by these neurotoxins was potentiated by the presence of anemone toxin II and presumably reflected the response of vesicular components of neuronal origin. An additional potassium-sensitive depolarization probably represented the response of vesicular components of glial origin with an apparent transmembrane potential of -8 to -35 mV. No correlation could be demonstrated between changes in transmembrane potential and stimulation of cyclic AMP generation by a variety of agents in this preparation.

Synaptic membrane proteins as substrates for cyclic AMP-stimulated protein phosphorylation in various regions of rat brain

Synaptosomal plasma membranes from mammalian brain contain protein kinase activity which phosphorylates endogenous membrane proteins and is stimulated by cyclic AMP. Using polyacrylamide gel electrophoresis it was shown that at least ten proteins in the synaptosomal plasma membrane fraction could be phosphorylated by endogenous cyclic AMP-stimulated protein kinase activity. The number of proteins whose phosphorylation was stimulated by cyclic AMP was strongly influenced by the pH and Mg2+ concentration used in the phosphorylation reaction. A complex pattern of cyclic AMP-stimulated protein phosphorylation was obtained only with synaptosomal plasma membranes and a crude microsomal fraction. Mitochondrial and myelin fractions exhibited no cyclic AMP-stimulated protein kinase activity. Investigation of the distribution of substrates for cyclic AMP-stimulated phosphorylation among various brain regions failed to reveal any regional differences.

Endogenous phosphorylation in vitro: differential effects of brain state (anesthesia, post-mortem) on electrophoretically separated brain proteins

In vitro phosphorylation of rat cerebral cortex synaptosomes was measured in animals that had been acutely treated with sodium pentobarbital. [32P]Labelled phosphoproteins were separated by SDS-slab gel electrophoresis, and the autoradiographs were analyzed by densitometry. We report here that Band F of our previous reports can be separated into two components, F1 and F2, using an improved gel system. This separation is particularly relevant in this report since these components appear to be differentially sensitive to the manipulations used. Specifically, we found that while F1 phosphorylation was markedly diminished by deep barbiturate anesthesia, F2 was relatively stable. While phosphorylation of F2 was also stable 24 h post-mortem, Band F1 phosphorylation was no longer detectable. Finally, while osmotic shock treatment of synaptosomes reduced phosphorylation of F2 somewhat, it eliminated the in vitro phosphorylation of Band F1. We found that under light barbiturate anesthesia, just at the time when the animals lost the righting reflex, the in vitro phosphorylation of Bands D (MR 78,000--80,000 daltons), F1 (MR 47,000--49,000) and F2 (MR 40,000--45,000) increased relative to unanesthetized controls. The in vitro labelling of Bands D and F1 was depressed in tissue prepared from animals that were deeply comatose. These effects of pentobarbital were more pronounced when animals were sacrificed by liquid nitrogen immersion, rather than by decapitation. Cyclic AMP-dependent phosphorylation of Band D exhibited remarkable stability 24 h post-morten (7 days in one case), even when brain tissue was left at room temperature (21--23 degrees C). Phosphorylation of Band F1, however, was not detectable in post-mortem tissue. The results of these studies indicate that phosphorylation of Band F1 is: (1) sensitive to pentobarbital, and (2) unstable post-mortem. Previous findings from our laboratory suggest that Band F1 is: (3) increased in phosphorylation in liquid nitrogen P2 preparations, and may be (4) cAMP-independent, (5) rapidly turning over its phosphate in vivo, and (6) altered by a training experience. Other evidence suggests that: (7) Band F1 phosphorylation may be Ca2+-dependent and that: (8) its phosphorylation is sensitive to osmotic lysis of synaptosomes. The results suggest an important and perhaps unique role for Band F1 in neuronal function.

Distribution and properties of protein kinase and protein phosphatase activities in synaptosomal plasma membranes and synaptic junctions

Some characteristics of the protein kinase activity associated with a synaptosomal plasma membrane (synaptic membrane) fraction and a synaptic junction fraction have been compared. Autoradiography of the phosphorylated fractions separated on sodium dodecyl sulfate polyacrylamide gels showed that cyclic AMP stimulates the phosphorylation of five polypeptides in synaptic membranes, whereas no cyclic AMP dependency could be detected in synaptic junctions. Kinetic studies demonstrated that synaptic junctions contain a high Km and a low Km protein kinase activity while only the high Km activity could be detected in synaptic membranes. The intrinsic ATPase activity of synaptic membranes was shown to strongly interfere with measurements of protein kinase activity. Cyclic AMP binding experiments revealed a 2.6-fold enrichment of cyclic AMP binding capacity in synaptic junctions as compared to synaptic membranes. Protein phosphatase activity was not detected in synaptic junctions but was associated with synaptic membranes, where cyclic AMP was shown to either stimulate or inhibit the dephosphorylation of different polypeptides.

Divalent cation dependent phosphorylation of proteins in squid giant axon

In vitro and in situ (after intracellular infusion) incubation of axoplasm from the squid giant axon with [gamma-32P]ATP produces a phosphorylation of primarily two proteins (of mol.wt. 200,000 and greater than 400,000). The phosphorylation of these proteins is stimulated by Mg2+, inhibited by Ca2+, and unaffected by 10(-7) to 10(-5) M cyclic nucleotides. The 200 kdalton and greater than 400 kdalton phosphorylated peaks appear to be neurofilament proteins, and phosphorylation of these peaks in situ is decreased by electrical stimulation of the axon.