Release of ascorbate from a synaptosomal fraction of rat brain

We have studied factors controlling the release of endogenous ascorbate from synaptosomes prepared from various regions of the rat brain. Ascorbate was spontaneously released from synaptosomes, and this efflux could be enhanced by incubation at 37°C. A further additional ascorbate release could be induced by potassium depolarization or, in striatal, hippocampal and cortical synaptosomes, by incubation with the amino acid glutamate. Spontaneous, depolarization and glutamate-evoked ascorbate release were shown to occur by separate mechanisms. Glutamate-evoked ascorbate release occurred by a heteroexchange mechanism. In cerebellar synaptosomes there was no evidence for such heteroexchange; however, in synaptosomes of this brain region kainic acid induced ascorbate release, probably by acting on excitatory amino acid receptors. The results are discussed in relation to the changes in extracellular brain ascorbate occurring in vivo.     

Acetylcholine in the brain of rats exposed to acute irradiation

A two-fold increase in acetylcholine, that can randomly be released by brain synaptosomes, is registered 60 min following whole-body X-irradiation of rats with a dose of 0.21 C/kg; depolarization of the synaptosome membranes by potassium chloride increases the release of acetylcholine the augmentation of the release in this case being lower than that in the control. The initial rate of spontaneous neuromediator release from synaptosomes grows by 80 per cent whereas after depolarization of synaptosome membranes by potassium chloride, by 15 per cent. There is a 2.5-fold increase in the maximum rate of a highly specific uptake of choline with Km value being constant. Acetylcholine content of gray substance of irradiated rat brain is invariable.     

45Ca2+ and 3H-GABA transport in nerve endings separated from the cerebral cortex of rats with hypoparathyroidism

Ca2+ blood serum level was reduced by 34.5% in rats with hypoparathyroidism (HPT) on the 7th-12th day after the damage of parathyroid glands. Synaptosomes isolated from the brain cortex of rats during this period accumulated in a normal medium more 45Ca2+ than synaptosomes from healthy animals. In potassium depolarization, control and experimental synaptosomes accumulated more 45Ca2+, however in HPT the increment in 45Ca2+ uptake in high potassium medium was less temperature-dependent. In normal medium 3H-GABA uptake and release by synaptosomes from the brain of rats with HPT slightly differed from those in the control. On the contrary, 3H-GABA release induced by synaptosome depolarization was depressed in HPT. It is suggested that nerve terminal excretory function disturbances contribute to increased excitability of the central nervous system in hypoparathyroidism.     

METABOLISM OF GLUCOSE AND GLUTAMATE BY SYNAPTOSOMES FROM MAMMALIAN CEREBRAL CORTEX

—(1) Synaptosomes incubated in high sodium, low potassium media showed high linear respiration in the presence of glucose which was converted into lactate, aspartate, glutamate, glutamine, alanine and GABA during 1 hr incubation periods. (2) Total conversion of glucose into most of these substrates over the incubation period was similar in synaptosomes and cortex slices. Half the lactate and only a small fraction of the glutamine made by slices was formed by synaptosomes. (3) Pool sizes of amino acids in cortex slices after incubation with glucose were, in general, higher than in synaptosomes, glutamate and glutamine being four-fold higher in slices. (4) Most of the amino acids made from glucose by synaptosomes were contained within their structure and not lost to the medium. (5) Glutamate was actively metabolized by synaptosomes to aspartate, glutamine, alanine and GABA. The specific radioactivities of the amino acids (except glutamine) after 1 hr incubation, approached that of the glutamate. (6) Pyridoxal phosphate added to the incubation medium increased GABA production from glutamate but not from glucose.     

Glucose,Lactate and Glutamine but not Glutamate Support Depolarization-Induced Increased Respiration in Isolated Nerve Terminals

Synaptosomes prepared from various aged and gene modified experimental animals constitute a valuable model system to study pre-synaptic mechanisms. Synaptosomes were isolated from whole brain and the XFe96 extracellular flux analyzer (Seahorse Bioscience) was used to study mitochondrial respiration and glycolytic rate in presence of different substrates. Mitochondrial function was tested by sequentially exposure of the synaptosomes to the ATP synthase inhibitor, oligomycin, the uncoupler FCCP (carbonyl cyanide-4-(trifluoromethoxy) phenylhydrazone) and the electron transport chain inhibitors rotenone and antimycin A. The synaptosomes exhibited intense respiratory activity using glucose as substrate. The FCCP-dependent respiration was significantly higher with 10 mM glucose compared to 1 mM glucose. Synaptosomes also readily used pyruvate as substrate, which elevated basal respiration, activity-dependent respiration induced by veratridine and the respiratory response to uncoupling compared to that obtained with glucose as substrate. Also lactate was used as substrate by synaptosomes but in contrast to pyruvate, mitochondrial lactate mediated respiration was comparable to respiration using glucose as substrate. Synaptosomal respiration using glutamate and glutamine as substrates was significantly higher compared to basal respiration, whereas oligomycin-dependent and FCCP-induced respiration was lower compared to the responses obtained in the presence of glucose as substrate. We provide evidence that synaptosomes are able to use besides glucose and pyruvate also the substrates lactate, glutamate and glutamine to support their basal respiration. Veratridine was found to increase respiration supported by glucose, pyruvate, lactate and glutamine and FCCP was found to increase respiration supported by glucose, pyruvate and lactate. This was not the case when glutamate was the only energy substrate.     

Functional characteristics of nerve endings isolated from brain by the Hajos method

A study was made of the functional potentialities of synaptosomes isolated from the brain cortex and lumbar enlargement of the spinal cord. The yield of synaptosomes from the brain cortex amounted to 10 mg (with reference to protein) from 1 g of wet tissue, and that of synaptosomes from the spinal cord was equal to 1/3 of the yield from the brain, with the preparation being strongly contaminated with myelin scraps. Brain synaptosomes were marked by high level of respiration whose magnitude was affected by the agents (ouabain, high concentrations of K+ and benzylpenicillin) that change ion membrane transport. Synaptosomes maintained higher GABA gradient across the plasmatic membrane. Ouabain and potassium depolarization produced a considerable release of GABA and 3H-GABA into the incubation medium. A conclusion is made that the method of Hajos should be rather used for rapid isolation of the synaptosomal fraction from the rat brain cortex.     

Calcium stimulation of glutamine hydrolysis in synaptosomes from rat brain

Calcium stimulates the hydrolysis of glutamine in synaptosomes prepared from rat brain both by the sucrose- (12) and the Ficoll/sucrose-gradient techniques (13). The calcium activation is phosphate-dependent and maximal effect is obtained at a calcium concentration of 0.5-1.0 mM. It is reduced by increasing the numbers of synaptosomes in the incubation mixture, and abolished by the product inhibitors of glutaminase, glutamate and ammonia, but unaffected by the uncoupler 2,4-dinitrophenol which inhibits the mitochondrial proton pump. Moreover, since the hydrolysis of glutamine is mediated by glutaminase (EC 3.5.1.2), and calcium does not activate the purified enzyme, an indirect phosphate-dependent effect of calcium on glutaminase is most likely. Calcium activates preferentially the N-ethylmaleimide insensitive fraction of glutaminase. The calcium activation is not dependent on synaptosomal membranes as it is found in synaptosomes subject to previous freezing. It is also found in isolated synaptosomal mitochondria and is thus a property of nerve endings. The calcium activation of glutaminase is unaffected by potassium in depolarizing concentrations, and may not be directly involved in the neurotransmission processes, but possibly in replenishing depleted stores of transmitter glutamate.     

Determination of electrical characteristics of synaptosomal membranes of the brain

A correct method for evaluating the potential differences across plasma membranes of synaptosomes from the brain is presented. It takes into consideration the multicompartment synaptosome organization and is based on the accumulation of the radioactive permeant cation [3H]tetraphenylphosphonium. It is shown that upon potassium depolarization of the synaptosomes to about -5 mv there is a sharp decrease in the ion selectivity of the synaptic membranes.     

A high level of cytoplasmic calcium inactivates ion channels, formed by alpha-latrotoxin in the rat brain synaptosomes

Effect of alpha-latrotoxin on the concentration level of free calcium [( Ca2+]in) in the rat brain synaptosomes and dependence of the activity of "latrotoxin" channels on [Ca2+]in were studied using fluorescent calcium probe quin-2. It is shown that alpha-latrotoxin exerts effect on calcium permeability of plasmalemma and does not induce calcium ejection from the intracellular compartments. A lag-period is characteristic of alpha-latrotoxin action. A degree of the [Ca2+]in increase in synaptosomes depends on the toxin concentration. When [Ca2+]in increases as a result of preliminary potassium depolarization of plasmalemma of synaptosomes, the amount of incoming calcium ions followed by the toxin effect as well as the calcium input rate considerably decrease. Inactivation of calcium-transferring channels induced by alpha-latrotoxin is not a result of a change in the potential on the membrane, as during the blockage of potential-depending calcium channels by D-600, an increase of KCl in the incubation medium does not influence the alpha-latrotoxin action. Differences in the properties of alpha-latrotoxin channels are discussed in synaptosomes and BLM.     

Effect of Low pH on Glutamate Uptake and Release in Isolated Presynaptic Endings from Rat Brain

The effect of acidification of the incubation medium on the membrane potential and glutamate uptake and release was studied in isolated presynaptic neuronal endings (synaptosomes) from rat brain. Using the fluorescent probe diS-C₃-(5), a rapid depolarization of plasma membrane was detected at pH 6.0, most probably as a result of the inhibition of the sodium pump and potassium channel blockade. The membrane potential decrease did not result in increase of basal efflux of glutamate. Glutamate release following K⁺-induced depolarization was decreased upon lowering pH to 6.0. Acidosis inhibited mainly calcium-dependent (vesicular) release of glutamate and did not significantly reduce [¹⁴C]glutamate uptake. This inhibition of glutamate release but not of glutamate uptake may be a mechanism of the protective effect of acidosis during brain ischemia.     

Role of calcium in synaptosomal substrate oxidation

The effect of veratridine-mediated depolarization on rat brain synaptosomal respiration in the presence and absence of calcium was investigated. Studies on respiration were performed employing three different pretreatments of the synaptosomes which attempted to deplete endogenous substrates. First, synaptosomes were preincubated for 10 min in the absence of any substrates in medium either containing or devoid of calcium. Second, synaptosomes were preincubated for either 15 or 60-min periods in the presence and absence of calcium, and the incubation medium was changed by centrifugation and resuspension of synaptosomes in their respective media. Irrespective of the prior treatment, maximal stimulation of respiration (400-600%) during veratridine (100 microM) elicited depolarization was observed only when calcium was present in the incubation media. In incubations performed in the absence of calcium, veratridine addition either modestly stimulated (10- and 15-min preincubated synaptosomes) or did not affect (60-min preincubated synaptosomes) the rate of respiration. However, when calcium was added back to these incubations the rate of respiration in the presence of veratridine was stimulated by five- to six-fold. Similarly, the rates of 14CO2 production from [1-14C]- and [2-14C]pyruvate were increased by veratridine only when synaptosomes were incubated in calcium-replete medium. These data indicate that calcium plays an obligatory role in depolarization-elicited stimulation of synaptosomal oxidative processes.     

Workshop 4: Compartmentation of Neuronal Metabolism. Compartmentation of energy metabolism and amino acid synthesis in synaptosomes

There is strong evidence that the brain can use multiple substrates for energy including glucose, lactate, ketone bodies, glutamate and glutamine. Competition studies show that certain substrates are preferentially used for energy by synaptic terminals even when other substrates are available. It has recently been shown that synaptosomes can use both glutamine and glutamate for energy and synthesis of amino acids; however, these substrates yield very different patterns of 13C‐labelling of end products. These findings provide evidence of differential compartmentalisation of the metabolism of glutamate taken up from the extracellular milieu as compared to the glutamate produced from glutamine within synaptic terminals. This compartmentalisation is related to the specific role(s) of glutamate vs. glutamine in synaptic terminals as well as the metabolism of these amino acids in either partial or complete TCA cycles for energy. The presence of glucose, which provides a source of acetyl‐CoA, can greatly modulate both the metabolic fate of other substrates and the pool size of amino acids such as glutamate and GABA. The differential localization of the enzymes glutamate dehydrogenase and aspartate aminotransferase contribute to this compartmentalisation as does the necessity that synaptic terminals balance their energy needs with the requirement to synthesize neurotransmitters.     

Synthesis of glutamate and aspartate in rat brain synaptosomes

ATP and glutamine are the sources of endogenous ammonia in rat brain synaptosomes. The amount of endogenous ammonia formed from exogenous ATP is not sufficient to assure the maximum rate of aspartate and glutamate accumulation in the synaptosomes utilizing pyruvate + malate. Addition of exogenous NH4+ or depolarization of synaptosome plasma membranes with high K+ concentration led to a twofold increase in the rate of accumulation of these amino acids. This indicates that both exogenous and endogenous NH4+ is involved in the synthesis of aspartate and glutamate in nerve terminals. Accumulation of glutamate was stimulated by aminooxyacetate and inhibited by haloperidol which indicates that NH4+ is bound in the reaction catalysed by glutamate dehydrogenase. Endogenous oxaloacetate derived from pyruvate metabolism was the substrate for synthesis of aspartate. Additive inhibition of aspartate accumulation by fluorocitrate and (-) hydroxyacetate shows that, in addition to the tricarboxylic acid cycle, the reaction catalysed by ATP-citrate lyase serves in the synaptosomes as another source of oxaloacetate.     

Compartmentalized neurotransmitter and amino acid synthesis in vivo studied by high field MRS

There is strong evidence that the brain can use multiple substrates for energy including glucose, lactate, ketone bodies, glutamate and glutamine. Competition studies show that certain substrates are preferentially used for energy by synaptic terminals even when other substrates are available. It has recently been shown that synaptosomes can use both glutamine and glutamate for energy and synthesis of amino acids; however, these substrates yield very different patterns of 13C-labelling of end products. These findings provide evidence of differential compartmentalisation of the metabolism of glutamate taken up from the extracellular milieu as compared to the glutamate produced from glutamine within synaptic terminals. This compartmentalisation is related to the specific role(s) of glutamate vs. glutamine in synaptic terminals as well as the metabolism of these amino acids in either partial or complete TCA cycles for energy. The presence of glucose, which provides a source of acetyl-CoA, can greatly modulate both the metabolic fate of other substrates and the pool size of amino acids such as glutamate and GABA. The differential localization of the enzymes glutamate dehydrogenase and aspartate aminotransferase contribute to this compartmentalisation as does the necessity that synaptic terminals balance their energy needs with the requirement to synthesize neurotransmitters.     

Glutamate and γ-Aminobutyric Acid Neurotransmitter Systems in the Acute Phase of Maple Syrup Urine Disease and Citrullinemia Encephalopathies in Newborn Calves

Cerebral cortex tissue was obtained at autopsy from neonatal Poll Hereford calves with clinically confirmed maple syrup urine disease (MSUD), neonatal Holstein-Friesian calves with clinically confirmed citrullinemia, and matched controls. From this, synaptosomes were prepared for studies of neurotransmitter amino acid uptake and stimulus-induced release, and synaptic plasma membranes were obtained for studies of associated postsynaptic receptor binding sites. As well as having abnormal brain tissue concentrations of the pathognomic plasma amino acids (markedly increased levels of the branched-chain compounds valine, isoleucine, and leucine in MSUD; marked elevation of citrulline levels in citrullinemia), both groups of diseased animals showed reduced brain tissue concentrations of each of the transmitter amino acids glutamate, aspartate, and gamma-aminobutyric acid (GABA). Nontransmitter amino acids were generally unaffected in either disease. Citrullinemic calves showed a marked increase in brain glutamine concentration; in calves with MSUD, the glutamine concentration was raised, but to a much lesser extent. The Na(+)-dependent synaptosomal uptake of both glutamate and GABA was markedly reduced (to less than 50% of control values in both cases) in citrullinemic calves but was unaltered in calves with MSUD. Whereas synaptosomes from normal calves showed the expected stimulus-coupled release of transmitter amino acids, especially glutamate and aspartate, and no response to stimulus of nontransmitter amino acids, there was no increased release of transmitter amino acids in response to depolarization in synaptosomes from citrullinemic calves.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of leu-enkephalin and the delta-sleep-inducing peptide, M (DSIP), on endogenous noradrenaline release by brain synaptosomes in the rat

Fluorometry was employed to measure the noradrenaline (NA) content in rat brain synaptosomes depending on the duration of incubation, depolarization effects (40 mM KCl or 1.5 mM ouabain), composition of the synaptosomal fraction and concentration of the peptides. The 10-minute incubation in a potassium medium of a suspension of light synaptosomes was used as an optimal test-system for studying the peptide action. Leu-enkephalin inhibited the depolarization-induced NA release. The effect was abolished by naloxone. The delta-sleep-inducing peptide (DSIP) did not influence the neurotransmitter release at concentrations of 10(-8)-10(-5) M. A mixture of amino acids imitating the amino acid composition of the DSIP influenced spontaneous release of NA. This effect is discussed in connection with the physiological action of the peptide on its intraventricular injection.     

Effects of neuroleptics on glutaminase from rat synaptosomes

Phosphate-activated glutaminase was isolated from synaptosomes from three areas of rat brain. Glutamine utilization phosphate activation and inhibition by glutamate or ammonia were assessed in the absence or presence of haloperidol, chlorpromazine, or clozapine. All three drugs (at 1 micromolar concentration) elevated theK _m for glutamine using preparations from the amygdala, hippocampus, or striatum. They interfered with phosphate activation only in the amygdala preparation. No drug affected end-product inhibition. The data suggest that neuroleptics may depress the release of glutamic acid from synaptosomes by interfering with the activation of glutaminase by phosphate.     

Effect of corticotropin on the rate of 32P-orthophosphate incorporation into the synaptosome phosphoinositides of the ischemic rat brain

A high rate of 32P turnover in polyphosphoinositides (up to 80% of the total radioactivity) was found in synaptosomes of normal and ischemic rat brain. Corticotropin (ACTH) increases the rate of 32P turnover in polyphosphoinositides of normal synaptosomes and decreases it in ischemic synaptosomes. Depolarization (high KCl concentration in the incubation medium) activates polyphosphoinositide metabolism in normal (by 50%) and ischemic (by 30%) synaptosomes. The combined influence of depolarization and ACTH results in the additive effect. Thus, a stimulating effect of ACTH on phosphoinositide metabolism disturbed in ischemia was recovered during depolarization of ischemic synaptosomes.     

Multiple calcium channels in synaptosomes: voltage dependence of 1,4-dihydropyridine binding and effects on function

The voltage dependence of binding of the calcium channel antagonist, (+)-[3H]PN200-110, to rat brain synaptosomes and the effects of dihydropyridines on 45Ca2+ uptake have been investigated. Under nondepolarizing conditions (+)-[3H]PN200-110 binds to a single class of sites with a Kd of 0.07 nM and a binding capacity of 182 fmol/mg of protein. When the synaptosomal membrane potential was dissipated either by osmotic lysis of the synaptosomes or by depolarization induced by raising the external K+ concentration, there was a decrease in affinity (approximately 7-fold) with no change in the number of sites. The effects of calcium channel ligands on 45Ca2+ uptake by synaptosomes have been measured as a function of external potassium concentration, i.e., membrane potential. Depolarization led to a rapid influx of 45Ca2+ whose magnitude was voltage-dependent. Verapamil (100 microM) almost completely inhibited calcium uptake at all potassium concentrations studied. In contrast, the effects of dihydropyridines (2 microM) appear to be voltage-sensitive. At relatively low levels of depolarization (10-25 mM K+) nitrendipine and PN200-110 completely inhibited 45Ca2+ influx, whereas the agonist Bay K8644 slightly potentiated the response. At higher K+ concentrations an additional dihydropyridine-insensitive component of calcium uptake was observed. These results provide evidence for the presence of dihydropyridine-sensitive calcium channels in synaptosomes which may be activated under conditions of partial depolarization.