Halothane-Induced Alterations of Glucose and Pyruvate Metabolism in Rat Cerebra Synaptosomes

Synaptosomes isolated from rat cerebra were used to study the effects of the inhalational anesthetic, halothane, on cholinergic processes. To identify possible mechanisms responsible for the depression of acetylcholine synthesis, we examined the effects of halothane on precursor metabolite metabolism involved with supplying the cytosol with acetyl-CoA for acetylcholine synthesis. Three percent halothane/air (vol/vol) depressed 14CO2 evolution from labeled pyruvate and glucose. Steady-state 14CO2 evolution from [1-14C]glucose was depressed 84% by halothane, while 14CO2 evolution from [6-14C]glucose and [3,4-14C]glucose was decreased 67 and 52%, respectively, when compared with control conditions. Halothane inhibited the activities of both pyruvate dehydrogenase (14% depression) and ATP-citrate lyase (32% depression). Total synaptosomal acetyl-CoA concentrations were unaffected by halothane. Three percent halothane/air (vol/vol) caused a 77% increase in medium glucose depletion rate from 1.38 nmol (mg protein)-1 min-1 to 2.44 nmol (mg protein)-1 min-1. Production of lactate by the synaptosomes in the presence of halothane increased by 231% from a control rate of 1.44 nmol (mg protein)-1 min-1 to 4.77 nmol (mg protein)-1 min-1. Lactate production rate from pyruvate was also enhanced by 56% in the presence of halothane. These data lend support to the concept that the NAD+/NADH potential may be involved in the halothane-induced depression of acetylcholine synthesis.     

Oxygen Dependence of Glucose and Acetylcholine Metabolism in Slices and Synaptosomes from Rat Brain

Abstract: Previous studies have shown that a reduction in the O₂ tension of the blood from 120 torr to 57 torr (hypoxic hypoxia) decreases brain acetylcholine (ACh) synthesis. To determine if this decrease is due to a direct impairment of ACh metabolism or to an indirect effect mediated by other neurotransmitter systems, we studied ACh formation in rat brain slices and synaptosomes. At O₂ tensions ranging from 760 to less than 1 torr, ¹⁴CO₂ production and [¹⁴C]ACh synthesis from [U-¹⁴C]glucose, the levels of lactate and ATP, and the ATP/ADP ratio were determined. In slices, the first decreases were observed in the rate of ¹⁴CO₂ production and [¹⁴C]ACh synthesis at an O₂ tension of 152 torr. The ATP level started to decline at 53–38 torr, and a reduction in the ATP/ADP ratio was first found at and below 19 torr. Lactate formation was maximally stimulated at 38–19 torr. Synaptosomes responded differently than brain slices to reduced O₂ tensions. In synaptosomes, ¹⁴CO₂ production and [¹⁴C]ACh synthesis from [U-¹⁴C]glucose, the levels of lactate and ATP, and the ATP/ADP ratio were unaltered if a minimum O₂ tension of 19 torr was maintained. Despite the difference in sensitivities to decreases in O₂ levels, there is a curvilinear relationship between [U-¹⁴C]glucose decarboxylation and [¹⁴C]ACh synthesis at various O₂ tensions for both tissue preparations with a high coefficient of determination (R²= 0.970). The difference in the metabolic sensitivity of slices and synaptosomes to a reduced O₂ level may be explained by the greater distance O₂ must diffuse in slices. The results are discussed in comparison with hypoxia in vivo.     

Arginine Metabolism in Mouse Brain Synaptosomes

In a study employing mouse brain synaptosomes and synaptosomal sonicates, the complete metabolic machinery was found to be present for transport of arginine into synaptosomes, its conversion to ornithine, and the formation from the latter of glutamic acid, gamma-aminobutyric acid, and proline. The results show that a delicate balance probably exists between the flows of metabolites. This balance, which probably determines the steady-state levels of these substances in nerve terminals, can be altered by concentrations of the metabolites themselves through feedback inhibition as well as by levels of cofactors.     

Glucose Availability to Individual Cerebral Structures Is Correlated to Glucose Metabolism

Regional cerebral glucose influx was measured using quantitative autoradiography after the intravenous infusion of [2-¹⁴C]glucose for a period of 10 or 20 s. Glucose influx varied considerably among structures over an almost threefold range. When compared with rates of regional glucose utilization, a significant correlation by region was found between glucose influx and utilization, demonstrating that the glucose supply to individual cere bral structures is closely matched to their metabolic needs.     

Stimulation of Immunoreactive Insulin Release by Glucose in Rat Brain Synaptosomes

The effect of glucose on the release of immunoreactive insulin (IRI) in synaptosomes isolated from rat brain was studied. In the absence of glucose synaptosomes release about 4% (0.77 IU/mg protein) of total content. Glucose increases significantly the IRI released by synaptosomes. Addition of the glycolytic inhibitor iodoacetic acid (IAA), decreased the glucose-induced release of IRI by about 50%, suggesting that glucose metabolism is involved. The observation that glucose provides a concentration related signal for IRI release indicates that this synaptosomal preparation may be useful as a model for research on the mechanism of insulin release in brain.     

Aging Decreases the Sensitivity of Rat Cortical Synaptosomes to Calcium Ionophore-Induced Acetylcholine Release

The capacity of calcium ions to trigger acetylcholine release was studied in cerebral cortical synaptosomes from adult (6-month-old) and senescent (24-month-old) rats, using a calcium ionophore, A23187, that bypasses voltage-sensitive calcium channels. The potency but not the efficacy of the A23187 was reduced with respect to releasing acetylcholine (ACh) in the aged animals. There was no age-related difference in the synthesis of ACh or potency of the ionophore with respect to increasing 45calcium uptake. These results suggest that aging reduces the sensitivity of cerebral cortical nerve terminals to calcium-triggered ACh-release.     

4-Aminobutyrate Can Be Released Exocytotically from Guinea-Pig Cerebral Cortical Synaptosomes

Guinea-pig synaptosomes possess two functional pools of 4-aminobutyrate (GABA). One is rapidly labelled by added [14C]GABA, is steadily released in a Ca2+-independent manner when the Na+ electrochemical potential across the plasma membrane is collapsed, and is depleted by the GABA analogue 2,4-diaminobutyrate (DABA), all of which is consistent with a cytosolic location. A second, noncytosolic compartment only slowly equilibrates with exogenous [14C]GABA, is not depleted by DABA, but can release 350 pmol of endogenous GABA/mg of protein (8% of the total intrasynaptosomal GABA) within 15 s of depolarization in the presence of Ca2+. Ca2+-independent release occurs by thermodynamic reversal of the plasma membrane uptake pathway following artifactually prolonged depolarization, whereas Ca2+-dependent release is consistent with physiological exocytosis from vesicular stores.     

The Rapid Uptake and Release of [3H]Adenosine by Rat Cerebral Cortical Synaptosomes

Abstract: Adenosine, a putative inhibitory transmitter or modulator in the brain, is rapidly transported by rat cerebral cortical synaptosomes. The uptake may represent a facilitated diffusion process, which is saturable and temperature-dependent. In this study, the uptake process was very rapid, reaching completion within 60 s of incubation at 37°C, and had an apparent K_m value of 0.9μM and a V_max value of 5.26 pmol/mg protein/ 30 s. Over 70% of the adenosine taken up remained unchanged, whereas 14% was metabolized to inosine. Twelve percent of the adenosine was converted to nucleotides. Rapid uptake of adenosine into rat cerebral cortical synaptosomes was partially inhibited by replacing Na⁺ with choline chloride in the medium. Ca²⁺ ion is important for the uptake process, as inhibition of adenosine uptake occurs in the presence of either Co²- or EGTA. Rapid uptake of adenosine is apparently mediated by a nucleoside carrier, a conclusion based on its inhibition by a variety of purine and pyrimidine nucleosides. Uptake was inhibited by dipyridamole, hexobendine, papaverine, flurazepam, and morphine. Over 60% of the adenosine taken up by the rapid uptake system (30 s) was released by depolarizing agents. In contrast, only 30% of the adenosine taken up during a 15-min incubation period was released under the same conditions. [³H]Adenosine was the predominant purine released in the presence or absence of depolarizing agents. The basal and KCl-evoked release mechanisms were found to be at least partially Ca²⁺-dependent, however, the release of adenosine by veratridine was increased in the presence of EGTA. This finding is in agreement with the reported Ca²⁺-independent release of ATP from brain synaptosomes. The present findings suggest that there are at least two functional pools of adenosine in synaptosomes. Adenosine taken up by different uptake systems may be destined for different uses (metabolism or release) in the neuron.     

Haloperidol and Cerebral Metabolism in the Conscious Rat: Relation to Pharmacokinetics

The time course and distribution of alterations in cerebral metabolic activity after haloperidol administration were evaluated in relation to the pharmacokinetics of haloperidol and the topography of the dopaminergic system in the brain. Local cerebral glucose utilization was measured, using the 2-deoxyglucose technique, in awake rats after i.p. administration of the dopamine antagonist haloperidol (0.5 or 1 mg/kg). Haloperidol significantly reduced glucose utilization in 60% of 59 brain regions examined, but produced a large increase in the lateral habenula. The regional distribution of changes in glucose utilization was not closely related to the known anatomy of the brain dopaminergic system. The time course of the effect of haloperidol on cerebral metabolism was different for the two doses studied (0.5 and 1 mg/kg), and was not simply related to estimated brain concentrations of haloperidol. However, a linear relation between the metabolic effect and the time-integrated brain concentration was demonstrated. These results show that haloperidol has an effect on CNS metabolic activity that is more widespread than would be predicted from the topography of the dopaminergic system; this may be due to indirect propagation of the primary effects of haloperidol. The metabolic response to haloperidol depends on brain concentration and duration of exposure to the drug.     

Depolarisation-Dependent Protein Phosphorylation in Rat Cortical Synaptosomes: Factors Determining the Magnitude of the Response

Abstract: 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 >20% increase in the labelling of 10 phosphoproteins, and this initial increase was maximal with 41 mM K⁺ for 5 s, or 30 μ M 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.     

Cerebral Cortical Glucose Utilization in the Conscious Rat: Evidence for a Circadian Rhythm

Abstract: The presence of a circadian rhythm of glucose utilization was demonstrated in vivo in rat cerebral cortex. The activity pattern of the rats, living in a controlled lighting regimen with lights on from 7 a.m. to 7 p. m., appeared to coincide with the rate of glucose consumption in the brain. The rate of utilization was measured at 3-h intervals throughout the day and was found to fall from a maximum at 3 a.m. of 0.98 ± 0.13 μmol min⁻¹ g⁻¹ to a minimum of 0.70 ± 0.08 μmol min⁻¹ g⁻¹ at 3 p. m. Brain glucose also varied with time and its fluctuating level weakly correlated with its rate of utilization. Animals entrained on a 5-h (4: 30-9: 30 p. m.) feeding schedule had a similar circadian rhythm, with only a slight increase in amplitude. Reversal of the light cycle caused a disruption in the normal rhythm, but utilization still varied significantly with time of day. The results both indicate the potential error that can be encountered in experiments done at different times of the day and stress the need for awareness of time of day as a factor in measurements of alterations of metabolic rate in the brain.     

Monoamine Oxidase-Catalyzed Metabolism of 3,4-Dihydroxyphenylethylamine in the Dopaminergic Synaptosomes from Rat Corpus Striatum

Abstract: This communication describes conditions under which the monoamine oxidase-catalyzed metabolism of 3,4-dihydroxyphenylethylamine can be assayed in dopaminergic synaptosomes from the rat striatum. In contrast to the activity of the isolated enzyme or that of free mitochondria, the synaptosomal reaction exhibits sigmoidal kinetics with respect to substrate concentration. This is consistent with a kinetic mechanism in which intrasynaptosomal substrate partitions between reaction and saturable storage in synaptic vesicles. The reaction is inhibited at moderately decreased oxygen tension, where catecholamine uptake is unaffected. The specificity of this effect suggests that it reflects limited availability of oxygen as an enzyme substrate.     

Influence of the Malate-Aspartate Shuttle on Oxidative Metabolism in Synaptosomes

beta-Methyleneaspartate, a specific inhibitor of aspartate aminotransferase (EC 2.6.1.1.), was used to investigate the role of the malate-aspartate shuttle in rat brain synaptosomes. Incubation of rat brain cytosol, "free" mitochondria, synaptosol, and synaptic mitochondria, with 2 mM beta-methyleneaspartate resulted in inhibition of aspartate aminotransferase by 69%, 67%, 49%, and 76%, respectively. The reconstituted malate-aspartate shuttle of "free" brain mitochondria was inhibited by a similar degree (53%). As a consequence of the inhibition of the aspartate aminotransferase, and hence the malate-aspartate shuttle, the following changes were observed in synaptosomes: decreased glucose oxidation via the pyruvate dehydrogenase reaction and the tricarboxylic acid cycle; decreased acetylcholine synthesis; and an increase in the cytosolic redox state, as measured by the lactate/pyruvate ratio. The main reason for these changes can be attributed to decreased carbon flow through the tricarboxylic acid cycle (i.e., decreased formation of oxaloacetate), rather than as a direct consequence of changes in the NAD+/NADH ratio. Malate/glutamate oxidation in "free" mitochondria was also decreased in the presence of 2 mM beta-methyleneaspartate. This is probably a result of decreased glutamate transport into mitochondria as a result of low levels of aspartate, which are needed for the exchange with glutamate by the energy-dependent glutamate-aspartate translocator.     

Neurotransmitter Metabolism in Rat Brain Synaptosomes: Effect of Anoxia and pH

Synaptosomes isolated from the rat cerebral cortex by means of a discontinuous Ficoll gradient carry out net, sodium-dependent, veratridine-sensitive accumulation of gamma-aminobutyric acid (GABA), serotonin, norepinephrine, and dopamine. The intrasynaptosomal contents of the four neurotransmitters are: 30.4 nmol/mg protein, 17.4 pmol/mg protein, 13.5 pmol/mg protein, and 21.2 pmol/mg protein, respectively. Anaerobic preincubation of synaptosomes causes an irreversible decrease in the rates of neurotransmitter accumulation but does not affect the rates of their release. The inhibitory effect of anaerobiosis is enhanced by increased concentration of [H+] (decreased pH) in the medium. The most sensitive is the uptake of dopamine, the least that of serotonin. The rates of neurotransmitter efflux are unaffected by anaerobiosis. Synaptosomes leak catecholamines, GABA, and serotonin into the medium when subjected to anaerobiosis, and reintroduction of oxygen is accompanied by a rapid reaccumulation of all four neurotransmitters. It is concluded that: (1) Responses of synaptosomes to anaerobiosis are remarkably similar to the behavior of intact brain in hypoxia and ischemia. (2) Neurotransmitter uptake systems are more sensitive to short periods of anaerobiosis than either the energy metabolism or ion transport. (3) Some neurotransmitter uptake systems are more easily damaged by anaerobiosis than others.     

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

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

Cholinergic Surface Antigen Chol-1 Is Present in a Subclass of VIP-Containing Rat Cortical Synaptosomes

The colocalization of vasoactive intestinal polypeptide (VIP) with the cholinergic specific surface antigen Chol-1 was investigated in synaptosomes derived from the rat cerebral cortex. Immunoaffinity purification of cortical synaptosomes using antisera to Chol-1 resulted in the copurification of VIP and cholinergic nerve terminals. VIP was purified with a yield of 75% of that of choline acetyltransferase (ChAT). These results suggest that approximately 53% of the cortical cholinergic terminals contain VIP, whereas 75% of the cortical VIP content is present in these cholinergic terminals. Both hypotonic lysis and depolarization of the nerve terminals resulted in the differential release of VIP and acetylcholine (ACh), indicating the different compartmentalization in the same nerve terminal. Complement-mediated lysis of cholinergic nerve terminals, using antisera to Chol-1, resulted in the release of 64% of the ChAT, 71% of ACh, and 27% of the VIP. The application of our method enables quantifying and mapping, with a fast, efficient, and specific technique, the coexisting peptides in cholinergic neurons of distinct brain areas.     

Inhibition by Quinacrine of Depolarization-Induced Acetylcholine Release and Calcium Influx in Rat Brain Cortical Synaptosomes

The effects of quinacrine on depolarization-induced [³H]acetylcholine (ACh) release and ⁴⁵Ca²⁺ influx were examined in rat brain cortical synaptosomes. Quinacrine significantly reduced the stimulated release of [³H]ACh by high K⁺ and veratridine without affecting the spontaneous efflux from the preloaded synaptosomes. Quinacrine had no effect on ionophore A23187-induced release of [³H]ACh from the synaptosomes. Quinacrine (100 μM) markedly diminished the stimulated Ca²⁺ influx by veratridine and high K⁺ but not that by “Na⁺-free.” Trifluoperazine, a potent calmodulin antagonist, inhibited both Ca²⁺ influx and ACh release induced by the depolarizing agents. Inhibitory potencies of the two drugs on ACh release and Ca²⁺ influx were compared with the antagonism of calmodulin by two drugs, suggesting that the inhibition of depolarization-induced Ca²⁺ influx and ACh release by these drugs could not be explained by the antagonism of calmodulin.     

Tryptophan Uptake and Hydroxylation in Rat Forebrain Synaptosomes

Tryptophan uptake, hydroxylation, and decarboxylation in isolated synaptosomes were studied to assess how their properties may determine the rate of serotonin synthesis in the presynaptic nerve terminals of the brain. Simultaneous measurements of the rates of uptake, hydroxylation, and decarboxylation in the presence and absence of various inhibitors showed that tryptophan hydroxylase is rate-limiting for serotonin synthesis in this model system. There was significant direct decarboxylation of tryptophan to tryptamine. Measurement of tryptophan hydroxylase flux with varying internal concentrations of tryptophan allowed the determination of the Km of tryptophan hydroxylase in synaptosomes for tryptophan of 120 +/- 15 microM. Depolarisation of synaptosomes with veratridine caused both a reduction in the internal tryptophan concentration and an apparent activation of tryptophan hydroxylase. This activation did not occur in the absence of Ca2+ or in the presence of trifluoperazine. Synaptosomal serotonin synthesis and brain stem-soluble tryptophan hydroxylase were inhibited by low concentrations of noradrenaline or dopamine. Dibutyryl cyclic AMP, glucagon, insulin, and vasopressin were observed to have no effect on tryptophan uptake or hydroxylation in synaptosomes.     

The Contribution of Citrate to the Synthesis of Acetyl Units in Synaptosomes of Developing Rat Brain

Abstract: The activities of pyruvate dehydrogenase, citrate synthase, and choline acetyltransferase in rat brain synaptosomes increased during on-togenesis by 3 and 14 times, respectively. Activity of ATP-citrate lyase decreased by 26% during the same period. Pyruvate consumption by synapto-somes from 1-day-old animals was 40% lower than that found in older rats; however, citrate efflux from intrasynaptosomal mitochondria in immature synaptosomes was over twice as high as that in mature ones. The rates of production of synaptoplasmic acetyl-CoA, ATP-citrate lyase were 1.03, 1.40, and 0.49 nmol/min/mg protein in 1-, 10-day-old, and adult rats, respectively. 3-Bromopyruvate (0.5 m M ) inhibited pyruvate consumption by 70% and caused a complete block of citrate utilization by citrate lyase in every age group. Parameters of citrate metabolism in cerebellar synaptosomes were the same as those in cerebral ones. These data indicate that production of acetyl-CoA. from citrate in synaptoplasm may be regulated either by adaptative, age-dependent changes in permeability and carrier capacity of the mitochondrial membrane or by the inhibition of synthesis of intramitochondrial acetyl-CoA. ATP-citrate lyase activity is not a rate-limiting factor in this process. Metabolic fluxes of pyruvate to cytoplasmic citrate and acetyl-CoA. are presumably the same in both cholinergic and noncholinergic nerve endings. The significance of citrate release from intrasynaptosomal mitochondria as a regulatory step in acetylcholine synthesis is discussed.     

Local Cerebral Glucose Utilization During Development and Aging of the Fischer-344 Rat

Abstract: Local cerebral glucose utilization was measured in brain regions of awake Fischer-344 rats. Measurements were taken in 15 regions of 1-month-old rats, and 19 regions of 3-, 12-, 24-, and 34-month-old rats. Between 1 and 3 months, glucose utilization tended to increase in all brain regions; statistically significant increases occurred in seven regions. Between the ages of 3 and 12 months, glucose utilization decreased significantly in 12 regions. The greatest reductions (25% or more) occurred in the striatum, inferior colliculus, and pons, but the hypothalamus and thalamus, nucleus accumbens, and septum showed no statistically significant change. Cerebral glucose utilization did not change between 12 and 24 months or between 24 and 34 months of age. The results demonstrate a rise in cerebral glucose utilization with development from 1 to 3 months, a decline between 3 and 12 months, and a constancy in the second and third years that does not reflect reported senescence-associated neurochemical and morphological cerebral changes.