Transport of Histidine into Synaptosomes of the Rat Central Nervous System

Abstract: Histidine transport into synaptosomes was studied in order to characterize this aspect of histamine synthesis in neurons. Histidine transport was found to be independent of sodium, calcium, and magnesium ions and dependent upon potassium and chloride ions. Histidine transport was also found to be energy dependent, and subcellular fractionation studies suggested it was highly localized to nerve terminals. Kinetic analysis of histidine transport in several brain regions indicated the presence of two uptake sites, a high-affinity site with a K _m of approximately 35 μ M and a low-affinity site with a K _m in the millimolar range. Density of the high-affinity site, as reflected by V_max, correlates well with density of proposed histaminergic innervation. Rate of histidine transport was not altered by prior depolarization of the synaptosomes, indicating that histidine transport probably does not play a regulatory role in histamine synthesis.     

Acetylcholine Turnover and Compartmentation in Rat Brain Synaptosomes

Abstract: The turnover of acetylcholine (ACh) in rat brain synaptosomes and its compartmentation in the labile bound and stable bound pools were investigated. The P₂ fraction from rat brain was subjected to three sequential incubations, each terminated by centrifugation followed by determination of ACh concentrations by gas chromatography-mass spectrometry (GCMS): (1) Depletion phase: Incubation of synaptosomes at 37°C for 10 min in Na⁺-free buffer containing 35 mM-KCl reduced the content of both labile bound and stable bound ACh by 40%. (2) Synthesis phase: Incubation at 37°C with 2 μ M -[²H₄]choline resulted in accumulation of labeled and unlabeled ACh in both compartments. Addition of an anticholinesterase had little effect on stable bound ACh but greatly increased the content of labile bound ACh. This excess accumulated ACh was probably due to inhibition of intracellular acetylcholinesterase (AChE), because negligible uptake of ACh from the medium was observed. The effects on ACh synthesis of altered cation concentrations and metabolic inhibitors were examined. (3) Release phase: The tissue was incubated in the presence of 35 mM-KCl, 40 μM-paraoxon, and 20 μM-hemicholinium-3 (HC-3) (to inhibit further synthesis of ACh). Measurements of the compartmental localization of ACh at several time points indicated that ACh was being released from the labile bound fraction. In support of this conclusion, 20 mM-Mg²⁺ reduced ACh release and increased the labile bound ACh concentration.     

Properties and Ontogenic Development of Membrane-Bound Histidine Decarboxylase from Rat Brain

Abstract: Histidine decarboxylase (HD) activity was determined in high-speed fractions (100,000 g for 60 min) obtained from whole rat brain homogenates. Twenty-eight percent of the HD activity was associated with membranes, and the remaining was soluble. Several properties of the soluble and membrane-bound HD were compared. No significant differences in the values of K _m for histidine and pyridoxal 5'-phosphate were observed. The solubilization of membrane-bound HD with Triton X-100 resulted in an increase of 60% over the nonsolubilized activity with no changes in the K _m for substrate and cofactor. The proportion of free pyridoxal 5'-phosphate-independent activity was identical in both fractions. The soluble and membrane-bound forms of the enzyme differ slightly in their pH-activity profiles, although both enzymes showed an optimum pH near 6.5. The HD activities present in soluble and membrane fractions were determined at different postnatal ages. The soluble activity increased until day 90, whereas the membrane-bound activity became stabilized from day 20.     

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.     

Diacylglycerol-Induced Stimulation of Neurotransmitter Release from Rat Brain Striatal Synaptosomes

These studies were undertaken to test the hypothesis that alterations in phosphatidylinositol metabolism can modulate neurotransmitter release in the central nervous system. The effects of 1,2-diacylglycerols (DAGs) on dopamine release in the rat central nervous system were determined by measuring dopamine release from rat striatal synaptosomes in response to two DAGs (sn-1,2-dioctanoylglycerol and 1-oleoyl-2-acetylglycerol) that can activate protein kinase C and one DAG (deoxydioctanoylglycerol) that does not activate this kinase. Dioctanoylglycerol and 1-oleoyl-2-acetylglycerol, at a concentration of 50 micrograms/ml, stimulated the release of labeled dopamine from striatal synaptosomes by 35-50 and 17%, respectively. Dioctanoylglycerol-induced release was also demonstrated for endogenous dopamine. In contrast, deoxydioctanoylglycerol (50 micrograms/ml) did not stimulate dopamine release. Dioctanoylglycerol-induced dopamine release was independent of external calcium concentration, indicating a utilization of internal calcium stores. Dioctanoylglycerol (50 micrograms/ml) also produced a 38% increase in labeled serotonin release from striatal synaptosomes. The addition of dioctanoylglycerol to the striatal supernatant fraction increased protein kinase C activity. These results are consistent with the concept that an increase in phosphatidylinositol metabolism can stimulate neurotransmitter release in the central nervous system via an increase in DAG concentration. The data suggest an involvement of protein kinase C in the DAG-induced release, but other sites for DAG action are also possible.     

Effects of Polyamines on the Uptake of Neurotransmitters by Rat Brain Synaptosomes

Abstract: The influence of putrescine, spermidine, spermine, and some aliphatic α,ω-diamines on the uptake of neurotransmitters by rat forebrain synaptosomes was investigated. Choline uptake was most effectively inhibited by spermine (IC₅₀= 0.22 m M ), less so by spermidine (IC₅₀= 4.0 m M ), but not by putrescine (IC₅₀ > 100 m M ). At 10 m M, 1,3-diaminopropane, cadaverine, and 1,8-diaminooctane all inhibited choline uptake by 50% or more. Spermine and spermidine inhibited the uptake of dopamine with IC₅₀ values of 2.7 and 2.2 m M , respectively. Putrescine was only slightly inhibitory (IC₅₀= 17.3 m M ) and the other diamines were inactive. The uptake of γ-aminobutyrate (GABA) was only slightly inhibited (15–40%) by the polyamines at 10 m M . With the exception of inhibition of glycine uptake by 1,8-diaminooctane (60%) and of glutamate uptake by cadaverine (35%) none of the polyamines, tested at 10 m M , affected the uptake of adenosine, glutamate, and glycine significantly. A possible modulatory role for polyamines in synaptic transmission through interaction by negatively charged groups of the synaptic membrane with the polycationic compounds is discussed.     

Phorbol Ester Enhancement of Neurotransmitter Release from Rat Brain Synaptosomes

Neurotransmitter release from rat brain synaptosomes was measured following pretreatment with various phorbol esters. Ca2+-dependent, evoked neurotransmitter release was increased by phorbol esters that were active in stimulating protein kinase C. Protein kinase C activation was demonstrated by increased incorporation of 32P into 87-kilodalton phosphoprotein, a specific substrate for that kinase. Inactive phorbol esters had no effect on neurotransmitter release or on the phosphorylation of 87-kilodalton phosphoprotein. The increased release was observed in either crude cortical synaptosomal fractions (P2) or purified cortical synaptosomal fractions. The enhancement was found for all neurotransmitters (norepinephrine, acetylcholine, gamma-aminobutyric acid, serotonin, dopamine, and aspartate), all brain regions (cerebral cortex, hippocampus, and corpus striatum), and all secretagogues (elevated extracellular K+ level, veratridine, or A23187) examined. It was also observed at all calcium concentrations present during stimulation of release. The phorbol ester enhancement of Ca2+-dependent release occurred whether or not calcium was present during pretreatment. These results indicate that stimulation of protein kinase C leads to an enhanced sensitivity of the stimulus-secretion coupling processes to calcium within the nerve terminal. The results support the possibility that presynaptic activation of protein kinase C modulates nerve terminal neurotransmitter release in the CNS.     

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.     

Ontogenetic Development of Histamine H1- Receptor Binding in Rat Brain

Abstract: Histamine H_1- receptors labeled with [³H]mepyramine in rat brain show an age-dependent development. [³H]Mepyramine receptor density and histidine decarboxylase activity in whole rat brain reach adult levels at 25–30 days after birth and they attain 50% of adult level at day 10 and 17, respectively. The apparently later development of histidine decarboxylase activity in whole rat brain is partly accounted for by a biphasic developmental increase of this enzymatic activity in cerebral cortex. For all other brain regions examined, the development of histamine H_1- receptors parallels that of histidine decarboxylase. The increase in [³H]mepyramine binding can be accounted for by an absolute increase in the numbers of the receptor sites, with no change in affinity. Subcellular fractionation studies indicate that histamine H_1- receptors are predominantly associated with synaptosomal fractions derived from both newborn and adult rat.     

Release of Immunoreactive Insulin from Rat Brain Synaptosomes Under Depolarizing Conditions

Synaptosome preparations were utilized to characterize the release and compartmentalization of immunoreactive insulin (IRI) in the adult rat brain. Depolarization of synaptosomes by elevation of the external potassium ion concentration elicited release of IRI from the synaptosomes into the incubation medium. This release was reduced or eliminated under three conditions known to prevent depolarization-induced Ca2+ flux: elevating the external MgCl2, adding CoCl2, and eliminating external Ca2+ with EGTA. Depolarization of synaptosomes by veratridine also elicited release of synaptosomal IRI. This release was inhibited by tetrodotoxin. The amount of IRI released under depolarizing conditions represented 3-7% of that contained in the synaptosomes. High levels of IRI release also were observed upon removal of external Na+ to allow depolarization-independent influx of external Ca2+ into the synaptosomal compartment. The Ca2+ dependency of synaptosomal IRI release suggests IRI is stored in the adult rat brain in synaptic vesicles within nerve endings from which it can be mobilized by exocytosis in association with neural activity.     

Rat Brain Synaptosomes Prepared by Phase Partition

Synaptosomes from rat forebrain can easily be isolated by combining centrifugation with partition in an aqueous two-phase system composed of dextran T500 and polyethylene glycol 4000 in which synaptosomes have an extreme affinity for the upper phase. The fraction thus obtained has been characterized by electron microscopy and biochemical markers for synaptosomes and some other cell components. The contamination by microsomes, free mitochondria, and myelin was 4.4, 3.2, and 0.1%, respectively. The morphometric analysis of the electron micrographs shows that greater than 60% of the structures are synaptosomes. This preparation of the isolation procedure is remarkably short (less than 1 h), formance as assayed by their respiratory activities and ATP level in the absence and presence of depolarizing agents. Synaptosomes prepared by phase partition release the neurotransmitter glutamate in a Ca2(+)-dependent manner. The duration of the isolation procedure is remarkably short (less than 1 h), no ultracentrifuge is required, and the method can be applied for small- or large-scale preparations.     

Release of Acetylcholine from Rat Brain Synaptosomes Stimulated with Leptinotarsin, A New Neurotoxin

Abstract: Leptinotarsin is a neurotoxic protein found in the hemolymph of potato beetles of the genus Leptinotarsa. In order to study the action of leptinotarsin from two species, L. haldemani and L. decemlineata , synaptosomes were prelabeled with [³H]choline in order to synthesize [³H] acetylcholine (ACh). These synaptosomes were then immobilized on Millipore filters and used for assay. Toxins from both species induce the release of radioactivity in this system. Fractionation of the released radioactivity indicated that ACh was released in preference to choline. The toxin that caused release was heat-labile and was partially dependent on Ca²⁺ in the perfusing medium. Release followed apparent first order kinetics when stimulation was effected with leptinotarsin from L. haldemani (leptinotarsin-h), but was more complex when using leptinotarsin from L. decemlineata (leptinotarsin-d). Increasing the concentration of toxin increased the rate of release, but the shapes of the dose-release curves elicited by the leptinotarsins from the two species were different. While leptinotarsin-h exhibited a simple, saturating dose-release curve, leptinotarsin-d was characterized by a sigmoid function, which was well described, with a Hill coefficient of 1.8. Antibodies directed toward black widow spider venom glands had no effect upon the releasing activity of leptinotarsin-h but could partially neutralize that of leptinotarsin-d. Toxins from both species have been partially purified and do not appear to be identical. The purified toxins should be useful tools with which to study the release of acetylcholine.     

Differential Labeling of Depot and Active Acetylcholine Pools in Nondepolarized and Potassium-Depolarized Rat Brain Synaptosomes

Abstract: To test the hypothesis that a pool of newly synthesized acetylcholine (ACh) turns over independently of preformed ACh, compartmentation and K⁺ -evoked release of ACh were examined in perfused synaptosomal beds intermittently stimulated by 50 m M K⁺. In resting synaptosomes, endogenous and labeled ACh was distributed between synaptic vesicles and the cytoplasm in a dynamic equilibrium ratio of 4:6. In the absence of new ACh synthesis, five sequential K⁺ -depolarizations caused a decremental release of preformed labeled ACh totaling 30% of the initial transmitter store. Further depolarization evoked little additional release, despite the fact that 60% of the labeled ACh remained in these preparations. Release of the preformed [¹⁴C]ACh was unaltered while new ACh was being synthesized from exogenous [³H]choline. Since the evoked release of [³H]ACh was maintained while that of [¹⁴C]ACh was decreasing, the [³H]ACh/[¹⁴C]ACh ratio in perfusate increased with each successive depolarization. This ratio was six to ten times higher than the corresponding ratio in vesicles or cytoplasm. These results indicate that the newly synthesized ACh did not equilibrate with either the depot vesicular or cytoplasmic ACh pools prior to release.     

A Role for Transglutaminase in Neurotransmitter Release by Rat Brain Synaptosomes

Rat brain synaptosomes exhibit calcium-dependent transglutaminase activity. This activity, measured in detergent-treated or sonicated preparations, was six- to sevenfold lower than that in the liver. The synaptosomal transglutaminase was inhibited by various amines and alpha-difluoromethylornithine, compounds known to inhibit activity of this enzyme in other tissues. The inhibitors of transglutaminase induced release of catecholamines, but not of gamma-aminobutyric acid, from synaptosomes both under basal and K+-stimulated conditions. The concentrations of the agents that caused stimulation of catecholamine release were approximately the same as those that inhibited the activity of transglutaminase. Stimulation of release was largely reduced by the withdrawal of calcium from the incubation medium. Inhibitors of transglutaminase had little effect either on the uptakes of neurotransmitters or the amounts of deaminated products of catecholamine degradation released into the medium. It is suggested that a synaptosomal transglutaminase is involved in suppressing vesicular release of catecholamines by resting (nondepolarized) neurons and that this action may also be a part of negative feedback control which prevents excessive transmitter release at the synapse during increased neuronal activity.     

Detergent Effects on the Phosphatidylinositol-Specific Phospholipase C in Rat Brain Synaptosomes

In the presence of Ca2+ (2.5 mM) and using [14C]arachidonoyl phosphatidylinositol (PI) membrane as substrate, phosphatidylinositol-specific phospholipase C (PI-PLC) (EC 3.1.4.10) in rat brain synaptosomes was activated by deoxycholate but not taurocholate. Calcium stimulated enzymic hydrolysis by both detergents, but the stimulatory effect of taurocholate was less than that of deoxycholate. Peak stimulation for deoxycholate was observed at 1 mg/ml, whereas that for taurocholate was 4 mg/ml. When 1 mM EDTA was added to the taurocholate (4 mg/ml) and Ca2+ (3.5 mM) system, synaptosomal PI-PLC activity was greatly stimulated, to almost the same level as the deoxycholate + Ca2+ system. This system required the presence of all three factors, and EGTA could not effectively replace EDTA in the stimulatory action. The detergent-induced hydrolysis of synaptosomal PI by the deoxycholate + Ca2+ and the taurocholate + Ca2+ + EDTA systems was strongly inhibited by divalent metal ions such as Zn2+, Cu2+, Pb2+, and Fe2+, whereas Mg2+ and Ca2+ were ineffective. Nevertheless, only the deoxycholate + Ca2+ system was responsive to enzyme inhibition by membrane-perturbing agents such as lysophospholipids and free fatty acids. The specific requirement for EDTA in the taurocholate system may be due to the release of a pool of inhibitory divalent metal ions from the membranes.     

Adenosine Transport into Guinea-pig Synaptosomes

Abstract: Kinetics for transport of adenosine into guinea-pig neocortex synaptosomes were studied by incubating them with [¹⁴C]adenosine for up to 30 s. The apparent K _m value of the high-affinity transport system for adenosine was 21.1 μM and the V _max value was 257.3 pmol/min/mg protein. The transport system was inhibited by both compounds structurally related (compounds 554 and 555) and unrelated (dipyridamole) to adenosine. Because electrically stimulated synaptosomes release up to 1.5% of the adenosine derivative content per min, the physiological significance of adenosine uptake is discussed as a possible mechanism to compensate for the loss of adenine nucleotides from synaptosomes preparations.     

Zinc Uptake into Synaptosomes

Zinc uptake was studied in synaptosomes, isolated by the Ficoll flotation technique, using the radiotracer 65Zn. True uptake of zinc could be discriminated from binding to the outside of the synaptosomes by the absence of accumulation at 0 degree C and the dependency of the rate of uptake on the medium osmolarity. The zinc uptake, studied in the presence of various zinc-complexing agents, showed saturation kinetics when analyzed in terms of [Zn]free, yielding Km = 0.25 microM. The zinc uptake was independent of both ATP and the Na+ gradient. No efflux of zinc could be demonstrated from preloaded synaptosomes due to the formation of insoluble zinc complexes inside the synaptosomes. The results are discussed in terms of the modulation of diverse neurochemical processes by zinc.     

Uptake of Agmatine into Rat Brain Synaptosomes: Possible Role of Cation Channels

Abstract: Agmatine (decarboxylated arginine), an endogenous ligand for imidazoline receptors, has been identified in brain where it is synthesized from arginine by arginine decarboxylase. Here we report a mechanism for the transport of agmatine into rat brain synaptosomes. The uptake of agmatine was energy- and temperature-dependent and saturable with a K _m of 18.83 ± 3.31 m M and a V _max of 4.78 ± 0.67 nmol/mg of protein/min. Treatment with ouabain (Na⁺,K⁺-ATPase inhibitor) or removal of extracellular Na⁺ did not attenuate the uptake rate. Agmatine transport was not inhibited by amino acids, polyamines, or monoamines, indicating that the uptake is not mediated by any amino acid, polyamine, or monoamine carriers. When we examined the effects of some ion-channel agents on agmatine uptake, only Ca²⁺-channel blockers inhibited the uptake, whereas a reduction in extracellular Ca²⁺ increased it. In addition, some imidazoline drugs, such as idazoxan and phentolamine, were strong noncompetitive inhibitors of agmatine uptake. Thus, a selective, Na⁺-independent uptake system for agmatine exists in brain and may be important in regulating the extracellular concentration of agmatine.     

Phosphate Ion Transport in Rabbit Brain Synaptosomes

Abstract: Synaptosomes (vesicles of nerve endings) isolated from rabbit brain were studied as a model system for the uptake of inorganic phosphate. The phosphate uptake showed a sodium-dependent, saturable component with a K _t of 0.29 m m , The sodium-dependent component was larger at pH 6 than at pH 7.4 or 8. Application of potassium salts, ouabain, monensin, nigericin or FCCP decreased the uptake. The results indicate that the sodium-sensitive phosphate influx is dependent on the Na⁺ gradient and on the membrane potential, which might act, preferentially, on the transport of the monovalent phosphate ion.     

Inhibition by Methylmalonate of Glycine Uptake by Synaptosomes from Rat Spinal Cord

Methylmalonate is accumulated in the genetically linked deficiency of methylmalonyl-CoA mutase (methylmalonic acidemia). In this condition is also observed an elevation of the glycine levels. This communication reports the inhibition of the synaptosomal glycine uptake by methylmalonate, when present at similar concentrations to those found in methylmalonic acidemia. This inhibition could be responsible, at least in part, for the neurological damage characteristic of this disease, by increasing the glycine levels in the synaptic cleft and thus interfering with the normal function of the inhibitory glycinergic synapsis in the spinal cord.