Investigation on Acetylcholine,Aspartate, Glutamate and GABA Extracellular Levels from Ventral Hippocampus During Repeated Exploratory Activity in the Rat

The extracellular levels of aspartate, glutamate, -aminobutyric acid (GABA), and acetylcholine (ACh) were investigated by microdialysis, coupled with HPLC, in the ventral hippocampus of rats during two 30-min exploration periods. Motor activity was monitored. During exploration I, an increase in motor activity associated with a 315% increase in aspartate, 181% in glutamate, and 264% in ACh levels, occurred during the first 10 min. The increase in GABA level reached a maximum of 257% during the second 10 min. The neurotransmitter levels returned to basal values within 40 min. During exploration II, 1 h later, a smaller increase in neurotransmitter levels and motor activity was observed. In both explorations, the increase in neurotransmitter levels was completely abolished by 1 and 3 M TTX. A statistically significant relationship was found between neurotransmitter extracellular levels and motor activity, for aspartate and glutamate in exploration I, and for ACh in exploration I and II. In conclusion, exploratory activity is associated with or depends on the activation of neuronal systems in the ventral hippocampus releasing aspartate, glutamate, GABA, and ACh. The activation is dampened by habituation.     

Short Communication Occupation of Dopamine Receptors by N-n-Propylnorapomorphine or Spiperone and Acetylcholine Levels in the Rat Striatum

In an attempt to quantify the interactions between dopaminergic and cholinergic processes, the consequences of complete or partial activation (with N-n-propylnorapomorphine) or blockade (with spiperone) of dopamine receptors for the acetylcholine levels in the rat striatum were studied. The number of specific striatal binding sites (receptors) of spiperone was nearly three times that of N-n-propylnorapomorphine (76 and 26 pmol g-1 wet weight, respectively). The agonist produced a significant increase in the striatal levels of acetylcholine, but there was no simple relationship between receptor binding and these levels. A linear negative correlation was found between the striatal levels of acetylcholine and specific spiperone binding, showing that further receptor blockade induces a decrease in acetylcholine levels, which is independent of the receptors already occupied by the antagonist. The results of this study are evidence that one striatal dopamine receptor regulates the metabolism of at least 400 molecules of acetylcholine.     

Postnatal Development of the Acetylcholine System in Different Parts of the Rat Cerebellum

Abstract: The components of the cholinergic nervous system, i.e., choline acetyltransferase, acetylcholinesterase, sodium-dependent high-affinity choline uptake, acetylcholine, and the muscarinic acetylcholine receptors, in the developing archi- and paleocerebellum of the rat have been investigated by biochemical methods. A close correlation between the development of the different elements of the system has been demonstrated in the two areas. The cholinergic structure develops first in the archicerebellum, which displays high levels of choline acetyltransferase, acetylcholinesterase, acetylcholine, and sodium-dependent high-affinity choline uptake. The paleocerebellum receives a sparser cholinergic innervation during development. The differences in the values for these components in the cerebellum as a whole may reflect the development of cholinergic and noncholinergic neuronal structures. It is concluded that the development of the cholinergic system cannot be analyzed in the cerebellum as a whole; rather specific regions such as the archi-, paleo-, or neocerebellum must be examined.     

Modulation of the Acetylcholine System in the Superior Cervical Ganglion of Rat: Effects of GABA and Hypoglossal Nerve Implantation After In Vivo GABA Treatment

gamma-Aminobutyric acid (GABA) was applied to the superior cervical ganglion (SCG) of CFY rats in vitro and in vivo, with or without implantation of a hypoglossal nerve, to evaluate the effects of these experimental interventions on the acetylcholine (ACh) system, which mainly serves the synaptic transmission of the preganglionic input. Long-lasting GABA microinfusion into the SCG in vivo apparently resulted in a "functional denervation." This treatment reduced the acetylcholinesterase (AChE; EC 3.1.1.7) activity by 30% (p less than 0.01) and transiently increased the number of nicotinic acetylcholine receptors, but had no significant effect on the choline acetyltransferase (acetyl-coenzyme A:choline-O-acetyltransferase; EC 2.3.1.6) activity, the ACh level, or the number of muscarinic acetylcholine receptors. The relative amounts of the different molecular forms of AChE did not change under these conditions. In vivo GABA application to the SCG with a hypoglossal nerve implanted in the presence of intact preganglionic afferent synapses exerted a significant modulatory effect on the AChE activity and its molecular forms. The "hyperinnervation" of the ganglia led to increases in the AChE activity (to 142.5%, p less than 0.01) and the 16S molecular form (to 200%, p less than 0.01). It is concluded that in vivo GABA microinfusion and GABA treatment in the presence of additional cholinergic synapses has a modulatory effect on the elements of the ACh system in the SCG of CFY rats.     

Relationship Between Dopamine Receptor Occupation by Spiperone and Acetylcholine Levels in the Rat Striatum After Long-Term Haloperidol Treatment Depends on Dopamine Innervation

The effect of chronic neuroleptic treatment on the relationship between the blockade of dopamine (DA) receptors by the neuroleptic drug spiperone and the decline in acetylcholine (ACh) levels was determined in the rat striatum in vivo. In rats, a unilateral lesion of the nigrostriatal pathway was produced with 6-hydroxydopamine. The rats were treated for 6 weeks with haloperidol (twice a day at 1 mg kg-1). Partial and complete receptor occupation was determined with radioactive spiperone (a D2 antagonist), given in various doses of different specific activity 2 h before death. ACh, choline, and radioactivity contents were measured in the same striatum. Following long-term haloperidol treatment, an increase in the maximal number of binding sites for spiperone was found. Virtually identical negative (linear) correlations between striatal ACh content and the number of receptors occupied by spiperone were found in saline- or subchronic haloperidol-treated rats when DA innervation was intact. The slope of the line describing the decrease in ACh content per occupied receptor, however, was much lower in haloperidol-treated rats than in saline-treated animals. After lesioning of the dopaminergic pathway, there was no longer a correlation between the receptor occupation and ACh levels in the striatum. These results show that receptor occupation by a neuroleptic correlates highly with function only when dopaminergic innervation is intact. Also, it appears that there is no fixed number of striatal ACh molecules per DA receptor, and, finally, that in vivo receptor detection methods distinguish differences in receptor density (as do in vitro techniques).     

Differential Effects of Bromocriptine on Dopamine and Acetylcholine Release Modulatory Receptors

Rabbit neostriatal slices were prelabeled with [3H]dopamine (DA) and [14C]choline and then superfused. The electrical stimulation-evoked release of DA and of acetylcholine (ACh) was abolished by 0.33 microM tetrodotoxin and by low calcium concentrations (0.13 mM). Bromocriptine, a selective D2-DA receptor agonist, inhibited in a concentration-dependent manner the evoked overflow of DA and ACh, without affecting the basal efflux of both transmitters. The effects of bromocriptine were antagonized by sulpiride, a specific antagonist of D2-DA receptors. With stimulation at 0.3 Hz and 120 pulses, bromocriptine was eight times more potent in inhibiting the evoked overflow of DA (IC50: 11 nM) than that of ACh (IC50: 83 nM). Stimulations at 3 Hz and 360 pulses markedly reduced the potency of bromocriptine in inhibiting DA and ACh release, and diminished its selectivity for presynaptic receptors. These results indicate that DA receptors that modulate the release of DA and ACh are of the D2 subtype. The greater potency of bromocriptine at pre- than at postsynaptic sites suggests that these receptors may be different in quantity and/or quality [D2-alpha (presynaptic) versus D2-beta (postsynaptic)]. Finally, marked differences in the potency and efficacy of DA agonist actions on DA and ACh release modulatory receptors are obtained, depending on the parameters of stimulation used.     

N-methyl-d-Aspartic Acid Differentially Regulates Extracellular Dopamine, GABA, and Glutamate Levels in the Dorsolateral Neostriatum of the Halothane-Anesthetized Rat: An In Vivo Microdialysis Study

Abstract: The effects of local perfusion with the glutamate receptor agonist NMDA and the noncompetitive NMDA receptor antagonist dizolcipine (MK-801) on extracellular dopamine (DA), GABA, and glutamate (Glu) levels in the dorsolateral striatum were monitored using in vivo microdialysis in the halothane-anesthetized rat. In addition, the sensitivity of both the basal and NMDA-induced increases in levels of these neurotransmitter substances to perfusion with tetrodotoxin (TTX; 10^?5 M) and a low Ca²⁺ concentration (0.1 mM) was studied. The results show that the local perfusion (10 min) with both the 10^?3 and 10^?4 M dose of NMDA increased striatal DA and GABA outflow, whereas only the (10^?3 M) dose of NMDA was associated with a small and delayed increase in extracellular Glu levels. The NMDA-induced effects were dose-dependently counteracted by simultaneous perfusion with MK-801 (10^?6 and 10^?5 M). Both the basal and NMDA (10^?3 M)-induced increase in extracellular striatal DA content was reduced in the presence of TTX and a low Ca²⁺ concentration, whereas both basal and NMDA-stimulated GABA levels were unaffected by these treatments. Both the basal and NMDA-stimulated Glu levels were enhanced following TTX treatment, whereas perfusion with a low Ca²⁺ concentration reduced basal Glu levels and enhanced and prolonged the NMDA-induced stimulation. These data support the view that NMDA receptor stimulation plays a role in the regulation of extracellular DA, GABA, and Glu levels in the dorsolateral neostriatum and provide evidence for a differential effect of NMDA receptor stimulation on these three striatal neurotransmitter systems, possibly reflecting direct and indirect actions mediated via striatal NMDA receptors.     

Effects of Ischaemia on Neurotransmitter Release from the Isolated Retina

Abstract: The effects of "ischaemia" (glucose-free Krebs-bicarbonate medium gassed with N₂/CO₂ on the release of glutamate and other major neurotransmitters in the retina were examined using the isolated rat and rabbit retina. Amino acid transmitters, acetylcholine, and dopamine were measured by HPLC. The release of glutamate, aspartate, GABA, and glycine from ischaemic retinas was more than doubled after 30 min, and after 90 min of ischaemia the release of amino acids was ∼ 15–20-fold that of control values. Ischaemia also produced large increases in the release of dopamine from both the rat and especially the rabbit retina. In contrast, the release of acetylcholine from the rat retina was significantly decreased by ischaemia, although the release of choline was increased. Because the ischaemia-induced release of glutamate, aspartate, and GABA from the rat retina was completely Ca independent, and exposure of the retina to high K (50 m M ) did not stimulate amino acid release, it is concluded that the mechanisms underlying the ischaemia-induced release do not involve an initial release of K or an influx of calcium.     

Effects of In Vivo Hypoxia on Acetylcholine Synthesis by Rat Brain Synaptosomes

Abstract: Synaptosomes from normoxic and hypoxic rats were incubated aerobically in the presence and absence of veratridine. In the absence of veratridine, no significant difference was observed between the two types of preparation regarding either ATP/ADP ratio or ¹⁴CO₂ or [¹⁴C]acetylcholine synthesis from D-[U-¹⁴C]glucose. However, in the presence of veratridine, significant reductions in the output of ¹⁴CO₂ and [¹⁴C]acetylcholine by synaptosomes from hypoxic rats were apparent. It was concluded that irreversible metabolic lesions occur at the synapse as a result of hypoxia, which are apparent only when the metabolism of the preparation is accelerated to a level comparable with the maximal rate occurring in vivo. The presence of such lesions is further evidenced by the significant reductions in ATP/ADP ratio, ¹⁴CO₂ output, and [¹⁴C]acetylcholine synthesis that occur in synaptosomes from hypoxic rats made anoxic in vitro and permitted to recover. Such decreases are not seen when synaptosomes from normoxic rats are similarly treated.     

Effects of Calyculin A and Okadaic Acid on Acetylcholine Release and Subcellular Distribution in Rat Hippocampal Formation

Abstract : The mechanisms regulating the compartmentation of acetylcholine (ACh) and the relationship between transmitter release and ACh stores are not fully understood. In the present experiments, we investigated whether the inhibitors of serine/threonine phosphatases 1 and 2A, calyculin A and okadaic acid, alter subcellular distribution and the release of ACh in rat hippocampal slices. Calyculin A and okadaic acid significantly (p < 0.05) depleted the occluded ACh of the vesicular P₃ fraction, but cytoplasmic ACh contained in the S₃ fraction was not significantly affected. The P₃ fraction is known to be heterogeneous ; calyculin A and okadaic acid reduced significantly (p < 0.05) the amount of ACh recovered with a monodispersed fraction (D) of synaptic vesicles, but the other nerve terminal bound pools (E-F and G-H) were not so affected. K⁺-evoked ACh release decreased significantly (p < 0.01) in the presence of calyculin A and okadaic acid, suggesting that fraction D's vesicular store of ACh contributes to transmitter release. The loss of ACh from synaptic vesicle fractions prepared from tissue exposed to phosphatase inhibitors appeared not to result from a reduced ability to take up ACh. Thus, when tissue was allowed to synthesize [³H]ACh from [³H]choline, the ratio of [³H]ACh in the S₃ to P₃ fractions was not much changed by exposure of tissue to calyculin A or okadaic acid ; furthermore, the specific activity of ACh recovered from the D fraction was not reduced disproportionately to that of cytosolic ACh. The changes are considered to reflect reduced synthesis of ACh by tissue treated with the phosphatase inhibitors, rather than an effect on vesicle uptake mechanisms. Thus, exposure of tissue to calyculin A or okadaic acid appears to produce selective depletion of tissue ACh content in a subpopulation of synaptic vesicles, suggesting that phosphatases play a role in ACh compartmentation.     

Effects of Feeding and Drinking on Acetylcholine Release in the Nucleus Accumbens, Striatum, and Hippocampus of Freely Behaving Rats

Extracellular levels of acetylcholine (ACh) were measured in the nucleus accumbens (NAC), striatum (STR), and hippocampus (HIPP) using microdialysis in 30-min intervals before, during, and after free-feeding in 20-h food-deprived rats. The effects on ACh in the NAC and STR were also observed in response to water intake in 20-h water-deprived animals. Neostigmine was used in the perfusate to improve ACh recovery. Basal ACh was sensitive to tetrodotoxin and low calcium, and therefore largely neuronal in origin. Feeding caused a 38% increase in extracellular ACh in the NAC and no change in the STR or HIPP. Dopamine was also increased in the NAC (48%) and to a lesser extent in the STR (21%) following feeding. Drinking caused 18-20% increases in ACh release in both the NAC and STR. In a separate experiment, ACh release in the NAC was monitored in 10-min intervals during free-feeding; ACh increased in the interval immediately following maximal food intake. These results suggest a site-specific increase in ACh release following feeding that cannot be solely attributed to the activation associated with this behavior.     

Taurine-induced attenuation of MPP+ neurotoxicity in vitro: a possible role for the GABA(A) subclass of GABA receptors

Taurine is a sulphur-containing beta-amino acid found in high (millimolar) concentrations in excitable tissues such as brain and heart. Its suggested roles include osmoregulator, thermoregulator, neuromodulator, and potential neurotransmitter. This amino acid has also been shown to be released in large concentrations during ischaemia and excitotoxin-induced neuronal damage. Here we report a protective effect of taurine against MPP(+)-induced neurotoxicity in coronal slices from rat brain. Significant protective effects were observed at taurine concentrations of 20 and 1 mM, suggesting a potential role for taurine in cases of neuronal insult. Studies with the synthetic taurine analogues taurine phosphonate, guanidinoethane sulphonate, and trimethyltaurine suggested the observed effect to be mediated via an extracellular mechanism. The use of GABA receptor ligands muscimol and bicuculline indicated the effect to be mediated through activation of GABA(A) receptors.     

Presynaptic Control of the Synthesis and Release of Dopamine from Striatal Synaptosomes: A Comparison Between the Effects of 5-Hydroxytryptamine, Acetylcholine, and Glutamate

The effects of 5-HT and glutamate on dopamine synthesis and release by striatal synaptosomes were investigated and compared with the action of acetylcholine, which acts presynaptically on this system. 5-HT inhibited (28%) synthesis of [¹⁴C]dopamine from L-[U-¹⁴C]tyrosine, at 10-⁵M and above. This contrasts with the action of acetylcholine, which stimulated [¹⁴C]-dopamine synthesis by 24% at 10-⁴ M. Tissue levels of GABA were unaffected by either 5-HT or acetylcholine up to concentrations of 10-⁴ M. The inhibitory action of 5-HT (5 × 10^?5 M and 2 × 10^?4 M) on [¹⁹C]dopamine synthesis was completely abolished by methysergide (2 × 10^?6 M). Higher concentrations of methysergide (10^?4 M) or cyproheptadine (10^?5 M) inhibited [¹⁴C]dopamine synthesis by 28% and 25%, respectively, when added alone to synaptosomes. However, only methysergide prevented the further inhibition of synthesis caused by 5-HT. At concentrations of 2 × 10^?5 M and above, 5-HT stimulated [¹⁴C]dopamine release. This releasing action differed from that of acetylcholine, which occurred at lower concentrations (e.g., 10^?6 M). Methysergide (up to 10^?4 M) or cyproheptadine (2 × 10^?4 M) did not reduce the 5-HT (5 × 10^?5 M)-induced release of [¹⁴C]dopamine, but methysergide (10^?4 M) showed a potentiation (49%) of this increased release. The stimulatory effects of 5-HT (2 × 10^?5 M) and K⁺ (56 mM) on [¹⁴C]dopamine release were additive, indicating that two separate mechanisms were involved. However, when both agents were present the stimulatory effect of K⁺ (56 mM) on [¹⁴C]dopamine synthesis was not seen above the inhibitory effect of 5-HT. Glutamate (0.1-5 mM) did not affect [⁴C]dopamine release or its synthesis from L-[U-¹⁴C]tyrosine. It is concluded that 5-HT modulates the synthesis of dopamine in striatal nerve terminals through a presynaptic receptor mechanism, an action antagonised by methysergide. The releasing action of 5-HT apparently occurs through a separate mechanism which is also distinct from that involved in the response to K⁺ depolarisation.     

NMDA and GABA B receptors are involved in controlling nematocyst discharge in hydra

The role of chemical neurotransmission in nematocyst discharge was investigated by stimulating the cnidocils of nematocysts in ablated tentacles of Hydra vulgaris with a piezoelectrically-driven glass probe, in the presence of selected neurotransmitters. Acetylcholine, dopamine, epinephrine, glycine, and serotonin (10^− 4, 10^− 6, 10^− 8 M) per se, did not alter stenotele and desmoneme discharge. γ-Amino-butyric acid (GABA) significantly increased desmoneme discharge when the cnidocil of another desmoneme in the same or adjacent battery cell complex was stimulated without affecting the discharge rates of the directly stimulated desmonemes or stenoteles. Baclofen (GABA_B agonist) mimicked the increase; its antagonist, phaclofen, counteracted it. GABA_A agonists and antagonists did not alter discharge rates. Glutamate caused a dose-dependent increase in the discharge rate of directly stimulated stenoteles; distant stenotele and desmoneme discharge rates were unaffected. Kainate, AMPA, and NMDA, per se, did not alter discharge rates. Co-administration of NMDA and kainate mimicked glutamate's effects. AMPA plus NMDA increased discharge rates. DAP-5 (NMDA antagonist) and CNQX, (kainate/AMPA antagonist) counteracted the increase. The findings suggest that metabotropic GABA is involved in recruiting desmonemes by disinhibiting those previously inhibited, and that the NMDA/kainate–AMPA mechanism regulating Ca⁺⁺ entry in higher neuroeffector systems is an early-evolved process, which, in hydra, modulates nematocyst discharge.     

Dopamine Agonist-Mediated Inhibition of Acetylcholine Release in Rat Striatum Is Modified by Thyroid Hormone Status

Abstract: K⁺-evoked acetyl[³H]choline ([³H]ACh) release was inhibited in a concentration-dependent manner by apomorphine and the D₂ agonist quinpirole in striatal slices prepared from euthyroid and hypothyroid rats. However, there was a significant increase in the maximum inhibition observed with both agonists in the hypothyroid compared with the euthyroid group, which paralleled the increased D₂ agonist sensitivity reported for stereotyped behavior. The D₂ antagonist raclopride decreased, and the D, antagonist SCH 23390 increased, the inhibition of [³H]ACh release by apomorphine, confirming an inhibitory role for D₂ receptors and an opposing role for D₁ receptors. Because there is no difference in D₁ or D₂ receptor concentration between the euthyroid and hypothyroid groups, it is suggested that thyroid hormone modulation of D₂ receptor sensitivity affects a receptor-mediated event. Following intrastriatal injection of pertussis toxin (PTX), apomorphine no longer inhibited [³H]ACh release. In fact, increased [³H]- ACh release was observed, an effect reduced by SCH 23390, providing evidence that D₁ receptors enhance [³H]- ACh release, and confirming that a PTX-sensitive G protein mediates the D₂ response. As it has been reported that thyroid hormones modulate G protein expression, this mechanism may underlie their effect on dopamine agonist- mediated inhibition of ACh.     

Effects of Activation of NMDA and AMPA Glutamate Receptors on the Extracellular Concentrations of Dopamine, Acetylcholine, and GABA in Striatum of the Awake Rat: A Microdialysis Study

The effects of activation of the AMPA and NMDA ionotropic glutamate receptors on the extracellular concentration of dopamine, acetylcholine, (ACh) and GABA in striatum of the awake rat was investigated. Also the levels of DOPAC, HVA, and choline (Ch) were included in this study. Seven to eight days after stereotaxical implantation of a guide-cannulae assembly, microdialysis experiments were performed. The dopamine and ACh content of samples were measured by HPLC coupled to electrochemical detection. GABA was measured using fluorometric detection. Perfusion of AMPA (1, 20, 100 mM) produced a dose-related increase of dopamine and a dose-related decrease of DOPAC and HVA. AMPA 100 M decreased extracellular concentrations of ACh and increased the extracellular concentration of Ch and GABA. Perfusion of NMDA 500 M increased the concentration of dopamine and decreased DOPAC and HVA. Also, NMDA 100 M decreased DOPAC. NMDA 500 M decreased the extracellular concentrations of ACh and increased the concentrations of Ch and GABA. Perfusion of the AMPA/kainate-antagonist DNQX (100 M) blocked the effects of AMPA (100 M) on dopamine, DOPAC, HVA, ACh, and GABA concentrations. Perfusion of the NMDA-antagonist CPP (100 M) blocked the effects of NMDA 500 M on dopamine, DOPAC, HVA, ACh, Ch, and GABA concentrations. These results suggest an interaction between glutamate-dopamine-ACh-GABA in striatum of the awake rat.     

Effects of Chronic Nicotinic Ligand Exposure on Functional Activity of Nicotinic Acetylcholine Receptors Expressed by Cells of the PC12 Rat Pheochromocytoma or the TE671/RD Human Clonal Line

Studies were conducted to ascertain the temporal and dose-dependent effects of nicotinic ligand exposure on functional activity of different nicotinic acetylcholine receptor (nAChR) subtypes, as expressed by cells of the PC12 rat pheochromocytoma (ganglia-type nAChR) or the TE671/RD human (muscle-type nAChR) clonal line. Chronic (3-72-h) agonist (nicotine or carbamylcholine) treatment of cells led to a complete (TE671) or nearly complete (PC12) loss of functional nAChR responses, which is referred to as "functional inactivation." Some inactivation of nAChR function was also observed for the nicotinic ligands d-tubocurarine (d-TC), mecamylamine, and decamethonium. Half-maximal inactivation of nAChR function was observed within 3 min for TE671 cells and within 10 min for PC12 cells treated with inactivating ligands. Functional inactivation occurred with dose dependencies that could not always be reconciled with those obtained for acute agonist activation of nAChR function or for acute inhibition of those responses by d-TC, decamethonium, or mecamylamine. Treatment of TE671 or PC12 cells with the nicotinic antagonist pancuronium or alcuronium alone had no effect on levels of expression of functional nAChRs. However, evidence was obtained that either of these antagonists protected TE671 cell muscle-type nAChRs or PC12 cell ganglia-type nAChRs from functional inactivation on long-term treatment with agonists. Recovery of TE671 cell nAChR function following treatment with carbamylcholine, nicotine, or d-TC occurred with half-times of 1-3 days whether cells were maintained in situ or harvested and replated after removal of ligand. By contrast, 50% recovery of functional nAChRs on PC12 cells occurred within 2-6 h after drug removal. In either case the time course for recovery from nAChR functional inactivation is much slower than recovery from nAChR "functional desensitization," which is a reversible process that occurs on shorter-term (0-5-min) agonist exposure of cells. These results indicate that ganglia-type and muscle-type nAChRs are similar in their sensitivities to functional inactivation by nicotinic ligands but differ in their rates of recovery from and onset of those effects. The ability of drugs such as the agonists d-TC, decamethonium, and mecamylamine to induce functional inactivation may relate to their activities as partial/full agonists, channel blockers, and/or allosteric regulators. Effects of drugs such as pancuronium and alcuronium are likely to reflect simple competitive inhibition of primary ligand binding at functional activation sites.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effect of Motor and Premotor Cortex Ablation on Concentrations of Amino Acids, Monoamines, and Acetylcholine and on the Ultrastructure in Rat Striatum. A Confirmation of Glutamate as the Specific Cortico-Striatal Transmitter

At 1, 2, and 4 weeks after unilateral premotor and motor cortex ablation in rats, a significant and lasting decrease in glutamate levels in the ipsilateral versus contralateral striatum was observed. A significant corresponding fall in aspartate was seen only after 1 week. In contrast, there was a large increase in the striatal concentrations of lysine, threonine, alanine, and glutamine 1 week after the cortical ablation. This correlates with the extensive glial proliferation in the deafferented ipsilateral striatum. Four weeks after cortical ablation the GABA concentration was significantly increased. There was no decrease in other putative transmitters (dopamine, serotonin, acetylcholine, glycine and taurine), nor was a glutamate decrease observed in the hippocampus or in the hypothalamus, which do not receive direct premotor and motor cortical inputs. Both biochemical and morphological evidence for a minor contralateral cortico-striatal projection was obtained. Correlating with the fall in glutamate, ultrastructural observations indicated the degeneration of two types of striatal synapses, i.e., those of the axo-spinous type III and of the axo-dendritic type VII. Frontal cortex ablation clearly affects, in opposite directions, the metabolism of various striatal amino acids but not that of acetylcholine and the monoamine transmitters. The results strongly support the view that glutamate is the transmitter of the cortico-striatal fibers.     

Effects of In Vitro Anoxia and Low pH on Acetylcholine Release by Rat Brain Synaptosomes

Acetylcholine and choline release from rat brain synaptosomes have been measured using a chemiluminescent technique under a variety of conditions set up to mimic anoxic insult, including conditions of low pH (6.2) and the presence of lactate plus pyruvate as substrate. Lactate plus pyruvate as substrate consistently gave higher respiration rates than glucose alone, but with either substrate (glucose or lactate plus pyruvate) the omission of Ca2+ caused an increase in respiration whereas a low pH caused a decreased respiration. Acetylcholine release under control conditions (glucose, pH 7.4) was Ca2+-dependent, stimulated by high K+ concentrations, and decreased significantly during anoxia but recovered fully after a period of postanoxic oxygenation. Low pH (6.2) suppressed K+ stimulation of acetylcholine release, and after a period of anoxia at low pH the recovery of acetylcholine release was only partial. With lactate plus pyruvate as substrate, the effects of anoxia and/or low pH on acetylcholine release and its subsequent recovery were exacerbated. Choline release from synaptosomes, however, was not affected by anoxic/ionic conditions in the same way as acetylcholine release. At low pH (6.2) there was a marked reduction in choline release both under aerobic and anoxic conditions. These results suggest that acetylcholine release per se from the nerve is very sensitive to anoxic insult and that the low pH occurring during anoxia may be an important contributory factor.     

Output, Tissue Levels, and Synthesis of Acetylcholine During and After Transient Forebrain Ischemia in the Rat

Biochemical changes in the rat brain cholinergic system during and after 60 min of ischemia were studied using a four-vessel occlusion model. Extracellular acetylcholine (ACh) concentrations in the unanesthetized rat hippocampus markedly increased during ischemia and reached a peak (about 13.5 times baseline levels) at 5-10 min after the onset of ischemia. At 2-5 h after reperfusion, extracellular ACh concentrations were reduced to 64-72% of the levels of controls. ACh levels in the hippocampus, striatum, and cortex decreased significantly during ischemia and exceeded their control values just after reperfusion. A significant increase in hippocampal ACh level after 2 days of reperfusion and a decrease in [14C]ACh synthesis from [14C]glucose in hippocampal slices excised at 2 days after reperfusion were observed. The extracellular concentrations and tissue levels of choline markedly increased after ischemia. These results show that ACh is markedly released into the extracellular space in the hippocampus during ischemia, and they suggest that ACh synthesis is activated just after reperfusion and that cholinergic activity is reduced after 2-48 h of reperfusion in the hippocampus.