Physiological release of striatal acetylcholine (in vivo): effect of somatostatin on dopaminergic-cholinergic interaction

The effects of somatostatin (SOM) on the release of acetylcholine (ACh) and dopamine (DA) from striatum of freely moving rats were studied by transversal microdialysis. Acetylcholine (ACh) and dopamine (DA) were detected by high performance liquid chromatography (HPLC) with electrochemical detection. Somatostatin (0.1, 0.5 and 1 microM), administered locally through the microdialysis probe to the striatum, was able to release dose-dependently ACh from the cholinergic neurons of the striatum. The increase in the extracellular levels of ACh produced by 1 microM SOM in the striatum reached a maximum of 200%. ACh-releasing effect of SOM was completely inhibited by tetrodotoxin indicating that neuronal firing is involved in its effect. Local infusion of sulpiride, 10 microM, D(2) receptor antagonist, potentiated (about 100%) the SOM (1 microM)-induced release of ACh. SOM, 1 microM, was more effective in enhancing the release of ACh in the striatum (two-fold increase) after degeneration of the nigrostriatal DA pathway with 6-hydroxydopamine (6-OHDA) (250 microg/animal, i.c.v.). The D(2) receptor agonists bromcriptine, 10 microM, or apomorphine, 10 microM, completely antagonize SOM-induced release. SOM, 1 microM, enhanced the release of DA (about 400%). These findings indicate that SOM is capable of releasing both ACh and DA in the striatum, however, its effect on ACh release is partially masked unless the D(2) receptor-mediated tonic inhibitory effect of released DA from the nigro-striatal pathway is attenuated.     

Changes in dopamine and acetylcholine in striatum of the awake rat after chronic treatment with a dopamine uptake blocker

The effects of chronic treatment with a dopamine uptake blocker on dopamine and acetylcholine extracellular concentrations in striatum of the awake rat was studied. Male Wistar rats received daily injections (i.p.) of the dopamine uptake blocker nomifensine (10 mg/kg) during 22 days. Control group was injected with vehicle (saline). Microdialysis experiments were performed on days 1, 8, 15 and 22 of treatment. Nomifensine injections increased extracellular concentration of dopamine in striatum in all days of treatment without differences among days. In contrast, acetylcholine levels showed no changes in days 1 and 8 but increased in days 15 and 22 of treatment. These results shows that chronic treatment with a dopamine uptake inhibitor, nomifensine, has no effects on dopamine release but it increases acetylcholine release in striatum of the awake rat. These results would help to further understand the effects of chronic dopamine uptake inhibition.     

Effects of carbamazepine on acetylcholine release and metabolism

To clarify the mechanisms of action of carbamazepine (CBZ), we investigated the effects of CBZ on acetylcholine (ACh) release and metabolism in rat striatum and hippocampus. Acute administration of effective dose of CBZ (25 mg/kg) increased both striatal and hippocampal extracellular levels of ACh, whereas a supraeffective dose of CBZ (50 mg/kg) did not affect the levels and a toxic dose of CBZ (100 mg/kg) decreased the extracellular ACh levels in both brain regions. Both acute and chronic administrations of CBZ (25 and 50 mg/kg, mg/kg per day) increased intracellular ACh levels in striatum and hippocampus. The striatal intracellular ACh levels were decreased by both acute and chronic administrations of CBZ (100 mg/kg, mg/kg per day), whereas the hippocampal intracellular ACh levels were not affected. The effective CBZ concentration did not affect cholinesterase activity, whereas supraeffective CBZ concentration reduced it weakly. Effective dose of CBZ enhanced ACh release and synthesis; however, supraeffective doses of CBZ reduced ACh release and synthesis without enhancement of ACh degradation, indicating that CBZ has biphasic effects on ACh release and synthesis. Thus, the present findings, the slight stimulation of ACh function by effective dose of CBZ, are involved, at least partially, in the antiepileptic and mood stabilizing mechanisms of action of CBZ.     

Augmented pharmacologic stimulation of striatal acetylcholine release following developmental hypoxic-ischemic injury

We have previously shown that developmental hypoxic-ischemic injury in a unilateral rodent model leads to an increase in both morphologic and biochemical indices of striatal cholinergic neurons. To investigate the functional significance these changes, we have used the in vivo microdialysis technique to examine the regulation of striatal acetylcholine release in awake, adult rats following postnatal hypoxic-ischemic injury. We have found that injury does not alter basal release of acetylcholine, but it results in a marked augmentation in the increase of acetylcholine release normally observed after infusion of atropine or pirenzepine.     

Modification of acetylcholine release by nociceptin in conscious rat striatum

Nociceptin (NOC), an endogenous ligand for the orphan opioid receptor ORL1 (ORL1), has recently been recognized as a neuropeptide. We used brain microdialysis and on-line high performance liquid chromatography (HPLC) to examine the effect of NOC on the basal outflow of acetylcholine (ACh) in the freely moving rat striatum in vivo. ACh release was reduced by nociceptin at a concentration of 10(-5) M to 79% of control release. This effect of NOC was attenuated by [Phe1Psi(CH2-NH)Gly2]nociceptin-(1-13)-NH2 (PhePsi), suggesting that NOC activates the ORL1 receptor and (PhePsi) acts as an antagonist on ORL1 in rat striatum in vivo. These findings indicate that NOC may act as a neuropeptide which inhibits ACh release in the striatum via ORL1.     

Choline increases acetylcholine release and protects against the stimulation-induced decrease in phosphatide levels within membranes of rat corpus striatum

This study examined the possibility that membrane phospholipids might be a source of choline used for acetylcholine (ACh) synthesis. Slices of rat striatum or cerebellum were superfused with a choline-free or choline-containing (10, 20 or 40 microM) physiological solution with eserine, for alternating 20 min periods of rest or electrical stimulation. Superfusion media were assayed for choline and ACh, and slice samples taken before and after stimulation were assayed for choline, ACh, various phospholipids, protein and DNA. The striatal slices were able to sustain the stimulation-induced release of ACh, releasing a total of about 3 times their initial ACh contents during the 8 periods of stimulation and rest. During these 8 cycles, 885 pmol/micrograms DNA free choline was released from the slices into the medium, an amount about 45-fold higher than the initial or final free choline levels in the slices. Although repeated stimulation of the striatal slices failed to affect tissue levels of free choline or of ACh, this treatment did cause significant, dose-related (i.e., number of stimulation periods) stoichiometric decreases in tissue levels of phosphatidylcholine (PC) and of the other major phospholipids; tissue protein levels also declined significantly. Addition of exogenous choline to the superfusion medium produced dose-related increases in resting and evoked ACh release. The choline also fully protected the striatal slices from phospholipid depletion for as many as 6 stimulation periods. Cerebellar slices liberated large amounts of free choline into the medium but did not release measurable quantities of ACh; their phospholipid and protein levels did not decline with electrical stimulation. These data show that membrane phospholipids constitute a reservoir of free choline that can be used for ACh synthesis. When free choline is in short supply, ACh synthesis and release are sustained at the expense of this reservoir. The consequent reduction in membrane PC apparently is associated with a depletion of cellular membrane. The use of free choline by cholinergic neurons for two purposes, the syntheses of both ACh and membrane phospholipids, may thus impart vulnerability to them in situations where the supply of free choline is less than that needed for acetylation.     

Regulation of cortical acetylcholine release: Insights from in vivo microdialysis studies

Acetylcholine release links the activity of presynaptic neurons with their postsynaptic targets and thus represents the intercellular correlate of cholinergic neurotransmission. Here, we review the regulation and functional significance of acetylcholine release in the mammalian cerebral cortex, with a particular emphasis on information derived from in vivo microdialysis studies over the past three decades. This information is integrated with anatomical and behavioral data to derive conclusions regarding the role of cortical cholinergic transmission in normal behavioral and how its dysregulation may contribute to cognitive correlates of several neuropsychiatric conditions. Some unresolved issues regarding the regulation and significance of cortical acetylcholine release and the promise of new methodology for advancing our knowledge in this area are also briefly discussed.     

GABA(A) receptor antagonists enhance cortical acetylcholine release induced by 5-HT(3) receptor blockade in freely moving rats

ACh release from the rat frontal cortex was increased by both local, 0.1-1 microM, and systemic, 0.1-10 microg/kg, administration of the 5-HT(3) receptor antagonist ondansetron, reaching a maximum peak of 143% over basal values. Bicuculline, 1-10 microM, and flumazenil, 5-10 mg/kg, antagonists at different sites of the GABA(A) receptor, also enhanced ACh release, with maximum effects of 85 and 124% above baseline, respectively. GABA(A) receptor antagonists potentiated the effect induced by ondansetron on ACh release, reaching a peak increase of 238% (with bicuculline) and 259% (with flumazenil) over basal levels. These results suggest an interaction of ondansetron with GABAergic neurons modulating ACh release in the rat frontal cortex in vivo.     

Adenylate cyclase in striatal cholinergic interneurons regulates acetylcholine release

Fractional [³H]ACH efflux from dissociated rat striata tested whether tonic inhibition prevents stimulation of acetylcholine (ACH) release by adenylate cyclase. Forskolin stimulated release from the dissociated cells (threshold at 300 nM; EC₅₀ ≥ 1 μM). Release was also stimulated by 3-isobutyl-l-methylxanthine and was additive with forskolin. The 1,9-dideoxy forskolin analog that lacks cyclase-stimulating activity was ineffective. Thus, stimulation of adenylate cyclase within striatal cholinergic interneurons increases ACH secretion but is tonically inhibited by endogenous striatal transmitters. Disinhibition of the excitatory cyclase by denervation of striatal cholinergic interneurons in situ could contribute to supersensitivity without receptor upregulation.     

Inhibition of striatal acetylcholine release by endogenous serotonin

We have examined the hypothesis that endogenous serotonin (5-HT) exerts an inhibitory influence on the release of acetylcholine (ACh) in striatum. Striatal slices were prepared from adult rats, preincubated with [3H]choline, superfused, and exposed to electrical field stimulation. The stimulation-induced overflow of tritium into the superfusate was used as a measure of ACh release. We observed that fluoxetine, an inhibitor of 5-HT uptake, reduced ACh overflow in slices prepared from caudal striatum, an area of high 5-HT concentration, but not in slices from rostral striatum, an area of low 5-HT concentration. Moreover, methysergide, a 5-HT antagonist, increased ACh efflux in caudal but not rostral striatum. Finally, direct activation of 5-HT receptors with the 5-HT agonist, quipazine, inhibited stimulation-induced ACh overflow in both rostral and caudal striatum. These results suggest that endogenous 5-HT normally is capable of inhibiting striatal ACh release, and that the extent of the modulation is related to the degree of serotonergic innervation. In addition, 5-HT receptors capable of modulating ACh release are present in 5-HT-poor rostral striatum, as well as in 5-HT-rich caudal striatum.     

Carbachol and naloxone synergistically elevate dopamine release in rat striatum: an in vivo microdialysis study

Striatal dopamine (DA) release increased to 184% of baseline after 10–20 min of continuous intrastriatal perfusion with 10 mM carbachol, dropping to 124% after 30–40 min. The addition of 100 μM naloxone amplified (to 236% of baseline) and prolonged the increase in DA release, but naloxone alone (up to 1 mM) had no effect. These data suggest that activation of opiate-releasing neurons suppresses cholinergic stimulation of DA release.     

Enhancement of dopamine release from the striatum through metabotropic glutamate receptor activation in methamphetamine sensitized rats

An intracerebral microdialysis technique was applied to study the effect of metabotropic glutamate receptor (mGluR) agonist on dopamine release in the striatum of methamphetamine (MAP)-sensitized rats. Rats were treated with MAP (I mg/kg, i.p.) once daily for 6 consecutive days, followed by a 6-day withdrawal. Perfusion of 0.l mM (1S,3R)-1-aminocyclopentane-trans-1,3-dicarboxylic acid through a microdialysis probe placed in the striatum enhanced the extracellular dopamine level, and induced stereotyped behavior in MAP-sensitized rats. The enhancement of dopamine release and the stereotyped behavior were attenuated by co-perfusion of 0.4 mM RS-α-methyl-4-carboxyphenyl-glycine, a mGluR antagonist. The present results suggest that mGluRs may be involved in the expression of MAP-induced sensitization.     

Extracellular glutamate and dopamine measured by microdialysis in the rat striatum during blockade of synaptic transmission in anesthetized and awake rats

We investigated the effect of high dose tetrodotoxin (TTX) on microdialysis measurements of extracellular striatal glutamate and dopamine in normal female rats. Both halothane-anesthetized rats with acutely implanted microdialysis probes and awake rats with microdialysis probes implanted for 24 h were tested. Glutamate levels in awake rats were 45% higher than those of anesthetized rats. Extracellular glutamate remained TTX-insensitive irregardless of TTX concentration, anesthesia, or time lapsed after probe implantation. In contrast, TTX reduced dialysate dopamine in all TTX concentrations tested. We speculate that the lower glutamate levels in anesthetized rats reflect the effect of anesthesia. Because glutamate is involved, either as a reactant or a product in a variety of reactions critical to intermediary metabolism in the brain, basal dialysate glutamate levels might indirectly reflect brain metabolism. Further, we conclude that extracellular glutamate collected during non-stimulated conditions is TTX-insensitive. The fact that glutamate levels are TTX-independent does not rule out that glutamate is synaptic in origin but rather demonstrates that it is not nerve impulse-dependent. However, the brain interstitial glutamate pool accessible to the microdialysis probe during control conditions is most likely isolated from the synapse, and therefore does not impose a neurotoxic potential.     

5-HT2 receptor regulation of acetylcholine release induced by dopaminergic stimulation in rat striatal slices

The role of 5-hydroxytryptamine (5-HT) receptor subtypes in acetylcholine (ACh) release induced by dopamine or neurokinin receptor stimulation was studied in rat striatal slices. The dopamine D₁ receptor agonist SKF 38393 potentiated in a tetrodotoxin-sensitive manner the K⁺-evoked [³H]ACh release while SCH 23390, a dopamine D₁ receptor antagonist, had no effect. [³H]ACh release was decreased by the dopamine D₂ receptor agonist LY 171555 (quinpirole) and slightly potentiated by the dopamine D₂ receptor antagonist haloperidol. The selective neurokinin NK₁ receptor agonist [Sar⁹, met(O₂)¹¹]SP also potentiated K⁺-evoked release of [³H]ACh. GR 82334, a NK₁ receptor antagonist, blocked not only the effect of [Sar⁹, met(O₂)¹¹]SP but also the release of ACh induced by the D₁ receptor agonist SKF 38393. Among the 5-HT agents studied, only the 5-HT_2A receptor antagonists ketanserin and ritanserin were able to reduce the ACh release induced by dopamine D₁ receptor stimulation. Mesulergine, a more selective 5-HT_2C antagonist, showed an intrinsic releasing effect but did not affect K⁺-evoked ACh release induced by SKF 38393. Methysergide and methiothepin, mixed 5-HT_1/2 antagonists, as well as ondansetron, a 5-HT₃ receptor antagonist, showed an intrinsic effect on ACh release, their effects being additive to that of SKF 38393. 5-HT₂ receptor agonists were ineffective. However, the 5-HT₂ agonist DOI was able to prevent the antagonism by ketanserin of the increased [³H]ACh efflux elicited by SKF 38393, suggesting a permissive role of 5-HT_2A receptors. None of the above indicated 5-HT agents was able to reduce the ACh release induced by the selective NK₁ agonist. The results suggest that 5-HT₂ receptors, probably of the 5-HT_2A subtype, modulate the release of ACh observed in slices from the rat striatum after stimulation of dopamine D₁ receptors. It seems that this serotonergic control is exerted on the interposed collaterals of substance P-containing neurons which promote ACh efflux through activation of NK₁ receptors located on cholinergic interneurons.     

differential effect of systemic administration of bromocriptine andl-DOPA on the release of acetylcholine from striatum of intact and 6-OHDA-treated rats

A presumed balance between striatal dopaminergic and cholinergic systems forms a major theoretical framework for the development of new agents for the treatments of Parkinson's disease. We therefore studied the effect of two drugs currently used as anti-parkinsonian agents, bromocriptine (BROMO) andl-β-3-,4-dihydroxyphenylalanine (l-DOPA), on the release of striatal acetylcholine (ACh) in intact and 6-hydroxy-dopamine-treated rats using in vivo microdialysis. Lesioned rats with a 90% tissue depletion of striatal dopamine (DA) had a significantly higher output of striatal ACh than unlesioned rats (88 fmol/min vs. 52 fmol/min; 0.3 μmol/l neostigmine in perfusate). BROMO (4 mg/kg) inhibited the output of striatal ACh in both groups. Whereas the lowest dose ofl-DOPA (50 mg/kg) potently stimulated ACh output in lesioned rats, unlesioned rats were significantly less responsive. A higher dose ofl-DOPA (100 mg/kg) stimulated ACh output to the same extent in both groups. At the highest dose tested,l-DOPA (200 mg/kg) given to intact rats did not further increase striatal ACh output. Thus, BROMO decreases whereasl-DOPA increases striatal ACh release after systematic application. Therapeutic as well as side effects ofl-DOPA may therefore be mediated by neurochemical alterations that are more complex than previously thought.     

Previous exposure to footshock stress attenuates nicotine-induced serotonin release in rat striatum during the subsequent stress

We have analyzed the effects of chronic or repeated footshock stress on the release of serotonin (5-hydroxytryptamine: 5-HT) in the striatum of rats that received nicotine by using a microdialysis technique. Neither local infusion of nicotine alone nor stress application alone changed 5-HT release. Local infusion of 1 mM nicotine to the striatum, however, significantly increased 5-HT release in the striatum to 145.9 +/- 30.8 pg/dialysate during simultaneous stress application. These increases of extracellular 5-HT release induced by the combination of nicotine and stress application were also observed in rats that had received daily chronic footshock. However, the previously administered footshock induced the reduced release of 5-HT from the striatum to 33.5 +/- 8. 6 (repeated footshock) and 10.0 +/- 3.6 pg/dialysate (daily footshock) when footshock was given together with nicotine infusion. These results suggest that previous exposure to stress attenuated the nicotine-induced 5-HT release in the striatum during the subsequent stress.     

Ceruletide, a CCK-like peptide, attenuates dopamine release from the rat striatum via a central site of action

Ceruletide (CLT), a cholecystokinin-like peptide was given subcutaneously or via the perfusate to rats to clarify the site of action (peripheral vs. central location) of CLT, using in vivo microdialysis techniques. Striatal dopamine (DA) release induced by haloperidol (HPD) was significantly inhibited by subcutaneously administered CLT (160 micrograms/kg) when given with a perfusate containing 15 mM K+. Subdiaphragmatic vagotomies failed to block the inhibitory effect of CLT. CLT (10(-15)-10(-11) M) locally applied, via a dialysis tube, produced an inhibitory effect on HPD-induced DA release in the striatum in a dose-dependent manner. The inhibitory effect of CLT given subcutaneously on DA release was antagonized by both locally applied proglumide and systemically administered L-365,260. These findings suggest that systemically administered CLT can directly act on the striatal neurons via CCK-B receptors and produce an inhibitory effect on DA release in the striatum under appropriate depolarization.     

Modulation of acetylcholine release via GABAA and GABAB receptors in rat striatum

In order to investigate whether changes in acetylcholine (ACh) release induced by GABA receptors are due to a direct or indirect effect on cholinergic neurons in the striatum, GABA_A and GABA_B receptor bindings were assayed in the striatum microinjected with ethylcholine mustard aziridinium ion (AF64A), a cholinergic neurotoxin. Intra-striatal injection of a selective concentration of AF64A (10 nmol) reduced GABA_A receptor binding without significantly altering GABA_B receptor binding. Treatment with a higher, less selective concentration of AF64A (20 nmol) reduced all markers examined. These results suggest that GABA_A, but not GABA_B receptors, are located on cholinergic neurons in the striatum, and that GABA can directly modulate ACh release through stimulation of GABA_A receptors. Findings further suggest that GABA can also indirectly modulate ACh release through stimulation of GABA_B receptors located on non-cholinergic neuronal elements in the striatum.     

Neurons with galanin innervate cholinergic cells in the human basal forebrain and galanin and acetylcholine coexist

Immunocytochemistry with antibodies against cholinacetyltransferase (ChAT) and the novel peptide galanin (GA) were conducted as a single label or as double label experiments on the basal forebrain nuclei of brains from eleven human subjects without prior history of neurological disease. ChAT positive or cholinergic neurons form the major population of cells in the basal nucleus of Meynert. A minor portion of these ChAT positive neurons demonstrate a coexistence with GA positive immunoreactivity suggesting that they are cholinergic/GA neurons. Small fusiform neurons with long dendrites and complex local axonal networks are GA immunoreactive and are local circuit interneurons. The cholinergic cells in the basal nucleus are innervated by a fine network of GA immunoreactive axons and terminals which enwrap their perikarya and dendrites. It is suggested that GA in local circuit interneurons may provide a significant control or modulation of the cholinergic neurons and of cholinergic functions within the basal nucleus. In human diseases which feature a destruction of the basal forebrain cholinergic neurons, surviving GA neurons may inhibit most remaining cholinergic neurons and their function, with severe consequences.     

Relations between acetylcholine release and electrophysiological characteristics of theta rhythm: A microdialysis study in the urethane-anesthetized rat hippocampus

In urethane-anesthetized rats, recording electrodes were implanted in the left dorsal hippocampus and a dialysis probe was placed in the contralateral dorsal or ventral hippocampus. Samples of extracellular acetylcholine (ACh) levels were assessed at 10-min intervals over a period of 30 min using microdialysis with high-performance liquid chromatography with electrochemical detection. EEG was recorded during the same period and amplitude, frequency, and duration of theta rhythm were calculated for each of the three 10-min intervals. Data were analyzed using the two-tailed Spearman rank-order correlation test. A positive and high rank correlation coefficient (rho = 0.90, p < 0.01, N = 8) was seen between the average ACh cutflow in the dorsal hippocampus and the average theta amplitude, both being calculated for the entire collection period. A lower but statistically significant positive correlation (rho = 0.59, p < 0.01) between dorsal hippocampus ACh output and theta amplitude was also found when the couples of values collected for the 30-min period were pooled (n = 20). In contrast, frequency and duration of theta were not significantly correlated with dorsal hippocampus ACh release. Also, no statistically significant correlation (p > 0.05) was found between ACh output in the ventral hippocampus and theta parameters. Because changes in hippocampal ACh outflow are believed to be the reflection of changes in number and/or level of activity of cholinergic afferents to the dorsal hippocampus, our present findings support the view that, at least in the dorsal hippocampus of the urethane-anesthetized rat, the septohippocampal cholinergic projection regulates the theta amplitude but not frequency. Finally, the possibility that ACh outflow increase and tonic release in the hippocampus is not a sufficient condition to induce and maintain theta in the urethane-anesthetized rat is discussed.