Simultaneous determination of cholecystokinin,dopamine, glutamate and aspartate in cortex and striatum of the rat using in vivo microdialysis

Summary Extracellular levels of cholecystokinin (CCK), dopamine (DA), glutamate (Glu) and aspartate (Asp) were simultaneously monitored in the frontoparietal cortex and the striatum of halothane-anaesthetized rats using in vivo microdialysis. Under basal conditions, cortical and striatal CCK levels were 3.11 ± 0.39 pM and 2.76 ± 0.15 pM, respectively. Local KCl (10^–1 M) and bicuculline (10^–4 M) co-application in cortex or striatum increased the CCK levels 18-fold and 26-fold, respectively. The DA level in striatum was 3.78 ± 0.28 nM and the local perfusion with KCl + bicuculline led to a 45-fold increase. The cortical and striatal outputs of Glu were of the order of 2 · 10^–6 M and Asp levels were around 6 · 10^–7 M. Local stimulation with KCl (10^–1 M) and bicuculline (10^–4 M) caused a small increase (2 fold) in cortical and striatal levels of Glu and Asp. The addition of KCl (10^–1 M) and bicuculline (10^–4 M) to the cortical perfusion medium did not modify CCK, DA or Glu concentrations in striatum. These results demonstrate that CCK, DA, Glu and Asp may be simultaneously monitored in vivo and support the idea that their extracellular levels recovered in the microdialysis perfusates could be derived from neuronal pools.     

Regulation of dopamine D1 receptor trafficking and desensitization by oligomerization with glutamate N-methyl-D-aspartate receptors

Activation of dopamine D1 receptors is critical for the generation of glutamate-induced long-term potentiation at corticostriatal synapses. In this study, we report that, in striatal neurons, D1 receptors are co-localized with N-methyl-d-aspartate (NMDA) receptors in the postsynaptic density and that they co-immunoprecipitate with NMDA receptor subunits from postsynaptic density preparations. Using modified bioluminescence resonance energy transfer, we demonstrate that D1 and NMDA receptor clustering reflects the existence of direct interactions. The tagged D1 receptor and NR1 subunit cotransfected in COS-7 cells generated a significant bioluminescence resonance energy transfer signal that was insensitive to agonist stimulation and that did not change in the presence of the NR2B subunit, suggesting that the D1 receptor constitutively and selectively interacts with the NR1 subunit of the NMDA channel. Oligomerization with the NR1 subunit substantially modified D1 receptor trafficking. In individually transfected HEK293 cells, NR1 was localized in the endoplasmic reticulum, whereas the D1 receptor was targeted to the plasma membrane. In cotransfected cells, both the D1 receptor and NR1 subunit were retained in cytoplasmic compartments. In the presence of the NR2B subunit, the NR1-D1 receptor complex was translocated to the plasma membrane. These data suggest that D1 and NMDA receptors are assembled within intracellular compartments as constitutive heteromeric complexes that are delivered to functional sites. Coexpression with NR1 and NR2B subunits also abolished agonist-induced D1 receptor cytoplasmic sequestration, indicating that oligomerization with the NMDA receptor could represent a novel regulatory mechanism modulating D1 receptor desensitization and cellular trafficking.     

L-dopa administration enhances exocytotic dopamine release in vivo in the rat striatum.

Peripheral administration of L-3,4-dihydroxyphenylalanine (L-DOPA) methylester increased extracellular levels of DOPA and dopamine (DA) in the rat striatum monitored by in vivo brain microdialysis. The increase in DA levels persisted after inhibition of DA reuptake by nomifensine. Administration of blockers of voltage-dependent Na+ (tetrodotoxin) or Ca2+ (NKY-722) channels through the dialysis membrane completely eliminated the increase in DA levels. These results demonstrate that the L-DOPA-induced DA release is exocytotic in nature and hence, derived from neurons in the striatum.     

Tonic autoinhibition contributes to the heterogeneity of evoked dopamine release in the rat striatum

Electrically evoked dopamine release as measured by voltammetry in the rat striatum is heterogeneous in both amplitude and temporal profile. Previous studies have attributed this heterogeneity to variations in the density of dopamine (DA) terminals at the recording site. We reach the alternate conclusion that the heterogeneity of evoked DA release derives from variations in the extent to which DA terminals are autoinhibited. We demonstrate that low-amplitude, slow evoked DA responses occur even though recording electrodes are close to DA terminals. Moreover, the D₂ agonist and antagonist, quinpirole and raclopride, respectively, affect the slow responses in a manner consistent with the known functions of pre-synaptic D₂ autoreceptors. Recording sites that exhibit autoinhibited responses are prevalent in the dorsal striatum. Autoinhibition preceded electrical stimulation, which is consistent with our prior reports that the striatum contains a tonic pool of extracellular DA at basal concentrations that exceed the affinity of D₂ receptors. We conclude that the striatum contains DA terminals operating on multiple time courses, determined at least in part by the local variation in autoinhibition. Thus, we provide direct, real-time observations of the functional consequence of tonic and phasic DAergic signaling in vivo .     

The in vitro release of endogenousm-tyramine,p-tyramine and dopamine from rat striatum

Administration of phenelzine (100 mg/kg, i.p., 18 hr) increased rat striatal concentrations of pTA, mTA and DA by 30, 6.7 and 1.5 fold, respectively. Lesions of the medial forebrain bundle prevented these increase, permitting the conclusion that the phenelzine-induced amine increases were localized in the synaptic terminals. The release of endogenous pTA, mTA and DA from striatal slices obtained from phenelzine-treated rats was investigated. 50 mM KCl elicited releases of pTA, mTA and DA which were significantly greater than their respective basal releases. These K⁺-stimulated releases were antagonized significantly by 15 mM MgCl₂, suggesting that they are calcium-dependent in nature. We have concluded, therefore, that mTA and pTA, as well as DA, are released from striatal nerve terminals in vivo. The total amounts of mTA and DA, but not pTA, released in the release experiments were greater than those found in the nonincubated tissue. It appears, therefore, that the biosynthesis of mTA and DA was stimulated during the incubation of the striatal slices.     

Comparison of dopamine uptake and release in vitro in sheep and rat striatum.

Cocaine inhibits tritium-labeled dopamine ([3H]DA) uptake in rat (IC50 approximately 400 nM) and sheep (IC50 approximately 1 microM) striatum. GBR 12909, a selective DA uptake inhibitor, potently inhibits [3H]DA uptake in rat (IC50 less than 10 nM), but is less effective (only 60% of the uptake is inhibited at a concentration of 10 microM) and less potent (IC50 approximately 300 nM) in sheep. [3H]DA release from slices of rat or sheep striatum is stimulated by potassium (15-50 mM). In the presence of nomifensine (10 microM), cocaine (10 microM) had no effect on potassium-stimulated [3H]DA release in either species. [3H]DA release is increased by N-methyl-D-aspartate (NMDA) (10-1000 microM) in rat striatum but NMDA did not stimulate [3H]DA release in sheep striatum. These findings suggest that NMDA receptors either are absent from or do not regulate release of preloaded [3H]DA in sheep striatum.     

Localization of rat striatal monoamine oxidase activities towards dopamine,serotonin and kynuramine by gradient centrifugation and nigro-striatal lesions

Subfractionation of the crude synaptosomal-mitochondrial fraction of rat striatum in a continuous sucrose gradient in a zonal rotor led to the following results. The distribution pattern of monoamine oxidase (MAO) activity towards dopamine (DA) was very similar to the pattern of MAO activity towards serotonin (5HT), but differed from the pattern of MAO activity towards kynuramine (KYN). As 5HT is specifically deaminated by MAO-A while KYN is a common MAO substrate, this supports earlier suggestions that in rat striatal preparations DA is deaminated preferentially by MAO-A. The patterns of the MAO activities towards DA and 5HT were clearly dissimilar, despite considerable overlap, to the patterns of tyrosine hydroxylase (TH) and DOPA decarboxylase (DD) activity, both marking the presence of striatal dopaminergic synaptosomes. The peak activities were separated and all patterns were symmetrical without showing a shoulder. This indicates that rat striatal MAO activity towards DA and 5HT is not specifically or for the greater part localized in dopaminergic terminals. We also investigated the effects of electrolytic and 6-hydroxydopamine lesions of the substantia nigra, both causing extensive degeneration of striatal dopaminergic terminals as appeared from the large decrease of striatal TH and DD activity. However, neither type of lesion induced a reduction of the MAO activity towards any of the substrates used. It is concluded towards DA and 5HT (probably MAO-A activity) present in dopaminergic terminals is very low compared with the total activity of this enzyme in rat striatal tissue.     

Halothane attenuated haloperidol and enhanced clozapine-induced dopamine release in the rat striatum

The effect of halothane anesthesia on changes in the extracellular concentrations of dopamine (DA) and its metabolites (3-methoxytyramine (3-MT), 3,4-dihydroxyphenylacetic acid (DOPAC), and homovanillic acid (HVA)) induced by neuroleptics was studied using in vivo microdialysis techniques. Halothane attenuated haloperidol-induced dopamine release and enhanced clozapine-induced dopamine release in the rat striatum.A microdialysis probe was implanted into the right striatum of male SD rats. Rats were given saline or the same volume of 200 microg kg(-1) haloperidol (D(2) receptor antagonist), 10 mg kg(-1) sulpiride (D(2) and D(3) antagonist), or 10 mg kg(-1) clozapine (D(4) and 5-HT(2) antagonist) intraperitoneally with or without 1-h halothane anesthesia (0.5 or 1.5%). Halothane anesthesia did not change the extracellular concentration of DA, but increased the metabolite concentrations in a dose-dependent manner. The increased DA concentration induced by haloperidol was significantly attenuated by halothane anesthesia, whereas the metabolite concentrations were unaffected. Halothane had no effect on the changes in the concentrations of DA or its metabolites induced by sulpiride. The clozapine-induced increases in DA and its metabolites were enhanced by halothane anesthesia.Our results suggest that halothane anesthesia modifies the DA release modulated by antipsychotic drugs in different ways, depending on the effects of dopaminergic or serotonergic pathways.     

Neuropharmacological analysis of interaction between galanin and glutamate receptors in the rat striatum

Bilateral injections of kainic acid (KA) in doses of 100 ng (but not of 20 ng) into the rat striatum caused behavioral disturbances, which were manifested as an increase in the latency of the movement initiation, a decrease in the indices of the locomotor activity in an “open field” test, an increase in muscle tone, and ptosis appearance. Intrastriatal bilateral administration of galanin (10 or 50 ng) decreased the number of crossing movements and rearings in the open field, without affecting the latency of the first crossing movement and the level of muscle tone, and with no ptosis. Combined administration of galanin (10, 20 or 50 ng) and KA (20 ng) into the striatum led to the dose-dependent emergence of behavioral disturbances, which resembled those caused by injections of 100 ng of KA into the caudate nuclei. Behavioral disturbances associated with intrastriatal injection of KA, galanin, and their combination were partially antagonized by naloxon, ketamine, and atropine. It is concluded that galanin potentiates specific behavioral effects of injected KA by modulation of receptors for endogenous opioids, excitatory amino acids, and acetylcholine.     

Effect of nootropic drugs on the dopamine release and dopamine uptake in structures of the rat striatum

Nootropics increase the overflow of dopamine from rat striatum slices in a concentration dependent manner, but without relation to their clinical effectiveness. The influence of a nootropic drugs and of amphetamine on the stimulus induced dopamine release points to a relationship between nootropic and nooanaleptic activity, on the one hand, and transmitter release, on the other. Dopamine re-uptake is not altered by nootropics like piracetam.     

Altered neurotransmitter synthetic enzyme activity in some extrapyramidal nuclei after lesions of the nigro-striatal dopamine projection

The effect of unilateral 6-hydroxydopamine lesions of the dopaminergic nigrostriatal pathway on glutamic acid decarboxylase (GAD) and choline acetyltransferase (CAT) was examined in various nuclei of the basal ganglia of the rat. GAD was significantly increased in the accumbens, head and tail of the striatum, and globus pallidus on the lesioned compared to the contralateral side. CAT was significantly increased in the head of the striatum, while the activity in the tail was decreased.     

Adenosine receptor-mediated modulation of dopamine release in the nucleus accumbens depends on glutamate neurotransmission and N-methyl-D-aspartate receptor stimulation

Adenosine, by acting on adenosine A(1) and A(2A) receptors, exerts opposite modulatory roles on striatal extracellular levels of glutamate and dopamine, with activation of A(1) inhibiting and activation of A(2A) receptors stimulating glutamate and dopamine release. Adenosine-mediated modulation of striatal dopaminergic neurotransmission could be secondary to changes in glutamate neurotransmission, in view of evidence for a preferential colocalization of A(1) and A(2A) receptors in glutamatergic nerve terminals. By using in vivo microdialysis techniques, local perfusion of NMDA (3, 10 microm), the selective A(2A) receptor agonist 2-p-(2-carboxyethyl)phenethylamino-5'-N-ethylcarboxamidoadenosine (CGS 21680; 3, 10 microm), the selective A(1) receptor antagonist 8-cyclopentyl-1,3-dimethylxanthine (CPT; 300, 1000 microm), or the non-selective A(1)-A(2A) receptor antagonist in vitro caffeine (300, 1000 microm) elicited significant increases in extracellular levels of dopamine in the shell of the nucleus accumbens (NAc). Significant glutamate release was also observed with local perfusion of CGS 21680, CPT and caffeine, but not NMDA. Co-perfusion with the competitive NMDA receptor antagonist dl-2-amino-5-phosphonovaleric acid (APV; 100 microm) counteracted dopamine release induced by NMDA, CGS 21680, CPT and caffeine. Co-perfusion with the selective A(2A) receptor antagonist MSX-3 (1 microm) counteracted dopamine and glutamate release induced by CGS 21680, CPT and caffeine and did not modify dopamine release induced by NMDA. These results indicate that modulation of dopamine release in the shell of the NAc by A(1) and A(2A) receptors is mostly secondary to their opposite modulatory role on glutamatergic neurotransmission and depends on stimulation of NMDA receptors. Furthermore, these results underscore the role of A(1) vs. A(2A) receptor antagonism in the central effects of caffeine.     

Differential regulation of cholinergic and peptidergic development in the rat striatum in culture

The development of substance P, somatostatin, and choline acetyltransferase activity was examined in embryonic rat striatum in vivo and in culture. The study was undertaken to help define mechanisms by which diverse neurotransmitter phenotypes may be regulated within the same structure in the brain. Choline acetyltransferase (CAT) was present in striatum before gestational Day 13.5 (E13.5), and enzyme levels increased continually between E13.5 and birth. By contrast, substance P (SP) and somatostatin (SS) did not develop in vivo until E15, and peptide levels fluctuated between E15 and birth, indicating that striatal peptidergic and cholinergic development were regulated differently. To define mechanisms mediating the differential regulation of striatal peptidergic and cholinergic neurons, neurotransmitter development was examined in embryonic striatum in vitro. Cultured striatal neurons from E13.5 embryos expressed substance P and somatostatin de novo after several days in culture, and peptide levels and CAT activity increased significantly in vitro. Each transmitter phenotype was regulated in vitro by a different constellation of environmental factors, and many factors differentially influenced SP, SS, and CAT development. For example, coculture of striatum with a target tissue, the ventral mesencephalon (substantia nigra), increased CAT activity and SP levels but had no significant effect on levels of SS. Moreover, there were widely differing effects on CAT, SP, and SS development of medium conditioned by exposure to a variety of cell types, indicating that the three transmitter systems were regulated by different soluble factors. Potassium-induced membrane depolarization also exerted different effects on the different transmitter traits, elevating CAT activity but decreasing SP and SS. Finally, insulin was required for the survival of SP-containing neurons, but not for the survival of SS- or CAT-containing neurons, indicating that the survival of different populations of striatal neurons was dependent upon different factors. Our observations suggest that different populations of neurons in the striatum are regulated by different mechanisms, so that alterations in the environment may produce strikingly diverse responses in the development of different phenotypic traits within the same structure.     

Effect of blocking of glutamatergic inputs to the striatum on regulation of extracellular dopamine level in the striatum by theN. accumbens

Investigation on awake rats of the Sprague-Dawley line, involving intrabrain dialysis in combination with radioenzymatic analysis of dopamine level, demonstrated that intrastriatal applications by the dialysis perfusion of diethyl glutamate (0.1 mM), a wide spectrum-action blocker of excitatory amino acid receptors, prevents, whereas applications of D,L-2-amino-5-phosphonovaleric acid or kinurenate, blockers of N-methyl-D-aspartate (NMDA) receptors (in the same concentrations), do not prevent an increase in the dopamine level in the extracellular space of the dorsal striatum, caused by application of haloperidol (1.0 mM) to then. accumbens.The findings lead to the assumption that participation of the glutamatergic inputs to the straitum in the transmission of tonic inhibitory effects of then. accumbens to the striatal dopaminergic system is mediated by non-NMDA type receptors.Neirofiziologiya/Neurophysiology, Vol. 25, No. 4, pp. 302–306, July–August, 1993.     

Cadmium effects on 24 h changes in glutamate,aspartate, glutamine,GABA and taurine content of rat striatum

This work evaluates the possible changes in 24 h variations of striatal aspartate, glutamate, glutamine, gamma-aminobutyric acid (GABA) and taurine content after oral cadmium treatment. Male rats were submitted to cadmium exposure at two doses (25 and 50 mg/L of cadmium chloride (CdCl₂)) in the drinking water for 30 days. Control rats received cadmium-free water. After the treatment, rats were killed at six different time intervals throughout a 24 h cycle. Differential effects of cadmium on 24 h amino acid fluctuations were observed. Metal exposure modified the daily pattern of the amino acids concentration found in control animals, except for GABA and taurine with the lowest dose used. Exposure to 25 mg/L of CdCl₂ decreased mean content of aspartate, as well as GABA concentration. These results suggest that cadmium exposure affects 24 h changes of the studied amino acids concentration in the striatum, and those changes may be related to alterations in striatal function.     

siRNA knock down of glutamate dehydrogenase in astrocytes affects glutamate metabolism leading to extensive accumulation of the neuroactive amino acids glutamate and aspartate

Glutamate is the most abundant excitatory neurotransmitter in the brain and astrocytes are key players in sustaining glutamate homeostasis. Astrocytes take up the predominant part of glutamate after neurotransmission and metabolism of glutamate is necessary for a continuous efficient removal of glutamate from the synaptic area. Glutamate may either be amidated by glutamine synthetase or oxidatively metabolized in the mitochondria, the latter being at least to some extent initiated by oxidative deamination by glutamate dehydrogenase (GDH). To explore the particular importance of GDH for astrocyte metabolism we have knocked down GDH in cultured cortical astrocytes employing small interfering RNA (siRNA) achieving a reduction of the enzyme activity by approximately 44%. The astrocytes were incubated for 2h in medium containing either 1.0mM [(15)NH(4)(+)] or 100μM [(15)N]glutamate. For those exposed to [(15)N]glutamate an additional 100μM was added after 1h. Metabolic mapping was performed from isotope incorporation measured by mass spectrometry into relevant amino acids of cell extracts and media. The contents of the amino acids were measured by HPLC. The (15)N incorporation from [(15)NH(4)(+)] into glutamate, aspartate and alanine was decreased in astrocytes exhibiting reduced GDH activity. However, the reduced GDH activity had no effect on the cellular contents of these amino acids. This supports existing in vivo and in vitro studies that GDH is predominantly working in the direction of oxidative deamination and not reductive amination. In contrast, when exposing the astrocytes to [(15)N]glutamate, the reduced GDH activity led to an increased (15)N incorporation into glutamate, aspartate and alanine and a large increase in the content of glutamate and aspartate. Surprisingly, this accumulation of glutamate and net-synthesis of aspartate were not reflected in any alterations in either the glutamine content or labeling, but a slight increase in mono labeling of glutamine in the medium. We suggest that this extensive net-synthesis of aspartate due to lack of GDH activity is occurring via the concerted action of AAT and the part of TCA cycle operating from α-ketoglutarate to oxaloacetate, i.e. the truncated TCA cycle.