(-)S amisulpride binds with high affinity to cloned dopamine D(3) and D(2) receptors.

Amisulpride is a substituted benzamide antipsychotic with nanomolar affinity and high selectivity for dopamine D(2) and dopamine D(3) receptors. The interaction of racemic (+/-)RS amisulpride and its two enantiomers (+)R and (-)S with dopamine D(2) and dopamine D(3) receptors subtypes were compared with that of haloperidol. Binding studies were performed using either [3H]spiperone or [3H]nemonapride in baculovirus/Spodoptera frugiperda insect (Sf-9) cell system expressing either the human dopamine recombinant D(2)long (hD(2L)) or the rat dopamine recombinant D(3) (rD(3)) receptors. K(i) values at dopamine rD(3) receptors were similar regardless of the radioligand used, whereas at hD(2L) receptors values were higher using [3H]spiperone than [3H]nemonapride. However, the rank order of compound potency against radiolabeled spiperone or nemonapride both at dopamine hD(2L) and at dopamine rD(3) receptors was similar. (-)S amisulpride displaced [3H]spiperone or [3H]nemonapride binding from both dopamine hD(2L) or dopamine rD(3) receptors, being twofold more potent than the racemic form and 38-19-fold more potent than (+)R enantiomer. Both racemic and the (-)S enantiomer exhibited 2-4 ([3H]spiperone)- and 3-4 ([3H]nemonapride)-fold higher affinity than haloperidol for dopamine rD(3) receptor, respectively. The (+)R enantiomer has weaker affinity with respect to haloperidol for both dopamine hD(2L) and dopamine rD(3) receptors. Our results show that (-)S amisulpride is the active enantiomer of amisulpride, showing high affinity for dopamine D(3) and dopamine D(2) receptors.

Quantitative autoradiographic distribution of gamma-hydroxybutyric acid binding sites in human and monkey brain.

gamma-Hydroxybutyric acid (GHB), a naturally occurring metabolite of GABA, is present in micromolar concentrations in various areas of the mammalian brain. Specific GHB binding sites, uptake system, synthetic and metabolizing enzymes have been identified in CNS. The present study shows the anatomical distribution of GHB binding sites in sections of primate (squirrel monkey) and human brain by radioligand quantitative autoradiography. In both species the highest densities of binding sites were found in the hippocampus, high to moderate densities in cortical areas (frontal, temporal, insular, cingulate and entorhinal) and low densities in the striatum; no binding sites were detected in the cerebellum. High density of GHB binding was found in the monkey amygdala. In addition the binding characteristics of [(3)H]GHB to membrane preparations of human brain cortex were examined. Scatchard analysis and saturation curves revealed both a high (K(d1) 92+/-4.4 nM; B(max1) 1027+/-110 fmol/mg protein) and a low-affinity binding site (K(d2) 916+/-42 nM; B(max2) 8770+/-159 fmol/mg protein). The present study is the first report on the autoradiographic distribution of specific GHB binding sites in the primate and human brain: such distribution is in both species in good agreement with the distribution found in the rat brain.

Lanthanides stimulate [3H]tyramine binding in the rat striatum.

Low (up to 100 nM) and high (approximately 100 microM) concentrations of lanthanides and Ca2+-ions, respectively, stimulated [3H]tyramine binding ([3H]TY) to rat striatal membranes, a putative marker for the vesicular transporter of dopamine. On the other hand, lanthanides (approximately 100 microM) inhibited or stimulated TY binding in striatal and extrastriatal (cortex, cerebellum) tissues, respectively. The binding increases by lanthanum (La3+) appeared to depend on endogenous Ca2+, whereas, those induced in EDTA-pretreated membranes were Ca2+-independent. The La3+-induced, apparent increase in the Bmax for [3H]TY binding seemed to reflect a retarded rate of dissociation of the ligand from its targets, rather than a larger availability of functionally-relevant, vesicular transport-related TY sites. This indicates uncertain mechanisms of present La3+ effects.

Dithiocarbamate pesticides affect glutamate transport in brain synaptic vesicles.

Dithiocarbamate compounds are widely used agricultural fungicides that display low acute toxicity in mammals and that may become neurotoxic after prolonged exposure. Mancozeb, among other dithiocarbamates tested, proved to be the most potent (Ki= 0.27 microM) at noncompetitively inhibiting the in vitro ATP-dependent uptake of [3H]glutamate in rat cortical vesicles. Furthermore, mancozeb partially (20%) inhibited the ATP-dependent uptake of [14C]methylamine, used as an index for the vesicular transmembrane proton gradient (DeltapH), and evoked its efflux from organelles previously incubated with the 3H-labeled marker. Meanwhile, the vesicular uptake of 36chloride- anions whose concentrations regulate the transmembrane potential gradient (DeltapsiSV) was not impaired. The dithiocarbamate effects on the vesicular transport of [3H]glutamate thus appeared to involve mainly the DeltapH gradient rather than the potential gradient. Dithiocarbamate metabolites, the potent neurotoxin carbon disulfide included, did not affect the uptake process, thus implying the relevance for inhibition of the persistence, if any, of parent compounds in the brain. The present novel and potent in vitro interferences of selected dithiocarbamate pesticides with the vesicular transport of glutamate, if representative of in vivo alterations, may play some role in the probably complex origin of dithiocarbamate neurotoxicity.

Selected pyrethroid insecticides stimulate glutamate uptake in brain synaptic vesicles.

We aimed to ascertain whether pyrethroid insecticides could influence the vesicular transport of the excitatory amino acid glutamate. The incubation of rat cortical synaptic vesicles with resmethrin and permethrin, consistently stimulated both ATP-dependent and -independent uptake of [3H]glutamate, while not evoking depletion of its vesicular content. Both processes were counteracted by valinomycin, a dissipator of the transmembrane potential gradient (deltapsi(sv)). Meanwhile, the vesicular influx of 36Cl- anions was impaired by pyrethroid concentrations which did not affect the ATP-dependent uptake of [14C]methylamine, as a marker for the proton gradient (deltapH). Thus, the stimulation of glutamate transport appeared to involve mainly the deltapsi(sv). A self-attenuating effect of selected pyrethroids on putatively enhanced excitatory transmission in severe intoxication is suggested.

Differential mechanisms in the effects of disulfiram and diethyldithiocarbamate intoxication on striatal release and vesicular transport of glutamate.

Intoxication with the alcohol-aversive drug disulfiram (Antabuse) and related dithiocarbamates may provoke neuropathies and, in some cases, damage the basal ganglia. Rats received a single administration of disulfiram (7 and 500 mg kg-1 i.p.) and equimolar doses (4 and 290 mg kg-1 i.p.) of its metabolite diethyldithiocarbamate (DDC), roughly corresponding to the daily maximum dose in alcohol abusers or to an estimated nonlethal overdose, respectively. The striatal, extracellular levels of glutamate in freely moving rats previously implanted with a microdialysis probe increased after low and intoxicating doses of disulfiram (126 +/- 3% and 154 +/- 10% of basal values, respectively) and DDC as well (135 +/- 10% and 215 +/- 14%, respectively), a partially Ca++-dependent effect. The prolonged (>7 hr) disulfiram-induced increase in glutamate observed in vivo may reflect the in vitro disulfiram-evoked release of glutamate from striato-cortical synaptic vesicles, where the drug nonspecifically inhibited (Ki approximately 4 microM) the uptake function and abolished the transmembrane proton gradient (DeltapH). In contrast, DDC did not seem to affect DeltapH. The prompt DDC-provoked increase in extracellular levels of glutamate was prevented by 7-nitroindazole, an in vivo specific inhibitor of neuronal nitric oxide synthase, which suggests that the thiol metabolite also acts via the nitric oxide synthesis. At variance, the short-acting 7-nitroindazole did not prevent the sustained in vivo effects of disulfiram and of DDC putatively formed with time. These findings provide new evidence for differential mechanisms underlying disulfiram- and DDC-induced increases in striatal glutamate release. Present glutamatergic changes, although not appearing dramatic enough to represent the only cause for neuronal damage from disulfiram overdose, might contribute to the drug neurotoxicity.