Reversible decrease in dopaminergic 3H-agonist binding after 6-hydroxydopamine and irreversible decrease after kainic acid

Six days after the unilateral intrastriatal injection of 30 ug 6-hydroxydopamine (6-OHDA) the number of stereospecific 3H-dopamine and 3H-apomorphine binding sites (Bmax) was reduced by 50-60% in the caudate nucleus ipsilateral to the lesion. The dopamine content of the lesioned caudate nucleus was also reduced to 2% of the contralateral side or of sham-operated controls. The preincubation of depleted homogenates with added dopamine reversed the effects of 6-OHDA on the Bmax of 3H-agonists. A similar pattern of depletion, decrease in binding and in vitro reversal by dopamine was observed after a single injection of reserpine (4.0 mg/kg, im.). The intrastriatal injection of kainic acid also lowered the Bmax of 3H-agonists by 65% without altering dopamine content. Preincubation of homogenates of kainic acid-lesioned caudate nuclei with 355 nM (endogenous) dopamine did not reverse the decrease in binding. We conclude that treatments which deplete endogenous dopamine, including the lesion of nigrostriatal terminals, induce a reversible change in the parameters of 3H-agonist binding whereas the destruction of intrinsic caudate neurons with kainic acid results in an irreversible loss of receptors.     

3H-dopamine binding to rat striatal D-2 and D-3 sites: Enhancement by magnesium and inhibition by guanine nucleotides and sodium

Previous studies have demonstrated high affinity ³H-dopamine binding sites on mammalian striatal membranes. These putative dopamine receptors of unknown physiological significance have been termed D-3 sites. Such studies have failed, however, to demonstrate high affinity ³H-dopamine binding to D-2 sites, which can be labeled by ³H-butyrophenones, and which represent the putative dopamine receptors most stronly implicated in the behavioral correlates of dopaminergic CNS activity. We now report that preincubation of membrane homogenates with Mg⁺⁺ and inclusion of Mg⁺⁺ (1–10mM) or other divalent metal cations during binding allows high affinity D-2 specific ³H-dopamine binding in rat striatal membranes, and that these ions also increase the Bmax of D-3 specific ³H-dopamine binding. GTP, GDP, and GppNHp can completely abolish all D-2 specific ³H-dopamine binding, while only a magnesium-dependent portion of D-3 sites appears to be GTP sensitive. These data are consistent with the hypothesis that the striatal D-2 receptor exists in two agonist affinity states whose interconversion is effected by guanine nucleotides and divalent metal cations. The GTP sensitive/magnesium dependent nature of ³H-dopamine binding to so-called D-3 sites suggests that some such sites may in fact represent a high agonist-affinity state of the D-1 adenylate cyclase stimulating dopamine receptor also found in this tissue.     

Increased acoplasmic transport of H3-dopamine in nigro-neostriatal neurons after reserpine

Recent evidence suggests that dopamine can undergo axoplasmic transport in nigro-neostriatal neurons by binding to amine storage granules. In the present experiments it was demonstrated that reserpine pretreatment (10 mg/kg) 24 hours before stereotaxic injections of ³H-DOPA or ³H-dopamine into the substantia nigra increases the amount of ³H-dopamine transported to the neostriatum by about 300 percent. The activity recovered from the substantia nigra was significantly reduced by reserpine pretreatment however. Stereotaxic injection of ¹⁴C-leucine into the substantia nigra indicated that neither fast nor slow axoplasmic transport of protein was influenced by reserpine pretreatment in these same neurons. The increased transport of dopamine appears therefore to be due to a relatively selective action of reserpine. The results suggest that reserpine either (i) increases the binding of dopamine to newly synthesized amine storage granules, (ii) increases the number of newly synthesized amine storage granules, or (iii) accelerates the rate of transport of amine storage granules. In addition, the results support the view that reserpine can increase the membrane permeability of adrenergic neurons to the outward movement of catecholamines.     

[3H]Dihydrotetrabenazine, a New In Vitro Monoaminergic Probe for Human Brain

The monoamine transporter of dopamine (DA), noradrenaline, and 5-hydroxytryptamine synaptic vesicles was assayed in rat and human brain homogenates by in vitro binding of [3H]dihydrotetrabenazine. [3H]Reserpine, a second ligand of the vesicular monoamine transporter, could not be used. [3H]Dihydrotetrabenazine binding in rat brain was stable after 72 h at 22 degrees C postmortem. In major human brain regions, [3H]dihydrotetrabenazine binding was specific and saturable (KD, 2.7 nM). Displacement constants by substrates or inhibitors of vesicular monoamine uptake, and regional distribution in human brain were similar to those found in rodents. The highest densities of binding sites were observed in caudate nucleus, putamen, and accumbens nucleus. In caudate nucleus and in putamen from normal human subjects, [3H]dihydrotetrabenazine binding and homovanillic acid concentration were significantly or nearly significantly correlated. A weaker correlation was found between [3H]dihydrotetrabenazine binding and DA, in association with a higher variability of DA. [3H]Dihydrotetrabenazine binding in caudate nucleus and in putamen decreased significantly with age, unlike DA and homovanillic acid concentrations. The results establish [3H]dihydrotetrabenazine as a presynaptic monoaminergic ligand of interest for studies on postmortem human brain.     

Differential effect of psychotropic drugs on dihydroxyphenylacetic acid (DOPAC) in the rat substantia nigra and caudate nucleus

The effect of different psychotropic drugs on DOPAC levels in the caudate nucleus and in the substantia nigra was compared. While pargyline, haloperidol and damphetamine caused parallel changes in both areas, apomorphine and reserpine influenced DOPAC levels in the caudate nucleus and in the substantia nigra differently. In both areas pargyline caused a rapid fall in DOPAC concentrations, while haloperidol caused a marked increase. D-amphetamine was slightly more potent in decreasing DOPAC level in the substantia nigra than in the caudate nucleus. On the other hand, apomorphine was very potent in decreasing DOPAC level in the caudate nucleus but failed to influence it in the substantia nigra. Finally, reserpine, which depleted dopamine stores in both areas, increased DOPAC in the caudate nucleus but decreased it in the substantia nigra.     

Dopaminergic 3H-agonist receptors in rat brain. New evidence on localization and pharmacology

Recent methodological advances have allowed the reliable assay of specific dopaminergic 3H-agonist binding sites in rat striatum. Successful assay depends on preincubation of tissue homogenates at 37 degrees C; this results in a guanyl nucleotide-sensitive and dopamine (DA)-dependent increase in the density (Bmax) of 3H-agonist binding. Lesions of DA terminals or drugs which deplete DA levels prevent the preincubation-induced increase in binding, and this effect is completely reversible by preincubation with added DA. In contrast, kainic acid lesions irreversibly reduce 3H-agonist binding. It is concluded that the evidence supporting the existence of presynaptic "D-3" sites is artefactual and that 3H-DA binding sites are more likely related to post-synaptic receptors. 3H-DA binding involves two sites, one of which has pharmacologic properties similar to D-1 receptors, whereas the other resembles D-2 receptors. The affinity of 15 antipsychotic drugs for 3H-haloperidol binding sites was highly correlated (R = 0.94) with their inhibitory potency at a subset of 3H-DA binding sites. However, the inhibition of 3H-DA binding by antipsychotic drugs was noncompetitive. These findings can be explained by an allosteric model, whereby antagonists bind to a site different from but allosterically linked to a high-affinity 3H-DA binding site.     

[3H]GBR-12935 Binding to the Dopamine Transporter Is Decreased in the Caudate Nucleus in Parkinson''s Disease

The specific binding of [3H]GBR-12935 to membranes prepared from human caudate nucleus is saturable (Bmax 1.36 +/- 0.18 pmol/mg protein), sodium dependent and of high affinity (KD 2.34 +/- 0.18 nM). Freezing of tissue from rat brain, or refrigeration followed by freezing, results in a small but significant (less than or equal to 20%) decrease in specific [3H]GBR-12935 binding when compared to the binding observed in fresh (nonfrozen) tissue, and this decrease may account, in part, for the differences in specific binding between rat and human brain membranes. Despite small differences in binding site density between fresh and frozen tissue there is a good correlation (r = 0.98; p less than 0.01) between the potencies of a series of drugs in displacing specific [3H]GBR-12935 binding to human caudate membranes and rat striatum as well as in inhibiting dopamine uptake in rat striatal synaptosomes (r = 0.96; p less than 0.01). The specific binding of [3H]GBR-12935 to membranes prepared from the caudate nuclei of patients with Parkinson's disease is decreased compared to membranes prepared from age- and sex-matched controls. These data suggest that [3H]GBR-12935 binds in a sodium-dependent fashion to the dopamine transport complex in human brain and that specific binding is decreased by a pathological degeneration of dopaminergic neurons to the caudate nucleus.     

Protein phosphorylation in rat caudate homogenate: stimulatory effects of dopamine and enhancement of dopamine response following 6-hydroxydopamine treatment.

Dopamine (3-hydroxytyramine) stimulates the incorporation of 32P into proteins endogenous to a homogenate of rat caudate nucleus when 10 microM [gamma-32P]-ATP is used as a substrate following preincubation with 400 microM ATP. The increase in 32P incorporation has pharmacological characteristics similar to caudate tissue. Chronic depletion of striatal dopamine in vivo by stereotaxic injection of 6-hydroxydopamine in the nigrostriatal pathway results in a significant enhancement of the dopamine stimulation of 32 p incorporation in vitro. Cyclic AMP-stimulated phosphorylation of caudate proteins remains unchanged following 6-hydroxydopamine treatment.     

Vasopressin affects adenylate cyclase activity in rat brain: a possible neuromodulator

The effect of vasopressin on adenylate cyclase activity was measured in the homogenates of selected rat brain regions. Adenylate cyclase activity in homogenate of the caudate nucleus did not change significantly with various concentrations of vasopressin. Furthermore, vasopressin did not reliably alter adenylate cyclase activity in various brain regions. Vasopressin in low concentrations significantly enhanced the activation of caudate adenylate cyclase activity by dopamine. This effect of vasopressin was dose dependent. Maximal enhancement by vasopressin occurred at 100 microM vasopressin. These results indicate that vasopressin may not have a direct effect on brain adenylate cyclase activity but appears to modulate the action of dopamine on brain adenylate cyclase.     

Heterogeneity of D2 dopamine receptors in different brain regions.

The binding of [3H]spiperone has been examined in membranes derived from different regions of bovine brain. In caudate nucleus, nucleus accumbens, olfactory tubercle and putamen binding is to D2 dopamine and 5HT2 serotonin receptors, whereas in cingulate cortex only serotonin 5HT2 receptor binding can be detected. D2 dopamine receptors were examined in detail in caudate nucleus, olfactory tubercle and putamen using [3H]spiperone binding in the presence of 0.3 microM-mianserin (to block 5HT2 serotonin receptors). No evidence for heterogeneity among D2 dopamine receptors either between brain regions or within a brain region was found from the displacements of [3H]spiperone binding by a range of antagonists, including dibenzazepines and substituted benzamides. Regulation of agonist binding by guanine nucleotides did, however, differ between regions. In caudate nucleus a population of agonist binding sites appeared resistant to guanine nucleotide regulation, whereas this was not the case in olfactory tubercle and putamen.     

Regional differences in the high affinity uptake or 3H-dopamine and 3H-norepinephrine in synaptosome rich homogenates of cat brain.

The uptake of ³H-dopamine and ³H-norepinephrine into synaptosome rich fractions of cat brain was studied. Following kinetic analysis of the high affinity uptake mechanism, the five areas investigated could be divided into two distinct groups: (1) the dorsal caudate nucleus and the septal region which showed a greater affinity for dopamine than for norepinephrine and (2) the hypothalamus, prefrontal and cerebellar cortex which showed equal affinities for both dopamine and norepinephrine. The distribution of monoamine oxidase activity did not correspond with the affinities for norepinephrine or dopamine but choline acetyltransferase activity was higher in areas which showed a preference for dopamine. A high affinity uptake system for 5-hydroxytryptamine was also observed in the septal region.     

Chemical lesion and drug induced supersentivity and subsensitivity of caudate dopamine receptors

In order to elucidate the mechanism of denervation supersensitivity, the effects of 6-hydroxydopamine lesion, placed in the substantia nigra, were examined on rat brain caudate adenylate cyclase and ³H-haloperidol binding to membrane dopamine receptors. In addition, the effects of chronic administration of L-DOPA, bromocriptine and piribedil were also investigated on ³H-haloperidol binding and dopamine, K⁺ isoproterenol (IPNE) and 2-Cl-adenosine stimulated formation of cyclic AMP in caudate slices. 6-Hydroxydopamine lesions resulted in significantly greater stimulation of adenylate cyclase by dopamine at various concentrations tested. The haloperidol binding sites were increased by 28% on lesioned side caudate without changes in dissociation constants (K_D). Three weeks after treatment with L-DOPA, bromocriptine or piribedil, the ³H-haloperidol binding sites were decreased by 40% with no change in K_D. The stimulatory effect of dopamine on cyclic AMP formation was also abolished, although there was no change in IPNE, K⁺, or 2-Cl-adenosine stimulated cyclic AMP formation in caudate slices, suggesting a specific effect of dopamine agonists on dopamine receptors. The results of these studies suggest a close relationship between at least some populations of dopamine receptors and adenylate cyclase in the caudate nucleus.     

Altered Dopamine Receptor and Dopamine Transporter Binding and Tyrosine Hydroxylase mRNA Expression Following Perinatal NMDA Receptor Blockade

This study examined how perinatal phencyclidine (PCP) treatment would affect dopamine D2 receptor and dopamine transporter (DAT) binding at different stages after treatment cessation. Female rat pups received injections of PCP (10 mg/kg, s.c.) or saline on postnatal day (PN)7, 9 and 11. D2 receptor and transporter binding was examined at four time-points (PN12, 18, 32 and 96) following injections. PCP treatment altered D2 receptor binding throughout development, with a final end-point of 22-33% decreased binding at adulthood in the nucleus accumbens and caudate putamen (P < 0.01), accompanied by a small but significant increase in DAT binding in the caudate putamen. Tyrosine hydroxylase mRNA expression was also significantly increased by 25% (P < 0.05) in the ventral tegmental area of adult rats, suggesting that this model may produce a long-term increase in dopamine output. This study demonstrates that early insult to the brain from NMDA receptor hypofunction alters the dopaminergic system at different stages of development.     

Antagonism of presynaptic dopamine receptors by phenothiazine drug metabolites

Electrically evoked release of dopamine from the caudate nucleus is reduced by the dopamine receptor agonists, apomorphine and bromocriptine, and facilitated by neuroleptic drugs, which act as dopamine autoreceptor antagonists. The potencies of chlorpromazine, fluphenazine, levomepromazine and their hydroxy-metabolites in modulating electrically evoked release of dopamine were examined by superfusion of rabbit caudate nucleus slices pre-incubated with 3H-dopamine. O-Desmethyl levomepromazine, 3-hydroxy- and 7-hydroxy metabolites of chlorpromazine and levomepromazine facilitated electrically evoked release of 3H-dopamine, having potencies similar to that of the parent compounds. 7-Hydroxy fluphenazine was less active than fluphenazine in this system. These results indicate that phenolic metabolites of chlorpromazine and levomepromazine, but not of fluphenazine, may contribute to effects of the drugs mediated by presynaptic dopamine receptors.     

Ascorbic acid enables reversible dopamine receptor 3H-agonist binding

The effects of ascorbic acid on dopaminergic ³H-agonist receptor binding were studied in membrane homogenates of bovine anterior pituitary and caudate, and rat striatum. In all tissues virtually no stereospecific binding (defined using luM (+)butaclamol) of the ³H-agonists N-propylnorapomorphine (NPA), apomorphine, or dopamine could be demonstrated in the absence of ascorbic acid. Although levels of total ³H-agonist binding were three to five times greater in the absence than in the presence of 0.1% ascorbic acid, the increased binding was entirely non-stereospecific. Greater amounts of dopamine-inhibitable ³H-NPA binding could be demonstrated in the absence of 0.1% ascorbic acid, but this measure of “specific binding” was demonstrated not to represent dopamine receptor binding since several other catecholamines and catechol were equipotent with dopamine and more potent than the dopamine agonist (±)amino-6,7-dihydroxy-1,2,3,4-tetrahydronapthalene (ADTN) in inhibiting this binding. High levels of dopamine-displaceable ³H-agonist binding were detected in fresh and boiled homogenates of cerebellum, an area of brain which receives no dopaminergic innervation, further demonstrating the non-specific nature of ³H-agonist binding in the absence of ascorbic acid. These studies emphasize that under typical assay conditions ascorbic acid is required in order to demonstrate reversible and specific ³H-agonist binding to dopamine receptors.     

The bicuculline-like properties of dopamine sulfate in rat brain

To determine whether the convulsive action of intraventricularly injected dopamine sulfate, a dopamine metabolite present in rat brain and human cerebrospinal fluid, could be due to its interaction with GABAergic pathway, we compared the convulsive effect of dopamine sulfate with that of bicuculline in the conscious rat and determined the interaction of dopamine sulfate with [3H] GABA binding and uptake in rat brain tissues. The results showed that the convulsive effects of dopamine sulfate and of bicuculline could be abolished by GABA agonists diazepam and muscimol, but not by DA antagonists haloperidol and metoclopramide. In addition they were additive. Both dopamine 3-O-sulfate and dopamine-4-O-sulfate, like bicuculline, could displace sodium-independent [3H] GABA binding to rat brain synaptic membranes (IC50 = 400 microM) but had no action on GABA uptake. DA sulfate had no effect on [3H] strychnine binding to rat brain homogenates. This evidence together with the structural resemblance between dopamine sulfate and GABA suggested that the convulsive activity of dopamine sulfate may result from its interaction with central GABA receptors.     

Distribution of a catecholamine-binding mechanism in rat brain

Summary The existence of characteristic regional differences in the binding capacity of tissue for catecholamines was demonstrated by incubating sections of rat brain with tritiated norepinephrine or epinephrine or dopamine, and by radioautography. Microscopically, catecholamine binding occurred diffusely in the neuropil, or in pericellular aggregates upon nerve cells, in a pattern highly suggestive of synaptic buttons. A neuroanatomical account of the regional distribution patterns of norepinephrine binding in rat brain showed similarity to the known regional distribution of norepinephrine. However, there were quantitative and qualitative differences between the distribution of the binding mechanism and that of norepinephrine. Minor differences were found between the binding of norepinephrine and epinephrine; little binding occurred for dopamine. The binding mechanism was not facilitated by ATP, and was resistant to reserpine.This investigation was supported by Public Health Grant NB 6239 from the National Institute of Neurological Diseases and Blindness.     

Effects of reserpine on dopamine metabolite in the nucleus accumbens and locomotor activity in freely moving rats

The effect of reserpine (2 mg/kg i.p.) on both locomotor activity and the turnover of dopamine metabolite in the rat nucleus accumbens was estimated by using an activity monitor (Animex) and by in vivo brain microdialysis. Three to five hours after reserpine administration locomotor activity was reduced and there was a concomitant increase in the level of the dopamine metabolite, homovamillic acid. These findings suggest that depletion of dopamine from the nucleus accumbens may result in decreased locomotor activity. The data support the notion that dopamine in this tissue contributes to the control of locomotion.     

Dopamine receptor binding: differentiation of agonist and antagonist states with 3H-dopamine and 3H-haloperidol.

³H-Dopamine and ³H-haloperidol bind with high affinity and selectivity to synaptic dopamine receptors in membrane preparations of the calf caudate. Binding of both ligands shows marked regional variations with greatest density in caudate, putamen, globus pallidus, nucleus accumbens and olfactory tubercle, areas rich in dopamine nerve terminals. The rank-order of phenothiazines and related agents as well as catecholamines in displacing both dopamine and haloperidol binding closely parallels their pharmacological potencies and affinities for the dopamine-sensitive adenylate cyclase. Dopamine's affinity for specific ³H-dopamine binding sites is 100 times its apparent affinity for the dopamine sensitive adenylate cyclase. Agonists have about 50 times more affinity for dopamine than haloperidol sites, whereas antagonists display about 100 times greater affinity for haloperidol than dopamine sites.     

Pharmacologic properties of a phosphate ester of dopamine

The 3 or 4 phosphate ester of dopamine (PD) was hydrolyzed by homogenates of rat tissues to give inorganic phosphate (Pi) and dopamine. The rate of hydrolysis of PD by kidney homogenates was increased by exogenous MgCl2 but not CaCl2 or KCl. The activity of brain, heart or liver homogenates was insensitive to the added salts. Several lines of evidence indicate that alkaline phosphatase activity contributes to the high rate of PD hydrolysis by the kidney but not brain homogenate. The intravenous infusion of PD at 12 mumole/kg in one hr to anesthetized rats increased the dopamine content of the plasma, kidney and heart without altering brain or liver dopamine. The results suggest that PD may be more effective than dopamine for increasing dopamine levels of the kidney. In addition, the hydrolysis of PD by brain homogenates, which is independent of alkaline phosphatase activity, suggests that specific enzymes exist for the metabolism of PD.