Two types of dopamine receptors in behavioral regulation.

Evidence has been presented indicating the existence of distinct dopamine receptors in the brain. The experimental proof that two types of dopamine receptors--the excitation-mediating (DAe) receptors and the inhibition-mediating (DAi) receptors--exist in the snail brain is put forward. The functioning of DAi and DAe receptors in locomotor activity and stereotyped behavior is discussed along with implications of dopaminergic involvement in a gratification system.     

Prolactin receptors in the brain during pregnancy and lactation: implications for behavior

Numerous studies have documented prolactin regulation of a variety of brain functions, including maternal behavior, regulation of oxytocin neurons, regulation of feeding and appetite, suppression of ACTH secretion in response to stress, and suppression of fertility. We have observed marked changes in expression of prolactin receptors in specific hypothalamic nuclei during pregnancy and lactation. This has important implications for neuronal functions regulated by prolactin. In light of the high circulating levels of prolactin during pregnancy and lactation and the increased expression of prolactin receptors in the hypothalamus, many of these functions may be enhanced or exaggerated in the maternal brain. The adaptations of the maternal brain allow the female to exhibit the appropriate behavior to feed and nurture her offspring, to adjust to the nutritional and metabolic demands of milk production, and to maintain appropriate hormone secretion to allow milk synthesis, secretion, and ejection. This review aims to summarize the evidence that prolactin plays a key role in regulating hypothalamic function during lactation and to discuss the hypothesis that the overall role of prolactin is to organize and coordinate this wide range of behavioral and neuroendocrine adaptations during pregnancy and lactation.     

Down regulation of striatal dopamine receptors in experimental hepatic encephalopathy

Dopamine receptors were studied in striatal synaptosomes prepared from rat brain with hepatic encephalopathy induced by galactosamine-HCl and documented by visual evoked potential recordings. In order to further characterize the model, plasma amino acid levels and striatal catecholamines and octopamine levels were assayed. In agreement with previous reports in animal and in man, plasma amino acids were increased both in mild and severe stage of this pathology. Striatal levels of norepinephrine and dopamine fell during the development of coma while octopamine rose. Dopamine binding studies showed a decrease in the affinity during the mild stage and a reduction of receptor numbers in the severe stage of encephalopathy. The overall results, in the light of previous reports on GABA receptor studies, seem to indicate the presence in the development of encephalopathy of an imbalance between the dopaminergic and the GABAergic system leading to a prevalence of GABAergic inhibitory system.     

Corticosterone regulation of brain and lymphoid corticosteroid receptors

Circulating lymphocytes are often used as a model for brain corticosteroid receptor regulation in clinical disease states, although it is not known if lymphoid receptors are regulated in a similar manner as brain receptors. In the present study the regulation of brain (hippocampus, frontal cortex, hypothalamus and striatum), lymphoid (circulating lymphocytes, spleen and thymus) and pituitary glucocorticoid receptors in response to alterations in circulating corticosterone levels was examined. Seven days following adrenalectomy, type II corticosteroid receptors (i.e. glucocorticoid receptors) were significantly increased in the hippocampus, frontal cortex and hypothalamus, but not in any other tissues. Administration of corticosterone (10 mg/kg) for 7 days significantly decreased type II as well as type I (i.e. mineralocorticoid receptors) receptors in the hippocampus. Type II receptors in the frontal cortex, circulating lymphocytes and spleen were also significantly decreased by chronic corticosterone treatment. Immobilization stress (2 h a day for 5 days) failed to alter receptor density in any of the tissues. These results demonstrate that homologous regulation of corticosteroid receptors by corticosterone does not invariably occur in all tissues and emphasize the complex degree of regulation of these receptors. However, the simultaneous downregulation of both hippocampal and lymphocyte glucocorticoid receptors by corticosterone provides support for the hypothesis that circulating lymphocytes do reflect some aspects of brain glucocorticoid receptor regulation.     

The neurobiology of dopamine receptors: evolution from the dual concept to heterodimer complexes

Context: G protein-coupled receptors (GPCRs) have been classically thought to work as monomeric entities. The current view of their organization, however, assumes that they are part of highly organized molecular complexes, where different receptors and interacting proteins are clustered. These heteromers have peculiar pharmacological, signaling, and trafficking properties. GPCR heteromerization, raising different combinatorial possibilities, thus underlies an unexpected level of diversity within this receptor family.

Methods: In this paper, we summarize recent data, reported by different research groups, suggesting that the dopamine (DA) D1 receptor forms heteromers with receptors of the same family and with structurally and functionally divergent receptors.

Results and discussion: DA D1 and D3 receptors and glutamate NMDA receptors regulate rewarding mechanisms and motivated behavior, modulate emotional and cognitive processes and regulate locomotor activity by extensive cross-talk mechanisms. Co-localization of D1 and D3 receptors and D1 and NMDA receptors in specific neuronal populations in the striatum and nucleus accumbens, moreover, suggested that their cross-talk may involve direct interactions. By using different experimental approaches various groups have, in fact, demonstrated the existence of D1-NMDA and D1-D3 heteromers, in both transfected cell systems and in the straitum, with peculiar pharmacological, signaling, and functional properties. The putative role of the D1-D3 and D1-NMDA heteromers in the physiological regulation of striatal function and in the development of motor dysfunctions will be discussed.     

Multiple benzodiazepine receptors and their regulation by gamma-aminobutyric acid

The interaction of propyl β-carboline-3-carboxylate (PCC) with benzodiazepine receptors in the cerebral cortex of the rat was investigated by direct measurements of [³H]PCC binding and by competitive inhibition of [³H]flunitrazepam (FLU) binding. Initial experiments showed that [³H]PCC binding exhibited characteristics of saturability, stereospecificity and a pharmacological specificity remarkably similar to that of [³H]FLU binding. Analysis of [³H]PCC binding isotherms and PCC/[³H]PCC competition curves revealed the presence of a small population of super high affinity PCC binding sites (K_SH = 30–100 pM) which represents approximately 3–6% of the total sites. When measured by competitive inhibition of [³H]FLU binding, receptor occupancy by PCC was generally consistent with that determined by direct measurements of [³H]PCC binding. Analysis of the PCC/[³H]FLU competition curve revealed the presence of two major populations of high and low affinity PCC binding sites with dissociation constants of 0.54 and 10 nM and relative abundances of 52 and 45%, respectively. Collectively, the results of the [³H]PCC binding isotherm, PCC/[³H]PCC competition curve and PCC/[³H]FLU competition curve are internally consistent when rationalized in terms of three populations of benzodiazepine receptors - super high, high, and low affinity - each having different affinities for PCC and equal affinity for FLU. The effects of γ-aminobutyric acid (GABA) on PCC and FLU binding were investigated, and it was observed that GABA enhanced the binding of FLU to the various receptor subtypes whereas no significant effect of GABA on the binding of PCC was detected.     

Swimming behavior regulation by GABAB receptors in Paramecium

In Paramecium, internal Ca(2+) concentration increase coupled to membrane depolarization induces a reversal in the direction of ciliary beating and, consequently, a reversal in swimming direction. The ciliary reversal (CR) duration is correlated to Ca(2+) influx, and the addition of drugs that block the Ca(2+) current leads to a reduction in the backward swimming duration. In this study we have examined the possible function of GABA(B) receptors in P. primaurelia swimming control. The presence of GABA(B) immunoanalogue in Paramecium was evidenced using SDS-PAGE, Western blotting, and confocal laser scanning microscopy. By applying the specific GABA(B) receptor agonist baclofen, a dose-dependent inhibition of the membrane depolarization-induced CR duration was observed. This inhibition was antagonized by phaclofen, persisted when K(+) channel blockers were applied, and disappeared after treatment with nifedipine and verapamil. Moreover, the action of baclofen on depolarization-induced CR was suppressed by treatment with pertussis toxin. Therefore, these experiments suggest that baclofen modulates CR by a G protein (G(0) or G(1)) mediated inhibition of dihydropyridine-sensible calcium channels. Finally, synthesis and release of GABA in the environment by Paramecium have been demonstrated by HPLC. Possible correlations between GABA(B) receptor activation and the regulation of intracellular Ca(2+) levels are discussed.     

Multiple neurotransmitter receptors in the brain: amines, adenosine, and cholecystokinin

Radioligand binding studies of neurotransmitter receptors have provided discrimination at the molecular level, permitting the differentiation of multiple receptor subtypes for several biogenic amines. Using this paradigm we have labeled two distinct receptors each for cholecystokinin (CCK) and for adenosine. Adenosine receptors were labeled in brain with [3H]N6-cyclohexyladenosine (3H-CHA) and [3H]1,3-diethyl-8-phenylxanthine (3H-DP). The adenosine receptor labeled by 3H-CHA appears to be an A1 site, associated with reduction of adenylate cyclase activity, while 3H-DP sites resemble A2 receptors linked to adenylate cyclase enhancement. Cholecystokinin-33 labeled by the Bolton-Hunter procedure with 125I(125I-BH-CCK) labels different receptors in brain and pancreas. The pancreatic receptor does not react with CCK derivatives of fewer than eight amino acids, while the brain receptor does recognize pentagastrin, the carboxyl-terminal five amino acids of CCK. The "brain type" CCK receptor may normally interact with CCK-4, the carboxyl-terminal tetrapeptide of CCK, recently identified as a unique neuropeptide highly concentrated in the brain. CCK-8, the other major molecular form of CCK, may be the endogenous ligand for the "pancreatic type" receptor.     

Modulation of dopamine receptors by thyrotropin-releasing hormone in the rat brain

Nanomolar concentration of thyrotropin-releasing hormone (TRH) in vitro caused a significant reduction of [3H]apomorphine binding sites (70% of the control) in the rat striatum and the limbic forebrain. [3H]Spiperone binding was not affected by TRH. On the other hand, dopamine and apomorphine displaced [3H]TRH binding partially, suggesting the presence of a TRH receptor subpopulation that has a high affinity for dopamine agonist. Most of the neuroleptics displaced [3H]TRH binding dose-dependently in the micromolar range. (-)-Sulpiride had no affinity to TRH receptors. These findings suggest that one of the important roles of TRH as a neuromodulator is to modulate receptors for classical neurotransmitters, and this receptor-receptor interaction may be of importance in explaining the well known stimulating effects of TRH on the dopaminergic system.     

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.     

Ratio of brain synaptosome Na, K-ATPase to dopamine receptors

Activating (0.3-3 microM) or inhibitory (0.03-0.3 mM) effects of dopamine (DA) in the absence of Ca2+, and its inhibitory effect in the presence of Ca2+ on Na,K-ATPase activity of synaptosomes from the caudate nucleus of the rat brain were confirmed. Na,K-ATPase was shown to be inhibited by 6 neuroleptics, with the degree of inhibition stronger in the presence of Ca2+. It was found that: 1) the biphasic or monophasic nature of DA action on Na,K-ATPase activity was preserved in the presence of neuroleptics, 2) DA enhances the inhibitory effects of neuroleptics on the enzyme, 3) the inhibitory effects of DA on Na,K-ATPase are enhanced by Ca2+ ions. The mechanisms of the modifying action of DA on synaptosomal Na,K-ATPase are discussed.     

Characterization of brain D2 dopamine receptors

In order to characterize and partially purify solubilized dopamine receptors, canine brain striatum microsomes were solubilized with 1% digitonin, and enriched by either gel permeation chromatography, preparative vertical column isoelectric focusing, or sucrose gradient ultracentrifugation. Chromatography on Sephacryl S-300 in buffer (contaning 0.05% Triton X-100) yielded a Stokes radius of 5.8 nm. Isoelectric focusing of the solubilized, radiolabelled receptor produced peaks of [³H]spiperone radioactivity corresponding to isoelectric values of 5.0 and 7.8, of which the former has been shown elsewhere to be the intact D₂ dopamine receptor. Sucrose density gradient ultracentrifugation, again in buffer containing 0.05% Triton X-100, indicated a hydrodynamic mol. wt of 136,000 Daltons, which corresponds closely to the value of 123,000 Daltons estimated using radiation inactivation. Such molecular characterization will aid in the distinction of dopamine receptor subtypes.     

The role of dopamine and opioid systems in the regulation of maternal behavior

This review describes in detail the different components and neuroanatomical basis of maternal behavior and also methodological approaches to investigation of parental reactions. The contributions of some endocrinal and neuromediator brain systems (in the first place, opioid and dopaminergic) to the regulation of maternal behavior are reported. The influences of ligands of opioid and dopamine receptors on the expressions of paternal reactions are analyzed especially. In concluding part the reasons of maternal depression and possibilities of this malfunction pharmacological correstion are discussed.     

MsrA knockout mouse exhibits abnormal behavior and brain dopamine levels

Oxidative stress can cause methionine oxidation that has been implicated in various proteins malfunctions, if not adequately reduced by the methionine sulfoxide reductase system. Recent evidence has found oxidized methionine residues in neurodegenerative conditions. Previously, we have described elevated levels of brain pathologies and an abnormal walking pattern in the methionine sulfoxide reductase A knockout (MsrA(-/-)) mouse. Here we show that MsrA(-/-) mice have compromised complex task learning capabilities relative to wild-type mice. Likewise, MsrA(-/-) mice exhibit lower locomotor activity and altered gait that exacerbated with age. Furthermore, MsrA(-/-) mice were less responsive to amphetamine treatment. Consequently, brain dopamine levels were determined. Surprisingly, relative to wild-type mice, MsrA(-/-) brains contained significantly higher levels of dopamine up to 12 months of age, while lower levels of dopamine were observed at 16 months of age. Moreover, striatal regions of MsrA(-/-) mice showed an increase of dopamine release parallel to observed dopamine levels. Similarly, the expression pattern of tyrosine hydroxylase activating protein correlated with the age-dependent dopamine levels. Thus, it is suggested that dopamine regulation and signaling pathways are impaired in MsrA(-/-) mice, which may contribute to their abnormal behavior. These observations may be relevant to age-related neurological diseases associated with oxidative stress.     

Alteration of dopamine receptors in the caudate nucleus and the putamen in schizophrenic brain

Neuroleptic binding to human caudate and putamen was investigated in seven patients with schizophrenia and compared to matched normal controls. [3H]-spiperone was used as a ligand for the binding studies and previous drug treatment was recorded. There was a statistically significant increase in maximal specific binding and in dissociation constants for [3H]-spiperone in the brains of schizophrenics in both brain regions studied. Long term as well as recent neuroleptic treatment both appeared to be associated with increases of Bmax and Kd of [3H]-spiperone.     

Plasma dopamine: regulation and significance

Dopamine (DA) normally circulates in plasma. The plasma concentration of the free form of DA is approximately equivalent to that of epinephrine (E) and 20% that of norepinephrine (NE). The free form constitutes less than 2% of total plasma DA, and the remainder exists predominantly as sulfate or glucuronide conjugates. DA is found in adrenal medulla and cortex, peripheral nerves, sympathetic ganglia, carotid body, and kidney, but quantitatively the origin of circulating DA remains poorly understood. Plasma concentrations of free DA increase in association with events that increase sympathetic tone, although to a much lesser degree than seen for NE or E. Thus, upright posture, bicycle exercise, a variety of emotional and physical stresses, and hypoglycemia may be associated with increases in plasma free DA. Plasma DA decreases during the course of dietary sodium depletion in humans, in contrast to the plasma NE response, and consistent with a physiological role for DA in the regulation of aldosterone secretion. Plasma DA increases after administration of its precursor L-dihydroxyphenylalanine, together with the decarboxylase inhibitor carbidopa. Plasma NE and (in some studies) plasma DA decrease after administration of the DA receptor agonist bromocriptine. In contrast, plasma DA and one of its major metabolites, homovanillic acid, increase after administration of the DA receptor antagonist haloperidol. Administration of the endogenous opioid peptide beta-endorphin into the brain increases central sympathetic outflow, thus increasing plasma DA concentration, although to a lesser extent than for NE or E. Disordered basal concentrations of DA in plasma or disordered responses of plasma DA have been reported in a number of disease states. Clear understanding of physiological roles of DA in plasma and of its pathophysiology awaits definition.     

Multiple transduction mechanisms of dopamine, somatostatin and angiotensin II receptors in anterior pituitary cells

The concept of multifactorial pituitary control is now well established. As in other cell systems, integration of complex messages involves dynamic interactions of receptors and coupling mechanisms. Regulation of adenohypophyseal secretions has been shown to involve cyclic AMP production, the modulation of phosphatidylinositol phosphate breakdown and Ca2+ mobilization. Dopamine, somatostatin and angiotensin II receptors are negatively coupled to adenylate cyclase in anterior pituitary cells. In the case of angiotensin, this effect on adenylate cyclase appears paradoxical since the peptide markedly stimulates prolactin secretion. In fact, angiotensin II also markedly stimulates inositol phosphate production and this effect could account for the stimulated hormone secretion. In addition, dopamine could inhibit inositol phosphate production stimulated by angiotensin II and thyrotropin-releasing hormone. Dopamine and somatostatin also directly modulate voltage-dependent calcium channels, perhaps through a direct coupling with potassium channels. On the other hand, steroids modulate the sensitivity of adenohypophyseal cells to neurohormones by different mechanisms. In the case of somatostatin, it increases the number of specific binding sites, while in the case of dopamine estradiol affects the transduction mechanisms of D2 dopamine receptors. In conclusion, dopamine and somatostatin receptors appear coupled to various transduction mechanisms through pertussis-sensitive G proteins in anterior pituitary cells.