Modulation of dopamine metabolism in the retina via dopamine D2 receptors

When rats are placed in a lighted environment from the dark retinal DOPAC increases. There is no significant change of retinal dopamine (DA) under either lighting condition. Blockade of aromaticl-amino acid decar☐ylase results in a more rapid accumulation of DOPA in the retina of animals in the light than in the dark implying that DA synthesis and metabolism are more rapid in the light than in the dark. Retinal DOPAC increases in the dark and in the light when rats are treated with the DA D₂ antagonists sulpiride and spiperone. Treatment with the D₂ agonist, quinpirole, lowers the content of DA in the retina of rats kept in the dark or exposed to light. D₁ receptor drugs induce only limited changes in DA metabolism. We conclude that D₂ receptors play a principal role for modulating DA synthesis and metabolism in the rat retina.     

Psychosis pathways converge via D2high dopamine receptors

The objective of this review is to identify a target or biomarker of altered neurochemical sensitivity that is common to the many animal models of human psychoses associated with street drugs, brain injury, steroid use, birth injury, and gene alterations. Psychosis in humans can be caused by amphetamine, phencyclidine, steroids, ethanol, and brain lesions such as hippocampal, cortical, and entorhinal lesions. Strikingly, all of these drugs and lesions in rats lead to dopamine supersensitivity and increase the high-affinity states of dopamine D2 receptors, or D2High, by 200-400% in striata. Similar supersensitivity and D2High elevations occur in rats born by Caesarian section and in rats treated with corticosterone or antipsychotics such as reserpine, risperidone, haloperidol, olanzapine, quetiapine, and clozapine, with the latter two inducing elevated D2High states less than that caused by haloperidol or olanzapine. Mice born with gene knockouts of some possible schizophrenia susceptibility genes are dopamine supersensitive, and their striata reveal markedly elevated D2High states; suchgenes include dopamine-beta-hydroxylase, dopamine D4 receptors, G protein receptor kinase 6, tyrosine hydroxylase, catechol-O-methyltransferase, the trace amine-1 receptor, regulator of G protein signaling RGS9, and the RIIbeta form of cAMP-dependent protein kinase (PKA). Striata from mice that are not dopamine supersensitive did not reveal elevated D2High states; these include mice with knockouts of adenosine A2A receptors, glycogen synthase kinase GSK3beta, metabotropic glutamate receptor 5, dopamine D1 or D3 receptors, histamine H1, H2, or H3 receptors, and rats treated with ketanserin or aD1 antagonist. The evidence suggests that there are multiple pathways that convergetoelevate the D2High state in brain regions and that this elevation may elicit psychosis. This proposition is supported by the dopamine supersensitivity that is a common feature of schizophrenia and that also occurs in many types of genetically altered, drug-altered, and lesion-altered animals. Dopamine supersensitivity, in turn, correlates with D2High states. The finding that all antipsychotics, traditional and recent ones, act on D2High dopamine receptors further supports the proposition.     

Cocaine increases ryanodine receptors via dopamine D1 receptors

For review there are little available data on regulatory mechanisms of ryanodine receptor (RyR) expression with cocaine treatment, though methamphetamine was reported to up-regulate RyRs in mouse brain. This study attempted to investigate regulatory mechanisms of RyR expression using the cerebral cortical neurons in primary culture intermittently exposed to a psychostimulant, cocaine. Intermittent exposure to cocaine (10 μM) significantly enhanced RyR 1 and 2 proteins and their mRNA, but not RyR 3 expression in the neurons. These cocaine-induced increases of RyR proteins and their mRNA were dose-dependently blocked by a dopamine D1 receptor antagonist (SCH23390), but not by a dopamine D2 receptor antagonist (sulpiride). These results indicate a regulatory role of dopamine D1 receptors in RyR expression bycocaine.     

Oligomers of D2 dopamine receptors

There is increasing evidence that G protein-coupled receptors form oligomers and that this might be important for their function. We have studied this phenomenon for the D2 dopamine receptor and have shown using a variety of biochemical and biophysical techniques that this receptor forms dimers or higher-order oligomers. Using ligand-binding studies, we have also found evidence that this oligomer formation has functional relevance. Thus, for the receptor expressed in either CHO cells or Sf 9 insect cells, the binding properties of several radioligands (in saturation, competition, and dissociation assays) do not conform to those expected for a monomeric receptor with a single binding site. We propose that the receptors exist in oligomers with homotropic and heterotropic negatively cooperative interactions between ligands.     

Diurnal metabolism of dopamine in the mouse retina

Dopamine is an important retinal neurotransmitter and neuromodulator that regulates key diurnal cellular and physiological functions. In the present study we carried out a comprehensive analysis of dopamine metabolism during the light phase of the diurnal cycle and evaluated the presence of diurnal and circadian rhythms of dopaminergic activity in the mouse retina. Steady-state levels of dopamine did not change significantly between the dark phase (night) and the light phase (day) of the diurnal cycle, nor did they change between early and late points in the day. Dopamine synthesis and utilization, however, revealed significant alterations between the night and day and between early and late time points in the day. A spike in synthesis and utilization was measured immediately after light onset at the end of the night. Subsequently, dopamine synthesis and utilization partially declined and remained stable throughout the remainder of the day at a level that was significantly higher than that at night. The burst of dopamine synthesis and utilization at the beginning of the day is entirely light evoked and not driven by a circadian clock. Similarly, there was no circadian rhythm in dopamine synthesis and utilization in mice kept in constant darkness. This daily pattern of dopaminergic activity may impact upon a variety of temporally regulated retinal events. Moreover, these data will provide a basis for evaluating the role of dopamine in retinal pathology in mouse models of retinal degeneration where mutations affect light perception.     

Striatal dopamine D2 receptors, metabolism, and volume in preclinical Huntington disease

Among 27 preclinical carriers of the Huntington disease mutation (PMC), the authors found normal striatal values for MRI volumetry in 88% and for fluorodesoxyglucose PET metabolic index in 67%. Raclopride PET binding potential (RAC-BP) was decreased in 50% and correlated with increases in the product of age and CAG repeat length (p < 0.0005). Dopamine D2 receptor availability measured by RAC-BP seems the most sensitive indicator of early neuronal impairment in PMC.     

Modulation of acetylcholine release by D1, D2 dopamine receptors in rat striatum under freely moving conditions

Using in vivo brain dialysis under freely moving conditions, we have studied the effects of dopamine (DA) agonists and antagonists on acetylcholine (ACh) and DA release in rat striatum. The striatal infusion of the D1 DA receptor specific agonist, SKF38393, increased striatal ACh release in a dose-dependent manner (10(-6) to 10(-4) M), and 3 x 10(-5) M SKF38393 elicited a 60% augmentation in the level of ACh release. The level of ACh was increased with perfusion of 10(-4) M SCH23390, a D1 specific antagonist, but decreased with 10(-3) M SCH23390. The D2 specific agonist, LY171555, and the antagonist, sulpiride, slightly altered the level of ACh in the striatum. On the other hand the level of DA dramatically increased in a dose-dependent manner with SKF38393 or SCH23390 and decreased with LY171555. LY171555 inhibited the effect of 10(-4) M SKF38393 on ACh release, and enhanced the effect of SKF38393 on DA release. These results suggest that the D1 DA receptor mainly mediates ACh release and the D2 DA receptor modifies the effects of the D1 receptor.     

Light-dependent regulation of dopamine receptors in mammalian retina

The specific binding of [3H]spiperone, a D-2 dopamine receptor ligand, in in retinas from rabbits kept one week in constant light was significantly lower than in retinas from rabbits exposed to constant dark. Constant light did not alter the binding of [3H]spiperone in the striatum, where melatonin does not inhibit dopamine release. The decrease in [3H]spiperone binding induced by constant light in retina appears to be associated with the activation of inhibitory melatonin receptors on dopaminergic neurons. In support of this hypothesis, treatments that elevate melatonin concentrations, such as dark or melatonin administration, reversed the light-induced down-regulation of D-2 dopamine binding sites in retina. It is concluded that the decrease in melatonin levels in constant light disinhibits the dopamine-containing retinal neurons in vivo leading to elevated dopamine release and subsequent D-2 dopamine receptor down-regulation.     

A role for dopamine in control of the hypoxic ventilatory response via D2 receptors in the zebrafish gill

Dopamine is a neurotransmitter involved in oxygen sensing and control of reflex hyperventilation. In aquatic vertebrates, oxygen sensing occurs in the gills via chemoreceptive neuroepithelial cells (NECs), but a mechanism for dopamine in autonomic control of ventilation has not been defined. We used immunohistochemistry and confocal microscopy to map the distribution of tyrosine hydroxylase (TH), an enzyme necessary for dopamine synthesis, in the gills of zebrafish. TH was found in nerve fibers of the gill filaments and respiratory lamellae. We further identified dopamine active transporter (dat) and vesicular monoamine transporter (vmat2) expression in neurons of the gill filaments using transgenic lines. Moreover, TH- and dat-positive nerve fibers innervated NECs. In chemical screening assays, domperidone, a D₂ receptor antagonist, increased ventilation frequency in zebrafish larvae in a dose-dependent manner. When larvae were confronted with acute hypoxia, the D₂ agonist, quinpirole, abolished the hyperventilatory response. Quantitative polymerase chain reaction confirmed expression of drd2a and drd2b (genes encoding D₂ receptors) in the gills, and their relative abundance decreased following acclimation to hypoxia for 48 h. We localized D₂ receptor immunoreactivity to NECs in the efferent gill filament epithelium, and a novel cell type in the afferent filament epithelium. We provide evidence for the synthesis and storage of dopamine by sensory nerve terminals that innervate NECs. We further suggest that D₂ receptors on presynaptic NECs provide a feedback mechanism that attenuates the chemoreceptor response to hypoxia. Our studies suggest that a fundamental, modulatory role for dopamine in oxygen sensing arose early in vertebrate evolution.     

Differential modulation of rod and cone calcium currents in tiger salamander retina by D2 dopamine receptors and cAMP

Synaptic transmission from vertebrate photoreceptors involves activation of L-type calcium currents (ICa). Dopamine is an important circadian neuromodulator in the retina and photoreceptors possess D2 dopamine receptors. We examined modulation of ICa by dopamine and cAMP in retinal slices and isolated cells of larval tiger salamander. Results show that dopamine and a D2 agonist, quinpirole, enhanced ICa in rods and red-, blue- and UV-sensitive small single cones but inhibited ICa in red-sensitive large single cones. A D1 agonist, SKF-38393, was without effect. Quinpirole effects were blocked by pertussis toxin (PTx) pretreatment indicating involvement of PTx-sensitive G-proteins. Like dopamine, inhibition of cAMP-dependent protein kinase (PKA) by Rp-cAMPS enhanced ICa in rods and small single cones, but inhibited ICa in large single cones. In contrast, forskolin and Sp-cAMPS, which stimulate PKA, inhibited ICa in rods and small single cones but enhanced ICa in large single cones. Sp-cAMPS also occluded effects of quinpirole. These results suggest that D2 receptors modulate ICa via inhibition of cAMP. Differences among the responses of photoreceptors to cAMP are consistent with the possibility that small single cones and rods may possess different Ca2+ channel subtypes than large single cones. The results with dopamine and quinpirole showing inhibition of ICa in large single cones and enhancement of rod ICa were unexpected because previous studies have shown that dopamine suppresses rod inputs and enhances cone inputs into second-order neurons. The present results therefore indicate that the dopaminergic enhancement of cone inputs does not arise from modulation of photoreceptor ICa.     

Loss of dopamine uptake sites and dopamine D2 receptors in striatonigral degeneration

To explore the mechanisms underlying L-dopa response, we studied, by postmortem autoradiography, selective makers of dopamine presynaptic terminals, [3H]WIN 35428, and dopamine D2 receptors, [3H]nemonapride, in the putamen of four Parkinson's disease (PD) and one striatonigral degeneration (SND) neuropathologically confirmed brains as compared with six matched control brains. Dopamine uptake transporter was dramatically decreased (> 90%) both in PD and SND striatum. Dopamine D2 receptors were preserved in PD, but clearly reduced (> 76%) in the SND putamen. These data confirm that L-dopa response is closely associated with the preservation of striatal dopamine D2 receptors.     

Modulation of CNS dopamine receptors by peptides

1. 1. L-prolyl-L-leucyl-glycinamide (PLG), when administered concurrently with neuroleptic drug, blocked the development of dopamine receptor supersensitivity both at the behavioral and biochemical level.

2. 2. Chronic administration of haloperidol resulted in development of cholecystokinin (CCK) receptor supersensitivity in the mesolimbic regions of the brain. There was no change in equilibrium dissociation constant (KD) for CCK binding.

3. 3. The results are discussed in relation to modulation of dopamine receptor by peptides and possible models of Interaction of peptides with dopamine receptors are proposed.

Modulation of dopamine release by striatal 5-HT2C receptors

Previous work has demonstrated that dopamine (DA) transmission is regulated by serotonin-2C (5-HT2C) receptors but the site(s) in the brain where these receptors are localized is not known. The present work utilized in vivo microdialysis to investigate the modulation of DA release by 5-HT2C receptors localized in the nerve terminal regions of the mesocortical and nigrostriatal DA pathways. Microdialysis probes implanted in the striatum or the prefrontal cortex (PFC) measured dialysate DA concentrations, while the selective 5-HT2B/2C inverse agonist SB 206553 was given locally by reverse dialysis into these terminal regions. Additionally, the effects of the 5-HT2C agonist mCPP on striatal DA were measured. Local administration of SB 206553 (0.1-100 microM) into the striatum increased DA efflux in a concentration-dependent manner. Systemic administration of mCPP (1.0 mg/kg i.p.) decreased striatal DA and attenuated the SB 206553-induced increase. In contrast, infusion of SB 206553 (0.1-500 microM) by reverse dialysis into the PFC had no significant effect on basal DA efflux in this region. Additionally, high concentrations of SB 206553 had no effect on high potassium (K(+))-stimulated DA release in the PFC. These data contribute to a body of evidence indicating that 5-HT2C receptors inhibit nigrostriatal dopaminergic transmission. In addition, the results suggest that the nigrostriatal system is regulated by 5-HT2C receptors localized in the dorsal striatum. Elucidating the mechanisms by which serotonin (5-HT) modulates striatal and prefrontocortical DA concentrations may lead to improvements in the treatment of diverse syndromes such as schizophrenia, Parkinson's disease, anxiety, drug abuse, and/or depression.     

Differential ontogenesis of D1 and D2 dopaminergic receptors in the chick embryo retina

The differentiation of D1 and D2 dopamine receptors was investigated during the ontogenesis of the chick embryo retina. Our results reveal an interesting complexity in dopaminergic differentiation, with one major receptor system developing before synapses and another one developing after. The dopamine-dependent increase of chick retina cAMP level differentiates early during retina ontogeny. By the embryonic day 10-11 10(-4) M dopamine and ADTN elicit a 13-fold increase in cAMP content of the retina. However, [3H]spiperone (D2 ligand) binds very little to crude membrane preparation of retinas from embryos in the same developmental stage (12-13 fmol/mg protein). High specific binding of [3H]spiperone is only detected after the embryonic day 17-18, attaining 80 to 100 fmol of specific spiperone binding sites in the retinas from post-hatched animals. Apomorphine also promotes the accumulation of cAMP of retinas from early embryonic stages. However, it is only 20-30% as effective as ADTN or dopamine. In addition, while the dopamine responsiveness of the tissue decreases sharply during its ontogeny, the apomorphine effect remains practically constant throughout this period. Both dopamine and apomorphine are equally effective in eliciting cAMP accumulation of retinas from post-hatched animals. Moreover, apomorphine is a potent inhibitor of dopamine-induced cAMP level of the embryonic tissue. The results presented here indicate that D1 and D2 receptors differentiate independently from each other, and that apomorphine elevates retina cAMP levels via a subclass of D1 receptors that does not desensitize significantly during retina development.     

Striatal dopamine D2 receptors attenuate neuropathic hypersensitivity in the rat

Earlier studies indicate that striatal dopamine D(2) receptors are involved in pain regulation in non-neuropathic conditions. We assessed whether striatal dopamine D(2) receptors contribute to pain regulation also in neuropathic conditions. The spared nerve injury model of neuropathy was induced by unilateral ligation of the tibial and common peroneal nerves in the rat. In awake nerve-injured animals, pain-related withdrawal responses to calibrated monofilaments or noxious heating were attenuated following striatal administration of a dopamine D(2) receptor agonist quinpirole. Pain-related responses were attenuated only in the nerve-injured limb ipsilateral to the injection and in the midline (tail). In unoperated controls, striatal administration of quinpirole at an antihypersensitive dose did not influence withdrawal responses to mechanical stimulation. Attenuation of pain-related responses induced by striatal administration of quinpirole was reversed by intrathecal administration of a dopamine D(2) receptor antagonist (eticlopride) or a non-selective 5-HT receptor antagonist (methysergide), but not by an alpha(2)-adrenoceptor antagonist (atipamezole). In the rostroventromedial medulla of lightly anesthetized neuropathic animals, striatal administration of quinpirole significantly decreased the activity of presumably pronociceptive cells that are activated by noxious stimulation. The innocuous H-reflex in lightly anesthetized control animals was not suppressed by striatal administration of quinpirole at an antihypersensitive dose. The results indicate that striatal dopamine D(2) receptors attenuate neuropathic hypersensitivity. The antihypersensitive effect induced by striatal dopamine D(2) receptors in peripheral neuropathy involves suppression of impulse discharge of presumably pronociceptive neurons in the rostroventromedial medulla, and a descending influence acting on spinal 5-HT and dopamine D(2) receptors.     

Lack of GTP-insensitive D2 dopamine receptors in Huntington's disease

Previous studies have shown that the mammalian neostriatum contains two subtypes of D2 dopamine receptors, which can be distinguished on the basis of the ability of GTP to convert high (RH) into low (RL) affinity sites for dopamine: GTP-sensitive (GS) and GTP-insensitive (GI) D2 receptors. The GI-D2 receptors in rat and human neostriatum are confined to the corticostriatal terminals. In rats, these receptors mediate the inhibitory effect of dopamine on the release of glutamate in the striatum. Here we report that the putamen in Huntington's disease (HD) lacks GI-D2 receptors. Their absence might be responsible for an inappropriate release of glutamate, which is neurotoxic in high concentrations, and might thus contribute to striatal cell death in HD.     

Bidirectional regulation of dopamine D2 and neurotensin NTS1 receptors in dopamine neurons

Several lines of evidence suggest a close association between dopamine (DA) and neurotensin (NT) systems in the CNS. Indeed, in the rodent brain, abundant NT-containing fibres are found in DA-rich areas such as the ventral tegmental area and substantia nigra. Moreover, it has been shown in vivo that NT, acting through its high-affinity receptor (NTS1), reduces the physiological and behavioural effects of DA D2 receptor (D2R) activation, a critical autoreceptor feedback system regulating DA neurotransmission. However, the mechanism of this interaction is still elusive. The aim of our study was thus to reproduce in vitro the interaction between D2R and NTS1, and then to characterize the mechanisms implicated. We used a primary culture model of DA neurons prepared from transgenic mice expressing green fluorescent protein under the control of the tyrosine hydroxylase promoter. In these cultures, DA neurons endogenously express both D2R and NTS1. Using electrophysiological recordings, we show that activation of D2R directly inhibits the firing rate of DA neurons. In addition, we find that NT, acting through a NTS1-like receptor, is able to reduce D2R autoreceptor function independently of its ability to enhance DA neuron firing, and that this interaction occurs through a protein kinase C- and Ca(2+)-dependent mechanism. Furthermore, prior activation of D2R reduces the ability of NTS1 to induce intracellular Ca(2+) mobilization. Our findings provide evidence for bidirectional interaction between D2R and NTS1 in DA neurons, a regulatory mechanism that could play a key role in the control of the activity of these neurons.