D5 dopamine receptor knockout mice and hypertension

Abnormalities in dopamine production and receptor function have been described in human essential hypertension and rodent models of genetic hypertension. All of the five dopamine receptor genes (D1, D2, D3, D4, and D5) expressed in mammals and some of their regulators are in loci linked to hypertension in humans and in rodents. Under normal conditions, D1-like receptors (D1 and D5) inhibit sodium transport in the kidney and the intestine. However, in the Dahl salt-sensitive and spontaneously hypertensive rats, and humans with essential hypertension, the D1-like receptor-mediated inhibition of sodium transport is impaired because of an uncoupling of the D1-like receptor from its G protein/effector complex. The uncoupling is genetic, and receptor-, organ-, and nephron segment-specific. In human essential hypertension, the uncoupling of the D1 receptor from its G protein/effector complex is caused by an agonist-independent serine phosphorylation/desensitization by constitutively active variants of the G protein-coupled receptor kinase type 4. The D5 receptor is also important in blood pressure regulation. Disruption of the D5 or the D1 receptor gene in mice increases blood pressure. However, unlike the D1 receptor, the hypertension in D5 receptor null mice is caused by increased activity of the sympathetic nervous system, apparently due to activation of oxytocin, V1 vasopressin, and non-N-methyl D-aspartate receptors in the central nervous system. The cause of the activation of these receptors remains to be determined.     

Dopamine-induced functional activation of Gαq mediated by dopamine D1-like receptor in rat cerebral cortical membranes

Although multiple roles of dopamine through D₁-like (D₁ and D₅) and D₂-like (D₂, D₃, and D₄) receptors are initiated primarily through stimulation or inhibition of adenylyl cyclase via G_s/olf or G_i/o, respectively, there have been many reports indicating diverse signaling mechanisms that involve alternative G protein coupling. In this study, dopamine-induced Gα_q activation in rat brain membranes was investigated. Agonist-induced Gα_q activation was assessed by increase in guanosine-5′-O-(3-[³⁵S]thio)triphosphate ([³⁵S]GTPγS) binding to Gα_q determined by [³⁵S]GTPγS binding/immunoprecipitation assay in rat brain membranes. Dopamine-stimulated Gα_q functionality was highest in cortex as compared to hippocampus or striatum. In cerebral cortical membranes, this effect was mimicked by benzazepine derivatives with agonist properties at dopamine D₁-like receptors, that is, SKF83959, SKF83822, R(+)-SKF81297, R(+)-SKF38393, and SKF82958, but not by the compounds with dopamine D₂-like receptor agonist properties except for aripiprazole. Against expectation, stimulatory effects were also induced by SKF83566, R(+)-SCH23390, and pergolide. The pharmacological profiling by using a series of antagonists indicated that dopamine-induced response was mediated through dopamine D₁-like receptor, which was distinct from the receptor involved in 5-HT-induced response (5-HT_2A receptor). Conversely, the responses induced by SKF83566, R(+)-SCH23390, and pergolide were most likely mediated by 5-HT_2A receptor, but not by dopamine D₁-like receptor. Caution should be paid when interpreting the experimental data, especially in behavioral pharmacological research, in which SKF83566 or R(+)-SCH23390 is used as a standard selective dopamine D₁-like receptor antagonist. Also, possible clinical implications of the agonistic effects of pergolide on 5-HT_2A receptor has been mentioned.     

Amphioxus expresses both vertebrate-type and invertebrate-type dopamine D1 receptors

The cephalochordate amphioxus (Branchiostoma floridae) has recently been placed as the most basal of all the chordates, which makes it an ideal organism for studying the molecular basis of the evolutionary transition from invertebrates to vertebrates. The biogenic amine, dopamine regulates many aspects of motor control in both vertebrates and invertebrates, and in both cases, its receptors can be divided into two main groups (D1 and D2) based on sequence similarity, ligand affinity and effector coupling. A bioinformatic study shows that amphioxus has at least three dopamine D1-like receptor sequences. We have recently characterized one of these receptors, AmphiD1/β, which was found to have high levels of sequence similarity to both vertebrate D1 receptors and to β-adrenergic receptors, but functionally appeared to be a vertebrate-type dopamine D₁ receptor. Here, we report on the cloning of two further dopamine D₁ receptors (AmphiAmR1 and AmphiAmR2) from adult amphioxus cDNA libraries and their pharmacological characterisation subsequent to their expression in cell lines. AmphiAmR1 shows closer structural similarities to vertebrate D₁-like receptors but shows some pharmacological similarities to invertebrate “DOP1” dopamine D₁-like receptors. In contrast, AmphiAmR2 shows closer structural and pharmacological similarities to invertebrate “INDR”-like dopamine D₁-like receptors.     

Endosomal location of dopamine receptors in neuronal cell cytoplasm

Five subtypes of dopamine receptor exist in two subfamilies: two D₁-like (D₁ and D₅) and three D₂-like (D₂, D₃ and D₄). We produced novel monoclonal antibodies against all three D₂-like receptors and used them to localize receptors in Ntera-2 (NT-2) cells, the human neuronal precursor cell line. Most of the immunostaining for all three receptors colocalized with mannose-6-phosphate receptor, a marker for late endosomes formed by internalization of the plasma membrane. This result was obtained with antibodies against three different epitopes on the D₃ receptor, to rule out the possibility of cross-reaction with another protein, and controls without primary antibody or in the presence of competitor antigen were completely negative. In rat cerebral cortex and hippocampus, some of the dopamine receptor staining was found in similar structures in neuronal cell cytoplasm. Only some of the neurons were positive for dopamine receptors and the pattern was consistent with previously-reported patterns of innervation by dopamine-producing neurons. Endosomal dopamine receptors may provide a useful method for identifying cell bodies of dopamine-responsive neurons to complement methods that detect only active receptors in the neuronal cell membrane.     

Systemic Blockade of Dopamine D2-Like Receptors Increases High-Voltage Spindles in the Globus Pallidus and Motor Cortex of Freely Moving Rats

High-voltage spindles (HVSs) have been reported to appear spontaneously and widely in the cortical–basal ganglia networks of rats. Our previous study showed that dopamine depletion can significantly increase the power and coherence of HVSs in the globus pallidus (GP) and motor cortex of freely moving rats. However, it is unclear whether dopamine regulates HVS activity by acting on dopamine D₁-like receptors or D₂-like receptors. We employed local-field potential and electrocorticogram methods to simultaneously record the oscillatory activities in the GP and primary motor cortex (M1) in freely moving rats following systemic administration of dopamine receptor antagonists or saline. The results showed that the dopamine D₂-like receptor antagonists, raclopride and haloperidol, significantly increased the number and duration of HVSs, and the relative power associated with HVS activity in the GP and M1 cortex. Coherence values for HVS activity between the GP and M1 cortex area were also significantly increased by dopamine D₂-like receptor antagonists. On the contrary, the selective dopamine D₁-like receptor antagonist, {"type":"entrez-protein","attrs":{"text":"SCH23390","term_id":"1052733334","term_text":"SCH23390"}}SCH23390, had no significant effect on the number, duration, or relative power of HVSs, or HVS-related coherence between M1 and GP. In conclusion, dopamine D₂-like receptors, but not D₁-like receptors, were involved in HVS regulation. This supports the important role of dopamine D₂-like receptors in the regulation of HVSs. An siRNA knock-down experiment on the striatum confirmed our conclusion.     

D1-Like Dopamine Receptor-Mediated Function in Congenic Mutants with D1 vs. D5 Receptor “Knockout”

Current understanding of the functional roles of individual dopamine D₁-like [D₁, D₅] and D₂-like [D_2L/S, D₃, D₄] receptor subtypes remains incomplete. In particular, the lack of pharmacological agonists and antagonists able to distinguish between D₁ and D₅ receptors means that any differential roles in the regulation of behavior are poorly understood. Mutant mice with targeted gene deletion (“knockout”) of individual dopamine receptor subtypes offer an important alternative approach to resolving these functional roles. In congenic D₁ mutants examined ethologically, progressive increases in specific topographies of behavior over wildtypes were considerably greater than those in D₁ mutants on a mixed genetic background; D₁ knockout appears to influence the neuronal substrate(s) of habituation to disrupt sculpture of the changing topography of behavior from initial exploration through to quiescence. Similarly, the D₁ receptor appears to regulate specific topographies of orofacial movement in the mouse as these are “sculpted” in a time-dependent manner. Although the well-recognized role of the D₁-like family in regulating several aspects of behavioral topography has been assumed to involve primarily D₁ receptors, this presumption may require modification to accommodate a subtle but not negligible role for their D₅ counterparts as evidenced in the phenotype of congenic D₅ mutants.     

Molecular and pharmacological characterization of two D(1)-like dopamine receptors in the Lyme disease vector, Ixodes scapularis

Advancements in tick neurobiology may impact the development of acaricides to control those species that transmit human and animal diseases. Here, we report the first cloning and pharmacological characterization of two neurotransmitter binding G protein-coupled receptors in the Lyme disease (blacklegged) tick, Ixodes scapularis. The genes IscaGPRdop1 and IscaGPRdop2 were identified in the I. scapularis genome assembly and predicted as orthologs of previously characterized D₁-like dopamine receptors in the fruit fly Drosophila melanogaster and honeybee Apis mellifera. Heterologous expression in HEK 293 cells demonstrated that each receptor functioned as a D₁-like dopamine receptor because significant increases in levels of intracellular cyclic adenosine monophosphate (cAMP) were detected following dopamine treatment. Importantly, the receptors were distinct in their pharmacological properties regarding concentration-dependent response to dopamine, constitutive activity, and response to other biogenic amines. Exposure to a variety of dopamine receptor agonists and antagonists further demonstrated a D₁-like pharmacology of these dopamine receptors and highlighted their differential activities in vitro.     

Differential voltage-sensitivity of D2-like dopamine receptors

Agonist potency at some neurotransmitter receptors has been shown to be regulated by transmembrane voltage, a mechanism which has been suggested to play a crucial role in the regulation of neurotransmitter release by autoreceptors and in synaptic plasticity. We have recently described the voltage-sensitivity of the dopamine D_2L receptor and we now extend our studies to include the other members of the D₂-like receptor subfamily; the D_2S, D₃, and D₄ dopamine receptors. Electrophysiological recordings were performed on Xenopus oocytes coexpressing human dopamine D_2S, D₃, or D₄ receptors with G protein-coupled potassium (GIRK) channels. Comparison of concentration-response relationships at −80 mV and at 0 mV for dopamine-mediated GIRK activation revealed significant rightward shifts for both D_2S and D₄ upon depolarization. In contrast, the concentration-response relationships for D₃-mediated GIRK activation were not appreciably different at the two voltages. Our findings provide new insight into the functional differences of these closely related receptors.     

Physicochemical Modulation of Agonist-Induced [35S]GTPγS Binding: Implications for Coexistence of Multiple Functional Conformations of Dopamine D1-Like Receptors

Dopamine agonist-stimulated [³⁵S]GTPγS binding to membrane G proteins was studied in select brain regions under experimental conditions that permit the activation of receptor coupling to the G proteins G_i, G_s, or G_q. Agents studied were agonists known to be effective at various dopamine receptor/effector systems and included quinelorane (D₂-like/G_i), SKF38393 (D₁-like/G_q, D₁-like/G_s), SKF85174 (D₁-like/G_s), and SKF83959 (D₁-like/G_q). Dopamine and SKF38393 significantly stimulated [³⁵S]GTPγS binding to normal striatal membranes by 161% and 67% above controls. Deoxycholate, which enhances agonist-induced phospholipase C (PLC) stimulation, markedly enhanced the agonistic effects of dopamine and SKF38393 to 530% and 637% above controls, respectively. The enhancing effects of deoxycholate were reversed if it was washed off the membranes before agonist addition. The thiol-reducing agent, dithiothreitol, completely abolished the effects of SKF38393 and SKF83959, whereas SKF85174 effects were augmented. Agonist responses were concentration-related, and highest efficacies were obtained in the hippocampus, thus paralleling both the brain regional distribution and agonist efficacies previously observed in phosphoinositide hydrolysis assays. These findings suggest that D₁-like receptor conformations that mediate agonist stimulation of G_s/adenylylcyclase may be structurally different from those that mediate G_q/PLC activation. Although the exact mechanism of deoxycholate's effect awaits elucidation, the results are consistent with the emerging concept of functional selectivity whereby deoxycholate could create a membrane environment that facilitates the transformation of the receptor from a conformation that activates G_s/adenylylcyclase to one that favors G_q/PLC signaling.     

Dopamine receptor localization in the mammalian retina

After a short history of dopamine receptor discovery in the retina and a survey on dopamine receptor types and subtypes, the distribution of dopamine receptors in the retinal cells is described and correlated with their possible role in cell and retinal physiology. All the retinal cells probably bear dopamine receptors. For example, the recently discovered D_1B receptor has a possible role in modulating phagocytosis by the pigment epithelium and a D₄ receptor is likely to be involved in the inhibition of melatonin synthesis in photoreceptors. Dopamine uncouples horizontal and amacrine cell-gap junctions through D₁-like receptors. Dopamine modulates the release of other transmitters by subpopulations of amacrine cells, including that of dopamine through a D₂ autoreceptor. Ganglion cells express dopamine receptors, the role of which is still uncertain. Müller cells also are affected by dopamine. A puzzling action of dopamine is observed in the ciliary retina, in which D₁- and D₂-like receptors are likely to be involved in the cyclic regulation of intraocular pressure. Most of the dopaminergic actions appears to be extrasynaptic and the signaling pathways remain uncertain. Further studies are needed to better understand the multiple actions of dopamine in the retina, especially those that implicate rhythmic regulations.     

G Protein-coupled Receptor Kinase 4 (GRK4) Regulates the Phosphorylation and Function of the Dopamine D3 Receptor

During conditions of moderate sodium excess, the dopaminergic system regulates blood pressure and water and electrolyte balance by engendering natriuresis. Dopamine exerts its effects on dopamine receptors, including the dopamine D₃ receptor. G protein-coupled receptor kinase 4 (GRK4), whose gene locus (4p16.3) is linked to essential hypertension, desensitizes the D₁ receptor, another dopamine receptor. This study evaluated the role of GRK4 on D₃ receptor function in human proximal tubule cells. D₃ receptor co-segregated in lipid rafts and co-immunoprecipitated and co-localized in human proximal tubule cells and in proximal and distal tubules and glomeruli of kidneys of Wistar Kyoto rats. Bimolecular fluorescence complementation and confocal microscopy revealed that agonist activation of the receptor initiated the interaction between D₃ receptor and GRK4 at the cell membrane and promoted it intracellularly, presumably en route to endosomal trafficking. Of the four GRK4 splice variants, GRK4-γ and GRK4-α mediated a 3- and 2-fold increase in the phosphorylation of agonist-activated D₃ receptor, respectively. Inhibition of GRK activity with heparin or knockdown of GRK4 expression via RNA interference completely abolished p44/42 phosphorylation and mitogenesis induced by D₃ receptor stimulation. These data demonstrate that GRK4, specifically the GRK4-γ and GRK4-α isoforms, phosphorylates the D₃ receptor and is crucial for its signaling in human proximal tubule cells.During conditions of moderate sodium excess, the dopaminergic system sits at the fulcrum of homeostatic control of water and electrolyte balance and blood pressure (1, 2). Dopamine promotes natriuresis by inhibiting sodium chloride reabsorption in specific segments of the nephron. Dopamine exerts its action on dopamine receptors, which belong to the family of G protein-coupled receptors (GPCRs).² The dopamine receptors are classified into two subtypes based on their ability to increase cAMP levels, sequence similarity, G protein coupling, and pharmacological profiles (3, 4). The D₁-like dopamine receptors activate adenylyl cyclase by coupling to stimulatory Gα_s/Gα_olf and include the D₁ (D₁R) and D₅ receptors (D₅R). The D₂-like dopamine receptors inhibit adenylyl cyclase by coupling to Gα_i/Gα_o and consist of the D₂ (D₂R), D₃ (D₃R), and D₄ (D₄R) receptors. The D₃R has also been shown to couple to Gα_o, Gβγ, and to the stimulatory Gα_s (5, 6).The signal transduction that follows ligand occupation of a GPCR is tightly regulated to limit the specificity and extent of cellular response. GPCR-mediated signal transduction is rapidly dampened via receptor desensitization or the waning of the responsiveness of the receptor to agonist with time. Desensitization involves receptor phosphorylation and is carried out by either GPCR kinases (GRKs) or second messenger-activated kinases such as protein kinase A and protein kinase C. Homologous desensitization involves GRKs that selectively phosphorylate only agonist-activated receptors, whereas heterologous desensitization is carried out by second messenger-dependent kinases that indiscriminately phosphorylate agonist-activated receptors and those that have not been exposed to the agonist (7).The GRKs are serine/threonine protein kinases comprising seven isoforms that are grouped into three subfamilies. GRK1 and GRK7 belong to the rhodopsin kinase subfamily and are expressed exclusively in the retina (8–10). GRK2 and GRK3 phosphorylate the β-adrenergic receptor and belong to the β-adrenergic receptor kinase subfamily (11), and GRK4, GRK5, and GRK6 belong to the GRK4 subfamily. GRK4 is highly enriched in the testis and, to a lesser degree, in the kidneys (12, 13). Four splice variants of human GRK4 result from the alternative splicing of exons 2 and 15 (11). GRK4-α is considered the full-length version, whereas GRK4-β, -γ, and -δ are shortened versions of GRK4-α (14). The coding region of the GRK4 gene, whose 4p16.3 locus has been linked to essential hypertension (15, 16), contains several single nucleotide polymorphisms, including R65L, A142V, and A486V, which have been linked to essential hypertension and/or salt sensitivity in various ethnic groups (17).The D₃R gene is found at 3q13.3 (18), a locus that is also linked to essential hypertension (19, 20). Sequence analysis of the D₃R gene shows the presence of several single nucleotide polymorphisms, which do not correlate with either essential hypertension among Japanese (21) or with blood pressure levels and diabetic nephropathy among Finns (22). However, D₃R knock-out mice develop a renin-dependent form of hypertension and fail to excrete a sodium load (23).The D₃R has a long third intracellular loop that contains several putative GRK phosphorylation sites (24). A previous study evaluated the ability of GRK2 and GRK3 to phosphorylate D₃R and showed that co-transfection of GRK3, but not GRK2, resulted in a weak phosphorylation of the heterologously expressed, dopamine-stimulated D₃R in HEK-293 (25), a human embryonic kidney cell line. We tested the hypothesis that GRK4 is required in D₃R signaling in terminally differentiated human renal proximal tubule cells (hPTCs) by determining the spatiotemporal dynamics of the interaction of D₃R and GRK4 through their subfractionation in membrane microdomains and subcellular co-localization via confocal microscopy and bimolecular fluorescence complementation assay (BiFC). We also identified which of the GRK4 splice variants are involved in D₃R phosphorylation and evaluated the physiological roles of GRK4 in D₃R signaling in the hPTCs. We now report that D₃R and GRK4 co-fractionate in lipid rafts and co-localize in both hPTCs and WYK kidneys. Moreover, D₃R is phosphorylated by GRK4-γ and GRK4-α isoforms, and the absence of GRK4 impairs D₃R-mediated mitogenesis and activation of p44/42 in hPTCs.     

Discovery of antagonists of tick dopamine receptors via chemical library screening and comparative pharmacological analyses

Ticks transmit a wide variety of disease causing pathogens to humans and animals. Considering the global health impact of tick-borne diseases, there is a pressing need to develop new methods for vector control. We are exploring arthropod dopamine receptors as novel targets for insecticide/acaricide development because of their integral roles in neurobiology. Herein, we developed a screening assay for dopamine receptor antagonists to further characterize the pharmacological properties of the two D₁-like dopamine receptors (Isdop1 and Isdop2) identified in the Lyme disease vector, Ixodes scapularis, and develop a screening assay for receptor antagonists. A cell-based, cyclic AMP luciferase reporter assay platform was implemented to screen the LOPAC¹²⁸⁰ small molecule library for Isdop2 receptor antagonists, representing the first reported chemical library screen for any tick G protein-coupled receptor. Screening resulted in the identification of 85 “hit” compounds with antagonist activity at the Isdop2 receptor. Eight of these chemistries were selected for confirmation assays using a direct measurement of cAMP, and the effects on both Isdop1 and Isdop2 were studied for comparison. Each of these eight compounds showed antagonistic activity at both Isdop1 and Isdop2, although differences were observed regarding their relative potencies. Furthermore, comparison of the pharmacological properties of the tick dopamine receptors with that of the AaDOP2 receptor from the yellow fever mosquito and the human dopamine D₁ receptor (hD₁) revealed species-specific pharmacological profiles of these receptors. Compounds influencing dopaminergic functioning, such as the dopamine receptor antagonists discovered here, may provide lead chemistries for discovery of novel acaricides useful for vector control.     

Coupling of D1 and D5 dopamine receptors to multiple G proteins

Dopamine receptors are a subclass of the super family of G protein-coupled receptors, that transduce their effects by coupling to specific G proteins. Within the dopamine receptor family, the adenylyl cyclase stimulatory receptors include the D₁ and D₅ subtypes. The D₁ and D₅ dopamine receptors are genetically distinct, sharing >80% sequence homology within the highly conserved seven transmembrane spanning domains, but displaying only 50% overall homology at the amino acid level. When expressed in transfected GH₄C₁ rat pituitary cells, both D₁ and D₅ receptors stimulate adenylyl cyclase and have identical affinities toward dopaminergic agonists and antagonists. In order to analyze specific signaling pathways mediated by activation of either D₁ or D₅ receptors, we have identified the G proteins that are coupled to these receptors. Through functional analyses and competition binding studies, and from immunoprecipitation techniques, using antisera against the various α subunits of G proteins, we have established that both D₁ and D₅ receptors couple to G_sα. In addition, D₁ receptors are also coupled to G_oα. Since G_oα has been implicated in the regulation of Ca²⁺, K⁺, and Na⁺ channels, this finding would suggest that D₁ receptors can mediate the functional activity of these ion channels. There is also evidence to indicate that D₅ receptors couple to G_zα, a novel G protein abundantly expressed in neurons. Thus, despite similar pharmacological properties, such differential coupling of D₁ and D₅ receptors to G proteins other than G_sα, indicates that dopamine can transduce varied signaling responses upon the simultaneous stimulation of both these receptors.     

Adenylyl Cyclase Interaction with the D2 Dopamine Receptor Family; Differential Coupling to Gi, Gz, and Gs

1.The D2-type dopamine receptors are thought to inhibit adenylyl cyclase (AC), via coupling to pertussis toxin (PTX)-sensitive G proteins of the Gi family. We examined whether and to what extent the various D2 receptors (D_2S, D_2L, D_3S, D_3L, and D₄) couple to the PTX-insensitive G protein Gz, to produce inhibition of AC activity.2.COS-7 cells were transiently transfected with the individual murine dopamine receptors alone, as well as together with the subunit of Gz. PTX treatment was employed to inactivate endogenous i, and coupling to Gi and Gz was estimated by measuring the inhibition of cAMP accumulation induced by quinpirole, in forskolin-stimulated cells.3.D_2S or D_2L receptors can couple to the same extent to Gi and to Gz. The D₄ dopamine receptor couples preferably to Gz, resulting in about 60% quinpirole-induced inhibition of cAMP accumulation. The D_3S and D_3L receptor isoforms couple slightly to Gz and result in 15 and 30% inhibition of cAMP accumulation, respectively.4.We have demonstrated for the first time that the two D₃ receptor isoforms, and not any of the other D2 receptor subtypes, also couple to Gs in both COS-7 and CHO transfected cells, in the presence of PTX.5.Thus, the differential coupling of the D2 dopamine receptor subtypes to various G proteins may add another aspect to the diversity of dopamine receptor function.     

Cocaine Inhibits Dopamine D2 Receptor Signaling via Sigma-1-D2 Receptor Heteromers

Under normal conditions the brain maintains a delicate balance between inputs of reward seeking controlled by neurons containing the D₁-like family of dopamine receptors and inputs of aversion coming from neurons containing the D₂-like family of dopamine receptors. Cocaine is able to subvert these balanced inputs by altering the cell signaling of these two pathways such that D₁ reward seeking pathway dominates. Here, we provide an explanation at the cellular and biochemical level how cocaine may achieve this. Exploring the effect of cocaine on dopamine D₂ receptors function, we present evidence of σ₁ receptor molecular and functional interaction with dopamine D₂ receptors. Using biophysical, biochemical, and cell biology approaches, we discovered that D₂ receptors (the long isoform of the D₂ receptor) can complex with σ₁ receptors, a result that is specific to D₂ receptors, as D₃ and D₄ receptors did not form heteromers. We demonstrate that the σ₁-D₂ receptor heteromers consist of higher order oligomers, are found in mouse striatum and that cocaine, by binding to σ₁ -D₂ receptor heteromers, inhibits downstream signaling in both cultured cells and in mouse striatum. In contrast, in striatum from σ₁ knockout animals these complexes are not found and this inhibition is not seen. Taken together, these data illuminate the mechanism by which the initial exposure to cocaine can inhibit signaling via D₂ receptor containing neurons, destabilizing the delicate signaling balance influencing drug seeking that emanates from the D₁ and D₂ receptor containing neurons in the brain.     

Synthesis and binding profile of haloperidol-based bivalent ligands targeting dopamine D2-like receptors

Homodimers of dopamine D₂-like receptors are suggested to be of particular importance in the pathophysiology of schizophrenia and, thus, serve as promising targets for the discovery of atypical antipsychotics. This study describes the development of a series of novel bivalent molecules with a pharmacophore derived from the dopamine receptor antagonist haloperidol. These dimers were investigated in comparison to their monomeric analogues for their D_2long, D_2short, D₃, and D₄ receptor binding and the ability to bridge two neighboring receptor protomers. Radioligand binding studies provided diagnostic insights when Hill slopes close to two for the bivalent ligand 13 incorporating 22 spacer atoms and a comparative analysis with monovalent control ligands indicated a bivalent binding mode with a simultaneous occupancy of two neighboring binding sites.     

The dopamine D1 receptor is expressed and facilitates relaxation in airway smooth muscle

Background

Dopamine signaling is mediated by G_s protein-coupled “D₁-like” receptors (D₁ and D₅) and G_i-coupled “D₂-like” receptors (D_2-4). In asthmatic patients, inhaled dopamine induces bronchodilation. Although the G_i-coupled dopamine D₂ receptor is expressed and sensitizes adenylyl cyclase activity in airway smooth muscle (ASM) cells, the G_s-coupled dopamine D₁-like receptor subtypes have never been identified on these cells. Activation of G_s-coupled receptors stimulates cyclic AMP (cAMP) production through the stimulation of adenylyl cyclase, which promotes ASM relaxation. We questioned whether the dopamine D₁-like receptor is expressed on ASM, and modulates its function through G_s-coupling.

Methods

The mRNA and protein expression of dopamine D₁-like receptor subtypes in both native human and guinea pig ASM tissue and cultured human ASM (HASM) cells was measured. To characterize the stimulation of cAMP through the dopamine D₁ receptor, HASM cells were treated with dopamine or the dopamine D₁-like receptor agonists ({"type":"entrez-nucleotide","attrs":{"text":"A68930","term_id":"4759850","term_text":"A68930"}}A68930 or {"type":"entrez-protein","attrs":{"text":"SKF38393","term_id":"1157151916","term_text":"SKF38393"}}SKF38393) before cAMP measurements. To evaluate whether the activation of dopamine D₁ receptor induces ASM relaxation, guinea pig tracheal rings suspended under isometric tension in organ baths were treated with cumulatively increasing concentrations of dopamine or {"type":"entrez-nucleotide","attrs":{"text":"A68930","term_id":"4759850","term_text":"A68930"}}A68930, following an acetylcholine-induced contraction with or without the cAMP-dependent protein kinase (PKA) inhibitor Rp-cAMPS, the large-conductance calcium-activated potassium (BK_Ca) channel blocker iberiotoxin, or the exchange proteins directly activated by cAMP (Epac) antagonist NSC45576.

Results

Messenger RNA encoding the dopamine D₁ and D₅ receptors were detected in native human ASM tissue and cultured HASM cells. Immunoblots confirmed the protein expression of the dopamine D₁ receptor in both native human and guinea pig ASM tissue and cultured HASM cells. The dopamine D₁ receptor was also immunohistochemically localized to both human and guinea pig ASM. The dopamine D₁-like receptor agonists stimulated cAMP production in HASM cells, which was reversed by the selective dopamine D₁-like receptor antagonists {"type":"entrez-protein","attrs":{"text":"SCH23390","term_id":"1052733334","term_text":"SCH23390"}}SCH23390 or {"type":"entrez-protein","attrs":{"text":"SCH39166","term_id":"1052842517","term_text":"SCH39166"}}SCH39166. {"type":"entrez-nucleotide","attrs":{"text":"A68930","term_id":"4759850","term_text":"A68930"}}A68930 relaxed acetylcholine-contracted guinea pig tracheal rings, which was attenuated by Rp-cAMPS but not by iberiotoxin or NSC45576.

Conclusions

These results demonstrate that the dopamine D₁ receptors are expressed on ASM and regulate smooth muscle force via cAMP activation of PKA, and offer a novel target for therapeutic relaxation of ASM.     

Pharmacological Characterization of Mammalian D1 and D2 Dopamine Receptors Expressed in Drosophila Schneider‐2 Cells

Abstract

Mammalian D₁ and D₂ dopamine receptors were stably expressed in Drosophila Schneider‐2 (S2) cells and screened for their pharmacological properties. Saturable, dose‐dependent, high affinity binding of the D₁‐selective antagonist [³H]SCH‐23390 was detected only in membranes from S2 cells induced to express rat dopamine D₁ receptors, while saturable, dose‐dependent, high affinity binding of the D₂‐selective antagonist [³H]methylspiperone was detected only in membranes from S2 cells induced to express rat dopamine D₂ receptors. No specific binding of either radioligand could be detected in membranes isolated from uninduced or untransfected S2 cells. Both dopamine D₁ and D₂ receptor subtypes displayed the appropriate stereoselective binding of enantiomers of the nonselective antagonist butaclamol. Each receptor subtype also displayed the appropriate agonist stereoselectivities. The dopamine D₁ receptor bound the (+)‐enantiomer of the D₁‐selective agonist SKF38393 with higher affinity than the (?)‐enantiomer, while the dopamine D₂ receptor bound the (?)‐enantiomer of the D₂‐selective agonist norpropylapomorphine with higher affinity than the (+)‐enantiomer. At both receptor subtypes, dopamine binding was best characterized as occurring to a single low affinity site. In addition, the low affinity dopamine binding was also found to be insensitive to GTPγS and magnesium ions. Overall, the pharmacological profiles of mammalian dopamine D₁ and D₂ receptors expressed in Drosophila S2 cells is comparable to those observed for these same receptors when they are expressed in mammalian cell lines. A notable distinction is that there is no evidence for the coupling of insect G proteins to mammalian dopamine receptors. These results suggest that the S2 cell insect G system may provide a convenient source of pharmacologically active mammalian D₁ and D₂ dopamine receptors free of promiscuous G protein contaminants.     

Voltage-sensitivity at the human dopamine D2S receptor is agonist-specific

Recently, we and others have shown that agonist potencies at some, but not all, G protein-coupled receptors are voltage-sensitive. Several of those studies employed electrophysiology assays in Xenopus oocytes with G protein-coupled potassium channels as a readout. Using this assay, we have now obtained evidence that voltage-sensitivity at the dopamine D_2S receptor is agonist-specific. Whereas the potency of dopamine at the D_2S receptor is decreased by depolarization, the potencies of β-phenethylamine, p- and m-tyramine are voltage-insensitive. Furthermore, both monohydroxylated and non-hydroxylated N,N-dipropyl-2-aminotetralin compounds are voltage-sensitive. Differential activation of G protein subtypes or differential ratios between effector and active G protein do not underlie this agonist-selective voltage-sensitivity. This is the first demonstration of voltage-sensitive and voltage-insensitive behaviour of different agonists acting via the same receptor.     

α<Subscript>2A</Subscript>- and α<Subscript>2C</Subscript>-Adrenoceptors as Potential Targets for Dopamine and Dopamine Receptor Ligands

The poor norepinephrine innervation and high density of Gi/o-coupled α_2A- and α_2C-adrenoceptors in the striatum and the dense striatal dopamine innervation have prompted the possibility that dopamine could be an effective adrenoceptor ligand. Nevertheless, the reported adrenoceptor agonistic properties of dopamine are still inconclusive. In this study, we analyzed the binding of norepinephrine, dopamine, and several compounds reported as selective dopamine D₂-like receptor ligands, such as the D₃ receptor agonist 7-OH-PIPAT and the D₄ receptor agonist RO-105824, to α₂-adrenoceptors in cortical and striatal tissue, which express α_2A-adrenoceptors and both α_2A- and α_2C-adrenoceptors, respectively. The affinity of dopamine for α₂-adrenoceptors was found to be similar to that for D₁-like and D₂-like receptors. Moreover, the exogenous dopamine receptor ligands also showed high affinity for α_2A- and α_2C-adrenoceptors. Their ability to activate Gi/o proteins through α_2A- and α_2C-adrenoceptors was also analyzed in transfected cells with bioluminescent resonance energy transfer techniques. The relative ligand potencies and efficacies were dependent on the Gi/o protein subtype. Furthermore, dopamine binding to α₂-adrenoceptors was functional, inducing changes in dynamic mass redistribution, adenylyl cyclase activity, and ERK1/2 phosphorylation. Binding events were further studied with computer modeling of ligand docking. Docking of dopamine at α_2A- and α_2C-adrenoceptors was nearly identical to its binding to the crystallized D₃ receptor. Therefore, we provide conclusive evidence that α_2A- and α_2C-adrenoceptors are functional receptors for norepinephrine, dopamine, and other previously assumed selective D₂-like receptor ligands, which calls for revisiting previous studies with those ligands.