Pancreatic Endocrine Effects of Dopamine Receptors in Human Islet Cells.

OBJECTIVE: To date, there are no reports on the cellular localization of dopamine receptors in the human pancreas. In our study, we determined the localization and expression of 5 dopamine receptors (D(1), D(2), D(3), D(4), and D(5)) in normal human pancreas tissue. METHODS: Human nonpathological pancreas tissues were fixed with 4% paraformaldehyde, paraffin-embedded, and processed for immunohistochemical analysis to detect dopamine receptors in the human pancreas tissue by using double immunofluorescent labeling and confocal microscopy. RESULTS: We found that the D(1) receptor is present in ß cells; the D(2) receptor is expressed by α, δ, and pancreatic polypeptide cells; the D(4) receptor is expressed by ß and polypeptide cells; whereas the D(5) receptor is expressed only by δ cells. CONCLUSIONS: Our results identify the dopamine receptors (D(1)-D(5)) in normal pancreas tissue and provide a morphological basis for studying the pancreatic endocrine effects of dopamine and suggest a new target for the clinical treatment of diabetes.

Upregulation of renal D5 dopamine receptor ameliorates the hypertension in D3 dopamine receptor-deficient mice.

D3 dopamine receptor (D3R)-deficient mice have renin-dependent hypertension associated with sodium retention, but the hypertension is mild. To determine whether any compensatory mechanisms in the kidney are involved in the regulation of blood pressure with disruption of Drd3, we measured the renal protein expression of all dopamine receptor subtypes (D1R, D2R, D4R, and D5R) in D3R homozygous (D3(-/-)) and heterozygous (D3(+/-)) knockout mice and their wild-type (D3(+/+)) littermates. The renal immunohistochemistry and protein expression of D5R were increased (n=5/group) in D3(-/-) mice; renal D4R protein expression was decreased, whereas renal protein expressions of D1R and D2R were similar in both groups. Renal D5R protein expression was also increased in D3(+/-) (n=5/group) relative to D3(+/+) mice, whereas D1R, D2R, and D4R protein expressions were similar in D3(+/-) and D3(+/+) mice. The increase in renal D5R protein expression was abolished when D3(-/-) mice were fed a high-salt diet. Treatment with the D1-like receptor antagonist, SCH23390, increased the blood pressure in anesthetized D3(-/-) but not D3(+/+) mice (n=4/group), suggesting that the renal upregulation of D5R may have minimized the hypertension in D3(-/-) mice. The renal D5R protein upregulation was not caused by increased transcription because renal mRNA expression of D5R was similar in D3(-/-) and D3(+/+) mice. Our findings suggest that the renal upregulation of D5R may have minimized the hypertension that developed in D3(-/-) mice.

Dopamine D5 receptors are localized at asymmetric synapses in the rat hippocampus.

Functional studies indicate that the dopamine D5 receptor is involved in synaptic transmission in the hippocampus. However, previous anatomical studies have detected D5 receptor labelling primarily on the soma and main dendrites of CA1 pyramidal cells and on dendritic spines in monkey but not in rats. In order to get a better understanding of putative dopamine function in the hippocampus, we quantified the D5 receptor immunoreactivity on the pyramidal cell somas and on spines and dendrites in stratum radiatum and stratum oriens in the hippocampal CA1 region of rats by quantitative immunofluorescence and immunogold electron microscopy. The quantitative immunogold results revealed a higher labelling density on dendritic spines, notably at their synaptic membranes, compared to pyramidal cell somas and dendrites. Hence, dopamine could have effects on spines as well as on somas and dendrites. The labelling density was similar on spines in stratum oriens and stratum radiatum, but the presence of labelling varied between the spines within each stratum, indicating that the effect of dopamine could be diverse between different spines.

Dopamine receptor subtypes in the native human heart.

The present study first time detected D1-D5 dopamine receptor subtypes in the native human heart simultaneously, found presence of D1, D2, D4, and D5 in cardiac tissues, and revealed distribution features of dopamine receptor subtypes in the epicardium, myocardium, and endocardium. Samples from four native hearts coming from young brain-dead donors, which for technical reason were not used for transplants, were studied. Dopamine receptors were revealed by immunochemistry technique and immunoblot analysis. Morphometrical quantification of the density of each receptor subtype was performed by an image analyzer. Our results demonstrate that only four subtypes of dopamine receptors can be found in cardiac tissues: D1, D2, D4, and D5. These dopamine receptors have been detected in endocardium, myocardium, and epicardium. D1 receptors were stored primarily in the epicardial layer. Dopamine receptors are distributed in the wall of both atria and ventricles, and its transmural gradient can be described in the wall of the human heart. Sections of atria and ventricles exposed to antidopamine receptor antibodies showed fluorescent-positive reaction in the epicardium, myocardium and endocardium. D4 receptor immune reactivity was remarkably less intense than D2 receptor immune reactivity. All the subtypes of dopamine receptors are in close relationships with all cardiac structures. Our findings provide a favorable basis for researching the role of dopamine receptors in controlling functions of the human heart and in the pathogenesis of cardiovascular diseases.

Should we be cautious on the use of commercially available antibodies to dopamine receptors?

Evidence indicate that it is difficult to obtain specific antibodies to G protein-coupled receptors and different technical difficulties may allow the generation of antibodies that lack specificity. We conducted experiments to validate the specificity of commercially available antibodies raised against dopamine (DA) receptors hD(1), hD(4), and hD(5) using a transfection approach: we studied whether, in HEK 293 cells selectively transfected with the various cloned subtypes, each antibody generates bands only in cells expressing its cognate receptor but not in those expressing the other DA receptors. Our results demonstrated that hD(1) and hD(4) receptor antibodies recognize not only their respective epitope, but also other DA receptor subtypes, while for the hD(5) receptor detection, we observed a signal only in the lane loaded with hD(5)-transfected HEK 293 cells, although with a lack of purity. Therefore, we recommend caution on the use of commercially available DA receptor antibodies.