th DA-S and DA can reach the adipocytes via the circulation, from infiltrating lymphocytes/macrophages, and from local sympathetic nerve endings. Lysosomal ARSA is secreted into the adjacent extracellular space where it can de-conjugate DA-S, enabling binding of free DA to its receptors. It is unlikely that adipocytes convert DA to NE, as this requires not only DA internalization, but also expression of dopamine beta hydroxylase, which is presumably specific to secretory granules within neurons and adrenal chromaffin cells. Activation of D2R by DA inhibits AC and MedChemExpress TSU 68 suppresses intracellular cAMP. This leads to inactivation of PKA/CREB-responsive elements within the superdistal promoter that regulates PRL gene expression, followed by a reduction in PRL release. The actions of DA on leptin, adiponectin and IL-6 release are mediated by D1R-like receptors via signaling pathways that may include PKA, PKG, or MAPK. Our model also assume that b-AR, which are abundantly expressed in adipocytes contribute, in an unclear manner, to adipokine/cytokine release. Finally, dopaminergic altering drugs are prescribed to millions of patients with neuro-psychiatric disorders. Many of these drugs cause excessive weight gain, alter metabolic homeostasis and increase the risk of death from cardiovascular disease. These effects have been solely attributed to the action of these drugs within the brain. The data reported here should inspire the reassessment of undesirable side effects of antipsychotics, by considering their ability to directly affect adipocyte functions that can lead “23303071 to weight gain or changes in lipid metabolism and circulating adipokines. Author Contributions Conceived and designed the experiments: DCB ERH NBJ. Performed the experiments: DCB ERH GI ADS NWR. Analyzed the data: DCB ERH GI. Contributed reagents/materials/analysis tools: JL. Wrote the paper: DCB NBJ. 9 September 2011 | Volume 6 | Issue 9 | e25537 Dopamine Receptors in Human Adipocytes 8. Amenta F, Ricci A, Tayebati SK, Zaccheo D The peripheral dopaminergic system: morphological analysis, functional and clinical applications. ” Ital J Anat Embryol 107: 145167. 9. Ben-Jonathan N, Hnasko R Dopamine as a prolactin inhibitor. Endocr Rev 22: 724763. 10. Ben-Jonathan N, Mershon JL, Allen DL, Steinmetz RW Extrapituitary prolactin: distribution, regulation, functions, and clinical aspects. Endocr Rev 17: 639669. 11. Zinger M, McFarland M, Ben-Jonathan N Prolactin expression and secretion by human breast glandular and adipose tissue explants. J Clin Endocrinol Metab 88: 689696. 12. Brandebourg TD, Hugo ER, Ben-Jonathan N Adipocyte prolactin: regulation of release and putative functions. Diabetes,Obesity and Metabolism 9: 364377. 13. Hugo ER, Borcherding DC, Gersin KS, Loftus J, Ben-Jonathan N Prolactin release by adipose explants, primary adipocytes, and LS14 adipocytes. J Clin Endocrinol Metab 93: 40064012. 14. Ben-Jonathan N Dopamine: a prolactin-inhibiting hormone. Endocr Rev 6: 564589. 15. Nisoli E, Tonello C, Memo M, Carruba MO Biochemical and functional identification of a novel dopamine receptor subtype in rat brown adipose tissue. Its role in modulating sympathetic stimulation-induced thermogenesis. J Pharmacol Exp Ther 263: 823829. 16. Goldstein DS, Eisenhofer G, Kopin IJ Sources and significance of plasma levels of catechols and their metabolites in humans. J Pharmacol Exp Ther 305: 800811. 17. Goldstein DS, Swoboda KJ, Miles JM, Coppack SW, Aneman A, et al. Sources and physiological s
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