3- and 4-O-sulfoconjugated and methylated dopamine: highly reduced binding affinity to dopamine D2 receptors in rat striatal membranes

Summary The binding properties of 3- and 4-O-sulfoconjugated dopamine (DA-3-0-S, DA-4-0-S) as well as 3-O-methylated dopamine (MT) to rat striatal dopamine D₂ receptors were investigated. ³H-spiperone was used as a radioligand in the binding studies. In saturation binding experiments (+)butaclamol, which has been reported to bind to dopaminergic D₂ and serotoninergic 5HT₂ receptors, was used in conjunction with ketanserin and sulpiride, which preferentially label 5HT₂ and D₂ receptors, respectively, in order to discriminate between ³H-spiperone binding to D₂ and to 5HT₂ receptors. Under our particular membrane preparation and assay conditions, ³H-spiperone binds to D₂ and 5HT₂ receptors with a maximal binding capacity (B_max) of 340 fmol/mg protein in proportions of about 75%:25% with similar dissociation constants K_D (35 pmol/l; 43 pmol/l). This result was verified by the biphasic competition curve of ketanserin, which revealed about 20% high (K_D = 24 nmol/l) and 80% low (K_D = 420 nmol/l) affinity binding sites corresponding to 5HT₂ and D₂ receptors, respectively. Therefore, all further competition experiments at a tracer concentration of 50 pmol/l were performed in the presence of 0.1 mol/l ketanserin to mask the 5HT₂ receptors. DA competition curves were best fitted assuming two binding sites, with high (K_H = 0.12 mol/l) and low (K_L = 18 mol/l) affinity, present in a ratio of 3:1. The high affinity binding sites were interconvertible by 100 mol/l guanyl-5-yl imidodiphosphate [Gpp(NH)p], resulting in a homogenous affinity state of DA receptors (K_D = 2.8 mol/l). Competition experiments with various compounds confirmed the binding of ³H-spiperone to D₂ receptors. DA-3-O-S, DA-4-O-S, and MT were more than 5,000-, more than 10,000-, and 530-fold less potent in competing for ³H-spiperone binding when compared with DA at the high affinity binding site which mediates biological effects. Therefore, it is concluded that these DA metabolites are biologically ineffective at central D₂ receptors.Send offprint requests to E. Werle at the above address