Thermodynamic analysis of antagonist and agonist interactions with dopamine receptor

Abstract

The binding of [ 3H]spiperone to dopamine D-2 receptors and its inhibition by antagonists and agoniste were examined in microsomes derived from die sheep caudate nucleus, at temperatures between 37 and 1°C, and the thermodynamic parameters of the binding were evaluated. The affinity of the receptor for the antagonists, spiperone and (+)-butaclamol, decreased as the incubation temperature decreased; the affinity for haloperidol did not further decrease at temperatures below 15°C. The binding of the antagonists was associated with very large increases in entropy, as expected for hydrophobic interactions. The enthalpy and entropy changes associated with halopsridol binding were dependent on temperature, in contrast to those associated with spiperone and (+)-butaclamol. The magnitude of the entropy increase associated with the specific binding of the antagonists did not correlate with the degree of lipophilicity of these drugs. The data suggest that, in addition to hydrophobic forces, other forces are also involved in the antagonist-dopamiae receptor interactions, and that a conformational change of the receptor could occur when the antagonist binds. Agonist binding data are consistent with a two-state model of the receptor, a high-affinity state (R H) and a low-affinity state (R l). The affinity of dopamine binding to the R h decreased with decreasing temperatures below 20°C, whereas the affinity for the R l increased at low temperatures. In contrast, the affinity of apomorphine for both states of the receptor decreased as the temperature decreased from 30 to 8°C. A clear distinction between the energetics of high-affinity and low-affinity agonist binding was observed. The formation of the high-affinity complex was associated with larger increases in enthalpy and entropy than the interaction with the low-affinity state was. The results suggest that the interaction of the receptor with the G-proteins, induced or stabilized by the binding of agonist, leads to an increase in entropy and to négative heat capacity changes in the system.