Pharmacologic methods for identification of receptors.

Determinations of apparent equilibrium dissociation constants of drug-receptor interactions are made from both functional and radioligand binding studies. In each type of study, reversible reactions are assumed and the mass action law is applied. Functional studies are frequently used to determine the dissociation constant of a competitive antagonist but are less frequently used to obtain this constant for agonist compounds since the latter determination requires an experimental procedure that irreversibly inactivates a fraction of the receptors. In the present report, values of dissociation constant for prototype agonists and antagonists, determined from binding and from functional studies, are examined in two classical isolated preparations, rabbit aorta and guinea-pig ileum. In each preparation the dissociation constants from binding and functional experiments agree well for the antagonists but differ markedly for the agonists. Further, the dissociation constant values from binding are seen to be greater for the agonists than for the antagonists. When a chronic treatment regimen in the rabbit resulted in a pronounced change in the functional dissociation constant of subsequently administered norepinephrine, there was no significant change in either the binding constant of this agonist or in the pA2 value of the alpha antagonist, phentolamine. These, and the previously described results, are shown to be compatible with a simple two-state receptor model in which agonists bind with high and low affinity to each state while antagonists do not distinguish between the states. In this model, the ratio of low to high affinity states accounts for the failure of the binding procedure to detect changes in the agonists dissociation constant that are highly significant in the functional study. Whereas the model is based on data for these two classical preparations only, and may not be more generally applicable, the findings demonstrate the necessity for employing both functional and radioligand binding experiments when characterizing drug receptors.