Risperidone-induced inactivation and clozapine-induced reactivation of rat cortical astrocyte 5-hydroxytryptamine₇ receptors: evidence for in situ G protein-coupled receptor homodimer protomer cross-talk.

We have reported previously novel drug-induced inactivation and reactivation of human 5-hydroxytryptamine₇ (5-HT₇) receptors in a recombinant cell line. To explain these novel observations, a homodimer structure displaying protomer-protomer cross-talk was proposed. To determine whether these novel observations and interpretations are due to an artifactual G protein-coupled receptor (GPCR) mechanism unique to the recombinant cell line, we explored the properties of r5-HT₇ receptors expressed by cortical astrocytes in primary culture. As in the recombinant cell line, risperidone, 9-OH-risperidone, methiothepin, and bromocriptine were found to potently inactivate r5-HT₇ receptors. As in the recombinant cell line, exposure of risperidone-inactivated astrocyte r5-HT₇ receptors to competitive antagonists resulted in the reactivation of r5-HT₇ receptors. The potencies of the reactivating drugs closely correlated with their affinities for h5-HT₇ receptors. These results indicate the novel inactivating and reactivating property of drugs is not due to an artifact of the recombinant cell line expressing h5-HT₇ receptors but is an intrinsic property of 5-HT₇ receptors in vitro and ex vivo. This evidence suggests that a native (nonmutated) GPCR, in its native membrane environment (cortical astrocyte primary culture), can function as a homodimer with protomer-protomer cross-talk. Homodimers may be a common GPCR structure. The experimental design used in our studies can be used to explore the properties of other GPCRs in their native forms in recombinant cells, primary cultures expressing the endogenous GPCRs, and possibly in vivo. The homodimer structure and protomer-protomer cross-talk offer new avenues of research into receptor dysfunction in disease states and the development of novel drugs.