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.

Clozapine and other competitive antagonists reactivate risperidone-inactivated h5-HT7 receptors: radioligand binding and functional evidence for GPCR homodimer protomer interactions.

RATIONALE: The h5-HT(7) receptor is subject to inactivation by risperidone and 9-OH-risperidone, apparently through a pseudo-irreversible complex formed between these drugs and the receptor. Although risperidone and 9-OH-risperidone ("inactivating antagonists") completely inactivate the receptor, only 50% of the receptors form a pseudo-irreversible complex with these drugs. OBJECTIVES: This study aims to more fully determine the mechanism(s) responsible for the novel effects of risperidone and 9-OH-risperidone and to determine if the inactivation can be reversed (reactivation). METHODS: The ability of non-inactivating drugs (competitive antagonists) to dissociate wash-resistant [(3)H]risperidone binding from h5-HT(7) receptors was investigated. Also, the ability of non-inactivating drugs to reactivate inactivated h5-HT(7) receptors was investigated, using cAMP accumulation as a functional endpoint. RESULTS: The competitive (non-inactivating) antagonists clozapine and mesulergine released the wash-resistant [(3)H]risperidone binding to the h5-HT(7) receptor. The competitive antagonists clozapine, SB269970, mianserin, cyproheptadine, mesulergine, and ICI169369 reactivated the risperidone-inactivated h5-HT(7) receptors in a concentration-dependent manner. The potencies for reactivation closely match the affinities of these drugs for the h5-HT(7) receptor (r(2) = 0.95), indicating that the reactivating antagonists are binding to and producing their effects through the orthosteric binding site of the h5-HT(7) receptor. Bioluminescence resonance energy transfer analyses indicate that the h5-HT(7) receptor forms homodimers. CONCLUSIONS: The ability of the non-inactivating drugs to bind h5-HT(7) orthosteric sites and reverse the wash-resistant effects of risperidone or 9-OH-risperidone, also bound to h5-HT(7) orthosteric sites, is evidence for protomer-protomer interactions between h5-HT(7) homodimers. This is the first demonstration of a non-mutated G-protein-coupled receptor homodimer engaging in protomer-protomer interactions in an intact cell preparation.

Pharmacological analysis of the novel, rapid, and potent inactivation of the human 5-Hydroxytryptamine7 receptor by risperidone, 9-OH-Risperidone, and other inactivating antagonists.

In a previous publication, using human 5-hydroxytryptamine(7) (h5-HT(7)) receptor-expressing human embryonic kidney (HEK) 293 cells, we reported the rapid, potent inactivation of the h5-HT(7) receptor stimulation of cAMP production by three antagonists: risperidone, 9-OH-risperidone, and methiothepin (Smith et al., 2006). To better understand the drug-receptor interaction producing the inactivation, we 1) expanded the list of inactivating drugs, 2) determined the inactivating potencies and efficacies by performing concentration-response experiments, and 3) determined the potencies and efficacies of the inactivators as irreversible binding site inhibitors. Three new drugs were found to fully inactivate the h5-HT(7) receptor: lisuride, bromocryptine, and metergoline. As inactivators, these drugs displayed potencies of 1, 80, and 321 nM, respectively. Pretreatment of 5-HT(7)-expressing HEK cells with increasing concentrations of the inactivating drugs risperidone, 9-OH-risperidone, methiothepin, lisuride, bromocriptine, and metergoline potently inhibited radiolabeling of the h5-HT(7) receptor, with IC(50) values of 9, 5.5, 152, 3, 73, and 10 nM, respectively. We were surprised to find that maximal concentrations of risperidone and 9-OH-risperidone inhibited only 50% of the radiolabeling of h5-HT(7) receptors. These results indicate that risperidone and 9-OH risperidone may be producing 5-HT(7) receptor inactivation by different mechanisms than lisuride, bromocryptine, metergoline, and methiothepin. These results are not interpretable using the conventional model of G-protein-coupled receptor function. The complex seems capable of assuming a stable inactive conformation as a result of the interaction of certain antagonists. The rapid, potent inactivation of the receptor-G-protein complex by antagonists implies a constitutive, pre-existing complex between the h5-HT(7) receptor and a G-protein.