Abstract

Allosteric modulation of metabotropic glutamate receptor subtype 1 (mGlu₁) represents a viable therapeutic target for treating numerous central nervous system disorders. Although multiple chemically distinct mGlu₁ positive (PAMs) and negative (NAMs) allosteric modulators have been identified, drug discovery paradigms have not included rigorous pharmacological analysis. In the present study, we hypothesized that existing mGlu₁ allosteric modulators possess unappreciated probe-dependent or biased pharmacology. Using human embryonic kidney 293 (HEK293A) cells stably expressing human mGlu_1, we screened mGlu₁ PAMs and NAMs from divergent chemical scaffolds for modulation of different mGlu₁ orthosteric agonists in intracellular calcium (iCa²⁺) mobilization and inositol monophosphate (IP₁) accumulation assays. Operational models of agonism and allosterism were used to derive estimates for important pharmacological parameters such as affinity, efficacy, and cooperativity. Modulation of glutamate and quisqualate-mediated iCa²⁺ mobilization revealed probe dependence at the level of affinity and cooperativity for both mGlu₁ PAMs and NAMs. We also identified the previously described mGlu₅ selective NAM PF-06462894 as an mGlu₁ NAM with a different pharmacological profile from other NAMs. Differential profiles were also observed when comparing ligand pharmacology between iCa²⁺ mobilization and IP₁ accumulation. The PAMs Ro67-4853 and CPPHA displayed apparent negative cooperativity for modulation of quisqualate affinity, and the NAMs CPCCOEt and PF-06462894 had a marked reduction in cooperativity with quisqualate in IP₁ accumulation and upon extended incubation in iCa²⁺ mobilization assays. These data highlight the importance of rigorous assessment of mGlu₁ modulator pharmacology to inform future drug discovery programs for mGlu₁ allosteric modulators.