Efforts Toward GPR88 Deorphanization: Challenges and Alternative Approaches to Troublesome Cell‐Based Second Messenger Assays

Abstract

G protein‐coupled receptors (GPCR) comprise a family of over 800 integral membrane proteins involved in signal transduction and serve as the primary cellular sensors for chemical stimuli. About 35% of current drugs act on GPCR targets. In addition, of the 300 agents in current clinical trials, greater than 20% target novel GPCRs for which there are no approved drugs (orphan GPCRs). Ligand discovery and deorphanization efforts seeking to assign function to understudied GPCRs are not trivial. Notoriously complex in nature, GPCR‐dependent signaling centers around receptor‐ligand interactions that serve to stabilize conformational access to intracellular signaling partners, G proteins. In GPCR signaling, receptors and heterotrimeric G proteins (made of the Gα and Gβγ subunits) work together to transmit signals via downstream effectors and distinct pathways. The measurement of GPCR mediated second messengers such as cyclic AMP (cAMP), intracellular calcium (Ca2+) mobilization, and ERK activation (MAP kinase) are commonly used as tools to detect ligand induced GPCR activation. However, experimental pathway elucidation is complicated by the tendencies for pathway crosstalk, receptor desensitization, and receptor‐G protein interaction promiscuity. Cell‐based assays that monitor second messenger responses are often used as screening tools for potential GPCR agonists and antagonists, however, commonly used cell‐lines such as HEK‐293, express many endogenous GPCRs that can complicate data analysis. Many classes of Gα subunits exist: Gαs and Gα i/o G‐proteins modulate cyclic AMP (cAMP) through stimulation or inhibition of adenylate cyclase while Gαq subunits activate phospholipase C and a subsequent rapid release of intracellular Ca2+. Specifically, the orphan receptor, GPR88, has been linked with psychiatric diseases including schizophrenia and bipolar disorder. Lacking a validated endogenous agonist, the GPR88 signaling pathway remains poorly understood, however, in vivo knockout experiments and in vitro preclinical studies with small molecule synthetic agonists indicate that GPR88 couples to Gαi/o G‐proteins to inhibit adenylate cyclase activity and reduce intracellular cAMP in cell‐based assays. In this work, we describe our challenges in the study of the GPR88 signaling pathway using second messenger cell‐based assays and explain our decision to move to a real‐time NanoLuc‐based GPCR/G protein complementation assay.Support or Funding InformationNIH grant 1 R15 MH109034