Abstract
Class A G-protein-coupled receptors (GPCRs) influence virtually every aspect of human physiology. Understanding receptor activation mechanism is critical for discovering novel therapeutics since about one-third of all marketed drugs target members of this family. GPCR activation is an allosteric process that couples agonist binding to G-protein recruitment, with the hallmark outward movement of transmembrane helix 6 (TM6). However, what leads to TM6 movement and the key residue level changes of this movement remain less well understood. Here, we report a framework to quantify conformational changes. By analyzing the conformational changes in 234 structures from 45 class A GPCRs, we discovered a common GPCR activation pathway comprising of 34 residue pairs and 35 residues. The pathway unifies previous findings into a common activation mechanism and strings together the scattered key motifs such as CWxP, DRY, Na+ pocket, NPxxY and PIF, thereby directly linking the bottom of ligand-binding pocket with G-protein coupling region. Site-directed mutagenesis experiments support this proposition and reveal that rational mutations of residues in this pathway can be used to obtain receptors that are constitutively active or inactive. The common activation pathway provides the mechanistic interpretation of constitutively activating, inactivating and disease mutations. As a module responsible for activation, the common pathway allows for decoupling of the evolution of the ligand binding site and G-protein-binding region. Such an architecture might have facilitated GPCRs to emerge as a highly successful family of proteins for signal transduction in nature.
Highlights
As the largest and most diverse group of membrane receptors in eukaryotes, G-protein-coupled receptors (GPCRs) mediate a wide variety of physiological functions (Lagerstrom and Schioth, 2008; Rosenbaum et al, 2009; Katritch et al, 2012; Venkatakrishnan et al, 2013; Katritch et al, 2013), including vision, olfaction, taste, neurotransmission, endocrine and immune responses via more than 800 family members, and are involved in many diseases
We developed an approach to rigorously quantify residue contacts in proteins structures and infer statistically significant conformational changes
Quantitative residue contact descriptor, residue-residue contact score (RRCS), and a family-wide comparison across 234 structures from 45 class A GPCRs, we reveal a common activation pathway that directly links ligand-binding pocket and G-protein-coupling region
Summary
As the largest and most diverse group of membrane receptors in eukaryotes, GPCRs mediate a wide variety of physiological functions (Lagerstrom and Schioth, 2008; Rosenbaum et al, 2009; Katritch et al, 2012; Venkatakrishnan et al, 2013; Katritch et al, 2013), including vision, olfaction, taste, neurotransmission, endocrine and immune responses via more than 800 family members, and are involved in many diseases Class A is the largest and most diverse GPCR subfamily in humans (Kolakowski, 1994; Bockaert and Pin, 1999; Fredriksson et al, 2003; Isberg et al, 2016), including 388 olfactory (Krautwurst et al, 1998; Spehr and Munger, 2009) and 286 non-olfactory receptors (PandySzekeres et al, 2018; Munk et al, 2019) (Figure 1a) They share a seven-transmembrane (7TM) helices domain, with ligand binding pocket and G-protein-binding region located in the extracellular and intracellular ends of the helix bundle.
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