Rules of Engagement: GPCRs and G Proteins.

G protein-coupled receptors (GPCRs) are a key drug target class. They account for over one-third of current pharmaceuticals, and both drugs that inhibit and promote receptor function are important therapeutically; in some cases, the same GPCR can be targeted with agonists and inhibitors, depending upon disease context. There have been major breakthroughs in understanding GPCR structure and drug binding through advances in X-ray crystallography, and membrane protein stabilization. Nonetheless, these structures have predominately been of inactive receptors bound to inhibitors. Efforts to capture structures of fully active GPCRs, in particular those in complex with the canonical, physiological transducer G protein, have been limited via this approach. Very recently, advances in cryo-electron microscopy have provided access to agonist:GPCR:G protein complex structures. These promise to revolutionize our understanding of GPCR:G protein engagement and provide insight into mechanisms of efficacy and coupling selectivity and how these might be controlled by biased agonists. Here we review what we have currently learned from the new GPCR:Gs and GPCR:Gi/o complex structures.

[1]  Alec Smith,et al.  Critical Role , 2019, They Create Worlds.

[2]  W. Baumeister,et al.  Cryo-EM structure of the active, Gs-protein complexed, human CGRP receptor , 2018, Nature.

[3]  Arthur Christopoulos,et al.  Dominant Negative G Proteins Enhance Formation and Purification of Agonist-GPCR-G Protein Complexes for Structure Determination. , 2018, ACS pharmacology & translational science.

[4]  Arthur Christopoulos,et al.  Structure of the adenosine-bound human adenosine A1 receptor–Gi complex , 2018, Nature.

[5]  O. Kuybeda,et al.  Cryo-EM structure of human rhodopsin bound to an inhibitory G protein , 2018, Nature.

[6]  A. Kruse,et al.  Structural Basis for G Protein-Coupled Receptor Signaling. , 2018, Annual review of biophysics.

[7]  J. García-Nafría,et al.  Cryo-EM structure of the serotonin 5-HT1B receptor coupled to heterotrimeric Go , 2018, Nature.

[8]  Naomi R. Latorraca,et al.  Structure of the μ Opioid Receptor-Gi Protein Complex , 2018, Nature.

[9]  W. Baumeister,et al.  Phase-plate cryo-EM structure of a biased agonist-bound human GLP-1 receptor–Gs complex , 2018, Nature.

[10]  Christopher G Tate,et al.  Cryo-EM structure of the adenosine A2A receptor coupled to an engineered heterotrimeric G protein , 2018, bioRxiv.

[11]  Jiahui Chen,et al.  Improvements to the APBS biomolecular solvation software suite , 2017, Protein science : a publication of the Protein Society.

[12]  T. S. Kobilka,et al.  Cryo-EM structure of the activated GLP-1 receptor in complex with G protein , 2017, Nature.

[13]  C. Tate,et al.  Mini-G proteins: Novel tools for studying GPCRs in their active conformation , 2017, PloS one.

[14]  Arthur Christopoulos,et al.  Phase-plate cryo-EM structure of a class B GPCR-G protein complex , 2017, Nature.

[15]  Arthur Christopoulos,et al.  Structure of the Adenosine A1 Receptor Reveals the Basis for Subtype Selectivity , 2017, Cell.

[16]  R. Sunahara,et al.  Mechanistic insights into GPCR-G protein interactions. , 2016, Current opinion in structural biology.

[17]  P. Sexton,et al.  Ligand-Dependent Modulation of G Protein Conformation Alters Drug Efficacy , 2016, Cell.

[18]  C. Tate,et al.  Engineering a minimal G protein to facilitate crystallisation of G protein-coupled receptors in their active conformation , 2016, Protein engineering, design & selection : PEDS.

[19]  R. Dey,et al.  Regulation, Signaling, and Physiological Functions of G-Proteins. , 2016, Journal of molecular biology.

[20]  A. Leslie,et al.  Structure of the adenosine A2A receptor bound to an engineered G protein , 2016, Nature.

[21]  B. Kobilka,et al.  Allosteric regulation of G protein-coupled receptor activity by phospholipids. , 2016, Nature chemical biology.

[22]  A. J. Venkatakrishnan,et al.  Universal allosteric mechanism for Gα activation by GPCRs , 2015, Nature.

[23]  Stephen M. Husbands,et al.  Structural insights into μ-opioid receptor activation , 2015, Nature.

[24]  Ron O. Dror,et al.  Structural basis for nucleotide exchange in heterotrimeric G proteins , 2015, Science.

[25]  A. J. Venkatakrishnan,et al.  Structural basis for chemokine recognition and activation of a viral G protein–coupled receptor , 2014, Science.

[26]  Garth J. Williams,et al.  Crystal structure of rhodopsin bound to arrestin by femtosecond X-ray laser , 2014, Nature.

[27]  Helmut Grubmüller,et al.  Position of transmembrane helix 6 determines receptor G protein coupling specificity. , 2014, Journal of the American Chemical Society.

[28]  H. Hamm,et al.  A Conserved Phenylalanine as a Relay between the α5 Helix and the GDP Binding Region of Heterotrimeric Gi Protein α Subunit* , 2014, The Journal of Biological Chemistry.

[29]  W. Kühlbrandt The Resolution Revolution , 2014, Science.

[30]  I. Dickerson Role of CGRP-receptor component protein (RCP) in CLR/RAMP function. , 2013, Current protein & peptide science.

[31]  Chris de Graaf,et al.  Structure of the human glucagon class B G-protein-coupled receptor , 2013, Nature.

[32]  Hualiang Jiang,et al.  Structural Basis for Molecular Recognition at Serotonin Receptors , 2013, Science.

[33]  Philippe Roche,et al.  2P2Idb: a structural database dedicated to orthosteric modulation of protein–protein interactions , 2012, Nucleic Acids Res..

[34]  Quincy Teng,et al.  Structural Biology , 2013, Springer US.

[35]  R. Stevens,et al.  Structural Basis for Allosteric Regulation of GPCRs by Sodium Ions , 2012, Science.

[36]  L. Pardo,et al.  Crystal structure of the μ-opioid receptor bound to a morphinan antagonist , 2012, Nature.

[37]  R. Ghirlando,et al.  Modulation of the interaction between neurotensin receptor NTS1 and Gq protein by lipid. , 2012, Journal of molecular biology.

[38]  A. Mushegian,et al.  G protein-coupled receptor kinases: more than just kinases and not only for GPCRs. , 2012, Pharmacology & therapeutics.

[39]  Virgil L. Woods,et al.  Conformational changes in the G protein Gs induced by the β2 adrenergic receptor , 2011, Nature.

[40]  Tong Liu,et al.  Structural flexibility of the Gαs α-helical domain in the β2-adrenoceptor Gs complex , 2011, Proceedings of the National Academy of Sciences.

[41]  S. Rasmussen,et al.  Crystal Structure of the β2Adrenergic Receptor-Gs protein complex , 2011, Nature.

[42]  A. Leslie,et al.  Agonist-bound adenosine A2A receptor structures reveal common features of GPCR activation , 2011, Nature.

[43]  P. Sexton,et al.  Determination of Adenosine A1 Receptor Agonist and Antagonist Pharmacology Using Saccharomyces cerevisiae: Implications for Ligand Screening and Functional Selectivity , 2009, Journal of Pharmacology and Experimental Therapeutics.

[44]  K. Palczewski,et al.  Phospholipids are needed for the proper formation, stability, and function of the photoactivated rhodopsin-transducin complex. , 2009, Biochemistry.

[45]  P. Escribá,et al.  Membrane interactions of G proteins and other related proteins. , 2008, Biochimica et biophysica acta.

[46]  R. Stevens,et al.  GPCR Engineering Yields High-Resolution Structural Insights into β2-Adrenergic Receptor Function , 2007, Science.

[47]  P. Sexton,et al.  A Critical Role for the Short Intracellular C Terminus in Receptor Activity-Modifying Protein Function , 2006, Molecular Pharmacology.

[48]  P. Sexton,et al.  Distinct Receptor Activity-Modifying Protein Domains Differentially Modulate Interaction with Calcitonin Receptors , 2006, Molecular Pharmacology.

[49]  Marcus Elstner,et al.  The retinal conformation and its environment in rhodopsin in light of a new 2.2 A crystal structure. , 2004, Journal of molecular biology.

[50]  Hyunsu Bae,et al.  Closely Related G-protein-coupled Receptors Use Multiple and Distinct Domains on G-protein α-Subunits for Selective Coupling* , 2003, Journal of Biological Chemistry.

[51]  C. Berlot A Highly Effective Dominant Negative αs Construct Containing Mutations That Affect Distinct Functions Inhibits Multiple Gs-coupled Receptor Signaling Pathways* , 2002, The Journal of Biological Chemistry.

[52]  R. Lefkowitz,et al.  The role of beta-arrestins in the termination and transduction of G-protein-coupled receptor signals. , 2002, Journal of cell science.

[53]  Ethan Lee,et al.  The G226A Mutant of G, Highlights the Requirement for Dissociation of G Protein Subunits* , 2001 .

[54]  C. Berlot,et al.  A surface-exposed region of G(salpha) in which substitutions decrease receptor-mediated activation and increase receptor affinity. , 2000, Molecular pharmacology.

[55]  M. Marzioch,et al.  Functional coupling of mammalian receptors to the yeast mating pathway using novel yeast/mammalian G protein α‐subunit chimeras , 2000, Yeast.

[56]  N. Artemyev,et al.  Roles of the Transducin α-Subunit α4-Helix/α4-β6 Loop in the Receptor and Effector Interactions* , 1999, The Journal of Biological Chemistry.

[57]  J. Cleator,et al.  The N54 mutant of Gαs has a conditional dominant negative phenotype which suppresses hormone‐stimulated but not basal cAMP levels , 1999, FEBS letters.

[58]  H. Bourne,et al.  A Gsalpha mutant designed to inhibit receptor signaling through Gs. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[59]  N. Artemyev,et al.  Roles of the transducin alpha-subunit alpha4-helix/alpha4-beta6 loop in the receptor and effector interactions. , 1999, The Journal of biological chemistry.

[60]  W. Sadee,et al.  Hydrophobic amino acid in the i2 loop plays a key role in receptor-G protein coupling. , 1993, The Journal of biological chemistry.

[61]  B. Conklin,et al.  Substitution of three amino acids switches receptor specificity of Gqα to that of Giα , 1993, Nature.

[62]  N. J. Gibson,et al.  Lipid headgroup and acyl chain composition modulate the MI-MII equilibrium of rhodopsin in recombinant membranes. , 1993, Biochemistry.

[63]  B. Conklin,et al.  Substitution of three amino acids switches receptor specificity of Gq alpha to that of Gi alpha. , 1993, Nature.

[64]  R. Taussig,et al.  The G226A mutant of Gs alpha highlights the requirement for dissociation of G protein subunits. , 1992, The Journal of biological chemistry.

[65]  H. Bourne,et al.  Identification of effector-activating residues of Gs alpha. , 1992, Cell.