Marjorie Damian

Asymmetric conformational changes in a GPCR dimer controlled by G-proteins

G‐protein‐coupled receptors (GPCRs) are key players in cell communication. Although long considered as monomeric, it now appears that these heptahelical proteins can form homo‐ or heterodimers. Here, we analyzed the conformational changes in each subunit of a receptor dimer resulting from agonist binding to either one or both subunits by measuring the fluorescent properties of a leukotriene B4 receptor dimer with a single 5‐hydroxytryptophan‐labeled protomer. We show that a receptor dimer with only a single agonist‐occupied subunit can trigger G‐protein activation. We also show that the two subunits of the receptor dimer in the G‐protein‐coupled state differ in their conformation, even when both are liganded by the agonist. No such asymmetric conformational changes are observed in the absence of G‐protein, indicating that the interaction of the G‐protein with the receptor dimer brings specific constraints that prevent a symmetric functioning of this dimer. These data open new options for the differential signaling properties of GPCR dimers.

Structural insights into biased G protein-coupled receptor signaling revealed by fluorescence spectroscopy

G protein-coupled receptors (GPCRs) are seven-transmembrane proteins that mediate most cellular responses to hormones and neurotransmitters, representing the largest group of therapeutic targets. Recent studies show that some GPCRs signal through both G protein and arrestin pathways in a ligand-specific manner. Ligands that direct signaling through a specific pathway are known as biased ligands. The arginine-vasopressin type 2 receptor (V2R), a prototypical peptide-activated GPCR, is an ideal model system to investigate the structural basis of biased signaling. Although the native hormone arginine-vasopressin leads to activation of both the stimulatory G protein (Gs) for the adenylyl cyclase and arrestin pathways, synthetic ligands exhibit highly biased signaling through either Gs alone or arrestin alone. We used purified V2R stabilized in neutral amphipols and developed fluorescence-based assays to investigate the structural basis of biased signaling for the V2R. Our studies demonstrate that the Gs-biased agonist stabilizes a conformation that is distinct from that stabilized by the arrestin-biased agonists. This study provides unique insights into the structural mechanisms of GPCR activation by biased ligands that may be relevant to the design of pathway-biased drugs.

Amphipol-Assisted in Vitro Folding of G Protein-Coupled Receptors †

G protein-coupled receptors (GPCRs) regulate numerous physiological functions. The primary difficulty presented by their study in vitro is to obtain them in sufficient amounts under a functional and stable form. Escherichia coli is a host of choice for producing recombinant proteins for structural studies. However, the insertion of GPCRs into its plasma membrane usually results in bacterial death. An alternative approach consists of targeting recombinant receptors to inclusion bodies, where they accumulate without affecting bacterial growth, and then folding them in vitro. This approach, however, stumbles over the very low folding yields typically achieved, whether in detergent solutions or in detergent-lipid mixtures. Here, we show that synthetic polymers known as amphipols provide a highly efficient medium for folding GPCRs. Using a generic protocol, we have folded four class A GPCRs to their functional state, as evidenced by the binding of their respective ligands. This strategy thus appears to have the potential to be generalized to a large number of GPCRs. These data are also of interest from a more fundamental point of view: they indicate that the structural information stored in the sequence of these four receptors allows them to reach their correct three-dimensional structure in an environment that bears no similarity, beyond the amphiphilic character, to lipid bilayers.

Ligands and signaling proteins govern the conformational landscape explored by a G protein-coupled receptor.

The dynamic character of G protein-coupled receptors is essential to their function. However, the details of how ligands stabilize a particular conformation to selectively activate a signaling pathway and how signaling proteins affect this conformational repertoire remain unclear. Using a prototypical peptide-activated class A G protein-coupled receptor (GPCR), the ghrelin receptor, reconstituted as a monomer into lipid discs and labeled with a fluorescent conformational reporter, we demonstrate that ligand efficacy and functional selectivity are directly related to different receptor conformations. Of importance, our data bring direct evidence that distinct effector proteins affect the conformational landscape of the ghrelin receptor in different ways. Whereas G proteins affect the balance between active and inactive receptor substates in favor of the active state, agonist-induced arrestin recruitment is accompanied by a marked change in the structural features of the receptor that adopt a conformation different from that observed in the absence of arrestin. In contrast to G proteins and arrestins, μ-AP2 has no significant effect on the organization of the transmembrane core of the receptor. Such a modulation of a GPCR conformational landscape by pharmacologically distinct ligands and effectors provides insights into the structural bases that decisively affect ligand efficacy and subsequent biological responses. This is also likely to have major implications for the design of drugs activating specific GPCR-associated signaling pathways.

High Constitutive Activity Is an Intrinsic Feature of Ghrelin Receptor Protein A STUDY WITH A FUNCTIONAL MONOMERIC GHS-R1a RECEPTOR RECONSTITUTED IN LIPID DISCS

Background: Constitutive activity is central to G protein-coupled receptor signaling but the mechanisms underlying it are still unknown. Results: The ghrelin receptor monomer reconstituted in a lipid disc activates Gq without agonist and recruits arrestin in a ligand-dependent manner. Conclusion: High constitutive activity is an intrinsic property of the ghrelin receptor. Significance: This is the first demonstration that the ghrelin receptor has all the determinants for constitutive activity and ligand-regulated internalization. Despite its central role in signaling and the potential therapeutic applications of inverse agonists, the molecular mechanisms underlying G protein-coupled receptor (GPCR) constitutive activity remain largely to be explored. In this context, ghrelin receptor GHS-R1a is a peculiar receptor in the sense that it displays a strikingly high, physiologically relevant, constitutive activity. To identify the molecular mechanisms responsible for this high constitutive activity, we have reconstituted a purified GHS-R1a monomer in a lipid disc. Using this reconstituted system, we show that the isolated ghrelin receptor per se activates Gq in the absence of agonist, as assessed through guanosine 5′-O-(thiotriphosphate) binding experiments. The measured constitutive activity is similar in its extent to that observed in heterologous systems and in vivo. This is the first direct evidence for the high constitutive activity of the ghrelin receptor being an intrinsic property of the protein rather than the result of influence of its cellular environment. Moreover, we show that the isolated receptor in lipid discs recruits arrestin-2 in an agonist-dependent manner, whereas it interacts with μ-AP2 in the absence of ligand or in the presence of ghrelin. Of importance, these differences are linked to ligand-specific GHS-R1a conformations, as assessed by intrinsic fluorescence measurements. The distinct ligand requirements for the interaction of purified GHS-R1a with arrestin and AP2 provide a new rationale to the differences in basal and agonist-induced internalization observed in cells.

Leukotriene BLT2 receptor monomers activate the G(i2) GTP-binding protein more efficiently than dimers.

Accumulating evidence indicates that G protein-coupled receptors can assemble as dimers/oligomers but the role of this phenomenon in G protein coupling and signaling is not yet clear. We have used the purified leukotriene B4 receptor BLT2 as a model to investigate the capacity of receptor monomers and dimers to activate the adenylyl cyclase inhibitory Gi2 protein. For this, we overexpressed the recombinant receptor as inclusion bodies in the Escherichia coli prokaryotic system, using a human α5 integrin as a fusion partner. This strategy allowed the BLT2 as well as several other G protein-coupled receptors from different families to be produced and purified in large amounts. The BLT2 receptor was then successfully refolded to its native state, as measured by high-affinity LTB4 binding in the presence of the purified G protein Gαi2. The receptor dimer, in which the two protomers displayed a well defined parallel orientation as assessed by fluorescence resonance energy transfer, was then separated from the monomer. Using two methods of receptor-catalyzed guanosine 5′-3-O-(thio)triphosphate binding assay, we clearly demonstrated that monomeric BLT2 stimulates the purified Gαi2β1γ2 protein more efficiently than the dimer. These data suggest that assembly of two BLT2 protomers into a dimer results in the reduced ability to signal.

Inhibition of heterotrimeric G-protein signaling by a small molecule acting on Galpha subunit

The simultaneous activation of many distinct G protein-coupled receptors (GPCRs) and heterotrimeric G proteins play a major role in various pathological conditions. Pan-inhibition of GPCR signaling by small molecules thus represents a novel strategy to treat various diseases. To better understand such therapeutic approach, we have characterized the biomolecular target of BIM-46187, a small molecule pan-inhibitor of GPCR signaling. Combining bioluminescence and fluorescence resonance energy transfer techniques in living cells as well as in reconstituted receptor-G protein complexes, we observed that, by direct binding to the Gα subunit, BIM-46187 prevents the conformational changes of the receptor-G protein complex associated with GPCR activation. Such a binding prevents the proper interaction of receptors with the G protein heterotrimer and inhibits the agonist-promoted GDP/GTP exchange. These observations bring further evidence that inhibiting G protein activation through direct binding to the Gα subunit is feasible and should constitute a new strategy for therapeutic intervention.

G Protein Activation by the Leukotriene B4 Receptor Dimer EVIDENCE FOR AN ABSENCE OF TRANS-ACTIVATION

There is compelling evidence that G protein-coupled receptors exist as homo- and heterodimers, but the way these assemblies function at the molecular level remains unclear. We used here the purified leukotriene B4 receptor BLT1 stabilized in its dimeric state to analyze how a receptor dimer activates G proteins. For this, we produced heterodimers between the wild-type BLT1 and a BLT1/ALXR chimera. The latter is no longer activated by leukotriene B4 but is still activated by ALXR agonists. In this heterodimer, agonist binding to either one of the two protomers induced asymmetric conformational changes within the receptor dimer. Of importance, no G protein activation was observed when using a dimer where the ligand-loaded protomer was not able to trigger GDP/GTP exchange due to specific mutations in its third intracellular loop, establishing that the conformation of the agonist-free protomer is not competent for G protein activation. Taken together, these data indicate that although ligand binding to one protomer in the heterodimer is associated with cross-conformational changes, a trans-activation mechanism where the ligand-free subunit would trigger GDP/GTP exchange cannot be considered in this case for G protein activation. This observation sheds light into the way GPCR dimers, in particular heterodimers, could activate their cognate G proteins.

Detergent-free Isolation of Functional G Protein-Coupled Receptors into Nanometric Lipid Particles

G protein-coupled receptors (GPCRs) are integral membrane proteins that play a pivotal role in signal transduction. Understanding their dynamics is absolutely required to get a clear picture of how signaling proceeds. Molecular characterization of GPCRs isolated in detergents nevertheless stumbles over the deleterious effect of these compounds on receptor function and stability. We explored here the potential of a styrene-maleic acid polymer to solubilize receptors directly from their lipid environment. To this end, we used two GPCRs, the melatonin and ghrelin receptors, embedded in two membrane systems of increasing complexity, liposomes and membranes from Pichia pastoris. The styrene-maleic acid polymer was able, in both cases, to extract membrane patches of a well-defined size. GPCRs in SMA-stabilized lipid discs not only recognized their ligand but also transmitted a signal, as evidenced by their ability to activate their cognate G proteins and recruit arrestins in an agonist-dependent manner. Besides, the purified receptor in lipid discs undergoes all specific changes in conformation associated with ligand-mediated activation, as demonstrated in the case of the ghrelin receptor with fluorescent conformational reporters and compounds from distinct pharmacological classes. Altogether, these data highlight the potential of styrene-maleic stabilized lipid discs for analyzing the molecular bases of GPCR-mediated signaling in a well-controlled membrane-like environment.

Ghrelin receptor conformational dynamics regulate the transition from a preassembled to an active receptor:Gq complex

Significance G protein-coupled receptors (GPCRs), one of the largest cell surface receptor families, transmit their signals through the coupling of intracellular partners, such as the G proteins. Knowing how this coupling occurs is essential, because it governs the entire signaling process. To address this open question, we used a purified GPCR as a model to which we applied various state-of-the-art biochemical and biophysical approaches. By doing so, we provide direct experimental evidence of a signaling mechanism in which receptor conformational changes are directly linked to a rearrangement of a preassembled complex between the receptor and its cognate Gq protein. This sheds light on the way in which a GPCR interacts with G proteins to trigger signaling. How G protein-coupled receptor conformational dynamics control G protein coupling to trigger signaling is a key but still open question. We addressed this question with a model system composed of the purified ghrelin receptor assembled into lipid discs. Combining receptor labeling through genetic incorporation of unnatural amino acids, lanthanide resonance energy transfer, and normal mode analyses, we directly demonstrate the occurrence of two distinct receptor:Gq assemblies with different geometries whose relative populations parallel the activation state of the receptor. The first of these assemblies is a preassembled complex with the receptor in its basal conformation. This complex is specific of Gq and is not observed with Gi. The second one is an active assembly in which the receptor in its active conformation triggers G protein activation. The active complex is present even in the absence of agonist, in a direct relationship with the high constitutive activity of the ghrelin receptor. These data provide direct evidence of a mechanism for ghrelin receptor-mediated Gq signaling in which transition of the receptor from an inactive to an active conformation is accompanied by a rearrangement of a preassembled receptor:G protein complex, ultimately leading to G protein activation and signaling.