Antoine Koehl scite author profile

The μ-opioid receptor (μOR) is a G-protein-coupled receptor (GPCR) and the target of most clinically and recreationally used opioids. The induced positive effects of analgesia and euphoria are mediated by μOR signalling through the adenylyl cyclase-inhibiting heterotrimeric G protein G. Here we present the 3.5 Å resolution cryo-electron microscopy structure of the μOR bound to the agonist peptide DAMGO and nucleotide-free G. DAMGO occupies the morphinan ligand pocket, with its N terminus interacting with conserved receptor residues and its C terminus engaging regions important for opioid-ligand selectivity. Comparison of the μOR-G complex to previously determined structures of other GPCRs bound to the stimulatory G protein G reveals differences in the position of transmembrane receptor helix 6 and in the interactions between the G protein α-subunit and the receptor core. Together, these results shed light on the structural features that contribute to the G protein-coupling specificity of the µOR.

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Crystal structure of the human σ1 receptor

Schmidt

Zheng

Gurpinar

et al. 2016

Nature

389

575

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The human σ1 receptor is an enigmatic ER-resident transmembrane protein implicated in a variety of disorders including depression, drug addiction, and neuropathic pain1. Recently, an additional connection to amyotrophic lateral sclerosis (ALS) has emerged from studies of human genetics and mouse models2. Unlike many transmembrane receptors that belong to large, extensively studied families such as G protein-coupled receptors or ligand-gated ion channels, the σ1 receptor is an evolutionary isolate with no discernible similarity to any other human protein. Despite its increasingly clear importance in human physiology and disease, the molecular architecture of the σ1 receptor and its regulation by drug-like compounds remain poorly defined. Here, we report crystal structures of the human σ1 receptor in complex with two chemically divergent ligands, PD144418 and 4-IBP. The structures reveal a trimeric architecture with a single transmembrane domain in each protomer. The carboxy-terminal domain of the receptor shows an extensive flat, hydrophobic membrane-proximal surface, suggesting an intimate association with the cytosolic surface of the ER membrane in cells. This domain includes a cupin-like β-barrel with the ligand-binding site buried at its center. This large, hydrophobic ligand-binding cavity shows remarkable plasticity in ligand recognition, binding the two ligands in similar positions despite dissimilar chemical structures. Taken together, these results reveal the overall architecture, oligomerization state, and molecular basis for ligand recognition by this important but poorly understood protein.

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Structural insights into the activation of metabotropic glutamate receptors

Koehl

Feng

et al. 2019

Nature

243

371

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Metabotropic glutamate receptors are Family C G protein coupled receptors that form obligate dimers and possess extracellular ligand binding Venus flytrap (VFT) domains, which are linked via cysteine rich domains (CRDs) to their 7-transmembrane (7TM) domain. Spectroscopic studies show that signaling is a dynamic process, with large scale conformational changes underlying the transmission of signal from the extracellular VFTs to the G protein-coupling domains (7TMs) in the membrane. Using a combination of x-ray crystallography, cryo-electron microscopy and signaling studies, we present a structural framework for the activation mechanism of metabotropic glutamate receptor subtype 5. Our results show that agonist binding at the VFTs leads to a compaction of the intersubunit dimer interface, thereby bringing the CRDs into close proximity. Interactions between the CRDs and the second extracellular loops of the receptor enable the rigid body repositioning of the 7TM domains, which come into contact with each other to initiate signaling.

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Development of an antibody fragment that stabilizes GPCR/G-protein complexes

et al. 2018

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Single-particle cryo-electron microscopy (cryo-EM) has recently enabled high-resolution structure determination of numerous biological macromolecular complexes. Despite this progress, the application of high-resolution cryo-EM to G protein coupled receptors (GPCRs) in complex with heterotrimeric G proteins remains challenging, owning to both the relative small size and the limited stability of these assemblies. Here we describe the development of antibody fragments that bind and stabilize GPCR-G protein complexes for the application of high-resolution cryo-EM. One antibody in particular, mAb16, stabilizes GPCR/G-protein complexes by recognizing an interface between Gα and Gβγ subunits in the heterotrimer, and confers resistance to GTPγS-triggered dissociation. The unique recognition mode of this antibody makes it possible to transfer its binding and stabilizing effect to other G-protein subtypes through minimal protein engineering. This antibody fragment is thus a broadly applicable tool for structural studies of GPCR/G-protein complexes.

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Capture and X-ray diffraction studies of protein microcrystals in a microfluidic trap array

Lyubimov

Murray

Koehl

et al. 2015

Acta Cryst D Biol Crystallogr

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A CLC-ec1 mutant reveals global conformational change and suggests a unifying mechanism for the CLC Cl–/H+ transport cycle

Chavan

Cheng

Jiang

et al. 2020

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Among coupled exchangers, CLCs uniquely catalyze the exchange of oppositely charged ions (Cl– for H+). Transport-cycle models to describe and explain this unusual mechanism have been proposed based on known CLC structures. While the proposed models harmonize with many experimental findings, gaps and inconsistencies in our understanding have remained. One limitation has been that global conformational change – which occurs in all conventional transporter mechanisms – has not been observed in any high-resolution structure. Here, we describe the 2.6 Å structure of a CLC mutant designed to mimic the fully H+-loaded transporter. This structure reveals a global conformational change to improve accessibility for the Cl– substrate from the extracellular side and new conformations for two key glutamate residues. Together with DEER measurements, MD simulations, and functional studies, this new structure provides evidence for a unified model of H+/Cl– transport that reconciles existing data on all CLC-type proteins.

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Structural mapping of the ClpBATPases of Plasmodium falciparum: Targeting protein folding and secretion for antimalarial drug design

AhYoung

Koehl

Cascio³

et al. 2015

Protein Science

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Caseinolytic chaperones and proteases (Clp) belong to the AAA1 protein superfamily and are part of the protein quality control machinery in cells. The eukaryotic parasite Plasmodium falciparum, the causative agent of malaria, has evolved an elaborate network of Clp proteins including two distinct ClpB ATPases. ClpB1 and ClpB2 are involved in different aspects of parasitic proteostasis. ClpB1 is present in the apicoplast, a parasite-specific and plastid-like organelle hosting various metabolic pathways necessary for parasite growth. ClpB2 localizes to the parasitophorous vacuole membrane where it drives protein export as core subunit of a parasite-derived protein secretion complex, the Plasmodium Translocon of Exported proteins (PTEX); this process is central to parasite virulence and survival in the human host. The functional associations of these two chaperones with parasite-specific metabolism and protein secretion make them prime drug targets. ClpB proteins function as unfoldases and disaggregases and share a common architecture consisting of four domains-a variable N-terminal domain that binds different protein substrates, followed by two highly conserved catalytic ATPase domains, and a C-terminal domain. Here, we report and compare the first crystal structures of the N terminal domains of ClpB1 and ClpB2 from Plasmodium and analyze their molecular surfaces. Solution scattering analysis of the N domain of ClpB2 shows that the average solution conformation is similar to the crystalline structure. These Abbreviations: Pfal, Plasmodium falciparum; AAA1, ATPase associated with diverse activities; Clp, caseinolytic protease; PTEX, Plasmodium translocon of exported proteins; PV, parasitophorous vacuole; PVM, parasitophorous vacuole membrane; GFP, green fluorescent protein; SAXS, small angle X-ray scattering; RMSD, root-mean-square deviation; ADP, atomic displacement parameters; SEC, size exclusion chromatography; Ec, Escherichia coli; Tth, Thermus thermophilus; Bsu, Bacillus subtilis; Vch, Vibrio cholera.Additional Supporting Information may be found in the online version of this article.Andrew P. AhYoung and Antoine Koehl contributed equally to this work. Published by Wiley-Blackwell. V C 2015 The Protein Society structures represent the first step towards the characterization of these two malarial chaperones and the reconstitution of the entire PTEX to aid structure-based design of novel anti-malarial drugs.

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Structure of a putative ClpS N‐end rule adaptor protein from the malaria pathogen Plasmodium falciparum

et al. 2016

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The N-end rule pathway uses an evolutionarily conserved mechanism in bacteria and eukaryotes that marks proteins for degradation by ATP-dependent chaperones and proteases such as the Clp chaperones and proteases. Specific N-terminal amino acids (N-degrons) are sufficient to target substrates for degradation. In bacteria, the ClpS adaptor binds and delivers N-end rule substrates for their degradation upon association with the ClpA/P chaperone/protease. Here, we report the first crystal structure, solved at 2.7 Å resolution, of a eukaryotic homolog of bacterial ClpS from the malaria apicomplexan parasite Plasmodium falciparum (Pfal). Despite limited sequence identity, Plasmodium ClpS is very similar to bacterial ClpS. Akin to its bacterial orthologs, plasmodial ClpS harbors a preformed hydrophobic pocket whose geometry and chemical properties are compatible with the binding of N-degrons. However, while the N-degron binding pocket in bacterial ClpS structures is open and accessible, the corresponding pocket in Plasmodium ClpS is occluded by a conserved surface loop that acts as a latch. Despite the closed conformation observed in the crystal, we show that, in solution, Pfal-ClpS binds and discriminates peptides mimicking bona fide N-end rule substrates. The presence of an apicoplast targeting peptide suggests that Pfal-ClpS localizes to this plastid-like organelle characteristic of all Apicomplexa Additional Supporting Information may be found in the online version of this article. and hosting most of its Clp machinery. By analogy with the related ClpS1 from plant chloroplasts and cyanobacteria, Plasmodium ClpS likely functions in association with ClpC in the apicoplast. Our findings open new venues for the design of novel anti-malarial drugs aimed at disrupting parasite-specific protein quality control pathways.

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Antoine Koehl

Structure of the µ-opioid receptor–Gi protein complex

Crystal structure of the human σ1 receptor

Structural insights into the activation of metabotropic glutamate receptors

Development of an antibody fragment that stabilizes GPCR/G-protein complexes

Capture and X-ray diffraction studies of protein microcrystals in a microfluidic trap array

A CLC-ec1 mutant reveals global conformational change and suggests a unifying mechanism for the CLC Cl–/H+ transport cycle

Structural mapping of the ClpBATPases of Plasmodium falciparum: Targeting protein folding and secretion for antimalarial drug design

Structure of a putative ClpS N‐end rule adaptor protein from the malaria pathogen Plasmodium falciparum

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