Rearrangement of the transmembrane domain interfaces associated with the activation of a GPCR hetero-oligomer

Xue, Li; Sun, Qian; Han, Zhiwei; Rovira, Xavier; Gai, Siyu; He, Qianwen; Pin, Jean‐Philippe; Liu, Jianfeng; Rondard, Philippe

doi:10.1038/s41467-019-10834-5

Cited by 41 publications

(44 citation statements)

References 70 publications

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“…2b, Fig. 3d), consistent with previous cross-linking studies 40 . This interface is also observed in the agonist-bound structure of the mGlu5 homodimer 33 , suggesting the TM6/TM6 interface is likely a hallmark of activation of class C GPCR.…”

Section: Resultssupporting

confidence: 92%

“…2, Extended Data Fig. 7a, b), propagating through the stalk domains to the TM domains, which in turn reorients the TM interface between two subunits from TM3-TM5/TM3-TM5 in the inactive state to TM6/TM6 in the active state, in perfect agreement with previous crosslinking data for GABA B receptor and mGlu homodimers 40,46 . Therefore, the overall domain rearrangements upon activation of GABA B receptor resemble the published cryo-EM structures of mGlu5 33 , suggesting this reorientation of TM domains is possibly the hallmark of class C GPCR activation.…”

Section: Resultssupporting

confidence: 88%

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Cryo-EM structures of inactive and G_i-coupled GABA_B heterodimer

Mao

Shen

et al. 2020

Preprint

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22Metabotropic GABA B G protein-coupled receptor functions as a mandatory heterodimer of 23 GB1 and GB2 subunits and mediates inhibitory neurotransmission in the central nervous system. 24Each subunit is composed of the extracellular Venus flytrap (VFT) domain and transmembrane 25 (TM) domain. Here we present cryo-EM structures of human full-length heterodimeric GABA B 26 receptor in the antagonist-bound inactive state and in the active state complexed with agonist 27 and positive allosteric modulator in the presence of G i1 protein at a resolution range of 2.8-3.0 28 Å. Cryo-EM analysis of the activated-GABA B -G i1 complex revealed that G i1 couples to the 29 activated receptor primarily in three major conformations, one via GB1 TM and two via GB2 30 TM, respectively. Our structures reveal that agonist binding stabilizes the closure of GB1 VFT, 31 which in turn triggers a rearrangement of TM interfaces between two subunits from TM3-32 TM5/TM3-TM5 in the inactive state to TM6/TM6 in the active state and finally induces the 33 opening of intracellular loop 3 and synergistically shifting of TM3, 4 and 5 helices in GB2 TM 34 domain to accommodate the α5-helix of G i1 . These results provide a structural framework for 35 understanding class C GPCR activation and a rational template for allosteric modulator design 36 targeting dimeric interface of GABA B receptor. 37 38 GABA B receptor belongs to the class C GPCR composed by metabotropic glutamate 54 receptors (mGlus), calcium-sensing receptor (CaSR) and taste 1 receptors 16 . Class C GPCR 55 form obligatory dimers, among them, mGlus and CaSR form the homodimer 17,18 , whereas 56 GABA B receptor is an obligatory heterodimer of two subunits GABA B1 (GB1) and GABA B2 57 (GB2) 19,20 . Each subunit is composed of a large extracellular 'Venus Flytrap' (VFT) domain, a 58 transmembrane (TM) domain, and a cytoplasmic tail 21 (Extended Data Fig. 1a, b). GB1 59 possesses an endoplasmic reticulum (ER) retention motif in its cytoplasmic tail 22 . The 60interaction between GB1 and GB2 facilitates its cell surface expression through coiled-coil 61 interactions in its cytoplasmic tail 23 . While GB1 is responsible for ligand recognition through 62 its VFT 24 , GB2 couples G i/o proteins through its TM 25,26 . However, a line of evidence show that 63 in the absence of GB2, GB1 asa (a GB1 mutant with deletion of ER retention signal) at the cell 64 surface or ER-localized GB1 also induces downstream signaling through G i/o proteins 27,28 . 65The crystal structures of isolated heterodimeric VFT of GABA B receptor in presence of the 66 antagonist or agonist revealed the open or closed conformation of GB1 VFT 29 . Structures of 67 isolated VFT and TM domains from other class C GPCR have been reported [30][31][32] , in addition to 68 more recently breakthrough that cryo-EM structures of full-length mGlu5 in apo state and in 69 the presence of agonist have been determined both at overall 4 Å resolution, providing the first 70 insights into the architecture of mGlu5 and structural framew...

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Section: Resultssupporting

confidence: 92%

Section: Resultssupporting

confidence: 88%

Cryo-EM structures of inactive and G_i-coupled GABA_B heterodimer

Mao

Shen

et al. 2020

Preprint

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“…Binding studies of isolated GABA B2 subunits and studies manipulating the receptor composition showed that the GABA B2 7TM domain is mainly responsible for recruiting G-proteins, in addition to hosting an allosteric binding site [23][24][25]. There is also evidence from biochemical and biophysical studies that the GABA B1 7TM participates in formation of GABA B -R oligomers by interacting with other GABA B1 7TMs in the inactive state [26][27][28]. The receptor was found to be in equilibrium between heterodimers and oligomers by applying SNAP-tag technology [27].…”

Section: Structure Of the Gaba B Receptormentioning

confidence: 99%

“…Changes in the 7TM subunit interaction interface upon agonist activation of the GABA B -R have been quantified by cysteine cross-linking studies [26], and is also described in the in the newly released papers describing cryo-EM structures [6,7]. The 7TM domain interface interactions in the inactive state is formed by TM3 (GABA B1 )-TM5 (GABA B2 ) and TM5 (GABA B1 )-TM3 (GABA B2 ) interactions and that the interactions between the protomers are facilitated through ionic interactions stabilized by aromatic residues [6,9,26]. The distance between the backbones of TM5 in each monomer is 8 Å and thereby much shorter than the distance between the homodimers in the inactive mGlu5, which is 21 Å [6,44].…”

Section: Transmembrane Domainsmentioning

confidence: 99%

The GABAB Receptor—Structure, Ligand Binding and Drug Development

2020

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The γ-aminobutyric acid (GABA) type B receptor (GABAB-R) belongs to class C of the G-protein coupled receptors (GPCRs). Together with the GABAA receptor, the receptor mediates the neurotransmission of GABA, the main inhibitory neurotransmitter in the central nervous system (CNS). In recent decades, the receptor has been extensively studied with the intention being to understand pathophysiological roles, structural mechanisms and develop drugs. The dysfunction of the receptor is linked to a broad variety of disorders, including anxiety, depression, alcohol addiction, memory and cancer. Despite extensive efforts, few compounds are known to target the receptor, and only the agonist baclofen is approved for clinical use. The receptor is a mandatory heterodimer of the GABAB1 and GABAB2 subunits, and each subunit is composed of an extracellular Venus Flytrap domain (VFT) and a transmembrane domain of seven α-helices (7TM domain). In this review, we briefly present the existing knowledge about the receptor structure, activation and compounds targeting the receptor, emphasizing the role of the receptor in previous and future drug design and discovery efforts.

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“…Systems investigated via disulfide trapping include ligand-bound class B GPCRs [ 93 , 94 , 95 ], chemokine receptors [ 96 , 97 ], the M3 muscarinic acetylcholine receptor [ 98 , 99 , 100 ], and other receptors [ 101 , 102 ]. Disulfide trapping has been used also to study GPCR dimerization [ 103 , 104 , 105 , 106 ] and to characterize interaction interfaces between GPCRs and G protein or arrestin [ 107 ]. Unfortunately, disulfide trapping does not always yield clear results, probably because of the requirement of nonreducing conditions during analysis of samples [ 93 , 95 , 96 , 98 ].…”

Section: The Contact Interfacementioning

confidence: 99%

Capturing Peptide–GPCR Interactions and Their Dynamics

Kaiser

Coin

2020

Molecules

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Many biological functions of peptides are mediated through G protein-coupled receptors (GPCRs). Upon ligand binding, GPCRs undergo conformational changes that facilitate the binding and activation of multiple effectors. GPCRs regulate nearly all physiological processes and are a favorite pharmacological target. In particular, drugs are sought after that elicit the recruitment of selected effectors only (biased ligands). Understanding how ligands bind to GPCRs and which conformational changes they induce is a fundamental step toward the development of more efficient and specific drugs. Moreover, it is emerging that the dynamic of the ligand–receptor interaction contributes to the specificity of both ligand recognition and effector recruitment, an aspect that is missing in structural snapshots from crystallography. We describe here biochemical and biophysical techniques to address ligand–receptor interactions in their structural and dynamic aspects, which include mutagenesis, crosslinking, spectroscopic techniques, and mass-spectrometry profiling. With a main focus on peptide receptors, we present methods to unveil the ligand–receptor contact interface and methods that address conformational changes both in the ligand and the GPCR. The presented studies highlight a wide structural heterogeneity among peptide receptors, reveal distinct structural changes occurring during ligand binding and a surprisingly high dynamics of the ligand–GPCR complexes.

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Rearrangement of the transmembrane domain interfaces associated with the activation of a GPCR hetero-oligomer

Cited by 41 publications

References 70 publications

Cryo-EM structures of inactive and G_i-coupled GABA_B heterodimer

Cryo-EM structures of inactive and G_i-coupled GABA_B heterodimer

The GABAB Receptor—Structure, Ligand Binding and Drug Development

Capturing Peptide–GPCR Interactions and Their Dynamics

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Rearrangement of the transmembrane domain interfaces associated with the activation of a GPCR hetero-oligomer

Cited by 41 publications

References 70 publications

Cryo-EM structures of inactive and Gi-coupled GABAB heterodimer

Cryo-EM structures of inactive and Gi-coupled GABAB heterodimer

The GABAB Receptor—Structure, Ligand Binding and Drug Development

Capturing Peptide–GPCR Interactions and Their Dynamics

Contact Info

Product

Resources

About

Cryo-EM structures of inactive and G_i-coupled GABA_B heterodimer

Cryo-EM structures of inactive and G_i-coupled GABA_B heterodimer