Thomas Clairfeuille scite author profile

Fast inactivation of voltage-gated sodium (Nav) channels is essential for electrical signaling, but its mechanism remains poorly understood. Here we determined the structures of a eukaryotic Nav channel alone and in complex with a lethal α-scorpion toxin, AaH2, by electron microscopy, both at 3.5-angstrom resolution. AaH2 wedges into voltage-sensing domain IV (VSD4) to impede fast activation by trapping a deactivated state in which gating charge interactions bridge to the acidic intracellular carboxyl-terminal domain. In the absence of AaH2, the S4 helix of VSD4 undergoes a ~13-angstrom translation to unlatch the intracellular fast-inactivation gating machinery. Highlighting the polypharmacology of α-scorpion toxins, AaH2 also targets an unanticipated receptor site on VSD1 and a pore glycan adjacent to VSD4. Overall, this work provides key insights into fast inactivation, electromechanical coupling, and pathogenic mutations in Nav channels.

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A unique PDZ domain and arrestin-like fold interaction reveals mechanistic details of endocytic recycling by SNX27-retromer

Gallon

Clairfeuille

Steinberg

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

174

240

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The sorting nexin 27 (SNX27)-retromer complex is a major regulator of endosome-to-plasma membrane recycling of transmembrane cargos that contain a PSD95, Dlg1, zo-1 (PDZ)-binding motif. Here we describe the core interaction in SNX27-retromer assembly and its functional relevance for cargo sorting. Crystal structures and NMR experiments reveal that an exposed β-hairpin in the SNX27 PDZ domain engages a groove in the arrestin-like structure of the vacuolar protein sorting 26A (VPS26A) retromer subunit. The structure establishes how the SNX27 PDZ domain simultaneously binds PDZ-binding motifs and retromer-associated VPS26. Importantly, VPS26A binding increases the affinity of the SNX27 PDZ domain for PDZ-binding motifs by an order of magnitude, revealing cooperativity in cargo selection. With disruption of SNX27 and retromer function linked to synaptic dysfunction and neurodegenerative disease, our work provides the first step, to our knowledge, in the molecular description of this important sorting complex, and more broadly describes a unique interaction between a PDZ domain and an arrestin-like fold.

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A molecular code for endosomal recycling of phosphorylated cargos by the SNX27–retromer complex

Clairfeuille

Mas

Chan

et al. 2016

Nat Struct Mol Biol

147

201

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The delicate balance between endocytosis and recycling of the cell surface receptors (NMDAR and AMPAR) is essential for controlling their surface levels and degradation, and is regulated by numerous processes including lateral membrane diffusion, scaffolding protein interactions and posttranslational modifications. Generally the NMDARs undergo activity-dependent endocytosis within clathrin-coated vesicles. They then enter the endosomal system where they are either sorted into the degradative lysosomal pathway, or are replenished via endosomal recycling. Defects in endosomal trafficking therefore lead to perturbed homeostasis of NMDARs. Our recent findings provide a comprehensive understanding of how post-translational modifications of NMDAR define an extended electrostatic peptide code for cargo sorting and influence their interactions with the trafficking machinery. Currently, I am trying to understand the mechanistic basis of intracellular trafficking in NMDAR receptor homeostasis. In my talk, I will be discussing about some of our efforts in the basic studies of the structure and function of SNX27, a unique member of PX-FERM module, that control membrane trafficking. Additionally, I will highlight the novel role for phosphorylation of the NMDARs in promoting SNX27-retromer interactions, which may have significant implications for activity-dependent trafficking of NMDARs during synaptic potentiation.

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Structure of the essential inner membrane lipopolysaccharide–PbgA complex

Clairfeuille¹,

Buchholz²,

Li³

et al. 2020

Nature

100

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Structure of the human sodium leak channel NALCN

Kschonsak¹,

Chua

Noland³

et al. 2020

Nature

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