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‘C-type’ closed state and gating mechanisms of K2P channels revealed by conformational changes of the TREK-1 channel

Qiansen Zhang, Jie Fu, Shao-ying Zhang, Peipei Guo, Shijie Liu, Juwen Shen, Jiangtao Guo, Huaiyu Yang, Xuebiao Yao

2022Journal of Molecular Cell Biology24 citationsDOIOpen Access PDF

Abstract

Two-pore domain potassium (K2P) channels gate primarily within the selectivity filter, termed 'C-type' gating. Due to the lack of structural insights into the nonconductive (closed) state, 'C-type' gating mechanisms remain elusive. Here, molecular dynamics (MD) simulations on TREK-1, a K2P channel, revealed that M4 helix movements induce filter closing in a novel 'deeper-down' structure that represents a 'C-type' closed state. The 'down' structure does not represent the closed state as previously proposed and instead acts as an intermediate state in gating. The study identified the allosteric 'seesaw' mechanism of M4 helix movements in modulating filter closing. Finally, guided by this recognition of K2P gating mechanisms, MD simulations revealed that gain-of-function mutations and small-molecule activators activate TREK-1 by perturbing state transitions from open to closed states. Together, we reveal a 'C-type' closed state and provide mechanical insights into gating procedures and allosteric regulations for K2P channels.

Topics & Concepts

GatingAllosteric regulationBiophysicsHelix (gastropod)Potassium channelChemistryBiologyBiochemistryReceptorEcologySnailIon channel regulation and functionNanopore and Nanochannel Transport StudiesNeuroscience and Neuropharmacology Research
‘C-type’ closed state and gating mechanisms of K2P channels revealed by conformational changes of the TREK-1 channel | Litcius