EMD-40496
Cryo-EM structure of TRPM7 in MSP2N2 nanodisc in apo state
EMD-40496
Single-particle2.19 Å
Deposition: 14/04/2023Map released: 17/05/2023
Last modified: 16/10/2024
Sample Organism:
Mus musculus
Sample: sample 1
Fitted models: 8si2 (Avg. Q-score: 0.523)
Deposition Authors: Nadezhdin KD
,
Neuberger A ,
Sobolevsky AI
Sample: sample 1
Fitted models: 8si2 (Avg. Q-score: 0.523)
Deposition Authors: Nadezhdin KD
,
Neuberger A ,
Sobolevsky AI
Structural mechanisms of TRPM7 activation and inhibition.
Nadezhdin KD ,
Correia L,
Narangoda C ,
Patel DS,
Neuberger A ,
Gudermann T ,
Kurnikova MG ,
Chubanov V ,
Sobolevsky AI
(2023) Nat Commun , 14 , 2639 - 2639
,
Correia L,
Narangoda C ,
Patel DS,
Neuberger A ,
Gudermann T ,
Kurnikova MG ,
Chubanov V ,
Sobolevsky AI
(2023) Nat Commun , 14 , 2639 - 2639
Abstract:
The transient receptor potential channel TRPM7 is a master regulator of the organismal balance of divalent cations that plays an essential role in embryonic development, immune responses, cell mobility, proliferation, and differentiation. TRPM7 is implicated in neuronal and cardiovascular disorders, tumor progression and has emerged as a new drug target. Here we use cryo-EM, functional analysis, and molecular dynamics simulations to uncover two distinct structural mechanisms of TRPM7 activation by a gain-of-function mutation and by the agonist naltriben, which show different conformational dynamics and domain involvement. We identify a binding site for highly potent and selective inhibitors and show that they act by stabilizing the TRPM7 closed state. The discovered structural mechanisms provide foundations for understanding the molecular basis of TRPM7 channelopathies and drug development.
The transient receptor potential channel TRPM7 is a master regulator of the organismal balance of divalent cations that plays an essential role in embryonic development, immune responses, cell mobility, proliferation, and differentiation. TRPM7 is implicated in neuronal and cardiovascular disorders, tumor progression and has emerged as a new drug target. Here we use cryo-EM, functional analysis, and molecular dynamics simulations to uncover two distinct structural mechanisms of TRPM7 activation by a gain-of-function mutation and by the agonist naltriben, which show different conformational dynamics and domain involvement. We identify a binding site for highly potent and selective inhibitors and show that they act by stabilizing the TRPM7 closed state. The discovered structural mechanisms provide foundations for understanding the molecular basis of TRPM7 channelopathies and drug development.