Role of protein dynamics in ion selectivity and allosteric coupling in the NaK channel

Brettmann, Joshua; Urusova, Darya V.; Tonelli, Marco; Silva, Jonathan R.; Henzler‐Wildman, Katherine

doi:10.1073/pnas.1515965112

Cited by 18 publications

(32 citation statements)

References 48 publications

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“…A similar allosteric coupling pathway was also identified by the Henzler-Wildman laboratory in the nonselective cation channel NaK. There, they found that NaK exhibits long-range allostery through the selectivity filter and the channel scaffolding as a result of cation passage through the channel (73). Their findings, together with ours, suggest that this behavior may be a common feature within ion channels to tightly control channel function.…”

Section: Ssnmr Identifies Conformational Changes Upon Lipid Bindingsupporting

confidence: 83%

Conformational changes upon gating of KirBac1.1 into an open-activated state revealed by solid-state NMR and functional assays

Amani

Borcik

Khan

et al. 2020

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

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The conformational changes required for activation and K+ conduction in inward-rectifier K+ (Kir) channels are still debated. These structural changes are brought about by lipid binding. It is unclear how this process relates to fast gating or if the intracellular and extracellular regions of the protein are coupled. Here, we examine the structural details of KirBac1.1 reconstituted into both POPC and an activating lipid mixture of 3:2 POPC:POPG (wt/wt). KirBac1.1 is a prokaryotic Kir channel that shares homology with human Kir channels. We establish that KirBac1.1 is in a constitutively active state in POPC:POPG bilayers through the use of real-time fluorescence quenching assays and Förster resonance energy transfer (FRET) distance measurements. Multidimensional solid-state NMR (SSNMR) spectroscopy experiments reveal two different conformers within the transmembrane regions of the protein in this activating lipid environment, which are distinct from the conformation of the channel in POPC bilayers. The differences between these three distinct channel states highlight conformational changes associated with an open activation gate and suggest a unique allosteric pathway that ties the selectivity filter to the activation gate through interactions between both transmembrane helices, the turret, selectivity filter loop, and the pore helix. We also identify specific residues involved in this conformational exchange that are highly conserved among human Kir channels.

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Section: Ssnmr Identifies Conformational Changes Upon Lipid Bindingsupporting

confidence: 83%

Conformational changes upon gating of KirBac1.1 into an open-activated state revealed by solid-state NMR and functional assays

Amani

Borcik

Khan

et al. 2020

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

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“…Because computational models of channels are readily incorporated into multiscale cell and tissue models, 136,138 this approach could be used to identify how inactivation should be targeted therapeutically to stabilize excitation at the tissue level to prevent arrhythmia. As additional structural data emerges, including the Cryo-EM structure of a mammalian Na V channel, 139 conformational data from fluorescence experiments, 140 and even NMR data showing channel dynamics, 141 these models will only improve, provided that the computational approaches needed to incorporate this type of information into the models continue to be developed in parallel.…”

Section: Toward Molecularly Detailed Models Of Inactivationmentioning

confidence: 99%

Mechanisms and models of cardiac sodium channel inactivation

et al. 2017

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Shortly after cardiac Na channels activate and initiate the action potential, inactivation ensues within milliseconds, attenuating the peak Na current, I and allowing the cell membrane to repolarize. A very limited number of Na channels that do not inactivate carry a persistent I, or late I. While late I is only a small fraction of peak magnitude, it significantly prolongs ventricular action potential duration, which predisposes patients to arrhythmia. Here, we review our current understanding of inactivation mechanisms, their regulation, and how they have been modeled computationally. Based on this body of work, we conclude that inactivation and its connection to late I would be best modeled with a "feet-on-the-door" approach where multiple channel components participate in determining inactivation and late I. This model reflects experimental findings showing that perturbation of many channel locations can destabilize inactivation and cause pathological late I.

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“…These observations, together with mutagenesis studies on NaK, suggested that loss of contiguous binding sites (S1 and S2) is responsible for ion non-selectivity 13 , 14 . Moreover, no structural rearrangement was observed in the crystal structures of NaK with Na + , K + , or rubidium (Rb + ) and a single SF conformation was detected for NaK in bicelles at high temperature by solution-state NMR 15 . The different ions were therefore proposed to permeate through the same SF conformation with different preferential binding sites 11 , 16 .…”

Section: Introductionmentioning

confidence: 99%

A single NaK channel conformation is not enough for non-selective ion conduction

Shi

Hendriks

et al. 2018

Nat Commun

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NaK and other non-selective channels are able to conduct both sodium (Na+) and potassium (K+) with equally high efficiency. In contrast to previous crystallographic results, we show that the selectivity filter (SF) of NaK in native-like lipid membranes adopts two distinct conformations that are stabilized by either Na+ or K+ ions. The atomic differences of these conformations are resolved by solid-state NMR (ssNMR) spectroscopy and molecular dynamics (MD) simulations. Besides the canonical K+ permeation pathway, we identify a side entry ion-conduction pathway for Na+ permeation unique to NaK. Moreover, under otherwise identical conditions ssNMR spectra of the K+ selective NaK mutant (NaK2K) reveal only a single conformational state. Therefore, we propose that structural plasticity within the SF and the selection of these conformations by different ions are key molecular determinants for highly efficient conduction of different ions in non-selective cation channels.

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Role of protein dynamics in ion selectivity and allosteric coupling in the NaK channel

Cited by 18 publications

References 48 publications

Conformational changes upon gating of KirBac1.1 into an open-activated state revealed by solid-state NMR and functional assays

Conformational changes upon gating of KirBac1.1 into an open-activated state revealed by solid-state NMR and functional assays

Mechanisms and models of cardiac sodium channel inactivation

A single NaK channel conformation is not enough for non-selective ion conduction

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