Probing Conformational Changes during the Gating Cycle of a Potassium Channel in Lipid Bilayers

Cruijsen, Elwin A. W. van der; Prokofyev, Alexander V.; Pongs, Olaf; Baldus, Marc

doi:10.1016/j.bpj.2016.12.001

Cited by 28 publications

(33 citation statements)

References 56 publications

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“…A network of energetically coupled amino acid residues largely mediates the communication between these structural motifs (35). This process is known as "allosteric coupling," and in the pore domain of K + channels is responsible for the functional and structural coupling of the channel's AG and its SF (24,(35)(36)(37)(38)(39)(40). This allosteric coupling underlies a process known as C-type inactivation coupled to activation gating in K + channels (24), and recently we have started to understand this mechanism at the molecular level (31,38,39).…”

Section: Discussionmentioning

confidence: 99%

Hysteresis of KcsA potassium channel's activation– deactivation gating is caused by structural changes at the channel’s selectivity filter

Tilegenova

Cortés

Cuello

2017

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

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Mode-shift or hysteresis has been reported in ion channels. Voltageshift for gating currents is well documented for voltage-gated cation channels (VGCC), and it is considered a voltage-sensing domain's (VSD) intrinsic property. However, uncoupling the Shaker K + channel's pore domain (PD) from the VSD prevented the modeshift of the gating currents. Consequently, it was proposed that an open-state stabilization of the PD imposes a mechanical load on the VSD, which causes its mode-shift. Furthermore, the mode-shift displayed by hyperpolarization-gated cation channels is likely caused by structural changes at the channel's PD similar to those underlying C-type inactivation. To demonstrate that the PD of VGCC undergoes hysteresis, it is imperative to study its gating process in the absence of the VSD. A back-door strategy is to use KcsA (a K + channel from the bacteria Streptomyces lividans) as a surrogate because it lacks a VSD and exhibits an activation coupled to C-type inactivation. By directly measuring KcsA's activation gate opening and closing in conditions that promote or halt C-type inactivation, we have found (i) that KcsA undergoes mode-shift of gating when having K + as the permeant ion; (ii) that Cs + or Rb + , known to halt C-inactivation, prevented mode-shift of gating; and (iii) that, in the total absence of C-type inactivation, KcsA's mode-shift was prevented. Finally, our results demonstrate that an allosteric communication causes KcsA's activation gate to "remember" the conformation of the selectivity filter, and hence KcsA requires a different amount of energy for opening than for closing.hysteresis | KcsA | potassium channels | mode-shift | C-type inactivation

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Section: Discussionmentioning

confidence: 99%

Hysteresis of KcsA potassium channel's activation– deactivation gating is caused by structural changes at the channel’s selectivity filter

Tilegenova

Cortés

Cuello

2017

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

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“…Afterwards, we washed exactly the same sample in acidic (pH 4) buffers, which is a well-known means to open the activation gate of KcsA. [5,15,16] Unexpectedly, we obtained drastically increased NHHC transfer efficiencies with open channels (Figure 2 A). We confirmed this result by "shuttling" the channels back to the closed state (pH 7), for which the NHHC transfer was again much weaker (Figure 2 B).…”

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Supramolecular Organization and Functional Implications of K⁺ Channel Clusters in Membranes

et al. 2017

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The segregation of cellular surfaces in heterogeneous patches is considered to be a common motif in bacteria and eukaryotes that is underpinned by the observation of clustering and cooperative gating of signaling membrane proteins such as receptors or channels. Such processes could represent an important cellular strategy to shape signaling activity. Hence, structural knowledge of the arrangement of channels or receptors in supramolecular assemblies represents a crucial step towards a better understanding of signaling across membranes. We herein report on the supramolecular organization of clusters of the K+ channel KcsA in bacterial membranes, which was analyzed by a combination of DNP‐enhanced solid‐state NMR experiments and MD simulations. We used solid‐state NMR spectroscopy to determine the channel–channel interface and to demonstrate the strong correlation between channel function and clustering, which suggests a yet unknown mechanism of communication between K+ channels.

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“…Wir maßen zuerst ein DNP‐ssNMR‐Experiment mit geschlossenen Kanälen (bei pH 7), was die Bildung von Ballungen bestätigte. Danach wuschen wir exakt dieselbe Probenpräparation in saurem Puffer (pH 4), was ein bekanntes Mittel ist, um die Aktivierungspforte von KcsA zu öffnen . Überraschenderweise beobachteten wir drastisch erhöhte Signale in NHHC‐Experimenten mit geöffneten Kanälen (Abbildung A).…”

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Supramolekulare Organisation und funktionale Auswirkungen von Ballungen von K⁺‐Kanälen in Membranen

et al. 2017

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Die Segregation von zellulären Oberflächen in heterogene Regionen wird in Bakterien und Eukaryoten als geläufiges Motiv betrachtet, und diese Sichtweise wird durch die Beobachtung von Ballungen und funktionalen Kopplungen von Membranproteinen wie Ionenkanälen oder Rezeptoren gestützt. Solche Prozesse könnten eine wichtige zelluläre Strategie sein, um die Signalverarbeitung zu optimieren. Daher sind strukturelle Erkenntnisse über die supramolekulare Organisation von Kanälen oder Rezeptoren entscheidend für ein besseres Verständnis der Signaltransduktion über Membranen. Wir beschreiben hier die supramolekulare Organisation von Ballungen des K+‐Kanals KcsA in bakteriellen Membranen. Diese Studie wurde durch eine Kombination von DNP‐verstärkter Festkörper‐NMR‐Spektroskopie und MD‐Simulationen ermöglicht. Wir bestimmen die Kanal‐Kanal‐Wechselwirkungsfläche und demonstrieren eine starke Korrelation zwischen Kanalfunktion und Kanalballung, was einen bisher unbekannten Mechanismus der Kommunikation zwischen K+‐Kanälen impliziert.

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Probing Conformational Changes during the Gating Cycle of a Potassium Channel in Lipid Bilayers

Cited by 28 publications

References 56 publications

Hysteresis of KcsA potassium channel's activation– deactivation gating is caused by structural changes at the channel’s selectivity filter

Hysteresis of KcsA potassium channel's activation– deactivation gating is caused by structural changes at the channel’s selectivity filter

Supramolecular Organization and Functional Implications of K⁺ Channel Clusters in Membranes

Supramolekulare Organisation und funktionale Auswirkungen von Ballungen von K⁺‐Kanälen in Membranen

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Probing Conformational Changes during the Gating Cycle of a Potassium Channel in Lipid Bilayers

Cited by 28 publications

References 56 publications

Hysteresis of KcsA potassium channel's activation– deactivation gating is caused by structural changes at the channel’s selectivity filter

Hysteresis of KcsA potassium channel's activation– deactivation gating is caused by structural changes at the channel’s selectivity filter

Supramolecular Organization and Functional Implications of K+ Channel Clusters in Membranes

Supramolekulare Organisation und funktionale Auswirkungen von Ballungen von K+‐Kanälen in Membranen

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Supramolecular Organization and Functional Implications of K⁺ Channel Clusters in Membranes

Supramolekulare Organisation und funktionale Auswirkungen von Ballungen von K⁺‐Kanälen in Membranen