A conserved threonine in the S1–S2 loop of KV7.2 and KV7.3 channels regulates voltage-dependent activation

Füll, Yvonne; Seebohm, Guiscard; Lerche, Holger; Maljevic, Snezana

doi:10.1007/s00424-012-1184-x

Cited by 8 publications

(9 citation statements)

References 23 publications

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“…The T210K/M variants resulted in loss of K + conductance and cell‐surface K V 2.1 expression. T210 is a critical residue forming the S1–pore interface . A hydroxyl group is required at this position for channel function .…”

Section: Discussionmentioning

confidence: 99%

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Spectrum of K_V2.1 Dysfunction in KCNB1‐Associated Neurodevelopmental Disorders

Kang

Vanoye

Misra

et al. 2019

Annals of Neurology

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Objective Pathogenic variants in KCNB1, encoding the voltage‐gated potassium channel KV2.1, are associated with developmental and epileptic encephalopathy (DEE). Previous functional studies on a limited number of KCNB1 variants indicated a range of molecular mechanisms by which variants affect channel function, including loss of voltage sensitivity, loss of ion selectivity, and reduced cell‐surface expression. Methods We evaluated a series of 17 KCNB1 variants associated with DEE or other neurodevelopmental disorders (NDDs) to rapidly ascertain channel dysfunction using high‐throughput functional assays. Specifically, we investigated the biophysical properties and cell‐surface expression of variant KV2.1 channels expressed in heterologous cells using high‐throughput automated electrophysiology and immunocytochemistry–flow cytometry. Results Pathogenic variants exhibited diverse functional defects, including altered current density and shifts in the voltage dependence of activation and/or inactivation, as homotetramers or when coexpressed with wild‐type KV2.1. Quantification of protein expression also identified variants with reduced total KV2.1 expression or deficient cell‐surface expression. Interpretation Our study establishes a platform for rapid screening of KV2.1 functional defects caused by KCNB1 variants associated with DEE and other NDDs. This will aid in establishing KCNB1 variant pathogenicity and the mechanism of dysfunction, which will enable targeted strategies for therapeutic intervention based on molecular phenotype. ANN NEUROL 2019;86:899–912

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Section: Discussionmentioning

confidence: 99%

“…T210 is a critical residue forming the S1-pore interface. 31,32 A hydroxyl group is required at this position for channel function. 32 Thus, substitution with either lysine or methionine would be incompatible with channel function.…”

Section: Comparison Of Same-site Substitutionsmentioning

confidence: 99%

Spectrum of K_V2.1 Dysfunction in KCNB1‐Associated Neurodevelopmental Disorders

Kang

Vanoye

Misra

et al. 2019

Annals of Neurology

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“…1a,b) and has been implicated as a candidate for a functional VSD-to-pore domain connection2032. Further, residues in the neighborhood of F416 form an important, close, and rigid contact point between the VSD and the pore domain3334353637. Here we explore the hypothesis that residue F416 is a possible candidate in the reciprocal VSD-to-pore interaction that modulates C-type inactivation.…”

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confidence: 97%

Reciprocal voltage sensor-to-pore coupling leads to potassium channel C-type inactivation

Conti

Renhorn

Gabrielsson

et al. 2016

Sci Rep

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Voltage-gated potassium channels open at depolarized membrane voltages. A prolonged depolarization causes a rearrangement of the selectivity filter which terminates the conduction of ions – a process called slow or C-type inactivation. How structural rearrangements in the voltage-sensor domain (VSD) cause alteration in the selectivity filter, and vice versa, are not fully understood. We show that pulling the pore domain of the Shaker potassium channel towards the VSD by a Cd2+ bridge accelerates C-type inactivation. Molecular dynamics simulations show that such pulling widens the selectivity filter and disrupts the K+ coordination, a hallmark for C-type inactivation. An engineered Cd2+ bridge within the VSD also affect C-type inactivation. Conversely, a pore domain mutation affects VSD gating-charge movement. Finally, C-type inactivation is caused by the concerted action of distant amino acid residues in the pore domain. All together, these data suggest a reciprocal communication between the pore domain and the VSD in the extracellular portion of the channel.

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“…K + channel alterations may reflect the clinical antinociceptive action. A number of studies have shown that voltage-gated K + channels have a major role in the regulation of neuronal excitability (21,22). …”

Section: Discussionmentioning

confidence: 99%

Effect of sodium ferulate on delayed rectifier K+ currents in PC12 cells

Wang

Zhang

et al. 2014

Experimental and Therapeutic Medicine

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In order to investigate the effect of sodium ferulate (SF) on voltage-activated K+ channels, the delayed rectifier K+ current (Ik) in PC12 rat pheochromocytoma cells was recorded using the automated patch-clamp method. The results indicated that following the application of SF, the Ik in PC12 cells was significantly decreased in a concentration-dependent manner. The analysis of activation kinetic curves and inactivation kinetic curves of Ik showed that SF had an effect on the activation and inactivation kinetics. Following the application of 15.3 μM SF, the activation curve of the Ik of PC12 cells was shifted to positive potentials and the inactivation curve of the Ik of PC12 cells was shifted to negative potentials. This study revealed that the delayed rectifier K+ currents of PC12 cells were inhibited following SF treatment in a concentration-dependent manner. The mechanism may be associated with the delayed activation and enhanced inactivation of Ik-associated channels.

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A conserved threonine in the S1–S2 loop of KV7.2 and KV7.3 channels regulates voltage-dependent activation

Cited by 8 publications

References 23 publications

Spectrum of K_V2.1 Dysfunction in KCNB1‐Associated Neurodevelopmental Disorders

Spectrum of K_V2.1 Dysfunction in KCNB1‐Associated Neurodevelopmental Disorders

Reciprocal voltage sensor-to-pore coupling leads to potassium channel C-type inactivation

Effect of sodium ferulate on delayed rectifier K+ currents in PC12 cells

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A conserved threonine in the S1–S2 loop of KV7.2 and KV7.3 channels regulates voltage-dependent activation

Cited by 8 publications

References 23 publications

Spectrum of KV2.1 Dysfunction in KCNB1‐Associated Neurodevelopmental Disorders

Spectrum of KV2.1 Dysfunction in KCNB1‐Associated Neurodevelopmental Disorders

Reciprocal voltage sensor-to-pore coupling leads to potassium channel C-type inactivation

Effect of sodium ferulate on delayed rectifier K+ currents in PC12 cells

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Product

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Spectrum of K_V2.1 Dysfunction in KCNB1‐Associated Neurodevelopmental Disorders

Spectrum of K_V2.1 Dysfunction in KCNB1‐Associated Neurodevelopmental Disorders