Functional Assembly of Kv7.1/Kv7.5 Channels With Emerging Properties on Vascular Muscle Physiology

Oliveras, Anna; Roura-Ferrer, Meritxell; Solé, Laura; Cruz, A.; Prieto, Ángela; Etxebarria, A.; Manils, Joan; Morales‐Cano, Daniel; Condom, Enric; Soler, Concepció; Cogolludo, Ángel; Valenzuela, Carmen; Villarroel, Álvaro; Comes, Núria; Felipe, Antônio

doi:10.1161/atvbaha.114.303801

Cited by 25 publications

(19 citation statements)

References 43 publications

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“…The simulated macroscopic current (Figure 5O) displays the two signatures of recorded macroscopic Kv7.1 ionic currents: a short initial delay (5 to 10 ms) and early inactivation. Additionally, the activation duration is consistent with that of the experimentally recorded currents (Oliveras et al, 2014; Shamgar et al, 2008; Wu et al, 2010a; Wu et al, 2010b). …”

Section: Discussionsupporting

confidence: 85%

Conformational changes of an ion-channel during gating and emerging electrophysiologic properties: Application of a computational approach to cardiac Kv7.1

Nekouzadeh

Rudy

2016

Progress in Biophysics and Molecular Biology

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Ion channels are the “building blocks” of the excitation process in excitable tissues. Despite advances in determining their molecular structure, understanding the relationship between channel protein structure and electrical excitation remains a challenge. The Kv7.1 potassium channel is an important determinant of the cardiac action potential and its adaptation to rate changes. It is subject to beta adrenergic regulation, and many mutations in the channel protein are associated with the arrhythmic long QT syndrome. In this theoretical study, we use a novel computational approach to simulate the conformational changes that Kv7.1 undergoes during activation gating and compute the resulting electrophysiologic function in terms of single-channel and macroscopic currents. We generated all possible conformations of the S4–S5 linker that couples the S3–S4 complex (voltage sensor domain, VSD) to the pore, and all associated conformations of VSD and the pore (S6). Analysis of these conformations revealed that VSD-to-pore mechanical coupling during activation gating involves outward translation of the voltage sensor, accompanied by a translation away from the pore and clockwise twist. These motions cause pore opening by moving the S4–S5 linker upward and away from the pore, providing space for the S6 tails to move away from each other. Single channel records, computed from the simulated motion trajectories during gating, have stochastic properties similar to experimentally recorded traces. Macroscopic current through an ensemble of channels displays two key properties of Kv7.1: an initial delay of activation and fast inactivation. The simulations suggest a molecular mechanism for fast inactivation; a large twist of the VSD following its outward translation results in movement of the base of the S4–S5 linker toward the pore, eliminating open pore conformations to cause inactivation.

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Section: Discussionsupporting

confidence: 85%

Conformational changes of an ion-channel during gating and emerging electrophysiologic properties: Application of a computational approach to cardiac Kv7.1

Nekouzadeh

Rudy

2016

Progress in Biophysics and Molecular Biology

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“…The voltage-dependence for activation varies among Kv7 channel subtypes when expressed in mammalian cells, with Kv7.5 activating at more negative voltages than other subtypes. The V 0.5 of activation of HASMC Kv7 currents (−41 mV) is most similar to that reported for cloned Kv7.5 channels expressed in mammalian cells (−44.2 ± 1.7 mV; −46 ± 3 mV [13,17]) and considerably more negative than that of Kv7.4 (−30.6 ± 1.2 mV [13]), or Kv7.3 (−37.3 ± 1.3 mV [18]). All told, the experimental evidence suggests that the endogenous Kv7 currents measured in HASMCs are elicited predominantly via Kv7.5 channels.…”

Section: Discussionsupporting

confidence: 79%

Mechanisms of PKA-Dependent Potentiation of Kv7.5 Channel Activity in Human Airway Smooth Muscle Cells

Brueggemann

Cribbs

Schwartz

et al. 2018

IJMS

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β-adrenergic receptor (βAR) activation promotes relaxation of both vascular and airway smooth muscle cells (VSMCs and ASMCs, respectively), though the signaling mechanisms have not been fully elucidated. We previously found that the activity of Kv7.5 voltage-activated potassium channels in VSMCs is robustly enhanced by activation of βARs via a mechanism involving protein kinase A (PKA)-dependent phosphorylation. We also found that enhancement of Kv7 channel activity in ASMCs promotes airway relaxation. Here we provide evidence that Kv7.5 channels are natively expressed in primary cultures of human ASMCs and that they conduct currents which are robustly enhanced in response to activation of the βAR/cyclic adenosine monophosphate (cAMP)/PKA pathway. MIT Scansite software analysis of putative PKA phosphorylation sites on Kv7.5 identified 8 candidate serine or threonine residues. Each residue was individually mutated to an alanine to prevent its phosphorylation and then tested for responses to βAR activation or to stimuli that elevate cAMP levels. Only the mutation of serine 53 (S53A), located on the amino terminus of Kv7.5, significantly reduced the increase in Kv7.5 current in response to these stimuli. A phospho-mimic mutation (S53D) exhibited characteristics of βAR-activated Kv7.5. Serine-to-alanine mutations of 6 putative PKA phosphorylation sites on the Kv7.5 C-terminus, individually or in combination, did not significantly reduce the enhancement of the currents in response to forskolin treatment (to elevate cAMP levels). We conclude that phosphorylation of S53 on the amino terminus of Kv7.5 is essential for PKA-dependent enhancement of channel activity in response to βAR activation in vascular and airway smooth muscle cells.

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“…Thus, it is plausible that cGMP may activate K v 7 channels through a PKA‐dependent activation of K v 7 channels (Chambard & Ashmore, ; Mani et al, ). Interestingly, we and other authors have shown that K v 7.5 may form functional heterotetrameric channels with K v 7.1 (Oliveras et al, ) and K v 7.4 (Brueggemann et al, ) in vascular tissues. Thus, it is conceivable that activation of K v 7.1/K v 7.5 or K v 7.4/K v 7.5 heterotetramers could contribute to cGMP‐mediated responses as previously proposed (Stott et al, ).…”

Section: Discussionmentioning

confidence: 53%

Activation of K_v7 channels as a novel mechanism for NO/cGMP‐induced pulmonary vasodilation

Mondéjar-Parreño

Moral-Sanz

Barreira

et al. 2019

British J Pharmacology

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Background and Purpose The NO/cGMP pathway represents a major physiological signalling controlling tone in pulmonary arteries (PA), and drugs activating this pathway are used to treat pulmonary arterial hypertension. Kv channels expressed in PA smooth muscle cells (PASMCs) are key determinants of vascular tone. We aimed to analyse the contribution of Kv1.5 and Kv7 channels in the electrophysiological and vasodilating effects evoked by NO donors and the GC stimulator riociguat in PA. Experimental Approach Kv currents were recorded in isolated rat PASMCs using the patch‐clamp technique. Vascular reactivity was assessed in a wire myograph. Key Results The NO donors diethylamine NONOate diethylammonium (DEA‐NO) and sodium nitroprusside hyperpolarized the membrane potential and induced a bimodal effect on Kv currents (augmenting the current between −40 and −10 mV and decreasing it at more depolarized potentials). The hyperpolarization and the enhancement of the current were suppressed by Kv7 channel inhibitors and by the GC inhibitor ODQ but preserved when Kv1.5 channels were inhibited. Additionally, DEA‐NO enhanced Kv7.5 currents in COS7 cells expressing the KCNQ5 gene. Riociguat increased Kv currents at all potentials ≥−40 mV and induced membrane hyperpolarization. Both effects were prevented by Kv7 inhibition. Likewise, PA relaxation induced by NO donors and riociguat was attenuated by Kv7 inhibitors. Conclusions and Implications NO donors and riociguat enhance Kv7 currents, leading to PASMC hyperpolarization. This mechanism contributes to NO/cGMP‐induced PA vasodilation. Our study identifies Kv7 channels as a novel mechanism of action of vasodilator drugs used in the treatment of pulmonary arterial hypertension.

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Functional Assembly of Kv7.1/Kv7.5 Channels With Emerging Properties on Vascular Muscle Physiology

Cited by 25 publications

References 43 publications

Conformational changes of an ion-channel during gating and emerging electrophysiologic properties: Application of a computational approach to cardiac Kv7.1

Conformational changes of an ion-channel during gating and emerging electrophysiologic properties: Application of a computational approach to cardiac Kv7.1

Mechanisms of PKA-Dependent Potentiation of Kv7.5 Channel Activity in Human Airway Smooth Muscle Cells

Activation of K_v7 channels as a novel mechanism for NO/cGMP‐induced pulmonary vasodilation

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Functional Assembly of Kv7.1/Kv7.5 Channels With Emerging Properties on Vascular Muscle Physiology

Cited by 25 publications

References 43 publications

Conformational changes of an ion-channel during gating and emerging electrophysiologic properties: Application of a computational approach to cardiac Kv7.1

Conformational changes of an ion-channel during gating and emerging electrophysiologic properties: Application of a computational approach to cardiac Kv7.1

Mechanisms of PKA-Dependent Potentiation of Kv7.5 Channel Activity in Human Airway Smooth Muscle Cells

Activation of Kv7 channels as a novel mechanism for NO/cGMP‐induced pulmonary vasodilation

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Activation of K_v7 channels as a novel mechanism for NO/cGMP‐induced pulmonary vasodilation