Voltage-Dependent Inactivation Gating at the Selectivity Filter of the MthK K+ channel

Voltage-dependent K+ channels can undergo a gating process known as C-type inactivation, which involves entry into a nonconducting state through conformational changes near the channel’s selectivity filter. C-type inactivation may involve movements of transmembrane voltage sensor domains, although the mechanisms underlying this form of inactivation may be heterogeneous and are often unclear. Here, we report on a form of voltage-dependent inactivation gating observed in MthK, a prokaryotic K+ channel that lacks a canonical voltage sensor and may thus provide a reduced system to inform on mechanism. In single-channel recordings, we observe that Po decreases with depolarization, with a half-maximal voltage of 96 ± 3 mV. This gating is kinetically distinct from blockade by internal Ca2+ or Ba2+, suggesting that it may arise from an intrinsic inactivation mechanism. Inactivation gating was shifted toward more positive voltages by increasing external [K+] (47 mV per 10-fold increase in [K+]), suggesting that K+ binding at the extracellular side of the channel stabilizes the open-conductive state. The open-conductive state was stabilized by other external cations, and selectivity of the stabilizing site followed the sequence: K+ ≈ Rb+ > Cs+ > Na+ > Li+ ≈ NMG+. Selectivity of the stabilizing site is weaker than that of sites that determine permeability of these ions, suggesting that the site may lie toward the external end of the MthK selectivity filter. We could describe MthK gating over a wide range of positive voltages and external [K+] using kinetic schemes in which the open-conductive state is stabilized by K+ binding to a site that is not deep within the electric field, with the voltage dependence of inactivation arising from both voltage-dependent K+ dissociation and transitions between nonconducting (inactivated) states. These results provide a quantitative working hypothesis for voltage-dependent, K+-sensitive inactivation gating, a property that may be common to other K+ channels.

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A unique mechanism of inactivation gating of the Kv channel family member Kv7.1 and its modulation by PIP2 and calmodulin

Science Advances ◽

10.1126/sciadv.abd6922 ◽

2020 ◽

Vol 6 (51) ◽

pp. eabd6922

Author(s):

Maya Lipinsky ◽

William Sam Tobelaim ◽

Asher Peretz ◽

Luba Simhaev ◽

Adva Yeheskel ◽

...

Keyword(s):

Family Member ◽

Selectivity Filter ◽

Wild Type ◽

Voltage Gated ◽

Kv Channel ◽

Kv Channels ◽

Dependent Inactivation ◽

Voltage Dependent ◽

Inactivation Gating ◽

Unique Mechanism

Inactivation of voltage-gated K+ (Kv) channels mostly occurs by fast N-type or/and slow C-type mechanisms. Here, we characterized a unique mechanism of inactivation gating comprising two inactivation states in a member of the Kv channel superfamily, Kv7.1. Removal of external Ca2+ in wild-type Kv7.1 channels produced a large, voltage-dependent inactivation, which differed from N- or C-type mechanisms. Glu295 and Asp317 located, respectively, in the turret and pore entrance are involved in Ca2+ coordination, allowing Asp317 to form H-bonding with the pore helix Trp304, which stabilizes the selectivity filter and prevents inactivation. Phosphatidylinositol 4,5-bisphosphate (PIP2) and Ca2+-calmodulin prevented Kv7.1 inactivation triggered by Ca2+-free external solutions, where Ser182 at the S2-S3 linker relays the calmodulin signal from its inner boundary to the external pore to allow proper channel conduction. Thus, we revealed a unique mechanism of inactivation gating in Kv7.1, exquisitely controlled by external Ca2+ and allosterically coupled by internal PIP2 and Ca2+-calmodulin.

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Complexity of the outward K+ current of the rat megakaryocyte

AJP Cell Physiology ◽

10.1152/ajpcell.1997.272.5.c1525 ◽

1997 ◽

Vol 272 (5) ◽

pp. C1525-C1531 ◽

Cited By ~ 5

Author(s):

E. Romero ◽

R. Sullivan

Keyword(s):

K Channel ◽

Delayed Rectifier ◽

Channel Blockers ◽

Excitable Cells ◽

Electrophysiological Properties ◽

Relative Contribution ◽

Delayed Rectifier Current ◽

Dependent Inactivation ◽

Voltage Dependent ◽

K Current

Megakaryocytes isolated from rat bone marrow express a voltage-dependent, outward K+ current with complex kinetics of activation and inactivation. We found that this current could be separated into at least two components based on differential responses to K+ channel blockers. One component, which exhibited features of the "transient" or "A-type" K+ current of excitable cells, was more strongly blocked by 4-aminopyridine (4-AP) than by tetrabutylammonium (TBA). This current, which we designated as "4-AP-sensitive" current, activated rapidly at potentials more positive than -40 mV and subsequently underwent rapid voltage-dependent inactivation. A separate current that activated slowly was blocked much more effectively by TBA than by 4-AP. This "TBA-sensitive" component, which resembled a typical delayed rectifier current, was much more resistant to voltage-dependent inactivation. The relative contribution of each of these components varied from cell to cell. The effect of charybdotoxin was similar to that of 4-AP. Our data indicate that the voltage-dependent K+ current of resting megakaryocytes is more complex than heretofore believed and support the emerging concept that megakaryocytes possess intricate electrophysiological properties.

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The gating cycle of a K+ channel at atomic resolution

eLife ◽

10.7554/elife.28032 ◽

2017 ◽

Vol 6 ◽

Cited By ~ 39

Author(s):

Luis G Cuello ◽

D Marien Cortes ◽

Eduardo Perozo

Keyword(s):

Conformational Changes ◽

Selectivity Filter ◽

Atomic Resolution ◽

K Channel ◽

Allosteric Interactions ◽

Inactivation Gating ◽

Pore Domain ◽

Fine Tune ◽

Conductive State

C-type inactivation in potassium channels helps fine-tune long-term channel activity through conformational changes at the selectivity filter. Here, through the use of cross-linked constitutively open constructs, we determined the structures of KcsA’s mutants that stabilize the selectivity filter in its conductive (E71A, at 2.25 Å) and deep C-type inactivated (Y82A at 2.4 Å) conformations. These structural snapshots represent KcsA’s transient open-conductive (O/O) and the stable open deep C-type inactivated states (O/I), respectively. The present structures provide an unprecedented view of the selectivity filter backbone in its collapsed deep C-type inactivated conformation, highlighting the close interactions with structural waters and the local allosteric interactions that couple activation and inactivation gating. Together with the structures associated with the closed-inactivated state (C/I) and in the well-known closed conductive state (C/O), this work recapitulates, at atomic resolution, the key conformational changes of a potassium channel pore domain as it progresses along its gating cycle.

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Structure of a pore-blocking toxin in complex with a eukaryotic voltage-dependent K+ channel

eLife ◽

10.7554/elife.00594 ◽

2013 ◽

Vol 2 ◽

Cited By ~ 122

Author(s):

Anirban Banerjee ◽

Alice Lee ◽

Ernest Campbell ◽

Roderick MacKinnon

Keyword(s):

Electron Density ◽

Selectivity Filter ◽

K Channel ◽

Wild Type ◽

Kv Channel ◽

Pore Blocking ◽

Kv Channels ◽

Filter Structure ◽

Conduction Pathway ◽

Voltage Dependent

Pore-blocking toxins inhibit voltage-dependent K+ channels (Kv channels) by plugging the ion-conduction pathway. We have solved the crystal structure of paddle chimera, a Kv channel in complex with charybdotoxin (CTX), a pore-blocking toxin. The toxin binds to the extracellular pore entryway without producing discernable alteration of the selectivity filter structure and is oriented to project its Lys27 into the pore. The most extracellular K+ binding site (S1) is devoid of K+ electron-density when wild-type CTX is bound, but K+ density is present to some extent in a Lys27Met mutant. In crystals with Cs+ replacing K+, S1 electron-density is present even in the presence of Lys27, a finding compatible with the differential effects of Cs+ vs K+ on CTX affinity for the channel. Together, these results show that CTX binds to a K+ channel in a lock and key manner and interacts directly with conducting ions inside the selectivity filter.

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Selectivity filter instability dominates the low intrinsic activity of the TWIK-1 K2P K+ channel

Journal of Biological Chemistry ◽

10.1074/jbc.ra119.010612 ◽

2019 ◽

Vol 295 (2) ◽

pp. 610-618

Author(s):

Ehsan Nematian-Ardestani ◽

Firdaus Abd-Wahab ◽

Franck C. Chatelain ◽

Han Sun ◽

Marcus Schewe ◽

...

Keyword(s):

Functional Activity ◽

Selectivity Filter ◽

Intrinsic Activity ◽

K Channel ◽

Open Probability ◽

Gating Mechanism ◽

Hydrophobic Barrier ◽

K2p Channels ◽

Voltage Dependent ◽

Low Levels

Two-pore domain K+ (K2P) channels have many important physiological functions. However, the functional properties of the TWIK-1 (K2P1.1/KCNK1) K2P channel remain poorly characterized because heterologous expression of this ion channel yields only very low levels of functional activity. Several underlying reasons have been proposed, including TWIK-1 retention in intracellular organelles, inhibition by posttranslational sumoylation, a hydrophobic barrier within the pore, and a low open probability of the selectivity filter (SF) gate. By evaluating these potential mechanisms, we found that the latter dominates the low intrinsic functional activity of TWIK-1. Investigating this further, we observed that the low activity of the SF gate appears to arise from the inefficiency of K+ in stabilizing an active (i.e. conductive) SF conformation. In contrast, other permeant ion species, such as Rb+, NH4+, and Cs+, strongly promoted a pH-dependent activated conformation. Furthermore, many K2P channels are activated by membrane depolarization via an SF-mediated gating mechanism, but we found here that only very strong nonphysiological depolarization produces voltage-dependent activation of heterologously expressed TWIK-1. Remarkably, we also observed that TWIK-1 Rb+ currents are potently inhibited by intracellular K+ (IC50 = 2.8 mm). We conclude that TWIK-1 displays unique SF gating properties among the family of K2P channels. In particular, the apparent instability of the conductive conformation of the TWIK-1 SF in the presence of K+ appears to dominate the low levels of intrinsic functional activity observed when the channel is expressed at the cell surface.

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Mechanism of the Voltage Sensitivity of IRK1 Inward-rectifier K+ Channel Block by the Polyamine Spermine

The Journal of General Physiology ◽

10.1085/jgp.200409242 ◽

2005 ◽

Vol 125 (4) ◽

pp. 413-426 ◽

Cited By ~ 45

Author(s):

Hyeon-Gyu Shin ◽

Zhe Lu

Keyword(s):

Steady State ◽

Voltage Dependence ◽

Ion Selectivity ◽

Inward Rectifier ◽

Selectivity Filter ◽

K Channel ◽

Voltage Sensitivity ◽

Channel Block ◽

Head Groups ◽

Voltage Dependent

IRK1 (Kir2.1) inward-rectifier K+ channels exhibit exceedingly steep rectification, which reflects strong voltage dependence of channel block by intracellular cations such as the polyamine spermine. On the basis of studies of IRK1 block by various amine blockers, it was proposed that the observed voltage dependence (valence ∼5) of IRK1 block by spermine results primarily from K+ ions, not spermine itself, traversing the transmembrane electrical field that drops mostly across the narrow ion selectivity filter, as spermine and K+ ions displace one another during channel block and unblock. If indeed spermine itself only rarely penetrates deep into the ion selectivity filter, then a long blocker with head groups much wider than the selectivity filter should exhibit comparably strong voltage dependence. We confirm here that channel block by two molecules of comparable length, decane-bis-trimethylammonium (bis-QAC10) and spermine, exhibit practically identical overall voltage dependence even though the head groups of the former are much wider (∼6 Å) than the ion selectivity filter (∼3 Å). For both blockers, the overall equilibrium dissociation constant differs from the ratio of apparent rate constants of channel unblock and block. Also, although steady-state IRK1 block by both cations is strongly voltage dependent, their apparent channel-blocking rate constant exhibits minimal voltage dependence, which suggests that the pore becomes blocked as soon as the blocker encounters the innermost K+ ion. These findings strongly suggest the existence of at least two (potentially identifiable) sequentially related blocked states with increasing numbers of K+ ions displaced. Consequently, the steady-state voltage dependence of IRK1 block by spermine or bis-QAC10 should increase with membrane depolarization, a prediction indeed observed. Further kinetic analysis identifies two blocked states, and shows that most of the observed steady-state voltage dependence is associated with the transition between blocked states, consistent with the view that the mutual displacement of blocker and K+ ions must occur mainly as the blocker travels along the long inner pore.

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Modulation of voltage-dependent inactivation of the inwardly rectifying K+ channel by chloramine-T

European Journal of Pharmacology ◽

10.1016/0014-2999(94)90493-6 ◽

1994 ◽

Vol 258 (3) ◽

pp. 281-284 ◽

Cited By ~ 8

Author(s):

Shin-ichi Koumi ◽

Ryoichi Sato ◽

Hirokazu Hayakawa

Keyword(s):

K Channel ◽

Dependent Inactivation ◽

Voltage Dependent ◽

Chloramine T ◽

Inwardly Rectifying

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Na+ Block and Permeation in a K+ Channel of Known Structure

The Journal of General Physiology ◽

10.1085/jgp.20028614 ◽

2002 ◽

Vol 120 (3) ◽

pp. 323-335 ◽

Cited By ~ 90

Author(s):

Crina M. Nimigean ◽

Christopher Miller

Keyword(s):

High Voltage ◽

Voltage Dependence ◽

Low Voltage ◽

Selectivity Filter ◽

K Channel ◽

Voltage Dependent

The effects of intracellular Na+ were studied on K+ and Rb+ currents through single KcsA channels. At low voltage, Na+ produces voltage-dependent block, which becomes relieved at high voltage by a “punchthrough” mechanism representing Na+ escaping from its blocking site through the selectivity filter. The Na+ blocking site is located in the wide, hydrated vestibule, and it displays unexpected selectivity for K+ and Rb+ against Na+. The voltage dependence of Na+ block reflects coordinated movements of the blocker with permeant ions in the selectivity filter.

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