A shaker Potassium Channel with a Miniature Engineered Voltage Sensor

AbstractPositively-charged amino acids respond to membrane potential changes to drive voltage sensor movement in voltage-gated ion channels, but determining the trajectory of voltage sensor gating charges has proven difficult. We optically tracked the movement of the two most extracellular charged residues (R1, R2) in the Shaker potassium channel voltage sensor using a fluorescent positively-charged bimane derivative (qBBr) that is strongly quenched by tryptophan. By individually mutating residues to tryptophan within the putative trajectory of gating charges, we observed that the charge pathway during activation is a rotation and a tilted translation that differs between R1 and R2 and is distinct from their deactivation pathway. Tryptophan-induced quenching of qBBr also indicates that a crucial residue of the hydrophobic plug is linked to the Cole-Moore shift through its interaction with R1. Finally, we show that this approach extends to additional voltage-sensing membrane proteins using the Ciona intestinalis voltage sensitive phosphatase (CiVSP).

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Tracking the movement of discrete gating charges in a voltage-gated potassium channel

eLife ◽

10.7554/elife.58148 ◽

2021 ◽

Vol 10 ◽

Author(s):

Michael F Priest ◽

Elizabeth EL Lee ◽

Francisco Bezanilla

Keyword(s):

Potassium Channel ◽

Voltage Sensor ◽

Charge Motion ◽

Shaker Potassium Channel ◽

Voltage Gated ◽

Charged Amino Acids ◽

Voltage Gated Ion Channels ◽

Sensing Membrane ◽

Positively Charged ◽

Gating Charges

Positively-charged amino acids respond to membrane potential changes to drive voltage sensor movement in voltage-gated ion channels, but determining the displacements of voltage sensor gating charges has proven difficult. We optically tracked the movement of the two most extracellular charged residues (R1, R2) in the Shaker potassium channel voltage sensor using a fluorescent positively-charged bimane derivative (qBBr) that is strongly quenched by tryptophan. By individually mutating residues to tryptophan within the putative pathway of gating charges, we observed that the charge motion during activation is a rotation and a tilted translation that differs between R1 and R2. Tryptophan-induced quenching of qBBr also indicates that a crucial residue of the hydrophobic plug is linked to the Cole-Moore shift through its interaction with R1. Finally, we show that this approach extends to additional voltage-sensing membrane proteins using the Ciona intestinalis voltage sensitive phosphatase (CiVSP) (Murata et al., 2005a).

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Quantitative Mapping of Interactions in the Voltage-Sensor Pore Interface of the Shaker Potassium Channel

Biophysical Journal ◽

10.1016/j.bpj.2014.11.667 ◽

2015 ◽

Vol 108 (2) ◽

pp. 119a

Author(s):

Kevin Oelstrom ◽

Ana Fernandez-Mariño ◽

Baron Chanda

Keyword(s):

Potassium Channel ◽

Voltage Sensor ◽

Shaker Potassium Channel ◽

Quantitative Mapping

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Deletion of the S3–S4 Linker in theShaker Potassium Channel Reveals Two Quenching Groups near the outside of S4

The Journal of General Physiology ◽

10.1085/jgp.115.2.209 ◽

2000 ◽

Vol 115 (2) ◽

pp. 209-222 ◽

Cited By ~ 28

Author(s):

J.B. Sørensen ◽

A. Cha ◽

R. Latorre ◽

E. Rosenman ◽

F. Bezanilla

Keyword(s):

Potassium Channel ◽

Conformational Changes ◽

Deletion Mutant ◽

Transient State ◽

Voltage Sensor ◽

Charge Movement ◽

Shaker Potassium Channel ◽

Gating Charge ◽

In The Wild ◽

S4 Segment

When attached outside the voltage-sensing S4 segment of the Shaker potassium channel, the fluorescent probe tetramethylrhodamine (TMRM) undergoes voltage-dependent fluorescence changes (ΔF) due to differential interaction with a pH-titratable external protein-lined vestibule (Cha, A., and F. Bezanilla. 1998. J. Gen. Physiol. 112:391–408.). We attached TMRM at the same sites [corresponding to M356C and A359C in the wild-type (wt) channel] in a deletion mutant of Shaker where all but the five amino acids closest to S4 had been removed from the S3–S4 linker. In the deletion mutant, the maximal ΔF/F seen was diminished 10-fold, and the ΔF at M356C became pH independent, suggesting that the protein-lined vestibule is made up in large part by the S3–S4 linker. The residual ΔF showed that the probe still interacted with two putative quenching groups near the S4 segment. One group was detected by M356C-TMRM (located outside of S3 in the deletion mutant) and reported on deactivation gating charge movement when applying hyperpolarizing voltage steps from a holding potential of 0 mV. During activating voltage steps from a holding potential of −90 mV, the fluorescence lagged considerably behind the movement of gating charge over a range of potentials. Another putative quenching group was seen by probes attached closer to the S4 and caused a ΔF at extreme hyperpolarizations (more negative than −90 mV) only. A signal from the interaction with this group in the wt S3–S4 linker channel (at L361C) correlated with gating charge moving in the hyperpolarized part of the Q-V curve. Probe attached at A359C in the deletion mutant and at L361C in wt channel showed a biphasic ΔF as the probe oscillated between the two groups, revealing that there is a transient state of the voltage sensor in between, where the probe has maximal fluorescence. We conclude that the voltage sensor undergoes two distinct conformational changes as seen from probes attached outside the S4 segment.

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