Mark E. Jurman scite author profile

Voltage-activated K+ channels are integral membrane proteins that open or close a K(+)-selective pore in response to changes in transmembrane voltage. Although the S4 region of these channels has been implicated as the voltage sensor, little is known about how opening and closing of the pore is accomplished. We explored the gating process by introducing cysteines at various positions thought to lie in or near the pore of the Shaker K+ channel, and by testing their ability to be chemically modified. We found a series of positions in the S6 transmembrane region that react rapidly with water-soluble thiol reagents in the open state but not the closed state. An open-channel blocker can protect several of these cysteines, showing that they lie in the ion-conducting pore. At two of these sites, Cd2+ ions bind to the cysteines without affecting the energetics of gating; at a third site, Cd2+ binding holds the channel open. The results suggest that these channels open and close by the movement of an intracellular gate, distinct from the selectivity filter, that regulates access to the pore.

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Dynamic Rearrangement of the Outer Mouth of a K+ Channel during Gating

Liu

Jurman

Yellen

1996

Neuron

429

415

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With prolonged stimulation, voltage-activated K+ channels close by a gating process called inactivation. This inactivation gating can occur by two distinct molecular mechanisms: N-type, in which a tethered particle blocks the intracellular mouth of the pore, and C-type, which involves a closure of the external mouth. The functional motion involved in C-type inactivation was studied by introducing cysteine residues at the outer mouth of Shaker K+ channels through mutagenesis, and by measuring state-dependent changes in accessibility to chemical modification. Modification of three adjacent residues in the outer mouth was 130-10,000-fold faster in the C-type inactivated state than in the closed state. At one position, state-dependent bridging or crosslinking between subunits was also possible. These results give a consistent picture in which C-type inactivation promotes a local rearrangement and constriction of the channel at the outer mouth.

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Mutations Affecting Internal TEA Blockade Identify the Probable Pore-Forming Region of a K ⁺ Channel

Yellen

Jurman

Abramson

et al. 1991

Science

626

296

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The active site of voltage-activated potassium channels is a transmembrane aqueous pore that permits ions to permeate the cell membrane in a rapid yet highly selective manner. A useful probe for the pore of potassium-selective channels is the organic ion tetraethylammonium (TEA), which binds with millimolar affinity to the intracellular opening of the pore and blocks potassium current. In the potassium channel encoded by the Drosophila Shaker gene, an amino acid residue that specifically affects the affinity for intracellular TEA has now been identified by site-directed mutagenesis. This residue is in the middle of a conserved stretch of 18 amino acids that separates two locations that are both near the external opening of the pore. These findings suggest that this conserved region is intimately involved in the formation of the ion conduction pore of voltage-activated potassium channels. Further, a stretch of only eight amino acid residues must traverse 80 percent of the transmembrane electric potential difference.

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Mark E. Jurman

Gated Access to the Pore of a Voltage-Dependent K+ Channel

Dynamic Rearrangement of the Outer Mouth of a K+ Channel during Gating

Mutations Affecting Internal TEA Blockade Identify the Probable Pore-Forming Region of a K ⁺ Channel

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Mark E. Jurman

Gated Access to the Pore of a Voltage-Dependent K+ Channel

Dynamic Rearrangement of the Outer Mouth of a K+ Channel during Gating

Mutations Affecting Internal TEA Blockade Identify the Probable Pore-Forming Region of a K + Channel

Contact Info

Product

Resources

About

Mutations Affecting Internal TEA Blockade Identify the Probable Pore-Forming Region of a K ⁺ Channel