Electrostatic interactions between transmembrane segments mediate folding of Shaker K+ channel subunits

Tiwari‐Woodruff, Seema K.; Schulteis, Christine T.; Mock, Allan F.; Papazian, Diane M.

doi:10.1016/s0006-3495(97)78797-6

Cited by 205 publications

(272 citation statements)

References 60 publications

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“…Previous work in Shaker channels suggests a structural basis for the novel effect of Ni 2ϩ on D274A channels (22,23). D274 is the homologue of E283 in the S2 segment of Shaker (Fig.…”

Section: Resultsmentioning

confidence: 95%

“…4A). Using a second-site suppressor strategy, we have presented evidence that E283 is involved in short-range electrostatic structural interactions with R368 and R371, two positively charged residues in the S4 segment that participate in the voltage-dependent conformational changes of S4 during activation gating of Shaker channels (22). Similar to D274A in eag, a neutralization mutation of E283, E283Q, does not eliminate functional expression of Shaker (15).…”

Section: Resultsmentioning

confidence: 99%

“…In contrast, the charge-reversal mutation, E283R, disrupts folding of the Shaker protein. The folding defect of E283R is suppressed specifically by R368E or R371E (22). Functional analysis suggests that during voltage-dependent activation of Shaker channels, first R368 and, subsequently, R371 enter an extracellular-facing gating pocket, where they interact with E283 (22,23).…”

Section: Resultsmentioning

confidence: 99%

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Structural basis of two-stage voltage-dependent activation in K⁺channels

Silverman

Roux

Papazian

2003

Proc. Natl. Acad. Sci. U.S.A.

119

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The structure of the voltage sensor and the detailed physical basis of voltage-dependent activation in ion channels have not been determined. We now have identified conserved molecular rearrangements underlying two major voltage-dependent conformational changes during activation of divergent K ؉ channels, ether-à -go-go (eag) and Shaker. Two conserved arginines of the S4 voltage sensor move sequentially into an extracellular gating pocket, where they interact with an acidic residue in S2. In eag, these transitions are modulated by a divalent ion that binds in the gating pocket. Conservation of key molecular details in the activation mechanism confirms that voltage sensors in divergent K ؉ channels share a common structure. Molecular modeling reveals that structural constraints derived from eag and Shaker specify the unique packing arrangement of transmembrane segments S2, S3, and S4 within the voltage sensor.

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“…Previous work in Shaker channels suggests a structural basis for the novel effect of Ni 2ϩ on D274A channels (22,23). D274 is the homologue of E283 in the S2 segment of Shaker (Fig.…”

Section: Resultsmentioning

confidence: 95%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Structural basis of two-stage voltage-dependent activation in K⁺channels

Silverman

Roux

Papazian

2003

Proc. Natl. Acad. Sci. U.S.A.

119

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“…49,[57][58][59][60][61] The rest of the transmembrane domains seem to remain mostly static as the S4 moves, providing a physical and electrostatic scaffold. 62,63 Given that the rest of the VSD remains static, as the charged residues in S4 move, they traverse its central portion, which contains an aromatic residue that has been dubbed the charge transfer center. 64 This residue is located at the region of the waist of the hourglass, and is the thinnest portion of the VSD structure, separating the outer and inner vestibules and keeping water and ions from traversing it.…”

Section: Molecular Mechanism Of Voltage Sensingmentioning

confidence: 99%

Functional diversity of potassium channel voltage-sensing domains

Islas¹

2016

Channels

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Voltage-gated potassium channels or Kv's are membrane proteins with fundamental physiological roles. They are composed of 2 main functional protein domains, the pore domain, which regulates ion permeation, and the voltage-sensing domain, which is in charge of sensing voltage and undergoing a conformational change that is later transduced into pore opening. The voltagesensing domain or VSD is a highly conserved structural motif found in all voltage-gated ion channels and can also exist as an independent feature, giving rise to voltage sensitive enzymes and also sustaining proton fluxes in proton-permeable channels. In spite of the structural conservation of VSDs in potassium channels, there are several differences in the details of VSD function found across variants of Kvs. These differences are mainly reflected in variations in the electrostatic energy needed to open different potassium channels. In turn, the differences in detailed VSD functioning among voltage-gated potassium channels might have physiological consequences that have not been explored and which might reflect evolutionary adaptations to the different roles played by Kv channels in cell physiology.

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“…The structure of the pore domain is thought to be similar to that of the bacterial potassium channel, KcsA, whose structure has been determined by x-ray diffraction (5-7). The remaining transmembrane segments, in particular the S2 to S4 segments, are thought to comprise the voltage-sensing domain of the channel (2,9,10). Of the four segments, S4 plays a pivotal role.…”

mentioning

confidence: 99%

Depolarization Induces Intersubunit Cross-linking in a S4 Cysteine Mutant of the Shaker Potassium Channel

Aziz¹,

Partridge²,

Munsey

et al. 2002

Journal of Biological Chemistry

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Voltage-gated potassium (K v ) channels are integral membrane proteins, composed of four subunits, each comprising six (S1-S6) transmembrane segments. S1-S4 comprise the voltage-sensing domain, and S5-S6 with the linker P-loop forms the ion conducting pore domain. During activation, S4 undergoes structural rearrangements that lead to the opening of the channel pore and ion conduction. To obtain details of these structural changes we have used the engineered disulfide bridge approach. For this we have introduced the L361C mutation at the extracellular end of S4 of the Shaker K channel and expressed the mutant channel in Xenopus oocytes. When exposed to mild oxidizing conditions (ambient oxygen or copper phenanthroline), Cys-361 formed an intersubunit disulfide bridge as revealed by the appearance of a dimeric band on Western blotting. As a consequence, the mutant channel suffered a significant loss in conductance (measured by two-electrode voltage clamp). Removal of native cysteines failed to prevent the disulfide formation, indicating that Cys-361 forms a disulfide with its counterpart in the neighboring subunit. The effect was voltage-dependent and occurred during channel activation after Cys-361 has been exposed to the extracellular phase. Although the disulfide bridge reduced the maximal conductance, it caused a hyperpolarizing shift in the conductance-voltage relationship and reduced the deactivation kinetics of the channel. The latter two effects suggest stabilization of the open state of the channel. In conclusion, we report that during activation the intersubunit distance between the N-terminal ends of the S4 segments of the L361C mutant Shaker K channel is reduced.

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Electrostatic interactions between transmembrane segments mediate folding of Shaker K+ channel subunits

Cited by 205 publications

References 60 publications

Structural basis of two-stage voltage-dependent activation in K⁺channels

Structural basis of two-stage voltage-dependent activation in K⁺channels

Functional diversity of potassium channel voltage-sensing domains

Depolarization Induces Intersubunit Cross-linking in a S4 Cysteine Mutant of the Shaker Potassium Channel

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Electrostatic interactions between transmembrane segments mediate folding of Shaker K+ channel subunits

Cited by 205 publications

References 60 publications

Structural basis of two-stage voltage-dependent activation in K+channels

Structural basis of two-stage voltage-dependent activation in K+channels

Functional diversity of potassium channel voltage-sensing domains

Depolarization Induces Intersubunit Cross-linking in a S4 Cysteine Mutant of the Shaker Potassium Channel

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Structural basis of two-stage voltage-dependent activation in K⁺channels

Structural basis of two-stage voltage-dependent activation in K⁺channels