Lu Z , Klem AM , Ramu Y .

GM61929 NIGMS NIH HHS , HL03814 NHLBI NIH HHS , R01 GM055560 NIGMS NIH HHS , R01 GM061929 NIGMS NIH HHS

	Figure 1. . Deletions of COOH-terminal residues in Shaker. (A) Sequence alignment of S6 and initial part of the COOH terminus for four voltage-gated K+ channels (the arrow indicates the last conserved residue in the region). (B–G) Current records from oocytes injected with RNA encoding Shaker or mutants that lack the indicated residues in the region under the horizontal bar in A. Dotted lines identify the zero current level. (H) G-V curves for Shaker and the HRE deletion mutant; the data points represent mean currents (± SEM, n = 15 and 6). The fitted curves correspond to the Boltzmann function, yielding V1/2 = −32.8 ± 0.3 mV and valence (Z) = 3.9 ± 0.3 for Shaker, and V1/2 = 6.8 ± 1.3 mV (n = 6) and Z = 1.1 ± 0.1 for the HRE deletion mutant.
	Figure 2. . Comparison between Shaker and a Shaker-KcsA chimera. (A) Schema of the polypeptide chain topology of a Shaker-KcsA chimeric channel subunit and partial sequences of the parent channels around the splicing sites. (B–D) Currents of Shaker (B) and the chimera (C), and the corresponding G-V curves (D) where the data points represent mean currents (± SEM; n = 9 and 15). The fitted curves superimposed on the data correspond to the Boltzmann function, yielding V1/2 = −32.8 ± 0.3 mV and valence (Z) = 3.9 ± 0.3 for Shaker, and V1/2 = 30.5 ± 0.3 mV and Z = 3.0 ± 0.1 for the chimera.
	Figure 3. . Shaker-KcsA chimeras with various distal junctions in S6. (A) Schema of the polypeptide chain topology of a Shaker-KcsA chimeric channel subunit and partial sequences of the parent channels around the splicing sites. All chimeras have the same proximal junction connecting Shaker's L396 to KcsA's G30 as indicated by the arrow. The distal junction is varied across the region, as pictured by the arrows, where the arrow type indicates whether a chimera expresses minimal (solid) or robust (dotted) voltage-independent conductance. (B–E) Current records of chimeric channels with the distal junction at four consecutive positions. (F) G-V curves (normalized tail currents vs. membrane voltage) for all chimeras expressing voltage-independent conductance at negative voltage. The fitted curves correspond to the Boltzmann function with an extra constant, “C,” which accounts for the voltage-independent conductance at negative voltage. (G) Values of V1/2 (mean ± SEM), Z, and C from the fits in F, where n is the number of oocytes examined. (H) The ratio (mean ± SEM, n = 5–11) of the currents at −80 and 80 mV versus the position of the distal junction in the chimeric constructs.
	Figure 4. . Currents of Shaker-KcsA chimeric channels recorded from a membrane patch versus a whole oocyte. (A) Schema of the polypeptide chain topology of a Shaker-KcsA chimeric channel subunit and partial sequences of the parent channels around the splicing sites. (B) Current records of the chimera. The first trace, below the voltage protocol, was recorded from a whole oocyte with a two-electrode voltage-clamp amplifier. The next six traces were recorded with a patch-clamp amplifier from a cell-attached patch, whereas the last one is the ensemble average of 50 current traces.
	Figure 5. . Time course of the current onset in chimeric channels. (A) Schema of the polypeptide chain topology of a Shaker-KcsA chimeric channel subunit and partial sequences of the parent channels around the splicing sites. (B) Current traces of the chimeric channels, whose initial part is shown in higher temporal resolution in C, where the beginning of the depolarization pulses is indicated by the arrow.
	Figure 6. . Nonfunctional Shaker-KcsA chimeras with various distal COOH-terminal junctions and their rescue by the replacement of the S4–S5 linker. (A and B) Two distinct sequence alignments between Shaker and KcsA in S6/M2-COOH terminus. The distal junction in four chimeric constructs is indicated by the arrows. (C) Alignment of Shaker's S4–S5 linker sequence and its KcsA counterpart (the arrows indicate two alternative proximal junctions). (D–K) Current records from oocytes injected with RNA encoding four chimeras with different distal junctions as indicated. Chimeras corresponding to D-G have a proximal junction that preserves Shaker's S4–S5 linker, whereas in those corresponding to H–K the Shaker S4–S5 linker is replaced by its KcsA counterpart.
	Figure 7. . Partial and full replacements of the S4–S5 linker by the counterparts in KcsA. All chimeras have an identical distal junction between KcsA's A109 and Shaker's I477 as in Fig. 3 E. (A) Sequence alignment between Shaker's S4–S5 linker and its KcsA counterpart (the downward arrow marks the center of the sequences). (B–E) Current records from chimeras containing Shaker's S4–S5 linker (B), and whose entire linker (C), or the proximal part (D), or the distal part (E) is replaced by the KcsA counterpart as pictured.
	Figure 8. . Restoration of Shaker's S4–S5 linker sequence. (A and B) Sequence alignment between Shaker's S4–S5 linker through the proximal part of S5 and the KcsA counterpart; the center of the linker is marked by the downward arrows. The arrows in A and B, respectively, indicate a systematic restoration of the Shaker sequence toward S4 and S5 from the center of the S4-S5 linker. The color and type of the arrows represent the chimeras which express minimal (solid black), robust (dotted black) voltage-independent conductance, or electrically nonfunctional chimeric constructs (gray). (C–F) Current records from chimeras with the proximal junction at four different positions. (G) The ratio (mean ± SEM, n = 5–8) of currents at −80 and 80 mV versus the position of the proximal junction in the chimeric constructs.
	Figure 9. . A DRK1-KcsA chimera and its HaTx sensitivity. (A) Schema of the polypeptide chain topology of a DRK1-KcsA chimeric channel subunit and partial sequences of the parent channels around the splicing sites. (B–E) Currents of DRK1 (B and D) and the chimera (C and E) without (B and C) and with (D and E) 4 μM HaTx. (F and G) G-V curves for DRK1 and the chimera with and without 4 μM HaTx; the data points represent mean currents (± SEM; n = 6–15). The fitted curves superimposed on the data without HaTx correspond to the Boltzmann function, yielding V1/2 = −0.4 ± 1.0 mV and Z = 2.5 ± 0.3 for DRK1, and V1/2 = 35.1 ± 0.4 mV and Z = 2.2 ± 0.4 for the chimera. The curves on the data with HaTx have no physical meaning.
	Figure 10. . Effects of including more KcsA pore residues by moving the junctions in the DRK1-KcsA chimera proximally or distally. (A) Schema of the polypeptide chain topology of a DRK1-KcsA chimeric channel subunit and partial sequences of the parent channels around the splicing sites. The shown chimera corresponding to B and D has the same distal junction as that in Fig. 9, A and C, but a different proximal junction (solid versus dotted arrow), whereas the one corresponding to C and E has the same proximal junction as that in Fig. 9, A and C, but a different distal junction (solid vs. dotted arrows). Currents shown were recorded in either the absence (B and C) or the presence (D and E) of 4 μM HaTx.
	Figure 11. . A cartoon of two Shaker subunits in the region from S4 to the initial part of the COOH terminus. Each ribbon corresponds to the structure of a KcsA subunit (Zhou et al., 2001). In each subunit, the blue region corresponds to T33 in M1 through L105 in M2, the red regions to W26-A32 in M1 and V106-T112 in M2, the green region to W113-E118 in M2, and the yellow region to Q119–A124. Each green strip represents S4 through the proximal part of the “S4–S5 linker.”
	Figure 12. . Minimal gating models. (A) A sequential model containing five closed states “C” and an open state “O”. (B) A minimal model reduced from that shown in A, where the channel is closed when the S4 is in the resting state (CS4), or open when the S4 is activated upon depolarization (OS4). (C) The minimal model shown in B with an additional transition accounting for the coupling interaction between the voltage sensors and the channel gate. It contains one closed state where the gate is coupled to the voltage sensors in the resting state (CS4), and two open states where the gate is coupled to the voltage sensors in the activated state (OS4) or it is decoupled from the sensors (O). KC is the equilibrium constant for the coupling step between the sensors and the gate, and KSG for the overall voltage sensing and gating transition. (D) A four-state allosteric model, where the voltage sensors move in the horizontal transitions, whereas the gate moves in the vertical. The gate can open with or without activating the voltage sensors (OS4 or OS4). KS and KG are, respectively, the equilibrium constants for the lower horizontal and the right vertical transitions. The coupling constant θ is defined as the ratio of the equilibrium constants either for the gating transitions without and with activating the voltage sensors, or for the voltage-sensing transitions without and with opening of the gate.
	Figure 13. . Simulations of G-V curves. (A) Simulated G-V curves with different coupling strength using equation 4, where KS = 10−9, KG = 1, and Z = 12, whereas θ is varied from 10−9 to 1 (right to left) in 10-fold increments. (B) Simulated G-V curves with the gating transition in different equilibria, where KS = 10−9, θ = 10−9, and Z = 12, whereas KG is varied from 1 to 1013 (right to left) in 10-fold increments.

Aggarwal, Contribution of the S4 segment to gating charge in the Shaker K+ channel. 1996, Pubmed, Xenbase

Aggarwal, Contribution of the S4 segment to gating charge in the Shaker K+ channel. 1996, Pubmed , Xenbase
Armstrong, Interaction of tetraethylammonium ion derivatives with the potassium channels of giant axons. 1971, Pubmed
Bezanilla, Gating of Shaker K+ channels: II. The components of gating currents and a model of channel activation. 1994, Pubmed , Xenbase
Caprini, Structural compatibility between the putative voltage sensor of voltage-gated K+ channels and the prokaryotic KcsA channel. 2001, Pubmed , Xenbase
Cha, Atomic scale movement of the voltage-sensing region in a potassium channel measured via spectroscopy. 1999, Pubmed
Chapman, Activation-dependent subconductance levels in the drk1 K channel suggest a subunit basis for ion permeation and gating. 1997, Pubmed , Xenbase
Cortes, Structural dynamics of the Streptomyces lividans K+ channel (SKC1): oligomeric stoichiometry and stability. 1997, Pubmed , Xenbase
Cox, Allosteric gating of a large conductance Ca-activated K+ channel. 1997, Pubmed , Xenbase
Doyle, The structure of the potassium channel: molecular basis of K+ conduction and selectivity. 1998, Pubmed
Frech, A novel potassium channel with delayed rectifier properties isolated from rat brain by expression cloning. 1989, Pubmed , Xenbase
Garcia, Purification and characterization of three inhibitors of voltage-dependent K+ channels from Leiurus quinquestriatus var. hebraeus venom. 1994, Pubmed , Xenbase
Glauner, Spectroscopic mapping of voltage sensor movement in the Shaker potassium channel. 1999, Pubmed , Xenbase
HODGKIN, A quantitative description of membrane current and its application to conduction and excitation in nerve. 1952, Pubmed
Hackos, Scanning the intracellular S6 activation gate in the shaker K+ channel. 2002, Pubmed , Xenbase
Ho, Cloning and expression of an inwardly rectifying ATP-regulated potassium channel. 1993, Pubmed , Xenbase
Holmgren, Trapping of organic blockers by closing of voltage-dependent K+ channels: evidence for a trap door mechanism of activation gating. 1997, Pubmed
Holmgren, N-type inactivation and the S4-S5 region of the Shaker K+ channel. 1996, Pubmed
Holmgren, The activation gate of a voltage-gated K+ channel can be trapped in the open state by an intersubunit metal bridge. 1998, Pubmed
Horn, Immobilizing the moving parts of voltage-gated ion channels. 2000, Pubmed
Horn, Conversation between voltage sensors and gates of ion channels. 2000, Pubmed
Horrigan, Allosteric voltage gating of potassium channels I. Mslo ionic currents in the absence of Ca(2+). 1999, Pubmed , Xenbase
Horrigan, Allosteric voltage gating of potassium channels II. Mslo channel gating charge movement in the absence of Ca(2+). 1999, Pubmed
Hoshi, Biophysical and molecular mechanisms of Shaker potassium channel inactivation. 1990, Pubmed , Xenbase
Hoshi, Two types of inactivation in Shaker K+ channels: effects of alterations in the carboxy-terminal region. 1991, Pubmed , Xenbase
Islas, Voltage sensitivity and gating charge in Shaker and Shab family potassium channels. 1999, Pubmed , Xenbase
Jackson, Dependence of acetylcholine receptor channel kinetics on agonist concentration in cultured mouse muscle fibres. 1988, Pubmed
Jackson, Spontaneous openings of the acetylcholine receptor channel. 1984, Pubmed
Jiang, Crystal structure and mechanism of a calcium-gated potassium channel. 2002, Pubmed
Jiang, The open pore conformation of potassium channels. 2002, Pubmed
Kamb, Multiple products of the Drosophila Shaker gene may contribute to potassium channel diversity. 1988, Pubmed
Kubo, Primary structure and functional expression of a mouse inward rectifier potassium channel. 1993, Pubmed , Xenbase
Larsson, Transmembrane movement of the shaker K+ channel S4. 1996, Pubmed , Xenbase
Li-Smerin, A localized interaction surface for voltage-sensing domains on the pore domain of a K+ channel. 2000, Pubmed , Xenbase
Li-Smerin, Localization and molecular determinants of the Hanatoxin receptors on the voltage-sensing domains of a K(+) channel. 2000, Pubmed , Xenbase
Li-Smerin, Helical structure of the COOH terminus of S3 and its contribution to the gating modifier toxin receptor in voltage-gated ion channels. 2001, Pubmed
Li-Smerin, Gating modifier toxins reveal a conserved structural motif in voltage-gated Ca2+ and K+ channels. 1998, Pubmed , Xenbase
Liman, Voltage-sensing residues in the S4 region of a mammalian K+ channel. 1991, Pubmed , Xenbase
Liu, Gated access to the pore of a voltage-dependent K+ channel. 1997, Pubmed
Lu, Ion conduction pore is conserved among potassium channels. 2001, Pubmed
MONOD, ON THE NATURE OF ALLOSTERIC TRANSITIONS: A PLAUSIBLE MODEL. 1965, Pubmed
MacKinnon, Determination of the subunit stoichiometry of a voltage-activated potassium channel. 1991, Pubmed , Xenbase
MacKinnon, Structural conservation in prokaryotic and eukaryotic potassium channels. 1998, Pubmed
Mannuzzu, Direct physical measure of conformational rearrangement underlying potassium channel gating. 1996, Pubmed , Xenbase
Morais-Cabral, Energetic optimization of ion conduction rate by the K+ selectivity filter. 2001, Pubmed
Papazian, Alteration of voltage-dependence of Shaker potassium channel by mutations in the S4 sequence. 1991, Pubmed , Xenbase
Perozo, S4 mutations alter gating currents of Shaker K channels. 1994, Pubmed , Xenbase
Perozo, Structural rearrangements underlying K+-channel activation gating. 1999, Pubmed
Pongs, Shaker encodes a family of putative potassium channel proteins in the nervous system of Drosophila. 1988, Pubmed
Ruiz, Single cyclic nucleotide-gated channels locked in different ligand-bound states. 1997, Pubmed , Xenbase
Schoppa, The size of gating charge in wild-type and mutant Shaker potassium channels. 1992, Pubmed
Schoppa, Activation of Shaker potassium channels. III. An activation gating model for wild-type and V2 mutant channels. 1998, Pubmed , Xenbase
Schrempf, A prokaryotic potassium ion channel with two predicted transmembrane segments from Streptomyces lividans. 1995, Pubmed
Seoh, Voltage-sensing residues in the S2 and S4 segments of the Shaker K+ channel. 1996, Pubmed , Xenbase
Swartz, Mapping the receptor site for hanatoxin, a gating modifier of voltage-dependent K+ channels. 1997, Pubmed
Swartz, An inhibitor of the Kv2.1 potassium channel isolated from the venom of a Chilean tarantula. 1995, Pubmed
Swartz, Hanatoxin modifies the gating of a voltage-dependent K+ channel through multiple binding sites. 1997, Pubmed , Xenbase
Tempel, Sequence of a probable potassium channel component encoded at Shaker locus of Drosophila. 1987, Pubmed
Tibbs, Allosteric activation and tuning of ligand efficacy in cyclic-nucleotide-gated channels. 1997, Pubmed , Xenbase
Tristani-Firouzi, Interactions between S4-S5 linker and S6 transmembrane domain modulate gating of HERG K+ channels. 2002, Pubmed , Xenbase
VanDongen, Alteration and restoration of K+ channel function by deletions at the N- and C-termini. 1990, Pubmed
Yang, Evidence for voltage-dependent S4 movement in sodium channels. 1995, Pubmed
Yang, Determination of the subunit stoichiometry of an inwardly rectifying potassium channel. 1995, Pubmed , Xenbase
Yang, Molecular basis of charge movement in voltage-gated sodium channels. 1996, Pubmed
Zagotta, Shaker potassium channel gating. III: Evaluation of kinetic models for activation. 1994, Pubmed , Xenbase
Zheng, Selectivity changes during activation of mutant Shaker potassium channels. 1997, Pubmed , Xenbase
Zhou, Chemistry of ion coordination and hydration revealed by a K+ channel-Fab complex at 2.0 A resolution. 2001, Pubmed
del Camino, Blocker protection in the pore of a voltage-gated K+ channel and its structural implications. 2000, Pubmed
del Camino, Tight steric closure at the intracellular activation gate of a voltage-gated K(+) channel. 2001, Pubmed