Cox DH , Cui J , Aldrich RW .

MH 48108 NIMH NIH HHS

	Figure 2. (A) Schematic representation of the 55 states of a fourfold symmetric homotetrameric channel that follow from the state diagram for each subunit in Fig. 1 A. These states, as well the 73 physically distinct states that a twofold symmetric homotetrameric channel can occupy (not shown), were found by enumeration. Each grouping of states represents those with a different number of Ca2+ ions bound as indicated. (B) Illustration of some equivalent states when no distinction is made between two activated subunits adjacent to one another and two activated subunits diagonally opposed to one another. (C) Scheme I, 35-state channel gating scheme that follows from assumptions 1, 2, and 3 if the simplifying assumption illustrated in B is made. In general, when subunit position is not taken into consideration, the number of states of a homomultimer with r subunits, each subunit of which can exist in n states, is given by the binomial coefficient (n + r − 1: n − 1) (Feller, 1968). Horizontal arrows represent Ca2+ binding steps. For simplicity, not all horizontal steps are represented. Each vertical grouping includes states with a given number of bound Ca2+ as indicated. Each horizontal tier represents a different number of activated voltage sensors.
	Figure 1. (A) Schematic representation of the four states of a channel subunit, which follow from assumptions 2 and 3. The filled circles represent the binding of a Ca2+ ion. The change in color from white to grey represents a voltage-dependent conformational change. These conventions are also followed in Figs. 2 and 3. (B) Illustration of an arrangement of four identical subunits that have twofold rotational symmetry about an axis perpendicular to the page passing through the point represented by the black dot. (C) Illustration of an arrangement of four identical subunits that have fourfold rotational symmetry about an axis perpendicular to the page passing through the point represented by the black dot.
	Figure 9. mslo (left) and voltage-dependent MWC model (right) traces determined at the indicated [Ca] and membrane voltages. Voltage steps were 20-ms long from the following holding voltages: 0 (0.84 μM [Ca]), −100 (10.2 μM [Ca]), and −120 mV (124 μM [Ca]). In each current family, the voltage increment was 10 mV. Repolarizations were to −80 mV. For display, model and mslo current families were scaled to have the same maximum amplitude at +90 mV. Single exponential fits to the activation time courses are superimposed on both the mslo and model traces. The fits to the model traces are hard to discern as they follow closely the time courses of activation. Data and model are from patch 1 (see Table III).
	Figure 4. V1/2 vs. [Ca] plots highlighting the three patches displayed in Fig. 5. Each data point represents the voltage at which the mslo G-V relation reached half maximal activation at the indicated [Ca]. In A–C, the data are from the same 22 patches; however, in A the V1/2 values for patch 1 (Fig. 5) are darkened, in B the V1/2 values for patch 2 (Fig. 5) are darkened, and in C the V1/2 values for patch 3 (Fig. 5) are darkened.
	Figure 5. mslo G-V relations determined from macroscopic currents at the following [Ca]: ∼2 nM (○), 0.84 (•), 1.7 (*), 4.5 (□), 10.2 (▪), 65 (▵), and 124 μM (▴). Data from three patches are displayed (A–C). Solid lines represent best least squares voltage- dependent MWC model fits to these data over the [Ca] range ∼2 nM–124 μM. Parameters for these fits are listed in Table I. The dashed lines represent best overall MWC model fits taking into account both kinetic and steady state data. Parameters for these fits were found by eye and are listed in Table III. Two sets of data recorded with 1.7 μM [Ca] are displayed in A corresponding to the beginning (*) and end (#) of this ∼40-min experiment. The grey symbols are data from 490 (▿), and 1,000 μM (▸◂) [Ca]. Model fits to these data are also included (grey solid and dashed lines). Patch 1 contained ∼100 channels. Patch 2 contained ∼70 channels. Patch 3 contained ∼80 channels. Similar data from patch 2 were displayed in Cui et al. (1997; Fig. 5 A). Typically, three or four voltage families were recorded consecutively and averaged before analysis.
	Figure 6. Equilibrium behavior of voltage- dependent MWC models. (A) Model G-V curves at 0, 1, 10, 100, and 1,000 μM [Ca]. The parameters used to generate these curves are indicated on the figure, and are similar to those used to fit the mslo data in Fig. 5 (Table III). (B) The effects of changing Q from 1.4 to 2.8. (C) The effects of changing L(0) from 2,000 to 2. (D) The effects of changing KC from 10 to 100 μM. (E) Plots of V1/2 vs. log[Ca] for the conditions indicated in A (•), B (□), C (▵), and D (○). (F) At higher voltages, fewer bound Ca2+ are necessary to achieve a given level of open probability. Plotted is open probability (Popen) as a function of the mean number of Ca2+ ions bound to the model channel. Each curve represents a different voltage as indicated. Model parameters were the same as in A. Open probability was calculated from Eq. 5. The mean number of Ca2+ ions bound to the model channel (M) was calculated from the relation M = 4(L(KO/KC)([Ca]/KO)(1 + [Ca]/ KC)3 + ([Ca]/KO)(1 + [Ca]/KO)3)/(L(1 + [Ca]/ KC)4 + (1 + [Ca]/KO)4) where L is given by Eq. 3.
	Figure 7. (A) Voltage-dependent MWC model, (B) general 10-state model, and (C) two-tiered KNF model least squares best fits to the steady state data of patch 2 (of Fig. 5), with data points at 490 and 1,000 μM included in the fitting. The parameters for the voltage-dependent MWC model fit are: KC = 13.28 μM, KO = 1.17 μM, L(0) = 3,052.5, Q = 1.44e. The parameters for the least squares general 10-state model fit are listed in Table II. The parameters for the two-tiered KNF model fit are: KCA = 0.046 μM, KCB = 1.42 μM, KCC = 43.90 μM, KOA = 0.047 μM, KOB = 0.100 μM, KOC = 0.213 μM, Q = 1.46e, L(0) = 4,328. The dashed lines in B represent a fit to the general 10-state model with the following parameters: KC1 = 9.03 μM, KC2 = 5.97 μM, KC3 = 5.90 μM, KC4 = 135.7 μM, KO1 = 0.68 μM, KO2 = 0.85 μM, KO3 = 1.19 μM, KO4 = 1.65 μM, Q = 1.38e, L(0) = 2,882.5.
	Figure 8. mslo (A) and voltage-dependent MWC model (B) Ca2+ dose-response curves are plotted for seven different voltages ranging from −40 to +80 mV in 20-mV steps (symbols). Each curve in A and B has been fitted with the Hill equation (Eq. 8) (solid curves) and the parameters of these fits are plotted as a function of voltage in C, D (see footnote 4), and E. mslo data and fit parameters are indicated with (•). Simulated data and fit parameters are indicated with (○). Data are from patch 1 (Fig. 5 A). The voltage-dependent MWC model parameters used for these simulations are those listed in Table III. Similar data from patch 1 were displayed in Cui et al. (1997) (Fig. 13).
	Figure 13. Comparison of mslo and model macroscopic deactivation kinetics over a wide range of conditions. [Ca] are as indicated. mslo (•), voltage-dependent MWC model (○), and general 10-state model (solid lines) currents were fitted with exponential functions starting 200 μs after the beginning of a voltage step to the indicated test voltage from a depolarized voltage where the channels were near maximally activated. The time constants of these fits are plotted as a function of test voltage. Prepulse potentials were: +180 (0.84 μM [Ca]), +160 (1.7 μM [Ca]), +120 (4.5 μM [Ca]), +100 (10.2 μM [Ca]), +90 (65 μM [Ca]), and +90 mV (124 μM [Ca]). Notice the change in range of the voltage axis as [Ca] is increased. Data are from patch 1. The voltage-dependent MWC model parameters are given in Table III. The general 10-state model parameters are given in Fig. 12.
	Figure 12. Comparison of mslo and model macroscopic activation kinetics over a wide range of conditions. [Ca] are as indicated. mslo (•), voltage-dependent MWC model (○), and general 10-state model (solid lines) traces were fitted with exponential functions starting 200 μs after the beginning of a voltage step to the indicated test voltage. The time constants of these fits are plotted as a function of test voltage. Two sets of data are displayed for 1.7 μM [Ca], corresponding to data recorded at the beginning (•) and the end (#) of the experiment. Notice the change in range of the voltage axis as [Ca] is increased. Holding voltages were: −50 (0.84 μM [Ca]), −80 (1.7 μM [Ca]), −100 (4.5 μM [Ca]), −100 (10.2 μM [Ca]), −120 (65 μM [Ca]), and −120 mV (124 μM [Ca]). Data are from patch 1. The voltage-dependent MWC model parameters are given in Table III. The general 10-state model parameters are as follows: L(0) = 1,647, Q = 1.40e, KC1 = 10.08 μM, KC2 = 5.22 μM, KC3 = 5.82 μM, KC4 = 70.64 μM, KO1 = 0.890 μM, KO2 = 0.764 μM, KO3 = 0.862 μM, KO4 = 1.52 μM, C0 → O0 = 2.75 s−1, C1 → O1 = 6.0 s−1, C2 → O2 = 32 s−1, C3 → O3 = 165 s−1, C4 → O4 = 1,000 s−1, O0 → C0 = 4,529.2 s−1, O1 → C1 = 872.7 s−1, O2 → C2 = 681.5 s−1, O3 → C3 = 520.1 s−1, O4 → C4 = 67.6 s−1, qforward = 0.70e, qbackward = −0.70e.
	Figure 10. Comparison of mslo and voltage-dependent MWC model macroscopic activation kinetics. mslo and model traces are shown normalized to their maximum values and superimposed. [Ca] and membrane voltages are as indicated. Holding voltages for each [Ca] are as stated in the legend to Fig. 9. Data and model are from patch 1 (see Table III).
	Figure 11. Comparison of mslo and voltage-dependent MWC model macroscopic deactivation kinetics. mslo and model currents are shown normalized to their values 200 μs after stepping to the indicated voltage from a voltage at which the channels were near maximally activated, and superimposed. Prepulse voltages were +180 (0.84 μM [Ca]), +100 (10.2 μM [Ca]), and +90 mV (124 μM [Ca]). [Ca] are as indicated. Data and model are from patch 1 (see Table III).
	Figure 14. Comparison of mslo and voltage- dependent MWC model single channel currents. (Left) mslo data from a single membrane patch. The voltage was held at +50 mV and currents were recorded at the indicated [Ca]. The traces displayed are from consecutive 100-ms time increments. The data were low base filtered at effectively 3.3 kHz before display. (Right) Simulated voltage-dependent MWC model single channel currents generated for the same conditions as the data on the left. The model for patch 1 was used. For parameters see Table III.
	Figure 15. The effects of modifications or mutations on model gating behavior. (A) Plots of V1/2 vs. log[Ca] for a hypothetical wild-type voltage-dependent MWC model channel (•), as well as after four types of modification: an increase in Q to 2.8 (□), a decrease in L(0) to 2 (▵), an increase in KC to 100 μM (○), and elimination of cooperative interactions between voltage-dependent conformational changes (⋄). The parameters for the wild-type model are as in Fig. 6 A. To simulate a loss of cooperativity between voltage-sensing elements, an expression for the equilibrium open probability of scheme I was used with L(0) = (1/2,000)1/4, Q = 0.35, KC = 10 μM, and KO = 1 μM where these parameters represent the properties of each individual subunit. No cooperativity between Ca2+ binding sites or voltage sensing elements was included. (B) Plots of QappV1/2 vs. log[Ca] for the same simulated data as in A. Qapp was determined from Boltzmann fits to the G-V relations for each case. (C) The plots in A have been shifted so as to have the same V1/2 value as the hypothetical wild type at 0 [Ca]. (D) The plots in B have been shifted so as to have the same QappV1/2 value as the hypothetical wild type at 0 [Ca].

Adelman, Calcium-activated potassium channels expressed from cloned complementary DNAs. 1992, Pubmed, Xenbase

Adelman, Calcium-activated potassium channels expressed from cloned complementary DNAs. 1992, Pubmed , Xenbase
Aggarwal, Contribution of the S4 segment to gating charge in the Shaker K+ channel. 1996, Pubmed , Xenbase
Art, The calcium-activated potassium channels of turtle hair cells. 1995, Pubmed
Atkinson, A component of calcium-activated potassium channels encoded by the Drosophila slo locus. 1991, Pubmed
Barrett, Properties of single calcium-activated potassium channels in cultured rat muscle. 1982, Pubmed
Blair, Developmental acquisition of Ca2+-sensitivity by K+ channels in spinal neurones. , Pubmed , Xenbase
Butler, mSlo, a complex mouse gene encoding "maxi" calcium-activated potassium channels. 1993, Pubmed , Xenbase
Carl, Ca2+-activated K channels of canine colonic myocytes. 1989, Pubmed
Colquhoun, On the stochastic properties of bursts of single ion channel openings and of clusters of bursts. 1982, Pubmed
Colquhoun, On the stochastic properties of single ion channels. 1981, Pubmed
Cornejo, Modification of Ca2+-activated K+ channels in cultured medullary thick ascending limb cells by N-bromoacetamide. 1987, Pubmed
Cox, Separation of gating properties from permeation and block in mslo large conductance Ca-activated K+ channels. 1997, Pubmed
Cui, Intrinsic voltage dependence and Ca2+ regulation of mslo large conductance Ca-activated K+ channels. 1997, Pubmed , Xenbase
DiChiara, Distinct effects of Ca2+ and voltage on the activation and deactivation of cloned Ca(2+)-activated K+ channels. 1995, Pubmed , Xenbase
Dworetzky, Phenotypic alteration of a human BK (hSlo) channel by hSlobeta subunit coexpression: changes in blocker sensitivity, activation/relaxation and inactivation kinetics, and protein kinase A modulation. 1996, Pubmed
Edelstein, A kinetic mechanism for nicotinic acetylcholine receptors based on multiple allosteric transitions. 1996, Pubmed
Falke, Molecular tuning of ion binding to calcium signaling proteins. 1994, Pubmed
Galzi, The multiple phenotypes of allosteric receptor mutants. 1996, Pubmed
Giangiacomo, Functional reconstitution of the large-conductance, calcium-activated potassium channel purified from bovine aortic smooth muscle. 1995, Pubmed
Golowasch, Allosteric effects of Mg2+ on the gating of Ca2+-activated K+ channels from mammalian skeletal muscle. 1986, Pubmed
Goulding, Molecular mechanism of cyclic-nucleotide-gated channel activation. 1994, Pubmed , Xenbase
Heginbotham, The aromatic binding site for tetraethylammonium ion on potassium channels. 1992, Pubmed
Holt, The pathway of allosteric control as revealed by hemoglobin intermediate states. 1995, Pubmed
Horn, Statistical methods for model discrimination. Applications to gating kinetics and permeation of the acetylcholine receptor channel. 1987, Pubmed
Hoshi, Shaker potassium channel gating. I: Transitions near the open state. 1994, Pubmed , Xenbase
Kaupp, Primary structure and functional expression from complementary DNA of the rod photoreceptor cyclic GMP-gated channel. 1989, Pubmed , Xenbase
Koshland, Comparison of experimental binding data and theoretical models in proteins containing subunits. 1966, Pubmed
Larsson, Transmembrane movement of the shaker K+ channel S4. 1996, Pubmed , Xenbase
Latorre, Reconstitution in planar lipid bilayers of a Ca2+-dependent K+ channel from transverse tubule membranes isolated from rabbit skeletal muscle. 1982, Pubmed
Liman, Voltage-sensing residues in the S4 region of a mammalian K+ channel. 1991, Pubmed , Xenbase
Liu, Subunit stoichiometry of cyclic nucleotide-gated channels and effects of subunit order on channel function. 1996, Pubmed
Logothetis, Gating charge differences between two voltage-gated K+ channels are due to the specific charge content of their respective S4 regions. 1993, Pubmed , Xenbase
Lopez, Hydrophobic substitution mutations in the S4 sequence alter voltage-dependent gating in Shaker K+ channels. 1991, Pubmed , Xenbase
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, Functional stoichiometry of Shaker potassium channel inactivation. 1993, Pubmed , Xenbase
MacKinnon, Functional modification of a Ca2+-activated K+ channel by trimethyloxonium. 1989, Pubmed
Magleby, Burst kinetics of single calcium-activated potassium channels in cultured rat muscle. 1983, Pubmed
Mannuzzu, Direct physical measure of conformational rearrangement underlying potassium channel gating. 1996, Pubmed , Xenbase
Marks, Calcium currents in the A7r5 smooth muscle-derived cell line. An allosteric model for calcium channel activation and dihydropyridine agonist action. 1992, Pubmed
Markwardt, Gating of maxi K+ channels studied by Ca2+ concentration jumps in excised inside-out multi-channel patches (myocytes from guinea pig urinary bladder). 1992, Pubmed
Mayer, The activation of calcium and calcium-activated potassium channels in mammalian colonic smooth muscle by substance P. 1990, Pubmed
McCobb, A human calcium-activated potassium channel gene expressed in vascular smooth muscle. 1995, Pubmed , Xenbase
McManus, Accounting for the Ca(2+)-dependent kinetics of single large-conductance Ca(2+)-activated K+ channels in rat skeletal muscle. 1991, Pubmed
McManus, Calcium-activated potassium channels: regulation by calcium. 1991, Pubmed
McManus, Functional role of the beta subunit of high conductance calcium-activated potassium channels. 1995, Pubmed , Xenbase
McManus, Kinetic states and modes of single large-conductance calcium-activated potassium channels in cultured rat skeletal muscle. 1988, Pubmed
McManus, Inverse relationship of the durations of adjacent open and shut intervals for C1 and K channels. , Pubmed
Meera, A calcium switch for the functional coupling between alpha (hslo) and beta subunits (KV,Ca beta) of maxi K channels. 1996, Pubmed , Xenbase
Methfessel, The gating of single calcium-dependent potassium channels is described by an activation/blockade mechanism. 1982, Pubmed
Moczydlowski, Gating kinetics of Ca2+-activated K+ channels from rat muscle incorporated into planar lipid bilayers. Evidence for two voltage-dependent Ca2+ binding reactions. 1983, Pubmed
Murcott, The cooperative binding of fructose-1,6-bisphosphate to yeast pyruvate kinase. 1992, Pubmed
Neet, Cooperativity in enzyme function: equilibrium and kinetic aspects. 1995, Pubmed
Oberhauser, Activation by divalent cations of a Ca2+-activated K+ channel from skeletal muscle membrane. 1988, Pubmed
Pallotta, Calcium-activated potassium channels in rat muscle inactivate from a short-duration open state. 1985, Pubmed
Papazian, Alteration of voltage-dependence of Shaker potassium channel by mutations in the S4 sequence. 1991, Pubmed , Xenbase
Pauling, The Oxygen Equilibrium of Hemoglobin and Its Structural Interpretation. 1935, Pubmed
Perutz, Haemoglobin: structure, function and synthesis. 1976, Pubmed
Pérez, Reconstitution of expressed KCa channels from Xenopus oocytes to lipid bilayers. 1994, Pubmed , Xenbase
Reinhart, A family of calcium-dependent potassium channels from rat brain. 1989, Pubmed
Segal, Maxi K+ channels and their relationship to the apical membrane conductance in Necturus gallbladder epithelium. 1990, Pubmed
Seoh, Voltage-sensing residues in the S2 and S4 segments of the Shaker K+ channel. 1996, Pubmed , Xenbase
Shen, Tetraethylammonium block of Slowpoke calcium-activated potassium channels expressed in Xenopus oocytes: evidence for tetrameric channel formation. 1994, Pubmed , Xenbase
Sheppard, Kinetics of voltage- and Ca2+ activation and Ba2+ blockade of a large-conductance K+ channel from Necturus enterocytes. 1988, Pubmed
Sigworth, Voltage gating of ion channels. 1994, Pubmed
Silberberg, Wanderlust kinetics and variable Ca(2+)-sensitivity of Drosophila, a large conductance Ca(2+)-activated K+ channel, expressed in oocytes. 1996, Pubmed , Xenbase
Singer, Characterization of calcium-activated potassium channels in single smooth muscle cells using the patch-clamp technique. 1987, Pubmed
Stevens, Interactions between intrinsic membrane protein and electric field. An approach to studying nerve excitability. 1978, Pubmed
Tabcharani, Ca2+-activated K+ channel in rat pancreatic islet B cells: permeation, gating and blockade by cations. 1989, Pubmed
Tseng-Crank, Cloning, expression, and distribution of functionally distinct Ca(2+)-activated K+ channel isoforms from human brain. 1994, Pubmed , Xenbase
Varnum, Subunit interactions in the activation of cyclic nucleotide-gated ion channels. 1996, Pubmed
Wallner, Characterization of and modulation by a beta-subunit of a human maxi KCa channel cloned from myometrium. 1995, Pubmed , Xenbase
Wei, Calcium sensitivity of BK-type KCa channels determined by a separable domain. 1994, Pubmed
Wei, Occult Drosophila calcium channels and twinning of calcium and voltage-activated potassium channels. 1986, Pubmed
Wong, Single calcium-dependent potassium channels in clonal anterior pituitary cells. 1982, Pubmed
Wu, A kinetic description of the calcium-activated potassium channel and its application to electrical tuning of hair cells. 1995, Pubmed
Wu, Relaxation spectra of aspartate transcarbamylase. Interaction of the native enzyme with an adenosine 5'-triphosphate analog. 1973, Pubmed
Yang, Molecular basis of charge movement in voltage-gated sodium channels. 1996, Pubmed
Yang, Evidence for voltage-dependent S4 movement in sodium channels. 1995, Pubmed
Zagotta, Shaker potassium channel gating. III: Evaluation of kinetic models for activation. 1994, Pubmed , Xenbase
Zagotta, Structure and function of cyclic nucleotide-gated channels. 1996, Pubmed
Zagotta, Shaker potassium channel gating. II: Transitions in the activation pathway. 1994, Pubmed , Xenbase