Brelidze TI , Magleby KL .

AR 32805 NIAMS NIH HHS , R01 AR032805 NIAMS NIH HHS

	Figure 1. Intracellular sugars decrease outward unitary currents through WT BK channels. (A) Representative outward single-channel currents recorded at +200 mV with no sugar in the intracellular solutions. Closed channel current level is indicated by C. Symmetrical 150 mM KCl and effective low pass filtering of 4 kHz in A and C. (B) Structures of the three sugar molecules used in this study shown as space filling surfaces. The images were obtained with Swiss Protein Viewer using atomic coordinates. The atomic coordinates for glycerol were from ChemFinder structural databases (http://chemfinder.cambridgesoft.com/), and for glucose and sucrose from the library of molecular structures at New York University (http://www.nyu.edu/pages/mathmol/library/library.html). The atoms are identified as: oxygen, red; carbon, white; and hydrogen, cyan. Scaling for the figure was based on dimensions determined from CPK models of the sugars (Harvard Apparatus). (C) Representative outward single-channel currents recorded at +200 mV with sugars in the intracellular solutions at the indicated concentrations. The type of sugar present in the solution for each column of currents in C is shown above the current records in B. (D) Plots of unitary current amplitudes at +200 mV versus the hydrodynamic radii of the different sugars over a range of concentrations, as indicated. The hydrodynamic radii were 3.1 Å, 4.2 Å, and 5.2 Å for glycerol, glucose, and sucrose, respectively, as determined by viscometry (Schultz and Solomon, 1961). (E) Plots of the unitary current amplitudes at +200 mV versus sugar concentration for the indicated sugars. The filled circles in D and E correspond to the unitary current amplitude at +200 mV in the absence of sugar.
	Figure 2. Intracellular sugar decreases outward unitary currents through WT BK channels in a size- and concentration-dependent manner over the examined range of voltages. (A–D) Plots of outward unitary current amplitudes versus voltage without and with the indicated sugar. The continuous lines are polynomial fits to the unitary currents in the absence of sugar, whereas the dashed lines for each sugar are empirical predictions obtained by scaling the continuous lines by a single value obtained from Eq. 5, as listed in Table I in the predicted column. Symmetrical 150 mM KCl. (D) Unitary current amplitudes saturate with 2 M sucrose at voltages >+100 mV with 150 mM K+i. (E and F) Outward currents drive sugar into the vestibule, decreasing the currents. Plots of the ratios of the outward unitary currents in the presence and absence of 1 M (E) and 2 M (F) sugar. The lines in D–F have no theoretical meaning.
	Figure 3. Outward unitary currents are diffusion limited for WT BK channels with 2 M intracellular sucrose and 150 mM K+i. (A) Representative outward unitary currents recorded at +200 mV from WT BK channels without and with 1 and 2 M sucrose, for 150 mM and 2 M K+i. Effective filtering: 4 kHz. (B) Plots of outward unitary current amplitude versus voltage without and with 1 M sucrose at the indicated K+i. (C) Currents with 1 M sucrose and 150 mM K+i are not diffusion limited. The data in B are replotted after shifting the 2 M K+i data to the right by 50 mV to correct for the shift in reversal potential and scaling the data by 1.8. The data points with 2 M K+i for shifted voltages >200 mV are not shown. (D and E) Increasing K+i removes the saturation of outward current at high voltage with 2 M sucrose, consistent with diffusion-limited currents in 2 M sucrose with 150 mM K+i. The unitary currents with 2 M sucrose and with 150 mM K+i or 2 M K+i are plotted in D. The data in D are then replotted in E after shifting and scaling the data in the same manner as for C. The lines in B–D have no theoretical meaning.
	Figure 4. Outward unitary currents with 2 M intracellular sucrose and 150 mM K+i are diffusion limited for mutant BK channels without the ring of negative charge. (A) Representative outward single-channel currents recorded at +120 mV from E321N/E324 mutant channels with the indicated K+i in the absence and presence of 2 M sucrose. Effective filtering: 4 kHz. (B and C) Plots of outward unitary current amplitudes versus voltage for E321N/E324N mutant channels in the absence (B) and presence (C) of 2 M sucrose at the indicated K+i. High K+i removes the saturation observed with 2 M sucrose. The lines in B and C have no theoretical meaning.
	Figure 5. Sugars differentially decrease inward and outward unitary currents in WT BK channels. (A) Representative inward single-channel currents recorded at −100 mV from WT BK channels with and without the indicated sugars. Effective filtering: 4 kHz. (B) Plots of inward unitary current amplitudes versus voltage with and without the indicated sugars. (C) Inward currents drive sugar out of the vestibule. Plots of the ratios of the inward unitary currents in the presence of the indicated sugars (is) to the inward unitary currents in the absence of sugars (i0) versus voltage. Symmetrical 150 mM K+i. The lines in B and C have no theoretical meaning.
	Figure 6. The reduction of outward unitary currents in WT BK channels is strongly correlated with sugar-induced changes in diffusion coefficient, conductivity, and fractional hydrodynamic volume occupied by the sugar, but not osmolality. (A–C) Plots of the outward unitary current at +200 mV versus osmolality (A), conductivity (B), and fractional hydrodynamic volume of the solution occupied by sugar (C). The arrow in A indicates that the osmolality of the solution with 2 M sucrose was greater than the plotted maximum value that the osmometer could read. (D) Plot of conductivity versus fractional hydrodynamic volume. Dashed lines in B, C, and D are linear regression fits to the all the plotted points, with correlation coefficients, R, of 0.97, −0.98, and −0.99 respectively. For B, C, and D, the data for each sugar are presented for concentrations of 0.4, 1, and 2 M. As the concentration of each sugar increases, the conductivity of the solution decreases and the fractional hydrodynamic volume occupied by each sugar increases.
	Figure 7. Cartoon of a BK channel with 150 mM K+ and 0.4 and 2 M sucrose. The inner vestibule is drawn with a depth of 20 Å and a diameter of 18.5 Å. The actual physical dimensions and shape are likely to be different. The number of ions visible is the average number that would be contained in an 8-Å slice in the plane of the figure centered on the centerline of the channel. It is assumed that the concentration of sucrose in the channel is the same as in the bulk intracellular solution. The negative charge at the entrance to the inner vestibule attracts additional K+ ions (Brelidze et al., 2003). The selectivity filter is drawn with two K+ ions (Morais-Cabral et al., 2001), and the pore helices are likely to provide a favorable electrostatic environment for a K+ ion in the vestibule (Roux and MacKinnon, 1999).

Alcayaga, Streaming potential measurements in Ca2+-activated K+ channels from skeletal and smooth muscle. Coupling of ion and water fluxes. 1989, Pubmed

Alcayaga, Streaming potential measurements in Ca2+-activated K+ channels from skeletal and smooth muscle. Coupling of ion and water fluxes. 1989, Pubmed
Andersen, Ion movement through gramicidin A channels. Single-channel measurements at very high potentials. 1983, Pubmed
Andersen, Ion movement through gramicidin A channels. Studies on the diffusion-controlled association step. 1983, Pubmed
Arakawa, Stabilization of protein structure by sugars. 1982, Pubmed
Armstrong, Interaction of tetraethylammonium ion derivatives with the potassium channels of giant axons. 1971, Pubmed
Armstrong, The inner quaternary ammonium ion receptor in potassium channels of the node of Ranvier. 1972, Pubmed
Barrett, Properties of single calcium-activated potassium channels in cultured rat muscle. 1982, Pubmed
Bernèche, Energetics of ion conduction through the K+ channel. 2001, Pubmed
Bezrukov, Probing alamethicin channels with water-soluble polymers. Effect on conductance of channel states. 1993, Pubmed
Blatz, Ion conductance and selectivity of single calcium-activated potassium channels in cultured rat muscle. 1984, Pubmed
Brelidze, A ring of eight conserved negatively charged amino acids doubles the conductance of BK channels and prevents inward rectification. 2003, Pubmed , Xenbase
Brelidze, Protons block BK channels by competitive inhibition with K+ and contribute to the limits of unitary currents at high voltages. 2004, Pubmed , Xenbase
Chung, Modeling diverse range of potassium channels with Brownian dynamics. 2002, Pubmed
Consiglio, Influence of pore residues on permeation properties in the Kv2.1 potassium channel. Evidence for a selective functional interaction of K+ with the outer vestibule. 2003, Pubmed
Cox, Separation of gating properties from permeation and block in mslo large conductance Ca-activated K+ channels. 1997, Pubmed
Davis-Searles, Interpreting the effects of small uncharged solutes on protein-folding equilibria. 2001, Pubmed
Doyle, The structure of the potassium channel: molecular basis of K+ conduction and selectivity. 1998, Pubmed
Eisenman, Multi-ion conduction and selectivity in the high-conductance Ca++-activated K+ channel from skeletal muscle. 1986, Pubmed
Ferguson, Competitive Mg2+ block of a large-conductance, Ca(2+)-activated K+ channel in rat skeletal muscle. Ca2+, Sr2+, and Ni2+ also block. 1991, Pubmed
Gekko, Mechanism of protein stabilization by glycerol: preferential hydration in glycerol-water mixtures. 1981, Pubmed
Hall, Stabilizing effect of sucrose against irreversible denaturation of rabbit muscle lactate dehydrogenase. 1995, Pubmed
Hamill, Improved patch-clamp techniques for high-resolution current recording from cells and cell-free membrane patches. 1981, Pubmed
Heginbotham, Mutations in the K+ channel signature sequence. 1994, Pubmed , Xenbase
Hille, Ionic channels in nerve membranes. 1970, Pubmed
Hille, Potassium channels in myelinated nerve. Selective permeability to small cations. 1973, Pubmed
Hsiao, Subunit-dependent modulation of neuronal nicotinic receptors by zinc. 2001, Pubmed , Xenbase
Jiang, The open pore conformation of potassium channels. 2002, Pubmed
Johansson, Phase equilibria and formation of vesicles of dioleoylphosphatidylcholine in glycerol/water mixtures. 1993, Pubmed
Krause, Xenopus laevis oocytes contain endogenous large conductance Ca2(+)-activated K+ channels. 1996, Pubmed , Xenbase
Kullman, Transport of maltodextrins through maltoporin: a single-channel study. 2002, Pubmed
Kuo, A functional view of the entrances of L-type Ca2+ channels: estimates of the size and surface potential at the pore mouths. 1992, Pubmed
Latorre, Conduction and selectivity in potassium channels. 1983, Pubmed
Latorre, Varieties of calcium-activated potassium channels. 1989, Pubmed
Li, Unique inner pore properties of BK channels revealed by quaternary ammonium block. 2004, Pubmed , Xenbase
Lu, Ion conduction pore is conserved among potassium channels. 2001, Pubmed
Läuger, Diffusion-limited ion flow through pores. 1976, Pubmed
MacKinnon, Structural conservation in prokaryotic and eukaryotic potassium channels. 1998, Pubmed
MacKinnon, Potassium channels. 2003, Pubmed
Marty, Ca-dependent K channels with large unitary conductance in chromaffin cell membranes. 1981, Pubmed
McManus, Functional role of the beta subunit of high conductance calcium-activated potassium channels. 1995, Pubmed , Xenbase
Morais-Cabral, Energetic optimization of ion conduction rate by the K+ selectivity filter. 2001, Pubmed
Nimigean, Electrostatic tuning of ion conductance in potassium channels. 2003, Pubmed , Xenbase
Oberhauser, Activation by divalent cations of a Ca2+-activated K+ channel from skeletal muscle membrane. 1988, Pubmed
Oh, Changes in permeability caused by connexin 32 mutations underlie X-linked Charcot-Marie-Tooth disease. 1997, Pubmed , Xenbase
Pallanck, Cloning and characterization of human and mouse homologs of the Drosophila calcium-activated potassium channel gene, slowpoke. 1994, Pubmed
Park, Effect of phosphatidylserine on unitary conductance and Ba2+ block of the BK Ca2+-activated K+ channel: re-examination of the surface charge hypothesis. 2003, Pubmed
Parsegian, Watching small molecules move: interrogating ionic channels using neutral solutes. 1995, Pubmed
Patten, Structural and functional modularity of voltage-gated potassium channels. 1999, Pubmed , Xenbase
Priev, Glycerol decreases the volume and compressibility of protein interior. 1996, Pubmed
Qu, Accessibility of cx46 hemichannels for uncharged molecules and its modulation by voltage. 2004, Pubmed , Xenbase
Roux, The cavity and pore helices in the KcsA K+ channel: electrostatic stabilization of monovalent cations. 1999, Pubmed
SCHULTZ, Determination of the effective hydrodynamic radii of small molecules by viscometry. 1961, Pubmed
Sabirov, Relation between ionic channel conductance and conductivity of media containing different nonelectrolytes. A novel method of pore size determination. 1993, Pubmed
Schreiber, Transplantable sites confer calcium sensitivity to BK channels. 1999, Pubmed , Xenbase
Snetkov, Inward rectification of the large conductance potassium channel in smooth muscle cells from rabbit pulmonary artery. 1996, Pubmed
Sugihara, Activation and two modes of blockade by strontium of Ca2+-activated K+ channels in goldfish saccular hair cells. 1998, Pubmed
Villarroel, Probing a Ca2+-activated K+ channel with quaternary ammonium ions. 1988, Pubmed
Vodyanoy, Probing alamethicin channels with water-soluble polymers. Size-modulated osmotic action. 1993, Pubmed
Webster, Intracellular gate opening in Shaker K+ channels defined by high-affinity metal bridges. 2004, Pubmed
Yang, Block of stretch-activated ion channels in Xenopus oocytes by gadolinium and calcium ions. 1989, Pubmed , Xenbase
Yellen, The voltage-gated potassium channels and their relatives. 2002, Pubmed
Yellen, Ionic permeation and blockade in Ca2+-activated K+ channels of bovine chromaffin cells. 1984, Pubmed
Yellen, Relief of Na+ block of Ca2+-activated K+ channels by external cations. 1984, Pubmed
Zhou, Chemistry of ion coordination and hydration revealed by a K+ channel-Fab complex at 2.0 A resolution. 2001, Pubmed
Zhou, A mutant KcsA K(+) channel with altered conduction properties and selectivity filter ion distribution. 2004, Pubmed
Zhou, Ion binding affinity in the cavity of the KcsA potassium channel. 2004, Pubmed