Click here to close
Hello! We notice that you are using Internet Explorer, which is not supported by Xenbase and may cause the site to display incorrectly.
We suggest using a current version of Chrome,
FireFox, or Safari.
???displayArticle.abstract???
We have examined the interaction between TEA and K+ ions in the pore of Shaker potassium channels. We found that the ability of external TEA to antagonize block of Shaker channels by internal TEA depended on internal K+ ions. In contrast, this antagonism was independent of external K+ concentrations between 0.2 and 40 mM. The external TEA antagonism of internal TEA block increased linearly with the concentration of internal K+ ions. In addition, block by external TEA was significantly enhanced by increases in the internal K+ concentration. These results suggested that external TEA ions do not directly antagonize internal TEA, but rather promote increased occupancy of an internal K+ site by inhibiting the emptying of that site to the external side of the pore. We found this mechanism to be quantitatively consistent with the results and revealed an intrinsic affinity of the site for K+ ions near 65 mM located approximately 7% into the membrane electric field from the internal end of the pore. We also found that the voltage dependence of block by internal TEA was influenced by internal K+ ions. The TEA site (at 0 internal K+) appeared to sense approximately 5% of the field from the internal end of the pore (essentially colocalized with the internal K+ site). These results lead to a refined picture of the number and location of ion binding sites at the inner end of the pore in Shaker K channels.
Figure 1. Only internal K+ ions allow external TEA to protect from internal TEA block. Currents recorded at 0 mV in the absence (Control) and in the presence of 1 mM internal TEA (smaller current in each panel, marked 1 mM TEAi in the first panel) without (left column) and with (right column) 100 mM external TEA. External and internal concentrations of the indicated ions were 5 and 135 mM, respectively.
Figure 4. Internal K+ and block by external TEA. KApp (at 0 mV) for block by external TEA as a function of the concentration of internal K+ ions. The solid line is a fit of to the data with Ko and KK values of 41 ± 3.9 and 64 ± 12 mM, respectively.
Figure 5. Voltage dependence of external TEA site and internal K+ site. Intrinsic affinity of external TEA site (Ko, âª, left ordinate) and K+ site (KK, â, right ordinate) at the indicated membrane voltages. (solid line) Fit to the Ko data of the standard (Woodhull 1972) equation for block by an external monovalent cation: Ko = Ko(0)exp(δoVmF/RT), where Ko(0) is the affinity at 0 mV, and δo is the fraction of the membrane voltage through which the external ion has to move to reach the site with values of 41 ± 0.11 mM and 0.29 ± 0.002 mM, respectively. (dashed line) Fit to the KK data of the equivalent equation for block by an internal monovalent cation. (inset) Voltage dependence of the apparent affinity for external TEA block determined with 135 mM internal K+. Solid line is the fit of the Woodhull equation with a zero voltage affinity of 16 ± 0.8 mM and δ value of 0.24 ± 0.032.
Figure 6. Internal K+ ions affect the voltage sensitivity of internal TEA block. (A) Voltage dependence of the apparent affinity of block by internal TEA in solutions of 20 (âª) and 100 mM (â) internal K+. Values obtained from fits of to data consisting of at least three independent measurements from at least four different TEA concentrations. (lines) Fits to the Woodhull equation (see Fig. 5 legend) with δ as the fraction of the membrane voltage (measured from the inner surface) through which internal TEA moves to reach its blocking site. (B) Apparent electrical distance (δ) determined as in A at the indicated internal K+ concentrations.
Figure 7. Pictorial representation of ion binding sites in the pore of Shaker K channels. Shown is a representation of the KcsA crystal structure (Doyle et al. 1998) with two of the four chains removed for clarity. The KcsA structure was visualized by RasMol (see http://www.umass.edu/microbio/rasmol/index2.htm), exported to a drawing program, and (crudely) converted to the âbent S6â conformation of del Camino et al. 2000.
Figure 2. Effects of internal TEA in the presence and absence of external TEA with 20 mM intracellular K+ ions. Currents recorded at â30, â10, +10, and +30 mV (smallest to largest in each panel) in the absence (left column) and the presence (right column) of 1 mM internal TEA without (top row) and with (bottom row) 100 mM external TEA.
Figure 3. Actions of external TEA on block by internal TEA with different concentrations of intracellular K+. (A, top) Fraction of current blocked (at 0 mV) by the indicated internal TEA concentrations in a 20-mM internal K+ solution without (âª) and with (â) 100 mM external TEA. (A, bottom) Fraction of current blocked (at 0 mV) by the indicated internal TEA concentrations in a 135-mM internal K+ solution without (âª) and with (â) 100 mM external TEA. Includes data from Thompson and Begenisich 2000. (lines) Fits of to the data with the indicated KApp values: 0.43 ± 0.017 mM and 0.66 ± 0.031 mM in the absence and presence of 100 mM TEAo with 20 mM internal K+ and 0.52 ± 0.022 mM (0 TEAo) and 1.5 ± 0.12 mM (100 mM TEAo) in 135 mM K+. (B) KApp (at 0 mV) for block by internal TEA (obtained as in A) as a function of the concentration of internal K+ ions without (âª) and with (â) 100 mM external TEA. The broken line represents the mean KApp value (0.45 mM) obtained in the absence of external TEA. The solid line is the fit of to the data with 100 mM external TEA with values for Ko and KK of 0.49 ± 0.06 and 68 ± 14 mM, respectively.
Almers,
Non-selective conductance in calcium channels of frog muscle: calcium selectivity in a single-file pore.
1984, Pubmed
Almers,
Non-selective conductance in calcium channels of frog muscle: calcium selectivity in a single-file pore.
1984,
Pubmed
Baukrowitz,
Modulation of K+ current by frequency and external [K+]: a tale of two inactivation mechanisms.
1995,
Pubmed
Baukrowitz,
Use-dependent blockers and exit rate of the last ion from the multi-ion pore of a K+ channel.
1996,
Pubmed
Choi,
The internal quaternary ammonium receptor site of Shaker potassium channels.
1993,
Pubmed
,
Xenbase
Dang,
Ion channel selectivity through stepwise changes in binding affinity.
1998,
Pubmed
del Camino,
Blocker protection in the pore of a voltage-gated K+ channel and its structural implications.
2000,
Pubmed
Doyle,
The structure of the potassium channel: molecular basis of K+ conduction and selectivity.
1998,
Pubmed
Goldin,
Maintenance of Xenopus laevis and oocyte injection.
1992,
Pubmed
,
Xenbase
Harris,
A permanent ion binding site located between two gates of the Shaker K+ channel.
1998,
Pubmed
,
Xenbase
Heginbotham,
The aromatic binding site for tetraethylammonium ion on potassium channels.
1992,
Pubmed
Heginbotham,
Conduction properties of the cloned Shaker K+ channel.
1993,
Pubmed
,
Xenbase
Hess,
Mechanism of ion permeation through calcium channels.
,
Pubmed
Hille,
Potassium channels as multi-ion single-file pores.
1978,
Pubmed
Hoshi,
Biophysical and molecular mechanisms of Shaker potassium channel inactivation.
1990,
Pubmed
,
Xenbase
Hurst,
Molecular determinants of external barium block in Shaker potassium channels.
1996,
Pubmed
,
Xenbase
Hurst,
External barium block of Shaker potassium channels: evidence for two binding sites.
1995,
Pubmed
,
Xenbase
Immke,
Ion-Ion interactions at the selectivity filter. Evidence from K(+)-dependent modulation of tetraethylammonium efficacy in Kv2.1 potassium channels.
2000,
Pubmed
Immke,
Potassium-dependent changes in the conformation of the Kv2.1 potassium channel pore.
1999,
Pubmed
Isacoff,
Putative receptor for the cytoplasmic inactivation gate in the Shaker K+ channel.
1991,
Pubmed
,
Xenbase
Jiang,
The barium site in a potassium channel by x-ray crystallography.
2000,
Pubmed
Kiss,
The interaction of Na+ and K+ in voltage-gated potassium channels. Evidence for cation binding sites of different affinity.
1998,
Pubmed
Newland,
Repulsion between tetraethylammonium ions in cloned voltage-gated potassium channels.
1992,
Pubmed
,
Xenbase
Neyton,
Potassium blocks barium permeation through a calcium-activated potassium channel.
1988,
Pubmed
Neyton,
Discrete Ba2+ block as a probe of ion occupancy and pore structure in the high-conductance Ca2+ -activated K+ channel.
1988,
Pubmed
Pérez-Cornejo,
The multi-ion nature of the pore in Shaker K+ channels.
1994,
Pubmed
Slesinger,
The S4-S5 loop contributes to the ion-selective pore of potassium channels.
1993,
Pubmed
,
Xenbase
Spassova,
Tuning the voltage dependence of tetraethylammonium block with permeant ions in an inward-rectifier K+ channel.
1999,
Pubmed
,
Xenbase
Stampe,
Nonindependent K+ movement through the pore in IRK1 potassium channels.
1998,
Pubmed
,
Xenbase
Stampe,
Unidirectional K+ fluxes through recombinant Shaker potassium channels expressed in single Xenopus oocytes.
1996,
Pubmed
,
Xenbase
Starkus,
Ion conduction through C-type inactivated Shaker channels.
1997,
Pubmed
,
Xenbase
Thompson,
Interaction between quaternary ammonium ions in the pore of potassium channels. Evidence against an electrostatic repulsion mechanism.
2000,
Pubmed
,
Xenbase
Vergara,
Localization of the K+ lock-In and the Ba2+ binding sites in a voltage-gated calcium-modulated channel. Implications for survival of K+ permeability.
1999,
Pubmed
Wood,
Two mechanisms of K(+)-dependent potentiation in Kv2.1 potassium channels.
2000,
Pubmed
Woodhull,
Ionic blockage of sodium channels in nerve.
1973,
Pubmed
Yellen,
Relief of Na+ block of Ca2+-activated K+ channels by external cations.
1984,
Pubmed
Yellen,
Mutations affecting internal TEA blockade identify the probable pore-forming region of a K+ channel.
1991,
Pubmed
