Mb. Goodman et Jj. Art, VARIATIONS IN THE ENSEMBLE OF POTASSIUM CURRENTS UNDERLYING RESONANCEIN TURTLE HAIR-CELLS, Journal of physiology, 497(2), 1996, pp. 395-412
1. Potassium currents were characterized in turtle cochlear hair cells
by whole-cell voltage clamp during superfusion with the potassium cha
nnel antagonists, tetraethylammonium (TEA) and 4-aminopyridine (4-AP).
The estimated resonant frequency f(o), was inferred from tau, the tim
e constant of deactivation of outward current upon repolarization to -
50 mV, according to the empirical relation, f(o) = k(1) tau(-1/2) + k(
2). 2. Dose-response relations for TEA and 4-AP were obtained by expos
ing single cells to ten concentrations exponentially distributed over
four orders of magnitude. Potassium current in cells tuned to low freq
uencies was carried by a single class of channels with an apparent aff
inity constant, K-i, for TEA of 35.9 mM. Half-blocking concentrations
of 4-AP were correlated with the time constant of deactivation and var
ied between 26.2 and 102 mu M. In cells tuned to higher frequencies, K
+ current was carried by a single class of channels with high affinity
for TEA (K-i = 0.215 mM) and low affinity for 4-AP (K-i = 12.3 mM). T
his pharmacological profile suggests that K+ current in low frequency
cells is purely voltage gated and in high frequency cells, it is gated
by both Ca2+ and voltage. 3. For each current type, the voltage depen
dence of activation was determined from tail current amplitude at -50
mV. The purely voltage-gated current, I-K(V), was found to increase e-
fold in 4.0 +/- 0.3 mV (n = 3) in low frequency cells exposed to TEA (
25 mM). The Ca2+- and voltage-gated current, I-K(Ca), was more steeply
voltage dependent, increasing e-fold in 1.9 mV (n = 2) in high freque
ncy cells exposed to 4-AP (0.8 mM). 4. I-K(V) was found to inactivate
slowly during prolonged voltage steps (similar to 10 s). Steady-state
inactivation increased with depolarization from -70 mV and was incompl
ete such that on average I-K(V) did not fall below similar to 0.39 of
its maximum value. 5. Superfusion of 4-AP (0.8 mM) reversibly depolari
zed a low frequency cell and eliminated steady voltage oscillations, w
hile TEA (6 mM) had no effect. In a high frequency cell, voltage oscil
lations were abolished by TEA, but not by 4-AP. 6. The differential ph
armacology of I-K(V) and I-K(Ca) was used to measure their contributio
n to K+ current in cells tuned to different frequencies. Both currents
exhibited a frequency-dependent increase in maximum conductance. I-K(
V) accounted for nearly all K+ current in cells tuned to less than 60
Hz, while I-K(Ca) was the dominant current in higher frequency cells.
7. Mapping resonant frequency onto epithelial position suggests an exp
onential relation between K+ current size and position. I-K(V) appeare
d to be limited to the apical or low frequency portion of the basilar
papilla and coincided with maximal expression of a K+- selective inwar
d rectifier, I-K(IR). This finding is consistent with the notion that
low frequency resonance is produced by interaction of I-K(V) and I-K(I
R) with the voltage-gated Ca2+ current, I-Ca, and the cell's capacitan
ce. The ionic events underlying higher frequency resonance are dominat
ed by the action of I-K(Ca) and I-Ca and include a contribution from I
-K(IR).