Two Mechanisms of K+-Dependent Potentiation in Kv2.1 Potassium Channels

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Two Mechanisms of K⁺-Dependent Potentiation in Kv2.1 Potassium Channels

Michael J. Wood and Stephen J. Korn

Department of Physiology and Neurobiology, University of Connecticut, Storrs, Connecticut 06269 USA

Elevation of external [K⁺] potentiates outward K⁺ current through several voltage-gated K⁺ channels. This increase in current magnitude is paradoxical inthat it occurs despite a significant decrease in driving force.We have investigated the mechanisms involved in K⁺-dependent current potentiation in the Kv2.1 K⁺ channel. With holding potentials of $-$ 120 to $-$ 150 mV, which completelyremoved channels from the voltage-sensitive inactivated state,elevation of external [K⁺] up to 10 mM produced a concentration-dependent increase in outwardcurrent magnitude. In the absence of inactivation, currents weremaximally potentiated by 38%. At more positive holding potentials,which produced steady-state inactivation, K⁺-dependent potentiation was enhanced. The additional K⁺-dependent potentiation (above 38%) at more positive holding potentialswas precisely equal to a K⁺-dependent reduction in steady-state inactivation. Mutation oftwo lysine residues in the outer vestibule of Kv2.1 (K356 andK382), to smaller, uncharged residues (glycine and valine, respectively),completely abolished K⁺-dependent potentiation that was not associated with inactivation.These mutations did not influence steady-state inactivation orthe K⁺-dependent potentiation due to reduction in steady-state inactivation.These results demonstrate that K⁺-dependent potentiation can be completely accounted for by twoindependent mechanisms: one that involved the outer vestibulelysines and one that involved K⁺-dependent removal of channels from the inactivated state. Previousstudies demonstrated that the outer vestibule of Kv2.1 can bein at least two conformations, depending on the occupancy of theselectivity filter by K⁺ (Immke, D., M. Wood, L. Kiss, and S. J. Korn. 1999. J. Gen. Physiol.113:819-836; Immke, D., and S. J. Korn. 2000. J. Gen. Physiol.115:509-518). This change in conformation was functionally definedby a change in TEA sensitivity. Similar to the K⁺-dependent change in TEA sensitivity, the lysine-dependent potentiationdepended primarily (>90%) on Lys-356 and was enhanced by loweringinitial K⁺ occupancy of the pore. Furthermore, the K⁺-dependent changes in current magnitude and TEA sensitivity werehighly correlated. These results suggest that the previously describedK⁺-dependent change in outer vestibule conformation underlies thelysine-sensitive, K⁺-dependent potentiationmechanism.

Biophys J, November 2000, p. 2535-2546, Vol. 79, No. 5
© 2000 by the Biophysical Society 0006-3495/00/11/2535/12 $2.00

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