The effect of holding potential on charge translocation by the Na +/K+-ATPase in the absence of potassium

Yanli Ding; Robert F. Rakowski

doi:10.1007/s00232-010-9293-y

The effect of holding potential on charge translocation by the Na ⁺/K⁺-ATPase in the absence of potassium

Yanli Ding, Robert F. Rakowski

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

The Na⁺/K⁺-ATPase exports 3Na⁺ and imports 2K⁺ at the expense of the hydrolysis of 1 ATP. In the absence of K⁺, it carries on electroneutral, Na⁺-dependent transient charge movement (also known as "electroneutral Na⁺/Na ⁺ exchange mode") and produces a transient current containing faster and slower components in response to a sudden voltage step. Components with different speeds represent sequential release of Na⁺ ions from three binding sites. The effect of holding potential on slow charge movement was studied in the presence of different concentrations of ADP_i, Na _i⁺ and Na_o⁺ with the intention of improving our understanding of Na_i⁺ binding. However, the manipulation of [ADP]_i and [Na⁺]_i did not cause as pronounced changes as predicted in the magnitude of charge movement (Q _tot), which indicated that our experimental conditions were not able to backwardly drive reaction across the energy barrier to Na_i ⁺ release/rebinding steps. On the contrary, lowering [Na ⁺]_o caused evident dependence of Q_tot on holding potential, with characteristics suggesting that pumps were escaping from E2P through the uncoupled Na⁺ efflux activity.

Original language	English (US)
Pages (from-to)	203-214
Number of pages	12
Journal	Journal of Membrane Biology
Volume	236
Issue number	2
DOIs	https://doi.org/10.1007/s00232-010-9293-y
State	Published - Jul 2010
Externally published	Yes

Bibliographical note

Funding Information:
This article is dedicated to Dr. R. F. Rakowski. His earnest attitude to teaching and research and his open-minded attitude to people will always shine in our hearts. We sincerely thank Dr. M. Holmgren for his consistent and instructive help on data collection, data interpretation and writing after Dr. Rakowski passed away. We also thank Dr. J. Duerr and R. DiCaprio for their patient help with writing; Dr. J. D. Horisberger and Dr. O. Capendeguy for providing cDNAs of Bufo NKA α and β and the reviewers for their constructive comments. Research was supported by NIH grant NS-022979 to R. F. R. 1 1

Keywords

Biophysics
Electrophysiology
Sodium pump
Voltage-clamp study

Publisher link

10.1007/s00232-010-9293-y

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title = "The effect of holding potential on charge translocation by the Na +/K+-ATPase in the absence of potassium",

abstract = "The Na+/K+-ATPase exports 3Na+ and imports 2K+ at the expense of the hydrolysis of 1 ATP. In the absence of K+, it carries on electroneutral, Na+-dependent transient charge movement (also known as {"}electroneutral Na+/Na + exchange mode{"}) and produces a transient current containing faster and slower components in response to a sudden voltage step. Components with different speeds represent sequential release of Na+ ions from three binding sites. The effect of holding potential on slow charge movement was studied in the presence of different concentrations of ADPi, Na i+ and Nao+ with the intention of improving our understanding of Nai+ binding. However, the manipulation of [ADP]i and [Na+]i did not cause as pronounced changes as predicted in the magnitude of charge movement (Q tot), which indicated that our experimental conditions were not able to backwardly drive reaction across the energy barrier to Nai + release/rebinding steps. On the contrary, lowering [Na +]o caused evident dependence of Qtot on holding potential, with characteristics suggesting that pumps were escaping from E2P through the uncoupled Na+ efflux activity.",

keywords = "Biophysics, Electrophysiology, Sodium pump, Voltage-clamp study",

author = "Yanli Ding and Rakowski, {Robert F.}",

note = "Funding Information: This article is dedicated to Dr. R. F. Rakowski. His earnest attitude to teaching and research and his open-minded attitude to people will always shine in our hearts. We sincerely thank Dr. M. Holmgren for his consistent and instructive help on data collection, data interpretation and writing after Dr. Rakowski passed away. We also thank Dr. J. Duerr and R. DiCaprio for their patient help with writing; Dr. J. D. Horisberger and Dr. O. Capendeguy for providing cDNAs of Bufo NKA α and β and the reviewers for their constructive comments. Research was supported by NIH grant NS-022979 to R. F. R. 1 1",

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N2 - The Na+/K+-ATPase exports 3Na+ and imports 2K+ at the expense of the hydrolysis of 1 ATP. In the absence of K+, it carries on electroneutral, Na+-dependent transient charge movement (also known as "electroneutral Na+/Na + exchange mode") and produces a transient current containing faster and slower components in response to a sudden voltage step. Components with different speeds represent sequential release of Na+ ions from three binding sites. The effect of holding potential on slow charge movement was studied in the presence of different concentrations of ADPi, Na i+ and Nao+ with the intention of improving our understanding of Nai+ binding. However, the manipulation of [ADP]i and [Na+]i did not cause as pronounced changes as predicted in the magnitude of charge movement (Q tot), which indicated that our experimental conditions were not able to backwardly drive reaction across the energy barrier to Nai + release/rebinding steps. On the contrary, lowering [Na +]o caused evident dependence of Qtot on holding potential, with characteristics suggesting that pumps were escaping from E2P through the uncoupled Na+ efflux activity.

AB - The Na+/K+-ATPase exports 3Na+ and imports 2K+ at the expense of the hydrolysis of 1 ATP. In the absence of K+, it carries on electroneutral, Na+-dependent transient charge movement (also known as "electroneutral Na+/Na + exchange mode") and produces a transient current containing faster and slower components in response to a sudden voltage step. Components with different speeds represent sequential release of Na+ ions from three binding sites. The effect of holding potential on slow charge movement was studied in the presence of different concentrations of ADPi, Na i+ and Nao+ with the intention of improving our understanding of Nai+ binding. However, the manipulation of [ADP]i and [Na+]i did not cause as pronounced changes as predicted in the magnitude of charge movement (Q tot), which indicated that our experimental conditions were not able to backwardly drive reaction across the energy barrier to Nai + release/rebinding steps. On the contrary, lowering [Na +]o caused evident dependence of Qtot on holding potential, with characteristics suggesting that pumps were escaping from E2P through the uncoupled Na+ efflux activity.

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