Current generated by backward-running electrogenic Na pump in squid giant axons

Current generated by backward-running electrogenic Na pump in squid giant axons

The sodium pump of animal cells is electrogenic, that is, it normally exports more sodium ions than it imports potassium ions. In the squid giant axon, the resulting net outward electric current has a density of a few microA cm-2, and contributes 1-2 mV to the resting membrane potential. The pump is...

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Bibliographic Details
Published in:Nature (London) Vol. 309; no. 5967; pp. 450 - 452
Main Authors: Weer, Paul De, Rakowski, R. F
Format: Journal Article
Language:English
Published: London Nature Publishing 31-05-1984
Subjects:
Animals
Axons - physiology
Biological and medical sciences
Decapodiformes
Electric Conductivity
Fundamental and applied biological sciences. Psychology
Invertebrates
Ion Channels - physiology
Kinetics
Membrane Potentials - drug effects
Mollusca
Physiology. Development
Potassium - pharmacology
Seawater
Sodium - metabolism
Marine environment
Cephalopoda
Sodium
Giant neuron
Axon
Invertebrata
Mollusca
Membrane channel
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Summary:The sodium pump of animal cells is electrogenic, that is, it normally exports more sodium ions than it imports potassium ions. In the squid giant axon, the resulting net outward electric current has a density of a few microA cm-2, and contributes 1-2 mV to the resting membrane potential. The pump is driven by the free energy of hydrolysis of ATP, and in some instances it has been possible to run the pump backwards and synthesize ATP by lowering the [ATP]/[ADP] X [Pi] ratio and steepening the transmembrane Na+ and K+ gradients. Here we have examined the question of whether a backward-running sodium pump conserves its Na+/K+ greater than 1 stoichiometry. We demonstrate reversal of the sodium pump of squid giant axon, and find that backward pumping indeed produces a net inward electric current. This current is voltage-sensitive. Our observations have mechanistic implications for models of the sodium pump.
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ISSN:0028-0836
1476-4687
DOI:10.1038/309450a0