Direct Measurement of Uptake of Sodium at the Outer Surface of the Frog Skin

Overview

Journal J Gen Physiol

Specialty Physiology

Date 1970 Jul 1

PMID 5514162

Citations 63

Authors

T U Biber

P F Curran

Affiliations

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Abstract

A combination of the methods described by Schultz et al. (6) and by Ussing and Zerahn (9) was used to measure directly the unidirectional uptake of sodium from the outside solution into the frog skin, under short-circuit conditions. The sodium uptake was determined at six sodium concentrations ranging from 3.4 to 114 mM. NaCl was replaced by choline chloride in the solutions bathing both sides of the skin. Sodium uptake is not a linear function of sodium concentration but appears to be composed of two components, a saturating one and one that varies linearly with concentration. The sodium uptake is inhibited by the addition of lithium to the outside solution. The effect appears to be primarily on the saturating component and has the characteristics of competitive inhibition. In addition, lithium uptake by the skin is inhibited by sodium. The effects of lithium cannot be ascribed to changes in electrical potential difference. Measurements with microelectrodes indicate that under short-circuit condition there is no change in the intracellular potential when lithium chloride is added to the outside solution.

Citing Articles

Sodium influx at the outer surface of frog skin : Evaluation of different extracellular markers.

Biber T, Cruz L, Curran P J Membr Biol. 2013; 7(1):365-76.

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Action of caerulein, gastrin 17, pentagastrin, and secretin on the active transport of sodium by the frog skin.

Greenwell J, Low H J Membr Biol. 1981; 61(2):91-6.

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Effects of chemical group specific reagents on sodium entry and the amiloride binding site in frog skin: evidence for separate sites.

Benos D, Mandel L, Simon S J Membr Biol. 1980; 56(2):149-58.

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Kinetics of ionic transport across frog skin: two concentration-dependent processes.

Ehrenfeld J J Membr Biol. 1980; 56(2):139-47.

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Influence of extracellular Cl concentration on Cl transport across isolated skin of Rana pipiens.

Biber T, Walker T, Mullen T J Membr Biol. 1980; 54(3):191-202.

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