Effect of External and Internal PH Changes on K and Cl Conductances in the Muscle Fiber Membrane of a Giant Barnacle

Overview

Journal J Gen Physiol

Specialty Physiology

Date 1968 Nov 1

PMID 5688083

Citations 33

Authors

S Hagiwara

R Gruener

H Hayashi

H Sakata

A D Grinnell

Affiliations

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Abstract

The membrane potential and conductance of the giant muscle fiber of a barnacle (Balanus nubilus Darwin) were analyzed in relation to changes in the external (3.5-10.0) and the internal (4.7-9.6) pH, under various experimental conditions. A sharp increase in membrane conductance, associated with a large increase in conductance to Cl ions, was observed when the external pH was lowered to values below 5.0. The ratio of Cl to K conductance in normal barnacle saline is between (1/6)-1/7 at pH 7.7, whereas at pH 4.0 the ratio is about 6-9. The behavior of the membrane in response to pH changes in a Cl-depleted muscle fiber shows that the K conductance decreases with decreasing external pH for the whole range of pH examined. A steep increase in Cl conductance is also observed when the internal pH of the fiber is lowered below 5.0. The K to Cl conductance ratio increases with increasing internal pH in a manner very similar to that found when the external pH is raised above 5.0. These facts suggest that the membrane is amphoteric with positive and negative fixed charge groups having dissociation constants such that at pH greater than 5, negative groups predominate and cations permeate more easily than anions, while at lower pH positive groups predominate, facilitating the passage of anions through the membrane.

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References

Hagiwara S, Takahashi K . Resting and spike potentials of skeletal muscle fibres of salt-water elasmobranch and teleost fish. J Physiol. 1967; 190(3):499-518. PMC: 1365424. DOI: 10.1113/jphysiol.1967.sp008224. View

Hoyle G, Smyth Jr T . NEUROMUSCULAR PHYSIOLOGY OF GIANT MUSCLE FIBERS OF A BARNACLE, BALANUS NUBILUS DARWIN. Comp Biochem Physiol. 1963; 10:291-314. DOI: 10.1016/0010-406x(63)90229-9. View

Hagiwara S, Naka K . THE INITIATION OF SPIKE POTENTIAL IN BARNACLE MUSCLE FIBERS UNDER LOW INTRACELLULAR CA++. J Gen Physiol. 1964; 48:141-62. PMC: 2195400. DOI: 10.1085/jgp.48.1.141. View

Hagiwara S, Chichibu S, Naka K . THE EFFECTS OF VARIOUS IONS ON RESTING AND SPIKE POTENTIALS OF BARNACLE MUSCLE FIBERS. J Gen Physiol. 1964; 48:163-79. PMC: 2195399. DOI: 10.1085/jgp.48.1.163. View