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» Articles » PMID: 5971030

Cation Effects on Chloride Fluxes and Accumulation Levels in Barley Roots

Overview
Journal J Gen Physiol
Specialty Physiology
Date 1966 Sep 1
PMID 5971030
Citations 7
Authors
P C Jackson
D G Edwards
Affiliations
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Abstract

Accumulation of Cl(-) by excised barley roots, as of K(+), approaches a maximum level at which the ion influx and efflux rates become equal. The rate of Cl(-) influx at this equilibrium is close to the initial rate while the efflux rate increases with time from zero to equality with influx. The Cl(-) fluxes are independent of simultaneous exchange flux of the cations, but depend on the nature and concentration of the salt solutions from which they originate. The Cl(-) content at equilibrium, however, is largely independent of the external concentrations. The approach to equilibrium reflects the presence of the cation. Cl(-) flux equilibrium is attained more rapidly in KCl than in CsCl or CaCl(2). This is presumably an effect of much slower distribution of Cs(+) and Ca(++) than of K(+) within the roots. Accumulated Cs(+) appears to form a barrier to ion movement primarily within the outermost cells, thereby reducing influx and ultimately efflux rates of both Cl(-) and cations. Slow internal mixing and considerable self-exchange of the incoming ions suggest internal transport over a series of steps which can become rate-limiting to the accumulation of ions in roots.

Citing Articles

[Evidence for mobile transport structures (carriers) involved in ion transport in plants and kinetics of anion transport in elodea in light and dark].

Weigl J Planta. 2014; 75(4):327-42.

PMID: 24549340 DOI: 10.1007/BF00387356.

[Exchange mechanism of ion transport in corn roots].

Weigl J Planta. 2014; 79(3):197-207.

PMID: 24522869 DOI: 10.1007/BF00396027.

[Fluxes, accumulation and transport of Cl(-) in excised corn roots].

Weigl J Planta. 2014; 98(4):315-22.

PMID: 24493456 DOI: 10.1007/BF00380232.

Potassium Fluxes during Potassium Absorption by Intact Barley Plants of Increasing Potassium Content.

Johansen C, Edwards D, Loneragan J Plant Physiol. 1970; 45(5):601-3.

PMID: 16657351 PMC: 396470. DOI: 10.1104/pp.45.5.601.

Simulation of Cl Uptake by Low-salt Barley Roots as a Test of Models of Salt Uptake.

Pitman M Plant Physiol. 1969; 44(10):1417-27.

PMID: 16657220 PMC: 396281. DOI: 10.1104/pp.44.10.1417.

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