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Literature DB >> 16657196

Adaptation of barley roots to low oxygen supply and its relation to potassium and sodium uptake.

Abstract

The uptake of Na(+) and K(+) by barley seedlings grown on aerated or non-aerated solutions was studied. Plants growing in culture solution took up K(+) with high selectivity whether the solution was aerated or not. Roots of plants grown on aerated CaSO(4) and transferred to a solution of KCl and NaCl had a lower preference for K(+) than roots of plants grown on non-aerated CaSO(4). Both kinds of low-salt roots were much less able to discriminate between K(+) and Na(+) than high-salt roots grown on a culture solution. The different levels of K(+) selectivity are suggested to be related to H(+) release from the tissue.

Entities: Chemical Species

Year: 1969 PMID： 16657196 PMCID： PMC396249 DOI： 10.1104/pp.44.9.1233

Source DB: PubMed Journal: Plant Physiol ISSN： 0032-0889 Impact factor: 8.340

14 in total

2. Correlation between Root-Generated Ionic Currents, pH, Fusicoccin, Indoleacetic Acid, and Growth of the Primary Root of Zea mays.

Authors: A L Miller; N A Gow
Journal: Plant Physiol Date: 1989-04 Impact factor: 8.340

Adaptation of barley roots to low oxygen supply and its relation to potassium and sodium uptake.

1. Sodium absorption by barley roots: role of the dual mechanisms of alkali cation transport.

2. Absorption of Cations by Roots. Effects of Hydrogen Ions and Essential Role of Calcium.

3. The essential role of calcium in selective cation transport by plant cells.

4. Localization of the ca-mediated apparent ion selectivity in the cross sectional volume of soybean roots.

5. Sodium absorption by barley roots: its mediation by mechanism 2 of alkali cation transport.

6. EFFECTS OF OXYGEN TENSION ON CERTAIN PHYSIOLOGICAL RESPONSES OF RICE, BARLEY, AND TOMATO.

7. The dual mechanisms of alkali cation absorption by plant cells: their parallel operation across the plasmalemma.

8. Regulation of betacyanin efflux from beet root by poly-L-lysine, ca-ion and other substances.

9. Relationship of Cell Sap pH to Organic Acid Change During Ion Uptake.

10. Equilibrium and Ion Exchange Characteristics of Potassium and Sodium Accumulation by Barley Roots.

1. Soil strength and macropore volume limit root elongation rates in many UK agricultural soils.

2. Correlation between Root-Generated Ionic Currents, pH, Fusicoccin, Indoleacetic Acid, and Growth of the Primary Root of Zea mays.

3. Electrical potential differences in cells of barley roots and their relation to ion uptake.

4. Development and Characteristics of Sodium-selective Transport in Red Beet.

5. Influence of Phenolic Acids on Ion Uptake: IV. Depolarization of Membrane Potentials.

6. Induction of coleoptile elongation by carbon dioxide.

7. Cell potentials, cell resistance, and proton fluxes in corn root tissue: effects of dithioerythritol.

8. The Release of Potassium and Sodium from Young Excised Roots of Zea mays under Various Efflux Conditions.

9. Transmembrane electropotential in barley roots as related to cell type, cell location, and cutting and aging effects.

10. Induction and development of increased ion absorption in corn root tissue.