Abstract
Proton net efflux of wheat (Triticum aestivum L.) roots growing in sand culture or hydroponics was determined by measuring the pH values of the solution surrounding the roots by pH microelectrodes, by base titration and by color changes of a pH indicator in solid nutrient media. The proton net efflux was dependent on light, aeration, and source of nitrogen (NH +4 , NO −3 ). Ammonium ions caused the highest proton efflux, whereas nitrate ions decreased the proton efflux. Iron deficiency had no significant effect on proton efflux. Replacement of ammonium by nitrate inhibited proton efflux, whereas the reverse enhanced proton extrusion. A lag period between changes in plant environment and proton efflux was observed. The proton net efflux occurred at the basal portion of the roots but not in the root tips or at the elongation zone. Under optimal conditions, proton efflux capacity reached a maximum value of 5.7 μmole H+ g−1 fresh weight h−1 with an average (between different measurements) of 3.4 μmole H+ g−1 fresh wth−1 whereas the pH value decreased to 3.2–3.7 and reached a minimal value of 2.9. Inhibition of ATPase activity by orthovanadate inhibited proton efflux. The results indicate that proton efflux in wheat roots is ammonium ion and light dependent and probably governed by ATPase activity.
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Manuscript No. 245-88 from the Ohio Agricultural Research and Development Center.
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Bashan, Y., Levanony, H. Effect of root environment on proton efflux in wheat roots. Plant Soil 119, 191–197 (1989). https://doi.org/10.1007/BF02370407
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DOI: https://doi.org/10.1007/BF02370407