Handbook of Plant and Crop Physiology

(Steven Felgate) #1

  1. BJ Barkla, E Blumwald. Identification of a 170-kDa protein associated with the vacuolar NaHantiport of
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  3. A Fukuda, Y Yazaki, T Ishikawa, S Koike, Y Tanaka. NaHantiporter in tonoplast vesicles from rice roots.
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  4. FJM Maathuis, D Sanders. Energization of potassium uptake in Arabidopsis thaliana.Planta 191:302–307,



  5. L Bruggemann, P Dietrich, D Becker, I Dreyer, K Palme, R Hedrich. Channel-mediated high-affinity Kup-
    take into guard cells from Arabidopsis.Proc Natl Acad Sci U S A 96:3298–3302, 1999.

  6. MJ Gracia-Sanches, MP Jaime, A Ramus, D Sanders. Na-dependent NO 3 transport at the plasma membrane
    of leaf cells of the marine higher plant Zoestera marinaL. Plant Physiol, in press.

  7. NA Walker, D Sanders. Sodium-coupled solute transport in Charophytealgae: a general mechanism for trans-
    port energization in plant cells? Planta 185:443–445, 1991.

  8. NA Walker. Sodium coupled symports in the plasma membrane of plant cells. In: MR Blatt, RA Leigh, D
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    of Biologists, 1994, pp 179–192.

  9. FJM Maathuis, D Verlin, FA Smith, D Sanders, JA Fernandez, NA Walker. The physiological relevance of
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  10. DP Schachtman, JI Schroeder. Structure and transport mechanism of a high-affinity potassium uptake trans-
    porter from higher plants. Nature 370:655–658, 1994.

  11. EJ Kim, JM Kwak, N Uozumi, JI Schroeder. Atkup1:anArabidopsisgene encoding high-affinity potassium
    transport activity. Plant Cell 10:51–62, 1998.

  12. TB Wang, W Gassman, F Rubio, JI Schroeder, ADM Glass. Rapid up-regulation of HKT1,a high affinity
    potassium transporter gene in roots of barley and wheat following withdrawal of potassium. Plant Physiol
    118:651–659, 1998.

  13. F Rubio, W Gassmann, JI Schroeder. Sodium-driven potassium uptake by the plant potassium transporter
    HKT1 and mutations conferring salt tolerance. Science 270:1660–1663, 1995.

  14. M Kasai, S Muto. Calcium ion pump and calcium ion/hydrogen ion antiporter in plasma membrane vesicles
    isolated by aqueous two-phase partitioning from corn leaves. J Membr Biol 114:133–142, 1990.

  15. KD Hirschi, RG Zhen, KW Cunningham, PA Rea, GR Fink. CAX1, an H/Ca^2 antiporter from Arabidopsis.
    Proc Natl Acad Sci U S A 93:8782–8786, 1996.

  16. KS Schumaker, H Sze. A Ca^2 /Hantiport system driven by the proton electrochemical gradient of a tono-
    plast H-ATPase from oat roots. Plant Physiol 79:1111–1117, 1985.

  17. KS Schumaker, H Sze. Calcium transport into the vacuole of oat roots: characterization of H/Ca^2 exchange
    activity. J Biol Chem 261:12172–12178, 1986.

  18. E Blumwald, RJ Poole. Kinetics of Ca^2 /Hantiport in isolated tonoplast vesicles from storage tissue of Beta
    vulgarisL. Plant Physiol 80:727–731, 1986.

  19. FM Dupont, DS Bush, JJ Windle, RL Jones. Calcium and proton transport in membrane vesicles from barley
    roots. Plant Physiol 94:179–188, 1990.

  20. S Blackford, PA Rea, D Sanders. Voltage sensitivity of H/Ca^2 antiport in higher plant tonoplasts suggests a
    role in vacuolar calcium accumulation. J Biol Chem 265:9617–9620, 1990.

  21. D Sanders. Gradient-coupled chloride transport in plant cells. In: GA Gerencser, ed. Chloride Transport Cou-
    pling in Biological Membranes. Amsterdam: Elsevier, 1984, pp 64–120.

  22. WR Ullrich, A Novacky. Nitrate-dependent membrane potentials and their induction in Lemna gibbaGI. Plant
    Sci Lett 22:211–217, 1981.

  23. ADM Glass, JE Shaff, LV Kochian. Studies of the uptake of nitrate in barley. IV. Electrophysiology. Plant
    Physiol 99:99–463, 1992.

  24. ECI Ullrich, A Novacky, AJE van Bel. Phosphate uptake in Lemna gibbaG1: energetics and kinetics. Planta
    161:46–52, 1984.

  25. K Sakano. Proton/phosphate stoichiometry in uptake of inorganic phosphate by cultured cells of Catharanthus
    roseus(L.) G. Don. Plant Physiol 93:479–482, 1990.

  26. B Lass, CI Ullrich Eberius. Evidence for proton/sulfate cotransport and its kinetics in Lemna gibbaG1. Planta
    161:53–60, 1984.

  27. B Jacoby, B Rudich. Proton-chloride symport in barley roots. Ann Bot 46:493–498, 1980.

  28. K Yamashita, Y Yamamoto, H Matsumoto. Characterization of an anion transporter in the plasma membrane
    of barley roots. Plant Cell Physiol 37:949–956, 1996.

  29. US Muchal, JM Pardo, KG Raghothama. Phosphate transporters from the higher plant Arabidopsis thaliana.
    Proc Natl Acad Sci U S A 93:10519–10523, 1996.

  30. C Liu, US Muchal, M Uthappa, AK Kononowicz, KG Raghotama. Tomato phosphate transporter genes are dif-
    ferentially regulated in plant tissues by phosphorus. Plant Physiol 116:91–99, 1998.

  31. P Daram, S Brunner, BL Persson, N Amrhein, M Bucher. Functional analysis and cell-specific expression of a
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MINERAL NUTRIENT TRANSPORT IN PLANTS 359

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