Abstract
Vacuoles isolated from red beet (Beta vulgaris L.) storage roots contain Na+ and K+ but their analysis does not give reliable information about the size of vacuolar pools of these ions in vivo. Analyses of isolated vacuoles indicated that between 53% and 90% of the Na+ was located in the vacuole and that the vacuolar concentrations of Na+ ranged between 4 and 45 mol m-3. Calculated concentrations of K+ in the vacuoles varied between 32 and 72 mol m-3 but, in contrast to Na+, only about 50% of the K+ was located in the vacuole. Considerations of the likely cytoplasmic concentrations of Na+ and K+ suggest that if these results indicate conditions in vivo a large proportion of these ions must be located in the extracellular space, where they would exert considerable osmotic pressure. To test this, the effect of washing on cell turgor (measured directly with a pressure probe) and on loss of Na+ and K+ was determined. Washing caused an increase in turgor of 5 bar but losses of Na+ and K+ were less than predicted by the experiments with isolated vacuoles. It is concluded that beet vacuoles leak Na+ and K+ when isolated resulting in an underestimation of the size of vacuolar pools of these cations in vivo. Nonetheless, the turgor measurements provide evidence for the presence of osmotically active solute in the extracellular space. The possible contribution of extracellular Na+ and K+ to the observed turgor reduction is calculated and the physiological importance of the accumulation of extracellular solutes is discussed.
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Briggs, G.E., Hope, A.B., Robertson, R.N. (1961) Electrolytes and plant cells. Blackwell Scientific Publications, Oxford
Cornel, D., Grignon, C., Rona, J.P., Heller, R. (1983) Measurement of intracellular potassium activity in protoplasts of Acer pseudoplatanus: origin of their electropositivity. Physiol. Plant. 57, 203–209
Cosgrove, D.J., Cleland, R.E. (1983) Solutes in the free space of growing stem tissues. Plant Physiol. 72, 326–331
Cram, W.J. (1980) The higher plant as a whole. In: Plant membrane transport: current conceptual issues, pp. 3–13, Spanswick, R.M., Lucas, W.J., Dainty, J., eds Elsevier/North-Holland Biomedical Press, Amsterdam New York Oxford
Dunlop, J. (1973) The transport of potassium to the xylem exudate of ryegrass. I. Membrane potentials and vacuolar potassium activities in seminal roots. J. Exp. Bot. 24, 995–1002
Gerson, D.F., Poole, R.J. (1972) Chloride accumulation by mung bean root tips. A low affinity active transport system at the plasmalemma. Plant Physiol. 50, 603–607
Gorham, J., Wyn Jones, R.G. (1983) Solute distribution in Suaeda maritima. Planta 157, 344–349
Granstedt, R.C., Huffaker, R.C. (1982) Identification of the leaf vacuole as a major nitrate storage pool. Plant Physiol. 70, 410–413
Harvey, D.M.R., Hall, J.L., Flowers T.J., Kent, B. (1981) Quantitative ion localization within Suaeda maritima leaf mesophyll cells. Planta 151, 555–560
Hoagland, D.R., Arnon, D.I. (1950) The water culture method of growing plants without soil. Univ. Calif. Berkeley Coll. Agric. Circ. 347
Hüsken, D., Steudle, E., Zimmermann, U. (1978) Pressure probe technique for measuring water relations of cells in higher plants. Plant Physiol 61, 158–163
Jeschke, W.D., Stelter W. (1976) Measurement of longitudinal ion profiles in single roots of Hordeum and Atriplex by use of flameless atomic absorption spectroscopy. Planta 128, 107–112
Jones, H., Tomos, A.D., Leigh, R.A., Wyn Jones, R.G. (1983) Water relation parameters of epidermal and cortical cells in the primary root of Triticum aestivum L. Planta 158, 230–236
Kelday, L.S., Bowling, D.J.F. (1980) Profiles of chloride concentration and PD in the root of Commelina communis L. J. Exp. Bot. 31, 1347–1355
Leigh, R.A. (1983) Methods, progress and potential for the use of isolated vacuoles in studies of solute transport in higher plant cells. Physiol. Plant. 57 390–396
Leigh, R.A., Ahmad, N., Wyn Jones, R.G. (1981) Assessment of glycinebetaine and proline compartmentation by analysis of isolated beet vacuoles. Planta 153, 34–41
Leigh, R.A., ap Rees, T., Fuller, W.A., Banfield, J. (1979) The location of acid invertase activity and sucrose in vacuoles of storage root of beetroot (Beta vulgaris). Biochem. J. 178, 539–547
Leigh, R.A., Branton, D. (1976) Isolation of vacuoles from root storage tissue of Beta vulgaris L. Plant Physiol 58, 656–662
Lin, W., Wagner, G.J., Siegelman, H.W., Hind, G. (1977) Membrane-bound ATPase of intact vacuoles and tonoplasts isolated from mature plant tissue. Biochim. Biophys. Acta 465, 110–117
Macklon, A.E.S. (1976) An examination, by compartmental flux analysis, of the development of sodium and chloride absorption capacities in beetroot disks. J. Exp. Bot. 27, 651–657
MacRobbie, E.A.C. (1970) The active transport of ions in plant cells. Q. Rev. Biophys. 3, 251–294
Martinoia, E., Heck, U., Wiemken, A. (1981) Vacuoles as storage compartments for nitrate in barley. Nature (London) 289, 292–294
Moskowitz, A.H., Hrazdina, G. (1981) Vacuolar contents of fruit subepidermal cells from Vitis species. Plant Physiol. 68, 686–692
Pitman, M.G. (1963) The determination of the salt relations of the cytoplasmic phase in beetroot tissue. Aust. J. Biol. Sci. 16 647–668
Pitman, M.G., Läuchli, A., Stelzer, R. (1981) Ion distribution in roots of barley seedlings measured by electron probe X-ray microanalysis. Plant Physiol. 68, 673–679
Poole, R.J. (1971) Effect of sodium on potassium fluxes at the cell membrane and vacuole membrane of red beet. Plant Physiol. 47, 731–734
Rona, J.P., Cornel, D., Grignon, C., Heller, R. (1982) The electrical potential difference across the tonoplast of Acer pseudoplatanus cells. Physiol. Vég. 20, 459–463
Steudle, E., Smith, J.A.C., Lüttge, U. (1980) Water relation parameters of individual mesophyll cells of the CAM plant Kalanchoë diagremontiana. Plant Physiol. 66, 1155–1163
Taylor, A.R.D., Hall, J.L. (1976) Some physiological properties of protoplasts isolated from maize and tobacco tissues. J. Exp. Bot. 27, 383–391
Tomos, A.D., Steudle, E., Zimmermann, U., Schulze, E-D. (1981) Water relations of leaf epidermal cells of Tradescantia virginiana. Plant Physiol. 68, 1135–1143
Tomos, A.D., Wyn Jones, R.G. (1982) Water relations in the epidermal cells of the halophyte Suaeda maritima. In: Biophysics of water, pp. 327–331, Franks, F., Mathias, S., eds. Wiley, chichester
Wagner, G.J., Siegelman, H.W. (1975) Large-scale isolation of intact vacuoles and isolation of chloroplasts from protoplansts of mature plant tissues. Science 190, 1298–1299
Walker, N.A., Pitman, M.G. (1976) Measurement of fluxes across membranes. In: Encyclopedia of plant physiology, N.S., vol. 2A: Transport in plants, pt. A: Cells, pp. 93–126, Lüttge, U., Pitman, M.G., eds. Springer, Berlin Heidelberg New York
Wyn Jones, R.G., Brady, C.J., Spiers, J. (1979) Ionic and osmotic relations in plant cells. In: Recent advances in the biochemistry of cereals. pp. 63–103. Laidman, D.L., Wyn Jones, R.G., eds. Academic Press, London New York
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Leigh, R.A., Tomos, A.D. An attempt to use isolated vacuoles to determine the distribution of sodium and potassium in cells of storage roots of red beet (Beta vulgaris L.). Planta 159, 469–475 (1983). https://doi.org/10.1007/BF00392083
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DOI: https://doi.org/10.1007/BF00392083