Abstract
The addition of 10 mM KNO3 to the solution bathing the roots of young nitrogen-starved seedlings of Zea mays L. enhanced root water transfer within 15 h, compared with 10 mM KCl addition. The free exudation flux was 2.2–3.9 times higher in excised KNO3-treated roots than in KCl-treated ones. Cryo-osmometry data for xylem sap suggested that, compared with chloride, nitrate treatment increased the steady solute flux into the xylem, but did not modify the osmotic concentration of sap. Root growth was not significantly modified by nitrate within 15 h. Root hydraulic conductances were measured by using either hydrostatic-pressure or osmotic-gradient methods. During hydrostatic experiments, the conductance (kp), which is thought to refer mainly to the apoplasmic pathway, was 1.6 times larger in KNO3-than in KCl-treated plants. From experiments in which polyethylene glycol (PEG) 8000 was used as external osmolyte, osmotic conductances (ks) were found to be smaller by 5–20 times than kp for the two kinds of plants. The KCl-treated roots were characterized by a low ks which was the same for influx or efflux of water. By contrast, KNO3-treated roots exhibited two distinct conductances ks1 and ks2, indicating that influx of water was easier than efflux when the water flow was driven by the osmotic pressure gradient. Infiltration of roots with KNO3 solution supported the idea that nitrate might enhance the efficiency of the cell-to-cell pathway. The low ks value of KCl-treated roots and the existence of two contrasting ks values (ks1 and ks2) for KNO3-treated roots are discussed in terms of reversible closing of water channels.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- BM:
-
basic medium
- Ce :
-
external solute concentration
- Cx :
-
xylem solute concentration
- kp :
-
hydrostatic conductance measured under hydrostatic pressure P (kp1: measured with P applied on the root system; kp2: measured with P applied on the xylem sap)
- ks :
-
osmotic conductance (ks1: low osmotic conductance, ks2: high osmotic conductance)
- Lp :
-
hydraulic conductivity
- P:
-
hydrostatic pressure
- PEG:
-
polyethylene glycol
- Ψe :
-
water potential of root bathing medium
- Q0 :
-
free exudation rate
References
Aschroft RT, Wallace A, Abou-Zamzan A (1972) Nitrogen pretreatments vs nitrate treatments after detopping on xylem exudation in tobacco. Plant Soil 36: 407–416
Azaizeh H, Steudle E (1991) Effects of salinity on water transport of excised maize (Zea mays L.) roots. Plant Physiol 97: 1136–1145
Barthes L, Bousser A, Hoarau J, Deléens E (1995). Reassessment of the relationship between nitrogen supply and xylem exudation in detopped maize seedlings. Plant Physiol Biochem 33: 173–183
Birner PT, Steudle E (1993) Effects of anaerobic conditions on water and solute relations, and on active transport in roots of maize (Zea mays L.). Planta 190: 474–483
Boyer JS (1985) Water transport. Annu Rev Plant Physiol 36: 473–516
Chrispeels MJ, Maurel C (1994) Aquaporins: the molecular basis of facilitated water movement through living plant cells? Plant Physiol 105: 9–13
Clarkson DT, Robards AW, Stephens AW, Stark M (1987) Suberin lamellae in the hypodermis of maize (Zea mays) roots: development and factors affecting the permeability of hypodermal layers. Plant Cell Environ 10: 83–93
Cruz RT, Jordan WR, Drew MC (1992) Structural changes and associated reduction of hydraulic conductance in roots of Sorghum bicolor L. following exposure to water deficit. Plant Physiol 99: 203–212
Dainty J (1985) Water transport through the root. Acta Hort 171: 21–31
Ezeta FN, Jackson WA (1975) Nitrate translocation by detopped corn seedlings. Plant Physiol 56: 148–156
Fiscus EL (1975) The interaction between osmotic-and pressureinduced water flow in plants roots. Plant Physiol 55: 917–922
Henzler T, Steudle E (1995) Reversible closing of water channels in Chara internodes provides evidence for a composite transport model of the plasma membrane. J Exp Bot 46: 199–209
Läuchli A, Spur AR, Epstein E (1971) Lateral transport of ions into the xylem of corn roots. II. Evaluation of a stelar pump. Plant Physiol 48: 118–124
Maggio A, Joly RJ (1995) Effects of mercury chloride on the hydraulic conductivity of tomato root systems. Evidence for a channelmediated water pathway. Plant Physiol 109: 331–335
Meiri A, Anderson WP (1970) Observations on the effects of pressure differences between the bathing medium and the exudates of excised maize roots. J Exp Bot 21: 899–907
Melchior W, Steudle E (1993) Water transport in onion (Allium cepa L.) roots. Changes of axial and radial hydraulic conductivities during root development. Plant Physiol 101: 1305–1315
Michel BE (1983) Evaluation of the water potentials of solutions of polyethylene glycol 8000 both in the absence and presence of other solutes. Plant Physiol 72: 66–70
Miller DM (1985) Studies of root function in Zea mays. IV. Effects of applied pressure on the hydraulic conductivity and volume flow through the excised root. Plant Physiol 77: 168–174
Miller DM (1987) Errors in the measurement of root pressure and exudation volume flow rate caused by damage during the transfer of unsupported roots between solutions. Plant Physiol 85: 164–166
Minshall WH (1964) Effect of nitrogen-containing nutrients on the exudation from detopped tomato plants. Nature 202: 925–926
Minshall WH (1968) Effect of nitrogenous materials on translocation and stump exudation in root system of tomato plants. Can J Bot 46: 363–376
Newman EI (1976) Water movement through root systems. Philos Trans R Soc Lond B 273: 463–478
Pitman MG, Welfare D, Carter C (1981) Reduction of hydraulic conductivity during inhibition of exudation from excised maize and barley roots. Plant Physiol 67: 802–808
Radin JW, Boyer JS (1982) Control of leaf expansion by nitrogen nutrition in sunflower plants: role of hydraulic conductivity and turgor. Plant Physiol 69: 771–775
Radin JW, Matthews MA (1989) Water transport properties of cortical cells in roots of nitrogen- and phosphorus-deficient cotton seedlings. Plant Physiol 89: 264–268
Schambil F, Woerman D (1989) Radial transport of water across cortical sleeves of excised roots of Zea mays L. Planta 178: 488–494
Steudle E (1994) The regulation of plant water at the cell, tissue and organ level: role of active processes and of compartmentation. In: Schulze (ed) Flux control in biological systems. From enzymes to populations and ecosystems. Academic Press, San Diego, pp 237–239
Steudle E, Frensch J (1989) Osmotic responses of maize roots. Planta 177: 281–295
Steudle E, Henzler T (1995) Water channels in plants: do basic concepts of water transport change? J Exp Bot 46: 1067–1076
Steudle E, Oren R, Schulze ED (1987) Water transport in maize roots. Plant Physiol 84: 1220–1232
Steudle E, Murrmann M, Peterson CA (1993) Transport of water and solutes across maize roots modified by puncturing the endodermis. Further evidence for the composite transport model of the root. Plant Physiol 103: 335–349
Steuter AA, Mozafar A, Goodin JR (1981) Water potential of aqueous polyethylene glycol. Plant Physiol 67: 64–67
Touraine B, Grignon C (1982) Potassium effect on nitrate secretion into the xylem roots. Physiol Vég 20: 23–31
Zhu GL, Steudle E (1991) Water transport across maize roots. Plant Physiol 95: 305–315
Zimmermann U, Rygol J, Balling A, Klock G, Metzler A, Haase A (1992) Radial turgor and osmotic pressure profiles in intact and excised roots of Aster tripolium. Plant Physiol 99: 186–196
Author information
Authors and Affiliations
Additional information
We are indebted to Professor J. Dainty for his criticisms and the careful review of the manuscript before its submission and Professor E. Steudle for many helpful discussions at Bayreuth and Orsay.
Rights and permissions
About this article
Cite this article
Hoarau, J., Barthes, L., Bousser, A. et al. Effect of nitrate on water transfer across roots of nitrogen pre-starved maize seedlings. Planta 200, 405–415 (1996). https://doi.org/10.1007/BF00231396
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00231396