Cation exchange on plant roots involving aluminium: Experimental data and modeling

Trace Elements in the Rhizosphere

Volumn , Issue , 2000, Pages 227-252

  Dufey, Joseph E ^a   Genon, José G ^a   Jaillard, Benoît ^b   Calba, Henri ^c   Rufyikiri, Gervais ^a   Delvaux, Bruno ^a  

^a UNIVERSITÉ CATHOLIQUE DE LOUVAIN   (Belgium)

^b CEMAGREF   (France)

^c CIRAD   (France)

Author keywords

[No Author keywords available]

Indexed keywords

EID: 85056955724     PISSN: None     EISSN: None     Source Type: Book    
DOI: None     Document Type: Chapter

References (95)

1. Hinsinger, Ph., 1998, How do plant roots acquire mineral nutrients? Chemical processes involved in the rhizosphere, Advances in Agronomy, 64, 225-265.
2. Knight, A.H., W.M. Crooke, and R.H.E. Inkson, 1961, Cation exchange capacities of tissues of higher and lower plants and their related uronic acid contents, Nature, 192, 142-143.
3. Horst, W.J., 1995, The role of apoplast in aluminium toxicity and resistance of higher plants: a review, Zeitschrift für Pflanzenernährung und Bodenk., 158, 419-428.
4. Marienfeld S., H. Lehmann, and R. Stelzer, 1995, Ultrastructural investigation and EDX-analyses of Al-treated oat (Avena sativa) roots, Plant and Soil, 171, 167-173.
5. Rasmussen, H.P., 1968, Entry and distribution of aluminium in Zea Mays, Planta (Berl.), 28-37.
6. Chen, J., E.I. Sucoff, and E.J. Stadelmann, 1991, Aluminium and temperature alteration of cell membrane permeability of Quercus rubra, Plant Physiol., 96, 644-649.
7. 3+on the physical properties of membrane lipids in Thermoplasma acidphilum, Biochim. Biophys. Res. Commun., 84, 138-144.
8. Ishikawa, S. and T. Wagatsuma, 1998, Plasma membrane permeability of root-tip cells following temporary exposure to Al ions is a rapid measure of Al tolerance among plant species, Plant Cell Physiol., 39, 516-525.
9. Dufey, J.E. and R. Braun, 1986, Cation exchange capacity of roots: titration, sum of exchangeable cations, copper adsorption, J. Plant Nutr., 9, 1147-1155.
10. Pintro, J., J. Barloy, and P. Fallavier, 1998, Uptake of aluminium by the root tips of an Al-sensitive and Al-tolerant cultivar of Zea mays, Plant Physiol. and Biochem., 36(6), 463-467.
11. Calba, H., P. Cazevielle, and B. Jaillard, 1999, Modelling of the dynamics of Al and protons in the rhizosphere of maize cultivated in acid substrate, Plant and Soil, 209, 57-69.
12. Rengel, Z. and D.L. Robinson, 1989, Determination of cation exchange capacity of rye-grass roots by summing exchangeable cations, Plant and Soil, 116, 217-222.
13. Cronan, C.S., 1991, Differential adsorption of Al, Ca, and Mg by roots of red spruce (Picea rubens Sagr.), Tree Physiology, 8, 227-237.
14. Godbold, D.L. and G. Jentschke, 1998, Aluminium accumulation in root cell walls coincides with inhibition of root growth but not with inhibition of magnesium uptake in Norway spruce, Physiologia Plantarum, 102, 553-560.
15. Wacquant, J.P., 1974, Recherche sur les propriétés d’adsorption cationique des racines, Ph.D. Thesis, Université des Sciences et Techniques du Languedoc, Montpellier, 141.
16. Dufey, J.E., D. Drimmer, I. Lambert, and P. Dupont, 1991, Composition of root exchange sites in acidic soil solutions, in Plant Roots and Their Environment, B.L. McMichael and H. Persson, Eds., Elsevier Science Publishers, Amsterdam, 31-38.
17. Crooke, W.M., A.H. Knight, and J.R. McDonald, 1960, Cation exchange capacity and pectin gradients in leek root segments, Plant and Soil, 13, 123-127.
18. Chamuah, G.S. and S.K. Dey, 1982, Cation exchange of clonal tea plants and its implications of fertilizers responses, J. Sci. Food Agric., 33, 309-317.
19. Ayadi, A., A. Monnier, N. Demarty, and M. Thellier, 1980, Echanges ioniques cellulaires:cas des plantes en milieu salés. Rôle particulier des parois cellulaires, Physiol. Végét., 18, 89-104.
20. Woodward, R.A., K.T. Harper, and A.R. Tiedemann, 1984, An ecological consideration of the significance of CEC of roots of some Utah range plants, Plant and Soil, 79, 169-180.
21. Ae, N., T. Otani, T. Makino, and J. Tazawa, 1996, Role of cell wall of groundnut roots in solubilizing sparingly soluble phosphorus in soil, Plant and Soil, 186, 197-204.
22. Mugwira, L.M. and S.M. Elgawhary, 1979, Aluminium accumulation and tolerance of triticale and wheat in relation to root cation exchange capacity, Soil Sci. Soc. Am. J., 43, 736-740.
23. +, and other cations on root elongation considered in terms of cell-surface electrical potential, Plant Physiol., 99, 1461-1468.
24. Zhang, G., J.J. Slaski, D.J. Archambault, and G.J. Taylor, 1997, Alteration of plasma membrane lipids in aluminium-resistant and aluminium-sensitive wheat genotypes in response to aluminium, Physiologia Plantarum, 99, 302-308.
25. Jones, D.L. and L.V. Kochian, 1997, Aluminium interaction with plasma membrane lipids and enzyme metal binding sites and its potential role in Al cytotoxicity, FEBS Lett., 400, 51-57.
26. Wagatsuma, T., 1983, Characterization of absorption sites for aluminium in the roots, Soil Sci. Plant Nutr., 29, 499-515.
27. Munn, D.A. and R.E. McCollum, 1976, Solution culture evaluation of sweet potato cultivar tolerance to aluminium, Agron. J., 68, 989-991.
28. +release by maize, New Phytol., 137, 607-616.
29. Lindsay, W.L., 1979, Chemical Equilibria in Soils, John Wiley & Sons, New York, 449.
30. Ritchie, G.S.P., 1995, Soluble aluminium in acidic soils: Principles and practicabilities, Plant and Soil, 171, 17-27.
31. Dahlgren, R.A., K.A. Vogt, and F.C. Ugolini, 1991, The influence of soil chemistry on fine root aluminium concentrations and root dynamics in a subalpine Spodosol, Washington State, USA, Plant and Soil, 133, 117-129.
32. Rufyikiri, G., 2000, Constraintes nutritionnelles chez le bananier (Musapp.) cultivé en milieux riches en aluminium soluble et consequences sur sacroissance, Ph.D. thesis, Université Catholique de Louvain, Louvain-la-Neuve, Belgique, 158.
33. Thomas, G.W., 1977, Historical developments in soil chemistry: ion exchange, Soil Sci. Soc. Am. J., 41, 230-237.
34. Sposito, G., 1981, Cation exchange in soils: an historical and theoretical perspective, in Chemistry in the Soil Environment, D.E. Baker, R.H. Dowdy, J.A. Ryan, and V.V. Volk, Eds., Spec. Publ. 40. Am. Soc. Agron., Soil Sci. Soc. Am., Madison, WI, 13-30.
35. Vanselow, A.P., 1932, Equilibria of the base-exchange reactions of bentonites, permutites, soil colloids, and zeolites, Soil Sci., 33, 95-113.
36. Gapon, E.N., 1933, On the theory of exchange adsorption in soils, J. Gen. Chem. USSR, 3, 144-163 (in Russian).
37. Gaines, G.L. and H.C. Thomas, 1953, Adsorption studies on clay minerals. II. A formulation of the thermodynamics of exchange adsorption, J. Chem. Phys., 21, 714-718.
38. Goulding, K.W.T. and O. Talibudeen, 1980, Heterogeneity of cation exchange sites for K-Ca exchange in aluminosilicates, J. Colloid. Interface Sci., 78, 15-24.
39. Inoue, A., 1984, Thermodynamic study of Na-K-Ca exchange reactions in vermiculite, Clays Clay Min., 32, 311-319.
40. Jardine, P.M. and D.L. Sparks, 1984, Potassium-calcium exchange in a multireactive soil system. II. Thermodynamics, Soil Sci. Soc. Am. J., 48, 45-50.
41. Levy, R. and I. Shainberg, 1972, Calcium-magnesium exchange in montmorillonite and vermiculite. Clays Clay Min., 20, 37-46.
42. 3+exchange on montmorillonite, Soil Sci. Soc. Am. J., 44, 964-969.
43. Fletcher, P., K.M. Holtzclaw, C. Jouany, G. Sposito, and C.S. Levesque, 1984, Sodium-calcium-magnesium exchange reactions on a montmorillonitic soil. 2. Ternary exchange reactions, Soil Sci. Soc. Am. J., 48, 1022-1025.
44. Shaviv, A. and S.V. Mattigod, 1985, Cation exchange equilibria in soils expressed as cation-ligand complex formation, Soil Sci. Soc. Am. J., 49, 569-573.
45. Sposito, G. and J. Coves, 1988, SOILCHEM: A computer program for the calculation of chemical speciation in soils, The Kearney Foundation of Soil Science, University of California, Riverside, CA.
46. Thellier, C. and G. Sposito, 1988, Quaternary cation exchange on Silver Hill illite, Soil Sci. Soc. Am. J., 52, 979-985.
47. Thellier, C., and G. Sposito, 1989, Influence of electrolyte concentration on quaternary cations exchange by Silver Hill illite, Soil Sci. Soc. Am. J., 53, 705-711.
48. Thellier, C., G. Sposito, and K.M. Holtzclaw, 1992, Proton effect on quaternary cation exchange and flocculation of Silver Hill illite, Soil Sci. Soc. Am. J., 56, 427-433.
49. Wada, S.I. and H. Seki, 1994, Ca-K-Na exchange equilibria on a smectitic soil:modeling the variation of selectivity coefficient, Soil Sci. Plant Nutr., 40, 629-636.
50. Grant, S.A., R.S. Mansell, S.A. Bloom, and R.D. Rhue, 1995, Simulated transport of three cations through porous media: effect of different approaches to modeling cation exchange reactions, Water Resources Res., 31, 185-198.
51. Cosby, B.J., G.M. Hornberger, J.N. Galoway, and R.F. Wright, 1985, Modeling the effects of acid deposition: Assessment of a lumped parameter model for soil water and streamwater chemistry, Water Resources Res., 21, 51-63.
52. Hendershot, W.H. and F. Courchesne, 1991, Simulation of solution chemistry in an acidic forest soil, Water, Air and Soil Pollut., 60, 11-25.
53. Robbins, C.W., 1991, Solute Transport and Reactions in Salt-Affected Soils, in Modeling Plant and Soil Systems - Agronomy Monograph 31, J. Hanks and J.T. Ritchie, Eds., ASA-CSSA-SSSA, Madison, Wisconsin, 365.
54. Sheta, T.H., G.R. Gobran, J.E. Dufey, and H. Laudelout, 1981, Sodium-calcium exchange in Nile Delta soils: single values for Vanselow and Gaines-Thomas selectivity coefficients, Soil Sci. Soc. Am. J., 45, 749-753.
55. Appelo, C.A.J., 1994, Some calculations on multicomponent transport with cation exchange in aquifers, Ground Water, 32, 968-975.
56. Jensen, H.E., 1973a, Potassium-calcium exchange equilibria on a montmorillonite and kaolinite clay. I. A test on the Argersinger thermodynamic approach, Agrochimica, 17, 181-190.
57. Momii, K., Y. Hiroshiro, K. Jinno, and R. Berndtsson, 1997, Reactive solute transport with a variable selectivity coefficient in an undisturbed soil column, Soil Sci. Soc. Am. J., 61, 1539-1546.
58. Barrer, R.M. and J. Klinowski, 1972, Ion exchange involving several groups of homogeneous sites, J. Chem. Soc. Farraday Trans. I., 68, 73-87.
59. Sposito, G., K.M. Holtzclaw, L. Charlet, C. Jouany, and A.L. Page, 1983b, Sodiumcalcium and sodium-magnesium exchange on Wyoming bentonite in perchlorate and chloride bachground ionic media, Soil Sci. Soc. Am. J., 47, 51-56.
60. Pratt, P.F. and B.L. Grover, 1964, Monovalent-divalent cation exchange equilibria in soils in relation to organic matter and type of clay, Soil Sci. Soc. Am. Proc., 28, 32-35.
61. Helling, C.S., G. Chesters, and R.B. Corey, 1964, Contribution of organic matter and clay to soil cation exchange capacity as affected by pH of the saturating solution, Soil Sci. Soc. Am. Proc., 28, 517-520.
62. Dufey, J.E. and B. Delvaux, 1989, Modeling potassium-calcium exchange isotherms in soils, Soil Sci. Soc. Am. J., 53, 1297-1299.
63. Tipping, E., 1994, WHAM - a chemical equilibrium model and computer code for waters, sediments, and soils incorporating a discrete site/electrostatic model of ionbinding by humic substances, Computer Geosci., 20, 973-1023.
64. Bresler, E., 1970, Numerical solution of the equation for interacting diffuse layers in mixed ionic systems with nonsymmetrical electrolytes, J. Colloid Interface Sci., 33, 278-283.
65. Jensen, H.E., 1973b, Potassium-calcium exchange equilibria on a montmorillonite and kaolinite clay. II. Application of double-layer theory, Agrochimica, 17, 191-201.
66. Shang, J.Q., K.Y. Lo, and R.M. Quigley, 1994, Quantitative determination of potential distribution in Stern-Gouÿ double-layer model, Can. Geotech. J., 31, 624-636.
67. Pashley, R.M. and J.P. Quirk, 1997, Co-Ion exclusion by clay surfaces. I. Equations for 1:1, 2:1, and 3:1 electrolyte solutions, Soil Sci. Soc. Am. J., 61, 58-63.
68. Amory, D.E. and J.E. Dufey, 1985, Model for the electrolytic environment and electrostatic properties of biomembranes, J. Bioenergetics Biomembranes, 17, 151-174.
69. Kinraide, T.B., 1994, Use of a Gouy-Chapman-Stern model for membrane-surface electrical potential to interpret some features of mineral rhizotoxicity, Plant Physiol., 106, 1583-1592.
70. Kinraide, T.B., U. Yermiyahu, and G. Rytwo, 1998, Computation of surface electrical potentials of plant cell membranes, Plant Physiol., 118, 505-512.
71. Miyajima, T., K. Yoshida, Y. Kanegae, H. Tohfuku, and J.A. Marinsky, 1991, Metal complexation of negatively charged polymers: evaluation of the electrostatic effect on the complexation equilibria, Reactive Polymers, 15, 55-62.
72. Miyajima, T., Y. Kanegae, K. Yoshida, M. Katsuki, and Y. Naitoh, 1992, A Donnan model for the analysis of metal complexation of weak-acidic polyelectrolytes - an approach to the quantitative analytical treatment of the metal complexation equilibria of humic substances, Sci. Total Envir., 117/118, 129-137.
73. Sentenac, H. and C. Grignon, 1981, A model for predicting ionic equilibrium concentrations in cell walls, Plant Physiol., 68, 415-419.
74. Kinniburgh, D.G., C.J. Milne, M.F. Benedetti, J.P. Pinheiro, J. Filius, L.K. Koopal, and W.H. van Riemsdijk, 1996, Metal ion binding by humic acid: application of the NICA-Donnan model, Environ. Sci. Technol., 30, 5, 1687-1698.
75. Benedetti, M.F., W.H. van Riemsdijk, and L.K. Koopal, 1996, Humic substances considered as a heterogeneous Donnan gel phase, Environ. Sci. Technol., 30(6), 1805-1813.
76. Plette, A.C.C., W.H. van Riemsdijk, M.F. Benedett, and A. van der Wal, 1995, pH dependent charging behavior of isolated cell walls of a Gram-positive soil bacterium, J. Colloid Interface Sci., 173, 354-363.
77. Tipping, E. and M.A. Hurley, 1988, A model of solid-solution interactions in acid organic soils, based on the complexation properties of humic substances, J. Soil Sci., 39, 505-519.
78. Tipping, E. and C. Woof, 1990, Humic substances in acid organic soils: Modelling their release to the soil solution in terms of humic charge, J. Soil Sci., 41, 573-586.
79. Tipping, E. and C. Woof, 1991, The distribution of humic substances between the solid and aqueous phases of acid organic soils. A description based on humic heterogeneity and charge-dependent sorption equilibria, J. Soil Sci., 42, 437-448.
80. Tipping, E., 1993, Modeling the binding of europium and the actinides by humic substances, Radiochimica Acta, 62, 141-152.
81. Tipping, E., D. Berggren, J. Mulder, and C. Woof, 1995a, Modelling the solid-solution distributions of protons, aluminium, base cations and humic substrances in acid soils, Europ. J. Soil Sci., 46, 77-94.
82. Tipping, E., A. Fitch, and F.J. Stevenson, 1995b, Proton and copper binding by humic acid: application of a discrete-site/electrostatic ion-binding model, Europ. J. Soil Sci., 46, 95-101.
83. Marinsky, J.A., 1995, An assessment of various approaches to the interpretation of ion-exchange equilibria, React. Functional Polym., 27, 107-115.
84. Sposito, G., K.M. Holtzclaw, L. Charlet, and C. Jouany, 1983a, Cation selectivity in sodium-calcium, sodium-magnesium, and calcium-magnesium exchange on Wyoming bentonite at 298 K, Soil Sci. Soc. Am. J., 47, 917-921.
85. Evangelou, V.P., 1986, The influence of anions on potassium quantity-intensity relationships, Soil Sci. Soc. Am. J., 50, 1182-1188.
86. Morel, F. and J. Morgan, 1972, A numerical method for computing equilibria in aqueous chemical systems, Environ. Sci. Tech., 6(1), 58-67.
87. Baes, A.U. and P.R. Bloom, 1988, Exchange of alkaline earth cations in soil organic matter, Soil Sci., 146, 6-14.
88. SAS Institute, Inc., 1985, SAS User’s Guide: Statistics 5th ed., SAS Inst., Cary, NC.
89. Amory, D.E. and J.E. Dufey, 1984, Adsorption and exchange of Ca, Mg and K-ions on the root cell walls of clover and rye-grass, Plant and Soil, 80, 181-190.
90. Bates, D.M. and D.G. Watts, 1988, Nonlinear Regression Analysis and its Applications, John Wiley & Sons, New York.
91. Whitehead, D.C., H. Buchan, and R.D. Hartley, 1979, Composition and decomposition of roots of ryegrass and red clover, Soil Biol. Biochem., 11, 619-628.
92. Ritchie, R.J. and A.W.D. Larkum, 1982, Cation exchange properties of the cell walls of Enteromorpha intestinalis (L.) Link. (Uvales, Chlorophyta), J. Exp. Bot., 33, 132, 125-139.
93. Gahoonia, T.S., 1993, Influence of root-induced pH on the solubility of soil aluminium in the rhizosphere, Plant and Soil, 149, 289-291.
94. Hinsinger, Ph. and R.J. Gilkes, 1995, Root-induced dissolution of phosphate rock in the rhizosphere of lupins grown in alkaline soil, Austr. J. Soil Res., 33, 477-489.
95. Jones, D.L. and L.V. Kochian, 1996, Aluminium-organic acid interactions in acid soils. I. Effect of root-derived organic acids on the kinetics of Al dissolution, Plant and Soil, 182, 221-228.