Abstract
Historically nutritional studies of anoxic plants have simply catalogued concentration and uptake changes of treated plants, frequently on a non-partitioned whole-plant basis. Major reviews of soil aeration and flooding generally agree that N, P, and K concentrations in plants are reduced by anoxia (Kozlowski, 1984; Glinski and Stepniewski, 1985). Sodium concentration increases and other major elements either remain unaffected or react irregularly. Until recent years explanations of nutritional changes have focused chiefly on alterations in the poorly aerated soil physicochemical environment. Factors such as: increased mineral solubilization, leaching, and dilution in high water content soils, increased water film coverage of roots, altered ion diffusion, solubility changes at altered valence states, altered pH resulting from redox reactions or increased CO2 concentrations, etc. have been used to explain nutritional responses to oxygen-limiting soil environments.
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References
Armstrong, W. (1971) Radial oxygen losses from intact rice roots as affected by distances from the apex, respiration and waterlogging. Physiol. Plant, 25, 192–7
Arnon, D.I. (1937) Ammonium and nitrate nitrogen nutrition of barley and at different seasons in relation to hydrogen ion concentrations, manganese, copper, and oxygen supply. Soil Sci., 44, 91–113
Bejaoui, M. (1980) Effects du NaC1 sur l’elongation, la georeaction et l’absorption d’oxygene de segments apicaux de racines de soja (Glycine max (L.) Merr.). Physiol. Veg., 18, 737–47
Bradford, K.J. (1982) Regulation of shoot responses to root stress by ethylene, abscisic acid, and cytokinin. In P.F. Warring Plant growth substances, Academic Press, London, pp. 599–608
Bradford, K.J, (1983) Involvement of plant growth substances in the alteration of leaf gas exchange of flooded tomato plants. Plant Physiol, 73, 480–3
Bradford, K.J. and Yang, S.F. (1981) Physiological responses of plants to waterlogging. HortScience, 16, 25–30
Bryce, J.H., Focht, D.D. and Stolzy, L.H. (1982) Soil aeration and plant growth response to urea peroxide fertilization. Soil Sci., 134, 111–16
Cooper, R.B., Blaser, R.E. and Brown, R.H. (1967) Potassium nutrition effects on net photosynthesis and morphology of alfalfa. Soil Sci. Soc. Am. Proc., 31, 231–5
Das, D.K. and Jat, R.L. (1977) Influence of three soil-water regimes on root porosity and growth of four rice varieties. Agron. J., 69, 197–200
Drew, M.C. and Dikumwin, E. (1985) Sodium exclusion from the shoots by roots of Zea mays (cv. LG11) and its breakdown with oxygen deficiency. J. Exp. Bot., 36, 55–62
Drew, M.C., Jackson, M.B. and Gifford, S. (1979) Ethylene-promoted adventitious rooting and development of cortical air spaces (aerenchyma) in roots may be adaptive responses to flooding in Zea mays L. Planta, 147, 83–8
Drew, M.C., Jackson, M.B., Gifford, S.C. and Campbell, R. (1981) Inhibition by silver ions of gas space (aerenchyma) formation in adventitious roots of Zea mays L. subjected to exogenous ethylene or to oxygen deficiency. Planta, 153, 217–24
Drew, M.C. and Läuchli, A. (1985) Oxygen-dependent exclusion of sodium ions from shoots by roots of Zea mays (cv. Pioneer 3906) in relation to salinity damage. Plant Physiol, 79, 171–611
Drew, M.C. and Lynch, J.M. (1980) Soil anaerobiosis, micro-organisms, and root function. Ann. Rev. Phytopathol., 18, 37–66
Drew, M.C. and Sisworo, E.J. (1977) Early effects of flooding on nitrogen deficiency and leaf chlorsis in barley. New Phytol, 79, 567–71
Drew, M.C. and Sisworo, E.J. (1979) The development of waterlogging damage in young barley plants in relation to plant nutrient status and changes in soil properties. New Phytol, 82, 301–14
Drew, M.C., Sisworo, E.J. and Saker, L.R. (1979) Alleviation of waterlogging damage to young barley plants by application of, nitrate and a synthetic cytokinin, and comparison between the effects of waterlogging, nitrogen deficiency and root excision. New Phytol, 82, 315–29
Dunn, G.A. (1921) Note on the histology of grain roots. Am. J. Bot., 8, 207–11
El-Beltagy, A.S. and Hall, M.A. (1974) Effect of water stress upon endogenous ethylene levels in Vicia faba. New Phytol, 73, 47–60
Fischer, R.A. (1968) Stomatal opening: role of potassium ion uptake by guard cells. Science, 168, 784–5
Fujino, M. (1959) Stomatal movement and active migration of potassium (Japanese). Kagaku, 29, 600–61
Garcia-Novo, F. and Crawford, R.M.M. (1973) Soil aeration, nitrate reduction and flooding tolerance in higher plants. New Phytol, 72, 1031–9
Gilbert, S.G. and Shive, J.W. (1942) The significance of oxygen in nutrient substrates for plants: The oxygen requirement. Soil Sci, 53, 143–52
Glinski, J. and Stepniewski, W. (1985) Soil aeration and its role for plants. CRC Press, Boca Raton, 229 pp.
Graham, R.D. and Ulrich, A. (1972) Potassium deficiency-induced changes in stomatal behavior, leaf water potentials, and root system permeability in Beta vulgaris L. Plant Physiol., 49, 105–9
Hall, M.A., Kapuya, J.A., Sivakumaran, S. and John A. (1977) The role of ethylene in the responses of plants to stress. Pest. Sci, 8, 217–23
Hammond, L.C.,Alloway, W.H. and Loomis, W.E. (1955) Effects of oxygen and carbon dioxide levels upon absorption of potassium by plants. Plant Physiol., 30, 155–61
Hardcastle, J. and Schutte, K.H. (1983) Aspects of an experimental study on root aerenchyma development and the ecological implications thereof. Bothalia, 14, 791–4
Herr, E.M. and Jarell, W.M. (1980) Response of chrysanthemum to urea peroxide. HortScience, 15, 501–2
Hiron, R.W.P. and Wright, S.T.C. (1973) The role of endogenous abscisic acid in the response of plants to stress. J. Exp. Bot., 24, 769–81
Hocking, P.J., Reicosky, D.C. and Meyer, W.S. (1985) Nitrogen status of cotton subjected to two short term periods of waterlogging of varying severity using a sloping plot water-table facility. Plant Soil, 87, 375–91
Hodgson, A.S. (1982) The effects of duration, timing and chemical amelioration of short-term waterlogging during furrow irrigation of cotton in a cracking grey clay. Aust. J. Agric. Res., 33, 1019–28
Jackson, M.B. (1985) Ethylene and responses of plants to soil waterlogging and submergence. Ann. Rev. Plant Physiol., 36, 145–74
Jackson, M.B., Drew, M.C. and Gifford, S.C. (1981) Effects of applying ethylene to the root system of Zea mays on growth and nutrient concentration in relation to flooding tolerance. Physiol. Plant., 52, 23–8
Jackson, M.B., Fenning, T.M. and Jenkins, W. (1985) Aerenchyma (gas-space) formation in adventitious roots of rice (Oryza sativa L.) is not controlled by ethylene or small partial pressures of oxygen. J. Exp. Bot., 36, 1566–72
Jones, R.J. and Mansfield, T.A. (1970) Suppression of stomatal opening in leaves treated with abscisic acid. J. Exp. Bot., 21, 714–19
Jones, R.J. and Mansfield, T.A. (1972) Effects of abscisic acid and its esters on stomatal aperture and the transpiration ratio. Physiol. Plant., 26, 321–7
Karlen, D.L., Sojka, R.E. and Robbins, M.L. (1983) Influence of excess soil-water and N-rates on leaf diffusive resistance and storage quality of tomato fruit. Commun. Soil Sci. Plant Anal., 14, 699–708
Konings, H. (1982) Ethylene-promoted formation of aerenchyma in seedling roots of Zea mays L. under aerated and non-aerated conditions. Physiol. Plant., 54, 119–24
Konings, H. and de Wolf, A. (1984) Promotion and inhibition by plant growth regulators of aerenchyma formation in seedling roots of Zea mays. Physiol. Plant., 60, 309–14
Konings, H. and Verschuren, G. (1980) Formation of aerenchyma in roots of Zea mays in aerated solutions, and its relation to nutrient supply. Physiol. Plant., 49, 265–70
Kozlowski, T.T. (ed.) (1984) Flooding and plant growth. Academic Press, New York, 356 pp.
Labanauskas, C.K., Letey, J., Stolzy, L.H. and Valoras, M. (1966) Effects of soil-oxygen and irrigation on the accumulation of macro-and micronutrients in citrus seedlings (Citrus sinensis Var. Osbeck). Soil Sci, 101, 378–84
Labanauskas, C.K., Stolzy, L.H. and Handy, M.F. (1972) Concentrations and total amounts of nutrients in citrus seedlings (Citrus sinensis Var. Osbeck) and in soil as influenced by differential soil oxygen treatments. Soil Sci. Soc. Am. Proc., 36, 457–64
Labanauskas, C.K., Stolzy, L.H., Klotz, L.J. and de Wolf, T.A. (1971) Soil oxygen diffusion rates and mineral accumulations in citrus seedlings (Citrus sinensis Var. Bessie). Soil Sci, 111, 386–92
Labanauskas, C.K., Stolzy, L.H. and Luxmoore, R.J. (1975) Soil temperature and soil aeration effects on concentrations and total amounts of nutrients in ‘Yecora’ wheat grain. Soil Sci, 120, 450–4
Leggett, J.E. and Stolzy, L.H. (1961) Anaerobiosis and sodium accumulation. Nature, 192, 991–2
Letey, J., Stolzy, L.H., Blank, G.B. and Lunt, O.R. (1961) Effect of temperature on oxygen-diffusion rates and subsequent shoot growth, root growth, and mineral content of two plant species. Soil Sci, 92, 314–21
Letey, J., Stolzy, L.H. and Valoras, N. (1965) Relationships between oxygen diffusion rate and corn growth. Agron. J., 57, 91–2
Letey, J., Stolzy, L.H., Valoras, N. and Szuszkiewicz, T.E. (1962) Influence of soil oxygen on growth and mineral concentration of barley. Agron. J., 54, 538–40
Leyshon, A.J. and Sheard, R.W. (1974) Influence of short-term flooding on the growth and plant nutrient composition of barley. Can. J. Soil Sci, 54, 463–73
Lotocki, A. (1977) Effect of root aeration and form of nitrogen on photosynthetic productivity of Scots pine (Pinus silvestris L.). Acta Soc. Bot. Polon., 46, 303–16
Luxmoore, R.J., Sojka, R.E. and Stolzy, L.H. (1972) Root porosity and growth responses of wheat to aeration and light intensity. Soil Sci, 113, 354–7
McCallum, A.B. (1905) On the distribution of potassium in animal and vegetable cells. J. Physiol. (London), 32, 95–118
McKee, W.H., Jr, Hook, D.D., DeBell, D.S. and Askew, J.L. (1984) Growth and nutrient status of loblolly pine seedlings in relation to flooding and phosphorus. Soil Sci. Soc. Am. J., 48, 1438–42
McPherson, D.C. (1939) Cortical air spaces in the roots of Zea mays L. New Phytol., 38, 190–202
MacRobbie, E.A.C. (1981) Effects of ABA in isolated guard cells of Commelina communis L. J. Exp. Bot., 32, 563–72
Magunda, M.K., Callebaut, F., DeBoot, M. and Gabriels, D. (1984) Role of calcium peroxide as a soil conditioner and oxygen fertilizer. Trop. Agric., (Trinidad), 61, 250–2
Malovolta, E. (1954) Studies on the nitrogenous nutrition of rice. Plant Physiol, 29, 98–9
Mansfield, T.A. and Jones, R.J. (1971) Effects of abscisic acid on potassium uptake and starch content of stomatal guard cells. Planta, 101, 147–58
Meek, B.D., Owen-Bartlett, E.C., Stolzy, L.H. and Labanauskas, C.K. (1980) Cotton yield and nutrient uptake in relation to water table depth. Soil Sci. Soc. Am. J., 44, 301–5
Moldau, H. (1973) Effects of various water regimes on stomatal and mesophyll conductances of bean leaves. Photosynthetica, 7, 1–7
Nazrul Islam, A.K.M., Saha, U.S. and Khan, M.R. (1980) Some aspects of the physiology and ecology of soybean under waterlogged and non-waterlogged condition. Bangladesh J. Bot., 9, 54–9
Pallaghy, C.K. and Raschke, K. (1972) No stomatal response to ethylene. Plant Physiol, 49, 275–6
Papenhuijzen, C. (1979) A comparison of the morphological devel-opment of aerated and non-aerated primary root systems of Phaseolus vulgaris L. Acta Bot. Neerl., 28, 281–7
Patrick, W.H. and Mikkelson, D.S. (1971) Plant nutrient behavior in flooded soil. In R.A. Olson, T.J. Army, J.J. Hanway and V.J. Kilmer (eds), Fertilizer technology and use, Soil Science Society of America, Madison, WI, pp. 187–215
Peaslee, D.E. and Moss, D.N. (1966) Stomatal conductivities in K-deficient leaves of maize (Zea mays L.). Crop Sci, 8, 427–30
Peoples, T.R. and Koch, D.W. (1979) Role of potassium in carbon dioxide assimilation in Medicago sativa L. Plant Physiol., 63, 878–81
Pessoa de Costa, G.T. and Smucker, A.J.M. (1981) Interactions of oxygen-nitrogen-salinity stresses on plant growth and mineral content of sunflower (Helianthus annuus L.) in sand culture. J. Plant Nutr., 3, 887–903
Pierce, M. and Raschke, K. (1980) Correlation between loss of turgor and accumulation of abscisic acid in detached leaves. Planta, 148, 174–82
Ponnamperuma, F.N., Yuan, W.L. and Nhung, M.T.M. (1965) Manganese dioxide as a remedy for a physiological disease of rice associated with reduction of the soil. Nature, 207, 1103–4
Radin, J.W. (1981) Water relations of cotton plants under nitrogen deficiency. IV. Leaf senescence during drought and in its relation to stomatal closure. Physiol. Plant., 51, 145–9
Radin, J.W. and Ackerson, R.C. (1981) Water relations of cotton plants under nitrogen deficiency. III. Stomatal conductance, photosynthesis, and abscisic acid accumulation during drought. Plant Physiol, 67, 115–19
Radin, J.W. and Parker, L.L. (1979) Water relations of cotton plants under nitrogen deficiency. II. Environmental interactions on stomata. Plant Physiol, 64, 499–501
Radin, J.W., Parker, L.L. and Guinn, G. (1982) Water relations of cotton plants under nitrogen deficiency. V. Environmental control of abscisic acid accumulation and stomatal sensitivity to abscisic acid. Plant Physiol, 70, 1066–70
Raskin, I. and Kende, H. (1983) How does deep water rice solve its aeration problem? Plant Physiol, 72, 447–54
Raskin, I. and Kende, H. (1985) Mechanism of aeration in rice. Science, 228, 327–9
Regehr, D.L., Bazzaz, F.A. and Boggess, W.R. (1975) Photosynthesis, transpiration, and leaf conductance of Populus deltoides in relation to flooding and drought. Photosynthetica, 9, 52–61
Reicosky, D.C., Meyer, W.S., Schaefer, N.L. and Sides, R.D. (1985a) Cotton response to short-term waterlogging imposed with a water-table gradient facility. Agric. Water Mgt., 10, 127–43
Reicosky, D.C., Smith R.C.G. and Meyer, W.S. (1985b) Foliage temperature as a means of detecting stress of cotton subjected to a short-term water-table gradient. Agric. For. Met., 35, 193–203
Reid, D.M. and Bradford, K.J. (1984) Effects of flooding on hormone relations. In T.T. Kozlowski (ed.), Flooding and plant growth, Academic Press, Orlando, pp. 195–219
Russell, E.W. (1976) The chemistry of waterlogged soils. In E.W. Russell (ed.) Soil conditions and plant growth, Longmans, New York, p. 849
Shaybany, B. and Martin, G.C. (1977) Abscisic acid identification and its quantitation in leaves of Juglans seedlings during waterlogging. J. Am. Soc. Hortic. Sci, 102, 300–2
Singh, R. and Ghildyal, B.P. (1980) Soil submergence effects on nutrient uptake, growth and yield of five corn cultivars. Agron. J., 72, 737–41
Sivakumaran, S. and Hall, M.A. (1978) Effects of age and water stress on endogenous levels of plant growth regulators in Euphorbia lathyrus L. J. Exp. Bot., 29, 195–205
Snow, A.G., Jr (1936) Transpiration as modified by potassium. Plant Physiol, 11, 583–94
Sojka, R.E. (1985) Soil-oxygen effects on two determinate soybean isolines. Soil Sci, 140, 333–43
Sojka, R.E. and Busscher, W.J. (1986) A computer-based plant/soilaeration bibliography. Proceedings of Poster Papers. In D.D. Hook et al, Ecology and management of wetlands Vol II management, use and value of of wetlands, Croom Helm Ltd., Kent, UK, pp. 284–9
Sojka, R.E. and Stolzy, L.H. (1980) Soil-oxygen effects on stomatal response. Soil Sci, 130, 350–8
Sojka, R.E., Stolzy, L.H. and Kaufmann, M.R. (1975) Wheat growth related to rhizosphere temperature and oxygen levels. Agron. J., 67, 591–6
Trolldenier, G. and von Rheinbaben (1981) Root respiration and bacterial population of roots. I: Effects of nitrogen source, potassium nutrition and aeration of roots. Z. Pflanzenernaehr. Bodink., 144, 366–77
Trought, M.C.T. and Drew, M.C. (1980a) The development of waterlogging damage in wheat seedlings (Triticum aestivum L.) I. Shoot and root growth in relation to changes in the concentrations of dissolved gases and solutes in the soil solution. Plant Soil, 54, 77–94
Trought, M.C.T. and Drew, M.C. (1980b) The development of waterlogging damage in wheat seedlings (Triticum aestivum L.) II. Accumulation and redistribution of nutrients by the shoot. Plant Soil, 56, 187–99
Trought, M.C.T. and Drew, M.C. (1980c) The development of waterlogging damage in wheat plants in anaerobic solution culture. J. Exp. Bot., 31, 1573–85
Trought, M.C.T. and Drew, M.C. (1981) Alleviation of injury to young wheat plants in anaerobic solution cultures in relation to the supply of nitrate and other inorganic nutrients. J. Exp. Bot., 32, 509–22
Wardle, K. and Simpkins, I. (1979) Stomatal responses of Phaseolus vulgaris L. seedlings to potassium chloride in the nutrient solution. J. Exp. Bot., 30, 1195–200
Wiersum, L.K. (1979) A comparison of the behavior of some root systems under restricted aeration. Neth. J. Agric. Sci, 27, 92–8
Willhite, F.M., Grable, A.R. and Rouse, H.K. (1965) Interaction of nitrogen and soil moisture on the production and persistence of timothy in lysimeters. Agron. J., 57, 479–81
Wright, S.T.C. (1977) The relationship between leaf water potential (leaf) and the levels of abscisic acid and ethylene in excised wheat leaves. Planta, 134, 183–9
Wright, S.T.C. (1972) Physiological and biochemical responses to wilting and stress conditions. pp. 349–361. In A.R. Rees, K.E. Cockshull, D.W. Hand and R.D. Hurd (eds), Crop processes in controlled environments, Academic Press, London
Yeas, J.W. and Zobel, R.W. (1983) The response of maize radicle orientation to soil solution and soil atmosphere. Plant Soil, 70, 27–35
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Sojka, R.E., Stolzy, L.H. (1988). Mineral Nutrition of Oxygen-Stressed Crops and Its Relationship to Some Physiological Responses. In: The Ecology and Management of Wetlands. Springer, New York, NY. https://doi.org/10.1007/978-1-4684-8378-9_35
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