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Polarographic oxygen electrodes and their use in plant aeration studies

Published online by Cambridge University Press:  05 December 2011

W. Armstrong
W. Armstrong
Affiliation:
Department of Applied Biology, University of Hull, Hull HU6 7RX, UK
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Synopsis

The electrolytic reduction of oxygen which occurs at a wetted ‘unattackable’ cathodic electrode of platinum or gold when polarised in conjunction with a Ag/AgCl anode, forms the basis of most polarographic oxygen measurements in plant biological work.

Various types of polarographic electrode and their uses are reviewed. These include cylindrical sleeving electrodes for quantifying localised oxygen fluxes from intact roots, ‘bare’, membrane-coated, and Clark-type microelectrodes suitable for measuring concentrations and profiles both inside roots and in the rhizosphere, and macro-Clark electrodes most frequently used in respiratory studies.

Some details concerning equipment and electrode construction are given and some pitfalls in electrode application are discussed.

Type
Research Article
Information
Proceedings of the Royal Society of Edinburgh, Section B: Biological Sciences , Volume 102: Oxygen and Environmental Stress in Plants , 1994 , pp. 511 - 527
Copyright
Copyright © Royal Society of Edinburgh 1994

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References

Armstrong, J. & Armstrong, W. 1989. Light-enhanced convective throughfiow increases oxygenation in rhizomes and rhizosphere of Phragmites australis (Cav.) Trin. ex Steud. New Phytologist 114, 121–8.CrossRefGoogle Scholar
Armstrong, W. 1964. Oxygen diffusion from the roots of some British bog plants. Nature 204, 801–2.CrossRefGoogle Scholar
Armstrong, W. 1967a. The use of polarography in the assay of oxygen diffusing from roots in anaerobic media. Physiologia Plantarum 20, 540–53.CrossRefGoogle Scholar
Armstrong, W. 1967b. The relationship between oxidation-reduction potentials and oxygen-diffusion levels in some waterlogged organic soils. Journal of Soil Science 18, 2734.CrossRefGoogle Scholar
Armstrong, W. 1979. Aeration in Higher Plants. In Woolhouse, H. W. W. (Ed.) Advances in botanical research vol. 7, pp. 225332. London: Academic Press.Google Scholar
Armstrong, W. 1988. Aeration in roots. In Cherry, T. (Ed.) Environmental stress physiology, NATO ASI series, vol. G19, pp. 197206, Berlin: Springer-Verlag.Google Scholar
Armstrong, W. & Gaynard, T. J. 1976. The critical oxygen pressure for root respiration in intact plants. Physiologia Plantarum 37, 200–6.CrossRefGoogle ScholarPubMed
Armstrong, W. & Webb, T. 1985. A critical oxygen pressure for root extension in rice. Journal of Experimental Botany 36, 1573–82.CrossRefGoogle Scholar
Armstrong, W. & Wright, E. J. 1975. The theoretical basis for the manipulation of flux data obtained by the cylindrical platinum electrode technique. Physiologia Plantarum 35, 21–6.CrossRefGoogle Scholar
Armstrong, W. & Wright, E. J. 1976. A polarographic assembly for the large scale sampling of soil oxygen in the field. Journal of Applied Ecology 13, 849–56.CrossRefGoogle Scholar
Armstrong, W., Booth, T. C., Priestley, P. & Read, D. J. 1976. The relationship between soil aeration, stability and growth of Sitka spruce, (Picea sitchensis Borg. Carr) on upland peaty-gleys. Journal of Applied Ecology 13, 585–91.CrossRefGoogle Scholar
Armstrong, W., Healy, X., & Lythe, L. 1983. Oxygen diffusion in pea. II The oxygen status of the primary root as affected by growth, the production of laterals and radial oxygen loss. New Phytologist 94, 549–59.CrossRefGoogle Scholar
Armstrong, W., Beckett, P. M., Justin, S. H. F. W. & Lythe, S. 1990. Modelling and other aspects of root aeration. In Jackson, M. B., Davies, D. D. & Lambers, H. (Eds.) Plant life under oxygen stress, pp. 267–82. The Hague: SPB Academic Publishing.Google Scholar
Armstrong, W., Cringle, S., Brown, M. & Greenway, H. 1993. A microelectrode study of oxygen distribution in the roots of intact maize seedlings. In Jackson, M. B. & Black, C. R. (Eds) Interacting stresses on plants in a changing climate. NATO ASI Series I; Global Change, Vol. 16, pp. 287304. Berlin: Springer-Verlag.CrossRefGoogle Scholar
Baumgärtl, H. & Lübbers, D. W. 1983. Microcoaxial needle sensor for polarographic measurement of local oxygen pressure in the cellular range of living tissue. Its Construction and properties. In Gnaiger, E. & Forster, H. (Eds) Polarographic oxygen sensors, pp. 3565. Berlin: Springer-Verlag.Google Scholar
Beckett, P. M., Armstrong, W., Justin, S. H. F. W. & Armstrong, J. 1988. On the relative importance of convective and diffusive gas-flows in plant aeration. New Phytologist 110, 463–68.CrossRefGoogle Scholar
Bedford, B. L., Bouldin, D. R. & Beliveau, B. D. 1991. Net oxygen and carbon dioxide balances in solutions bathing roots of wetland plants. Journal of Ecology 79, 943–59.CrossRefGoogle Scholar
Blackwell, P. S. 1983. Measurements of aeration in waterlogged soils: some improvements of techniques and their application to experiments using lysimeters. Journal of Soil Science 34, 271–85.CrossRefGoogle Scholar
Bowling, D. J. F. 1973. Measurement of a gradient of oxygen partial pressure across the intact root. Planta 111, 323–28.CrossRefGoogle ScholarPubMed
Chance, B. & Williams, G. R. 1955. Respiratory enzymes in oxidative phosphorylation. I. Kinetics of oxygen utilisation. Journal of Biological Chemistry 217, 383–93.CrossRefGoogle Scholar
Davies, P. W. 1962. The oxygen cathode. In Physical Techniques in biological research, Vol IV: special methods, pp. 137179. New York: Academic Press.Google Scholar
Davies, P. W. & Brink, F. Jr 1942. Microelectrodes for measuring local oxygen tensions in animal tissue. Review of Scientific Instruments 13, 524–33.CrossRefGoogle Scholar
Gaynard, T. J. & Armstrong, W. 1987. Some aspects of internal plant aeration in amphibious habitats. In Crawford, R. M. M. (Ed) Amphibious and intertidal plants. British Ecological Society Special Symposium 5. pp. 303320. Oxford: Blackwell Scientific Publishers.Google Scholar
Glud, R. N., Ramsing, N. B. & Revsbech, N. P. 1992. Photosynthesis and photosynthesis-coupled respiration in natural biofilms quantified with oxygen microsensors. Journal of Phycology 28, 5160.CrossRefGoogle Scholar
Gnaiger, E. & Forster, H. 1983. Polarographic oxygen sensors. Berlin: Springer-Verlag.CrossRefGoogle Scholar
Gries, C., Kappen, L. & Losch, R. 1990. Mechanism of flood tolerance in reed. Phragmites australis (Cav.) Trin. ex Steudel. New Phytologist 114, 589–93.CrossRefGoogle Scholar
Højberg, O. & Sørensen, . 1993. Microgradients of microbial oxygen consumption in a barley rhizosphere model system. Applied and Environmental Microbiology 59, 431–7.CrossRefGoogle Scholar
Kolthoff, I. M. & Lingane, J. J. 1952. Polarography. New York: Interscience Publishers.Google Scholar
Kessler, M. & Lubbers, D. W. et al (Eds). 1973. Oxygen supply: theoretical and practical aspects of oxygen supply and microcirculation of tissue. Workshop Proceedings, Max-Planck Institute, Dortmund. Baltimore, USA: University Park Press.Google Scholar
Kludze, H. K., DeLaune, R. D. & Patrick, W. H. Jr 1993. Aerenchyma formation and methane and oxygen exchange in rice. Soil Science Society of America Journal 57, 386–91.CrossRefGoogle Scholar
Laan, P., Smolders, A., Blom, C. W. P. M. & Armstrong, W. 1989. The relative roles of internal aeration, radial oxygen losses, iron exclusion and nutrient balance in flood-tolerance in Rumex species. Ada Botanica Neerlandica 38, 131–45.CrossRefGoogle Scholar
Laan, P., Tosserams, M., Blom, C. W. P. M. & Armstrong, W. 1990. Internal oxygen transport in Rumex species and its significance for respiration under hypoxic conditions. Plant & Soil 122, 3946.CrossRefGoogle Scholar
Lemon, E. R. & Erickson, A. E. 1952. The measurement of oxygen diffusion in the soil with a platinum electrode. Proceedings of the Soil Science Society of America 16, 160–63.CrossRefGoogle Scholar
Lemon, E. R. & Erickson, A. E. 1955. Principle of the platinum microelectrode as a method of characterizing soil aeration. Soil Science 79, 383–92.CrossRefGoogle Scholar
Mclntyre, D. S. 1970. The platinum microelectrode method for soil aeration measurement. Advances in Agronomy 22, 235283.CrossRefGoogle Scholar
Revsbech, N. P. 1989. An oxygen sensor with a guard cathode. Limnology & Oceanography 34, 474–78.CrossRefGoogle Scholar
Revsbech, N. P. & Jorgensen, B. B. 1986. Microelectrodes: their use in microbial ecology. Advances in Microbial Ecology 9, 293352.CrossRefGoogle Scholar
Revsbech, N. P. & Ward, D. M. 1983. Oxygen microelectrode that is insensitive to medium chemical composition: use in an acid microbial mat dominated by Cyanidium caldarium. Applied Environmental Microbiology 45, 755–99.CrossRefGoogle Scholar
Saglio, P. H., Rancillac, M., Bruzan, F. & Pradet, A. 1984. Critical oxygen pressure for growth and respiration of excised and intact roots. Plant Physiology 76, 151–54.CrossRefGoogle ScholarPubMed
Sorrell, B. K. & Armstrong, W. 1994. On the difficulties of measuring oxygen release by root systems of wetland plants. Journal of Ecology 82, 177–84.CrossRefGoogle Scholar
Sorrell, B. K., Brix, H. & Orr, P. T. 1993. Oxygen exchange by entire root systems of Cyperus involucratus and Eleocharis sphacelata. Journal of Aquatic Plant Management 31, 2428.Google Scholar
Thomson, C. J., Armstrong, W., Waters, I. & Greenway, H. 1990. Aerenchyma formation and associated oxygen movement in seminal and nodal roots of wheat. Plant, Cell and Environment 13, 395403.CrossRefGoogle Scholar
Tjepkema, J. D. & Yocum, C. S. 1974. Measurement of oxygen partial pressure within soybean nodules by oxygen microelectrodes. Planta 119, 351–60.CrossRefGoogle ScholarPubMed
Waters, I., Armstrong, W., Thomson, C. J., Setter, T. L., Adkins, S., Gibbs, J. & Greenway, H. 1989. Diurnal changes in radial oxygen loss and ethanol metabolism in roots of submerged and non-submerged rice seedlings. New Phytologist 113, 439–51.CrossRefGoogle Scholar
Whalen, W. J., Riley, J. & Nair, P. 1967. A microelectrode for measuring intracellular pO2. Journal of Applied Physiology 23, 798801.CrossRefGoogle ScholarPubMed
Witty, J. F., Skot, L. & Revsbech, N. P. 1987. Direct evidence for changes in the resistance of legume nodules to oxygen diffusion. Journal of Experimental Botany 38, 1129–40.CrossRefGoogle Scholar