Microelectrode and Modelling Study of Oxygen Distribution in Roots

doi:10.1006/anbo.1994.1120

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Annals of Botany 74: 287-299, 1994
© 1994 Annals of Botany Company

Microelectrode and Modelling Study of Oxygen Distribution in Roots

W. Armstrong, M. E. Strange, S. Cringle and P. M. Beckett

Department of Applied Biology, University of Hull, HU6 7RX, UK; Lions' Eye Institute, Queen Elizabeth II Hospital, University of Western Australia and Department of Applied Mathematics, University of Hull, UK.

The use of polarographic microelectrodes to explore the radialdistribution of oxygen in maize roots aerated chiefly via theshoot is described. Also given is a brief description of a mathematicalmodel of root aeration which introduces two simultaneous oxygensources (the shoot and the rooting medium), and mimicks morerealistically than hitherto the diffusive characteristics ofthe non-porous epidermal/hypodermal shell.

In keeping with modelling predictions, steep radial diffusiongradients were a characteristic of the non-porous epidermal/hypodermalshell and stele, while shallow profiles generally characterisedthe cortex. Stelar anoxia, previously forecast by earlier mathematicalmodelling, was inducible by manipulating the oxygen concentrationsaround the shoot.

The stelar diffusion gradients always indicated an inward diffusionfrom the cortex. However, two-way gradients were sometimes evidentin the epidermal/hypodermal annulus, and were also found inthe sheathing extensions of the root cap. These indicated diffusioninto these annuli simultaneously from both the cortex and therooting medium. Elsewhere the gradients in the epidermis/hypodermalcylinder were either solely positive or negative depending uponthe oxygen concentrations within the root cortex and surroundingagar. Examples of two-way and one-way diffusion in the epidermal/hypodermalcylinder were created satisfactorily by the model.

Finally, the results indicate that with roots in stagnant anaerobicmedia, the bulk of the root cap proper is likely to be anoxic,and that some anoxia may be the norm within the basipetal extensionsof the cap which ensheath the root apex.Copyright 1994, 1999Academic Press

Anoxia, microelectrodes, modelling, oxygen, roots, root cap, Zea mays

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