Root responses to soil physical conditions; growth dynamics from field to cell

doi:10.1093/jxb/erj003

JXB Advance Access published online on November 29, 2005
Journal of Experimental Botany, doi:10.1093/jxb/erj003

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© The Author [2005]. Published by Oxford University Press [on behalf of the Society for Experimental Biology]. All rights reserved. For Permissions, please e-mail: journals.permissions@oxfordjournals.org
Received June 7, 2005
Accepted September 5, 2005

PHENOTYPIC PLASTICITY AND THE CHANGING ENVIRONMENT SPECIAL ISSUE ARTICLE

Root responses to soil physical conditions; growth dynamics from field to cell

A. Glyn Bengough ¹ ^*, M. Fraser Bransby ², Joachim Hans ¹, Stephen J. McKenna ³, Tim J. Roberts ³, and Tracy A. Valentine ¹

¹ Scottish Crop Research Institute, Dundee DD2 5DA, Scotland, UK
² Division of Civil Engineering, University of Dundee, Dundee, Scotland, UK
³ Division of Applied Computing, University of Dundee, Dundee, Scotland, UK

^* To whom correspondence should be addressed.
A. Glyn Bengough, E-mail: Glyn.Bengough{at}scri.ac.uk

Abstract

Root growth in the field is often slowed by a combination ofsoil physical stresses, including mechanical impedance, waterstress, and oxygen deficiency. The stresses operating may varycontinually, depending on the location of the root in the soilprofile, the prevailing soil water conditions, and the degreeto which the soil has been compacted. The dynamics of root growthresponses are considered in this paper, together with the cellularresponses that underlie them. Certain root responses facilitateelongation in hard soil, for example, increased sloughing ofborder cells and exudation from the root cap decreases friction;and thickening of the root relieves stress in front of the rootapex and decreases buckling. Whole root systems may also growpreferentially in loose versus dense soil, but this responsedepends on genotype and the spatial arrangement of loose andcompact soil with respect to the main root axes. Decreased rootelongation is often accompanied by a decrease in both cell fluxand axial cell extension, and recent computer-based models areincreasing our understanding of these processes. In the caseof mechanical impedance, large changes in cell shape occur,giving rise to shorter fatter cells. There is still uncertaintyabout many aspects of this response, including the changes incell walls that control axial versus radial extension, and thedegree to which the epidermis, cortex, and stele control rootelongation. Optical flow techniques enable tracking of rootsurfaces with time to yield estimates of two-dimensional velocityfields. It is demonstrated that these techniques can be appliedsuccessfully to time-lapse sequences of confocal microscopeimages of living roots, in order to determine velocity fieldsand strain rates of groups of cells. In combination with newmolecular approaches this provides a promising way of investigatingand modelling the mechanisms controlling growth perturbationsin response to environmental stresses.

Keywords: Cell expansion; cell walls; mechanical impedance; root growth; soil compaction; water stress.

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