Abstract
The mechanical properties of cell walls play a vital role in plant development. Atomic-force microscopy (AFM) is widely used for characterization of these properties. However, only surface or isolated plant cells have been used for such investigations, at least as non-embedded samples. Theories that claim a restrictive role of a particular tissue in plant growth cannot be confirmed without direct measurement of the mechanical properties of internal tissue cell walls. Here we report an approach of assessing the nanomechanical properties of primary cell walls in the inner tissues of growing plant organs. The procedure does not include fixation, resin-embedding or drying of plant material. Vibratome-derived longitudinal and transverse sections of maize root were investigated by AFM in a liquid cell to track the changes of cell wall stiffness and elasticity accompanying elongation growth. Apparent Young’s modulus values and stiffness of stele periclinal cell walls in the elongation zone of maize root were lower than in the meristem, i.e., cell walls became more elastic and less resistant to an applied force during their elongation. The trend was confirmed using either a sharp or spherical probe. The availability of such a method may promote our understanding of individual tissue roles in the plant growth processes.
Highlights
IntroductionAll living organisms that have cell walls (plants, fungi, and bacteria) must deal with the need to find a balance between wall strength and extensibility, which is necessary for growth [1]
All living organisms that have cell walls must deal with the need to find a balance between wall strength and extensibility, which is necessary for growth [1]
A properly oriented piece of plant material can be sectioned by a vibratome to produce a surface appropriate for atomic force microscopy (AFM), formed by cut cell walls of inner tissues
Summary
All living organisms that have cell walls (plants, fungi, and bacteria) must deal with the need to find a balance between wall strength and extensibility, which is necessary for growth [1]. These changes are expressed at different extents for cell walls of different origin probably because of their porosity and lamellar structure [17] These parameters, in turn, are known to vary among cell types and change during cell development [2], calling into doubt the reliability of any comparative studies using resin-embedded material. The embedding procedure includes fixation and dehydration steps Both were shown to lead to substantial changes in the architecture and properties of living cells [18,19,20]. Dehydration accompanies cryosectioning, making this approach inapplicable to study nanomechanics of plant internal tissues, at least for cells with primary cell walls. We present a method for AFM-based characterization of plant cell wall mechanical properties for internal tissues of plant organs using non-fixed and never-dried material of maize roots. Investigations were conducted on both longitudinal and transverse sections to examine the anisotropy of the mechanical properties
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