Roles of cellulose and xyloglucan in determining the mechanical properties of primary plant cell walls

The primary cell walls of growing and fleshy plant tissue mostly share a common set of molecular components, cellulose, xyloglucan (XyG), and pectin, that are required for both inherent strength and the ability to respond to cell expansion during growth. To probe molecular mechanisms underlying mate...

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Bibliographic Details
Published in:Plant physiology (Bethesda) 1999-10, Vol.121 (2), p.657-663
Main Authors: Whitney, S.E.C, Gothard, M.G.E, Mitchell, J.T, Gidley, M.J
Format: Article
Language:English
Subjects:
Biochemistry and Macromolecular Structure
Biological and medical sciences
Cell growth
cell ultrastructure
Cell walls
Cellulose
Cirques
Deformation
Fundamental and applied biological sciences. Psychology
growth
Mechanical properties
pectins
Physical agents
Plant cells
Plant physiology and development
Plants
rheological properties
Rheology
shear strength
Solanum lycopersicum var. lycopersicum
Solar fibrils
Stiffness
strength
Vegetative apparatus, growth and morphogenesis. Senescence
xyloglucans
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Summary:The primary cell walls of growing and fleshy plant tissue mostly share a common set of molecular components, cellulose, xyloglucan (XyG), and pectin, that are required for both inherent strength and the ability to respond to cell expansion during growth. To probe molecular mechanisms underlying material properties, cell walls and analog composites from Acetobacter xylinus have been measured under small deformation and uniaxial extension conditions as a function of molecular composition. Small deformation oscillatory rheology shows a common frequency response for homogenized native cell walls, their sequential extraction residues, and bacterial cellulose alone. This behavior is characteristic of structuring via entanglement of cellulosic rods and is more important than cross-linking with XyG in determining shear moduli. Compared with cellulose alone, composites with XyG have lower stiffness and greater extensibility in uniaxial tension, despite being highly cross-linked at the molecular level. It is proposed that this is due to domains of cross-linked cellulose behaving as mechanical elements, whereas cellulose alone behaves as a mat of individual fibrils. The implication from this work is that XyG/cellulose networks provide a balance of extensibility and strength required byprimary cell walls, which is not achievable with cellulose alone.
ISSN:0032-0889
1532-2548
DOI:10.1104/pp.121.2.657