Atomic force microscopy of cotton fiber cell wall surfaces in air and water: quantitative and qualitative aspects

Atomic force microscopy of cotton fiber cell wall surfaces in air and water: quantitative and qualitative aspects

Cotton (Gossypium hirsutum cv. MD51) fiber cell walls were analyzed with an atomic force microscope to determine the effect of chemical treatments on cell wall organization and topography. Analysis of fibers in either air or water and without any staining or coating produced high-resolution images o...

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Bibliographic Details
Published in:Planta Vol. 202; no. 4; pp. 435 - 442
Main Authors: Pesacreta, Thomas C., Carlson, Lisa C., Triplett, Barbara A.
Format: Journal Article
Language:English
Published: Berlin Springer-Verlag 17-07-1997
Springer
Subjects:
Atomic force microscopy
Biological and medical sciences
Cell physiology
Cell walls
Cells, cell elements: structure and function
Cotton
Cotton fibers
Fractals
Fundamental and applied biological sciences. Psychology
Imaging
Plant cuticle
Plant physiology and development
Raw data
Surface areas
Surface roughness
Malvaceae
Atomic force microscopy
Air environment
Microfibril
Plant fiber
Anatomy
Orientation
Fiber crop
Cell surface
Cell wall
Aquatic environment
Chemical treatment
Dicotyledones
Angiospermae
Spermatophyta
Gossypium hirsutum
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Summary:Cotton (Gossypium hirsutum cv. MD51) fiber cell walls were analyzed with an atomic force microscope to determine the effect of chemical treatments on cell wall organization and topography. Analysis of fibers in either air or water and without any staining or coating produced high-resolution images of cell wall microstructure which could be used for detailed quantitative analysis. Treatment of fibers with 1% H2O2 had little effect on surface morphology. Alkali removed much of the cuticle, some primary wall components, and revealed mostly thin-diameter microfibrils. Acidic Updegraff reagent fragmented the fibers, removed much of the cuticle, and revealed mostly thick microfibrils. The surface roughness of fibers treated sequentially with alkali and acid was quantitatively distinguishable from all other fiber types based on the standard deviation of the height data, amplification of surface area, and integration of the scan line data. Analysis of the fractal dimension enabled untreated and peroxide-treated fibers to be clearly distinguished from the other fiber types. Segmentation of the fractal data revealed specific portions of the fractal dimension which were especially useful for defining the size of structures that differentiated fiber types. Areas containing microfibrils could be quantitatively differentiated from non-microfibrillar areas. In water, some alkali-treated fibers had microfibrils that were relatively small in diameter while others appeared to consist of crystalline arrays of smaller fibrils.
ISSN:0032-0935
1432-2048
DOI:10.1007/s004250050147