A theoretical approach to the relationship between wettability and surface microstructures of epidermal cells and structured cuticles of flower petals

A theoretical approach to the relationship between wettability and surface microstructures of epidermal cells and structured cuticles of flower petals

The epidermal surface of a flower petal is composed of convex cells covered with a structured cuticle, and the roughness of the surface is related to the wettability of the petal. If the surface remains wet for an excessive amount of time the attractiveness of the petal to floral visitors may be imp...

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Bibliographic Details
Published in:Annals of botany Vol. 115; no. 6; pp. 923 - 937
Main Authors: Taneda, Haruhiko, Watanabe-Taneda, Ayako, Chhetry, Rita, Ikeda, Hiroshi
Format: Journal Article
Language:English
Published: England Oxford University Press 01-05-2015
Subjects:
Ecosystem
Flowers - cytology
Flowers - ultrastructure
Models, Theoretical
Original
ORIGINAL ARTICLES
Plant Epidermis - cytology
Plant Epidermis - ultrastructure
Thermodynamics
Water
Wettability
Nepal
petal effect
Cassie–Baxter wetting
petal wettability
water run-off
thermodynamic model
Epidermis
alpine plant
cuticle structure
Wenzel wetting
lotus effect
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Summary:The epidermal surface of a flower petal is composed of convex cells covered with a structured cuticle, and the roughness of the surface is related to the wettability of the petal. If the surface remains wet for an excessive amount of time the attractiveness of the petal to floral visitors may be impaired, and adhesion of pathogens may be promoted. However, it remains unclear how the epidermal cells and structured cuticle contribute to surface wettability of a petal. By considering the additive effects of the epidermal cells and structured cuticle on petal wettability, a thermodynamic model was developed to predict the wetting mode and contact angle of a water droplet at a minimum free energy. Quantitative relationships between petal wettability and the geometries of the epidermal cells and the structured cuticle were then estimated. Measurements of contact angles and anatomical traits of petals were made on seven herbaceous species commonly found in alpine habitats in eastern Nepal, and the measured wettability values were compared with those predicted by the model using the measured geometries of the epidermal cells and structured cuticles. The model indicated that surface wettability depends on the height and interval between cuticular steps, and on a height-to-width ratio for epidermal cells if a thick hydrophobic cuticle layer covers the surface. For a petal epidermis consisting of lenticular cells, a repellent surface results when the cuticular step height is greater than 0·85 µm and the height-to-width ratio of the epidermal cells is greater than 0·3. For an epidermis consisting of papillate cells, a height-to-width ratio of greater than 1·1 produces a repellent surface. In contrast, if the surface is covered with a thin cuticle layer, the petal is highly wettable (hydrophilic) irrespective of the roughness of the surface. These predictions were supported by the measurements of petal wettability made on flowers of alpine species. The results indicate that surface roughness caused by epidermal cells and a structured cuticle produces a wide range of petal wettability, and that this can be successfully modelled using a thermodynamic approach.
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ISSN:0305-7364
1095-8290
DOI:10.1093/aob/mcv024