The Bulk Elastic Modulus and the Reversible Properties of Cell Walls in Developing Quercus Leaves

doi:10.1093/pcp/pcj042

Plant and Cell Physiology Advance Access originally published online on March 29, 2006
Plant and Cell Physiology 2006 47(6):715-725; doi:10.1093/pcp/pcj042

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The Bulk Elastic Modulus and the Reversible Properties of Cell Walls in Developing Quercus Leaves

Takami Saito¹^,*, Kouichi Soga², Takayuki Hoson² and Ichiro Terashima¹

¹ Department of Biology, Graduate School of Science, Osaka University, 1-1 Machikaneyama-cho, Toyonaka, Osaka, 560-0043 Japan
² Department of Biological Sciences, Graduate School of Science, Osaka City University, Sumiyoshi-ku, Osaka, 558-8585 Japan

^* Corresponding author: E-mail, takami{at}bio.sci.osaka-u.ac.jp; Fax, +81-6-6850-5808.

We examined the relationship between the bulk elastic modulus( ${varepsilon}$ ) of an individual leaf obtained by the pressure–volume(P–V) technique and the mechanical properties of cellwalls in the leaf. The plants used were Quercus glauca and Q.serrata, an evergreen and a deciduous broad-leaved tree species,respectively. We compared ${varepsilon}$ and Young’s modulus of leafspecimens determined by the stretch technique at various stagesof their leaf development. The results showed that ${varepsilon}$ increasedfrom approximately 5 to 20 MPa during leaf development,although other potential determinants of ${varepsilon}$ such as the apoplasticwater content in the leaf and the diameter of a palisade tissuecells remained almost constant. ${varepsilon}$ in these two species was similarat every developmental stages, although the apparent mechanicalstrength of the leaf lamina and thickness of mesophyll cellwalls were greater in Q. glauca. There were significant linearrelationships between Young’s modulus and ${varepsilon}$ (P < 0.01;R ² = 0.78 and 0.84 in Q. glauca and Q. serrata, respectively)with small y-intercepts. From these results, we conclude that ${varepsilon}$ is closely related to the reversible properties of the cellwalls. From the estimation of ${varepsilon}$ based on a physical model, wesuggest that the effective thickness of cell walls responsiblefor ${varepsilon}$ is smaller than the observed wall thickness.

(Received March 2, 2006; Accepted March 20, 2006)
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