Differential growth and shape formation in plant organs
| Autor: | Subra Suresh, K. Jimmy Hsia, David J. Quinn, Zilu Wang, Changjin Huang |
|---|---|
| Přispěvatelé: | School of Chemical and Biomedical Engineering, School of Mechanical and Aerospace Engineering |
| Jazyk: | angličtina |
| Rok vydání: | 2018 |
| Předmět: |
0301 basic medicine
Chemical engineering::Biochemical engineering [Engineering] growth Morphogenesis Soft robotics Plant Development morphogenesis Shape formation Flowers Growth Biology 3D structure Models Biological 03 medical and health sciences Orchidaceae Multidisciplinary soft matter fungi Robustness (evolution) food and beverages Biological Sciences 3d shapes Plant Leaves Cell expansion Applied Physical Sciences Biophysics and Computational Biology 030104 developmental biology Physical Sciences Petal Biological system Differential growth |
| Zdroj: | Proceedings of the National Academy of Sciences of the United States of America |
| Popis: | Significance Plant leaves and flower petals in nature exhibit a wide variety of complex 3D shapes. Formation of these shapes has largely been studied from genetic and biomolecular viewpoints, overlooking contributions from biophysical factors such as mechanical stress and deformation. By means of computational simulations and quantitative analyses of the growth strains in live plant organs, we develop fundamental mechanistic insights into how nature invokes mechanics in the evolution of four commonly found shapes in plant organs by differential growth. We also demonstrate how these common shapes can be synthetically reproduced in hydrogel using this mechanistic understanding. Our study provides a broad scientific framework for rationalizing plant organ morphogenesis, but also provides pathways for generating bioinspired 3D architectures in soft materials. Morphogenesis is a phenomenon by which a wide variety of functional organs are formed in biological systems. In plants, morphogenesis is primarily driven by differential growth of tissues. Much effort has been devoted to identifying the role of genetic and biomolecular pathways in regulating cell division and cell expansion and in influencing shape formation in plant organs. However, general principles dictating how differential growth controls the formation of complex 3D shapes in plant leaves and flower petals remain largely unknown. Through quantitative measurements on live plant organs and detailed finite-element simulations, we show how the morphology of a growing leaf is determined by both the maximum value and the spatial distribution of growth strain. With this understanding, we develop a broad scientific framework for a morphological phase diagram that is capable of rationalizing four configurations commonly found in plant organs: twisting, helical twisting, saddle bending, and edge waving. We demonstrate the robustness of these findings and analyses by recourse to synthetic reproduction of all four configurations using controlled polymerization of a hydrogel. Our study points to potential approaches to innovative geometrical design and actuation in such applications as building architecture, soft robotics and flexible electronics. |
| Databáze: | OpenAIRE |
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