Hydromechanical field theory of plant morphogenesis

arXiv - PHYS - Biological Physics Pub Date : 2024-09-04 DOI:arxiv-2409.02775

Hadrien Oliveri, Ibrahim Cheddadi

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Abstract

The growth of plants is a hydromechanical phenomenon in which cells enlarge by absorbing water, while their walls expand and remodel under turgor-induced tension. In multicellular tissues, where cells are mechanically interconnected, morphogenesis results from the combined effect of local cell growths, which reflects the action of heterogeneous mechanical, physical, and chemical fields, each exerting varying degrees of nonlocal influence within the tissue. To describe this process, we propose a physical field theory of plant growth. This theory treats the tissue as a poromorphoelastic body, namely a growing poroelastic medium, where growth arises from pressure-induced deformations and osmotically-driven imbibition of the tissue. From this perspective, growing regions correspond to hydraulic sinks, leading to the possibility of complex non-local regulations, such as water competition and growth-induced water potential gradients. More in general, this work aims to establish foundations for a mechanistic, mechanical field theory of morphogenesis in plants, where growth arises from the interplay of multiple physical fields, and where biochemical regulations are integrated through specific physical parameters.

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植物形态发生的水力机械场理论

植物的生长是一种水力学现象，细胞通过吸水而增大，同时细胞壁在张力作用下扩张和重塑。在多细胞组织中，细胞是机械地相互连接在一起的，形态发生是局部细胞生长的综合效应的结果，它反映了异质机械场、物理场和化学场的作用，每种场在组织内都施加了不同程度的非局部影响。为了描述这一过程，我们提出了植物生长的物理场理论。该理论将组织视为多孔弹性体，即生长的多孔弹性介质，其生长源于压力引起的变形和组织的运动驱动浸润。从这个角度看，生长区域相当于水力汇，从而可能产生复杂的非局部调节，如水竞争和生长诱导的水势梯度。总的来说，这项工作旨在为植物形态发生的机械力学场理论奠定基础，在这一理论中，生长源于多个物理场的相互作用，而生化调控则通过特定的物理参数整合在一起。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Biological Physics

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