Institut Jean-Pierre Bourgin, UMR1318 INRA-AgroParisTech Versailles, France ; UMR 547 PIAF, INRA Clermont-Ferrand Cedex 01, France ; UMR 547 PIAF, BP 10448, Clermont Université, Université Blaise Pascal Clermont-Ferrand, France ; Matière et Systèmes Complexes, Université Paris-Diderot Paris Cedex 13, France ; Department of Physics, School of Engineering and Applied Sciences, Harvard University Cambridge, MA, USA.
Matière et Systèmes Complexes, Université Paris-Diderot Paris Cedex 13, France.
Front Plant Sci. 2014 Apr 14;5:136. doi: 10.3389/fpls.2014.00136. eCollection 2014.
Gravitropism, the slow reorientation of plant growth in response to gravity, is a major determinant of the form and posture of land plants. Recently a universal model of shoot gravitropism, the AC model, was presented, in which the dynamics of the tropic movement is only determined by the conflicting controls of (1) graviception that tends to curve the plants toward the vertical, and (2) proprioception that tends to keep the stem straight. This model was found to be valid for many species and over two orders of magnitude of organ size. However, the motor of the movement, the elongation, was purposely neglected in the AC model. If growth effects are to be taken into account, it is necessary to consider the material derivative, i.e., the rate of change of curvature bound to expanding and convected organ elements. Here we show that it is possible to rewrite the material equation of curvature in a compact simplified form that directly expresses the curvature variation as a function of the median elongation and of the distribution of the differential growth. By using this extended model, called the ACĖ model, growth is found to have two main destabilizing effects on the tropic movement: (1) passive orientation drift, which occurs when a curved element elongates without differential growth, and (2) fixed curvature, when an element leaves the elongation zone and is no longer able to actively change its curvature. By comparing the AC and ACĖ models to experiments, these two effects are found to be negligible. Our results show that the simplified AC mode can be used to analyze gravitropism and posture control in actively elongating plant organs without significant information loss.
向重性,即植物生长对重力的缓慢重新定向,是陆地植物形态和姿势的主要决定因素。最近提出了一个普遍的茎向重性模型,即 AC 模型,该模型认为向重性运动的动力学仅由(1)向重性,即趋向于使植物垂直弯曲的控制,和(2)本体感受,即保持茎直的控制之间的冲突来决定。该模型被发现对许多物种和两个数量级的器官大小都有效。然而,在 AC 模型中,运动的马达,即伸长,被故意忽略了。如果要考虑生长效应,就有必要考虑物质导数,即扩展和对流器官元素的曲率变化率。在这里,我们展示了如何将曲率的物质方程重写为一个紧凑简化的形式,该形式直接将曲率变化表示为中值伸长和微分生长分布的函数。通过使用这个称为 ACĖ 模型的扩展模型,发现生长对向重性运动有两个主要的不稳定性效应:(1)当弯曲的元素在没有微分生长的情况下伸长时,会发生被动定向漂移,(2)当一个元素离开伸长区并且不再能够主动改变其曲率时,会发生固定曲率。通过将 AC 和 ACĖ 模型与实验进行比较,发现这两种效应可以忽略不计。我们的结果表明,简化的 AC 模型可以用于分析主动伸长植物器官的向重性和姿势控制,而不会有明显的信息丢失。
