A conserved cellular mechanism for cotton fiber diameter and length control

IF 2.6 Q1 AGRONOMY

in silico Plants Pub Date : 2022-04-14 DOI:10.1093/insilicoplants/diac004

M. Yanagisawa, S. Keynia, S. Belteton, J. A. Turner, D. Szymanski

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引用次数: 4

Abstract

Highly polarized cotton fiber cells that develop from the seed coat surface are the foundation of a multi-billion-dollar international textile industry. The unicellular trichoblast emerges as a hemispherical bulge that is efficiently converted to a narrower and elongated shape that extends for about two weeks before transitioning into a cellulose-generating machine. The polarized elongation phase employs an evolutionarily conserved microtubule-cellulose synthase control module that patterns the cell wall and enables highly anisotropic diffuse growth. As the multi-scale interactions and feedback controls among cytoskeletal systems, morphologically potent cell wall properties, and a changing cell geometry are uncovered, opportunities emerge to engineer architectural traits. However, in cotton such efforts are hampered by insufficient knowledge about the underlying morphogenetic control mechanisms. For example, fiber diameter is an important trait that is determined during the earliest stages of development, but the basic growth mode and the mechanisms by which cytoskeletal and cell wall systems mediate fiber tapering are not known. This paper combines multiparametric and multiscale fiber phenotyping and finite element computational modeling of a growing cell to discover an evolutionarily conserved tapering mechanism. The actin network interconverts between two distinct longitudinal organizations that broadly distributes organelles and likely enables matrix secretion patterns that maintain cell wall thickness during growth. Based on plausible finite element models and quantitative analyses of the microtubule cytoskeleton, tapering and anisotropic growth is programmed by a constricting apical microtubule depletion zone and highly aligned microtubules along the fiber shaft. The finite element model points to a central role for tensile forces in the cell wall to dictate the densities and orientations of morphologically potent microtubules.

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棉纤维直径和长度控制的保守细胞机制

从种皮表面发育出来的高度极化的棉纤维细胞是数十亿美元的国际纺织工业的基础。单细胞毛原细胞以半球形凸起的形式出现，有效地转化为更窄和细长的形状，延伸约两周，然后转变为纤维素产生机器。极化延伸期采用进化上保守的微管-纤维素合成酶控制模块，该模块在细胞壁上形成图案，并实现高度各向异性的扩散生长。随着细胞骨架系统之间的多尺度相互作用和反馈控制，形态学上有效的细胞壁特性和不断变化的细胞几何结构被发现，出现了设计建筑特征的机会。然而，在棉花中，由于对潜在的形态发生控制机制了解不足，这种努力受到阻碍。例如，纤维直径是发育早期决定的重要性状，但细胞骨架和细胞壁系统调节纤维变细的基本生长方式和机制尚不清楚。本文将多参数和多尺度纤维表型分析与生长细胞的有限元计算建模相结合，以发现进化保守的变细机制。肌动蛋白网络在两个不同的纵向组织之间相互转换，广泛分布细胞器，并可能使基质分泌模式在生长过程中维持细胞壁厚度。基于合理的有限元模型和微管细胞骨架的定量分析，逐渐变细和各向异性生长是由一个收缩的顶端微管枯竭区和沿纤维轴高度排列的微管控制的。有限元模型指出细胞壁上的张力在决定微管的密度和方向方面起着核心作用。

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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来源期刊

in silico Plants Agricultural and Biological Sciences-Agronomy and Crop Science

CiteScore

4.70

自引率

9.70%

发文量

审稿时长

10 weeks