Strain rate controls alignment in growing bacterial monolayers

IF 2.9 3区 化学 Q3 CHEMISTRY, PHYSICAL
Soft Matter Pub Date : 2024-10-15 DOI:10.1039/D4SM00625A
Blake Langeslay and Gabriel Juarez
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Abstract

Growing monolayers of rod-shaped bacteria exhibit local alignment similarly to extensile active nematics. When confined in a channel or growing inward from a ring, the local nematic order of these monolayers changes to a global ordering with cells throughout the monolayer orienting in the same direction. The mechanism behind this phenomenon is so far unclear, as previously proposed mechanisms fail to predict the correct alignment direction in one or more confinement geometries. We present a strain-based model relating net deformation of the growing monolayer to the cell-level deformation resulting from single-cell growth and rotation, producing predictions of cell orientation behavior based on the velocity field in the monolayer. This model correctly predicts the direction of preferential alignment in channel-confined, inward growing, and unconfined colonies. The model also quantitatively predicts orientational order when the velocity field has no net negative strain rate in any direction. We further test our model in simulations of expanding colonies confined to spherical surfaces. Our model and simulations agree that cells away from the origin cell orient radially relative to the colony's center. Additionally, our model's quantitative prediction of the orientational order agrees with the simulation results in the top half of the sphere but fails in the lower half where there is a net negative strain rate. The success of our model bridges the gap between previous works on cell alignment in disparate confinement geometries and provides insight into the underlying physical effects responsible for large-scale alignment.

Abstract Image

菌株速率控制着生长细菌单层的排列。
生长中的杆状细菌单层表现出与伸展型活性向列菌类似的局部排列。当被限制在一个通道中或从一个环向内生长时,这些单层的局部向列秩序会转变为全局秩序,整个单层的细胞都朝同一方向排列。这种现象背后的机理迄今尚不清楚,因为之前提出的机理无法预测一种或多种约束几何形状下的正确排列方向。我们提出了一个基于应变的模型,该模型将生长单层的净变形与单细胞生长和旋转产生的细胞级变形联系起来,根据单层中的速度场预测细胞的定向行为。该模型能正确预测通道封闭、向内生长和非封闭菌落的优先排列方向。当速度场在任何方向上都没有净负应变率时,该模型还能定量预测定向顺序。我们还通过模拟限制在球形表面的不断扩大的菌落,进一步检验了我们的模型。我们的模型和模拟结果一致表明,远离起源细胞的细胞相对于菌落中心呈放射状定向。此外,我们的模型对定向顺序的定量预测与球体上半部分的模拟结果一致,但在存在净负应变率的下半部分却失效了。我们模型的成功弥补了以往关于不同封闭几何结构中细胞排列的研究之间的差距,并让我们深入了解了导致大规模排列的潜在物理效应。
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
Soft Matter
Soft Matter 工程技术-材料科学:综合
CiteScore
6.00
自引率
5.90%
发文量
891
审稿时长
1.9 months
期刊介绍: Where physics meets chemistry meets biology for fundamental soft matter research.
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