Non-linear stress-softening of the bacterial cell wall confers cell shape homeostasis

Paola Bardetti, Felix Barber, Enrique R Rojas
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Abstract

The bacillus - or rod - is a pervasive cellular morphology among bacteria. Rod-shaped cells elongate without widening by reinforcing their cell wall anisotropically to prevent turgor pressure from inflating cell width. Here, we demonstrate that a constrictive force is also essential for avoiding pressure-driven widening in Gram-positive bacteria. Specifically, super-resolution measurements of the nonlinear mechanical properties of the cell wall revealed that across a range of turgor pressure cell elongation directly causes width constriction, similar to a "finger trap" toy. As predicted by theory, this property depends on cell-wall anisotropy and is precisely correlated with the cell's ability to maintain a rod shape. Furthermore, the acute non-linearities in the dependence between cell length and width deformation result in a negative-feedback mechanism that confers cell-width homeostasis. That is, the Gram-positive cell wall is a "smart material" whose exotic mechanical properties are exquisitely adapted to execute cellular morphogenesis.
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细菌细胞壁的非线性应力软化使细胞形状保持稳定
杆菌(或称杆状体)是细菌中普遍存在的一种细胞形态。杆状细胞通过各向异性地加固细胞壁来防止细胞宽度受压力膨胀,从而拉长而不变宽。在这里,我们证明了在革兰氏阳性细菌中,收缩力对于避免压力驱动的细胞变宽也是至关重要的。具体来说,对细胞壁非线性机械特性的超分辨率测量显示,在一定范围内,细胞伸长会直接导致宽度收缩,类似于 "手指陷阱 "玩具。正如理论预测的那样,这种特性取决于细胞壁的各向异性,并与细胞保持杆状的能力精确相关。此外,细胞长度与宽度变形之间存在着尖锐的非线性依赖关系,从而形成了一种负反馈机制,使细胞宽度保持稳定。也就是说,革兰氏阳性细胞壁是一种 "智能材料",其奇特的机械特性能够很好地适应细胞的形态发生。
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