规模依赖性相互作用使肌动蛋白-波形蛋白复合材料能够产生微流变应力响应。

IF 2.9 3区 化学 Q3 CHEMISTRY, PHYSICAL Soft Matter Pub Date : 2024-10-30 DOI:10.1039/D4SM00988F
Julie Pinchiaroli, Renita Saldanha, Alison E. Patteson, Rae M. Robertson-Anderson and Bekele J. Gurmessa
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引用次数: 0

摘要

哺乳动物细胞的机械特性调控着许多细胞功能,并在很大程度上由细胞骨架决定。细胞骨架是由蛋白质丝组成的复合网络,包括肌动蛋白、微管和中间丝。这些不同细丝之间的相互作用产生了难以合成的新机械特性,最近的研究在加深我们对肌动蛋白和微管细丝之间机械相互作用的理解方面取得了长足进步。虽然中间丝在细胞的应激反应中起着关键作用,但它们对复合细胞骨架流变特性的影响仍鲜为人知。在这里,我们使用光学镊子微流变学测量了肌动蛋白和波形蛋白复合材料的线性粘弹性和非线性应力响应,肌动蛋白和波形蛋白的摩尔比各不相同。我们发现,与单组分网络相比,肌动蛋白-波形蛋白网络力学在线性和非线性状态下的效果几乎相反,令人惊讶。也就是说,与单组分的肌动蛋白或波形蛋白网络相比,复合材料的线性弹性高原模量和零剪切粘度明显降低,而在非线性体系中,复合材料与单组分网络相比,初始响应力和刚度最大。虽然这些新出现的趋势表明肌动蛋白和波形蛋白之间存在不同的相互作用,但非线性僵化和长时间应力响应似乎都主要由肌动蛋白决定,这与之前的体流变学研究不一致。我们证明,这些复杂的、依赖于尺度的效应来自于网络密度、丝状刚度、非特异性相互作用和孔弹性对不同时空尺度机械响应的不同贡献。细胞可能会利用这种复杂的行为来促进在不同尺度上对不同刺激做出不同的应激反应,从而实现其标志性的多功能性。
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Scale-dependent interactions enable emergent microrheological stress response of actin–vimentin composites†

The mechanical properties of the mammalian cell regulate many cellular functions and are largely dictated by the cytoskeleton, a composite network of protein filaments, including actin, microtubules, and intermediate filaments. Interactions between these distinct filaments give rise to emergent mechanical properties that are difficult to generate synthetically, and recent studies have made great strides in advancing our understanding of the mechanical interplay between actin and microtubule filaments. While intermediate filaments play critical roles in the stress response of cells, their effect on the rheological properties of the composite cytoskeleton remains poorly understood. Here, we use optical tweezers microrheology to measure the linear viscoelastic properties and nonlinear stress response of composites of actin and vimentin with varying molar ratios of actin to vimentin. We reveal a surprising, nearly opposite effect of actin–vimentin network mechanics compared to single-component networks in the linear versus nonlinear regimes. Namely, the linear elastic plateau modulus and zero-shear viscosity are markedly reduced in composites compared to single-component networks of actin or vimentin, whereas the initial response force and stiffness are maximized in composites versus single-component networks in the nonlinear regime. While these emergent trends are indicative of distinct interactions between actin and vimentin, nonlinear stiffening and long-time stress response appear to both be dictated primarily by actin, at odds with previous bulk rheology studies. We demonstrate that these complex, scale-dependent effects arise from the varied contributions of network density, filament stiffness, non-specific interactions, and poroelasticity to the mechanical response at different spatiotemporal scales. Cells may harness this complex behavior to facilitate distinct stress responses at different scales and in response to different stimuli to allow for their hallmark multifunctionality.

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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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