粘度可调节细胞扩散以及细胞与细胞外基质的相互作用。

Hugh Xiao, Xiangyu Gong, Seyma Nayir Jordan, Zixie Liang, Michael Mak
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引用次数: 0

摘要

流体粘度和渗透压是细胞可以检测到的一些未被重视的机械刺激。粘度和渗透压等多种流体因素的异常变化与囊性纤维化、癌症和冠心病等疾病有关。粘度的变化最近被认为是细胞运动的调节因子。这些新研究的重点是细胞在玻璃基质和微通道上的迁移和扩散,而粘度是否会影响细胞外基质(ECM)的细胞重塑仍是一个问题。在这里,我们证明了粘度升高会诱导胶原基底的细胞重塑,并增强细胞在模拟 ECM 基底上的扩散。我们的研究结果拓展了最近的研究,即粘度可诱导细胞力的增加,并证明粘度可推动局部 ECM 的致密化。我们的数据进一步表明,微管、Ras 相关 C3 肉毒毒素底物 1(Rac1)、肌动蛋白相关蛋白 2/3 (Arp2/3)复合物、Rho 相关蛋白激酶 1(ROCK)和肌球蛋白是粘度诱导 ECM 重塑的重要调节因子。在粘度诱导细胞扩散的情况下,在玻璃基质和胶原基质上培养的细胞对药理处理的反应明显不同,这表明微管、Rac1 和 Arp2/3 在调节细胞扩散中的作用因基质而异。此外,我们的研究结果表明,高渗透压通过抑制膜皱褶来覆盖粘度诱导的细胞扩散。我们的研究结果表明,粘度是纤维微环境中 ECM 重塑和细胞扩散的调节因子。我们还揭示了粘度和渗透压之间复杂的相互作用。我们希望我们的研究能为今后研究粘度在生理和病理条件下的关键作用铺平道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Viscosity regulates cell spreading and cell-extracellular matrix interactions.

Fluid viscosity and osmolarity are among some of the underappreciated mechanical stimuli that cells can detect. Abnormal changes of multiple fluidic factors such as viscosity and osmolarity have been linked with diseases such as cystic fibrosis, cancer, and coronary heart disease. Changes in viscosity have been recently suggested as a regulator of cell locomotion. These novel studies focus on cell migration and spreading on glass substrates and through microchannels, and it remains a question whether viscosity impacts the cellular remodeling of extracellular matrices (ECMs). Here, we demonstrate that elevated viscosity induces cellular remodeling of collagen substrates and enhances cell spreading on ECM-mimetic substrates. Our results expand on recent work showing that viscosity induces increased cellular forces and demonstrates that viscosity can drive local ECM densification. Our data further show that microtubules, Ras-related C3 botulinum toxin substrate 1 (Rac1), actin-related protein 2/3 (Arp2/3) complex, Rho-associated protein kinase 1 (ROCK), and myosin are important regulators of viscosity-induced ECM remodeling. In the context of viscosity-induced cell spreading, cells cultured on glass and collagen substrates exhibit markedly different responses to pharmacological treatments, indicating that microtubules, Rac1, and Arp2/3 play distinct roles in regulating cellular spreading depending on the substrate. In addition, our results demonstrate that high osmotic pressures override viscosity-induced cell spreading by suppressing membrane ruffling. Our results demonstrate viscosity as a regulator of ECM remodeling and cell spreading in a fibrillar microenvironment. We also reveal a complex interplay between viscosity and osmolarity. We anticipate that our research can pave the way for future investigations into the crucial roles played by viscosity in both physiological and pathological conditions.

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