Laboratory of Cell Biology, Center for Cancer Research, National Cancer Institute, National Institutes of Health, Bethesda, MD 20892.
Laboratory of Cell Biology, Center for Cancer Research, National Cancer Institute, National Institutes of Health, Bethesda, MD 20892
Proc Natl Acad Sci U S A. 2019 Jul 16;116(29):14448-14455. doi: 10.1073/pnas.1814271116. Epub 2019 Jul 2.
Mechanical homeostasis describes how cells sense physical cues from the microenvironment and concomitantly remodel both the cytoskeleton and the surrounding extracellular matrix (ECM). Such feedback is thought to be essential to healthy development and maintenance of tissue. However, the nature of the dynamic coupling between microscale cell and ECM mechanics remains poorly understood. Here we investigate how and whether cells remodel their cortex and basement membrane to adapt to their microenvironment. We measured both intracellular and extracellular viscoelasticity, generating a full factorial dataset on 5 cell lines in 2 ECMs subjected to 4 cytoskeletal drug treatments at 2 time points. Nonmalignant breast epithelial cells show a similar viscoelasticity to that measured for the local ECM when cultured in 3D laminin-rich ECM. In contrast, the malignant counterpart is stiffer than the local environment. We confirmed that other mammary cancer cells embedded in tissue-mimetic hydrogels are nearly 4-fold stiffer than the surrounding ECM. Perturbation of actomyosin did not yield uniform responses but instead depended on the cell type and chemistry of the hydrogel. The observed viscoelasticity of both ECM and cells were well described by power laws in a frequency range that governs single filament cytoskeletal dynamics. Remarkably, the intracellular and extracellular power law parameters for the entire dataset collectively fall onto 2 parallel master curves described by just 2 parameters. Our work shows that tumor cells are mechanically plastic to adapt to many environments and reveals dynamical scaling behavior in the microscale mechanical responses of both cells and ECM.
机械内稳态描述了细胞如何感知来自微环境的物理线索,并同时重塑细胞骨架和周围的细胞外基质 (ECM)。这种反馈被认为对于组织的健康发育和维持至关重要。然而,细胞和 ECM 力学之间的微观尺度动态耦合的性质仍知之甚少。在这里,我们研究了细胞如何以及是否重塑它们的皮质和基底膜以适应其微环境。我们测量了细胞内和细胞外的粘弹性,在 2 种 ECM 中对 5 种细胞系进行了 4 种细胞骨架药物处理,并在 2 个时间点生成了一个完整的因子数据集。非恶性乳腺上皮细胞在富含层粘连蛋白的 3D ECM 中培养时,表现出与局部 ECM 相似的粘弹性。相比之下,恶性对应物比局部环境更硬。我们证实,嵌入组织模拟水凝胶中的其他乳腺癌细胞比周围的 ECM 硬近 4 倍。肌动球蛋白的扰动没有产生统一的反应,而是取决于细胞类型和水凝胶的化学性质。在控制单丝细胞骨架动力学的频率范围内,观察到的 ECM 和细胞的粘弹性都很好地用幂律描述。值得注意的是,整个数据集的细胞内和细胞外幂律参数共同落在由仅 2 个参数描述的 2 条平行主曲线上。我们的工作表明,肿瘤细胞具有机械适应性,可以适应多种环境,并揭示了细胞和 ECM 的微观力学响应中的动态标度行为。