Department of Mechanical Engineering, Stanford University, Stanford, CA, USA.
Sarafan ChEM-H, Stanford University, Stanford, CA, USA.
Nat Rev Mol Cell Biol. 2023 Jul;24(7):495-516. doi: 10.1038/s41580-023-00583-1. Epub 2023 Feb 27.
Mechanical properties of extracellular matrices (ECMs) regulate essential cell behaviours, including differentiation, migration and proliferation, through mechanotransduction. Studies of cell-ECM mechanotransduction have largely focused on cells cultured in 2D, on top of elastic substrates with a range of stiffnesses. However, cells often interact with ECMs in vivo in a 3D context, and cell-ECM interactions and mechanisms of mechanotransduction in 3D can differ from those in 2D. The ECM exhibits various structural features as well as complex mechanical properties. In 3D, mechanical confinement by the surrounding ECM restricts changes in cell volume and cell shape but allows cells to generate force on the matrix by extending protrusions and regulating cell volume as well as through actomyosin-based contractility. Furthermore, cell-matrix interactions are dynamic owing to matrix remodelling. Accordingly, ECM stiffness, viscoelasticity and degradability often play a critical role in regulating cell behaviours in 3D. Mechanisms of 3D mechanotransduction include traditional integrin-mediated pathways that sense mechanical properties and more recently described mechanosensitive ion channel-mediated pathways that sense 3D confinement, with both converging on the nucleus for downstream control of transcription and phenotype. Mechanotransduction is involved in tissues from development to cancer and is being increasingly harnessed towards mechanotherapy. Here we discuss recent progress in our understanding of cell-ECM mechanotransduction in 3D.
细胞外基质 (ECM) 的力学性能通过力学转导调节细胞的基本行为,包括分化、迁移和增殖。细胞-ECM 力学转导的研究主要集中在培养于二维 (2D) 弹性基底上、具有不同硬度的细胞上。然而,细胞通常在体内与 ECM 以三维 (3D) 形式相互作用,并且 3D 中的细胞-ECM 相互作用和力学转导机制与 2D 中的不同。ECM 表现出各种结构特征和复杂的力学性能。在 3D 中,周围 ECM 的机械限制限制了细胞体积和形状的变化,但允许细胞通过延伸突起和调节细胞体积以及通过肌动球蛋白的收缩力来对基质施加力。此外,由于基质重塑,细胞-基质相互作用是动态的。因此,ECM 的刚度、粘弹性和可降解性通常在调节 3D 中的细胞行为方面起着关键作用。3D 力学转导的机制包括传统的整联蛋白介导的途径,该途径感知机械性能,以及最近描述的机械敏感离子通道介导的途径,该途径感知 3D 限制,两者都汇聚到细胞核,以进行转录和表型的下游控制。力学转导涉及从发育到癌症的组织,并越来越多地被用于力学治疗。在这里,我们讨论了我们对 3D 中细胞-ECM 力学转导的理解的最新进展。