Department of Biomedical Engineering, University of Minnesota, Minneapolis, MN 55455, USA.
Integr Biol (Camb). 2023 Apr 11;15. doi: 10.1093/intbio/zyad009.
Epithelial tissues adapt their form and function following mechanical perturbations, or mechano-adapt, and these changes often result in reactive forces that oppose the direction of the applied change. Tissues subjected to ectopic tensions, for example, employ behaviors that lower tension, such as increasing proliferation or actomyosin turnover. This oppositional behavior suggests that the tissue has a mechanical homeostasis. Whether attributed to maintenance of cellular area, cell density, or cell and tissue tensions, epithelial mechanical homeostasis has been implicated in coordinating embryonic morphogenesis, wound healing, and maintenance of adult tissues. Despite advances toward understanding the feedback between mechanical state and tissue response in epithelia, more work remains to be done to examine how tissues regulate mechanical homeostasis using epithelial sheets with defined micropatterned shapes. Here, we used cellular microbiaxial stretching (CμBS) to investigate mechano-adaptation in micropatterned tissues of different shape consisting of Madin-Darby canine kidney cells. Using the CμBS platform, tissues were subjected to a 30% stretch that was held for 24 h. We found that, following stretch, tissue stresses immediately increased then slowly evolved over time, approaching their pre-stretch values by 24 h. Organization of the actin cytoskeletal was found to play a role in this process: anisotropic ally structured tissues exhibited anisotropic stress patterns, and the cytoskeletal became more aligned following stretch and reorganized over time. Interestingly, in unstretched tissues, stresses also decreased, which was found to be driven by proliferation-induced cellular confinement and change in tissue thickness. We modeled these behaviors with a continuum-based model of epithelial growth that accounted for stress-induced actin remodeling and proliferation, and found this model to strongly capture experimental behavior. Ultimately, this combined experimental-modeling approach suggests that epithelial mechano-adaptation depends on cellular architecture and proliferation, which can be modeled with a field-averaged approach applicable to more specific contexts in which change is driven by epithelial mechanical homeostasis. Insight box Epithelial tissues adapt their form and function following mechanical perturbation, and it is thought that this 'mechano-adaptation' plays an important role in driving processes like embryonic morphogenesis, wound healing, and adult tissue maintenance. Here, we use cellular microbiaxial stretching to probe this process in vitro in small epithelial tissues whose geometries were both controlled and varied. By using a highly precise stretching device and a continuum mechanics modeling framework, we revealed that tissue mechanical state changes following stretch and over time, and that this behavior can be explained by stress-dependent changes in actin fibers and proliferation. Integration of these approaches enabled a systematic approach to empirically and precisely measure these phenomena.
上皮组织在受到机械扰动后会改变其形态和功能,即机械适应,这些变化通常会产生与施加变化方向相反的反作用力。例如,受到异位张力的组织会采用降低张力的行为,例如增加增殖或肌动球蛋白周转率。这种反作用力表明组织具有机械内稳态。无论是归因于维持细胞面积、细胞密度还是细胞和组织张力,上皮组织的机械内稳态都与协调胚胎形态发生、伤口愈合和维持成人组织有关。尽管在理解上皮组织中机械状态和组织反应之间的反馈方面取得了进展,但仍需要更多的工作来研究组织如何使用具有定义的微图案形状的上皮片来调节机械内稳态。在这里,我们使用细胞双轴拉伸(CμBS)来研究由犬肾细胞组成的不同形状的微图案组织中的机械适应。使用 CμBS 平台,组织受到 30%的拉伸,持续 24 小时。我们发现,拉伸后,组织应力立即增加,然后随着时间的推移缓慢演变,在 24 小时内接近其预拉伸值。发现细胞骨架的肌动蛋白细胞骨架组织的排列在这个过程中起着作用:各向异性组织的组织表现出各向异性的应力模式,并且在拉伸后细胞骨架变得更加对齐,并随着时间的推移重新组织。有趣的是,在未拉伸的组织中,应力也会降低,这是由增殖诱导的细胞限制和组织厚度变化引起的。我们使用一种基于连续体的上皮生长模型来模拟这些行为,该模型考虑了应激诱导的肌动蛋白重塑和增殖,并发现该模型能够很好地捕捉实验行为。最终,这种结合实验-建模的方法表明,上皮机械适应取决于细胞结构和增殖,这可以通过适用于由上皮机械内稳态驱动的更具体情况的场平均方法来建模。见解框上皮组织在受到机械扰动后会改变其形态和功能,人们认为这种“机械适应”在驱动胚胎形态发生、伤口愈合和成人组织维持等过程中起着重要作用。在这里,我们使用细胞双轴拉伸在其几何形状既受控制又变化的小型上皮组织中体外探测这一过程。通过使用高度精确的拉伸设备和连续体力学建模框架,我们揭示了组织机械状态在拉伸后和随时间的变化,并且这种行为可以通过依赖于应力的肌动蛋白纤维和增殖的变化来解释。这些方法的整合使我们能够系统地通过经验和精确测量这些现象。
