David Böhringer, Mar Cóndor, Lars Bischof, Tina Czerwinski, Niklas Gampl, Phuong Anh Ngo, Andreas Bauer, Caroline Voskens, Rocío López-Posadas, Kristian Franze, Silvia Budday, Christoph Mark, Ben Fabry, Richard Gerum
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引用次数: 0
Abstract
Immune cells, such as natural killer cells, migrate with high speeds of several micrometres per minute through dense tissue. However, the magnitude of the traction forces during this migration is unknown. Here we present a method to measure dynamic traction forces of fast migrating cells in biopolymer matrices from the observed matrix deformations. Our method accounts for the mechanical nonlinearity of the three-dimensional tissue matrix and can be applied to time series of confocal or bright-field image stacks. It allows for precise force reconstruction over a wide range of force magnitudes and object sizes—even when the imaged volume captures only a small part of the matrix deformation field. We demonstrate the broad applicability of our method by measuring forces from around 1 nN for axon growth cones up to around 10 μN for mouse intestinal organoids. We find that natural killer cells show bursts of large traction forces around 50 nN that increase with matrix stiffness. These force bursts are driven by myosin II contractility, mediated by integrin β1 adhesions, focal adhesion kinase and Rho-kinase activity, and occur predominantly when the cells migrate through narrow matrix pores. Immune cells are believed not to generate large traction forces during migration. Now, measurements of natural killer cells in dense tissue reveal bursts of large traction forces as they move through narrow pores.
免疫细胞(如自然杀伤细胞)会以每分钟几微米的速度在致密组织中高速迁移。然而,这种迁移过程中的牵引力大小尚不清楚。在此,我们提出了一种方法,通过观察基质变形来测量生物聚合物基质中快速迁移细胞的动态牵引力。我们的方法考虑了三维组织基质的机械非线性,可应用于共聚焦或明视场图像的时间序列。即使成像体积只捕捉到基质变形场的一小部分,它也能在很大的力大小和物体尺寸范围内进行精确的力重建。我们通过测量从轴突生长锥的约 1 nN 到小鼠肠有机体的约 10 μN 的力,证明了我们的方法具有广泛的适用性。我们发现,自然杀伤细胞会爆发出 50 nN 左右的巨大牵引力,并随着基质硬度的增加而增大。这些牵引力爆发由肌球蛋白II收缩力驱动,由整合素β1粘附、局灶性粘附激酶和Rho-激酶活性介导,主要发生在细胞迁移穿过狭窄的基质孔时。
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