Inferring geometrical dynamics of cell nucleus translocation

Sirine Amiri, Yirui Zhang, Andonis Gerardos, Cécile Sykes, Pierre Ronceray
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Abstract

The ability of eukaryotic cells to squeeze through constrictions is limited by the stiffness of their large and rigid nucleus. However, migrating cells are often able to overcome this limitation and pass through constrictions much smaller than their nucleus, a mechanism that is not yet understood. This is what we address here through a data-driven approach using microfluidic devices where cells migrate through controlled narrow spaces of sizes comparable to the ones encountered in physiological situations. Stochastic Force Inference is applied to experimental nuclear trajectories and nuclear shape descriptors, resulting in equations that effectively describe this phenomenon of nuclear translocation. By employing a model where the channel geometry is an explicit parameter and by training it over experimental data with different sizes of constrictions, we ensure that the resulting equations are predictive to other geometries. Altogether, the approach developed here paves the way for a mechanistic and quantitative description of dynamical cell complexity during its motility.
推断细胞核易位的几何动态
真核细胞挤压通过狭小空间的能力受限于其巨大而坚硬的细胞核的硬度。然而,迁移的细胞往往能够克服这一限制,穿过比细胞核小得多的狭小空间,而这一机制尚不清楚。在这里,我们通过数据驱动的方法,利用微流体设备来解决这个问题,在这些设备中,细胞会通过受控的狭窄空间进行迁移,这些空间的大小与生理情况下遇到的空间大小相当。我们将随机力推理应用于实验核轨迹和核形状描述符,从而得出有效描述这种核迁移现象的方程。通过采用一个以通道几何形状为明确参数的模型,并在具有不同大小限制的实验数据上对其进行训练,我们确保了所得到的方程对其他几何形状具有预测性。总之,本文提出的方法为从机制上定量描述细胞运动过程中的动态复杂性铺平了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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