Biophysical Analysis of Mechanical Signals in Immotile Cilia of Mouse Embryonic Nodes Using Advanced Microscopic Techniques.

Bio-protocol Pub Date : 2023-07-20 DOI:10.21769/BioProtoc.4715

Takanobu A Katoh, Toshihiro Omori, Takuji Ishikawa, Yasushi Okada, Hiroshi Hamada

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Abstract

Immotile cilia of crown cells at the node of mouse embryos are required for sensing leftward fluid flow that gives rise to the breaking of left-right (L-R) symmetry. The flow-sensing mechanism has long remained elusive, mainly because of difficulties inherent in manipulating and precisely analyzing the cilium. Recent progress in optical microscopy and biophysical analysis has allowed us to study the mechanical signals involving primary cilia. In this study, we used high-resolution imaging with mechanical modeling to assess the membrane tension in a single cilium. Optical tweezers, a technique used to trap sub-micron-sized particles with a highly focused laser beam, allowed us to manipulate individual cilia. Super-resolution microscopy allowed us to discern the precise localization of ciliary proteins. Using this protocol, we provide a method for applying these techniques to cilia in mouse embryonic nodes. This method is widely applicable to the determination of mechanical signals in other cilia.

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利用先进的显微技术对小鼠胚胎节点静止纤毛机械信号的生物物理分析。

小鼠胚胎节点的冠细胞的不动纤毛是感知向左流动的液体所必需的，这会导致左右(L-R)对称性的破坏。长期以来，流量传感机制一直是难以捉摸的，主要是因为在操纵和精确分析纤毛方面存在固有的困难。光学显微镜和生物物理分析的最新进展使我们能够研究涉及初级纤毛的机械信号。在这项研究中，我们使用高分辨率成像和机械建模来评估单个纤毛的膜张力。光学镊子，一种用高度聚焦的激光束捕获亚微米大小的粒子的技术，使我们能够操纵单个纤毛。超分辨率显微镜使我们能够辨别纤毛蛋白的精确定位。利用该方案，我们提供了一种将这些技术应用于小鼠胚胎淋巴结纤毛的方法。该方法可广泛应用于其它纤毛机械信号的测定。

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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