Mechanical heterogeneity along single cell-cell junctions is driven by lateral clustering of cadherins during vertebrate axis elongation.

Robert J Huebner,John B Wallingford,Abdul Naseer Malmi-Kakkada,Shinuo Weng,Sena Sarıkaya,D Thirumalai

doi:10.7554/elife.65390

Robert J Huebner, John B Wallingford + Show 4 more

Open Access

https://doi.org/10.7554/elife.65390

Copy DOI

Journal: eLife	Publication Date: May 25, 2021
Citations: 37	License type: CC BY 4.0

Affiliation: The University of Texas at Austin, Augusta University

Abstract

Morphogenesis is governed by the interplay of molecular signals and mechanical forces across multiple length scales. The last decade has seen tremendous advances in our understanding of the dynamics of protein localization and turnover at subcellular length scales, and at the other end of the spectrum, of mechanics at tissue-level length scales. Integrating the two remains a challenge, however, because we lack a detailed understanding of the subcellular patterns of mechanical properties of cells within tissues. Here, in the context of the elongating body axis of Xenopus embryos, we combine tools from cell biology and physics to demonstrate that individual cell-cell junctions display finely-patterned local mechanical heterogeneity along their length. We show that such local mechanical patterning is essential for the cell movements of convergent extension and is imparted by locally patterned clustering of a classical cadherin. Finally, the patterning of cadherins and thus local mechanics along cell-cell junctions are controlled by Planar Cell Polarity signaling, a key genetic module for CE that is mutated in diverse human birth defects.

Highlights

The establishment and maintenance of animal form involves the control of physical forces by molecular systems encoded in the genome, and the elongation of an animal’s head-to-tail body axis is a long-studied paradigm for understanding morphogenesis (Guillot and Lecuit, 2013)
We show that sub-cellular mechanical heterogeneity is essential for convergent extension (CE) and is imparted by cadherins via locally patterned intracellular interactions
We explored the physical basis of asymmetric motion in active and passive vertices using mean squared displacement (MSD)(SI Section 2)

Summary

Introduction

The establishment and maintenance of animal form involves the control of physical forces by molecular systems encoded in the genome, and the elongation of an animal’s head-to-tail body axis is a long-studied paradigm for understanding morphogenesis (Guillot and Lecuit, 2013). This essential step in the construction of a new embryo is driven by an array of morphogenetic engines, including an evolutionarily ancient suite of collective cell behaviors termed convergent extension (Figure 1A; Figure 1—figure supplement 1; Huebner and Wallingford, 2018). A more granular examination of the mechanics of CE has been made possible by the use of theoretical

Methods

Results

Conclusion