Emergence of cellular nematic order is a conserved feature of gastrulation in animal embryos

TL;DR

This study reveals that a nematic liquid crystal phase emerges early during gastrulation across diverse animal species, driven by a conserved physical mechanism linked to cell polarity and adhesion, with implications for understanding embryonic tissue organization.

Contribution

The paper uncovers a conserved physical mechanism underlying nematic order formation during gastrulation in different animals, supported by experiments and a predictive theoretical model.

Findings

Nematic order forms early before cell shape changes.

Long-range correlations follow a power-law decay.

Disruption of nematic phase occurs with loss of cell polarity or adhesion.

Abstract

Cells undergo dramatic morphological changes during embryogenesis, yet how these changes affect the formation of ordered tissues remains elusive. Here, we show that a phase transition leading to the formation of a nematic liquid crystal state during gastrulation in the development of embryos of fish, frogs, and fruit flies occurs by a common mechanism despite substantial differences between these evolutionarily distant animals. Importantly, nematic order forms early before any discernible changes in the shapes of cells. All three species exhibit similar propagation of the nematic phase, reminiscent of nucleation and growth mechanisms. The spatial correlations in the nematic phase in the notochord region are long-ranged and follow a similar power-law decay (y~$x^{-\alpha}$ ) with $\alpha$ less than unity, indicating a common underlying physical mechanism. To explain the common physical mechanism, we created a theoretical model that not only explains the experimental observations but also predicts that the nematic phase should be disrupted upon loss of planar cell polarity (frog), cell adhesion (frog), and notochord boundary formation (zebrafish). Gene knockdown or mutational studies confirm the theoretical predictions. The combination of experiments and theory provides a unified framework for understanding the potentially universal features of metazoan embryogenesis, in the process shedding light on the advent of ordered structures during animal development.