Embryonic gene regulation through mechanical forces

It is generally thought that embryonic development and cellular differentiation of animals and humans follows a precise genetic program of spatiotemporal gene expression. However, a number of recent studies suggested that mechanotransduction — the ability of cells to transform mechanical forces into biochemical signals — can also contribute to the regulation of gene expression and thus may play an important role in development. While most of these studies were done in cell culture, the team of Ulrich Technau from the University of Vienna now reports experiments with mechanosensitive gene expression during early development of the starlet sea anemone Nematostella vectensis.

The authors show in a recent publication in the Proceedings of the National Academy of Sciences USA that chemical inhibition of cellular myosin function not only blocks the morphogenetic movement of gastrulation — the process where inner and outer cell layers are formed by invagination — but also abolishes the expression of a crucial developmental regulator gene, brachyury. This gene has a crucial ancient role in the development of virtually all animals. Surprisingly, external mechanical pressure applied to such embryos can activate or restore the expression of brachyury. Furthermore, brachyury expression in Nematostella vectensis via mechanotransduction depends on ?-catenin, a key protein with a conserved dual role in cell-cell adhesion and in gene regulation following a signaling cascade.

Based on their findings, the authors propose a feedback loop whereby mechanical and genetic regulation work together to ensure robust brachyury expression. In addition, because ?-catenin-dependent mechanotransduction occurs in other animals like zebrafish and the fruitfly, the findings suggest that this form of gene regulation dates back to at least 600 million years ago, the evolutionary split between vertebrates, insects and sea anemones.