Deciphering mechanical determinants of morphological evolution
Summary
How morphological diversity arises from variations in biomechanical processes remains an open question. Although forces shape tissues, how force-generating systems differ across species to create diverse forms is unclear. Here, we combine comparative morphogenesis and active matter theory across six cnidarian species spanning 500 million years of divergence to identify the mechanical basis of larval shape diversity. We define species-specific configurations of mechanical modules-termed mec
Content
# Deciphering mechanical determinants of morphological evolution
*Published: 2026 Apr 30*
How morphological diversity arises from variations in biomechanical processes
remains an open question. Although forces shape tissues, how force-generating
systems differ across species to create diverse forms is unclear. Here, we
combine comparative morphogenesis and active matter theory across six cnidarian
species spanning 500 million years of divergence to identify the mechanical
basis of larval shape diversity. We define species-specific configurations of
mechanical modules-termed mechanotypes-that quantitatively predict larval shapes
across taxa. We find that shape elongation is a simple trait at the mesoscale
level, as its variation depends on one mechanical module, whereas shape polarity
is a complex trait dependent on several modules. Perturbations mimicking
interspecies regulatory differences reshape these modules, reprogramming larval
morphology into forms resembling sister species. By establishing a mesoscale
mechanical framework for cross-species comparison, this work reveals how
variations in a limited set of tissue-scale parameters generate morphological
diversity.
DOI: 10.1016/j.cell.2026.02.010