Developmentally driven self-assembly and dynamics of living chiral crystals

The emergent dynamics exhibited by collections of living organisms often shows signatures of symmetries that are broken at the single-organism level. At the same time, early organism development itself is accompanied by a sequence of symmetry breaking events that eventually establish the body plan. Combining these key aspects of collective phenomena and embryonic development, we describe here the spontaneous formation of hydrodynamically stabilized active crystals made of hundreds of starfish embryos during early development. As development progresses and embryos change morphology, crystals become increasingly disordered and eventually stop forming. We introduce a minimal hydrodynamic model that is fully parameterized by experimental measurements of single embryos. Using this theory, we can quantitatively describe the stability, formation and rotation of crystals, as well as the emergence of long-lived chiral deformation waves. Our work thereby quantitatively connects developmental symmetry breaking events on the single-embryo level with the remarkable macroscopic properties of a novel living chiral crystal system.