Artificial Cells Evidence Apical Compressive Forces Building up During Neuroepithelial Organoid Early Development

During early stages of development of cerebral organoids, budding neuroepithelia display striking changes in size and morphology, occurring very rapidly. Whilst mechanical forces mediated by cadherin-cadherin junctions are known to control the assembly, maturation and stability of epithelia, little is known of the mechanical context associated with neuroepithelial organoid development. In this report, we demonstrate a rapid translocation of YAP to budding neuroepithelial apical junctions, suggesting the build-up of strong compressive forces early on in their development. To study the mechanics of budding rosettes, we designed oil microdroplets stabilised by protein nanosheets displaying cadherin receptors, able to engage with receptors presented by neighbouring neuroepithelial cells, to integrate into embryoid bodies and developing organoids. The resulting artificial cells are able to sustain the formation of mature junctions with neighbouring cells and lead to the recruitment of tight junction maturation proteins such as ZO1. During early budding of neuroepithelial rosettes, artificial cells are found to be rapidly expelled from the developing organoids, further evidencing apical compressive forces. These forces are not opposed by sufficiently strong shear forces from neighbouring cells, or adhesive forces maintaining anchorage to the apical junction, to induce deformation of artificial cells.