Patterned shear flows drive folding during organogenesis

In morphogenesis, living matter translates information encoded at the cellular scale into complex shape transformations. How does in-plane tissue patterning generate out-of-plane deformation needed to sculpt complex forms? A dramatic example of this theme is the fruit fly midgut -- a tube that folds and coils into a helical configuration in only two hours. Here, using a combination of light-sheet microscopy, genetics, computer vision, and tissue cartography, we reconstruct the full 3D shape dynamics and identify the driving sources of the shape change by linking out-of-plane motion to the cellular flow and active contraction patterns. Optogenetic manipulation of contractility in the endoderm and muscle layers decouples the role of each in sculpting the bilayer organ, enabling a simple mechanical model for midgut morphogenesis.