On-chip large-scale-integration and 2D collective modes of genetically programmed artificial cells

The on-chip large-scale-integration of genetically programmed artificial cells capable of exhibiting collective modes is an important goal for fundamental research and technology. Here, we report assembly of a 2D layout of 1024 monolithic DNA compartments as artificial cells on a 5-millimeter square silicon chip. Homeostatic cell-free protein synthesis reactions driven by genetic circuits occur inside the compartments. We created a reaction-diffusion system with a 30x30 square lattice of artificial cells interconnected by thin capillaries for diffusion of products. Driving the system by a genetic oscillator revealed emergent collective modes of synchrony and propagating phase waves in 2D, with dynamics controlled by geometry. This demonstrates a class of nonequilibrium autonomous systems, where chemical energy consumed to make proteins induces 2D collective patterns of gene expression on multicellular scales, with applications in biological computing, sensing, and materials synthesis. ### Competing Interest Statement The authors have declared no competing interest.