Controlling Organization and Forces in Active Matter Through Optically-Defined Boundaries

A distinguishing feature of living matter is its ability to control force-generating structures that accomplish tasks such as chromosome segregation, intracellular transport, and cell movement. To generate and manipulate these micron-scale structures and force fields, cells create spatiotemporal patterns of molecular-scale activity. Here, we control micron-scale structures and fluid flow by manipulating molecular-scale protein activity set by dynamic optical boundaries in an engineered system of purified proteins. Our engineered system consists of microtubules and light-activatable motor proteins that crosslink and reorganize microtubules upon illumination. During reorganization, crosslinked motors do work to create non-equilibrium structures. We design light patterns that enable us to create, move, and merge microtubule asters with spatial and temporal precision. By composing these basic operations, we create microtubule networks that can span several hundred microns in length and contract at speeds up to an order of magnitude faster than the speed of an individual motor. By scaling the size and speed of contractile networks, we generate and sculpt advective fluid flows. Our work shows that dynamic boundaries enable control over active matter. The principles of boundary-mediated control we uncover may be used to study emergent cellular structures and forces and to develop programmable active matter devices.