A platform to induce and mature biomolecular condensates using chemicals and light

Biomolecular condensates are membraneless compartments that impart spatial and temporal organization to cells. Condensates can undergo maturation, transitioning from dynamic liquid-like states into solid-like states associated with neurodegenerative diseases, including amyotrophic lateral sclerosis (ALS) and Huntington’s disease. Despite their important roles, many aspects of condensate biology remain incompletely understood, requiring tools for acutely manipulating condensate-relevant processes within cells. Here we used the BCL6 BTB domain and its ligands BI-3802 and BI-3812 to create a chemical genetic platform, BTBolig, allowing inducible condensate formation and dissolution. We also developed optogenetic and chemical methods for controlled induction of condensate maturation, where we surprisingly observed recruitment of chaperones into the condensate core and formation of dynamic biphasic condensates. Our work provides insights into the interaction of condensates with proteostasis pathways and introduces a suite of chemical–genetic approaches to probe the role of biomolecular condensates in health and disease. Hernandez-Candia et al. introduce BTBolig, a chemical-based tool to manipulate biomolecular condensates, and CoSMo, a method for control of condensate maturation. When used together, the authors observe dynamic interactions of condensates with protein chaperones.