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Abstract
Creating artificial organelles that sequester and release specific proteins in response to a small molecule in mammalian cells is an attractive approach for regulating protein function. In this work, by combining phase-separated condensates formed by the tandem fusion of two oligomeric proteins with a trimethoprim (TMP)-responsive nanobody switch for GFP (LAMA; ligand-modulated antibody fragment), we developed a synthetic condensate system that initially sequesters GFP-tagged proteins within condensates and rapidly releases them into the cytoplasm upon TMP treatment. The released proteins can then be resequestered by washing out the TMP. This system enabled user-defined, temporal, rapid, and reversible control of cellular processes, including membrane ruffling mediated by exogenously expressed GFP-Vav2 and modulation of the cellular localization of endogenous ERK2-GFP generated by genome knock-in. Our results highlight the utility of the LAMA-based synthetic condensate platform as a novel, chemically switchable tool for regulating protein function through controlled protein sequestration and release in mammalian cells.


