Live-Cell Imaging to Resolve Salt-Induced Liquid-Liquid Phase Separation of FUS Protein by Dye Self-Labeling.

Abstract

The aggregation of fusion in sarcoma (FUS) in the cytoplasm and nucleus is a pathological feature of Amyotrophic lateral sclerosis (ALS) and Frontotemporal Dementia (FTD). Genetic mutations, abnormal protein synthesis, environmental stress, and aging have all been implicated as causative factors in this process. Salt ions are essential to many physiological processes in the body, and the imbalance of them is an important environmental stress factor in cells. However, their effect on liquid-liquid phase separation (LLPS) of FUS proteins in living cells is not well understood. Here, we map the various salt-induced LLPS of FUS in living cells by genetically coding and self-labeling FUS with organic dyes. The brightness and photostability of the dyes enable long-term imaging to track the mechanism of the assembly and disappearance of FUS phase separation. The FUS protein showed a better phase separation tendency under 0.3 M salt stimulation, and there was a large amount of FUS shuttling from the nucleus to the cytoplasm. At this concentration, various salt solutions displayed different effects on the phase separation of FUS protein, following the Hofmeister effects. We further observed that the assembly of FUS droplets underwent a process of rapid formation of small droplets, plateaus, and mutual fusion. Strikingly, The CsCl-stimulated FUS droplets were not completely reversible after washing, and some solid-like granules remained in the nucleus. Taken together, these results help broaden our understanding of the LLPS of FUS proteins in cellular stress responses.