SUMMARY In recent years, it has become increasingly clear that the material properties of biomolecular condensates (BMCs), which are formed via liquid-liquid phase separation, play crucial roles in both cellular physiology and pathology. Nevertheless, mechanistic understandings of the molecular determinants and modulators of BMC viscoelastic phases remain incomplete due to the limitations of currently available techniques to probe their dynamics across single-molecule to mesoscale. The goal of this proposal is to address this critical gap by the development of a multi-parametric experimental toolbox that simultaneously reports on condensate structure and dynamics across different length scales, with high sensitivity. Our approach will feature correlative multicolor single-molecule fluorescence microscopy, single-molecule spectroscopy, dual-trap optical tweezers, and microfluidics. Utilizing our novel toolbox, we will decipher the mechanisms of liquid-to-liquid and liquid-to-solid phase transitions of intracellular BMCs, processes that critically contribute to the onset or development of many neurodegenerative diseases including amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). Commonly used fluorescence microscopy techniques, such as fluorescence recovery after photobleaching (FRAP), offer only probe-specific protein/RNA diffusivity within the RNP granules. In contrast, our proposed correlative force-fluorescence microscopy platform will provide a multiscale view of BMC structure and dynamics by taking advantage of optical tweezer-based rheological and fluid dynamics measurements in conjunction with quantification of protein/RNA dynamics using single-molecule fluorescence. Recent results from the project supported by the parent award clearly established that BMCs are network fluids where the network connectivity and dynamics govern their functional output. These results, in conjunction with our recent discovery that oncofusion transcription factors reprogram gene expression via ectopic phase separation in the nucleus, collectively led us to hypothesize that BMC network structure and dynamics from single-molecule-to-mesoscale precisely orchestrate gene regulation within the nuclear chromatin. Overall, our research program will address three Key Challenges (KCs): (a) we will develop a novel multi-parametric approach based on correlative single- molecule fluorescence microscopy, single-molecule spectroscopy, and dual-trap optical tweezer that simultaneously reports on molecular and mesoscale protein-RNA condensate structure and dynamics in vitro and in live cells (KC 1), (b) we will apply our toolbox to map the transition pathways of physiologic BMCs to pathologic states in c9orf72 repeat expansion disorder (KC 2), and (c) we will identify mechanisms of transcriptional condensate formation, regulation, and function at DNA enhancer sites (KC 3). Our studies will provide new insights into the determinants of functional BMC materia...