Liquid-liquid phase separation (LLPS) is a fundamental biophysical process driving the formation of dynamic biomolecular condensates, which spatially organize cellular biochemistry without membrane de Show more
Liquid-liquid phase separation (LLPS) is a fundamental biophysical process driving the formation of dynamic biomolecular condensates, which spatially organize cellular biochemistry without membrane delimitation. These condensates arise from multivalent, weak interactions among intrinsically disordered proteins, modular interaction motifs, and RNA scaffolds, enabling highly tunable and reversible compartmentalization of biomolecules. This phase behavior regulates critical cellular functions such as gene expression, signal transduction, and stress response, while its dysregulation contributes to pathological aggregation and disease. Recent advances leverage LLPS principles to design synthetic condensates with controllable composition, properties, and activities. Combining structural insights, quantitative phase behavior, and synthetic biology tools, engineered condensates have been developed for enhanced catalysis, metabolic control, targeted drug delivery, and biosensing. This review summarizes the molecular mechanisms, design strategies, and translational prospects of LLPS-mediated condensates, thereby paving the way for future exploration at the interface of cellular biophysics and bioengineering. Show less
Liyan Jia, Yan Qiao · 2025 · Journal of the American Chemical Society · ACS Publications · added 2026-04-20
In nature, life is inherently dissipative. Cells continuously consume energy (such as ATP) to sustain homeostasis, drive metabolism, and respond dynamically to environmental cues. Inspired by this pri Show more
In nature, life is inherently dissipative. Cells continuously consume energy (such as ATP) to sustain homeostasis, drive metabolism, and respond dynamically to environmental cues. Inspired by this principle, we develop a synthetic protocell system that exhibits dissipative behavior and initiates metabolic-like processes. Our design features synthetic vesicles formed from a cationic surfactant, which undergo a fuel-driven transformation into coacervate protocells via liquid-liquid phase separation. Dissipation is achieved through alkaline phosphatase (ALP)-catalyzed ATP hydrolysis, driving the reverse transition from coacervates back to vesicles. The distinct physicochemical properties and internal organization of vesicle and coacervate protocells enable us to design functional regulators capable of producing secondary signals, such as fluorescence and enzymatic products. This work offers a strategy for engineering enzymatic reaction-regulated dissipative behaviors of protocell systems that emulate key aspects of cellular metabolism, representing a step toward synthetic life-like systems with dynamic behavior and functional complexity. Show less