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Biomaterial design inspired by membraneless organelles

Compartmentalization is ubiquitous in the broad cellular context, especially in the formation of membraneless organelles (MOs). Membraneless organelles (MOs) are phase-separated liquid compartments that provide spatiotemporal control of biomolecules and metabolic activities inside a cell. While MOs exhibit intriguing properties such as efficient compositional regulation, thermodynamic metastability, environmental sensitivity and reversibility, their formation is driven by weak non-covalent interactions derived from simple motifs of intrinsic disordered proteins (IDPs). Understanding the natural design of IDPs and the liquid-liquid phase separation behavior will not only reveal insights about the contributions of MOs to cellular physiology and disease pathology, but also provides inspirations for the de novo design of dynamic biomolecules depots, self-regulated biochemical reactors, and stimuli-responsive systems. In this article, the sequence and structural features of IDPS that contribute to the organization of MOs are reviewed. Artificial MOs formed following these principles, including self-assembling peptides, synthetic IDPs, polyelectrolytes and peptide-polymer hybrids are described. Finally, we illustrate the applications and discuss the potential of the MO-inspired biomaterials, with examples spanning biochemical reactors, synthetic biology, drug discovery and drug delivery.