Covalent on-cell conjugation of biomaterials through oxidative phenolic coupling regulates stem cell fate via intracellular biophysical programming
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Abstract
Mechanotransduction is widely used to guide cell fate in hydrogels. Traditionally, hydrogels contain adhesive ligands that dynamically bond with cells to stimulate biochemical signalling axis such as YAP-TAZ. However, the molecular toolbox to achieve mechanotransduction has remained virtually limited to non-covalent bonds, which limits our ability to program engineered living matter. Here, we demonstrate that on-cell chemistry can be leveraged to covalently tether biomaterials directly onto cells, and reveal that mechanotransduction is enabled via intracellular biophysical programming. Specifically, droplet microfluidics produced single-cell microgels in which individual stem cells were extracellularly conjugated to either soft or stiff hydrogels via on-cell oxidative phenolic coupling, which allowed for investigation of mechanotransduction at single-cell resolution. Interestingly, this altered intracellular molecular crowding, calcium signalling, and chromatin organization by regulating cytoplasmic and nuclear volume in a stiffness-dependent yet YAP/TAZ-independent manner. Notably, addition of conventional dynamic adhesive ligands such as RGDs decreased chondrogenic commitment indicating that covalent cell-material tethering is both efficient and sufficient for programming cell fate. Encoding biomaterials with a novel form of mechanotransduction in the form of covalent on-cell chemistry, such as oxidative phenolic coupling, expands our ability to guide cellular behaviour, which can accelerate development of drug-screening models, lab-grown meat, and engineered tissues.
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- last seen: 2026-05-20T01:45:00.602351+00:00