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Emergent mechanics of a networked multivalent protein condensate

Zhitao Liao, Bowen Jia, Dongshi Guan, Xudong Chen, Mingjie Zhang, Penger Tong

2025Nature Communications14 citationsDOIOpen Access PDF

Abstract

Multivalent proteins can form membraneless condensates in cells by liquid-liquid phase separation, and significant efforts have been made to study their biochemical properties. Here, we demonstrate the emergent mechanics of a functional multivalent condensate reconstituted with six postsynaptic density proteins, using atomic-force-microscopy-based mesoscale rheology and quantitative fluorescence measurements. The measured relaxation modulus and protein mobility reveal that the majority (80%) of the proteins in the condensate are mobile and diffuse through a dynamically cross-linked network made of the remaining (20%) non-mobile scaffold proteins. This percolating structure gives rise to a two-mode mechanical relaxation with an initial exponential decay followed by a long-time power-law decay, which differs significantly from simple Maxwell fluids. The power-law rheology with an exponent α ≃ 0.5 is a hallmark of weak bonds' binding/unbinding dynamics in the multivalent protein network. The concurrent molecular and mechanical profiling thus provides a reliable readout for characterizing the mechanical state of protein condensates and investigating their physiological functions and associations with diseases.

Topics & Concepts

RheologyChemical physicsBiophysicsPower lawRelaxation (psychology)ChemistryFluorescence recovery after photobleachingFluorescenceMaterials sciencePhysicsThermodynamicsOpticsMathematicsPsychologyStatisticsBiologySocial psychologyRNA Research and SplicingCellular Mechanics and InteractionsNuclear Structure and Function