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Nonequilibrium Amyloid Polymers Exploit Dynamic Covalent Linkage to Temporally Control Charge-Selective Catalysis

Surashree Goswami, Antara Reja, Sumit Pal, Abhishek Singh, Dibyendu Das

2022Journal of the American Chemical Society19 citationsDOI

Abstract

Extant proteins exploit thermodynamically activated negatively charged coenzymes and hydrotropes to temporally access mechanistically important conformations that regulate vital biological functions, from metabolic reactions to expression modulation. Herein, we show that a short amyloid peptide can bind to a small molecular coenzyme by exploiting reversible covalent linkage to polymerize and access catalytically proficient nonequilibrium amyloid microphases. Subsequent hydrolysis of the activated coenzyme leads to depolymerization, realizing a variance of the surface charge of the assembly as a function of time. Such temporal change of surface charge dynamically modulates catalytic activities of the transient assemblies as observed in highly evolved modern-day biocatalysts.

Topics & Concepts

ChemistryCovalent bondDepolymerizationCofactorAmyloid (mycology)PeptideCatalysisBiophysicsEnzymeBiochemistryOrganic chemistryBiologyInorganic chemistrySupramolecular Self-Assembly in MaterialsLipid Membrane Structure and BehaviorProtein Structure and Dynamics
Nonequilibrium Amyloid Polymers Exploit Dynamic Covalent Linkage to Temporally Control Charge-Selective Catalysis | Litcius