Fuel-regulated self-assembly is a key principle by which Nature creates spatiotemporally controlled materials and dynamic molecular systems that are in continuous communication (molecular exchange) with the external environment. Designing artificial materials that self-assemble and disassemble via conversion/consumption of a chemical fuel is a grand challenge in supramolecular chemistry, which requires a profound knowledge of the factors governing these complex systems. Here we focus on recently reported metal-coordinated monomers that polymerise in the presence of ATP and depolymerise upon ATP hydrolysis, exploring their fuel-regulated self-assembly/disassembly via multiscale molecular modelling. We use all-atom simulations to assess the role of ATP in stabilising these monomers in assemblies, and we then build on a minimalistic model to investigate their fuel-driven polymerisation and depolymerisation on a higher scale. In this way, we elucidate general aspects of fuel-regulated self-assembly that are important toward the rational design of new types of bioinspired materials.

Multiscale Molecular Modelling of ATP-Fueled Supramolecular Polymerisation and Depolymerisation** / C. Perego, L. Pesce, R. Capelli, S.J. George, G.M. Pavan. - In: CHEMSYSTEMSCHEM. - ISSN 2570-4206. - 3:2(2021 Mar), pp. e2000038.1-e2000038.10. [10.1002/syst.202000038]

Multiscale Molecular Modelling of ATP-Fueled Supramolecular Polymerisation and Depolymerisation**

R. Capelli;
2021

Abstract

Fuel-regulated self-assembly is a key principle by which Nature creates spatiotemporally controlled materials and dynamic molecular systems that are in continuous communication (molecular exchange) with the external environment. Designing artificial materials that self-assemble and disassemble via conversion/consumption of a chemical fuel is a grand challenge in supramolecular chemistry, which requires a profound knowledge of the factors governing these complex systems. Here we focus on recently reported metal-coordinated monomers that polymerise in the presence of ATP and depolymerise upon ATP hydrolysis, exploring their fuel-regulated self-assembly/disassembly via multiscale molecular modelling. We use all-atom simulations to assess the role of ATP in stabilising these monomers in assemblies, and we then build on a minimalistic model to investigate their fuel-driven polymerisation and depolymerisation on a higher scale. In this way, we elucidate general aspects of fuel-regulated self-assembly that are important toward the rational design of new types of bioinspired materials.
Biomimetic Materials; Fuel-driven Self-assembly; Molecular Dynamics; Molecular Modelling; Supramolecular Polymerisation;
Settore CHIM/02 - Chimica Fisica
Settore FIS/03 - Fisica della Materia
mar-2021
28-set-2020
Article (author)
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2434/933799
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