Dissipative Assembly of Aqueous Carboxylic Acid Anhydrides Fueled by Carbodiimides

Kariyawasam, Lasith S.; Hartley, C. Scott

doi:10.1021/jacs.7b06099

Cited by 180 publications

(212 citation statements)

References 45 publications

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“…3a). 11,[26][27][28][29][30][31][32][33][34] Here, a chemical fuel (F) reacts -either covalently or noncovalentlywith monomer M leading to an activated monomer M* which has the ability to aggregate (A* n ) in a thermodynamically favored process. Contemporaneously a backward reaction takes place which converts M* (or A* n ) back to M (or A n ) accompanied by the release of waste (W).…”

Section: Fig 3 ‫|‬ Dissipative Self-assembly Amentioning

confidence: 99%

Energy consumption in chemical fuel-driven self-assembly

2018

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Nature extensively exploits high-energy transient self-assembly structures that are able to perform work through a dissipative process. Often, self-assembly relies on the use of molecules as fuel that is consumed to drive thermodynamically unfavourable reactions away from equilibrium. Implementing this kind of non-equilibrium self-assembly process in synthetic systems is bound to profoundly impact the fields of chemistry, materials science and synthetic biology, leading to innovative dissipative structures able to convert and store chemical energy. Yet, despite increasing efforts, the basic principles underlying chemical fuel-driven dissipative self-assembly are often overlooked, generating confusion around the meaning and definition of scientific terms, which does not favour progress in the field. The scope of this Perspective is to bring closer together current experimental approaches and conceptual frameworks. From our analysis it also emerges that chemically fuelled dissipative processes may have played a crucial role in evolutionary processes.

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Section: Fig 3 ‫|‬ Dissipative Self-assembly Amentioning

confidence: 99%

Energy consumption in chemical fuel-driven self-assembly

2018

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“…This has sparked strong interest in the design of chemical‐fuel driven out‐of‐equilibrium systems, in particular related to self‐assembly . The majority of reported examples rely on the covalent modification of building blocks, which changes their propensity to form assemblies . However, driven self‐assembly processes in Nature, that is, fuel‐driven processes that lead to a population of a high‐energy state, rely exquisitely on the use of noncovalent interactions for building block activation .…”

Section: Figurementioning

confidence: 99%

Substrate‐Induced Self‐Assembly of Cooperative Catalysts

et al. 2018

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Dissipative self-assembly processes in Nature rely on chemical fuels that activate proteins for assembly through the formation of a noncovalent complex. The catalytic activity of the assemblies causes fuel degradation, resulting in the formation of an assembly in a high-energy, out-of-equilibrium state. Herein, we apply this concept to a synthetic system and demonstrate that a substrate can induce the formation of vesicular assemblies, which act as cooperative catalysts for cleavage of the same substrate.

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“…The precursor in our reaction cycle has a C‐terminal aspartic or glutamic acid, such that it carries two carboxylates: one on the C‐terminus and one on its side group. These carboxylates can be condensed into their corresponding cyclic anhydride at the expense of a carbodiimide fuel (Scheme b) . The conversion to the anhydride constitutes the activation reaction.…”

Section: Methodsmentioning

confidence: 99%

“…These carboxylates can be condensed into their corresponding cyclic anhydride at the expense of a carbodiimide fuel (Scheme 1b). [32,33] The conversion to the anhydride constitutes the activation reaction. As a fuel, we used EDC (1-ethyl-3-(3-dimethylaminopropyl) carbodiimide) which was irreversibly converted into its corresponding urea (waste).…”

Section: Dynamic Vesicles Formed By Dissipative Self-assemblymentioning

confidence: 99%

Dynamic Vesicles Formed By Dissipative Self‐Assembly

et al. 2019

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Synthetic lipid membranes have served as important models for cellular membranes. However, these static membranes do not recapitulate the dynamic nature of the biological membranes which are frequently remodeled to support cellular function. An ideal membrane model would thus also display dynamic exchange of lipids. In this work, we achieve such a system by coupling the self‐assembly of peptides into membranes with a chemical reaction cycle. The reaction cycle activates and deactivates the peptides for self‐assembly at the expense of a chemical fuel. The resulting membranes are dynamically remodeled, and, over their 40 min lifetime, they emerge, grow, and are torn apart before they eventually decay.

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Dissipative Assembly of Aqueous Carboxylic Acid Anhydrides Fueled by Carbodiimides

Cited by 180 publications

References 45 publications

Energy consumption in chemical fuel-driven self-assembly

Energy consumption in chemical fuel-driven self-assembly

Substrate‐Induced Self‐Assembly of Cooperative Catalysts

Dynamic Vesicles Formed By Dissipative Self‐Assembly

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