De novo design of a hyperstable non-natural protein–ligand complex with sub-Å accuracy

Protein catalysis requires the atomic-level orchestration of side chains, substrates and cofactors, and yet the ability to design a small-molecule-binding protein entirely from first principles with a precisely predetermined structure has not been demonstrated. Here we report the design of a novel p...

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Veröffentlicht in:	Nature chemistry 2017-12, Vol.9 (12), p.1157-1164
Hauptverfasser:	Polizzi, Nicholas F., Wu, Yibing, Lemmin, Thomas, Maxwell, Alison M., Zhang, Shao-Qing, Rawson, Jeff, Beratan, David N., Therien, Michael J., DeGrado, William F.
Format:	Artikel
Sprache:	eng
Schlagworte:	631/114/469 631/92/552 639/638/263/49/1141 639/638/92/469 Analytical Chemistry Atomic structure Binding Binding sites Biochemistry Catalysis Chemistry Chemistry/Food Science Cofactors Coordination compounds Design First principles Inorganic Chemistry Ligands Models, Molecular Organic Chemistry Physical Chemistry Porphyrins - chemistry Presenilin 1 Proteins Proteins - chemistry Substrates Temperature
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container_end_page	1164
container_issue	12
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container_title	Nature chemistry
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creator	Polizzi, Nicholas F. Wu, Yibing Lemmin, Thomas Maxwell, Alison M. Zhang, Shao-Qing Rawson, Jeff Beratan, David N. Therien, Michael J. DeGrado, William F.
description	Protein catalysis requires the atomic-level orchestration of side chains, substrates and cofactors, and yet the ability to design a small-molecule-binding protein entirely from first principles with a precisely predetermined structure has not been demonstrated. Here we report the design of a novel protein, PS1, that binds a highly electron-deficient non-natural porphyrin at temperatures up to 100 °C. The high-resolution structure of holo-PS1 is in sub-Å agreement with the design. The structure of apo-PS1 retains the remote core packing of the holoprotein, with a flexible binding region that is predisposed to ligand binding with the desired geometry. Our results illustrate the unification of core packing and binding-site definition as a central principle of ligand-binding protein design. The first demonstration of a protein designed entirely from first principles that binds a small-molecule cofactor in a precisely predetermined orientation has now been described. The design method utilizes a remote protein core that both anchors and predisposes a flexible binding site for the desired cofactor-binding geometry.
doi_str_mv	10.1038/nchem.2846
format	Article
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Here we report the design of a novel protein, PS1, that binds a highly electron-deficient non-natural porphyrin at temperatures up to 100 °C. The high-resolution structure of holo-PS1 is in sub-Å agreement with the design. The structure of apo-PS1 retains the remote core packing of the holoprotein, with a flexible binding region that is predisposed to ligand binding with the desired geometry. Our results illustrate the unification of core packing and binding-site definition as a central principle of ligand-binding protein design. The first demonstration of a protein designed entirely from first principles that binds a small-molecule cofactor in a precisely predetermined orientation has now been described. 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subjects	631/114/469 631/92/552 639/638/263/49/1141 639/638/92/469 Analytical Chemistry Atomic structure Binding Binding sites Biochemistry Catalysis Chemistry Chemistry/Food Science Cofactors Coordination compounds Design First principles Inorganic Chemistry Ligands Models, Molecular Organic Chemistry Physical Chemistry Porphyrins - chemistry Presenilin 1 Proteins Proteins - chemistry Substrates Temperature
title	De novo design of a hyperstable non-natural protein–ligand complex with sub-Å accuracy
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