De novo design of a non-local β-sheet protein with high stability and accuracy

Enrique Marcos; Tamuka M. Chidyausiku; Andrew C. McShan; Thomas Evangelidis; Santrupti Nerli; Lauren Carter; Lucas G. Nivón; Audrey Davis; Gustav Oberdorfer; Konstantinos Tripsianes; Nikolaos G. Sgourakis; David Baker

doi:10.1038/s41594-018-0141-6

De novo design of a non-local β-sheet protein with high stability and accuracy

Enrique Marcos^*, Tamuka M. Chidyausiku, Andrew C. McShan, Thomas Evangelidis, Santrupti Nerli, Lauren Carter, Lucas G. Nivón, Audrey Davis, Gustav Oberdorfer, Konstantinos Tripsianes, Nikolaos G. Sgourakis, David Baker^*

^*Corresponding author for this work

Institute of Biochemistry (6480)

Research output: Contribution to journal › Article › peer-review

Abstract

β-sheet proteins carry out critical functions in biology, and hence are attractive scaffolds for computational protein design. Despite this potential, de novo design of all-β-sheet proteins from first principles lags far behind the design of all-α or mixed-αβ domains owing to their non-local nature and the tendency of exposed β-strand edges to aggregate. Through study of loops connecting unpaired β-strands (β-arches), we have identified a series of structural relationships between loop geometry, side chain directionality and β-strand length that arise from hydrogen bonding and packing constraints on regular β-sheet structures. We use these rules to de novo design jellyroll structures with double-stranded β-helices formed by eight antiparallel β-strands. The nuclear magnetic resonance structure of a hyperthermostable design closely matched the computational model, demonstrating accurate control over the β-sheet structure and loop geometry. Our results open the door to the design of a broad range of non-local β-sheet protein structures.

Original language	English
Pages (from-to)	1028-1034
Number of pages	7
Journal	Nature Structural & Molecular Biology
Volume	25
Issue number	11
DOIs	https://doi.org/10.1038/s41594-018-0141-6
Publication status	Published - 1 Nov 2018

ASJC Scopus subject areas

Structural Biology
Molecular Biology

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title = "De novo design of a non-local β-sheet protein with high stability and accuracy",

abstract = "β-sheet proteins carry out critical functions in biology, and hence are attractive scaffolds for computational protein design. Despite this potential, de novo design of all-β-sheet proteins from first principles lags far behind the design of all-α or mixed-αβ domains owing to their non-local nature and the tendency of exposed β-strand edges to aggregate. Through study of loops connecting unpaired β-strands (β-arches), we have identified a series of structural relationships between loop geometry, side chain directionality and β-strand length that arise from hydrogen bonding and packing constraints on regular β-sheet structures. We use these rules to de novo design jellyroll structures with double-stranded β-helices formed by eight antiparallel β-strands. The nuclear magnetic resonance structure of a hyperthermostable design closely matched the computational model, demonstrating accurate control over the β-sheet structure and loop geometry. Our results open the door to the design of a broad range of non-local β-sheet protein structures.",

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AU - Marcos, Enrique

AU - Chidyausiku, Tamuka M.

AU - McShan, Andrew C.

AU - Evangelidis, Thomas

AU - Nerli, Santrupti

AU - Carter, Lauren

AU - Nivón, Lucas G.

AU - Davis, Audrey

AU - Oberdorfer, Gustav

AU - Tripsianes, Konstantinos

AU - Sgourakis, Nikolaos G.

AU - Baker, David

PY - 2018/11/1

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N2 - β-sheet proteins carry out critical functions in biology, and hence are attractive scaffolds for computational protein design. Despite this potential, de novo design of all-β-sheet proteins from first principles lags far behind the design of all-α or mixed-αβ domains owing to their non-local nature and the tendency of exposed β-strand edges to aggregate. Through study of loops connecting unpaired β-strands (β-arches), we have identified a series of structural relationships between loop geometry, side chain directionality and β-strand length that arise from hydrogen bonding and packing constraints on regular β-sheet structures. We use these rules to de novo design jellyroll structures with double-stranded β-helices formed by eight antiparallel β-strands. The nuclear magnetic resonance structure of a hyperthermostable design closely matched the computational model, demonstrating accurate control over the β-sheet structure and loop geometry. Our results open the door to the design of a broad range of non-local β-sheet protein structures.

AB - β-sheet proteins carry out critical functions in biology, and hence are attractive scaffolds for computational protein design. Despite this potential, de novo design of all-β-sheet proteins from first principles lags far behind the design of all-α or mixed-αβ domains owing to their non-local nature and the tendency of exposed β-strand edges to aggregate. Through study of loops connecting unpaired β-strands (β-arches), we have identified a series of structural relationships between loop geometry, side chain directionality and β-strand length that arise from hydrogen bonding and packing constraints on regular β-sheet structures. We use these rules to de novo design jellyroll structures with double-stranded β-helices formed by eight antiparallel β-strands. The nuclear magnetic resonance structure of a hyperthermostable design closely matched the computational model, demonstrating accurate control over the β-sheet structure and loop geometry. Our results open the door to the design of a broad range of non-local β-sheet protein structures.

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De novo design of a non-local β-sheet protein with high stability and accuracy

Abstract

ASJC Scopus subject areas

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