Restricted sidechain plasticity in the structures of native proteins and complexes

Sarel J. Fleishman; Sagar D. Khare; Nobuyasu Koga; David Baker

doi:10.1002/pro.604

Restricted sidechain plasticity in the structures of native proteins and complexes

Sarel J. Fleishman
, Sagar D. Khare
, Nobuyasu Koga
, David Baker

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

47 Scopus citations

Abstract

Protein-design methodology can now generate models of protein structures and interfaces with computed energies in the range of those of naturally occurring structures. Comparison of the properties of native structures and complexes to isoenergetic design models can provide insight into the properties of the former that reflect selection pressure for factors beyond the energy of the native state. We report here that sidechains in native structures and interfaces are significantly more constrained than designed interfaces and structures with equal computed binding energy or stability, which may reflect selection against potentially deleterious non-native interactions. Published by Wiley-Blackwell.

Original language	English (US)
Pages (from-to)	753-757
Number of pages	5
Journal	Protein Science
Volume	20
Issue number	4
DOIs	https://doi.org/10.1002/pro.604
State	Published - Apr 2011
Externally published	Yes

All Science Journal Classification (ASJC) codes

Biochemistry
Molecular Biology

Keywords

Aromatic residues
Boltzmann distribution
Entropy of binding
Monomer design
Negative design
Protein design
Rossman fold design
Small-molecule binding

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10.1002/pro.604

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abstract = "Protein-design methodology can now generate models of protein structures and interfaces with computed energies in the range of those of naturally occurring structures. Comparison of the properties of native structures and complexes to isoenergetic design models can provide insight into the properties of the former that reflect selection pressure for factors beyond the energy of the native state. We report here that sidechains in native structures and interfaces are significantly more constrained than designed interfaces and structures with equal computed binding energy or stability, which may reflect selection against potentially deleterious non-native interactions. Published by Wiley-Blackwell.",

keywords = "Aromatic residues, Boltzmann distribution, Entropy of binding, Monomer design, Negative design, Protein design, Rossman fold design, Small-molecule binding",

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AU - Khare, Sagar D.

AU - Koga, Nobuyasu

AU - Baker, David

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Y1 - 2011/4

N2 - Protein-design methodology can now generate models of protein structures and interfaces with computed energies in the range of those of naturally occurring structures. Comparison of the properties of native structures and complexes to isoenergetic design models can provide insight into the properties of the former that reflect selection pressure for factors beyond the energy of the native state. We report here that sidechains in native structures and interfaces are significantly more constrained than designed interfaces and structures with equal computed binding energy or stability, which may reflect selection against potentially deleterious non-native interactions. Published by Wiley-Blackwell.

AB - Protein-design methodology can now generate models of protein structures and interfaces with computed energies in the range of those of naturally occurring structures. Comparison of the properties of native structures and complexes to isoenergetic design models can provide insight into the properties of the former that reflect selection pressure for factors beyond the energy of the native state. We report here that sidechains in native structures and interfaces are significantly more constrained than designed interfaces and structures with equal computed binding energy or stability, which may reflect selection against potentially deleterious non-native interactions. Published by Wiley-Blackwell.

KW - Aromatic residues

KW - Boltzmann distribution

KW - Entropy of binding

KW - Monomer design

KW - Negative design

KW - Protein design

KW - Rossman fold design

KW - Small-molecule binding

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DO - 10.1002/pro.604

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AN - SCOPUS:79953169868

SN - 0961-8368

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SP - 753

EP - 757

JO - Protein Science

JF - Protein Science

IS - 4

ER -

Restricted sidechain plasticity in the structures of native proteins and complexes

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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