Prediction of Stable Globular Proteins Using Negative Design with Non-native Backbone Ensembles

被引:19
作者
Davey, James A. [1 ]
Damry, Adam M. [1 ]
Euler, Christian K. [1 ]
Goto, Natalie K. [1 ,2 ]
Chica, Roberto A. [1 ]
机构
[1] Univ Ottawa, Dept Chem & Biomol Sci, Ottawa, ON K1N 6N5, Canada
[2] Univ Ottawa, Dept Biochem Microbiol & Immunol, Ottawa, ON K1N 6N5, Canada
来源
STRUCTURE | 2015年 / 23卷 / 11期
基金
加拿大自然科学与工程研究理事会; 加拿大创新基金会;
关键词
ENERGY FUNCTIONS; COMPUTATIONAL DESIGN; STABILITY; SPECIFICITY; CRYSTAL; OPTIMIZATION; PERFORMANCE; ALGORITHM;
D O I
10.1016/j.str.2015.07.021
中图分类号
Q5 [生物化学]; Q7 [分子生物学];
学科分类号
071010 ; 081704 ;
摘要
Accurate predictions of protein stability have great potential to accelerate progress in computational protein design, yet the correlation of predicted and experimentally determined stabilities remains a significant challenge. To address this problem, we have developed a computational framework based on negative multistate design in which sequence energy is evaluated in the context of both native and non-native backbone ensembles. This framework was validated experimentally with the design of ten variants of streptococcal protein G domain beta 1 that retained the wild-type fold, and showed a very strong correlation between predicted and experimental stabilities (R-2 = 0.86). When applied to four different proteins spanning a range of fold types, similarly strong correlations were also obtained. Overall, the enhanced prediction accuracies afforded by this method pave the way for new strategies to facilitate the generation of proteins with novel functions by computational protein design.
引用
收藏
页码:2011 / 2021
页数:11
相关论文
共 49 条
[1]   Design of a heterospecific, tetrameric, 21-residue miniprotein with mixed α/β structure [J].
Ali, MH ;
Taylor, CM ;
Grigoryan, G ;
Allen, KN ;
Imperiali, B ;
Keating, AE .
STRUCTURE, 2005, 13 (02) :225-234
[2]   Dramatic performance enhancements for the FASTER optimization algorithm [J].
Allen, Benjamin D. ;
Mayo, Stephen L. .
JOURNAL OF COMPUTATIONAL CHEMISTRY, 2006, 27 (10) :1071-1075
[3]   Experimental library screening demonstrates the successful application of computational protein design to large structural ensembles [J].
Allen, Benjamin D. ;
Nisthal, Alex ;
Mayo, Stephen L. .
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA, 2010, 107 (46) :19838-19843
[4]   An Efficient Algorithm for Multistate Protein Design Based on FASTER [J].
Allen, Benjamin D. ;
Mayo, Stephen L. .
JOURNAL OF COMPUTATIONAL CHEMISTRY, 2010, 31 (05) :904-916
[5]  
[Anonymous], 2015, MOL OP ENV MOE
[6]   Potential energy functions for protein design [J].
Boas, F. Edward ;
Harbury, Pehr B. .
CURRENT OPINION IN STRUCTURAL BIOLOGY, 2007, 17 (02) :199-204
[7]   Specificity versus stability in computational protein design [J].
Bolon, DN ;
Grant, RA ;
Baker, TA ;
Sauer, RT .
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA, 2005, 102 (36) :12724-12729
[8]   The Nose-Poincare method for constant temperature molecular dynamics [J].
Bond, SD ;
Leimkuhler, BJ ;
Laird, BB .
JOURNAL OF COMPUTATIONAL PHYSICS, 1999, 151 (01) :114-134
[9]   Computational protein design: Software implementation, parameter optimization, and performance of a simple model [J].
Busch, Marcel Schmidt Am ;
Lopes, Anne ;
Mignon, David ;
Simonson, Thomas .
JOURNAL OF COMPUTATIONAL CHEMISTRY, 2008, 29 (07) :1092-1102
[10]   Generation of longer emission wavelength red fluorescent proteins using computationally designed libraries [J].
Chica, Roberto A. ;
Moore, Matthew M. ;
Allen, Benjamin D. ;
Mayo, Stephen L. .
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA, 2010, 107 (47) :20257-20262
12345