Cluster expansion models for flexible-backbone protein energetics

Protein structure prediction and design often involve discrete modeling of side-chain conformations on structural templates. Introducing backbone flexibility into such models has proven important in many different applications. Backbone flexibility improves model accuracy and provides access to larg...

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Bibliographic Details
Published in:Journal of computational chemistry 2009-11, Vol.30 (15), p.2402-2413
Main Authors: Apgar, James R, Hahn, Seungsoo, Grigoryan, Gevorg, Keating, Amy E
Format: Article
Language:English
Subjects:
Analytical chemistry
Cluster analysis
cluster expansion
Computer Simulation
flexible backbone
Models, Chemical
Molecular structure
Protein Conformation
protein design
protein modeling
Protein Structure, Tertiary
Proteins
Proteins - chemistry
Quantum Theory
Spine
structure prediction
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Summary:Protein structure prediction and design often involve discrete modeling of side-chain conformations on structural templates. Introducing backbone flexibility into such models has proven important in many different applications. Backbone flexibility improves model accuracy and provides access to larger sequence spaces in computational design, although at a cost in complexity and time. Here, we show that the influence of backbone flexibility on protein conformational energetics can be treated implicitly, at the level of sequence, using the technique of cluster expansion. Cluster expansion provides a way to convert structure-based energies into functions of sequence alone. It leads to dramatic speed-ups in energy evaluation and provides a convenient functional form for the analysis and optimization of sequence-structure relationships. We show that it can be applied effectively to flexible-backbone structural models using four proteins: α-helical coiled-coil dimers and trimers, zinc fingers, and Bcl-xL/peptide complexes. For each of these, low errors for the sequence-based models when compared with structure-based evaluations show that this new way of treating backbone flexibility has considerable promise, particularly for protein design.
ISSN:0192-8651
1096-987X
DOI:10.1002/jcc.21249