Mapping Allostery through Computational Glycine Scanning and Correlation Analysis of Residue–Residue Contacts

Understanding allosteric mechanisms is essential for the physical control of molecular switches and downstream cellular responses. However, it is difficult to decode essential allosteric motions in a high-throughput scheme. A general two-pronged approach to performing automatic data reduction of sim...

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Bibliographic Details
Published in:Biochemistry (Easton) 2015-02, Vol.54 (7), p.1534-1541
Main Authors: Johnson, Quentin R, Lindsay, Richard J, Nellas, Ricky B, Fernandez, Elias J, Shen, Tongye
Format: Article
Language:English
Subjects:
Allosteric Regulation
Animals
Chickens
glycine (amino acid)
Glycine - chemistry
Glycine - genetics
Glycine - metabolism
Molecular Dynamics Simulation
physical control
Point Mutation
Principal Component Analysis
Protein Conformation
receptors
Receptors, Thyroid Hormone - chemistry
Receptors, Thyroid Hormone - genetics
Receptors, Thyroid Hormone - metabolism
Retinoid X Receptors - chemistry
Retinoid X Receptors - genetics
Retinoid X Receptors - metabolism
simulation models
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Summary:Understanding allosteric mechanisms is essential for the physical control of molecular switches and downstream cellular responses. However, it is difficult to decode essential allosteric motions in a high-throughput scheme. A general two-pronged approach to performing automatic data reduction of simulation trajectories is presented here. The first step involves coarse-graining and identifying the most dynamic residue–residue contacts. The second step is performing principal component analysis of these contacts and extracting the large-scale collective motions expressed via these residue–residue contacts. We demonstrated the method using a protein complex of nuclear receptors. Using atomistic modeling and simulation, we examined the protein complex and a set of 18 glycine point mutations of residues that constitute the binding pocket of the ligand effector. The important motions that are responsible for the allostery are reported. In contrast to conventional induced-fit and lock-and-key binding mechanisms, a novel “frustrated-fit” binding mechanism of RXR for allosteric control was revealed.
ISSN:0006-2960
1520-4995
1520-4995
DOI:10.1021/bi501152d