Thermodynamic propensities of amino acids in the native state ensemble: Implications for fold recognition

doi:10.1110/ps.01601

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Thermodynamic propensities of amino acids in the native state ensemble: Implications for fold recognition

James O. Wrabl¹, Scott A. Larson¹ and Vincent J. Hilser¹

¹ Department of Human Biological Chemistry & Genetics and Sealy Center for Structural Biology, University of Texas Medical Branch, Galveston, Texas 77555-1055, USA

Reprint requests to: Vincent J. Hilser, Department of Human Biological Chemistry & Genetics and Sealy Center for Structural Biology, 5.162 Medical Research Bldg., University of Texas Medical Branch, Galveston, Texas 77555-1055, USA; e-mail: vince{at}hbcg.utmb.edu; fax: (409) 747-6816.

An amino acid sequence, in the context of the solvent environment,contains all of the thermodynamic information necessary to encodea three-dimensional protein structure. To investigate the relationshipbetween an amino acid sequence and its corresponding proteinfold, a database of thermodynamic stability information wasassembled that spanned 2951 residues from 44 nonhomologous proteins.This information was obtained using the COREX algorithm, whichcomputes an ensemble-based description of the native state ofa protein. It was observed that amino acid types partitionedunequally into high, medium, and low thermodynamic stabilityenvironments. Furthermore, these distributions were reproducibleand were significantly different than those expected from randompartitioning. To assess the structural importance of the distributions,simple fold-recognition experiments were performed based ona 3D-1D scoring matrix containing only COREX residue stabilityinformation. This procedure was able to recover amino acid sequencescorresponding to correct target structures more effectivelythan scoring matrices derived from randomized data. High-scoringsequences were often aligned correctly with their correspondingtarget profiles, suggesting that calculated thermodynamic stabilityprofiles have the potential to encode sequence information.As a control, identical fold-recognition experiments were performedon the same database of proteins using DSSP secondary structureinformation in the scoring matrix, instead of COREX residuestability information. The comparable performance of both approachessuggested that COREX residue stability information and secondarystructure information could be of equivalent utility in moresophisticated fold-recognition techniques. The results of thiswork are a consequence of the idea that amino acid sequencesfold not into single, rigidly stable structures but rather intothermodynamic ensembles best represented by a time-averagedstructure.

Keywords: Native state ensemble; threading and fold-recognition; protein structure prediction; residue thermodynamics; protein stability

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