TY - JOUR
T1 - A novel method reveals that solvent water favors polyproline II over β-strand conformation in peptides and unfolded proteins
T2 - Conditional hydrophobic accessible surface area (CHASA)
AU - Fleming, Patrick J.
AU - Fitzkee, Nicholas C.
AU - Mezei, Mihaly
AU - Srinivasan, Rajgopal
AU - Rose, George D.
PY - 2005/1
Y1 - 2005/1
N2 - In aqueous solution, the ensemble of conformations sampled by peptides and unfolded proteins is largely determined by their interaction with water. It has been a long-standing goal to capture these solute-water energetics accurately and efficiently in calculations. Historically, accessible surface area (ASA) has been used to estimate these energies, but this method breaks down when applied to amphipathic peptides and proteins. Here we introduce a novel method in which hydrophobic ASA is determined after first positioning water oxygens in hydrogen-bonded orientations proximate to all accessible peptide/protein backbone N and O atoms. This conditional hydrophobic accessible surface area is termed CHASA. The CHASA method was validated by predicting the polyproline-II (PII) and β-strand conformational preferences of non-proline residues in the coil library (i.e., non-α-helix, non-β-strand, non-β-turn library derived from X-ray elucidated structures). Further, the method successfully rationalizes the previously unexplained solvation energies in polyalanyl peptides and compares favorably with published experimentally determined PII residue propensities. We dedicate this paper to Frederic M. Richards.
AB - In aqueous solution, the ensemble of conformations sampled by peptides and unfolded proteins is largely determined by their interaction with water. It has been a long-standing goal to capture these solute-water energetics accurately and efficiently in calculations. Historically, accessible surface area (ASA) has been used to estimate these energies, but this method breaks down when applied to amphipathic peptides and proteins. Here we introduce a novel method in which hydrophobic ASA is determined after first positioning water oxygens in hydrogen-bonded orientations proximate to all accessible peptide/protein backbone N and O atoms. This conditional hydrophobic accessible surface area is termed CHASA. The CHASA method was validated by predicting the polyproline-II (PII) and β-strand conformational preferences of non-proline residues in the coil library (i.e., non-α-helix, non-β-strand, non-β-turn library derived from X-ray elucidated structures). Further, the method successfully rationalizes the previously unexplained solvation energies in polyalanyl peptides and compares favorably with published experimentally determined PII residue propensities. We dedicate this paper to Frederic M. Richards.
KW - CHASA
KW - Coil library
KW - Conditional hydrophobic accessible surface area
KW - Polyproline-II
KW - Probability density map
KW - Solvation energy
UR - http://www.scopus.com/inward/record.url?scp=11144230087&partnerID=8YFLogxK
U2 - 10.1110/ps.041047005
DO - 10.1110/ps.041047005
M3 - Article
C2 - 15576559
AN - SCOPUS:11144230087
SN - 0961-8368
VL - 14
SP - 111
EP - 118
JO - Protein Science
JF - Protein Science
IS - 1
ER -