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The unusual internal motion of the villin headpiece subdomain
Author(s) -
Harpole Kyle W.,
O'Brien Evan S.,
Clark Matthew A.,
McKnight C. James,
Vugmeyster Liliya,
Wand A. Joshua
Publication year - 2016
Publication title -
protein science
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.353
H-Index - 175
eISSN - 1469-896X
pISSN - 0961-8368
DOI - 10.1002/pro.2831
Subject(s) - chemistry , protein folding , folding (dsp implementation) , deuterium , side chain , protein dynamics , crystallography , villin , relaxation (psychology) , nuclear magnetic resonance , molecular dynamics , chemical physics , physics , computational chemistry , atomic physics , biochemistry , organic chemistry , psychology , social psychology , actin , electrical engineering , engineering , polymer
Abstract The thermostable 36‐residue subdomain of the villin headpiece (HP36) is the smallest known cooperatively folding protein. Although the folding and internal dynamics of HP36 and close variants have been extensively studied, there has not been a comprehensive investigation of side‐chain motion in this protein. Here, the fast motion of methyl‐bearing amino acid side chains is explored over a range of temperatures using site‐resolved solution nuclear magnetic resonance deuterium relaxation. The squared generalized order parameters of methyl groups extensively spatially segregate according to motional classes. This has not been observed before in any protein studied using this methodology. The class segregation is preserved from 275 to 305 K. Motions detected in Helix 3 suggest a fast timescale of conformational heterogeneity that has not been previously observed but is consistent with a range of folding and dynamics studies. Finally, a comparison between the order parameters in solution with previous results based on solid‐state nuclear magnetic resonance deuterium line shape analysis of HP36 in partially hydrated powders shows a clear disagreement for half of the sites. This result has significant implications for the interpretation of data derived from a variety of approaches that rely on partially hydrated protein samples.

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