2PRU

NMR Structure of Human apoS100B at 10C

2PRU の概要

• エントリーDOI: 10.2210/pdb2pru/pdb
• 関連するPDBエントリー: 1B4C 1CFP 1NSH
• NMR情報: BMRB: 5377
• 分子名称: Protein S100-B (1 entity in total)
• 機能のキーワード: s100, calcium binding protein, ef-hand, all alpha helical protein, metal binding protein
• 由来する生物種: Homo sapiens (human)
• 細胞内の位置: Cytoplasm: P04271
• タンパク質・核酸の鎖数: 2
• 化学式量合計: 21191.68

構造登録者

Malik, S.,Shaw, G.S.,Revington, M. (登録日: 2007-05-04, 公開日: 2008-04-15, 最終更新日: 2024-05-22)

主引用文献

Malik, S.,Revington, M.,Smith, S.P.,Shaw, G.S.
Analysis of the structure of human apo-S100B at low temperature indicates a unimodal conformational distribution is adopted by calcium-free S100 proteins.
Proteins, 73:28-42, 2008

PubMed Abstract: S100B is one of the best-characterized members of the calcium-signaling S100 protein family. Most S100 proteins are dimeric, with each monomer containing two EF-hand calcium-binding sites (EF1, EF2). S100B and other S100 proteins respond to calcium increases in the cell by coordinating calcium and undergoing a conformational change that allows them to interact with a variety of cellular targets. Although several three dimensional structures of S100 proteins are available in the calcium-free (apo-) state it has been observed that these structures appear to adopt a wide range of conformations in the EF2 site with respect to the positioning of helix III, the helix that undergoes the most dramatic calcium-induced conformational change. In this work, we have determined the structure of human apo-S100B at 10 degrees C to examine whether temperature might be responsible for these structural differences. Further, we have used this data, and other available apo-S100 structures, to show that despite the range of interhelical angles adopted in the apo-S100 structures, normal Gaussian distributions about the mean angles found in the structure of human apo-S100B are observed. This finding, only obvious from the analysis of all available apo-S100 proteins, provides direct structural evidence that helix III is a loosely packed helix. This is likely a necessary functional property of the S100 proteins that facilitates the calcium-induced conformational change of helix III. In contrast, the calcium-bound structures of the S100 proteins show significantly smaller variability in the interhelical angles. This shows that calcium binding to the S100 proteins causes not only a conformational change but results in a tighter distribution of helices within the EF2 calcium binding site required for target protein interactions.

PubMed: 18384084
DOI: 10.1002/prot.22037

実験手法

SOLUTION NMR