利用埋藏的水分子探索蛋白质的能量景观。

Using buried water molecules to explore the energy landscape of proteins.

作者信息

Denisov V P, Peters J, Hörlein H D, Halle B

机构信息

Condensed Matter Magnetic Resonance Group, Department of Chemistry, Lund University, Lund, Sweden.

出版信息

Nat Struct Biol. 1996 Jun;3(6):505-9. doi: 10.1038/nsb0696-505.

DOI:10.1038/nsb0696-505

PMID:8646535

Abstract

Buried water molecules constitute a highly conserved, integral part of nearly all known protein structures. Such water molecules exchange with external solvent as a result of protein conformational fluctuations. We report here the results of water (17)O and (2)H magnetic relaxation dispersion measurements on wild-type and mutant bovine pancreatic trypsin inhibitor in aqueous solution at 4-80 degrees C. These data lead to the first determination of the exchange rate of a water molecule buried in a protein. The strong temperature dependence of this rate is ascribed to large-scale conformational fluctuations in an energy landscape with a statistical ruggedness of approximately 10 kJ mol(-1).

摘要

埋藏的水分子构成了几乎所有已知蛋白质结构中高度保守的整体部分。由于蛋白质构象波动，这些水分子会与外部溶剂发生交换。我们在此报告了在4至80摄氏度的水溶液中对野生型和突变型牛胰蛋白酶抑制剂进行水的17O和2H磁弛豫色散测量的结果。这些数据首次确定了埋藏在蛋白质中的水分子的交换速率。该速率对温度的强烈依赖性归因于能量景观中的大规模构象波动，其统计粗糙度约为10 kJ mol-1。

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利用埋藏的水分子探索蛋白质的能量景观。

Using buried water molecules to explore the energy landscape of proteins.

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