通过引入非天然氨基酸来重新设计限速的毫秒级酶运动。
Reengineering rate-limiting, millisecond enzyme motions by introduction of an unnatural amino acid.
机构信息
Department of Chemistry, Yale University, New Haven, Connecticut, USA.
出版信息
Biophys J. 2011 Jul 20;101(2):411-20. doi: 10.1016/j.bpj.2011.05.039.
Abstract
Rate-limiting millisecond motions in wild-type (WT) Ribonuclease A (RNase A) are modulated by histidine 48. Here, we incorporate an unnatural amino acid, thia-methylimidazole, at this site (H48C-4MI) to investigate the effects of a single residue on protein motions over multiple timescales and on enzyme catalytic turnover. Molecular dynamics simulations reveal that H48C-4MI retains some crucial WT-like hydrogen bonding interactions but the extent of protein-wide correlated motions in the nanosecond regime is decreased relative to WT. NMR Carr-Purcell-Meiboom-Gill relaxation dispersion experiments demonstrate that millisecond conformational motions in H48C-4MI are present over a similar pH range compared to WT. Furthermore, incorporation of this nonnatural amino acid allows retention of WT-like catalytic activity over the full pH range. These studies demonstrate that the complexity of the protein energy landscape during the catalytic cycle can be maintained using unnatural amino acids, which may prove useful in enzyme design efforts.
摘要
野生型(WT)核糖核酸酶 A(RNase A)中的限速毫秒级运动受组氨酸 48 调节。在这里,我们在该位点(H48C-4MI)引入非天然氨基酸噻甲基咪唑,以研究单个残基对蛋白质在多个时间尺度上的运动和酶催化周转的影响。分子动力学模拟表明,H48C-4MI 保留了一些关键的 WT 样氢键相互作用,但与 WT 相比,纳秒级的蛋白质整体相关运动程度降低。NMR Carr-Purcell-Meiboom-Gill 弛豫弥散实验表明,与 WT 相比,H48C-4MI 中的毫秒构象运动在相似的 pH 范围内存在。此外,该非天然氨基酸的引入允许在整个 pH 范围内保留 WT 样的催化活性。这些研究表明,在催化循环中,使用非天然氨基酸可以维持蛋白质能量景观的复杂性,这可能在酶设计工作中证明是有用的。
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