酶活性位点处缓慢的溶剂化动力学：对催化作用的影响。

Slow solvation dynamics at the active site of an enzyme: implications for catalysis.

作者信息

Guha Soumi, Sahu Kalyanasis, Roy Durba, Mondal Sudip Kumar, Roy Siddhartha, Bhattacharyya Kankan

机构信息

Department of Biophysics, Bose Institute, P-1/12 CIT Scheme VIIM, Kolkata 700 054, India.

出版信息

Biochemistry. 2005 Jun 28;44(25):8940-7. doi: 10.1021/bi0473915.

DOI:10.1021/bi0473915

PMID:15966719

Abstract

Solvation dynamics at the active site of an enzyme, glutaminyl-tRNA synthetase (GlnRS), was studied using a fluorescence probe, acrylodan, site-specifically attached at cysteine residue C229, near the active site. The picosecond time-dependent fluorescence Stokes shift indicates slow solvation dynamics at the active site of the enzyme, in the absence of any substrate. The solvation dynamics becomes still slower when the substrate (glutamine or tRNA(Gln)) binds to the enzyme. A mutant Y211H-GlnRS was constructed in which the glutamine binding site is disrupted. The mutant Y211H-GlnRS labeled at C229 with acrylodan exhibited significantly different solvent relaxation, thus demonstrating that the slow dynamics is indeed associated with the active site. Implications for catalysis and specificity have been discussed.

摘要

利用一种荧光探针丙烯罗丹明，对谷氨酰胺-tRNA合成酶（GlnRS）活性位点的溶剂化动力学进行了研究。该探针通过位点特异性连接在活性位点附近的半胱氨酸残基C229上。皮秒级时间依赖的荧光斯托克斯位移表明，在没有任何底物的情况下，该酶活性位点的溶剂化动力学较慢。当底物（谷氨酰胺或tRNA(Gln)）与酶结合时，溶剂化动力学变得更慢。构建了一个谷氨酰胺结合位点被破坏的突变体Y211H-GlnRS。用丙烯罗丹明标记在C229处的突变体Y211H-GlnRS表现出显著不同的溶剂弛豫，从而证明缓慢的动力学确实与活性位点相关。文中还讨论了其对催化作用和特异性的影响。

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酶活性位点处缓慢的溶剂化动力学：对催化作用的影响。

Slow solvation dynamics at the active site of an enzyme: implications for catalysis.

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