Cold adaptation of a psychrophilic chitinase: a mutagenesis study.

Protein engineering Pub Date : 2003-07-01 DOI:10.1093/protein/gzg069

K Mavromatis, G Feller, M Kokkinidis, V Bouriotis

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引用次数: 27

Abstract

The gene encoding chitinase ArChiB from the Antarctic Arthrobacter sp. TAD20 has been expressed in Escherichia coli and the recombinant enzyme purified to homogeneity. In an effort to engineer cold-adapted biocatalysts through rational redesign to operate at elevated temperatures, we performed several mutations aiming to increase the rigidity of the molecular edifice of the selected psychrophilic chitinase. The mutations were designed on the basis of a homology-based three-dimensional model of the enzyme, and included an attempt to introduce a salt bridge (mutant N198K) and replacements of selected Gly residues by either Pro (mutants G93P, G254P) or Gln (G406Q). Mutant N198K resulted in a more stable protein (DeltaTm = 0.6 degrees C). Mutant G93P exhibited a DeltaTm of 1.2 degrees C, while mutants G254P and G406Q exhibited decreased stability. We conclude that the effect of mutating Gly residues on enzyme stability is rather complex and can only be understood in the context of the structural environment. Kinetic and spectroscopic analysis of these enzyme variants revealed that the kinetic parameters kcat and Km have been significantly modified.

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嗜冷几丁质酶的冷适应性:诱变研究。

在大肠杆菌中表达了南极节杆菌TAD20几丁质酶ArChiB的基因，并对重组酶进行了纯化。为了通过合理的重新设计来设计适应寒冷的生物催化剂，使其在高温下工作，我们进行了几次突变，旨在增加所选的嗜冷几丁质酶的分子结构的刚性。这些突变是基于酶的同源性三维模型设计的，包括尝试引入盐桥(突变体N198K)和用Pro(突变体G93P、G254P)或Gln (G406Q)替换选定的Gly残基。突变体N198K产生了更稳定的蛋白(δ tatm = 0.6℃)，突变体G93P的δ tatm为1.2℃，而突变体G254P和G406Q的稳定性下降。我们得出结论，突变Gly残基对酶稳定性的影响是相当复杂的，只能在结构环境的背景下理解。对这些酶的动力学和光谱分析表明，这些酶的动力学参数kcat和Km发生了显著的变化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Protein engineering

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