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末端氨基酸会破坏木聚糖酶的热稳定性和活性。

Terminal amino acids disturb xylanase thermostability and activity.

机构信息

Life Science College, Henan Agricultural University, Zhengzhou 450002, China.

出版信息

J Biol Chem. 2011 Dec 30;286(52):44710-5. doi: 10.1074/jbc.M111.269753. Epub 2011 Nov 9.

DOI:10.1074/jbc.M111.269753
PMID:22072708
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3247970/
Abstract

Protein structure is composed of regular secondary structural elements (α-helix and β-strand) and non-regular region. Unlike the helix and strand, the non-regular region consists of an amino acid defined as a disordered residue (DR). When compared with the effect of the helix and strand, the effect of the DR on enzyme structure and function is elusive. An Aspergillus niger GH10 xylanase (Xyn) was selected as a model molecule of (β/α)(8) because the general structure consists of ~10% enzymes. The Xyn has five N-terminal DRs and one C-terminal DR, respectively, which were deleted to construct three mutants, XynΔN, XynΔC, and XynΔNC. Each mutant was ~2-, 3-, or 4-fold more thermostable and 7-, 4-, or 4-fold more active than the Xyn. The N-terminal deletion decreased the xylanase temperature optimum for activity (T(opt)) 6 °C, but the C-terminal deletion increased its T(opt) 6 °C. The N- and C-terminal deletions had opposing effects on the enzyme T(opt) but had additive effects on its thermostability. The five N-terminal DR deletions had more effect on the enzyme kinetics but less effect on its thermo property than the one C-terminal DR deletion. CD data showed that the terminal DR deletions increased regular secondary structural contents, and hence, led to slow decreased Gibbs free energy changes (ΔG(0)) in the thermal denaturation process, which ultimately enhanced enzyme thermostabilities.

摘要

蛋白质结构由规则的二级结构元件(α-螺旋和β-折叠)和不规则区域组成。与螺旋和链不同,不规则区域由氨基酸组成,定义为无序残基(DR)。与螺旋和链的影响相比,DR 对酶结构和功能的影响难以捉摸。选择黑曲霉 GH10 木聚糖酶(Xyn)作为(β/α)(8)的模型分子,因为一般结构由约 10%的酶组成。Xyn 有五个 N 端 DR 和一个 C 端 DR,分别缺失以构建三个突变体 XynΔN、XynΔC 和 XynΔNC。与 Xyn 相比,每个突变体的热稳定性分别提高了约 2、3 或 4 倍,活性提高了 7、4 或 4 倍。N 端缺失使木聚糖酶活性的最适温度(T(opt))降低了 6°C,但 C 端缺失使其 T(opt)升高了 6°C。N 和 C 端缺失对酶 T(opt)有相反的影响,但对其热稳定性有相加的影响。五个 N 端 DR 缺失对酶动力学的影响较大,但对其热性质的影响较小,而一个 C 端 DR 缺失对酶动力学的影响较小,但对其热性质的影响较大。CD 数据表明,末端 DR 缺失增加了规则的二级结构含量,从而导致在热变性过程中缓慢降低吉布斯自由能变化(ΔG(0)),最终提高了酶的热稳定性。

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