氧化短小杆菌 GH49 支链淀粉酶的晶体结构：催化碱的鉴定和基于 B 因子的半理性设计对热稳定性的改善。

Crystal Structure of GH49 Dextranase from Arthrobacter oxidans KQ11: Identification of Catalytic Base and Improvement of Thermostability Using Semirational Design Based on B-Factors.

机构信息

Jiangsu Provincial Key Laboratory of Marine Biology, College of Resources and Environmental Sciences , Nanjing Agricultural University , Nanjing , Jiangsu 210095 , People's Republic of China.

出版信息

J Agric Food Chem. 2019 Apr 17;67(15):4355-4366. doi: 10.1021/acs.jafc.9b01290. Epub 2019 Apr 3.

DOI:10.1021/acs.jafc.9b01290

PMID:30919632

Abstract

The crystal structure of Dextranase from the marine bacterium Arthrobacter oxidans KQ11 (Aodex) was determined at a resolution of 1.4 Å. The crystal structure of the conserved Aodex fragment (Ala52-Thr638) consisted of an N-terminal domain N and a C-terminal domain C. The N-terminal domain N was identified as a β-sandwich, connected to a right-handed parallel β-helix at the C-terminus. Sequence comparisons, cavity regions, and key residues of the catalytic domain analysis all suggested that the Aodex was an inverting enzyme, and the catalytic acid and base were Asp439 and Asp420, respectively. Asp440 was not a general base in the Aodex catalytic domain, and Asp396 in Dex49A may not be a general base in the catalytic domain. The thermostability of the S357F mutant using semirational design based on B-factors was clearly better than that of wild-type Aodex. This process may promote the aromatic-aromatic interactions that increase the thermostability of mutant Phe357.

摘要

海洋细菌节杆菌（Arthrobacter oxidans KQ11）来源的右旋糖酐酶的晶体结构在 1.4 Å 的分辨率下被确定。保守的 Aodex 片段（Ala52-Thr638）的晶体结构由一个 N 端结构域 N 和一个 C 端结构域 C 组成。N 端结构域 N 被鉴定为一个β-sandwich，在 C 端与右手平行β-螺旋相连。序列比较、腔区和催化结构域的关键残基分析均表明 Aodex 是一种反转酶，催化酸和碱分别为 Asp439 和 Asp420。Asp440 不是 Aodex 催化结构域中的一般碱，而 Dex49A 中的 Asp396 在催化结构域中可能也不是一般碱。基于 B 因子的半理性设计，S357F 突变体的耐热性明显优于野生型 Aodex。这一过程可能促进了增加突变体 Phe357 耐热性的芳香族-芳香族相互作用。

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氧化短小杆菌 GH49 支链淀粉酶的晶体结构：催化碱的鉴定和基于 B 因子的半理性设计对热稳定性的改善。

Crystal Structure of GH49 Dextranase from Arthrobacter oxidans KQ11: Identification of Catalytic Base and Improvement of Thermostability Using Semirational Design Based on B-Factors.

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