沙雷氏菌属几丁质酶 D 通过改变底物相互作用提高了转糖基化作用。

Transglycosylation by chitinase D from Serratia proteamaculans improved through altered substrate interactions.

机构信息

Department of Plant Sciences, School of Life Sciences, University of Hyderabad, Gachibowli, Hyderabad-500046, A.P., India.

出版信息

J Biol Chem. 2012 Dec 28;287(53):44619-27. doi: 10.1074/jbc.M112.400879. Epub 2012 Oct 31.

DOI:10.1074/jbc.M112.400879

PMID:23115231

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3531777/

Abstract

We describe the improvement of transglycosylation (TG) by chitinase D from Serratia proteamaculans (SpChiD). The SpChiD produced a smaller quantity of TG products for up to 90 min with 2 mm chitotetraose as the substrate and subsequently produced only hydrolytic products. Of the five residues targeted at the catalytic center, E159D resulted in substantial loss of both hydrolytic and TG activities. Y160A resulted in a product profile similar to SpChiD and a rapid turnover of substrate with slightly increased TG activity. The rest of the three mutants, M226A, Y228A, and R284A, displayed improved TG and decreased hydrolytic ability. Four of the five amino acid substitutions, F64W, F125A, G119S, and S116G, at the catalytic groove increased TG activity, whereas W120A completely lost the TG activity with a concomitant increase in hydrolysis. Mutation of Trp-247 at the solvent-accessible region significantly reduced the hydrolytic activity with increased TG activity. The mutants M226A, Y228A, F125A, S116G, F64W, G119S, R284A, and W247A accumulated approximately double the concentration of TG products like chitopentaose and chitohexaose, compared with SpChiD. The double mutant E159D/F64W regained the activity with accumulation of 6.0% chitopentaose at 6 h, similar to SpChiD at 30 min. Loss of chitobiase activity was unique to Y228A. Substitution of amino acids at the catalytic center and/or groove substantially improved the TG activity of SpChiD, both in terms of the quantity of TG products produced and the extended duration of TG activity.

摘要

我们描述了来自变形沙雷氏菌（Serratia proteamaculans）的几丁质酶 D（SpChiD）对转糖苷（TG）的改进。SpChiD 用 2mm 的壳四糖作为底物时，在长达 90 分钟的时间内产生的 TG 产物数量较少，随后只产生水解产物。在针对催化中心的五个残基中，E159D 导致水解和 TG 活性都大幅丧失。Y160A 导致产物谱与 SpChiD 相似，底物快速转化，TG 活性略有增加。其余三个突变体 M226A、Y228A 和 R284A 的 TG 活性提高，水解能力降低。五个催化沟氨基酸取代中的四个，F64W、F125A、G119S 和 S116G，提高了 TG 活性，而 W120A 完全失去了 TG 活性，同时水解增加。溶剂可及区域的色氨酸-247 突变显著降低了水解活性，同时增加了 TG 活性。突变体 M226A、Y228A、F125A、S116G、F64W、G119S、R284A 和 W247A 积累的 TG 产物（如壳五糖和壳六糖）的浓度约为 SpChiD 的两倍。双突变体 E159D/F64W 在 6 小时时恢复了活性，积累了 6.0%的壳五糖，与 30 分钟时的 SpChiD 相似。只有 Y228A 失去了壳二糖酶活性。催化中心和/或沟的氨基酸取代极大地提高了 SpChiD 的 TG 活性，无论是在产生的 TG 产物数量还是 TG 活性的延长时间方面。

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