Stabilization of Bacillus circulans xylanase by combinatorial insertional fusion to a thermophilic host protein

Vandan Shah, B. Pierre, Tamari Kirtadze, Seung-Yeol Shin, J. Kim
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引用次数: 5

Abstract

High thermostability of an enzyme is critical for its industrial application. While many engineering approaches such as mutagenesis have enhanced enzyme thermostability, they often suffer from reduced enzymatic activity. A thermally stabilized enzyme with unchanged amino acids is preferable for subsequent functional evolution necessary to address other important industrial needs. In the research presented here, we applied insertional fusion to a thermophilic maltodextrin-binding protein from Pyrococcus furiosus (PfMBP) in order to improve the thermal stability of Bacillus circulans xylanase (BCX). Specifically, we used an engineered transposon to construct a combinatorial library of randomly inserted BCX into PfMBP. The library was then subjected to functional screening to identify successful PfMBP-BCX insertion complexes, PfMBP-BCX161 and PfMBP-BCX165, displaying substantially improved kinetic stability at elevated temperatures compared to unfused BCX and other controls. Results from subsequent characterizations were consistent with the view that lowered aggregation of BCX and reduced conformational flexibility at the termini was responsible for increased thermal stability. Our stabilizing approach neither sacrificed xylanase activity nor required changes in the BCX amino acid sequence. Overall, the current study demonstrated the benefit of combinatorial insertional fusion to PfMBP as a systematic tool for the creation of enzymatically active and thermostable BCX variants.
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通过与嗜热宿主蛋白的组合插入融合稳定环状芽孢杆菌木聚糖酶
酶的高热稳定性对其工业应用至关重要。虽然诱变等许多工程方法提高了酶的热稳定性,但它们往往会降低酶的活性。具有不变氨基酸的热稳定酶对于后续功能进化是必要的,以解决其他重要的工业需求。在本研究中,为了提高环状芽孢杆菌木聚糖酶(BCX)的热稳定性,我们对来自发热热球菌(PfMBP)的嗜热麦芽糊精结合蛋白进行了插入融合。具体来说,我们使用工程转座子构建了一个随机插入BCX到PfMBP中的组合文库。然后对该文库进行功能筛选,以确定成功的PfMBP-BCX插入复合物PfMBP-BCX161和PfMBP-BCX165,与未融合的BCX和其他对照相比,在高温下表现出显著提高的动力学稳定性。随后表征的结果与BCX聚集降低和末端构象柔韧性降低的观点一致,这是热稳定性增加的原因。我们的稳定方法既不牺牲木聚糖酶活性,也不需要改变BCX氨基酸序列。总的来说,目前的研究证明了PfMBP的组合插入融合作为创建酶活性和耐热性BCX变体的系统工具的好处。
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