In silico design of multipoint mutants for enhanced performance of Thermomyces lanuginosus lipase for efficient biodiesel production

IF 6.1 1区工程技术 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Biotechnology for Biofuels Pub Date : 2024-02-24 DOI:10.1186/s13068-024-02478-5

Jinsha Huang, Xiaoman Xie, Wanlin Zheng, Li Xu, Jinyong Yan, Ying Wu, Min Yang, Yunjun Yan

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Abstract

Background

Biodiesel, an emerging sustainable and renewable clean energy, has garnered considerable attention as an alternative to fossil fuels. Although lipases are promising catalysts for biodiesel production, their efficiency in industrial-scale application still requires improvement.

Results

In this study, a novel strategy for multi-site mutagenesis in the binding pocket was developed via FuncLib (for mutant enzyme design) and Rosetta Cartesian_ddg (for free energy calculation) to improve the reaction rate and yield of lipase-catalyzed biodiesel production. Thermomyces lanuginosus lipase (TLL) with high activity and thermostability was obtained using the Pichia pastoris expression system. The specific activities of the mutants M11 and M21 (each with 5 and 4 mutations) were 1.50- and 3.10-fold higher, respectively, than those of the wild-type (wt–TLL). Their corresponding melting temperature profiles increased by 10.53 and 6.01 °C, \(T_{50}^{15}\) (the temperature at which the activity is reduced to 50% after 15 min incubation) increased from 60.88 to 68.46 °C and 66.30 °C, and the optimum temperatures shifted from 45 to 50 °C. After incubation in 60% methanol for 1 h, the mutants M11 and M21 retained more than 60% activity, and 45% higher activity than that of wt–TLL. Molecular dynamics simulations indicated that the increase in thermostability could be explained by reduced atomic fluctuation, and the improved catalytic properties were attributed to a reduced binding free energy and newly formed hydrophobic interaction. Yields of biodiesel production catalyzed by mutants M11 and M21 for 48 h at an elevated temperature (50 °C) were 94.03% and 98.56%, respectively, markedly higher than that of the wt–TLL (88.56%) at its optimal temperature (45 °C) by transesterification of soybean oil.

Conclusions

An integrating strategy was first adopted to realize the co-evolution of catalytic efficiency and thermostability of lipase. Two promising mutants M11 and M21 with excellent properties exhibited great potential for practical applications for in biodiesel production.

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硅学设计多点突变体，提高兰氏热霉菌脂肪酶的性能，以高效生产生物柴油。

背景：生物柴油是一种新兴的可持续和可再生的清洁能源，作为化石燃料的替代品已引起广泛关注。尽管脂肪酶是生物柴油生产的理想催化剂，但其在工业规模应用中的效率仍有待提高：结果：本研究通过 FuncLib（用于突变酶设计）和 Rosetta Cartesian_ddg（用于自由能计算）开发了一种在结合袋中进行多位点突变的新策略，以提高脂肪酶催化生物柴油生产的反应速率和产量。利用 Pichia pastoris 表达系统获得了具有高活性和热稳定性的热霉菌脂肪酶（TLL）。突变体 M11 和 M21（分别有 5 个和 4 个突变）的比活性分别是野生型（wt-TLL）的 1.50 倍和 3.10 倍。它们相应的熔融温度曲线分别升高了 10.53 和 6.01 °C，[计算公式：见正文]（孵育 15 分钟后活性降低到 50%的温度）从 60.88 °C升高到 68.46 °C和 66.30 °C，最适温度从 45 °C升高到 50 °C。在 60% 的甲醇中孵育 1 小时后，突变体 M11 和 M21 的活性保持在 60% 以上，比 wt-TLL 的活性高 45%。分子动力学模拟表明，热稳定性的提高可归因于原子波动的减少，而催化性能的改善则归因于结合自由能的降低和新形成的疏水相互作用。突变体 M11 和 M21 在高温（50 °C）下催化生物柴油生产 48 小时的产量分别为 94.03% 和 98.56%，明显高于 wt-TLL 在最佳温度（45 °C）下通过酯交换大豆油生产生物柴油的产量（88.56%）：首先采用了一种整合策略来实现脂肪酶催化效率和耐热性的共同进化。M11和M21这两个突变体具有优异的性能，在生物柴油生产中具有巨大的实际应用潜力。

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来源期刊

Biotechnology for Biofuels 工程技术-生物工程与应用微生物

自引率

0.00%

发文量

审稿时长

2.7 months

期刊介绍： Biotechnology for Biofuels is an open access peer-reviewed journal featuring high-quality studies describing technological and operational advances in the production of biofuels, chemicals and other bioproducts. The journal emphasizes understanding and advancing the application of biotechnology and synergistic operations to improve plants and biological conversion systems for the biological production of these products from biomass, intermediates derived from biomass, or CO2, as well as upstream or downstream operations that are integral to biological conversion of biomass. Biotechnology for Biofuels focuses on the following areas: • Development of terrestrial plant feedstocks • Development of algal feedstocks • Biomass pretreatment, fractionation and extraction for biological conversion • Enzyme engineering, production and analysis • Bacterial genetics, physiology and metabolic engineering • Fungal/yeast genetics, physiology and metabolic engineering • Fermentation, biocatalytic conversion and reaction dynamics • Biological production of chemicals and bioproducts from biomass • Anaerobic digestion, biohydrogen and bioelectricity • Bioprocess integration, techno-economic analysis, modelling and policy • Life cycle assessment and environmental impact analysis