Rational design engineering of a more thermostable Sulfurihydrogenibium yellowstonense carbonic anhydrase for potential application in carbon dioxide capture technologies

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2023-09-15 DOI:10.1016/j.bbapap.2023.140962

Shima Ghaedizadeh , Majid Zeinali , Bahareh Dabirmanesh , Behnam Rasekh , Khosrow Khajeh , Ali Mohammad Banaei-Moghaddam

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Abstract

Implementing hyperthermostable carbonic anhydrases into CO₂ capture and storage technologies in order to increase the rate of CO₂ absorption from the industrial flue gases is of great importance from technical and economical points of view. The present study employed a combination of in silico tools to further improve thermostability of a known thermostable carbonic anhydrase from Sulfurihydrogenibium yellowstonense. Experimental results showed that our rationally engineered K100G mutant not only retained the overall structure and catalytic efficiency but also showed a 3 °C increase in the melting temperature and a two-fold improvement in the enzyme half-life at 85 °C. Based on the molecular dynamics simulation results, rearrangement of salt bridges and hydrogen interactions network causes a reduction in local flexibility of the K100G variant. In conclusion, our study demonstrated that thermostability can be improved through imposing local structural rigidity by engineering a single-point mutation on the surface of the enzyme.

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合理设计一种更耐热的硫氢黄石松碳酸酐酶，用于二氧化碳捕获技术的潜在应用。

从技术和经济的角度来看，将高温碳酸酐酶应用于CO2捕获和储存技术中以提高从工业烟气中吸收CO2的速率是非常重要的。本研究采用了多种硅内工具的组合，进一步提高了一种已知的来自黄石硫的耐热碳酸酐酶的热稳定性。实验结果表明，我们合理设计的K100G突变体不仅保留了整体结构和催化效率，而且在85°C时，融化温度提高了3°C，酶半衰期提高了两倍。基于分子动力学模拟结果，盐桥和氢相互作用网络的重排导致K100G变体的局部灵活性降低。总之，我们的研究表明，通过在酶表面设计单点突变，可以通过施加局部结构刚性来提高热稳定性。

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