Supercharged Phosphotriesterase for improved Paraoxon activity

Protein Engineering, Design and Selection Pub Date : 2024-09-18 DOI:10.1093/protein/gzae015

Jacob Kronenberg, Dustin Britton, Leif Halvorsen, Stanley Chu, Maria Jinu Kulapurathazhe, Jason Chen, Ashwitha Lakshmi, P Douglas Renfrew, Richard Bonneau, Jin Kim Montclare

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Abstract

Phosphotriesterases (PTEs) represent a class of enzymes capable of efficient neutralization of organophosphates (OPs), a dangerous class of neurotoxic chemicals. PTEs suffer from low catalytic activity, particularly at higher temperatures, due to low thermostability and low solubility. Supercharging, a protein engineering approach via selective mutation of surface residues to charged residues, has been successfully employed to generate proteins with increased solubility and thermostability by promoting charge–charge repulsion between proteins. We set out to overcome the challenges in improving PTE activity against OPs by employing a computational protein supercharging algorithm in Rosetta. Here, we discover two supercharged PTE variants, one negatively supercharged (with −14 net charge) and one positively supercharged (with +12 net charge) and characterize them for their thermostability and catalytic activity. We find that positively supercharged PTE possesses slight but significant losses in thermostability, which correlates to losses in catalytic efficiency at all temperatures, whereas negatively supercharged PTE possesses increased catalytic activity across 25°C – 55°C while offering similar thermostability characteristic to the parent PTE. The impact of supercharging on catalytic efficiency will inform the design of shelf-stable PTE and criteria for enzyme engineering.

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增压磷酸酯酶可提高副氧自由基的活性

磷酸三酯酶（PTEs）是一类能够有效中和有机磷酸酯（OPs）的酶，OPs 是一类危险的神经毒性化学品。由于热稳定性低和溶解度低，PTEs 的催化活性较低，尤其是在较高温度下。超充电（Supercharging）是一种蛋白质工程方法，通过选择性地将表面残基突变为带电残基，促进蛋白质之间的电荷排斥，从而成功地生成具有更高溶解度和耐热性的蛋白质。我们在 Rosetta 中采用了一种计算蛋白质增重算法，以克服在提高 PTE 对 OPs 的活性方面所面临的挑战。在这里，我们发现了两种超电荷 PTE 变体，一种是负超电荷（净电荷为 -14），另一种是正超电荷（净电荷为 +12），并对它们的耐热性和催化活性进行了表征。我们发现，正向增压的 PTE 在热稳定性方面有轻微但显著的损失，这与在所有温度下催化效率的损失有关，而负向增压的 PTE 在 25°C - 55°C 范围内的催化活性有所提高，同时具有与母体 PTE 相似的热稳定性特征。增压对催化效率的影响将为设计货架稳定的 PTE 和酶工程标准提供参考。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Protein Engineering, Design and Selection

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