Directed Evolution of Protein-Based Sensors for Anaerobic Biological Activation of Methane

Biosensors Pub Date : 2024-06-30 DOI:10.3390/bios14070325
Ehsan Bahrami Moghadam, Nam Nguyen, Yixi Wang, Patrick C. Cirino
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Abstract

Microbial alkane degradation pathways provide biological routes for converting these hydrocarbons into higher-value products. We recently reported the functional expression of a methyl-alkylsuccinate synthase (Mas) system in Escherichia coli, allowing for the heterologous anaerobic activation of short-chain alkanes. However, the enzymatic activation of methane via natural or engineered alkylsuccinate synthases has yet to be reported. To address this, we employed high-throughput screening to engineer the itaconate (IA)-responsive regulatory protein ItcR (WT-ItcR) from Yersinia pseudotuberculosis to instead respond to methylsuccinate (MS, the product of methane addition to fumarate), resulting in genetically encoded biosensors for MS. Here, we describe ItcR variants that, when regulating fluorescent protein expression in E. coli, show increased sensitivity, improved overall response, and enhanced specificity toward exogenously added MS relative to the wild-type repressor. Structural modeling and analysis of the ItcR ligand binding pocket provide insights into the altered molecular recognition. In addition to serving as biosensors for screening alkylsuccinate synthases capable of methane activation, MS-responsive ItcR variants also establish a framework for the directed evolution of other molecular reporters, targeting longer-chain alkylsuccinate products or other succinate derivatives.
基于蛋白质的甲烷厌氧生物活化传感器的定向进化
微生物烷烃降解途径提供了将这些碳氢化合物转化为高价值产品的生物途径。我们最近报道了大肠杆菌中甲基琥珀酸烷基合成酶(Mas)系统的功能表达,该系统可对短链烷烃进行异源厌氧活化。然而,通过天然或工程烷基琥珀酸合成酶对甲烷进行酶活化的研究尚未见报道。为了解决这个问题,我们利用高通量筛选技术,将来自假结核耶尔森菌的伊塔康酸(IA)反应调控蛋白 ItcR(WT-ItcR)改造成对琥珀酸甲酯(MS,甲烷加到富马酸中的产物)做出反应,从而产生了基因编码的琥珀酸甲酯生物传感器。在这里,我们描述了 ItcR 变体,与野生型抑制因子相比,这些变体在调节大肠杆菌中荧光蛋白的表达时,对外源添加的 MS 的灵敏度提高、总体响应改善、特异性增强。对 ItcR 配体结合袋的结构建模和分析为了解分子识别的改变提供了深入的见解。除了作为生物传感器用于筛选能够活化甲烷的烷基琥珀酸酯合成酶外,MS 响应的 ItcR 变体还为针对长链烷基琥珀酸酯产物或其他琥珀酸酯衍生物的其他分子报告器的定向进化建立了一个框架。
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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