Increasing thermostability of the key photorespiratory enzyme glycerate 3-kinase by structure-based recombination

IF 10.1 1区 生物学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Ludmila V. Roze, Anna Antoniak, Daipayan Sarkar, Aaron H. Liepman, Mauricio Tejera-Nieves, Josh V. Vermaas, Berkley J. Walker
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Abstract

As global temperatures rise, improving crop yields will require enhancing the thermotolerance of crops. One approach for improving thermotolerance is using bioengineering to increase the thermostability of enzymes catalysing essential biological processes. Photorespiration is an essential recycling process in plants that is integral to photosynthesis and crop growth. The enzymes of photorespiration are targets for enhancing plant thermotolerance as this pathway limits carbon fixation at elevated temperatures. We explored the effects of temperature on the activity of the photorespiratory enzyme glycerate kinase (GLYK) from various organisms and the homologue from the thermophilic alga Cyanidioschyzon merolae was more thermotolerant than those from mesophilic plants, including Arabidopsis thaliana. To understand enzyme features underlying the thermotolerance of C. merolae GLYK (CmGLYK), we performed molecular dynamics simulations using AlphaFold-predicted structures, which revealed greater movement of loop regions of mesophilic plant GLYKs at higher temperatures compared to CmGLYK. Based on these simulations, hybrid proteins were produced and analysed. These hybrid enzymes contained loop regions from CmGLYK replacing the most mobile corresponding loops of AtGLYK. Two of these hybrid enzymes had enhanced thermostability, with melting temperatures increased by 6 °C. One hybrid with three grafted loops maintained higher activity at elevated temperatures. Whilst this hybrid enzyme exhibited enhanced thermostability and a similar Km for ATP compared to AtGLYK, its Km for glycerate increased threefold. This study demonstrates that molecular dynamics simulation-guided structure-based recombination offers a promising strategy for enhancing the thermostability of other plant enzymes with possible application to increasing the thermotolerance of plants under warming climates.
通过结构重组提高关键光呼吸酶甘油酸-3-激酶的耐热性
随着全球气温升高,要提高作物产量,就必须增强作物的耐热性。提高耐热性的一种方法是利用生物工程提高催化重要生物过程的酶的耐热性。光呼吸是植物的一个重要循环过程,与光合作用和作物生长密不可分。光呼吸的酶是提高植物耐热性的目标,因为这一途径限制了高温下的碳固定。我们探讨了温度对各种生物的光呼吸酶甘油酸激酶(GLYK)活性的影响,结果发现嗜热藻类 Cyanidioschyzon merolae 的同源物比中温植物(包括拟南芥)的同源物更耐高温。为了了解 C. merolae GLYK(CmGLYK)耐热性背后的酶特征,我们使用 AlphaFold 预测的结构进行了分子动力学模拟。在这些模拟的基础上,产生并分析了杂交蛋白。这些杂交酶含有来自 CmGLYK 的环区,取代了 AtGLYK 流动性最强的相应环区。其中两种杂交酶的热稳定性增强,熔化温度提高了 6 °C。一种具有三个接枝环的杂交酶在高温下保持较高的活性。与 AtGLYK 相比,这种杂交酶的耐热性增强,对 ATP 的 Km 值相似,但对甘油酸的 Km 值增加了三倍。这项研究表明,分子动力学模拟指导下的基于结构的重组为提高其他植物酶的耐热性提供了一种有前途的策略,有可能应用于提高植物在气候变暖条件下的耐热性。
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来源期刊
Plant Biotechnology Journal
Plant Biotechnology Journal 生物-生物工程与应用微生物
CiteScore
20.50
自引率
2.90%
发文量
201
审稿时长
1 months
期刊介绍: Plant Biotechnology Journal aspires to publish original research and insightful reviews of high impact, authored by prominent researchers in applied plant science. The journal places a special emphasis on molecular plant sciences and their practical applications through plant biotechnology. Our goal is to establish a platform for showcasing significant advances in the field, encompassing curiosity-driven studies with potential applications, strategic research in plant biotechnology, scientific analysis of crucial issues for the beneficial utilization of plant sciences, and assessments of the performance of plant biotechnology products in practical applications.
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