嗜热苹果酸合成酶的预测结构

Shaelee Nielsen, Jantzen Orton, Bruce Howard
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摘要

本项目的目的是解决楔形芽孢杆菌(Sulfolobus acidocaldarius)苹果酸合成酶的结构问题。研究发现,其他已知的苹果酸合成酶的活性位点需要镁离子才能进行催化反应,但一项研究报告称,S. acidocaldarius 苹果酸合成酶不需要镁离子。这表明这种酶有一种新的机制。此外,成熟的 S. acidocaldarius 蛋白质比其他任何具有结构特征的苹果酸合成酶都要大约 100 个残基。据报道,它还能形成二聚体,而以前解决的结构只显示了单体、三聚体和六聚体排列。我们计划通过实验确定其结构。不过,DeepMind 开发的人工智能系统 AlphaFold 最近在蛋白质结构预测的准确性方面取得了重大进展,它彻底改变了这一领域,并在很大程度上解决了蛋白质折叠问题。华盛顿大学戴维-贝克实验室开发的类似人工智能系统 RoseTTAFold 也已公开发布。在这里,我们报告了对使用这两种算法预测的该蛋白质结构的分析,以及使用 ClusPro 预测的二聚形式酶的结构模型。我们的结果有力地支持了一种需要镁的保守催化机制,这与之前解决的所有苹果酸合成酶同工型是共通的。关键词: 乙醛酸循环;苹果酸合成酶;蛋白质预测;嗜热菌;Sulfolobus acidocaldarius;镁;AlphaFold;RoseTTAFold
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The Predicted Structure of a Thermophilic Malate Synthase
This project aims to solve the structure of the crenarchaeal Sulfolobus acidocaldarius enzyme malate synthase. Other known malate synthase enzymes have been found to require a magnesium ion in the active site to carry out catalytic activities, but a study reported that S. acidocaldarius malate synthase does not require magnesium. This suggests a novel mechanism for this enzyme. Additionally, the mature S. acidocaldarius protein is approximately 100 residues larger than any other structurally characterized malate synthase. It has also been reported to form a dimer, while previously solved structures have only displayed monomeric, trimeric, and hexameric arrangements. We plan to determine the structure experimentally. However, major advances in the accuracy of protein structure prediction were made recently by AlphaFold, an artificial intelligence system developed by DeepMind, which has revolutionized the field and has largely solved the protein folding problem. A similar AI system, RoseTTAFold, developed by David Baker’s lab at the University of Washington, has been publicly available. Here, we report our analysis of the structure of this protein, predicted using both of these algorithms and of a predicted structural model for the dimeric form of the enzyme using ClusPro. Our results strongly support a conserved catalytic mechanism requiring magnesium, which is common with all previously solved malate synthase isoforms. KEYWORDS: Glyoxylate Cycle; Malate synthase; Protein Prediction; Thermophile; Sulfolobus acidocaldarius; Magnesium; AlphaFold; RoseTTAFold
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