3-Hydroxy-3-Methylglutaryl Synthases 催化多酮生物合成中 β-分支第一步的结构可塑性支撑了底物容纳的动态机制。

IF 8.5 Q1 CHEMISTRY, MULTIDISCIPLINARY JACS Au Pub Date : 2024-09-23 eCollection Date: 2024-10-28 DOI:10.1021/jacsau.4c00477
Sabrina Collin, Kira J Weissman, Arnaud Gruez
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引用次数: 0

摘要

了解酶是如何通过进化被重新利用以执行新功能的,是机理酶学的一个关键目标。在本研究中,我们旨在确定初级异戊二烯组装的 3-羟基-3-甲基戊二酰(HMG)-CoA 合酶(HMGCS)在专门的多酮生物合成途径中发挥作用所需的适应性,它们在该途径中启动了 β 支链。这种作用尤其要求 HMG 合成酶(HMGSs)作用于与非催化酰基载体蛋白(ACP)结构域而非辅酶 A 相连的底物,并在活性位点内容纳更大的链。在这里,我们使用 X 射线晶体学和小角 X 射线散射相结合的方法证明,维吉尼霉素系统中的模型 HMGS 与其特征 HMGCS 对应物相比,显示出明显增加的灵活性。这种灵活性包括多个二级结构元素,它们定义了活性位点的尺寸和化学性质,以及催化残基本身。鉴于 HMGS 在 HMGS/ACP 复合物中的有序性,这一结果出乎意料,但同步辐射圆二色性分析表明,这种相互作用导致 HMGS 折叠性增加。AlphaFold2 无法解释这种从柔性到刚性的转变,因为 AlphaFold2 得出的结构模型与原生底物的结合不相容。综上所述,这些结果表明,结合晶体学和溶液相数据的综合结构生物学方法对于阐明酶重塑的内在机制仍然十分必要,这些信息可以为在实验室中有效复制这种进化的策略提供依据。
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Structural Plasticity within 3-Hydroxy-3-Methylglutaryl Synthases Catalyzing the First Step of β-Branching in Polyketide Biosynthesis Underpins a Dynamic Mechanism of Substrate Accommodation.

Understanding how enzymes have been repurposed by evolution to carry out new functions is a key goal of mechanistic enzymology. In this study we aimed to identify the adaptations required to allow the 3-hydroxy-3-methylglutaryl (HMG)-CoA synthase (HMGCS) enzymes of primary isoprenoid assembly to function in specialized polyketide biosynthetic pathways, where they initiate β-branching. This role notably necessitates that the HMG synthases (HMGSs) act on substrates tethered to noncatalytic acyl carrier protein (ACP) domains instead of coenzyme A, and accommodation of substantially larger chains within the active sites. Here, we show using a combination of X-ray crystallography and small-angle X-ray scattering, that a model HMGS from the virginiamycin system exhibits markedly increased flexibility relative to its characterized HMGCS counterparts. This mobility encompasses multiple secondary structural elements that define the dimensions and chemical nature of the active site, as well the catalytic residues themselves. This result was unexpected given the well-ordered character of the HMGS within the context of an HMGS/ACP complex, but analysis by synchrotron radiation circular dichroism demonstrates that this interaction leads to increased HMGS folding. This flexible to more rigid transition is notably not accounted for by AlphaFold2, which yielded a structural model incompatible with binding of the native substrates. Taken together, these results illustrate the continued necessity of an integrative structural biology approach combining crystallographic and solution-phase data for elucidating the mechanisms underlying enzyme remodeling, information which can inform strategies to replicate such evolution effectively in the laboratory.

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