Catalytic Redundancies and Conformational Plasticity Drives Selectivity and Promiscuity in Quorum Quenching Lactonases

IF 8.5 Q1 CHEMISTRY, MULTIDISCIPLINARY
Marina Corbella, Joe Bravo, Andrey O. Demkiv, Ana Rita Calixto, Kitty Sompiyachoke, Celine Bergonzi, Alfie-Louise R. Brownless, Mikael H. Elias* and Shina Caroline Lynn Kamerlin*, 
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Abstract

Several enzymes from the metallo-β-lactamase-like family of lactonases (MLLs) degrade N-acyl L-homoserine lactones (AHLs). They play a role in a microbial communication system known as quorum sensing, which contributes to pathogenicity and biofilm formation. Designing quorum quenching (QQ) enzymes that can interfere with this communication allows them to be used in a range of industrial and biomedical applications. However, tailoring these enzymes for specific communication signals requires a thorough understanding of their mechanisms and the physicochemical properties that determine their substrate specificities. We present here a detailed biochemical, computational, and structural study of GcL, which is a highly proficient and thermostable MLL with broad substrate specificity. We show that GcL not only accepts a broad range of substrates but also hydrolyzes these substrates through at least two different mechanisms. Further, the preferred mechanism appears to depend on both the substrate structure and/or the nature of the residues lining the active site. We demonstrate that other lactonases, such as AiiA and AaL, show similar mechanistic promiscuity, suggesting that this is a shared feature among MLLs. Mechanistic promiscuity has been seen previously in the lactonase/paraoxonase PON1, as well as with protein tyrosine phosphatases that operate via a dual general acid mechanism. The apparent prevalence of this phenomenon is significant from both a biochemical and protein engineering perspective: in addition to optimizing for specific substrates, it may be possible to optimize for specific mechanisms, opening new doors not just for the design of novel quorum quenching enzymes but also of other mechanistically promiscuous enzymes.

Abstract Image

催化冗余和构象可塑性驱动了法定量淬灭乳酸菌酶的选择性和杂交性
金属-β-内酰胺酶样内酯酶家族(MLLs)中有几种酶能降解 N-酰基 L-高丝氨酸内酯(AHLs)。它们在称为 "法定人数感应 "的微生物通讯系统中发挥作用,而法定人数感应是致病性和生物膜形成的原因之一。设计出能够干扰这种交流的法定人数淬灭(QQ)酶,可将其用于一系列工业和生物医学应用。然而,要针对特定的通讯信号定制这些酶,就必须彻底了解它们的机制以及决定其底物特异性的理化特性。我们在此对 GcL 进行了详细的生物化学、计算和结构研究,GcL 是一种具有广泛底物特异性的高效恒温 MLL。我们发现 GcL 不仅能接受多种底物,还能通过至少两种不同的机制水解这些底物。此外,优先选择的机制似乎取决于底物结构和/或活性位点残基的性质。我们证明,其他内酯酶,如 AiiA 和 AaL,也表现出类似的机制杂乱性,这表明这是 MLLs 的共同特征。以前在内酯酶/paraoxonase PON1 以及通过双通式酸机制运作的蛋白酪氨酸磷酸酶中也曾出现过机理杂交现象。从生物化学和蛋白质工程学的角度来看,这种现象的明显普遍性具有重要意义:除了针对特定底物进行优化外,还有可能针对特定机制进行优化,这不仅为设计新型法定量淬灭酶打开了新的大门,也为设计其他机制杂乱的酶打开了新的大门。
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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来源期刊
CiteScore
9.10
自引率
0.00%
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审稿时长
10 weeks
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