Bridging the Gap in the Structure-Function Paradigm of Enzymatic PET Degradation-Aromatic Residue Driven Balanced Interactions with Catalytic and Anchoring Subsite.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
ACS Applied Bio Materials Pub Date : 2024-11-04 Epub Date: 2024-10-17 DOI:10.1002/cbic.202400555
Anjima James, Anjitha Bhasi, Susmita De
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引用次数: 0

Abstract

Understanding all parameters contributing to enzyme activity is crucial in enzyme catalysis. For enzymatic PET degradation, this involves examining the formation of the enzyme-PET complex. In IsPETase (WT), a PET-degrading enzyme from Ideonella sakaiensis, mutating two non-catalytic residues (DM) significantly enhances activity. Such mutations, depending on their position in the tertiary structure, fine-tune enzyme function. However, detailed molecular insights into these mutations' structure-function relationship for PET degradation are lacking. This study characterizes IsPETase's catalytic ability compared to WT TfCut2 using molecular dynamics simulations and quantum mechanical methods. We explore the conformational landscape of the enzyme-PET complex and quantify residue-wise interaction energy. Notably, aromatic and hydrophobic residues Tyr, Trp, and Ile in the catalytic subsite S1, and aromatic Phe and polar Asn in the anchoring subsite S3, crucially optimize PET binding. These residues enhance PET specificity over non-aromatic plastics. Our findings suggest that the balance between binding at subsite S1 and subsite S3, which is influenced by cooperative mutations, underlies catalytic activity. This balance shows a positive correlation with experimentally obtained kcat/Km values: WT TfCut2

弥合酶促 PET 降解结构-功能范式中的差距--芳香族残基与催化和锚定亚基的平衡相互作用。
了解有助于酶活性的所有参数对酶催化至关重要。对于酶降解 PET 来说,这涉及到研究酶-PET 复合物的形成。在 Ideonellasakaiensis 的 PET 降解酶 IsPETase(WT)中,突变两个非催化残基(DM)可显著提高其活性。这种突变根据其在三级结构中的位置,可以微调酶的功能。然而,关于这些突变在 PET 降解过程中的结构功能关系,还缺乏详细的分子见解。本研究利用分子动力学模拟和量子力学方法,描述了 IsPETase 与 WT TfCut2 相比的催化能力。我们探索了酶-PET 复合物的构象格局,并量化了残基方面的相互作用能。值得注意的是,催化位点 S1 中的芳香族和疏水残基 Tyr、Trp 和 Ile 以及锚定位点 S3 中的芳香族 Phe 和极性 Asn 对 PET 的结合起到了至关重要的优化作用。与非芳香族塑料相比,这些残基增强了 PET 的特异性。我们的研究结果表明,位点 S1 和位点 S3 之间的结合平衡受合作突变的影响,是催化活性的基础。这种平衡与实验获得的 kcat/Km 值呈正相关:WT TfCut2 < WT IsPETase
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
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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