New insights into the substrate specificity of cholesterol oxidases for more aware application

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Michail Shapira , Alexandra Dobysh , Anastasia Liaudanskaya , Hanna Aucharova , Yaraslau Dzichenka , Volha Bokuts , Suzana Jovanović-Šanta , Aliaksey Yantsevich
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Abstract

Cholesterol oxidases (ChOxes) are enzymes that catalyze the oxidation of cholesterol to cholest-4-en-3-one. These enzymes find wide applications across various diagnostic and industrial settings. In addition, as a pathogenic factor of several bacteria, they have significant clinical implications. The current classification system for ChOxes is based on the type of bond connecting FAD to the apoenzyme, which does not adequately illustrate the enzymatic and structural characteristics of these proteins. In this study, we have adopted an integrative approach, combining evolutionary analysis, classic enzymatic techniques and computational approaches, to elucidate the distinct features of four various ChOxes from Rhodococcus sp. (RCO), Cromobacterium sp. (CCO), Pseudomonas aeruginosa (PCO) and Burkhoderia cepacia (BCO). Comparative and evolutionary analysis of substrate-binding domain (SBD) and FAD-binding domain (FBD) helped to reveal the origin of ChOxes. We discovered that all forms of ChOxes had a common ancestor and that the structural differences evolved later during divergence. Further examination of amino acid variations revealed SBD as a more variable compared to FBD independently of FAD coupling mechanism. Revealed differences in amino acid positions turned out to be critical in determining common for ChOxes properties and those that account for the individual differences in substrate specificity. A novel look with the help of chemical descriptors on found distinct features were sufficient to attempt an alternative classification system aimed at application approach. While univocal characteristics necessary to establish such a system remain elusive, we were able to demonstrate the substrate and protein features that explain the differences in substrate profile.

Abstract Image

Abstract Image

对胆固醇氧化酶底物特异性的新认识,以提高应用意识
胆固醇氧化酶(ChOxes)是催化胆固醇氧化成胆固醇-4-烯-3-酮的酶。这些酶在各种诊断和工业环境中应用广泛。此外,作为几种细菌的致病因子,它们还具有重要的临床意义。目前的氧化胆固醇酶分类系统是基于连接 FAD 与载脂蛋白酶的键的类型,这并不能充分说明这些蛋白质的酶学和结构特征。在本研究中,我们采用了一种综合方法,结合进化分析、经典酶学技术和计算方法,阐明了来自 Rhodococcus sp.(RCO)、Cromobacterium sp.(CCO)、Pseudomonas aeruginosa(PCO)和 Burkhoderia cepacia(BCO)的四种 ChOxes 的不同特征。底物结合结构域(SBD)和 FAD 结合结构域(FBD)的比较和进化分析有助于揭示 ChOxes 的起源。我们发现,所有形式的 ChOxes 都有一个共同的祖先,结构上的差异是后来在分化过程中演化出来的。对氨基酸变异的进一步研究发现,与 FAD 耦合机制无关,SBD 与 FBD 相比变异更大。所发现的氨基酸位置差异被证明是决定 ChOxes 特性共性的关键,也是造成底物特异性个体差异的关键。在化学描述符的帮助下,对所发现的不同特征进行新颖的观察,足以尝试一种针对应用方法的替代分类系统。虽然建立这样一个系统所需的明确特征仍然难以确定,但我们能够证明底物和蛋白质特征可以解释底物特征的差异。
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
7.20
自引率
4.30%
发文量
567
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