Phenoxazinone synthase-like activity: Schiff base bound model complexes

IF 3.9 2区 化学 Q2 CHEMISTRY, PHYSICAL Molecular Catalysis Pub Date : 2024-09-20 DOI:10.1016/j.mcat.2024.114523
Poulami Koley , Bidyut Ghosh , Jyotipriyo Bhattacharyya , Alokesh Hazari
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Abstract

In order to get a better life, industrial revolution prevails worldwide since past few centuries but the rapid growth of industrialization in our planet invites different type of severe pollutions and hence environmental damage, which has now impacted on the survival of mankind. Although, the survival of mankind demands physical resourses but these are limited in quantity. In this problematic situation, biomimetics can be a solution. Biomimetics is the study which deals with nature and natural phenomenon to investigate the fundamental mechanisms, and afterwards to apply the concepts in the field of science, technology, and vastly in medical. In this present study, we look into one of the biomimetic enzymes, phenoxazinone synthase. Phenoxazinone synthase is an important class of enzyme that catalyzes the oxidation of o-aminophenol to aminophenoxazinone with the activation of molecular dioxygen. Bioinorganic chemists are largely influenced by the nature's design on phenoxazinone synthase and hence they are excited to synthesize this mimics model enzyme to understand the mechanistic pathways properly, so that they can explored its potential applications in the field of bioelectronics, material science, optoelectronics, and biomedical. In the literature, a significant number of Schiff base bound model complexes (about 126) for phenoxazinone synthase-like activity have been synthesized and catalytically characterized by different research groups. A variety of Schiff base ligands (about 68) are employed to prepare such model complexes with different nuclearities in presence of one or more 3d metals like V, Mn, Fe, Co, Ni, Cu and Zn in order to modulate the catalytic activity and to get a better structure property relationship on phenoxazinone synthase activity. This article aims to explore the recent advances, challenges, and opportunities in bioenzymatic catalysis, highlighting its promise to revolutionize the way we create value added compounds and materials.

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苯并噁嗪酮合成酶样活性:与希夫碱结合的模型复合物
为了过上更好的生活,过去几个世纪以来,工业革命在全球范围内盛行,但工业化在地球上的快速发展造成了不同类型的严重污染,进而对环境造成破坏,现在已经影响到人类的生存。虽然人类的生存需要物质资源,但这些资源的数量是有限的。在这种困难的情况下,生物仿生学不失为一种解决方案。生物仿生学是一门研究自然界和自然现象的学科,它研究自然界和自然现象的基本机制,然后将这些概念应用于科学、技术和医学领域。在本研究中,我们将研究生物仿生酶之一--苯并噁嗪酮合成酶。苯并噁嗪酮合成酶是一类重要的酶,在分子二氧的活化下催化邻氨基苯酚氧化为苯并噁嗪酮。生物无机化学家在很大程度上受到了大自然对苯并噁嗪酮合成酶设计的影响,因此他们热衷于合成这种模拟模型酶,以正确理解其机理途径,从而探索其在生物电子学、材料科学、光电子学和生物医学领域的潜在应用。在文献中,不同研究小组合成了大量具有类似苯并噁嗪酮合成酶活性的希夫碱结合模型配合物(约 126 个),并对其进行了催化表征。在一种或多种三维金属(如 V、Mn、Fe、Co、Ni、Cu 和 Zn)存在的情况下,采用多种希夫碱配体(约 68 种)制备具有不同核性的模型配合物,以调节催化活性并获得吩噁嗪酮合成酶活性的更好的结构属性关系。本文旨在探讨生物酶催化的最新进展、挑战和机遇,强调生物酶催化有望彻底改变我们创造高附加值化合物和材料的方式。
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来源期刊
Molecular Catalysis
Molecular Catalysis Chemical Engineering-Process Chemistry and Technology
CiteScore
6.90
自引率
10.90%
发文量
700
审稿时长
40 days
期刊介绍: Molecular Catalysis publishes full papers that are original, rigorous, and scholarly contributions examining the molecular and atomic aspects of catalytic activation and reaction mechanisms. The fields covered are: Heterogeneous catalysis including immobilized molecular catalysts Homogeneous catalysis including organocatalysis, organometallic catalysis and biocatalysis Photo- and electrochemistry Theoretical aspects of catalysis analyzed by computational methods
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