细菌锰超氧化物歧化酶的关系、结构多样性及其在治疗和化妆品中的应用策略

Microbiology Indonesia Pub Date : 2022-01-26 DOI:10.5454/mi.15.4.2

D. Retnoningrum, A. .. Artarini, W. Ismaya, Abykhair Muhammad, Muhammad D. Fadilah, R. A. Utami

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引用次数: 1

摘要

细菌中锰超氧化物歧化酶(MnSOD)具有较高的氨基酸序列同源性和几乎相同的结构。尽管如此，它们的特征是多种多样的，这可能是由于它们的细菌起源和对环境的适应。最重要的是，它们的结构相似性延伸到真核MnSOD，即人类。因此，细菌MnSOD的结构研究与其人类SOD的结构相关，并将其作为一种治疗剂或化妆品成分用于人类。此外，真核生物的MnSOD是四聚体，而几乎所有的原核生物都是二聚体。本文就MnSOD的氨基酸序列与结构的关系及其起源和演化进行了综述。比较了MnSOD最接近的同源物FeSOD和形生型SOD的结构。该研究为细菌MnSOD的潜在安全应用提供了见解，包括必要的修饰以获得用于人体的所需特性。

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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Relationship and structural diversity of bacterial manganese superoxide dismutases and the strategy for its application in therapy and cosmetics

Manganese superoxide dismutase (MnSOD) from bacteria shares high amino acid sequence homology and nearly identical structure. Despite of that, their characteristics are diverse, which likely due to their bacterial origin and adaptation to the environment. Most importantly, their structural similarity extends to eukaryotic MnSOD, i.e. human. Therefore, structural study of bacterial MnSOD is relevant to its human SOD and henceforth for its use in human as a therapeutic agent or a cosmetic ingredient. Further, eukaryotic MnSOD occurs as a tetramer while almost all of the prokaryotic are dimeric. In this review, relationship between the amino acid sequences and structures of MnSOD as well as their origin and evolution is discussed. The structures of FeSOD and cambialistic SOD, which are MnSOD closest homologs, are visited as the comparison. This study provides an insight to potential safe application of bacterial MnSOD, including necessary modifications to obtain desired characteristics for applications in human.

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Microbiology Indonesia

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