Biomineralization of Magnetosomes: Billion-Year Evolution Shaping Modern Nanotools

Nanocrystals [Working Title] Pub Date : 2020-12-02 DOI:10.5772/intechopen.94465

Tarcisio Correa, Igor Nunes Taveira, Rogerio Presciliano de Souza Filho, Fernanda Abreu

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引用次数: 2

Abstract

Biomineralization in the microbial realm usually gives origin to finely structured inorganic nanomaterials. Perhaps, one of the most elegant bioinorganic processes found in nature is the iron biomineralization into magnetosomes, which is performed by magnetotactic bacteria. A magnetosome gene cluster within the bacterial genome precisely regulates the mineral synthesis. The spread and evolution of this ability among bacteria are thought to be a 2,7-billion-year process mediated by horizontal gene transfers. The produced magnetite or greigite nanocrystals coated by a biological membrane have a narrow diameter dispersibility, a highly precise morphology, and a permanent magnetic dipole due to the molecular level control. Approaches inspired by this bacterial biomineralization mechanism can imitate some of the biogenic nanomagnets characteristics in the chemical synthesis of iron oxide nanoparticles. Thus, this chapter will give a concise overview of magnetosome synthesis’s main steps, some hypotheses about the evolution of magnetosomes’ biomineralization, and approaches used to mimic this biological phenomenon in vitro.

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磁小体的生物矿化:十亿年的进化塑造了现代纳米工具

微生物领域的生物矿化作用通常产生结构精细的无机纳米材料。也许，自然界中发现的最优雅的生物无机过程之一是铁生物矿化到磁小体中，这是由趋磁细菌完成的。细菌基因组中的一个磁小体基因簇精确地调控着矿物质的合成。这种能力在细菌中的传播和进化被认为是一个27亿年的过程，由水平基因转移介导。制备的生物膜包裹的磁铁矿或灰长铁矿纳米晶体具有较窄的直径分散性，高度精确的形态，由于分子水平的控制，具有永久的磁偶极子。受这种细菌生物矿化机制启发的方法可以模仿氧化铁纳米颗粒化学合成中的一些生物源纳米磁体特征。因此，本章将简要概述磁小体合成的主要步骤，关于磁小体生物矿化进化的一些假设，以及用于体外模拟这一生物现象的方法。

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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Nanocrystals [Working Title]

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