具有生物技术应用潜力的细菌视紫红质突变体的产生和分析。

Generation and analysis of bacteriorhodopsin mutants with the potential for biotechnological applications.

机构信息

Faculty of Science, Department of Biology, Science and Research Branch, Islamic Azad University, Tehran, Iran.

出版信息

Bioengineered. 2012 Sep-Oct;3(5):275-9. doi: 10.4161/bioe.21048. Epub 2012 Sep 1.

DOI:10.4161/bioe.21048

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3477695/

Abstract

The properties of bacteriorhodopsin (BR) can be manipulated by genetic engineering. Therefore, by the methods of gene engineering, Asp85 was replaced individually by two other amino acids (D85V, D85S). The resulting recombinant proteins were assembled into soybean vesicles retinylated to form functional BR-like nano-particles. Proton translocation was almost completely abrogated by the mutant D85S, while the D85V mutant was partially active in pumping protons. Compared with wild type, maximum absorption of the mutants, D85V and D85S, were 563 and 609 nm, which illustrated 5 nm reductions (blue shift) and 41 nm increases (red shift), respectively. Since proton transport activity and spectroscopic activities of the mutants are different, a wide variety of membrane bioreactors (MBr) have been developed. Modified proteins can be utilized to produce unique photo/Electro-chromic materials and tools.

摘要

通过遗传工程可以操纵菌紫质（BR）的性质。因此，通过基因工程的方法，将 Asp85 分别替换为另外两种氨基酸（D85V、D85S）。所得重组蛋白被组装到大豆囊泡中，进行视黄酰化以形成功能性 BR 样纳米颗粒。突变体 D85S 几乎完全阻断质子转移，而 D85V 突变体在质子泵中具有部分活性。与野生型相比，突变体 D85V 和 D85S 的最大吸收峰分别为 563nm 和 609nm，分别减少了 5nm（蓝移）和增加了 41nm（红移）。由于突变体的质子传输活性和光谱活性不同，已经开发了各种各样的膜生物反应器（MBR）。改性蛋白可用于生产独特的光/电致变色材料和工具。

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