大肠杆菌超延伸古菌膜脂人工合成途径的构建。

IF 2.6 Q2 BIOCHEMICAL RESEARCH METHODS Synthetic biology (Oxford, England) Pub Date : 2020-09-30 eCollection Date: 2020-01-01 DOI:10.1093/synbio/ysaa018
Ryo Yoshida, Hisashi Hemmi
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引用次数: 0

摘要

古细菌产生独特的膜脂,它具有两个完全饱和的类异戊二烯链,通过醚键与甘油部分相连。古细菌膜脂的类异戊二烯链长度被认为是古细菌在极端环境中生存的重要因素,因为超嗜热古细菌Aeropyrum pernix和一些嗜盐古细菌合成了延长的C25,C25-古细菌二醚型膜脂,其类异戊二烯链比典型的C20,C20-二醚类膜脂长。然而,具有较长C30或C35类异戊二烯链的天然古细菌二醚脂质尚未被分离出来。在本研究中,我们试图合成这种超延伸古菌膜脂。我们研究了在C25,C25-古细菌膜脂生物合成途径中催化C25第二类异戊二烯链向甘油部分转移的n-2,3-(二戊二酰法尼基)甘油-1-磷酸合成酶对底物的偏好。该酶可接受具有C30类异戊二烯链的sn-3-六戊烯基甘油-1-磷酸作为戊烯基受体底物,合成sn-2-香叶基法尼基-3-六戊烯基甘油-1-磷酸,这被认为是超延伸C25、C30古细菌膜脂的前体。此外,我们将枯草芽孢杆菌的4个古菌基因和1个基因导入大肠杆菌细胞,构建了人工生物合成途径,使大肠杆菌产生了超延伸的C25、c30 -古菌膜脂,这是迄今为止未见报道的。
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Construction of an artificial biosynthetic pathway for hyperextended archaeal membrane lipids in the bacterium Escherichia coli.

Archaea produce unique membrane lipids, which possess two fully saturated isoprenoid chains linked to the glycerol moiety via ether bonds. The isoprenoid chain length of archaeal membrane lipids is believed to be important for some archaea to thrive in extreme environments because the hyperthermophilic archaeon Aeropyrum pernix and some halophilic archaea synthesize extended C25,C25-archaeal diether-type membrane lipids, which have isoprenoid chains that are longer than those of typical C20,C20-diether lipids. Natural archaeal diether lipids possessing longer C30 or C35 isoprenoid chains, however, have yet to be isolated. In the present study, we attempted to synthesize such hyperextended archaeal membrane lipids. We investigated the substrate preference of the enzyme sn-2,3-(digeranylfarnesyl)glycerol-1-phosphate synthase from A. pernix, which catalyzes the transfer of the second C25 isoprenoid chain to the glycerol moiety in the biosynthetic pathway of C25,C25-archaeal membrane lipids. The enzyme was shown to accept sn-3-hexaprenylglycerol-1-phosphate, which has a C30 isoprenoid chain, as a prenyl acceptor substrate to synthesize sn-2-geranylfarnesyl-3-hexaprenylglycerol-1-phosphate, a supposed precursor for hyperextended C25,C30-archaeal membrane lipids. Furthermore, we constructed an artificial biosynthetic pathway by introducing 4 archaeal genes and 1 gene from Bacillus subtilis in the cells of Escherichia coli, which enabled the E. coli strain to produce hyperextended C25,C30-archaeal membrane lipids, which have never been reported so far.

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