生产去甲金丝桃苷的生物合成-代谢混合途径

IF 4.4 3区 生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY
Bin Li, Jue Liang, Margaret A Phillips, Anthony J Michael
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引用次数: 0

摘要

多胺正链哌啶的唯一已知生物合成途径是从天冬氨酸β-半醛开始形成二胺 1,3-二氨基丙烷,然后通过羧基正链哌啶中间体转化为正链哌啶。这种途径主要存在于γ-蛋白质细菌的维布里尔菌目。然而,在其他种类的细菌和古细菌中,以及在各种单细胞真核生物、叶绿藻和植物中,也发现了去甲精胺,但它们没有编码已知的去甲精胺生物合成途径。我们推断,多胺分解产物可能是生产去甲肾上腺嘧啶的另一条途径。精胺和亚精胺的末端分解可形成 1,3-二氨基丙烷,热精胺的分解可形成去甲精胺。我们发现,单细胞叶绿藻莱茵衣藻热精胺合成酶(CrACL5)在大肠杆菌中表达时,不能有效地将外源的 1,3-二氨基丙烷氨丙基化。相反,它能将所有大肠杆菌原生精胺完全转化为热精胺。在大肠杆菌中同时表达来自狼尾草属植物 Selaginella lepidophylla 的多胺氧化酶 5(SelPAO5)和 CrACL5 热精胺合成酶,可将几乎所有的热精胺转化为去甲精胺。尽管 CrACL5 能有效地将去甲精胺氨丙基化,形成四胺去甲精胺,但 SelPAO5 会将去甲精胺氧化回去甲脒,通量的平衡完全倾向于去甲脒氧化。共同表达热精胺合成酶 CrACL5 和多胺氧化酶 SelPAO5 的大肠杆菌的稳态多胺含量几乎完全被去甲精胺取代。 我们重现了大肠杆菌中产生去甲精胺的潜在混合生物合成-代谢途径,这可以解释去甲精胺在不编码已知天冬氨酸β-半醛依赖途径的物种中的积累。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A hybrid biosynthetic-catabolic pathway for norspermidine production.

The only known pathway for biosynthesis of the polyamine norspermidine starts from aspartate β-semialdehyde to form the diamine 1,3-diaminopropane, which is then converted to norspermidine via a carboxynorspermidine intermediate. This pathway is found primarily in the Vibrionales order of the γ-Proteobacteria. However, norspermidine is also found in other species of bacteria and archaea, and in diverse single-celled eukaryotes, chlorophyte algae and plants that do not encode the known norspermidine biosynthetic pathway. We reasoned that products of polyamine catabolism could be an alternative route to norspermidine production. 1,3-diaminopropane is formed from terminal catabolism of spermine and spermidine, and norspermidine can be formed from catabolism of thermospermine. We found that the single-celled chlorophyte alga Chlamydomonas reinhardtii thermospermine synthase (CrACL5) did not aminopropylate exogenously-derived 1,3-diaminopropane efficiently when expressed in Escherichia coli. In contrast, it completely converted all E. coli native spermidine to thermospermine. Co-expression in E. coli of the polyamine oxidase 5 from lycophyte plant Selaginella lepidophylla (SelPAO5), together with the CrACL5 thermospermine synthase, converted almost all thermospermine to norspermidine. Although CrACL5 was efficient at aminopropylating norspermidine to form tetraamine norspermine, SelPAO5 oxidizes norspermine back to norspermidine, with the balance of flux being inclined fully to norspermine oxidation. The steady-state polyamine content of E. coli co-expressing thermospermine synthase CrACL5 and polyamine oxidase SelPAO5 was an almost total replacement of spermidine by norspermidine. We have recapitulated a potential hybrid biosynthetic-catabolic pathway for norspermidine production in E. coli, which could explain norspermidine accumulation in species that do not encode the known aspartate β-semialdehyde-dependent pathway.

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来源期刊
Biochemical Journal
Biochemical Journal 生物-生化与分子生物学
CiteScore
8.00
自引率
0.00%
发文量
255
审稿时长
1 months
期刊介绍: Exploring the molecular mechanisms that underpin key biological processes, the Biochemical Journal is a leading bioscience journal publishing high-impact scientific research papers and reviews on the latest advances and new mechanistic concepts in the fields of biochemistry, cellular biosciences and molecular biology. The Journal and its Editorial Board are committed to publishing work that provides a significant advance to current understanding or mechanistic insights; studies that go beyond observational work using in vitro and/or in vivo approaches are welcomed. Painless publishing: All papers undergo a rigorous peer review process; however, the Editorial Board is committed to ensuring that, if revisions are recommended, extra experiments not necessary to the paper will not be asked for. Areas covered in the journal include: Cell biology Chemical biology Energy processes Gene expression and regulation Mechanisms of disease Metabolism Molecular structure and function Plant biology Signalling
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