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真核生物的 MEP 途径基因是进化保守的,起源于衣原体和蓝细菌。

The eukaryotic MEP-pathway genes are evolutionarily conserved and originated from Chlaymidia and cyanobacteria.

机构信息

Institute for Integrative Genome Biology and Department of Botany and Plant Sciences, University of California, Riverside, CA, 92521, USA.

出版信息

BMC Genomics. 2021 Feb 26;22(1):137. doi: 10.1186/s12864-021-07448-x.

DOI:10.1186/s12864-021-07448-x
PMID:33637041
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7912892/
Abstract

BACKGROUND

Isoprenoids are the most ancient and essential class of metabolites produced in all organisms, either via mevalonate (MVA)-and/or methylerythritol phosphate (MEP)-pathways. The MEP-pathway is present in all plastid-bearing organisms and most eubacteria. However, no comprehensive study reveals the origination and evolutionary characteristics of MEP-pathway genes in eukaryotes.

RESULTS

Here, detailed bioinformatics analyses of the MEP-pathway provide an in-depth understanding the evolutionary history of this indispensable biochemical route, and offer a basis for the co-existence of the cytosolic MVA- and plastidial MEP-pathway in plants given the established exchange of the end products between the two isoprenoid-biosynthesis pathways. Here, phylogenetic analyses establish the contributions of both cyanobacteria and Chlamydiae sequences to the plant's MEP-pathway genes. Moreover, Phylogenetic and inter-species syntenic block analyses demonstrate that six of the seven MEP-pathway genes have predominantly remained as single-copy in land plants in spite of multiple whole-genome duplication events (WGDs). Substitution rate and domain studies display the evolutionary conservation of these genes, reinforced by their high expression levels. Distinct phenotypic variation among plants with reduced expression levels of individual MEP-pathway genes confirm the indispensable function of each nuclear-encoded plastid-targeted MEP-pathway enzyme in plant growth and development.

CONCLUSION

Collectively, these findings reveal the polyphyletic origin and restrict conservation of MEP-pathway genes, and reinforce the potential function of the individual enzymes beyond production of the isoprenoids intermediates.

摘要

背景

异戊烯基是所有生物产生的最古老和最基本的代谢物类别,无论是通过甲羟戊酸(MVA)-和/或甲基赤藓醇磷酸(MEP)途径。MEP 途径存在于所有含有质体的生物和大多数真细菌中。然而,没有全面的研究揭示真核生物 MEP 途径基因的起源和进化特征。

结果

这里,对 MEP 途径的详细生物信息学分析深入了解了这一必不可少的生化途径的进化历史,并为植物细胞溶质 MVA 和质体 MEP 途径的共存提供了基础,因为已经建立了这两种异戊烯生物合成途径之间的终产物的交换。在这里,系统发育分析确定了蓝细菌和衣原体序列对植物 MEP 途径基因的贡献。此外,系统发育和种间同线性块分析表明,尽管发生了多次全基因组复制事件(WGD),但在陆地植物中,七个 MEP 途径基因中的六个主要保持为单拷贝。取代率和结构域研究显示这些基因的进化保守性,其高表达水平得到了加强。具有单个 MEP 途径基因表达水平降低的植物之间的明显表型变异证实了每个核编码的质体靶向 MEP 途径酶在植物生长和发育中的不可或缺的功能。

结论

总之,这些发现揭示了 MEP 途径基因的多系起源和限制保守性,并强化了单个酶除了产生异戊烯中间体外的潜在功能。

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