Hajieghrari Behzad, Farrokhi Naser, Kamalizadeh Mojahed
Department of Agricultural Biotechnology, College of Agriculture, Jahrom University, Jahrom, Iran.
Department of Cell & Molecular Biology, Faculty of Life Sciences & Biotechnology, Shahid Beheshti University, Evin, Tehran, Iran.
J Genet Eng Biotechnol. 2022 Jul 12;20(1):103. doi: 10.1186/s43141-022-00380-x.
Small RNAs (sRNAs) that do not get untranslated into proteins exhibit a pivotal role in the expression regulation of their cognate gene(s) in almost all eukaryotic lineages, including plants. Hitherto, numerous protein families such as Dicer, a unique class of Ribonuclease III, have been reported to be involved in sRNAs processing pathways and silencing. In this study, we aimed to investigate the phylogenetic relationship and evolutionary history of the DCL protein family.
Our results illustrated the DCL family of proteins grouped into four main subfamilies (DCLs 1-4) presented in either Eudicotyledons or Liliopsids. The accurate observation of the phylogenetic trees supports the independent expansion of DCL proteins among the Eudicotyledons and Liliopsids species. They share the common origin, and the main duplication events for the formation of the DCL subfamilies occurred before the Eudicotyledons/Liliopsids split from their ancestral DCL. In addition, shreds of evidence revealed that the divergence happened when multicellularization started and since the need for complex gene regulation considered being a necessity by organisms. At that time, they have evolved independently among the monophyletic lineages. The other finding was that the combination of DCL protein subfamilies bears several highly conserved functional domains in plant species that originated from their ancestor architecture. The conservation of these domains happens to be both lineage-specific and inter lineage-specific.
DCL subfamilies (i.e., DCL1-DCL4) distribute in their single clades after diverging from their common ancestor and before emerging into higher plants. Therefore, it seems that the main duplication events for the formation of the DCL subfamilies occurred before the Eudicotyledons/Liliopsida split and before the appearance of moss, and after the single-cell green algae. We also observed the same trends among the main DCL subfamilies from functional unit composition and architecture. Despite the long evolutionary course from the divergence of Liliopsida lineage from the Eudicotyledons, a significant diversifying force to domain composition and orientation was absent. The results of this study provide a deeper insight into DCL protein evolutionary history and possible sequence and structural relationships between DCL protein subfamilies in the main higher plant monophyletic lineages; i.e., Eudicotyledons and Liliopsida.
未被翻译为蛋白质的小RNA(sRNA)在几乎所有真核生物谱系(包括植物)中其同源基因的表达调控中发挥着关键作用。迄今为止,已有许多蛋白质家族,如独特的核糖核酸酶III类Dicer,被报道参与sRNA加工途径和沉默过程。在本研究中,我们旨在研究DCL蛋白家族的系统发育关系和进化历史。
我们的结果表明,双子叶植物或单子叶植物中的DCL蛋白家族分为四个主要亚家族(DCL1 - 4)。对系统发育树的精确观察支持了DCL蛋白在双子叶植物和单子叶植物物种中的独立扩张。它们有共同的起源,并且形成DCL亚家族的主要复制事件发生在双子叶植物/单子叶植物从其祖先DCL分化之前。此外,有证据表明,分化发生在多细胞化开始时,并且由于生物体认为复杂的基因调控是必要的。在那时,它们在单系谱系中独立进化。另一个发现是,DCL蛋白亚家族的组合在源自其祖先结构的植物物种中具有几个高度保守的功能域。这些结构域的保守性恰好是谱系特异性和谱系间特异性的。
DCL亚家族(即DCL1 - DCL4)在从其共同祖先分化后且在高等植物出现之前分布在各自独立的进化枝中。因此,似乎形成DCL亚家族的主要复制事件发生在双子叶植物/单子叶植物分化之前、苔藓出现之前以及单细胞绿藻之后。我们还在主要DCL亚家族的功能单元组成和结构中观察到了相同的趋势。尽管单子叶植物谱系与双子叶植物谱系分化后的进化历程漫长,但对结构域组成和方向没有显著的多样化影响。本研究结果为DCL蛋白的进化历史以及主要高等植物单系谱系(即双子叶植物和单子叶植物)中DCL蛋白亚家族之间可能的序列和结构关系提供了更深入的见解。