The structural diversity of CACTA transposons in genomes of Chenopodium (Amaranthaceae, Caryophyllales) species: specific traits and comparison with the similar elements of angiosperms
{"title":"The structural diversity of CACTA transposons in genomes of Chenopodium (Amaranthaceae, Caryophyllales) species: specific traits and comparison with the similar elements of angiosperms","authors":"Belyayev, Alexander, Josefiová, Jiřina, Jandová, Michaela, Kalendar, Ruslan, Mahelka, Václav, Mandák, Bohumil, Krak, Karol","doi":"10.1186/s13100-022-00265-3","DOIUrl":null,"url":null,"abstract":"CACTA transposable elements (TEs) comprise one of the most abundant superfamilies of Class 2 (cut-and-paste) transposons. Over recent decades, CACTA elements were widely identified in species from the plant, fungi, and animal kingdoms, but sufficiently studied in the genomes of only a few model species although non-model genomes can bring additional and valuable information. It primarily concerned the genomes of species belonging to clades in the base of large taxonomic groups whose genomes, to a certain extent, can preserve relict and/or possesses specific traits. Thus, we sought to investigate the genomes of Chenopodium (Amaranthaceae, Caryophyllales) species to unravel the structural variability of CACTA elements. Caryophyllales is a separate branch of Angiosperms and until recently the diversity of CACTA elements in this clade was unknown. Application of the short-read genome assembly algorithm followed by analysis of detected complete CACTA elements allowed for the determination of their structural diversity in the genomes of 22 Chenopodium album aggregate species. This approach yielded knowledge regarding: (i) the coexistence of two CACTA transposons subtypes in single genome; (ii) gaining of additional protein conserved domains within the coding sequence; (iii) the presence of captured gene fragments, including key genes for flower development; and (iv)) identification of captured satDNA arrays. Wide comparative database analysis revealed that identified events are scattered through Angiosperms in different proportions. Our study demonstrated that while preserving the basic element structure a wide range of coding and non-coding additions to CACTA transposons occur in the genomes of C. album aggregate species. Ability to relocate additions inside genome in combination with the proposed novel functional features of structural-different CACTA elements can impact evolutionary trajectory of the host genome.","PeriodicalId":18854,"journal":{"name":"Mobile DNA","volume":"177 1","pages":""},"PeriodicalIF":4.7000,"publicationDate":"2022-04-04","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Mobile DNA","FirstCategoryId":"99","ListUrlMain":"https://doi.org/10.1186/s13100-022-00265-3","RegionNum":2,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"GENETICS & HEREDITY","Score":null,"Total":0}
引用次数: 1
Abstract
CACTA transposable elements (TEs) comprise one of the most abundant superfamilies of Class 2 (cut-and-paste) transposons. Over recent decades, CACTA elements were widely identified in species from the plant, fungi, and animal kingdoms, but sufficiently studied in the genomes of only a few model species although non-model genomes can bring additional and valuable information. It primarily concerned the genomes of species belonging to clades in the base of large taxonomic groups whose genomes, to a certain extent, can preserve relict and/or possesses specific traits. Thus, we sought to investigate the genomes of Chenopodium (Amaranthaceae, Caryophyllales) species to unravel the structural variability of CACTA elements. Caryophyllales is a separate branch of Angiosperms and until recently the diversity of CACTA elements in this clade was unknown. Application of the short-read genome assembly algorithm followed by analysis of detected complete CACTA elements allowed for the determination of their structural diversity in the genomes of 22 Chenopodium album aggregate species. This approach yielded knowledge regarding: (i) the coexistence of two CACTA transposons subtypes in single genome; (ii) gaining of additional protein conserved domains within the coding sequence; (iii) the presence of captured gene fragments, including key genes for flower development; and (iv)) identification of captured satDNA arrays. Wide comparative database analysis revealed that identified events are scattered through Angiosperms in different proportions. Our study demonstrated that while preserving the basic element structure a wide range of coding and non-coding additions to CACTA transposons occur in the genomes of C. album aggregate species. Ability to relocate additions inside genome in combination with the proposed novel functional features of structural-different CACTA elements can impact evolutionary trajectory of the host genome.
CACTA转座子(TEs)是一类最丰富的2类(剪切-粘贴)转座子超家族之一。近几十年来,CACTA元件在植物、真菌和动物领域的物种中得到了广泛的鉴定,但在少数模式物种的基因组中得到了充分的研究,尽管非模式基因组可以带来额外的有价值的信息。它主要涉及属于大型分类群基础分支的物种的基因组,这些物种的基因组在一定程度上可以保存遗存和/或具有特定特征。因此,我们对藜属植物(苋菜科,石竹科)的基因组进行了研究,以揭示CACTA元件的结构变异性。石竹属植物是被子植物的一个独立分支,直到最近才知道这个分支中CACTA元素的多样性。应用短读基因组组装算法,对检测到的完整CACTA元件进行分析,确定了22种Chenopodium album aggregate种基因组的结构多样性。该方法获得了以下方面的知识:(i)两个CACTA转座子亚型在单个基因组中共存;(ii)在编码序列中获得额外的蛋白质保守结构域;(iii)存在捕获的基因片段,包括花发育的关键基因;(iv)识别捕获的卫星dna阵列。。广泛的比较数据库分析显示,确定的事件以不同的比例分散在被子植物中。我们的研究表明,在保留基本元件结构的同时,CACTA转座子出现了广泛的编码和非编码添加。基因组内添加物的重新定位能力与CACTA元件结构不同的新功能特征相结合,可以影响宿主基因组的进化轨迹。
期刊介绍:
Mobile DNA is an online, peer-reviewed, open access journal that publishes articles providing novel insights into DNA rearrangements in all organisms, ranging from transposition and other types of recombination mechanisms to patterns and processes of mobile element and host genome evolution. In addition, the journal will consider articles on the utility of mobile genetic elements in biotechnological methods and protocols.