Evolution of Chromosome Number in Wild Onions (Allium, Amaryllidaceae)

IF 0.9 3区 生物学 Q4 EVOLUTIONARY BIOLOGY
Courtney H. Babin, C. Bell
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引用次数: 0

Abstract

Abstract Polyploidy has been shown to be a significant driver of diversification among land plants. In addition to whole-genome duplication, other common mechanisms of chromosome number evolution include increases by a multiple of 1.5 in chromosome number due to the fusion of gametes with different ploidy levels (demi-polyploidy), gains or losses of single chromosomes that alter the DNA content of an organism (aneuploidy), or chromosome fission or fusion (ascending dysploidy or descending dysploidy, respectively). Considering the high variability in chromosome number transitions across multiple clades within angiosperms and the ancient genome duplication events responsible for their diversity, more studies of large polyploid systems are necessary to close the gaps in understanding chromosomal evolution in polyploid plants. Allium L. (Amaryllidaceae) is an ideal candidate for polyploid research because it is a large clade that includes numerous natural populations of diploid and polyploid species. Species of Allium mainly occupy temperate climates in the Northern Hemisphere and include economically important ornamentals and cultivated crops such as leeks, garlic, chives, and onions. Here, we used a molecular phylogeny of Allium to examine chromosomal evolution with chromEvol v. 2.0 which uses likelihood-based methods for inferring the pattern of chromosome number change across a phylogeny. The best-fit model of chromosomal evolution indicated that chromosome transitions within Allium occurred through the constant gains and losses of single chromosomes as well as demi-polyploidization events, with the rate of chromosome gain events being approximately 2.5 to 4.5 times more likely to occur than demi-polyploidization and loss events, respectively.
野生洋葱(葱、石蒜科)染色体数目的进化
摘要多倍体已被证明是陆地植物多样化的重要驱动因素。除了全基因组复制之外,染色体数量进化的其他常见机制包括由于具有不同倍性水平的配子融合而导致染色体数量增加1.5倍(半多倍体)、改变生物体DNA含量的单染色体的获得或丢失(非整倍体)、,或染色体分裂或融合(分别为上行异常或下行异常)。考虑到被子植物内多个分支的染色体数量转换的高度可变性,以及导致其多样性的古老基因组复制事件,有必要对大型多倍体系统进行更多的研究,以填补理解多倍体植物染色体进化的空白。Allium L.(石蒜科)是多倍体研究的理想候选者,因为它是一个庞大的分支,包括许多二倍体和多倍体物种的自然种群。葱的种类主要分布在北半球的温带气候中,包括经济上重要的观赏植物和栽培作物,如韭菜、大蒜、韭菜和洋葱。在这里,我们使用葱的分子系统发育来检查chromEvol v.2.0的染色体进化,该版本使用基于可能性的方法来推断整个系统发育中染色体数量变化的模式。染色体进化的最佳拟合模型表明,葱体内的染色体转换是通过单染色体的不断获得和丢失以及半多倍体化事件发生的,染色体获得事件的发生率分别是半多倍体和丢失事件的2.5至4.5倍。
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来源期刊
Systematic Botany
Systematic Botany 生物-进化生物学
CiteScore
1.80
自引率
10.00%
发文量
72
审稿时长
6-12 weeks
期刊介绍: Systematic Botany Monographs is a series of peer-reviewed taxonomic monographs and revisions published the American Society of Plant Taxonomists. ISSN 0737-8211, ISBN prefix 978-0-912861. No; volumes of Systematic Botany Monographs must be ordered separately. ASPT membership inludes only a subscription to the quarterly journal Systematic Botany. SBM is supported by sales, author"s subsidies, and donations.
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