通过强有力的系统发生组证据揭示 Tussilaginae 亚族(菊科:番泻叶属)复杂而清晰的异源多倍体模式,开发新型同源物分类管道

IF 6.1 1区 生物学 Q1 EVOLUTIONARY BIOLOGY Systematic Biology Pub Date : 2024-07-22 DOI:10.1093/sysbio/syae046
Chen Ren, Long Wang, Ze-Long Nie, Ming Tang, Gabriel Johnson, Hui-Tong Tan, Nian-He Xia, Jun Wen, Qin-Er Yang
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引用次数: 0

摘要

多倍体是真核生物进化的一个重要机制,在植物界尤为普遍。然而,我们对这一现象及其对进化影响的了解仍然有限。研究多倍体的一个主要障碍是很难弄清异源多倍体的起源。由于杂交和复杂的多倍体后二倍体化过程的共同作用导致了基因组的急剧变化和异源多倍体信号的侵蚀,长期以来,解析异源多倍体的起源一直是一项具有挑战性的任务。在此,我们以 Tussilagininae 亚支(菊科:Senecioneae)为例重新探讨了这一问题,并开发了 HomeoSorter,这是一种通过将同源物与亲本亚基因组分期进行网络推断的新方法。该管道基于之前研究的基本思想,但在解决缩放问题和实现一些新功能方面做了重大改动。通过模拟数据,我们证明了 HomeoSorter 可高效处理基因组规模的数据,并且在识别多倍体模式和分配同源物方面具有很高的准确性。通过使用 HomeoSorter、Phylonet 的最大伪似然模型和基因组尺度数据,我们进一步研究了 Tussilaginae 的复杂起源,这是一个以高基染色体数(主要是 x = 30、40)为特征的物种群(约 45 属和 710 种)。特别是,推断的模式得到了染色体证据的有力支持。结果表明,Tussilaginae(蝶形目)由两个大类群组成,具有连续的异源多倍体起源:Tussilaginae s.s.(主要为 x = 30)和 Gynoxyoid 群(x = 40)。两个异源多倍体事件首先产生了 Tussilaginae s.s.、第一个事件发生在 Senecioninae 亚族的祖先(x = 10)与 Brachyglottis 联盟的一个世系(很可能 x = 10)之间,由此产生的杂交世系与 Chersodoma 的祖先(x = 10)杂交,形成 Tussilaginae s.s.、再次与 Chersodoma 系发生第三次异源多倍体,产生了 Gynoxyoid 群。我们的研究凸显了 HomeoSorter 和同源物分类方法在多倍体系统发育学中的价值。Tussilaginae s.s.和 Gynoxyoid 群具有丰富的物种多样性和清晰的进化模式,是未来研究多倍体的绝佳模型。
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Complex but Clear Allopolyploid Pattern of Subtribe Tussilagininae (Asteraceae: Senecioneae) Revealed by Robust Phylogenomic Evidence, with Development of a Novel Homeolog-Sorting Pipeline
Polyploidy is a significant mechanism in eukaryotic evolution and is particularly prevalent in the plant kingdom. However, our knowledge about this phenomenon and its effects on evolution remains limited. A major obstacle to the study of polyploidy is the great difficulty in untangling the origins of allopolyploids. Due to the drastic genome changes and the erosion of allopolyploidy signals caused by the combined effects of hybridization and complex post-polyploid diploidization processes, resolving the origins of allopolyploids has long been a challenging task. Here we revisit this issue with the interesting case of subtribe Tussilagininae (Asteraceae: Senecioneae) and by developing HomeoSorter, a new pipeline for network inferences by phasing homeologs to parental subgenomes. The pipeline is based on the basic idea of a previous study but with major changes to address the scaling problem and implement some new functions. With simulated data, we demonstrate that HomeoSorter works efficiently on genome-scale data and has high accuracy in identifying polyploid patterns and assigning homeologs. Using HomeoSorter, the maximum pseudo-likelihood model of Phylonet, and genome-scale data, we further address the complex origin of Tussilagininae, a speciose group (ca. 45 genera and 710 species) characterized by having high base chromosome numbers (mainly x = 30, 40). In particular, the inferred patterns are strongly supported by the chromosomal evidence. Tussilagininae is revealed to comprise two large groups with successive allopolyploid origins: Tussilagininae s.s. (mainly x = 30) and the Gynoxyoid group (x = 40). Two allopolyploidy events first give rise to Tussilagininae s.s., with the first event occurring between the ancestor of subtribe Senecioninae (x = 10) and a lineage (highly probably with x = 10) related to the Brachyglottis alliance, and the resulting hybrid lineage crossing with the ancestor of Chersodoma (x = 10) and leading to Tussilagininae s.s. Then, after early diversification, the Central American group (mainly x = 30) of Tussilagininae s.s., is involved in a third allopolyploidy event with, again, the Chersodoma lineage and produces the Gynoxyoid group. Our study highlights the value of HomeoSorter and the homeolog-sorting approach in polyploid phylogenetics. With rich species diversity and clear evolutionary patterns, Tussilagininae s.s. and the Gynoxyoid group are also excellent models for future investigations of polyploidy.
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来源期刊
Systematic Biology
Systematic Biology 生物-进化生物学
CiteScore
13.00
自引率
7.70%
发文量
70
审稿时长
6-12 weeks
期刊介绍: Systematic Biology is the bimonthly journal of the Society of Systematic Biologists. Papers for the journal are original contributions to the theory, principles, and methods of systematics as well as phylogeny, evolution, morphology, biogeography, paleontology, genetics, and the classification of all living things. A Points of View section offers a forum for discussion, while book reviews and announcements of general interest are also featured.
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