基于 ITS 和 5.8S rDNA 序列的花生属系统发育关系。

Phylogenetic relationships in genus Arachis based on ITS and 5.8S rDNA sequences.

机构信息

Universidade de Marília, UNIMAR - Marília, SP, Brazil.

出版信息

BMC Plant Biol. 2010 Nov 19;10:255. doi: 10.1186/1471-2229-10-255.

DOI:10.1186/1471-2229-10-255

PMID:21092103

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3095334/

Abstract

BACKGROUND

The genus Arachis comprises 80 species and it is subdivided into nine taxonomic sections (Arachis, Caulorrhizae, Erectoides, Extranervosae, Heteranthae, Procumbentes, Rhizomatosae, Trierectoides, and Triseminatae). This genus is naturally confined to South America and most of its species are native to Brazil. In order to provide a better understanding of the evolution of the genus, we reconstructed the phylogeny of 45 species using the variation observed on nucleotide sequences in internal transcribed spacer regions (ITS1 and ITS2) and 5.8 S of nuclear ribosomal DNA.

RESULTS

Intraspecific variation was detected, but in general it was not enough to place accessions of the same species in different clades. Our data support the view that Arachis is a monophyletic group and suggested Heteranthae as the most primitive section of genus Arachis. The results confirmed the circumscriptions of some sections (Caulorrhizae, Extranervosae), but raised questions about others. Sections Erectoides, Trierectoides and Procumbentes were not well defined, while sections Arachis and Rhizomatosae seem to include species that could be moved to different sections. The division of section Arachis into A and B genome species was also observed in the phylogenetic tree and these two groups of species may not have a monophyletic origin. The 2n = 2x = 18 species of section Arachis (A. praecox, A. palustris and A. decora) were all placed in the same clade, indicating they are closely related to each other, and their genomes are more related to B genome than to the A genome. Data also allowed insights on the origin of tetraploid A. glabrata, suggesting rhizome appeared twice within the genus and raising questions about the placement of that species in section Rhizomatosae.

CONCLUSION

The main clades established in this study in general agreed with many other studies that have used other types of evidences and sets of species, being some of them included in our study and some not. Thus, the relationships established can be a useful framework for future systematic reviews of genus Arachis and for the selection of species to pre-breeding programs.

摘要

背景

落花生属包含 80 个种，分为九个分类群（落花生、茎根型、直立型、离脉型、异型、匍匐型、根茎型、三叶型和三粒节型）。该属主要局限于南美洲，其大部分物种原产于巴西。为了更好地了解该属的进化，我们利用核核糖体 DNA 的内部转录间隔区（ITS1 和 ITS2）和 5.8S 核苷酸序列的变异重建了 45 个种的系统发育。

结果

检测到种内变异，但总体而言，这不足以将同一物种的标本放置在不同的分支中。我们的数据支持落花生属是一个单系群的观点，并表明异型是落花生属最原始的分类群。结果证实了一些分类群（茎根型、离脉型）的定义，但对其他分类群提出了疑问。直立型、三叶型和匍匐型分类群的定义不明确，而落花生型和根茎型分类群似乎包含可以移到不同分类群的物种。在系统发育树中也观察到落花生型分为 A 和 B 基因组种，这两个组的物种可能没有单系起源。Arachis 节的 2n = 2x = 18 种（A. praecox、A. palustris 和 A. decora）都被放置在同一分支中，表明它们彼此密切相关，它们的基因组与 B 基因组的关系比与 A 基因组的关系更密切。数据还使人们对四倍体 A. glabrata 的起源有了深入的了解，表明根茎在属内出现了两次，并对该物种在根茎型分类群中的位置提出了疑问。

结论

本研究中建立的主要分支与许多其他使用其他类型的证据和物种集的研究基本一致，其中一些研究包括在本研究中，而另一些则没有。因此，所建立的关系可以为落花生属的未来系统综述以及前育种计划中物种的选择提供有用的框架。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7149/3095334/4e5706c0eabf/1471-2229-10-255-1.jpg

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基于 ITS 和 5.8S rDNA 序列的花生属系统发育关系。

Phylogenetic relationships in genus Arachis based on ITS and 5.8S rDNA sequences.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSION

背景

结果

结论

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