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通过直接测序揭示植物中天然初级三重杂种的分子证据。

Molecular evidence for a natural primary triple hybrid in plants revealed from direct sequencing.

作者信息

Kaplan Zdenek, Fehrer Judith

机构信息

Institute of Botany, Academy of Sciences of the Czech Republic, CZ-252 43 Průhonice, Czech Republic.

出版信息

Ann Bot. 2007 Jun;99(6):1213-22. doi: 10.1093/aob/mcm072. Epub 2007 May 3.

DOI:10.1093/aob/mcm072
PMID:17478544
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3243585/
Abstract

BACKGROUND AND AIMS

Molecular evidence for natural primary hybrids composed of three different plant species is very rarely reported. An investigation was therefore carried out into the origin and a possible scenario for the rise of a sterile plant clone showing a combination of diagnostic morphological features of three separate, well-defined Potamogeton species.

METHODS

The combination of sequences from maternally inherited cytoplasmic (rpl20-rps12) and biparentally inherited nuclear ribosomal DNA (ITS) was used to identify the exact identity of the putative triple hybrid.

KEY RESULTS

Direct sequencing showed ITS variants of three parental taxa, P. gramineus, P. lucens and P. perfoliatus, whereas chloroplast DNA identified P. perfoliatus as the female parent. A scenario for the rise of the triple hybrid through a fertile binary hybrid P. gramineus x P. lucens crossed with P. perfoliatus is described.

CONCLUSIONS

Even though the triple hybrid is sterile, it possesses an efficient strategy for its existence and became locally successful even in the parental environment, perhaps as a result of heterosis. The population investigated is the only one known of this hybrid, P. x torssanderi, worldwide. Isozyme analysis indicated the colony to be genetically uniform. The plants studied represented a single clone that seems to have persisted at this site for a long time.

摘要

背景与目的

由三种不同植物物种构成的天然初级杂种的分子证据鲜有报道。因此,对一种不育植物克隆的起源及可能的产生情况展开了调查,该克隆呈现出三种不同的、界定明确的眼子菜属物种的诊断性形态特征组合。

方法

利用来自母系遗传的细胞质(rpl20 - rps12)和双亲遗传的核核糖体DNA(ITS)的序列组合,来确定假定的三倍体杂种的确切身份。

主要结果

直接测序显示出三个亲本类群,即禾本科眼子菜、光泽眼子菜和穿叶眼子菜的ITS变体,而叶绿体DNA鉴定出穿叶眼子菜为母本。描述了通过可育的二元杂种禾本科眼子菜×光泽眼子菜与穿叶眼子菜杂交产生三倍体杂种的一种情况。

结论

尽管三倍体杂种不育,但它拥有一种有效的生存策略,甚至在亲本环境中也在当地获得了成功,这可能是杂种优势的结果。所调查的种群是世界上已知的这种杂种(托桑德眼子菜)的唯一种群。同工酶分析表明该群体在遗传上是一致的。所研究的植物代表了一个似乎在该地点长期存在的单一克隆。

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