多倍体物种比二倍体物种更依赖营养繁殖：对旧假说的重新审视。

Polyploid species rely on vegetative reproduction more than diploids: a re-examination of the old hypothesis.

作者信息

Herben Tomáš, Suda Jan, Klimešová Jitka

机构信息

Department of Botany, Faculty of Science, Charles University in Prague, Benátská 2, CZ-128 00 Praha 2, Czech Republic.

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

出版信息

Ann Bot. 2017 Aug 1;120(2):341-349. doi: 10.1093/aob/mcx009.

DOI:10.1093/aob/mcx009

PMID:28334206

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5737615/

Abstract

BACKGROUND AND AIMS

Polyploidy is arguably the single most important genetic mechanism in plant speciation and diversification. It has been repeatedly suggested that polyploids show higher vegetative reproduction than diploids (to by-pass low fertility after the polyploidization), but there are no rigorous tests of it.

METHODS

Data were analysed by phylogenetic regressions of clonal growth parameters, and vegetative reproduction in culture on the ploidy status of a large set of species (approx. 900) from the Central European Angiosperm flora. Further, correlated evolution of ploidy and clonal traits was examined to determine whether or not polyploidy precedes vegetative reproduction.

KEY RESULTS

The analyses showed that polyploidy is strongly associated with vegetative reproduction, whereas diploids rely more on seed reproduction. The rate of polyploid speciation is strongly enhanced by the existence of vegetative reproduction (namely extensive lateral spread), whereas the converse is not true.

CONCLUSIONS

These findings confirm the old hypothesis that polyploids can rely on vegetative reproduction which thus may save many incipient polyploids from extinction. A closer analysis also shows that the sequence of events begins with development of vegetative reproduction, which is then followed by polyploidy. Vegetative reproduction is thus likely to play an important role in polyploid speciation.

摘要

背景与目的

多倍体可以说是植物物种形成和多样化过程中最重要的单一遗传机制。人们多次提出，多倍体比二倍体表现出更高的营养繁殖能力（以绕过多倍体化后的低育性），但尚未对此进行严格验证。

方法

通过对中欧被子植物区系中大量物种（约900种）的克隆生长参数和培养中的营养繁殖与倍性状态进行系统发育回归分析数据。此外，研究了倍性与克隆性状的协同进化，以确定多倍体是否先于营养繁殖出现。

主要结果

分析表明，多倍体与营养繁殖密切相关，而二倍体更多地依赖种子繁殖。营养繁殖（即广泛的侧向扩散）的存在极大地提高了多倍体物种形成的速率，反之则不然。

结论

这些发现证实了一个古老的假说，即多倍体可以依靠营养繁殖，从而可能使许多新形成的多倍体免于灭绝。进一步分析还表明，事件顺序始于营养繁殖的发展，随后是多倍体化。因此，营养繁殖可能在多倍体物种形成中发挥重要作用。

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本文引用的文献

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