草类中耐盐性的重复进化。

Repeated evolution of salt-tolerance in grasses.

机构信息

Centre for Macroevolution and Macroecology, Research School of Biology, Australian National University, Canberra, Australian Capital Territory 0200, Australia.

出版信息

Biol Lett. 2013 Feb 27;9(2):20130029. doi: 10.1098/rsbl.2013.0029. Print 2013 Apr 23.

DOI:10.1098/rsbl.2013.0029

PMID:23445947

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3639779/

Abstract

The amount of salt-affected agricultural land is increasing globally, so new crop varieties are needed that can grow in salt-affected soils. Despite concerted effort to develop salt-tolerant cereal crops, few commercially viable salt-tolerant crops have been released. This is puzzling, given the number of naturally salt-tolerant grass species. To better understand why salt-tolerance occurs naturally but is difficult to breed into crop species, we take a novel, biodiversity-based approach to its study, examining the evolutionary lability of salt-tolerance across the grass family. We analyse the phylogenetic distribution of naturally salt-tolerant species on a phylogeny of 2684 grasses, and find that salt-tolerance has evolved over 70 times, in a wide range of grass lineages. These results are confirmed by repeating the analysis at genus level on a phylogeny of over 800 grass genera. While salt-tolerance evolves surprisingly often, we find that its evolution does not often give rise to a large clade of salt-tolerant species. These results suggest that salt-tolerance is an evolutionarily labile trait in grasses.

摘要

受盐影响的农业土地在全球范围内不断增加，因此需要培育能够在受盐影响的土壤中生长的新作物品种。尽管人们一直在努力开发耐盐谷物作物，但只有少数具有商业可行性的耐盐作物被培育出来。考虑到有大量天然耐盐草本物种，这令人费解。为了更好地理解为什么盐耐受性是自然发生的，但却难以培育到作物品种中，我们采用了一种新颖的、基于生物多样性的方法来研究它，研究了整个禾本科植物中盐耐受性的进化不稳定性。我们分析了在 2684 种禾本科植物的系统发育树上自然耐盐物种的系统发育分布，并发现盐耐受性在广泛的禾本科植物谱系中已经进化了 70 多次。通过在一个包含 800 多种禾本科植物的系统发育树上重复该分析，得到了同样的结果。虽然盐耐受性的进化频率很高，但我们发现它的进化并不经常导致大量的耐盐物种形成一个大的分支。这些结果表明，盐耐受性在禾本科植物中是一个进化不稳定的特征。

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