牵牛花(旋花科)中块根的平行进化。
Parallel evolution of storage roots in morning glories (Convolvulaceae).
机构信息
Plant Biology Department, University of Georgia, Athens, GA, 30602, USA.
Present address: Conservation and Research Department, Atlanta Botanical Garden, Atlanta, GA, 30309, USA.
出版信息
BMC Plant Biol. 2018 May 29;18(1):95. doi: 10.1186/s12870-018-1307-4.
BACKGROUND
Storage roots are an ecologically and agriculturally important plant trait that have evolved numerous times in angiosperms. Storage roots primarily function to store carbohydrates underground as reserves for perennial species. In morning glories, storage roots are well characterized in the crop species sweetpotato, where starch accumulates in storage roots. This starch-storage tissue proliferates, and roots thicken to accommodate the additional tissue. In morning glories, storage roots have evolved numerous times. The primary goal of this study is to understand whether this was through parallel evolution, where species use a common genetic mechanism to achieve storage root formation, or through convergent evolution, where storage roots in distantly related species are formed using a different set of genes. Pairs of species where one forms storage roots and the other does not were sampled from two tribes in the morning glory family, the Ipomoeeae and Merremieae. Root anatomy in storage roots and fine roots was examined. Furthermore, we sequenced total mRNA from storage roots and fine roots in these species and analyzed differential gene expression.
RESULTS
Anatomical results reveal that storage roots of species in the Ipomoeeae tribe, such as sweetpotato, accumulate starch similar to species in the Merremieae tribe but differ in vascular tissue organization. In both storage root forming species, more genes were found to be upregulated in storage roots compared to fine roots. Further, we find that fifty-seven orthologous genes were differentially expressed between storage roots and fine roots in both storage root forming species. These genes are primarily involved in starch biosynthesis, regulation of starch biosynthesis, and transcription factor activity.
CONCLUSIONS
Taken together, these results demonstrate that storage roots of species from both morning glory tribes are anatomically different but utilize a common core set of genes in storage root formation. This is consistent with a pattern of parallel evolution, thus highlighting the importance of examining anatomy together with gene expression to understand the evolutionary origins of ecologically and economically important plant traits.
背景
块根是被子植物中具有生态和农业重要性的植物特征,已经在被子植物中多次进化。块根的主要功能是将碳水化合物储存在地下,作为多年生物种的储备。在牵牛科植物中,块根在作物甜薯中得到了很好的描述,淀粉在块根中积累。这种淀粉储存组织增殖,根变厚以适应额外的组织。在牵牛科植物中,块根已经进化了很多次。本研究的主要目的是了解这是通过平行进化还是趋同进化而来的,平行进化中,物种使用共同的遗传机制来实现块根的形成,而趋同进化中,亲缘关系较远的物种的块根是通过不同的基因集形成的。从牵牛科的两个族,Ipomoeeae 和 Merremieae 中,选取了一个形成块根而另一个不形成块根的物种对进行取样。对块根和细根的根解剖结构进行了研究。此外,我们对这些物种的块根和细根中的总 mRNA 进行了测序,并分析了差异基因表达。
结果
解剖学结果表明,Ipomoeeae 族的块根,如甜薯,与 Merremieae 族的物种类似,积累淀粉,但在维管束组织的组织上有所不同。在形成块根的两个物种中,与细根相比,更多的基因在块根中上调。此外,我们发现,在形成块根的两个物种中,有 57 个直系同源基因在块根和细根之间的表达存在差异。这些基因主要参与淀粉生物合成、淀粉生物合成的调控和转录因子活性。
结论
综上所述,这些结果表明,来自牵牛科两个族的物种的块根在解剖学上有所不同,但在块根形成过程中利用了一套共同的核心基因。这与平行进化的模式一致,因此强调了在研究具有生态和经济重要性的植物特征的进化起源时,同时研究解剖学和基因表达的重要性。
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