Comparative genomics reveals a unique nitrogen-carbon balance system in Asteraceae

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作者
Fei Shen
Yajuan Qin
Rui Wang
Xin Huang
Ying Wang
Tiangang Gao
Junna He
Yue Zhou
Yuannian Jiao
Jianhua Wei
Lei Li
Xiaozeng Yang
机构
[1] Institute of Biotechnology,Beijing Key Laboratory of Agricultural Genetic Resources and Biotechnology
[2] Beijing Academy of Agriculture and Forestry Sciences,Beijing Key Laboratory of Development and Quality Control of Ornamental Crops, College of Horticulture
[3] China Agricultural University,State Key Laboratory of Protein and Plant Gene Research, School of Advanced Agricultural Sciences
[4] Peking University,State Key Laboratory of Evolutionary and Systematic Botany, Institute of Botany
[5] the Chinese Academy of Sciences,undefined
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Nature Communications | / 14卷
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摘要
The Asteraceae (daisy family) is one of the largest families of plants. The genetic basis for its high biodiversity and excellent adaptability has not been elucidated. Here, we compare the genomes of 29 terrestrial plant species, including two de novo chromosome-scale genome assemblies for stem lettuce, a member of Asteraceae, and Scaevola taccada, a member of Goodeniaceae that is one of the closest outgroups of Asteraceae. We show that Asteraceae originated ~80 million years ago and experienced repeated paleopolyploidization. PII, the universal regulator of nitrogen-carbon (N-C) assimilation present in almost all domains of life, has conspicuously lost across Asteraceae. Meanwhile, Asteraceae has stepwise upgraded the N-C balance system via paleopolyploidization and tandem duplications of key metabolic genes, resulting in enhanced nitrogen uptake and fatty acid biosynthesis. In addition to suggesting a molecular basis for their ecological success, the unique N-C balance system reported for Asteraceae offers a potential crop improvement strategy.
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