Whole‐chromosome oligo‐painting in licorice unveils interspecific chromosomal evolutionary relationships and possible origin of triploid genome species

种间竞争 生物 基因组 进化生物学 染色体 遗传学 植物 基因
作者
Zhuang Meng,Qian Zheng,Shandang Shi,Wei Wang,Fei Wang,Quanliang Xie,Xifeng Chen,Haitao Shen,Guanghui Xiao,Hongbin Li
出处
期刊:Plant Journal [Wiley]
卷期号:120 (5): 2089-2100 被引量:4
标识
DOI:10.1111/tpj.17102
摘要

SUMMARY Licorice is one of the most extensively studied medicinal plants in the world, whose roots and rhizomes have long been used as both a sweetener and an essential component in numerous herbal preparations. However, the genus Glycyrrhiza has a complex composition, and the interspecies chromosomal relationships, origin, and evolution are still largely unclear. Here, we develop a set of whole‐chromosome painting probes that allowed identification of all eight chromosomes of licorice on same metaphase chromosomes. Comparative chromosome painting analyses in seven different Glycyrrhiza species revealed that the genus Glycyrrhiza maintained extraordinarily conserved chromosomal synteny after about 3–12 million years of divergence. No cytologically visible inter‐chromosomal rearrangements were identified in any species. By comparative chromosomal karyotype analyses, we revealed interspecific chromosome evolutionary relationships and dramatic variable chromosomal karyotype after independent divergence and demonstrated that G. prostrate was the most closely related to the ancestral type among the seven Glycyrrhiza species. Furthermore, we also discovered a G. glandulosa seed with distinct triploid‐genome for the first time in China, suggesting the existence of a polyploid evolutionary pathway in the genus Glycyrrhiza , which challenges the previous notion that only diploids of licorice existed in nature. This study expands our knowledge of the chromosome evolution of licorice and will lay an important foundation for the genome origin and evolution studies in the genus Glycyrrhiza .
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