Maternal Inheritance of U’s Triangle and Evolutionary Process of Brassica Mitochondrial Genomes

The sequences and genomic structures of plant mitochondrial (mt) genomes provide unique material for phylogenetic studies. The nature of uniparental inheritance renders an advantage when utilizing mt genomes for determining the parental sources of hybridized taxa. In this study, a concatenated matri...

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Bibliographic Details
Published in:Frontiers in plant science 2020-06, Vol.11, p.805-805
Main Authors: Xue, Jia-Yu, Wang, Yue, Chen, Min, Dong, Shanshan, Shao, Zhu-Qing, Liu, Yang
Format: Article
Language:English
Subjects:
Brassica
evolutionary history
maternal inheritance
mitochondrial genome
paleogenomics
phylogenomics
Plant Science
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Summary:The sequences and genomic structures of plant mitochondrial (mt) genomes provide unique material for phylogenetic studies. The nature of uniparental inheritance renders an advantage when utilizing mt genomes for determining the parental sources of hybridized taxa. In this study, a concatenated matrix of mt genes was used to infer the phylogenetic relationships of six cultivated Brassica taxa and explore the maternal origins of three allotetraploids. The well-resolved sister relationships between two pairs of diploid and allotetraploid taxa suggest that Brassica carinata ( car ) possessed a maternal origin from Brassica nigra , while Brassica juncea ( jun ) was maternally derived from Brassica rapa ( cam ). Another allotetraploid taxon, Brassica napus (cv. Wester) may have been maternally derived from the common ancestor of B. rapa and Brassica oleracea ( ole ), and/or have undergone (an) extra hybridization event(s) along its evolutionary history. The characteristics of Brassica mt genomic structures also supported the phylogenetic results. Sinapis arvensis was nested inside the Brassica species, sister to the B. nigra–B. carinata lineage, and possessed an mt genome structure that mostly resembled B. nigra . Collectively, the evidence supported a systematic revision that placed S. arvensis within Brassica. Finally, ancestral mt genomes at each evolutionary node of Brassica were reconstructed, and the detailed and dynamic evolution of Brassica mt genomes was successfully reproduced. The mt genome of B. nigra structurally resembled that of the Brassica ancestor the most, with only one reversion of a block, and the Brassica oleracea underwent the most drastic changes. These findings suggested that repeat-mediated recombinations were largely responsible for the observed structural variations in the evolutionary history of Brassica mt genomes.
ISSN:1664-462X
1664-462X
DOI:10.3389/fpls.2020.00805