Phylogenomic and evolutionary dynamics of inverted repeats across Angelica plastomes.

Resource Type: 
Publication
Publication Type: 
Journal Article
Title: 
Phylogenomic and evolutionary dynamics of inverted repeats across Angelica plastomes.
Authors: 
Wang M, Wang X, Sun J, Wang Y, Ge Y, Dong W, Yuan Q, Huang L
Series Name: 
BMC plant biology
Journal Abbreviation: 
BMC Plant Biol
Volume: 
21
Issue: 
1
Page Numbers: 
26
Publication Year: 
2021
Publication Date: 
2021 Jan 07
DOI: 
10.1186/s12870-020-02801-w
ISSN: 
1471-2229
EISSN: 
1471-2229
Cross Reference: 
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Citation: 
Wang M, Wang X, Sun J, Wang Y, Ge Y, Dong W, Yuan Q, Huang L. Phylogenomic and evolutionary dynamics of inverted repeats across Angelica plastomes.. BMC plant biology. 2021 Jan 07; 21(1):26.
Abstract: 

BACKGROUND
Angelica L. (family Apiaceae) is an economically important genus comprising ca. One hundred ten species. Angelica species are found on all continents of the Northern Hemisphere, and East Asia hosts the highest number of species. Morphological characters such as fruit anatomy, leaf morphology and subterranean structures of Angelica species show extreme diversity. Consequently, the taxonomic classification of Angelica species is complex and remains controversial, as the classifications proposed by previous studies based on morphological data and molecular data are highly discordant. In addition, the phylogenetic relationships of major clades in the Angelica group, particularly in the Angelica s. s. clade, remain unclear. Chloroplast (cp) genome sequences have been widely used in phylogenetic studies and for evaluating genetic diversity.

RESULTS
In this study, we sequenced and assembled 28 complete cp genomes from 22 species, two varieties and two cultivars of Angelica. Combined with 36 available cp genomes in GenBank from representative clades of the subfamily Apioideae, the characteristics and evolutionary patterns of Angelica cp genomes were studied, and the phylogenetic relationships of Angelica species were resolved. The Angelica cp genomes had the typical quadripartite structure including a pair of inverted repeats (IRs: 5836-34,706 bp) separated by a large single-copy region (LSC: 76,657-103,161 bp) and a small single-copy region (SSC: 17,433-21,794 bp). Extensive expansion and contraction of the IR region were observed among cp genomes of Angelica species, and the pattern of the diversification of cp genomes showed high consistency with the phylogenetic placement of Angelica species. Species of Angelica were grouped into two major clades, with most species grouped in the Angelica group and A. omeiensis and A. sinensis grouped in the Sinodielsia with Ligusticum tenuissimum.

CONCLUSIONS
Our results further demonstrate the power of plastid phylogenomics in enhancing the phylogenetic reconstructions of complex genera and provide new insights into plastome evolution across Angelica L.

Publication Model: 
Electronic
Language: 
English
Language Abbr: 
eng
Journal Country: 
England
Keywords: 
  • Ligusticum
  • chloroplast genome
  • chloroplasts
  • cultivars
  • fruits
  • genetic variation
  • leaf morphology
  • phylogeny