Comparative chloroplast genomes of Paris Sect. Marmorata: insights into repeat regions and evolutionary implications

Species of Paris Sect. Marmorata are valuable medicinal plants to synthesize steroidal saponins with effective pharmacological therapy. However, the wild resources of the species are threatened by plundering exploitation before the molecular genetics studies uncover the genomes and evolutionary sign...

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Bibliographic Details
Published in:BMC genomics 2018-12, Vol.19 (Suppl 10), p.878-878, Article 878
Main Authors: Gao, Xiaoyang, Zhang, Xuan, Meng, Honghu, Li, Jing, Zhang, Di, Liu, Changning
Format: Article
Language:English
Subjects:
Chloroplast genome
Chloroplasts
Codon usage
Endosymbiosis
Evolutionary rates
Genomes
Herbal medicine
Paris Sect. Marmorata
Repeat sequence
Supply and demand
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Summary:Species of Paris Sect. Marmorata are valuable medicinal plants to synthesize steroidal saponins with effective pharmacological therapy. However, the wild resources of the species are threatened by plundering exploitation before the molecular genetics studies uncover the genomes and evolutionary significance. Thus, the availability of complete chloroplast genome sequences of Sect. Marmorata is necessary and crucial to the understanding the plastome evolution of this section and facilitating future population genetics studies. Here, we determined chloroplast genomes of Sect. Marmorata, and conducted the whole chloroplast genome comparison. This study presented detailed sequences and structural variations of chloroplast genomes of Sect. Marmorata. Over 40 large repeats and approximately 130 simple sequence repeats as well as a group of genomic hotspots were detected. Inverted repeat contraction of this section was inferred via comparing the chloroplast genomes with the one of P. verticillata. Additionally, almost all the plastid protein coding genes were found to prefer ending with A/U. Mutation bias and selection pressure predominately shaped the codon bias of most genes. And most of the genes underwent purifying selection, whereas photosynthetic genes experienced a relatively relaxed purifying selection. Repeat sequences and hotspot regions can be scanned to detect the intraspecific and interspecific variability, and selected to infer the phylogenetic relationships of Sect. Marmorata and other species in subgenus Daiswa. Mutation and natural selection were theĀ main forces to drive the codon bias pattern of most plastid protein coding genes. Therefore, this study enhances the understanding about evolution of Sect. Marmorata from the chloroplast genome, and provide genomic insights into genetic analyses of Sect. Marmorata.
ISSN:1471-2164
1471-2164
DOI:10.1186/s12864-018-5281-x