Nguyen Nhat Nam, Nguyen Pham Anh Thi, Hoang Dang Khoa Do
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引用次数: 0
Abstract
The mitochondrial plastid DNAs (MTPTs) in seed plants were reported more than 40 years ago and exhibited a high diversity regarding gene content, quantity, and size. However, the mechanism that resulted in the current diversity of MTPTs in angiosperms has not been fully discovered. In this study, we sequenced and characterized the complete organelle genomes of Limonia acidissima L., a monotypic species of Rutaceae. The newly generated and previously published organelle genomes of 42 species were used to explore the diversity of MTPTs regarding quantity, gene content, size, and coverage of chloroplast genome (cpDNA) regions. The results showed that the number of MTPTs ranged from three to 74, of which the lengths were from 100 to 53,731 bp. The highest coverage of MTPTs was found in the inverted repeat region, whereas the small single repeat region had the lowest coverage. Based on the previous data and current results, we propose a scenario for the diversity of MTPTs in angiosperms. In the first stage, the whole cpDNA might migrate to the mitogenome. Then, different genomic events, such as duplication, deletion, substitution, and inversion, have occurred continuously and independently and resulted in extremely variable profiles of mitogenomes among angiosperms. Our hypothesis provides a new and possibly reliable scenario for explaining the present circumstances of MTPTs in angiosperms. However, more genomic data should be mined, and more studies should be conducted to clarify this natural phenomenon in plants.
期刊介绍:
About the journal
Genome Biology and Evolution (GBE) publishes leading original research at the interface between evolutionary biology and genomics. Papers considered for publication report novel evolutionary findings that concern natural genome diversity, population genomics, the structure, function, organisation and expression of genomes, comparative genomics, proteomics, and environmental genomic interactions. Major evolutionary insights from the fields of computational biology, structural biology, developmental biology, and cell biology are also considered, as are theoretical advances in the field of genome evolution. GBE’s scope embraces genome-wide evolutionary investigations at all taxonomic levels and for all forms of life — within populations or across domains. Its aims are to further the understanding of genomes in their evolutionary context and further the understanding of evolution from a genome-wide perspective.