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Phylogenetic position of Apostasia ramifera inferred by maximum likelihood (ML) of complete cp genome. The bootstrap values are shown next to the nodes.
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Apostasia ramifera S. C. Chen & K. Y. Lang 1986 is a Chinese endemic and endangered orchid. Here, we report the complete chloroplast (cp) genome sequence and the cp genome features of A. ramifera. The cp genome was 157,518 bp in length with a typical quadripartite structure, which was comprised of one large single-copy region (LSC, 86,353 bp) and o...
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Apostasioideae, the early divergent subfamily of Orchidaceae, comprises Apostasia and Neuwiedia genera with approximately 20 species. Despite extensive research on Apostasioideae, previous studies have struggled to resolve taxonomic issues, particularly concerning the position of species within this subfamily. Here, we sequenced and annotated plastomes of Apostasia fujianica and Neuwiedia malipoensis, unveiling their phylogenetic relationships and shared plastome features with the other five published plastomes. We identified and analyzed the length, GC content, repeat sequences, and RSCU values of the chloroplast genomes. It is noteworthy that the chloroplast genome of N. malipoensis stands out as the largest among all known chloroplast genomes within the Apostasioideae subfamily, primarily due to contributions from both the LSC and SSC regions. Furthermore, our analysis revealed three unique structural rearrangements located approximately 10k–47k bp (ycf3–trnS-GCU) and 58k–59k bp(accD) in the LSC region and 118k–119k (ndhI) bp in the SSC region of the chloroplast genomes across all five species within the Apostasia genus, which presents a potential avenue for identifying distinctive chloroplast genetic markers, setting them apart from other orchid plants. And a total of four mutational hotspots (rpoC2, atpH, rps4, ndhK, and clpP) were identified. Moreover, our study suggested that Apostasia and Neuwiedia formed a monophyletic group, with Apostasia being sister to Neuwiedia. Within the Apostasia genus, five species were classified into two major clades, represented as follows: (A. odorata (A. shenzhenica and A. fujianica) (A. ramifera and A. wallichii)). These findings hold significance in developing DNA barcoding of Apostasioideae and contribute to the further phylogenetic understanding of Apostasioideae species.
High-throughput sequencing technology has been facilitated the development of new methodologies and approaches for studying the origin and evolution of plant genomes and subgenomes, population domestication, and functional genomics. Orchids have tens of thousands of members in nature. Many of them have promising application potential in the extension and conservation of the ecological chain, the horticultural use of ornamental blossoms, and the utilization of botanical medicines. However, a large-scale gene knockout mutant library and a sophisticated genetic transformation system are still lacking in the improvement of orchid germplasm resources. New gene editing tools, such as the favored CRISPR-Cas9 or some base editors, have not yet been widely applied in orchids. In addition to a large variety of orchid cultivars, the high-precision, high-throughput genome sequencing technology is also required for the mining of trait-related functional genes. Nowadays, the focus of orchid genomics research has been directed to the origin and classification of species, genome evolution and deletion, gene duplication and chromosomal polyploidy, and flower morphogenesis-related regulation. Here, the progressing achieved in orchid molecular biology and genomics over the past few decades have been discussed, including the evolution of genome size and polyploidization. The frequent incorporation of LTR retrotransposons play important role in the expansion and structural variation of the orchid genome. The large-scale gene duplication event of the nuclear genome generated plenty of recently tandem duplicated genes, which drove the evolution and functional divergency of new genes. The evolution and loss of the plastid genome, which mostly affected genes related to photosynthesis and autotrophy, demonstrated that orchids have experienced more separate transitions to heterotrophy than any other terrestrial plant. Moreover, large-scale resequencing provide useful SNP markers for constructing genetic maps, which will facilitate the breeding of novel orchid varieties. The significance of high-throughput sequencing and gene editing technologies in the identification and molecular breeding of the trait-related genes in orchids provides us with a representative trait-improving gene as well as some mechanisms worthy of further investigation. In addition, gene editing has promise for the improvement of orchid genetic transformation and the investigation of gene function. This knowledge may provide a scientific reference and theoretical basis for orchid genome studies.
