Dendrobium officinale , an important medicinal plant of the genus Dendrobium in Orchidaceae family, has been used as traditional Chinese medicine (TCM) for nearly thousands of years. Here, we report the first chromosome-level reference genome of D . officinale , based on PacBio long-reads, Illumina short-reads and Hi-C data. The high-quality assembled genome is 1.23 Gb long, with contig N50 of 1.44 Mb. A total of 93.53% genome sequences were assembled into 19 pseudochromosomes with a super scaffold N50 of 63.07 Mb. Through comparative genomic analysis, we explored the expanded gene families of D . officinale , and also their impact on environmental adaptation and biosynthesis of secondary metabolites. We further performed detailed transcriptional analysis of D. officinale , and identified the candidate genes involved in the biosynthesis of three main active ingredients, including polysaccharides, alkaloids and flavonoids. In addition, the MODIFYING WALL LIGNIN-1 ( MWL1 ) gene, which inferred from Genome-Wide Association Studies (GWAS) based on the resequencing date from D. officinale and five related species and their morphologic features, may contribute to the plant production (yield of stems) of D. officinale . Therefore, the high-quality reference genome reported in this study could benefits functional genomics research and molecular breeding of D. officinale .
Background Dendrobium nobile Lindl. is an important pharmacopeial plant with medicinal and ornamental value. This study sought to provide a technical means for the large-scale production of total alkaloid in D. nobile. Seedlings were cultured in vitro using a temporary immersion bioreactor system (TIBS). The four tested immersion frequencies (min/h; 5/2, 5/4, 5/6, and 5/8) influenced the production of biomass and total alkaloid content. In addition, to compare the effects of different concentrations of the phytohormone methyl jasmonate (MeJA) and treatment time on biomass and total alkaloid accumulation, MeJA was added to the TIBS medium after 50 days. Finally, total alkaloid production in semi-solid system (SSS), TIBS, and TIBS combined with the MeJA system (TIBS-MeJA) were compared. Results The best immersion frequency was found to be 5/6 (5 min every 6 h), which ensured appropriate levels of biomass and total alkaloid content in plantlets. The alkaloid content and production level of seedlings were the highest after treatment with 10 μM MeJA separately for 20 and 30 days using TIBS. The maximum content (7.41 mg/g DW) and production level (361.24 mg/L) of total alkaloid on use of TIBS-MeJA were 2.32- and 4.69-fold, respectively, higher in terms of content, and 2.07- and 10.49-fold, respectively, higher in terms of production level than those on using of TIBS (3.20 mg/g DW, 174.34 mg/L) and SSS (1.58 mg/g DW, 34.44 mg/L). Conclusions Our results show TIBS-MeJA is suitable for large-scale production of total alkaloid in in vitro seedlings. Therefore, this study provides a technical means for the large-scale production of total alkaloid in D. nobile.
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Dendrobium orchids have multiple photosynthetic pathways, which can be used as a model system for studying the evolution of crassulacean acid metabolism (CAM). In this study, based on the results of the net photosynthetic rates (Pn), we classified Dendrobium species into three photosynthetic pathways, then employed and compared their chloroplast genomes. The Dendrobium chloroplast genomes have typical quartile structures, ranging from 150,841–153,038 bp. The apparent differences in GC content, sequence variability, and IR junctions of SSC/IRB junctions (JSBs) were measured within chloroplast genomes among different photosynthetic pathways. The phylogenetic analysis has revealed multiple independent CAM origins among the selected Dendrobium species. After counting insertions and deletions (InDels), we found that the occurrence rates and distribution densities among different photosynthetic pathways were inconsistent. Moreover, the evolution patterns of chloroplast genes in Dendrobium among three photosynthetic pathways were also diversified. Considering the diversified genome structure variations and the evolution patterns of protein-coding genes among Dendrobium species, we proposed that the evolution of the chloroplast genomes was disproportional among different photosynthetic pathways. Furthermore, climatic correlation revealed that temperature and precipitation have influenced the distribution among different photosynthetic pathways and promoted the foundation of CAM pathway in Dendrobium orchids. Based on our study, we provided not only new insights into the CAM evolution of Dendrobium but also provided beneficial genetic data resources for the further systematical study of Dendrobium.
Reconstructing mitochondrial genomes of angiosperms is extremely intricate due to frequent recombinations which give rise to varied sized in Dendrobium mitogenomes and their structural variations, even in most orchid species. In this study, we first sequenced two complete and five draft mitochondrial genomes of Dendrobium using next‐generation and third‐generation sequencing technologies. The mitochondrial genomes were 420 538–689 048 bp long, showing multipartite (multichromosomal) structures that consisted of variably sized circular or linear‐mapping isoforms (chromosomes). The comparison of mitochondrial genomes showed frequent gene losses in Dendrobium species. To explore structure variations of mitochondrial genomes in vivo, we quantified copy numbers of five mitochondrial genes and DNA contents per mitochondrion. The gene copy numbers and the DNA contents showed extreme differences during Dendrobium development, suggesting dynamic structures of mitochondrial genomes. Furthermore, phylogenetic relationships of 97 accessions from 39 Dendrobium species were constructed based on 12 nuclear single‐copy genes and 15 mitochondrial genes. We discovered obvious discordance between the nuclear and mitochondrial trees. Reticulate evolution was inferred from the species network analysis in Dendrobium. Our findings revealed the rapid structural evolution of Dendrobium mitochondrial genomes and the existence of hybridization events in Dendrobium species, which provided new insights into in vivo structural variations of plant mitochondrial genomes and the strong potential of mitochondrial genes in deciphering plant evolution history.
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