RESUMO
The whole chloroplast genome ofthe medicinal plant Paeonia mairei H. Lév. was sequenced using the Illumina HiSeq X Ten platform and then assembled, annotated, and characterized by bioinformatic methods in this study. The complete chloroplast genome of P. mairei is 152 731 bp in length with the typical quadripartite structure, which consists of a large single copy-region (LSC, 84 402 bp), a small single copy-region (SSC, 16 969 bp), and a pair of inverted repeat regions (IRa and IRb, 25 680 bp), with an overall GC content of 38.4%. A total of 136 predicted genes, including 90 protein-coding genes, 38 tRNA genes and eight rRNA genes were identified. Among these, seven protein-coding genes, seven tRNA genes and four rRNA genes were found duplicated in the IR regions. In addition, 28 dispersed repeats, 10 tandem repeats, and 64 simple sequence repeats were detected within the whole chloroplast genome of P. mairei. Comparative analyses between 12 Peaonia species showed that the chloroplast genomes are highly conserved in length, gene content, gene order, and GC content. Meanwhile, the noncoding sequences (intergenic regions and introns) show a higher variation than the protein coding sequences, and sequences from the LSC region and SSC region are more variable than those from the IR regions. P. mairei was inferred forming in a distinct clade with P. lactiflora, P. obovate, and P. anomala subsp. veitchii with a 100% bootstrap value and is phylogenetically closest to P. lactiflora. These results may provide a basis for further genetic studies and the development and utilization of medicinal P. mairei.
RESUMO
In this study, RACE technology was employed to isolate the full length cDNA of DoHT1 in Dendrobium officinale, followed by bioinformatics analysis of the sequence characteristics. And the expression pattern of the gene was also analyzed by quantitative PCR. The full length cDNA of DoHT1 was 1 586 bp in length, containing a 1 536 bp ORF, which encoded a 511-aa protein with molecular weight of 56.18 kD and isoelectric point of 9.08. The deduced DoHT1 protein had the major facilitator superfamily conserved domain (22-483), SUGAR₋TRANSPORT₋1 (139-164), and SUGAR₋TRANSPORT₋2 (338-355), typical for sugar transporter; DoHT1, without a single peptide had 11 transmembrane regions, and was predicted to locate in the plasma membrane; DoHT1 had high identities (54.7%-80.7%) with HTs proteins from various plants. DoHT1 belonged to the MST (monosaccharide transporter) group of the evolutionary tree, and was closely related to the Phalaenopsis equestris. DoHT1 was differentially expressed in the three included organs. The transcripts were significantly the most abundant in the leaves with 19.36 fold than roots, then 1.82 fold in the stems than the roots. The identification and molecular characterization of the full length DoHT1 will be essential for further function study of the gene during the regulation of sugar metabolism of D. officinale.