Dataset on ITS and some chloroplast DNA regions of Blume in Vietnam.

Species of the genus have the potential to be natural medicines and have industrial fibre production uses. Many species of this genus are morphologically similar and are difficult to distinguish, especially when their morphology is distorted. This dataset includes sequence information of several DNA regions isolated from the genome of , namely ITS (from the nuclear genome), , trnL-trnF, trnH-psbA, and (from the chloroplast genome) and phylogenetic analysis results based on the isolated sequences.

Dataset on intergenic spacer regions of chloroplast genome and potential DNA barcode of var in Vietnam.

var an epiphytic plant, is both an ornamental and a valuable medicinal plant. However, has a similar morphology to other species belonging to the genus, so it is challenging to distinguish the var plant accurately. Alternatively, if var is deformed or powdered, it is more challenging to identify.

Three new minor steroidal glycosides from the whole plants of (Wall. ex Hornem.) Wight.

Three new minor steroidal glycosides were isolated from the whole plants of (Wall. ex Hornem.) Wight.

The columbamine O-methyltransferase gene (CoOMT) is capable of increasing alkaloid content in transgenic tobacco plants.

Background: In the alkaloid biosynthetic pathways of Stephania and Rannunculaceae, columbamine O-methyltransferase (CoOMT) is an important enzyme that catalyses the formation of the tetrahydropalmatin (rotundin) biosynthesis pathway. In this study, the transgenic construct pBI121-35S-CoOMT-cmyc-Kdel was designed successfully.

Methods And Results: The real-time RT-PCR results proved that the CoOMT transgene was successfully introduced into Nicotiana tabacum L.

GmDREB6, a soybean transcription factor, notably affects the transcription of the and genes in transgenic tobacco under salt stress conditions.

Soil is contaminated with salinity, which inhibits plant growth and development and reduces crop yields. The (dehydration responsive element binding protein) gene responds to salt stresses through enhanced transcriptional expression and activation of genes involved in plant salinity resistance. In this study, we present the results of the analysis of the expression of the transgene, a gene that encodes the soybean DREB6 transcription factor, regulating the transcription of the and genes in transgenic tobacco under salt stress conditions.