RESUMEN
Hoya verticillata var verticillata, an epiphytic plant, is both an ornamental and a valuable medicinal plant. However, H. verticillata has a similar morphology to other species belonging to the Hoya genus, so it is challenging to distinguish the H. verticillata var verticillata, plant accurately. Alternatively, if H. verticillata var verticillata, is deformed or powdered, it is more challenging to identify. This dataset includes information on H. verticillata var verticillata, samples collected from the natural environment and four chloroplast DNA markers to support H. verticillata var verticillata, species identification. Phylogenetic analysis based on sequences of intergenic spacer regions (trnK-rps16, rps16-trnQ, psbI-atpA, and ndhC-trnV) shows that H. verticilata var verticillata, is very closely related and distributed in the same group as Hoya carnosa with a Bootstrap coefficient of 99-100 %. Four intergenic spacer region sequences, trnK-rps16, rps16-trnQ, psbI-atpA, and ndhC-trnV from the chloroplast genome are potential DNA barcoding candidates to distinguish H. verticilata var verticillata, from different species in the Hoya genus.
RESUMEN
Ficus simplicissima Lour. is an Asian species of fig tree in the family Moraceae. The chloroplast (cp) genome of F. simplicissima m3 was sequenced using the Pacbio sequel platform. The F. simplicissima cpDNA has a size of 160,321 bp in length, of which GC content accounts for 36.13%. The cp genome of F. simplicissima consists of a single large copy (LSC) with a size of 91,346 bp, a single small copy (SSC) with a size of 20,131 bp, and a pair of inverted repeats with a size of 24,421 to 24,423 bp. The cp genome of F. simplicissima has 127 genes, including 85 protein-coding genes, eight rRNA genes, and 34 tRNA genes; 92 simple sequence repeats and 39 long repeats were detected in the cpDNA of F. simplicissim. A comparative cp genome analysis among six species in the Ficus genus indicated that the genome structure and gene content were highly conserved. The non-coding regions show more differentiation than the coding regions, and the LSC and SSC regions show more differences than the inverted repeat regions. Phylogenetic analysis supported that F. simplicissima m3 had a close relationship with F. hirta. The complete cp genome of F. simplicissima was proposed as a chloroplast DNA barcoding for genus-level in the Moraceae family and the psbA-trnH gene region for species-level identification.
RESUMEN
Soil is contaminated with salinity, which inhibits plant growth and development and reduces crop yields. The DREB (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 GmDREB6 transgene, a gene that encodes the soybean DREB6 transcription factor, regulating the transcription of the NtP5CS and NtCLC genes in transgenic tobacco under salt stress conditions. The transcription of GmDREB6, NtP5CS, and NtCLC in transgenic tobacco lines was confirmed by qRT-PCR. Under salt stress conditions, the GmDREB6 gene transcription levels in the transgenic tobacco lines L1 and L9 had increased from 2.40- to 3.22- fold compared with the condition without salinity treatment. Two transgenic lines, L1 and L9, had transcription levels of the P5CS gene that had increased from 1.24- to 3.60- fold compared with WT plants. For the NtCLC gene, under salt stress conditions, the transgenic lines had transcription levels that had increased by 3.65-4.54 (fold) compared with WT plants (P < 0.05). The L1-transgenic tobacco line showed simultaneous expression of both the GmDREB6 transgene and two intrinsic genes, the NtP5CS and NtCLC genes. This study demonstrated that expression of the GmDREB6 gene from soybean increases the transcription levels of the NtP5CS and NtCLC genes in transgenic tobacco plants under salt stress conditions. The analysis results have suggested that the GmDREB6 gene is a potential candidate for improving the salt tolerance of plants, opening up research and development opportunities for salt stress-tolerant crops to respond to climate change and the rise in sea levels.
