Curcuma amada Roxb. (Zingiberaceae), commonly known as mango ginger because its rhizome and foliar parts have a similar aroma to mango. The rhizome has been widely used in food industries and alternative medicines to treat a variety of internal diseases such as cough, bronchitis, indigestion, colic, loss of appetite, hiccups, and constipation. The composition of the volatile constituents in a fresh rhizome of C. amada is not reported in detail. The present study aimed to screen and characterize the composition of volatile organic compound (VOC) in a fresh rhizome of three C. amada (ZO45, ZO89, and ZO114) and one C. longa (ZO138) accessions originated from Myanmar. The analysis was carried out by means of headspace solid-phase microextraction (HS-SPME) coupled with gas chromatography-time-of-flight-mass spectrometry (GC-TOF-MS). As a result, 122 VOCs were tentatively identified from the extracted 373 mass spectra. The following compounds were the ten most highly abundant and broadly present ones: ar-turmerone, α-zingiberene, α-santalene, (E)-γ-atlantone, cuparene, β-bisabolene, teresantalol, β-sesquiphellandrene, trans-α-bergamotene, γ-curcumene. The intensity of ar-turmerone, the sesquiterpene which is mainly characterized in C. longa essential oil (up to 15.5–27.5%), was significantly higher in C. amada accession ZO89 (15.707 ± 5.78a) compared to C. longa accession ZO138 (0.300 ± 0.08b). Cis-α-bergamotene was not detected in two C. amada accessions ZO45 and ZO89. The study revealed between-species variation regarding identified VOCs in the fresh rhizome of C. amada and C. longa.
The emissions of volatile organic compounds (VOCs) strongly depend on the plant species and are differently represented in specific taxa. VOCs have a degree of chemical diversity and also can serve as chemotaxonomic markers. Zingiber barbatum Wall. is a wild medicinal ginger plant endemic to Myanmar whose VOC composition has never been screened before. In this study, we screened the rhizome of Z. barbatum to identify the VOC composition by the application of gas chromatography combined with time-of-flight-mass spectrometry (GC-TOF-MS). The resulting VOC profile of Z. barbatum showed that it consists mainly of monoterpenes (21%) and sesquiterpenes (30%). Intraspecific similarities and dissimilarities were found to exist between Z. barbatum genotypes in terms of VOC composition. Four accessions (ZO191, ZO223, ZO217, and the control accession ZO105) collected from the Shan State and Mandalay region of Myanmar were found to share a similar VOC profile, while two accessions (ZO64 and ZO160) collected from the Bago region were found to vary in their VOC profiles compared with the control accession. The two identified compounds, i.e., α-bergamotene and β-(E)-guaiene may serve as discriminative chemical markers for the characterization of Z. barbatum species collected in these three geographical regions of Myanmar. This study represents a first attempt to identify and describe the VOCs in the medicinal species Z. barbatum that have not been reported to date.
Field surveys of Ephedra plants were conducted in the Zaravshan Mountains of Tajikistan. E. equisetina, E. intermedia, and their putative hybrids were collected. They were identified based on their phenotypes and their sequences of nuclear ribosomal DNA internal transcribed spacer 1 (ITS1) region. Sequencing and species-specific PCR analyses of their ITS1 sequences revealed six putative hybrids of E. equisetina and E. intermedia. The total ephedrine and pseudoephedrine content of most of the Ephedra samples collected in Tajikistan were higher than the 0.7% lower limit prescribed by the Japanese pharmacopoeia, 17th edition (JP17), and varied from 0.34 to 3.21% by dry weight. The total alkaloid level of E. intermedia (11E08-1) cultivated in Japan varied from 1.77 to 2.30% by dry weight, which was much higher than the 0.7% lower limit prescribed by JP17.
Polyploidization can be a way to produce new varieties in vegetatively propagated species where options on increasing genetic variability are limited compared with sexual reproduction. While there are hundreds of publications with in vitro methods in somatic doubling, it is cardinal to custom-test for a target species of interest on choosing specific reagents and optimizing conditions. This research was performed to provide a reference process for Zingiberaceae species of which the majority is reproduced with vegetative propagation. Ginger lilies, Hedychium gardnerianum Shepard ex Ker Gawl. and Hedychium coronarium J. Koenig, were employed to optimize chromosome doubling for tetraploid production as they are typically used by vegetative propagation. However, they have the popularity as ornamentals globally due to their horticultural aspects. Tetraploid induction was optimized by in vitro somatic chromosome doubling on H. coronarium and H. gardnerianum through callogenesis. The explant segments of young leaf blades or leaf sheaths were treated with different concentrations of either with colchicine or with oryzalin. The regenerated shoots from callus cultures were transferred to basal MS medium for 2mo to confirm somatic stability. The ploidy was assessed by flow cytometry, measuring the size and density of stomata, counting chromosomes, and chloroplasts in guard cells. The highest percentage of tetraploid regenerated plants was observed with 1250 µM colchicine treatment for Hedychium gardnerianum when compared to the other treatments tested, while no tetraploid plants were obtained from the oryzalin treatment. In H. coronarium, four mixoploid regenerated plants treated with 15 µM oryzalin were confirmed and no shoots were obtained from the colchicine treatment. The results indicated that the in vitro polyploid induction is optimized with the two Hedychium species, which could reference other Zingiberaceae species.
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