ABSTRACT
ABSTRACT The carapace of the tortoise Chinemys reevesii is an ingredient of "Guijia", a traditional Chinese medicine. However, C. reevesii is difficult to raise in aquaculture and is rare in the wild. Counterfeit tablets are made from carapaces of other species. In addition to C. reevesii, other species including Mauremys sinensis, Indotestudo elongate and Trachemys scripta have been used in Plastrum Testudinis as well. After processing, these carapaces are difficult to identify on the basis of morphological characteristics, which impedes law enforcement. Our study used DNA barcoding technology to identify C. reevesii and its substitutes. We extracted concentrated genomic DNA for PCR amplification. Based on the analysis of 61 full-length COI sequences, we designed four pairs of mini-barcode primers: Tu-A, Tu-B, Tu-C and Tu-D. The Tu-B primers sequenced genomic DNA with a success rate of 76.47%, and the Tu-D primers sequenced genomic DNA with a success rate of 88.24%. The identification efficiency of these two mini-barcodes was 70.59% and 64.71%, and the overall identification efficiency was approximately 76.47%. Similarly, a set of mini barcode systems was generated, which may provide an effective and low-cost method for the identification of authentic tortoise shells.
ABSTRACT
ABSTRACT One-year-old Glycyrrhiza uralensis Fisch. ex DC, Fabaceae, was treated with three exogenous phytohormones in June and July, namely gibberellin, auxin (indole-3-acetic acid), methyl jasmonate at different concentrations. Control plants were treated with water. Roots of controls and hormones-treated G. uralensis plants were harvested at different times, and the contents of seven main chemical components were determined. Root glycyrrhizic acid content of plants treated in June increased significantly compared with controls, and the difference was significant. As for plants treated in July, root glycyrrhizic acid content increased in which sprayed with appropriate concentrations of hormones, but the effects of hormones were more evident in plants treated in June coincided with the vigorous growth period than those treated in July. Gibberellin at 40 mg/l and auxin at 40 mg/l applied in the two treatment periods significantly promoted the accumulation of glycyrrhizic acid in G. uralensis root. Treatment with methyl jasmonate at 100 and 25 mg/l in June and July, respectively, also increased glycyrrhizic acid content significantly. The determination of major active compositions indicated that liquiritin, isoliquiritin, isoliquiritin apioside and liquiritin apioside contents were positively related to glycyrrhizic acid content. The study preliminarily found phytohormones and the main chemical components associated with glycyrrhizic acid content, and these discoveries could provide a basis for establishing a chemical control network with glycyrrhizic acid as the core, confirming the secondary product metabolic pathways in the network and completely uncovering synthesis mechanism underlying glycyrrhizic acid-combined functional gene polymorphism.