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ObjectiveUltra-performance liquid chromatography-quadrupole-time-of-flight tandem mass spectrometry (UPLC-Q-TOF-MS/MS) was used to analyze the chemical constituents in the aerial part and roots of Gentiana straminea from different areas of Qinghai province, and the main chromatographic peaks and differential components of different parts were identified. MethodThe chromatographic separation was performed on a Waters ACQUITY UPLC HSS T3 column (2.1 mm×100 mm, 1.8 μm) with 0.1% formic acid aqueous solution (A)-acetonitrile (B) as the mobile phase for gradient elution (0-1 min, 1%-13%B; 1-5 min, 13%-18%B; 5-7 min, 18%-50%B; 7-9.5 min, 50%-60%B; 9.5-11 min, 60%-99%B; 11-14 min; 99%B; 14-15 min, 99%-1%B; 15-16 min, 1%B), the column temperature at 40 ℃, and the flow rate of 0.3 mL·min-1. Electrospray ionization (ESI) and negative ion full scan mode were selected for the mass spectrometric conditions to analyze the samples, and the detection range was m/z 50-1 200. Chemical constituents of the aerial part were qualitatively analyzed with the reference substances, literature information and ChemSpider. Principal component analysis (PCA) and orthogonal partial least squares discriminant analysis (OPLS-DA) were used to analyze the classification trend, correlation and differential chemical components between aerial part and roots of G. straminea. ResultA total of 68 components, including 24 iridoids, 13 flavonoids, 8 triterpenoids, 6 xanthones, 5 fatty acids, 4 saccharides, 3 phenolic glycosides, 2 alkaloids, 2 sterols and 1 lignan, were preliminarily identified from the aerial part of G. straminea. Among them, 42 components were firstly reported in 4 Gentiana species included in the 2020 edition of Chinese Pharmacopoeia. Eight differential components were screened out, namely sucrose, maltotriose, loganic acid, shanzhiside methyl ester, 6′-O-β-D-glucosylgentiopicroside, swertiamarin, gentiopicrin and isovitexin. ConclusionThe aerial part of G. straminea is rich in chemical constituents and has good medicinal potential. There were significant differences in the chemical components between the aerial part and roots of G. straminea, and the main differential components were iridoids, which could provide a basis for exploring efficacy differences in different parts of G. straminea.
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Objective: To assess the genetic diversity of Gentiana straminea (Gentianaceae). Methods: Intersimple sequence repeat (ISSR) markers were used. Twenty-eight populations (83 individuals) of G. straminea were sampled from Sichuan, Qinghai, Gansu provinces, and Autonomous Region of Tibet. ISSR data were analyzed with the program POPGEN, and a UPGMA dendrogram was constructed. Results: PCR products corresponding to 183 alleles at 95 loci, amplified by the seven primers were scored. Eighty-eight loci were polymorphic. Expected heterozygosity (He) and Shannon's information index (Im) were 0.288 2 and 0.437 1, respectively. Nei's coefficient of genetic differentiation (Gst) and gene flow (Nm) were 0.678 3 and 0.237 1 at the population level, respectively. The genetic distance varied from 0.074 3 to 0.490 0. G. straminea populations were mainly divided into two braches by UPGMA tree. Conclusion: Genetic diversity level of G. straminea is high, and genetic diversity level among populations of G. straminea is higher than that in one population; Its autogenous variation mainly exist among populations; Hereditary capacity has certain correlation with geographical distribution. This work contributes basic information for variety identification, species in situ conservation, and enviroment investigation on the influence of heredity differentiated and Chinese Materia Medica genuine study. The congruence between genetic distance and geographic distances is high.
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This paper is aimed to predict ecology suitability distribution of Gentianae Macrophyllae Radix and search the main ecological factors affecting the suitability distribution. The 313 distribution information about G. macrophylla, 186 distribution information about G. straminea, 343 distribution information about G. dauricaand 131 distribution information about G. crasicaulis were collected though investigation and network sharing platform data . The ecology suitable distribution factors for production Gentianae Macrophyllae Radix was analyzed respectively by the software of ArcGIS and MaxEnt with 55 environmental factors. The result of MaxEnt prediction was very well (AUC was above 0.9). The results of predominant factors analysis showed that precipitation and altitude were all the major factors impacting the ecology suitable of Getiana Macrophylla Radix production. G. macrophylla ecology suitable region was mainly concentrated in south of Gansu, Shanxi, central of Shaanxi and east of Qinghai provinces. G. straminea ecology suitable region was mainly concentrated in southwest of Gansu, east of Qinghai, north and northwest of Sichuan, east of Xizang province. G. daurica ecology suitable region was mainly concentrated in south and southwest of Gansu, east of Qinghai, Shanxi and north of Shaanxi province. G. crasicaulis ecology suitable region was mainly concentrated in Sichuan and north of Yunnan, east of Xizang, south of Gansu and east of Qinghai province. The ecological suitability distribution result of Gentianae Macrophyllae Radix was consistent with each species actual distribution. The study could provide reference for the collection and protection of wild resources, meanwhile, provide the basis for the selection of cultivation area of Gentiana Macrophylla Radix.
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Objective: To study the genetic diversity of 17 samples of Gentiana straminea from different habitats of Tibet. Methods: Sampling in populations was carried out, and the related species G. crassicaulis from the same area was as the out group; nr DNA ITS sequences were amplified and analyzed; UPGMA systematic tree was constructed. Results: One polymorphic site of G. straminea from Tibet was found; the six samples of out group have the identical DNA ITS sequences. Conclusion: The difference between G. straminea and the out group is obvious; seventeen samples of G. straminea from different habitats are divided into two groups; genetic diversity is more abundant; the result could provide the basic reference for the quality evaluation and the construction of core germplasm of G. straminea in Tibet.
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Objective To study the non-iridoid constituents from the roots of Gentiana straminea.Methods The compounds were repeatedly separated and purified on column chromatography of silica gel,Sephadex LH-20,and ODS,and their structures were identified on the basis of spectral and chemical methods.Results Twelve compounds were isolated from 70% ethanol extract of G.straminea and were identified as(-)-syringaresinol-4,4′-bis-?-O-D-glucopyranoside(1),gentiaphyllide-D(2),erythrecentaurin(3),macrophyiioside D(4),gentiaphyllide-E(5),roburic acid(6),uvaol(7),?-sitosterol(8),daucosterol(9),gentianose(10),?-glucose(11),and ?-glucose(12),respectively.Conclusion Compounds 1-6 and 10 are isolated from this plant for the first time.
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Objective To establish the fingerprint of Gentiana straminea from Qinghai Province by HPLC. Methods By orthogonal design and related methods based on information theories and chemometrics to optimize the proper HPLC conditions so that the fingerprint spectra of ten groups of different samples have been formed. Results The experimental results are the fact that the common fingerprint peaks, precision, and repeatability in the fingerprint totally meet the relative regulations required in Technical Requirements of the Fingerprint Research in Injection of Chinese Materia Medica (Tentatine Standard). Conclusion The chromatographic fingerprint can be used to identify and evaluate the quality of G. straminea.
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AIM: To establish the HPLC fingerprint of Genti ana straminea Maxim. METHODS: It was adopted gradient with Methanol and 0.4% phospho ric acid, the detection wavelength was at 230nm and recording time. And it w as compared with a software published by Zhejiang University. RESULTS: The constituents of Gentiana straminea Maxim. were well se parated by HPLC, and the similarity was more than 0.90 . CONCLUSION: The method can be used as the fingerprint of G entiana straminea Maxim.