西洋参中8种人参皂苷类成分的UPLC-MS/MS定量分析

建立超高效液相色谱串联三重四级杆质谱法(UPLC-MS/MS)同时测定西洋参中8种人参皂苷类成分(人参皂苷Rb1、人参皂苷Rb2、人参皂苷Rb3、人参皂苷Re、人参皂苷Rc、人参皂苷Rd、人参皂苷Rg1和拟人参皂苷F11)的定量分析方法。采用Waters Acquity BEH C18柱(100 mm×2.1 mm,1.7μm)色谱柱,流动相为0.1%甲酸水(A)-乙腈(B),梯度洗脱,流速0.25 m L/min,柱温35℃。电喷雾电离源(ESI),采用多反应检测模式(MRM),以保留时间及定性离子对之间的相对丰度定性,以定量离子对峰面积进行定量。定量分析西洋参中8种人参皂苷类成分在考察的浓度范围内呈良好的线性关系(r0.99);回收率和RSD分别在95.65%~103.34%,0.38%~4.33%。本研究所建立的同时测定西洋参中8种皂苷类成分的UPLC-MS/MS定量分析方法简便、快捷、准确,可为综合评价西洋参的质量提供参考。     

人参发根的诱导及其适宜培养条件的研究

利用发根农杆菌A₄菌株在人参根外植体上直接诱导产生发根。在1/2MS固体培养基上建立起发根离体培养系,经连续多代的培养,发根仍保持旺盛生长状态。PCR扩增结果表明,发根农杆菌R_I质粒的rolC基因已在人参发根基因组中整合并得到表达。液体培养基中发根生长速度约为固体培养的2倍。经对发根中人参皂苷含量及比生长速率的测定,筛选出高产发根系R9923。利用HPLC法测定了R9923发根系中单体皂苷Rg1、Re、Rf、Rb1、Rc、Rb2和Rd的含量,人参总皂苷含量达15.2mg/g。确定1/2MS培养液（30g/L蔗糖）、摇床转速110r/min、每２周更换一次培养液、继代培养时间4周,为人参发根生长适宜条件。探讨了培养容积、发根初始接种量以及分级放大培养工艺对发根大规模生产过程中生物产量和皂苷含量的影响。     

三七叶、人参叶和西洋参叶皂苷类成分的研究(英文)

三七叶、人参叶和西洋参叶其皂苷类成分相近,但专属性成分各异,皂苷类成分的分布比例也各不相同。本文建立了HPLC-UV法测定上述皂苷成分的方法,经过方法学考察,各种皂苷成分精密度好、加样回收率高,方法可靠。11种皂苷成分总含量顺序为:西洋参叶>人参叶>三七叶;二醇组皂苷成分含量:西洋参叶>三七叶>人参叶;三醇组皂苷成分含量:人参叶>西洋参叶>三七叶。西洋参叶中二醇组皂苷和人参叶中三醇组皂苷含量明显高于其他。西洋参叶中人参皂苷Rb3和Rd的含量之和占11种皂苷成分的60%以上。鉴于其中人参皂苷的高含量,三七叶、人参叶和西洋参叶应该作为皂苷来源得到充分利用;不同的皂苷成分有不同的药理活性,应基于它们的皂苷组成和比例选择性进行研究和开发。     

绵萆薢三萜皂苷类成分研究

为了解绵萆薢(Dioscorea spongiosa)的化学成分,从其70%乙醇水溶液提取物中分离鉴定了8个化合物,经理化性质和波谱数据分析分别鉴定为:20(S)-人参皂苷Rh1(1)、人参皂苷Rg1(2)、人参皂苷Re(3)、三七皂苷R1(4)、人参皂苷Rd(5)、人参皂苷Rb1(6)、常青藤皂苷元3-O-α-L-吡喃阿拉伯糖苷(7)和木通皂苷D(8)。化合物1、2、3、5和6为首次从该种植物中分离得到,化合物7和8为首次从薯蓣属植物中分离得到。     

人参生殖器官皂苷含量动态变化

为了明确从现蕾、开花到结实过程中的人参生殖器官中各单体皂苷含量的动态变化,应用HPLC法测定了人工栽培的五年生人参不同时期生殖器官中的人参单体皂苷Rb1、Rb2、Rb3、Rc、Rd、Re、Rg1和Rg3的含量。结果显示:从现蕾到果实成熟的过程中,人参单体皂苷Rb1、Rb2、Rb3、Rc、Rd、Re、Rg1和Rg3的含量的平均值分别为0.643%,0.189%,1.026%,1.014%,1.941%,8.381%,0.724%和0.041mg.g-1。从现蕾到果实成熟的过程中,人参单体皂苷Rb1含量的最高值在7月16日,单体皂苷Rb3、Rc、Rd和Rg1含量的最高值在7月11日,单体皂苷Rb2和Rg2含量的最高值在8月7日。     

西洋参总皂苷酶水解产物成分研究

西洋参总皂苷经β-糖苷酶催化水解,采用HPLC检测分析确定西洋参总皂苷中的主要原人参二醇型皂苷Rb1、Rd、Rc和Rb2已经完全被水解。水解产物通过反复硅胶柱层析和反向硅胶柱层析分离纯化得到7个皂苷,通过NMR谱图分析分别鉴定为人参皂苷compound K(1)、人参皂苷Mc(2)、人参皂苷Rg1(3)、人参皂苷Rg2(4)、人参皂苷Re(5)、人参皂苷F1(6)和拟人参皂苷F11(7)。β-糖苷酶催化西洋参总皂苷水解实验表明,西洋参中原人参二醇型皂苷的水解产物是人参皂苷compound K和人参皂苷Mc。     

蜗牛酶中一种人参皂苷Rb1水解酶的分离纯化

通过DEAE-Sepharose离子交换分段层析,DEAE-Sepharose离子交换梯度层析和Sephadex G100凝胶过滤层析三种方法的联用从中华白玉蜗牛消化酶中分离出一种人参皂苷Rb1水解酶。分离后该酶在SDS-PAGE上呈单一蛋白质条带。应用SDS-PAGE和凝胶过滤层析对分子量的测定,提示该酶是由4个分子量为110～115 kD的相同亚基组成的同源四聚体。Rb1为底物的动力学参数K_m和V_max分别为0.790 mmol/L和10.192 μmol/min/mg。该酶对人参皂苷Rb₁糖键进行有选择的水解,可水解人参皂苷Rb₁C₂₀位的一个糖苷键生成人参皂苷Rd。     

HPLC法同时测定人参皂苷Rb1、Rc、Rd、Rg3、CK和Rh2

目的:建立高效液相色谱法同时测定人参皂苷Rb1、Rc、Rd、Rg3、CK和Rh2的方法.方法:采用ODSC18(4.6 mm×150 mm)色谱柱,流动相乙腈-0.05%磷酸水,梯度洗脱,流速1 Ml/min,检测波长203 nm,柱温35 ℃.结果:人参皂苷Rb1、Rc、Rd、Rg3、CK和Rh2分离效果良好,线性关...     

黑曲霉降解人参皂苷Rb1制备稀有皂苷Compound K

稀有人参皂苷Compound K(C-K)具有显著的生物学活性。从东北农耕土壤中分离出9株真菌,系统研究了其转化人参皂苷Rb1制备C-K的能力。其中,黑曲霉Aspergillus niger sp.J7能够高效转化人参皂苷Rb1生成C-K,转化途径为Rb1→Rd→F2→C-K。对黑曲霉J7转化Rb1制备C-K的条件进行优化,在最优条件下,Rb1可完全转化成C-K。将该转化体系扩大到200 m L,60 h内可将Rb1完全转化成C-K,转化率为74.7%。黑曲霉J7为人参皂苷Rb1高效水解为稀有人参皂苷C-K奠定了基础。     

专一转化人参二醇类皂苷Rb1为Rd的真菌菌株的筛选

于2009年的7－10月间在辽宁省的桓仁,吉林省的集安、靖宇、抚松等药材产区采集人参及人参根际土壤样品45份。通过真菌分离和培养,共获得真菌菌株105株,经形态学鉴定分属于15属48种。通过活性筛选,得到具有转化人参总皂苷活性的菌株25株,其中菌株SR87和SR105对人参皂苷Rb1具有专一转化活性。通过TLC和HPLC检测,其转化产物为人参皂苷Rd。经形态学鉴定,确定阳性菌株SR87为莫勒接霉Zygorhynchus moelleri,SR105为灰绿犁头霉Absidia glauca。这两株真菌均有较高的转化潜力,可以应用于制备人参皂苷Rd。     

Ginsenoside Rb1 promotes adipogenesis in 3T3-L1 cells by enhancing PPARgamma2 and C/EBPalpha gene expression

Evidence has accumulated that ginseng and its main active constituents, ginsenosides, possess anti-diabetic and insulin-sensitizing properties which may be partly realized by regulating adipocyte development and functions. In the present study, we explored the effect of ginsenoside Rb(1), the most abundant ginsenoside in ginseng root, on adipogenesis of 3T3-L1 cells. We found that with standard differentiation inducers, ginsenoside Rb(1) facilitated adipogenesis of 3T3-L1 preadipocytes in a dose-dependent manner; 10 microM Rb(1) increased lipid accumulation by about 56%. Treatment of differentiating adipocytes with 10 microM Rb(1) increased the expression of mRNA and protein of PPARgamma(2) and C/EBPalpha, as well as mRNA of ap2, one of their target genes. After the treatment of differentiating adipocytes with Rb(1), basal and insulin-mediated glucose uptake was significantly augmented, accompanied by the up-regulation of mRNA and protein level of GLUT4, but not of GLUT1. In addition, ginsenoside Rb(1) also inhibited the proliferation of preconfluent 3T3-L1 preadipocytes. Our data indicate that anti-diabetic and insulin-sensitizing activities of ginsenosides, at least in part, are involved in the enhancing effect on PPARgamma2 and C/EBPalpha expression, hence promoting adipogenesis.     

In vitro metabolism of ginsenosides by the ginseng root pathogen Pythium irregulare

The role of ginseng saponins (ginsenosides) as modulators or inhibitors of disease is vague, but our earlier work supports the existence of an allelopathic relationship between ginsenosides and soilborne microbes. Interestingly, this allelopathy appears to significantly promote the growth of the important ginseng pathogen, Pythium irregulare while inhibiting that of an antagonistic non-pathogenic fungus, Trichoderma hamatum. Herein we report on the apparent selective metabolism of 20(S)-protopanaxadiol ginsenosides by an extracellular glycosidase from P. irregulare. Thus, when P. irregulare was cultured in the presence of a purified (> 90%) ginsenoside mixture, nearly all of the 20(S)-protopanaxadiol ginsenosides (Rb1, Rb2, Rc, Rd, and to a limited extent G-XVII) were metabolized into the minor ginsenoside F2, at least half of which appears to be internalized by the organism. No metabolism of the 20(S)-protopanaxatriol ginsenosides (Rg1 and Re) was evident. By contrast, none of the ginsenosides added to the culture medium of the non-pathogenic fungus T. hamatum were metabolized. The metabolism of 20(S)-protopanaxadiol ginsenosides by P. irregulare appears to occur through the hydrolysis of terminal monosaccharide units from disaccharides present at C-3 and/or C-20 of ginsenosides Rb1, Rc, Rb2, Rd and G-XVII to yield one major product, ginsenoside F2 and one minor product (possibly G-III). A similar transformation of ginsenosides was observed using a crude protein preparation isolated from the spent medium of P. irregulare cultures.     

Simultaneous Determination and Analysis of Major Ginsenosides in Wild American Ginseng Grown in Tennessee

Ginsenosides are the major constituent that is responsible for the health effects of American ginseng. The ginsenoside profile of wild American ginseng is ultimately the result of germplasm, climate, geography, vegetation species, water, and soil conditions. This is the first report to address the ginsenoside profile of wild American ginseng grown in Tennessee (TN), the third leading state for production of wild American ginseng. In the present study, ten major ginsenosides in wild American ginseng roots grown in TN, including Rb1, Rb2, Rb3, Rc, Rd, Re, Rf, Rg1, Rg2, and Rg3, were determined simultaneously. The chemotypic differences among TN wild ginseng, cultivated American ginseng, and Asian ginseng were assessed based on the widely used markers of ginsenoside profiling, including the top three ginsenosides, ratios of PPD/PPT, Rg1/Rb1, Rg1/Re, and Rb2/Rc. Our findings showed marked variation in ginsenoside profile for TN wild ginseng populations. Nevertheless, TN wild ginseng has significant higher ginsenoside content and more ginsenoside diversity than the cultivated ginseng. The total ginsenoside content in TN wild ginseng, as well as ginsenosides Rg1 and Re, increases with the age of the roots. Marked chemotypic differences between TN wild ginseng and cultivated American ginseng were observed based on the chemotypic markers. Surprisingly, we found that TN wild ginseng is close to Asian ginseng with regard to these characteristics in chemical composition. This study verified an accessible method to scientifically elucidate the difference in chemical constituents to distinguish wild from the cultivated American ginseng. This work is critical for the ecological and biological assessments of wild American ginseng so as to facilitate long‐term sustainability of the wild population.     

人参皂苷与生态因子的相关性

环境条件影响中药材活性成分的形成和积累.利用各种数学统计分析方法探讨影响人参皂苷积累的生态因子,提高人参品质.人参样品采自人参道地产区(主产区)吉林、辽宁、黑龙江三省5年生栽培人参,同时采集采样点处的土壤样品.超高效液相(UPLC)色谱法分析了不同产区9种人参皂苷(Rg1、Re、Rf、Rg2、Rb1、Rc、Rb2、Rb3、Rd)的含量;利用“中药材产地适宜性分析地理信息系统”的生态因子空间数据库,获得采样区包括温度、水分、光照等10个生态因子数据;按土壤理化性质常规方法测定土壤样品中的有效硼、有效铁等微量元素和速效氮、速效钾等有效养分.对人参有效成分含量与土壤养分进行典型相关性分析发现,土壤中的有效硼、有效铁、速效氮与人参皂苷含量呈显著正相关,即适当提高土壤中有效硼、有效铁和速效氮的含量可以促进人参皂苷成分的积累,土壤水分与所测人参皂苷含量(Rb3除外)呈显著正相关,速效磷(P)、pH、速效锌(Zn)与各人参皂苷含量呈弱相关;人参皂苷与气候因子相关分析表明,温度(年活动积温、年平均气温、7月最高气温、7月平均气温、1月最低气温、1月平均气温)与人参皂苷含量呈显著负相关,其中与药典中人参含量测定项下的人参皂苷Rg1、Re、Rb1负相关尤为显著(r＞0.6),说明在一定温度范围内,人参皂苷是随着温度的降低而升高的,即适当低温有利于人参皂苷有效成分的积累;海拔与人参皂苷Rc、Rb2、Rb3含量呈显著正相关(r＞0.6),即相对较高的海拔可以促进这3种成分的积累;而年均降水量、年相对湿度和年均日照时数与人参皂苷相关不显著.通过主成分分析(PCA)、典型相关分析、排序等统计方法,考察不同产地样品中人参皂苷含量与生态因子间的相关性,研究结果揭示了温度在人参的主要活性成分-皂苷类形成中起决定性作用,在一定的温度范围内,温度越低越有利于人参皂苷的积累;阐明了土壤中的有效硼、有效铁、速效氮与人参皂苷含量成正相关.研究结果提示在人参实践生产中可以通过适当低温处理,增施硼、铁、氮肥等农艺措施来调控人参皂苷含量.     

Microbial conversion of ginsenoside Rd from Rb1 by the fungus mutant Aspergillus niger strain TH-10a

Ginsenoside Rd, one of the ginsenosides with significant pharmaceutical activities, is getting more and more attractions on its biotransformation. In this study, a novel fungus mutant, the Aspergillus niger strain TH-10a, which can efficiently convert ginsenoside Rd from Rb1, was obtained through screening survival library of LiCl and ultraviolet (UV) irradiation. The transformation product ginsenoside Rd, generated by removing the outer glucose residue from the position C20 of ginsenoside Rb1, was identified through high-performance liquid chromatography (HPLC) analysis. Factors for the microbial culture and biotransformation were investigated in terms of the carbon sources, the nitrogen sources, pH values, and temperatures. This showed that maximum mycelia growth could be obtained at 28°C and pH 6.0 with cellobiose and tryptone as the carbon source and the nitrogen source, respectively. The highest transformation rate (～86%) has been achieved at 32°C and pH 5.0 with the feeding time of substrate 48 hr. Also, Aspergillus niger strain TH-10a could tolerate even 40 mg/mL ginseng root extract as substrate with 60% bioconversion rate after 72 hr of treatment at the optimal condition. Our results highlight a novel ginsenoside Rd transformation fungus and illuminate its potentially practical application in the pharmaceutical industries.     

Understory light and root ginsenosides in forest-grown Panax quinquefolius

The objective of this study was to determine the relationship between light levels in the understory of a broadleaf forest and the content of six ginsenosides (Rg(1), Re, Rb(1), Rc, Rb(2,) and Rd) in 1- and 2-year-old American ginseng (Panax quinquefolius L.) roots. Our results revealed that ginsenoside contents in 1- and 2 year-old roots collected in September were significantly related to direct and total light levels, and duration of sunflecks. At this time, the effect of light levels accounted for up to 48 and 62% of the variation in ginsenoside contents of 1- and 2-year-old American ginseng roots. Also, red (R) and far red (FR) light, and the R:FR ratio significantly affected Rd, Rc, and Rg(1) contents in 2-year-old roots, accounting for up to 40% of the variation in ginsenoside contents.     

小型生物反应器内人参不定根的人参皂苷累积

对小型生物反应器(3~10 L)培养人参不定根的生长和人参皂苷(Rg1、Re、Rb1)的累积规律,以及蔗糖浓度、初始接种量对其生长和人参皂苷累积的影响进行研究。结果表明:小型生物反应器内人参不定根的最佳收获周期为7周。初始接种量和蔗糖浓度影响生物反应器内人参不定根的生长和人参皂苷的累积,20或40 g/L蔗糖对人参不定根的生长和人参皂苷的累积优于60 g/L蔗糖;5和10 L生物反应器内最佳初始接种量分别为15和30g,其不定根的生长量分别为9.29和19.17 g,人参皂苷含量分别为5.16和4.58 mg/g。生物反应器内培养7周的人参与栽培4年的人参相比,人参皂苷Rg1和Re含量相差不大,但栽培人参中Rb1的含量远高于生物反应器中所培养的人参不定根。     

Methyl jasmonate elicitation enhanced synthesis of ginsenoside by cell suspension cultures of Panax ginseng in 5-l balloon type bubble bioreactors

The effects of methyl jasmonate (MJ) elicitation on the cell growth and accumulation of ginsenoside in 5-l bioreactor suspension cultures of Panax ginseng were investigated. Ginsenoside accumulation was enhanced by elicitation by MJ (in the range 50–400 M); however, fresh weight, dry weight and growth ratio of the cells was strongly inhibited by increasing MJ concentration. The highest ginsenoside yield was obtained at 200 M MJ. In the second experiment, 200 M MJ was added on day 15 during the cultivation. The ginsenoside, Rb group, and Rg group ginsenoside content increased 2.9, 3.7, and 1.6 times, respectively, after 8 days of MJ treatment. Rb group gisnsenosides accumulated more than Rg group ginsenosides. Among Rb group ginsenosides, Rb1 content increased significantly by four times but the contents of Rb2, Rc and Rd increased only slightly. Among Rg group ginsenosides, Rg1 and Re showed 2.3-fold and 3.0-fold increments, respectively, whereas there was only a slight increment in Rf group ginsenosides. These results suggest that MJ elicitation is beneficial for ginsenoside production using 5-l bioreactor cell suspension cultures.     

Effects of ginsenosides on glycine receptor alpha1 channels expressed in Xenopus oocytes

Ginsenosides, major active ingredients of Panax ginseng, are known to regulate the excitatory ligand-gated ion channel activity. Recent reports showed that ginsenosides attenuate nicotinic acetylcholine and NMDA receptor channel activity. However, it is not known whether ginsenosides also affect the inhibitory ligand-gated ion channel activity. We investigated the effect of ginsenosides on human glycine alpha1 receptor channel activity expressed in Xenopus oocytes using a two-electrode voltage clamp technique. Treatment of ginsenoside Rf enhances glycine-induced inward peak current (IGly) with dose dependent and reversible manner but ginsenoside Rf itself did not elicit membrane currents. The half-stimulatory concentrations (EC50) of ginsenoside Rf was 49.8 +/- 8.9 microM. Glycine receptor antagonist strychnine completely blocked the inward current elicited by glycine plus ginsenoside Rf. Cl- channel blocker 4,4'-disothiocyanostilbene-2,2'-disulfonic acid (DIDS) also blocked the inward current elicited by glycine plus ginsenoside Rf. We also tested the effect of eight individual ginsenosides (i.e., Rb1, Rb2, Rc, Rd, Re, Rg1, Rg2, and Ro) in addition to ginsenoside Rf. We found that five of them significantly enhanced the inward current induced by glycine with the following order of potency: Rb1 > Rb2 > Rg2 > or = Rc > Rf > Rg1 > Re. These results indicate that ginsenosides might regulate gylcine receptor expressed in Xenopus oocytes and this regulation might be one of the pharmacological actions of Panax ginseng.     

High-performance liquid chromatography coupled with tandem mass spectrometry applied for metabolic study of ginsenoside Rb1 on rat

Liquid chromatography coupled with mass spectrometry and tandem mass spectrometry has been applied to investigate the in vivo metabolism of ginsenoside Rb(1) in rat. Both positive electrospray ionization mass spectrometry and negative electrospray ionization mass spectrometry were used to identify the Rb(1) and its metabolites in rat plasma, urine, and feces samples. Oxygenation and deglycosylation were found to be the major metabolic pathways of Rb(1) in rat. A total of nine metabolites were detected in urine and feces samples collected after intravenous and oral administration. Deglycosylated metabolism of Rb(1) generated other ginsenosides as the major metabolites, such as Rd, Rg(3) or F(2), Rh(2), or C-K. This result indicates that the ginsenoside Rb(1) has many pharmacological activities and could be used as a prodrug.