乌腺金丝桃愈伤组织中总黄酮及金丝桃素含量测定

以乌腺金丝桃新鲜叶片为材料,建立稳定的乌腺金丝桃愈伤组织的培养体系,进一步对愈伤组织总黄酮与金丝桃素的含量进行测定。以MS为基础培养基,考察不同激素组合对愈伤组织诱导的影响。结果表明,乌腺金丝桃诱导愈伤组织的最佳培养基为MS+2,4-D 4.0 mg/L+6-BA 0.2 mg/L;采用超声波法提取乌腺金丝桃愈伤组织中的总黄酮和金丝桃素,分别采用紫外分光光度法和HPLC法测定乌腺金丝桃愈伤组织中总黄酮及金丝桃素的含量,结果表明,干燥乌腺金丝桃愈伤组织中总黄酮含量为27.99 mg/g,金丝桃素的含量为0.515 mg/g。     

NO对金丝桃悬浮细胞生长及金丝桃素生物合成的促进作用研究

一氧化氮 (NO)是近年来发现的一种新型植物信号分子。以硝普钠 (Sodiumnitroprusside ,SNP)为一氧化氮 (NO)的供体 ,研究外源NO对金丝桃悬浮细胞生长及金丝桃素生物合成的影响。试验结果表明 ,金丝桃悬浮细胞在含 0 5和 15 0mmol LSNP的培养基中培养 2 0d后 ,细胞的干重分别为对照组的 140%和50% ;细胞中金丝桃素的含量分别为对照组的 98%和210%。试验结果表明 ,低浓度SNP处理有利于金丝桃悬浮细胞生长 ,而高浓度SNP可以促进金丝桃素的合成。在细胞培养初期 (0d)加入 0.5mmol LSNP并在指数生长后期 (14d)加入15.0mmol LSNP的金丝桃悬浮细胞在培养 2.5d后 ,细胞的干重和金丝桃素的含量分别为对照组的1.4和1.8倍 ,金丝桃素的产量达15.2mg/L ,比对照高3.2倍。SNP对金丝桃悬浮细胞生长及金丝桃素含量的影响可以被NO专一性淬灭剂CPITO(2-4-carboxyphenyl-4 ,4 ,5 ,5-tetramethylimidazoline-1-oxyl-3-oxide)所抑制,说明SNP是通过其分解产物NO影响细胞生长和金丝桃素的合成。试验结果同时表明,在15.0mmol/L的SNP处理下,金丝桃悬浮细胞中的苯丙氨酸解氨酶(PAL)的活性显著升高,推测NO可能通过触发金丝桃悬浮细胞的防卫反应,激活了细胞中金丝桃素的生物合成途径。     

金丝桃属植物分泌结构的类型和金丝桃素含量的相关性

利用整体透明,石蜡制片和半薄切片法,对金丝桃属（Hypericum L.)8组20种1变种植物的分泌结构进行了比较解剖研究,结果表明：该属植物的分泌结构可分泌细胞团和分泌囊两种类型,但在不同植物种和不同器官内,分泌结构的类型和分布密度存在差异,对上述植物的提取物进行薄层层析和高效液相层析检测,结果表明,具有分泌细胞团的植物器官含有金丝桃素,而无分泌细胞团的植物器官,则不含金丝桃素,从而证明金丝桃素由分泌细胞团合成和贮藏,在前中,其金丝桃素的含量与其分泌细胞团密度成正相关。     

贯叶连翘中金丝桃素的合成与积累研究进展

金丝桃素是贯叶连翘的主要药理活性成分。本文概述了金丝桃素的化学与生物合成途径,介绍了金丝桃素在贯叶连翘个体发育过程中的积累以及利用贯叶连翘的细胞和组织培养技术生产与积累金丝桃素的研究进展。最后,指出分子生物学和电子显微镜技术的发展为深入研究金丝桃素的产生和积累提供了有利工具。     

NO和H_2O_2在介导热激诱发金丝桃细胞合成金丝桃素中的信号互作

热激处理(40℃,10min)可以诱发金丝桃细胞中金丝桃素的生物合成并诱导细胞产生一氧化氮(NO)和过氧化氢(H2O2).过氧化氢酶(CAT)和NO专一性淬灭剂(cPTIO)不仅可以分别抑制由热激诱发的H2O2积累和NO合成,而且还可以阻断热激处理对金丝桃素生物合成的促进作用.H2O2单独处理虽然不能提高细胞的金丝桃素产量,但是H2O2和NO共同处理对金丝桃素产量的促进作用显著高于NO单独处理,表明NO和H2O2对金丝桃素的生物合成具有协同诱导效应.NO处理可以提高细胞的H2O2水平,而外源H2O2对金丝桃细胞的NO合成积累也具有促进作用,说明NO和H2O2对彼此的合成反应具有促进作用.CAT在抑制热激诱发H2O2合成的同时还能够部分抑制热激细胞中NO的合成,而cPITO也可以同时降低热激细胞的H2O2水平.上述实验结果提示,在热激处理下金丝桃细胞中的NO和H2O2可能通过互作反应提高各自的信号水平.质膜NAD(P)H氧化酶抑制剂DPI和NO合酶抑制剂PBITU可以抑制NO和H2O2之间的互作反应,并且解除NO和H2O2对金丝桃素合成的协同诱导作用,说明NO和H2O2对金丝桃素合成积累的协同效应依赖于两种信号分子之间的互作反应.本文实验结果不仅证实了NO和H2O2是参与热激诱发金丝桃细胞中金丝桃素合成所必需的两种信号分子,而且揭示了NO和H2O2在介导热激诱发金丝桃素生物合成过程中特殊的信号互作现象.     

NO和H2O2在介导热激诱发金丝桃细胞合成金丝桃素中的信号互作

热激处理（40℃,10min）可以诱发金丝桃细胞中金丝桃素的生物合成并诱导细胞产生一氧化氮（NO）和过氧化氢（H2O2）．过氧化氢酶（CAT）和NO专一性淬灭剂（cPTIO）不仅可以分别抑制由热激诱发的H2O2积累和NO合成,而且还可以阻断热激处理对金丝桃素生物合成的促进作用．H2O2单独处理虽然不能提高细胞的金丝桃素产量,但是H2O2和NO共同处理对金丝桃素产量的促进作用显著高于NO单独处理,表明NO和H2O2对金丝桃素的生物合成具有协同诱导效应．NO处理可以提高细胞的H2O2水平,而外源H2O2对金丝桃细胞的NO合成积累也具有促进作用,说明NO和H2O2对彼此的合成反应具有促进作用．CAT在抑制热激诱发H2O2合成的同时还能够部分抑制热激细胞中NO的合成,而cPITO也可以同时降低热激细胞的H2O2水平．上述实验结果提示,在热激处理下金丝桃细胞中的NO和H2O2可能通过互作反应提高各自的信号水平．质膜NAD（P）H氧化酶抑制剂DPI和NO合酶抑制剂PBITU可以抑制NO和H2O2之间的互作反应,并且解除NO和H2O2对金丝桃素合成的协同诱导作用,说明NO和H2O2对金丝桃素合成积累的协同效应依赖于两种信号分子之间的互作反应．本文实验结果不仅证实了NO和H2O2是参与热激诱发金丝桃细胞中金丝桃素合成所必需的两种信号分子,而且揭示了NO和H2O2在介导热激诱发金丝桃素生物合成过程中特殊的信号互作现象．     

贯叶金丝桃叶中分泌细胞团的超微结构

随着贯叶金丝桃（Hypericum perforatum L.)叶中分泌细胞团的发育,其细胞中质体的数量和体积逐渐增大,但一些质体局部出现解体,大量的深色管状结构和小泡出现在退化质体的周围,有些小泡与液泡融合,并将其内容物释放至液泡中,导致液泡中出现大量的多泡结构,多膜结构和嗜锇滴。同时,高尔基体分泌小泡进入液泡。然而,当分泌细胞团发育成熟后,分泌细胞被含有灰色均匀的分泌物（金丝桃素）的大液泡所占据,嗜锇滴消失。表明嗜锇滴可能是金丝桃素的前体物,来源于退化的质体。出现于质体和嗜锇滴之间的内质网和高尔基体可能也参与了金丝桃素前体物的合成和细胞内的转运。     

贯叶金丝桃叶中分泌细胞团的超微结构

随着贯叶金丝桃( Hypericum perforatum L.)叶中分泌细胞团的发育,其细胞中质体的数量和体积逐渐增大,但一些质体局部出现解体,大量的深色管状结构和小泡出现在退化质体的周围,有些小泡与液泡融合,并将其内容物释放至液泡中,导致液泡中出现大量的多泡结构、多膜结构和嗜锇滴.同时,高尔基体分泌小泡进入液泡.然而,当分泌细胞团发育成熟后,分泌细胞被含有灰色均匀的分泌物(金丝桃素)的大液泡所占据,嗜锇滴消失.表明嗜锇滴可能是金丝桃素的前体物,来源于退化的质体.出现于质体和嗜锇滴之间的内质网和高尔基体可能也参与了金丝桃素前体物的合成和细胞内的转运.     

中国金丝桃属金丝桃组(藤黄科)新分类群

描述了中国云南北部的金丝桃属Hypericum L.(藤黄科)两个新种,即楚雄金丝桃H. fosteri N. Robson和漾濞金丝桃H. wardianum N. Robson.二者均与短柱金丝桃H. hookerianum Wight & Arn.相近.楚雄金丝桃为一地方特有种,目前仅在模式地点发现;漾濞金丝桃在缅甸东北部还有分布.二者主要以蒴果伸长,非卵状近球形,萼片无中脉而有别于短柱金丝桃.此外,将宽萼金丝桃H. latisepalum (N. Robson) N. Robson从亚种提升为种;将变异较大的纤枝金丝桃H. lagarocladum N. Robson划分为两个亚种,即叶较宽、具有开张习性的原亚种纤枝金丝桃H. lagarocladum ssp. lagarocladum和叶较窄、更为直立的新亚种狭叶金丝桃H. lagarocladum ssp. angustifolium N. Robson.     

美丽金丝桃中的一个新桥环化合物

采用L1210细胞株对美丽金丝桃(Hypericum bellum Li)的粗提物及其分步萃取物进行了细胞毒试验,结果表明,美丽金丝桃的氯仿及乙酸乙酯萃取物具有细胞毒活性,其IC50分别为5．4和6．0μg/ml。在细胞毒试验结果指导下,同步对美丽金丝桃有效部位进行了化学成分分离。首次从该植物中得到3个化合物,通过理化数据测定及波谱数据分析,分别鉴定为4,4—二甲基—7α,8β—二羟基—3,5—二氧代二环[4．3．1]癸—1(10)—烯—2—酮(1),槲皮素(quercetin,2)及木犀草素(luteolin,3)。其中,1为一新桥环化合物,并通过2D NMR分析,对黄酮类化合物2及3的^13C NMR谱中的C5和C9数据指认进行了修正。     

A method for determination of iododeoxyuridine substitution of thymidine using reversed-phase high-performance liquid chromatography

An assay for thymidine substitution by iododeoxyuridine (IdUrd) using reversed-phase high-performance liquid chromatography (HPLC) has been developed. Three principal steps in this procedure are: extraction of DNA from cell or tissues, hydrolysis of DNA into deoxynucleosides and separation using HPLC. Approximately 1 microgram of DNA was recovered from 10(5) cells by phenol extraction, and subjected to hydrolysis into deoxynucleosides which required a three-stage DNA digestion using enzymes DNAse I. phosphodiesterase I and alkaline phosphatase. The deoxynucleosides were separated on the Microsorb C18 column with isocratic elution; 90-100% of the DNA was recovered as deoxynucleosides on the column. The method was used to determine quantitatively the percent IdUrd substitution of thymidine in Chinese hamster lung cells in vitro and BA1112 rhabdomyosarcoma in WAG/Rij rats perfused with IdUrd. It was possible to determine the thymidine substitution by IdUrd as small as 1% using a few micrograms of DNA. The close correspondence between the percent substitutions determined by HPLC and those determined by radioactive assay using [125I]-labelled IdUrd, confirmed the accuracy of our HPLC method. The HPLC analysis is especially suitable for the determination of percent IdUrd substitution of thymidine in tissue biopsies from animals used in in vivo experiments or humans undergoing radiation treatment.     

曲美他嗪人血浆蛋白结合率的测定

目的:建立测定曲美他嗪与人血浆蛋白结合率的高效液相色谱法(HPLC),测定曲美他嗪在人血浆中的蛋白结合率。方法:采用平衡透析法,结合HPLC测定曲美他嗪在人血浆中的蛋白结合率。结果:低、中、高3个浓度下,曲美他嗪的血浆蛋白结合率分别为14.7%,16.2%和15.5%。结论:本方法灵敏度高,重现性好,操作简单,能满足生物样品分析的要求。曲美他嗪与血浆蛋白结合率较低。     

Method development and validation of a high-performance liquid chromatographic method for tramadol in human plasma using liquid-liquid extraction

An HPLC system using a simple liquid-liquid extraction and HPLC with UV detection has been validated to determine tramadol concentration in human plasma. The method developed was selective and linear for concentrations ranging from 10 to 2000 ng/ml with average recovery of 98.63%. The limit of quantitation (LOQ) was 10 ng/ml and the percentage recovery of the internal standard phenacetin was 76.51%. The intra-day accuracy ranged from 87.55 to 105.99% and the inter-day accuracy, 93.44 to 98.43% for tramadol. Good precision (5.32 and 6.67% for intra- and inter-day, respectively) was obtained at LOQ. The method has been applied to determine tramadol concentrations in human plasma samples for a pharmacokinetic study.     

High-performance liquid chromatographic determination of phospholipid peroxidation products of rat liver after carbon tetrachloride administration

A method to detect and determine phospholipid peroxidation products in a biological system was developed using reversed-phase high performance liquid chromatography and normal-phase HPLC. Reversed-phase HPLC could separate phosphatidylcholine (PC) hydroperoxides and phosphatidylethanolamine (PE) hydroperoxides of rat liver from the respective phospholipids. A linear relationship was observed between these hydroperoxides and their peak areas on the chromatogram. In the experiment with rats administered CCl4, reversed-phase HPLC gave prominent, large peaks attributable to the peroxidation of phospholipids, and the peroxide level of the liver phospholipids was tentatively determined. Normal-phase HPLC analysis confirmed that both PC and PE in the liver phospholipids were peroxidized after CCl4 treatment. Neither the thiobarbituric acid value of the liver homogenate nor the fatty acid composition of the liver phospholipid fraction showed any significant difference between CCl4-treated and control rats. It is concluded that normal-phase HPLC and reversed-phase HPLC can complement each other to serve as a direct and sensitive method for the determination of lipid peroxide levels in a biological source. However, it was difficult to distinguish phospholipid hydroperoxides from their hydroxy derivatives.     

Elucidation of the structure of talinolol metabolites in man determination of talinolol and hydroxylated talinolol metabolites in urine and analysis of talinolol in serum

The objective of this study was to determine the structure of talinolol metabolites formed and the amounts excreted in urine. Talinolol metabolites in urine were identified by comparing their HPLC retention times and their GC—MS profile with those of previously characterized reference compounds. The metabolites were quantified by HPLC with a normal-phase silica column, a single chloroform extraction and UV detection. Less than 1% of an administered dose was found in urine as hydroxylated talinolol. Other metabolites could be excluded. A sensitive method to determine talinolol in serum and a simple method for analysis of talinolol in urine are described. These methods were found to be precise and accurate for the measurement of talinolol in samples obtained from patients during chronic talinolol treatment as well as from healthy volunteers after a single dose of talinolol.     

Determination of the absolute configuration of the sugar residues of complex polysaccharides by circular dichroism spectroscopy

Circular dichroism spectroscopy is used to determine the absolute configuration of the constituent sugar residues of bacterial polysaccharides from two strains of Streptococcus sanguis which are important receptors in bacterial coaggregation in the formation of dental plaque. A high-pressure liquid chromatographic method for carbohydrate analysis of glycoproteins, glycolipids, and polysaccharides has been extended to sugar chirality determination by collection of the eluted HPLC fractions and subsequent measurement of their circular dichroism spectra. The method involves methanolysis of the polysaccharide followed by formation of O-benzoyl derivatives and HPLC on reverse-phase columns. Circular dichroism spectra of the collected derivatives in acetonitrile solution in the region 230 nm show large ellipticity bands resulting from "chiral exciton" interaction among the O-benzoyl chromophores which are sensitive to the orientation of hydroxyl groups in the parent sugars. The sensitivity of the method is in the submicrogram range for the absolute configuration of single sugar residues. The circular dichroism of the intact polysaccharide in aqueous solution shows CD bands from the amide chromophore in the region 180 to 220 nm which are sensitive to the chirality of 2-acetamido sugar residues.     

Determination of propofol in low-volume samples by high-performance liquid chromatography with fluorescence detection

In order to determine propofol in rat whole-blood samples of 50 μl, we developed a rapid, simple and reliable method which is characterized by precipitation of blood elements with acetonitrile and submission of the supernatant to HPLC analysis with fluorescence detection. The method described is linear from 0.4 to 40 mg/l and the relative standard deviations in this concentration range are less than 10%. The limit of quantification proved to be 0.4 mg/l. Blood constituents do not interfere with the assay.     

A comparison of trihydroxyindole and HPLC/electrochemical methods for catecholamine measurement in adrenal chromaffin cells

Three commonly used methods for the determination of epinephrine and norepinephrine levels in adrenal medullary tissue were compared. Two variations of the trihydroxyindole procedure, which utilized oxidation at room temperature or 0°C, underestimated levels of total catecholamines in certain standard solutions and were unable to determine correctly their norepinephrine:epinephrine ratios. However, both the variability and the underestimation of the trihydroxyindole procedure carried out at room temperature were more pronounced than that of the trihydroxyindole assay at 0°C. In addition, we tested an isocratic HPLC method utilizing electrochemical detection which separates epinephrine from norepinephrine. The ability of this method to measure correctly total and individual catecholamine levels was superior to either trihydroxyindole procedure, as was its variability. When the three assay methods were used to measure total and individual catecholamine levels in cultured adrenal bovine chromaffin cells, both the trihydroxyindole (0°C) method and the HPLC method yielded values in agreement with those in the literature. However, the HPLC method produced data with lower error estimates. The trihydroxyindole (room temperature) assay was unable to reliably measure levels of epinephrine and norepinephrine in chromaffin cells.These comparisons of catecholamine assays demonstrated that there are circumstances under which the use of each is appropriate. In experiments where the epinephrine:norephinephrine ratio may be changing, the more accurate and precise HPLC assay may be essential, since the trihydroxyindole assays underestimate total catecholamines to varying degrees depending on this ratio. However, the HPLC method suffers from a requirement for technical sophistication for routine use. Therefore, in some laboratories and for repetitive measurement of many samples, the trihydroxyindole assay has a distinct advantage due to its easy utilization and ubiquitous materials. However, the superior results obtained with the trihydroxyindole (0°C) assay over the trihydroxyindole (room temperature) assay emphasizes the need to evaluate the trihydroxyindole procedure for the required purpose, especially if differential oxidation is used for estimation of individual catecholamine levels.     

银耳多糖单糖组成分析的三种色谱方法比较

为选择一种准确快捷的方法测定银耳多糖的单糖组成,对薄层色谱法(TLC)、气相色谱法(GC)、高效液相色谱法(HPLC)三种色谱方法进行比较。结果表明,前两种方法的测定结果均不理想,而HPLC法,操作简便,灵敏度高,分离效果好,信息完整。测定结果为由葡萄糖、甘露糖、葡萄糖醛酸、木糖、岩藻糖组成,其摩尔比为0.24∶1.00∶0.06∶0.29∶0.25。HPLC法对酸性杂多糖组成糖分析是一种比较理想的选择。     

High-performance liquid chromatographic determination of biotin in biological materials after crown ether-catalyzed fluorescence derivatization with panacyl bromide.

This paper reports a high-performance liquid chromatographic (HPLC) technique to determine biotin in biological samples. Biotin and the internal standard dethiobiotin are converted into fluorescent derivatives by using panacyl bromide [p-(9-anthroyloxy)phenacyl bromide] as a fluorescence label. Biotin is extracted from biological tissue with trichloroacetic acid and the extract is purified by a combination of solid-phase extraction on C18 cartridges, ion-exchange chromatography on DOWEX formate resin, and thin-layer chromatography. The purified sample extract is derivatized in the presence of a crown ether. The resulting panacyl esters can be separated on reversed-phase as well as on normal-phase HPLC. Normal phase HPLC is preferable because it provides higher sensitivity and demands less sample pretreatment. Analysis of rat intestinal tissue revealed that only about 13% of the biotin is present in free form whereas 87% is bound in proteins from which it can be released by hydrolysis. Biotin values determined by this method are comparable to those obtained by other techniques.