桑叶多糖SJB的结构分析和蛋白酪氨酸磷酸酯酶PTP1B抑制活性

通过DEAE-纤维素和凝胶过滤柱色谱对桑叶碱提粗多糖进行分级分离, 获得均一多糖SJB, 进行结构鉴定. 采用蛋白酪氨酸磷酸酯酶PTP1B体外模型对SJB进行降血糖活性测定. 结果表明: SJB的相对分子质量为5.4×104, 由鼠李糖、阿拉伯糖、葡萄糖、半乳糖、半乳糖醛酸组成的酸性杂多糖; 主链由1,2-、1,2,4-连接的鼠李糖和1,4-、1,3,4-连接的半乳糖醛酸组成; 侧链包括末端、1,5-、1,3,5-连接的阿拉伯糖; 末端、1,4-连接的葡萄糖以及末端、1,3-、1,4-、1,6-连接的半乳糖, 主要通过鼠李糖的O4位和半乳糖醛酸的O3位与主链相连. 该多糖为首次从桑叶中获得的酸性杂多糖. 20 μg/mL SJB对PTP1B的抑制率为31.7%.     

巴戟天中一种多糖的分离与结构表征

以巴戟天的根为原料, 经热水浸提、Sevag法除蛋白、乙醇沉淀和DEAE-Sepharose CL-6B离子交换柱层析, 得到一种水溶性的巴戟天多糖(MOPI-3). 通过UV、IR、NMR、GC-MS、高碘酸氧化、Smith降解和甲基化等物理化学方法对MOPI-3的纯度、理化性质和组成结构进行表征. 结果表明, MOPI-3分子量为36061, 是一种由阿拉伯糖、半乳糖和葡萄糖组成的杂多糖, 以α-1,3-吡喃葡萄糖和α-1,4-吡喃半乳糖为主链, 平均每5个葡萄糖连接一个半乳糖, 每个重复单元具有一个支链, 支链由3个呋喃阿拉伯糖以α-1,3-键型组成, 连接在主链葡萄糖的6位碳上, MOPI-3含有乙酰基, 连接在主链半乳糖的2位碳原子上.     

黑小麦麦麸戊聚糖的部分酸水解特征与甲基化分析

研究了黑小麦麦麸戊聚糖(AEPH)的部分酸水解特征及其糖链的取代度和取代方式等结构信息. 分别采用0.02, 0.1和0.2 mol/L的三氟乙酸(Trifluoroacetic acid, TFA)对AEPH进行部分酸水解, 结合甲基化分析、 GC-MS和HPLC等方法对AEPH的糖链结构和相对分子质量分布进行了分析. 结果表明, 戊聚糖AEPH的糖残基主要由阿拉伯糖(Araf)和木糖(Xylp)组成. 其取代度(A/X), 即Araf与Xylp的比值为0.60, 并具有较高的相对分子质量(M_w=3.81×10⁵). AEPH的主链由Xylp残基通过1→4连接形成木聚糖. 主链Xylp在O2, O3或O2/O3位被Araf单取代或双取代. 非取代(u)、 单取代(m)和双取代(d)Xylp残基的组成比例为57.7∶22.0∶6.2. 非取代与取代Xylp的比值为2.1, 双取代与单取代Xylp比值(d/m)为0.3. Araf主要以非还原性末端T-Araf以及通过1→2和1→5连接形成低聚阿拉伯糖的形式与主链Xylp相连, 或与T-Xylp相连形成戊聚糖分子的支链.     

竹黄多糖的化学研究

竹黄是高等真菌,腐生于箣竹上.子实体经分离后按常规发酵,再分离、纯化得到竹黄多糖SB1及SB2两个组分.物理化学性质测定证明分别为单一的均匀组分.经定性及定量气相层析分析表明SB1含D-葡萄糖、D-半乳糖和L-阿拉伯糖,摩尔比为0.37:1:0.07;SB2含D-葡萄糖、D-半乳糖、D-甘露糖和L-阿拉伯糖,摩尔比为0.25:1:0.47:0.12.经甲基化、过碘酸盐氧化、Smith降解和逐步水解等证明SB1的重复结构中含8种类型的单糖连接方式,非还原末端基团为葡萄糖、半乳糖和阿拉伯糖,主要键的连接方式为1,3-和1,3,6-葡萄糖及1,4-,1,6-和1,3,6-半乳糖.SB2的重复结构中含7种类型的单糖连接方式,非还原末端基团为葡萄糖和阿拉伯糖,主要单糖的连接方式为1,2-和1,3,6-甘露糖及1,4-,1,6-和1,3,6-半乳糖.上述多糖为一种新的杂多糖.     

当归多糖ASP3的甲基化分析

通过部分酸水解和甲基化分析, 结合GC-MS测试手段, 对当归多糖ASP3的糖链结构进行了研究. 采用0.2 mol/L三氟乙酸(Trifluoroacetic acid, TFA)对ASP3进行了部分酸水解, 对水解前后的多糖组分进行甲基化分析. 结果显示: ASP3的糖残基主要由D-GalpA, D-Galp, L-Araf和L-Rhap组成, 主链由1,4-D-GalpA连接, 形成“光滑区”半乳糖醛酸聚糖, 由1,4-D-GalpA通过O-4位与1,2-; 1,2,4-L-Rhap的O-2位交替连接形成含有较多分支的“毛发区”鼠李半乳糖醛酸聚糖. 58.8%的Rhap残基发生O-4位取代(1,2,4-L-Rhap). 由T-, 1,5-, 1,3,5-Araf和T-, 1,3-, 1,3,6-, 1,4-, 1,4,6-D-Galp聚合形成的阿拉伯半乳聚糖、半乳聚糖以及阿拉伯聚糖是ASP3侧链的主要组成, 通过Rhap残基的O-4位与主链相连.     

柘树根多糖的分离纯化及结构表征

以柘树[Cudrania tricuspidata(Carr.) Bur.]的根为材料, 经热水抽提、木瓜蛋白酶-Sevag法除蛋白、乙醇沉淀和DEAE-Sephadex A-50凝胶柱层析分离纯化, 得到一种水溶性的柘树根多糖(CPS-0). 采用HPLC、糖基组成分析、甲基化分析、GC、GC-MS、NMR(1H NMR, 13C NMR及HMQC)、元素分析、UV和IR等技术对CPS-0的纯度、性质、组成和结构进行表征. 结果表明, CPS-0仅含葡萄糖, 分子量为4.6×103, 主链由1,4-连接的α-D-葡萄糖残基组成, 其侧链由末端及1,4-连接的葡萄糖残基构成, 取代于主链分支点葡萄糖的6位, 平均每10个葡萄糖残基组成的重复单元中含有1个分支.     

沙蒿籽水溶性胶多糖ASPI-A的结构与免疫活性的初步研究

从沙蒿籽中提取出水溶性胶多糖,经柱色谱分离纯化得到一种中性多糖组分ASPI-A.采用高效凝胶渗透色谱法(HPGPC)测定其为均一性多糖,平均分子量为5.42×104Da.经IR,GC部分酸水解、甲基化分析等方法对该多糖的化学结构进行了表征.结果表明,该多糖由阿拉伯糖、甘露糖、葡萄糖及半乳糖组成,其物质的量的比为1∶2.8∶4.9∶1.9.ASPI-A为多分支结构,以(1→4)-β-Glc构成主链,部分葡萄糖C6存在分支,由甘露糖以-4)Man(1-连接在葡萄糖C6位,Glc(1-和Gal(1-连接在甘露糖C4位构成.免疫活性实验结果表明,ASPI-A在10～50μg·mL-1浓度范围内对ConA诱导的小鼠T淋巴细胞增殖反应具有促进作用.     

白骨壤酸性果胶多糖HAM-3-Ⅱb-Ⅱ的结构分析

以分离纯化得到的白骨壤酸性多糖HAM-3-Ⅱb-Ⅱ为研究对象, 采用高碘酸氧化-Smith降解、部分酸水解以及甲基化分析等技术对该多糖的结构进行分析. 结果表明, HAM-3-Ⅱb-Ⅱ为典型的鼠李半乳糖醛酸聚糖I 型酸性果胶类多糖, 主链骨架包括: 1,4-连接的α-D-GalpA构成的无分支的半乳糖醛酸聚糖(光滑区)和通过α-D-GalpA的O4位与1,2-和1,2,4-L-Rhap的O2交替相连构成的含有较多分支的鼠李半乳糖醛酸聚糖(毛发区). 由T-、1,6-、1,3,6-、1,4-、1,4,6-D-Galp和T-、1,2-、1,3-、1,5-、1,2,5-、1,3,5-Aaraf聚合成的AGⅠ型阿拉伯半乳聚糖、AGⅡ型阿拉伯半乳聚糖、半乳聚糖以及阿拉伯聚糖, 构成了HAM-3-Ⅱb-Ⅱ的侧链部分, 通过Rha残基的O4位与主链相连.     

山茱萸酸性多糖FCP5-A的分离纯化与结构表征

从山茱萸中提取出水溶性粗多糖, 经柱色谱分离纯化得到一种酸性多糖组分FCP5-A. 采用高效凝胶渗透色谱法(HPGPC)测定其为均一性多糖, 平均分子量为8.7×104. 经IR、GC、部分酸水解、13C NMR及甲基化分析等方法对该多糖的化学结构进行了表征. 结果表明, 该多糖由鼠李糖、阿拉伯糖、半乳糖及半乳糖醛酸组成, 其摩尔比为1∶5.7∶0.6∶1.2. FCP5-A为多分支结构, 由-2)Rha(1-及-4)GalA(1-构成主链, 在鼠李糖的4位存在分支; 支链主要由高度分支的阿拉伯糖构成, 此外还存在-3)Gal(1-; 末端残基为Ara(1-及Gal(1-. 结果提示, FCP5-A为一种新的山茱萸酸性分支多糖.     

基于多孔石墨化碳柱-四极杆-飞行时间质谱解析甜菜果胶精细结构

采用高温酸法提取甜菜果胶(SBP), 经强阴离子交换柱层析分离, 获得甜菜果胶水洗脱组分(SBPW)和盐洗脱组分(SBP3). 单糖组成分析和分子量表征结果表明, SBPW主要由半乳糖(Gal)、 阿拉伯糖(Ara)和半乳糖醛酸(GalA)组成, 分子量为1100； SBP3则以GalA为主, 分子量为41450. 通过顺序酶法降解, 应用多孔石墨化碳柱-四极杆-飞行时间质谱(PGC-Triple-Tof MS)联用技术分析鉴定了SBPW和SBP3寡糖的精细结构. 结果表明, SPBW的主链为[→4)-α-GalA-(1→2)-α-Rha-(1→]重复单元构成的Ⅰ型聚鼠李半乳糖醛酸(RG-Ⅰ果胶), 鼠李糖O-4位被中性糖侧链[α-(1→5)阿拉伯聚糖和β-(1→4)半乳聚糖]所取代. SBP3由α-1,4链接的聚半乳糖醛酸(HG)和RG-Ⅰ构成, HG和RG-Ⅰ通过α-1,4糖苷键直接相连, 并发现了α-GalA(1→2)α-Rha(1→4)α-Rha(1→4)α-GalA(1→2)α-Rha的新特征结构.     

金钗石斛精油化学成份研究

金钗石斛(Dendrobium nobile Lindl.)是中药石斛的品种之一,目前有以鲜金钗石斛水蒸气蒸馏液制成的制剂(如鲜石斛露)供药用,具有滋阴养胃,清热解酒,润肺止咳,生津止渴之功效。经我们药理实验证明,金钗石斛水蒸气蒸馏液对豚鼠离体肠管活动有兴奋作用,对大肠杆菌、枯草杆菌、金黄色葡萄球菌有抑制作用,但其精油成分的研究未见文献报道。我们采用 GC—MS—DS 技术对金钗石斛鲜茎水蒸气蒸馏精油成分进行了研究,发现其主要成份为泪柏醇,另外还有紫罗兰酮等53个成份。     

Novel Bis(bibenzyl) and (Propylphenyl)bibenzyl Derivatives from Dendrobium nobile

Two novel compounds possessing a bis(bibenzyl) (see 1 ) and a (propylphenyl)bibenzyl skeleton (see 2 ) and eight known compounds were isolated from the stems of Dendrobium nobile Lindl . (Orchidaceae). Their structures were identified by spectroscopic analyses.     

Dendrocoumarin: a new benzocoumarin derivative from the stem of Dendrobium nobile

A new benzocoumarin derivative, dendrocoumarin (1), along with itolide A were isolated from the stems of Dendrobium nobile. The structure of the new compound 1 elucidated on the basis of NMR and mass spectroscopic data. Compounds 1 and 2 showed broad spectrum antibacterial activity against five terrestrial pathogenic bacteria.     

Elution-extrusion counter-current chromatography separation of five bioactive compounds from Dendrobium chrysototxum Lindl

The elution-extrusion counter-current chromatography (EECCC) method was firstly developed by Berthod in 2003 and has been used in natural products separation in recent years. The advantages of this method have been well documented such as reducing the separation time and solvent consumption. In the EECCC method, the time point of the extrusion step is very important during the whole separation process as it directly affects the resolutions, separation time and solvent consumption. However, how to choose a suitable time point to perform the extrusion step without decreasing the resolution has not been studied yet. In the present study, a strategy for systematically calculating the time point for extrusion was developed in theory and five bioactive compounds from the extract of Dendrobium chrysototxum Lindl. were separated and compared using normal CCC and EECCC method. Our results demonstrated that the accurate time point to perform the extrusion could be calculated and reduced both separation time and solvent consumption without losing separation performance. Using this EECCC method, five bioactive compounds were separated and purified with high purity. The separation time and solvent consumption were decreased from 200 min to 100 min and 5-2.5L during the separation process while the resolutions were still acceptable. Finally, 63 mg, 48 mg, 97 mg, 162 mg and 43 mg of hydroxyl phenanthrenes and bibenzyls with the purity of 98.7%, 98.0%, 98.2%, 99.0% and 98.7%, respectively were isolated from 1.2 g crude extract of D. chrysototxum Lindl. initially purified by column chromatography in one step separation. The purities of compounds were determined by HPLC. Their structures were identified by electrospray ionization-mass spectrometry (ESI-MS) and NMR.     

铁皮石斛的裂解气相色谱指纹图谱及其系统聚类分析

采用裂解气相色谱/质谱法(Py-GC/MS)测定了10种不同产地的铁皮石斛并结合系统聚类分析法比较了这些铁皮石斛的指纹图谱,采用释放气体分析法考察了裂解温度对指纹图谱的影响。结果表明,0.4 mg样品在450 ℃下可瞬间裂解,10种样品的指纹图谱具有相似性,且重现性好;采用系统聚类分析能区别不同产地的样品。本法快速、简便、准确,不失为药材质量控制的良好方法。     

UPLC-Q/TOF-MS coupled with multivariate analysis for comparative analysis of metabolomic in Dendrobium nobile from different growth altitudes

Dendrobium nobile alkaloids (DNLA) and glycosides are the main active components extracted from Dendrobium nobile Lindl. (D. nobile) used for thousands of years in China. The pharmacological effects of the above chemical components are significantly different. D. nobile is mainly grown at an altitude ranging from 230 to 800 m in Chishui City, Northwest Guizhou Province. However, it is unclear whether the metabolite in D. nobile is influenced by the planting altitude. Hence, to reveal the different metabolite in D. nobile cultivated at the altitude of 336 m, 528 m, and 692 m, ultra-high performance liquid chromatography with Q/TOF-MS couple with multivariate analysis were developed. Using the orthogonal partial least squares-discriminant analysis, 19 different metabolites were discovered and then tentatively assigned their structures as alkaloids and glycosides by comparing mass spectrometry data with in-house database and literature. Moreover, the result of semiquantitative analysis showed the content of dendrobine that was belonged to alkaloids significantly increased at the altitude of 692 m, whereas the content of glycosides demonstrated an accumulation trend at the altitude of 528 m. The results could provide valuable information for the optimal clinical drug therapeutics and provide a reference for quality control.     

4-dehydroxyepisarcovagine A,a new steroidal alkaloid from Sarcococca pruniformis Lindl.

A new steroidal alkaloid, 4-dehydroxyepisarcovagine A (1), along with seven known alkaloids, sarcovagine D (2), sarcovagenine C (3), epoxysarcovagenine D (4), Pachysamine L (5), Pachysamine E (6), sarcovagine A (7) and sarcovagine B (8), was isolated from the roots and stems of Sarcococca pruniformis Lindl. The structure of compound 1 was elucidated by means of spectroscopic analysis.     

Purification of polysaccharide from artificially cultivated Anoectochilus roxburghii (wall.) Lindl. by high‐speed counter current chromatography and its antitumor activity

To establish a systematic method for the extraction, purification, characterization and antitumor activity study of polysaccharide from artificially cultivated Anoectochilus roxburghii (wall.) Lindl. (AC‐ARPS). High‐speed counter current chromatography with two‐phase aqueous systems was successfully applied to purify AC‐ARPS after one‐step separation. The purity of the AC‐ARPS obtained by phenol/sulfuric acid method was 95.01%. The chemical structures of AC‐ARPS were identified by a series of analytical methods including high‐performance liquid chromatography and liquid chromatography with mass spectrometry. High‐performance liquid chromatography and liquid chromatography with mass spectrometry indicated that AC‐ARPS was mainly composed of mannose, ribose, glucose, galactose and arabinose with a molar ratio of 1.00:8.47:47.30:1.17:1.19. AC‐ARPS is a homogeneous polysaccharide with a molecular weight of 25 681 Da. The antitumor effect of AC‐ARPS was evaluated on lung cancer A549, osteosarcoma 143B, rat adrenal pheochromocytoma PC 12, breast cancer MCF‐7, acute leukemia HL 60, chronic leukemia K562, colon cancer SW620, esophageal cancer OE 19, liver cancer HepG2, and neuroglioma U251 cells in vitro. AC‐ARPS showed the best inhibitory effect on OE 19 cells, and the IC₅₀ value was 5.67 ± 0.831 μmol/L. Fluorescence analysis and flow cytometry results showed that AC‐ARPS induced apoptosis and G2/M phase arrest in OE 19 cells.