瑞香狼毒茎叶化学成分研究

新鲜瑞香狼毒(Stellera chamaejasme)茎叶经正已烷提取,脱腊后进行GC-MS-DS联用分析,鉴定出20个化合物。主要成分为正十八烷;正十九烷;2,6,10,14 — 四甲基十六烷;十六烷酸;十六烷酸甲酯;十六烷酸乙酯;9,12,15-十八碳三烯酸甲酯;9,12-+八碳二烯酸;9,12,15-十八碳三烯酸和十八烷酸。     

金线莲挥发油化学成分的研究

采用水蒸气蒸馏法提取花叶开唇兰挥发油,用GC毛细管柱进行分析,归一化法测定其相对含量,并用GC-MS法鉴定化学成分。检出182个成分,鉴定出73个化合物,占挥发油总量的92.64%,主要成分为:正十六烷酸(25.22%)、(Z,Z)-9,12-十八碳二烯酸甲酯(6.47%)、11,14,17-二十碳三烯酸甲酯(4.42%)、(Z,Z)-9,12-十八碳二烯酸(15.35%)和(Z,Z,Z)-9,12,15-十八碳三烯酸甲酯(13.64%)。     

发酵无花果香料的挥发性成分分析

利用微生物发酵无花果开发特色香料,并采用同时蒸馏萃取装置收集挥发性成分并用气相色谱一质谱仪对生物技术制备的无花果香料挥发性成分进行分离和鉴定,经毛细管色谱分离出47种组分,确认了其中的45种成分,并用面积归一化法测定了各种成分的百分含量,其主要成分为：9,12-十八碳二烯酸乙酯(27．34％)、十六酸乙酯(23．99％)、邻苯二甲酸二丁酯(6．18％)、邻苯二甲酸二异丁酯(5．52％)、9,12-十八碳二烯酸甲酯(4．72％)、十六酸甲酯(4．67％)、9,12,15-十八碳三烯酸乙酯(4．48％)、9-十八碳烯酸乙酯(3．80％)、糠醛(2．53％)、9,12,15-十八碳三烯酸甲酯(1．85％)、十八酸乙酯(1．42％)、9-十八碳烯酸甲酯(1．26％)等。     

云南丛生树花净油的组成：1.主要的脂肪酸乙酯

根据气相色谱-质谱数据推定云南丛生树花净油液体部分中四种主要成分为辛酸乙酯、十六烷酸乙酯、十八烷酸乙酯和2,4,6-十八碳三烯酸乙酯。     

蝴蝶果茎挥发油的化学成分

采用水蒸汽蒸馏法从大戟科蝴蝶果茎中提取挥发油,用气相色谱-质谱联用技术对挥发油化学成分进行分析。分离出36个峰,鉴定出35种化合物,占总油量的98.34%,并应用面积归一化法测定各成分的相对百分含量。其主要成分为十六烷酸乙酯(13.19%)、正十六烷酸(11.11%)、十八碳烯酸乙酯(6.18%)、正十八烷(4.98%)、(Z,Z)-9,12-十八碳二烯酸(4.90%)及十八碳二烯酸乙酯(4.21%)。     

卷丝苣苔和勐醒芒毛苣苔脂肪酸成分的研究

用索氏提取法提取,甲酯化处理后采用气相色谱-质谱联用技术首次对卷丝苣苔(Corallodiscus kingianus)和勐醒芒毛苣苔(Aeschynanthus mengxingensis)中脂肪酸成分进行了分析.从卷丝苣苔的脂肪酸成分中鉴定出33个化合物,占检出物总质量分数的95.44%,主要成分为9,12-十八碳二烯酸、(Z,Z,Z)-9,12,15-十八碳三烯酸、十六烷酸.从勐醒芒毛苣苔的脂肪酸成分中鉴定出30个化合物,占检出物总质量分数的94.23%,主要成分为14-甲基-十五烷酸、(E)-9-十八碳烯酸、10,13-十八碳二烯酸.二者有15个组分是相同的.     

云南使君子仁油化学成分的GC-MS分析

以常规溶剂萃取得使君子仁油,取两份油,一份经甲酯化处理,别一份不甲酯化,然后采用重量法和气相色谱-质谱联用技术分别测定使君子仁油含量和脂肪酸成分。结果表明：使君子仁油含量为15％;从甲酯化脂肪油中共检测出5种成分,其中E-9-十八烯酸占脂肪酸总量的46．99％,十六烷酸甲酯占脂肪酸总量的28．25％;另外,从未甲酯化脂肪油中共检测出7种成分,其中含防十八烯酸63．19％,十六烷酸甲酯15．26％,同时还检测出11．79％的γ-生育酚。使君子仁油是具有抗氧化性的植物源脂肪油,是开发和利用E-9-十八烯酸,十六烷酸甲酯和γ-生育酚的理想原料,在食用、医疗保健方面具有巨大潜力和广阔前景。     

云南干巴菌挥发油化学成分的研究

利用气相色谱－质谱联用技术对云南干巴菌的挥发油化学成分进行了研究,共鉴定出49种组分。其中主要成分为业油酸甲酯、棕榈酸、1,1－二乙氧基乙烷、苯乙醛、十六碳烯酸、十五烷酸、邻苯二甲酸二丁 、苯甲酸、苯乙醇、硬脂酸、二十一烷、肉豆蔻酸、十八碳烯酰胺、苯乙酸等,其中亚油酸甲酯的含量最高,占挥发油成分总量的27.12％,检出成分占挥发油总量的90％。     

乳杆菌DM9811发酵液的挥发性脂肪酸组分分析

目的：通过分析乳杆菌DM9811发酵液的挥发性脂肪酸,探讨乳杆菌对机体作用的分子机制。方法：采用高压气相色谱方法。结果：乳杆菌DM9811发酵液中存在乙酸、9-十六碳烯酸,十六烷酸,9,12-十八碳二烯酸,9-十八碳烯酸,其中乙酸浓度为1.6mg/ml。结论：乳杆菌DM9811发酵液中除含有乙酸外,还含有十六～十八碳饱和与不饱和脂肪酸。     

稻曲球脂溶性成分及其抗细菌和抗氧化活性

采用水蒸气蒸馏法从稻曲球甲醇提取物的石油醚萃取部分制备出油状物,得率为稻曲球干重的0.36%。用GC-MS鉴定出14个成分,主要成分为10,13-十八碳二烯酸甲酯(37.31%)、14-甲基十五烷酸甲酯(30.09%)、(Z,Z)-9,12-十八碳二烯酸(15.63%)、棕榈酸(10.52%)和十八烷酸甲酯(5.54%)。从石油醚萃取部分还分离到3个化合物,经理化和波谱分析鉴定为油酸(1)、正四十烷(2)和麦角甾-5,7,22-三烯-3-醇(3)。化合物3对黄瓜角斑病菌等4种供试细菌表现出较强的抑制活性,化合物1和2以及油状物表现出一定的抗氧化活性。这是首次对稻曲球中脂溶性成分及其抗细菌和抗氧化活性的报道。     

THE INFLUENCE OF KINETIN AND ANTIMETABOLITES ON THE SYNTHESIS OF FATTY ACIDS IN LEAVES

Green leaf tissues contain relatively higher proportions of unsaturated fatty acids, especially α-linolenic acid, than do etiolated or senescent tissues. There appear to be developmental changes in the fatty acid composition of leaves during maturation and senescence. The normal rate of development of spinach (Spinacia oleracea L.) and bean (Phaseolus vulgaris L.) leaf tissues was altered by the application of kinetin and antimetabolites. Spinach was used for the kinetin studies and bean for the antimetabolite studies. Supposedly the kinetin retarded senescence and the antimetabolites retarded normal development. Special emphasis was placed on the incorporation of acetate into palmitate, the most abundant saturated fatty acid, and into linolenate, the most abundant unsaturated fatty acid. Kinetin does not enhance linolenate synthesis, but kinetin-treated tissues contain proportionately more linolenate. In contrast, tissues treated with antimetabolites contain proportionately less linolenate. Actinomycin-D and puromycin seem to have a greater effect on the synthesis of linolenate than on the synthesis of palmitate. Chloramphenicol does not have this same differential effect. The possible influence of antimetabolites on the synthesis of unsaturated fatty acids is discussed.     

A COMPARATIVE STUDY OF THE METABOLISM OF DE NOVO SYNTHESIZED FATTY ACIDS FROM ACETATE AND GLUCOSE, AND EXOGENOUS FATTY ACIDS, IN SLICES OF RABBIT CEREBRAL CORTEX DURING DEVELOPMENT

Slices of rabbit cerebral cortex, from the foetal stage to the adult have been used to compare lipid synthesis from fatty acids synthesized de novo from [U-¹⁴C]glucose and [1-¹⁴C]acetate, with lipid synthesis from exogenous albumin-bound [1-¹⁴C]palmitate. Incorporation into cellular lipid has been determined in terms of DNA, protein, wet wt. of tissue and wet weight of whole brain. On a wet wt. basis, maximum incorporation of glucose carbon into lipid occurred in the foetal brain while lipid synthesis from acetate and palmitate was maximum at 4–14 days after birth. Glucose and acetate were incorporated into a diversity of lipids (with increasing amounts of phosphatidylcholine synthesized during maturation), while palmitate was incorporated into the free fatty acid and triglyceride fractions. A greater proportion of acetate was incorporated into fatty acids of chain-length longer than C16 compared with the incorporation of palmitate. However, on a molar basis de novo synthesized and exogenous palmitate were elongated, desaturated and incorporated into phospholipids at a similar rate, while exogenous palmitate was incorporated to a greater extent than de nova synthesized fatty acid into the triglyceride fraction. This difference in metabolism may be due to the different size of the non-esterified fatty acid pool in the two situations. At the period of their most active formation, the very long-chain fatty acids may be synthesized from a pool of the C18 series of fatty acids (saturated and monoenoic) not in equilibrium with the bulk of C₁₈ acids in cerebral lipids. This could be a pool of acyl groups derived from ethanolamine phospholipids.     

Linoleic acid passage through the blood-brain barrier and a possible effect of age

It has already been established that the blood-brain barrier is readily crossed by unsaturated fatty acids, while saturated fatty acid transport appears to be protein mediated. When the passage of the fatty acids is tested in vivo by using perfusion buffers containing both linoleate and palmitate in different concentrations, linoleate is able to decrease the palmitate passage, while palmitate increases the linoleate passage. These results could be related to the effect of two fatty acids on the ratio between the fatty acids bound to the serum albumin and the free fatty acid pool, which is only available for transport through membranes. However, on the basis of some results obtained with aged rats, the possibility that a relationship may exist between palmitate and linoleate during their passage through the BBB is discussed. Moreover, it seems likely that in aged rats a moderate modification for fatty acids takes place in the BBB.     

Fatty acids and esters from Panax pseudo-ginseng rhizomes

In addition to methyl palmitate, palmitic acid, stearic acid, eicosanoic acid, triacontanoic acid, hexatriacontanoic acid, pentatriacontane, sitosterol and sitosterol-β-D-glucoside, two new compounds isolated from the rhizomes of Panax pseudo-ginseng have been characterized as 14-hydroxyheneicosanoic acid and dotriacontanyl palmitate, respectively, by physico-chemical studies.     

Site-specific S-Acylation of Influenza Virus Hemagglutinin: THE LOCATION OF THE ACYLATION SITE RELATIVE TO THE MEMBRANE BORDER IS THE DECISIVE FACTOR FOR ATTACHMENT OF STEARATE*

S-Acylation of hemagglutinin (HA), the main glycoprotein of influenza viruses, is an essential modification required for virus replication. Using mass spectrometry, we have previously demonstrated specific attachment of acyl chains to individual acylation sites. Whereas the two cysteines in the cytoplasmic tail of HA contain only palmitate, stearate is exclusively attached to a cysteine positioned at the end of the transmembrane region (TMR). Here we analyzed recombinant viruses containing HA with exchange of conserved amino acids adjacent to acylation sites or with a TMR cysteine shifted to a cytoplasmic location to identify the molecular signal that determines preferential attachment of stearate. We first developed a new protocol for sample preparation that requires less material and might thus also be suitable to analyze cellular proteins. We observed cell type-specific differences in the fatty acid pattern of HA: more stearate was attached if human viruses were grown in mammalian compared with avian cells. No underacylated peptides were detected in the mass spectra, and even mutations that prevented generation of infectious virus particles did not abolish acylation of expressed HA as demonstrated by metabolic labeling experiments with [³H]palmitate. Exchange of conserved amino acids in the vicinity of an acylation site had a moderate effect on the stearate content. In contrast, shifting the TMR cysteine to a cytoplasmic location virtually eliminated attachment of stearate. Thus, the location of an acylation site relative to the transmembrane span is the main signal for stearate attachment, but the sequence context and the cell type modulate the fatty acid pattern.     

Effects of linoleic and gamma-linolenic acids (efamol evening primrose oil) on fatty acid-binding proteins of rat liver

Summary We have studied the effects of Efamol evening primrose oil (EPO) on fatty acid-binding proteins (L-FABP) of rat liver. EPO contains 72% cis-linoleic acid and 9% cis-gamma linolenic acid. EPO has been clinically used for treatment of a number of diseases in humans and animals. EPO is also known to lower cholesterol level in humans and animals. Feeding of an EPO supplemented diet to rats (n = 9) for 2 months decreases the oleate binding capacity of purified L-FABP of rat liver whereas the palmitate binding activity was increased by 38%. However, EPO feeding did not alter the L-FABP concentrations significantly as measured by using the fluorescence fatty acid probe, dansylamino undecanoic acid. Endogenous fatty acid analysis of L-FABPs revealed significant qualititative and quantitative changes in fatty acid pattern after EPO feeding. EPO feeding decreased the endogenous palmitate level by 53% and oleate level by 64% in L-FABPs and also EPO feeding decreased the total endogenous fatty acid content from 62 nanomole per mg of protein to 42 nanomole per mg of L-FABP (n = 3).     

Metabolism of palmitate in cultured rat Sertoli cells

Isolated rat Sertoli cells were incubated in the presence of [1-14C]palmitate at a cell concentration of 1.54 +/- 0.31 mg protein/flask (n = 7). The oxidation of palmitate was concentration dependent and maximal oxidation was obtained at 0.35 mM-palmitate. At a saturating concentration of palmitate the oxidation was linear for at least 6 h. About 65% of the total amount of palmitate oxidized during 5 h at 0.52 mM-palmitate (109 +/- 44 nmol/flask, n = 5) was recovered as CO2 and the rest as acid-soluble compounds. Almost all radioactive acid-soluble compounds which were secreted by the Sertoli cells were shown to be 3-hydroxybutyrate and acetoacetate. The palmitate recovery in cellular lipids and triacylglycerols was 9.4 +/- 5.1 nmol/flask (n = 5) and 3.5 +/- 2.8 nmol/flask (n = 5) respectively. Addition of glucose had no significant effect on palmitate oxidation but caused a 9-fold increase in esterification of palmitate into triacylglycerols. We conclude that cultured rat Sertoli cells can oxidize palmitate to CO2 and ketone bodies and that fatty acids appear to be a major energy substrate for these cells.     

Impact on fatty acid metabolism and differential localization of FATP1 and FAT/CD36 proteins delivered in cultured human muscle cells

We compared the intracellular distribution and regulatory role of fatty acid transporter protein (FATP1) and fatty acid translocase (FAT/CD36) on muscle cell fatty acid metabolism. With the use of adenoviruses, FATP1 and FAT genes were delivered to primary cultured human muscle cells. FATP1 and FAT moderately enhanced palmitate and oleate transport evenly at concentrations of 0.05, 0.5, and 1 mM. Long-term (16 h) consumption of palmitate and oleate from the media, and particularly incorporation into triacylglyceride (TAG), was stimulated equivalently by FATP1 and FAT at all fatty acid concentrations tested. In contrast, long-term CO₂ production was reduced by FATP1 and FAT at all doses of palmitate and at the lower concentrations of oleate. Neither FATP1 nor FAT markedly altered the production of acid-soluble metabolic intermediates from palmitate or oleate. The intracellular localization of fusion constructs of FATP1 and FAT with enhanced green fluorescent protein (EGFP) was examined. Independently of fatty acid treatment, FATPGFP was observed throughout the cytosol in a reticular pattern and concentrated in the perinuclear region, partly overlapping with the Golgi marker GM-130. FATGFP was found in the extracellular membrane and in cytosolic vesicles not coincident with GM-130. Neither FATP1 nor FAT proteins colocalized with lipid droplets in oleate-treated cells. We conclude that whereas FAT is localized on the extracellular membrane, FATP1 is active in the cytosol and imports fatty acids into myotubes. Overall, both FATP1 and FAT stimulated transport and consumption of palmitate and oleate, which they channeled away from complete oxidation and toward TAG synthesis. palmitate; oleate; fatty acid binding proteins; skeletal muscle     

Phosphatase activity in rat adipocytes: effects of insulin and insulin resistance

Insulin regulates the activity of both protein kinases and phosphatases. Little is known concerning the subcellular effects of insulin on phosphatase activity and how it is affected by insulin resistance. The purpose of this study was to determine insulin-stimulated subcellular changes in phosphatase activity and how they are affected by insulin resistance. We used an in vitro fatty acid (palmitate) induced insulin resistance model, differential centrifugation to fractionate rat adipocytes, and a malachite green phosphatase assay using peptide substrates to measure enzyme activity. Overall, insulin alone had no effect on adipocyte tyrosine phosphatase activity; however, subcellularly, insulin increased plasma membrane adipocyte tyrosine phosphatase activity 78 +/- 26% (n = 4, P < 0.007), and decreased high-density microsome adipocyte tyrosine phosphatase activity 42 +/- 13% (n = 4, P < 0.005). Although insulin resistance induced specific changes in basal tyrosine phosphatase activity, insulin-stimulated changes were not significantly altered by insulin resistance. Insulin-stimulated overall serine/threonine phosphatase activity by 16 +/- 5% (n = 4, P < 0.005), which was blocked in insulin resistance. Subcellularly, insulin increased plasma membrane and crude nuclear fraction serine/threonine phosphatase activities by 59 +/- 19% (n = 4, P < 0. 005) and 21 +/- 7% (n = 4, P < 0.007), respectively. This increase in plasma membrane fractions was inhibited 23 +/- 7% (n = 4, P < 0. 05) by palmitate. Furthermore, insulin increased cytosolic protein phosphatase-1 (PP-1) activity 160 +/- 50% (n = 3, P < 0.015), and palmitate did not significantly reduce this activity. However, palmitate did reduce insulin-treated low-density microsome protein phosphatase-1 activity by 28 +/- 6% (n = 3, P < 0.04). Insulin completely inhibited protein phosphatase-2A activity in the cytosol and increased crude nuclear fraction protein phosphatase-2A activity 70 +/- 29% (n = 3, P < 0.038). Thus, the major effects of insulin on phosphatase activity in adipocytes are to increase plasma membrane tyrosine and serine/threonine phosphatase, crude nuclear fraction protein phosphatase-2A, and cytosolic protein phosphatase-1 activities, while inhibiting cytosolic protein phosphatase-2A. Insulin resistance was characterized by reduced insulin-stimulated serine/threonine phosphatase activity in the plasma membrane and low-density microsomes. Specific changes in phosphatase activity may be related to the development of insulin resistance.