外源脂肪酸对酒精诱导自絮凝颗粒酵母细胞膜磷脂脂肪酸组成变化的影响

实验将自絮凝颗粒酵母培养于同时添加脂肪酸 (0.6mmol/L)和酒精 (6 %～ 9% ,V/V)条件下以考察其细胞膜磷脂脂肪酸组成的变化。与单独添加棕榈酸相比 ,同时添加酒精引起细胞膜磷脂棕榈酸含量明显增加 ,伴随 9十四碳烯酸、棕榈油酸和油酸含量明显减少 ;与单独添加亚油酸相比 ,同时添加酒精未引起细胞膜磷脂亚油酸含量明显变化 ,但引起油酸含量明显增加 ,伴随 9 十四碳烯酸、棕榈油酸和棕榈酸含量减少 ;与单独添加亚麻酸相比 ,同时添加酒精引起细胞膜磷脂亚麻酸含量减少 ,伴随油酸含量显著增加 ,同时 9 十四碳烯酸、棕榈油酸和棕榈酸含量减少。存活率实验证实 ,上述变化是菌体对酒精刺激的适应性响应 ,因为 ,与培养于仅添加脂肪酸条件下的菌体相比 ,培养于同时添加酒精条件下的菌体耐酒精能力明显提高。研究表明 ,棕榈酸和油酸都可通过加强细胞膜渗透屏障而提高菌体的耐酒精能力 ,这是饱和脂肪酸 (SFA)与不饱和脂肪酸 (UFA)可提高同一菌株耐酒精能力的新的实验现象 ,揭示UFA与SFA在影响酵母菌耐酒精能力的机制上存在共同的作用方式     

不同种源山桐子果实脂肪酸组成变异分析

以采自11个种源的山桐子为材料,测定其果实脂肪酸的组成及其变异情况,结果表明：山桐子果实中不饱和脂肪酸含量较高,尤以亚油酸含量最高,11个种源的平均值为63．58％,且种源间差异显著,分宜、宜昌种源亚油酸相对含量明显高于其他9个种源;饱和脂肪酸以棕榈酸为主,11个种源山桐子果实棕榈酸差异显著,且以平武种源最高;其余脂肪酸含量均较低,变异幅度较大;种子中棕榈酸和棕榈烯酸含量明显高于果肉,而亚油酸、亚麻酸及硬脂酸含量明显低于果肉,油酸含量相近：果实不饱和脂肪酸含量依次为果肉〉全果〉种子,且变异系数及相对极差均较小,尤以果肉中最小;除硬脂酸外,山桐子果实中其他4种主要脂肪酸组分受海拔等地理环境的影响均较小。     

甘肃胡麻地方种质资源品质特性研究

对甘肃省116份胡麻地方品种的重要品质指标———粗脂肪、硬脂酸、棕榈酸、油酸、亚油酸、亚麻酸含量和碘值进行测定,并根据这些品质指标对供试品种进行聚类分析。结果显示:(1)供试品种粗脂肪含量平均值为37.48%,变异系数3.8%;硬脂酸、油酸含量平均值分别为5.32%和29.05%,变异系数分别为19.5%和11.6%;棕榈酸、亚麻酸、亚油酸含量平均值分别为5.9%、48.76%、10.95%,变异系数分别为8.4%、8%、8%;平均碘价175.60,变异系数2.76%;(2)聚类分析结果显示,116个品种聚为7大类,其中:b亚组群硬脂酸和油酸含量最高,而亚麻酸含量最低;d亚组群品种亚麻酸含量最高;e亚组群粗脂肪含量和碘价最高,油酸含量最低;f亚组群硬脂酸含量最低;g亚组群棕榈酸含量最高,碘价最低。     

乌桕梓油和桕脂的脂肪酸组成研究

运用色谱-质谱分析方法,鉴定乌桕梓油和桕脂的脂肪酸成分.分析结果,野生乌桕和栽培乌桕在脂肪酸组成上相同;梓油除了含常见的亚麻酸、亚油酸、油酸、棕榈酸和硬脂酸之外,还含有不常见的2,4-癸二烯酸和8-羟基-5,6-辛二烯酸;桕脂含棕榈酸、油酸、硬脂酸和亚油酸.两者的主要差异在于蜡质层厚度和核的大小及其油脂含量的不同.     

乌桕梓油和桕脂的脂肪酸组成研究

运用色谱-质谱分析方法,鉴定乌桕梓油和桕脂的脂肪酸成分.分析结果,野生乌桕和栽培乌桕在脂肪酸组成上相同;梓油除了含常见的亚麻酸、亚油酸、油酸、棕榈酸和硬脂酸之外,还含有不常见的2,4-癸二烯酸和8-羟基-5,6-辛二烯酸;桕脂含棕榈酸、油酸、硬脂酸和亚油酸.两者的主要差异在于蜡质层厚度和核的大小及其油脂含量的不同.     

华南主要野生蔬菜的脂肪酸成分分析

本实验以华南主要野生蔬菜守宫木、土人参、一点红、白仔菜、紫背菜、鳄嘴花、藤三七、塘葛菜为材料,并以华南特产蔬菜菜心为对照,对8种野生蔬菜的脂肪酸成分进行了分析.结果表明:8种野菜共检出十四酸、软脂酸、棕榈油酸、硬脂酸、油酸、亚油酸、亚麻酸、二十二酸和二十四酸共9种脂肪酸,但不同野菜之间的脂肪酸组成与含量差异极大.8种野菜的饱和脂肪酸的总量都高于菜心,饱和脂肪酸种类最多的是藤三七,含4种.不饱和脂肪酸的变化与饱和脂肪酸相反,8种野菜都低于菜心,但其油酸、亚油酸远高过菜心.菜心富含亚麻酸,但不含亚油酸.可见8种野菜油营养价值较高.     

灵芝孢子油脂肪酸组分的分析

采用气相色谱与质谱(GC-MS)联用分析,从超临界CO2萃取孢子油中鉴定出18种脂肪酸成分,包括6种不饱和脂肪酸、7种饱和脂肪酸、2种环链脂肪酸,以及己酸、辛酸、壬酸等短链脂肪酸。GC定量分析结果表明:灵芝孢子油中检出9种已知脂肪酸,不饱和脂肪酸总量为73.6%;其中,主体成分油酸(C18∶1)、亚油酸(C18∶2)和棕榈酸(C16∶0)等含量分别为57.5%、13.4%、19.6%;此外,不饱和脂肪酸十六碳烯酸(C16∶1)、亚麻酸(C18∶3)等不饱和脂肪酸含量为2.2%、0.5%。     

缅甸蟒脂肪酸分析

用气相色谱法测定了缅甸蟒油20种脂肪酸,其中不饱和脂肪酸含量达67.5%,多不饱和脂肪酸含量达10.3%.含量较高的脂肪酸有油酸、棕榈酸、亚油酸、棕榈油酸,特有脂肪酸DHA、α-亚麻酸,并且明显不同于其他蟒和蛇的脂肪酸含量.缅甸蟒油具有重要的药用和保健品开发利用价值.     

超临界CO_2萃取韭菜籽油成分的GC-MS分析

以索氏提取法为对照,采用超临界二氧化碳(SC-CO_2)萃取韭菜籽油,气相色谱-质谱联用技术(GC-MS)对韭菜籽油成分进行分析,NIST 02质谱数据库对其进行分析和鉴定.结果表明,SC-CO_2萃取压力为22.25 MPa、温度为40.40℃条件下萃取86.7 min时,萃取得率为17.52%,共分离鉴定出17种物质,其中,饱和脂肪酸以棕榈酸(6.25%)为主,占脂肪酸总量的 9.05%;不饱和脂肪酸主要是亚油酸(69.71%)和油酸(19.53%),占脂肪酸总量的90.50%.采用索氏提取得率为16.50%,共鉴定出10种物质,饱和脂肪酸以棕榈酸(7.22%)为主,占总脂肪酸量的9.84%;不饱和脂肪酸主要是亚油酸(69.34%)和油酸(20.12%),不饱和脂肪酸占脂肪酸总量的90.16%.另外SC-CO_2萃取韭菜籽油还检出单不饱和脂肪酸7-棕榈烯酸、角鲨烯和β-谷甾醇.     

不同品种亚麻籽粒中主要脂肪酸含量的变化

不同亚麻品种‘陇亚7号’、‘82（50）’、‘匈牙利3号’和‘范昵’籽粒中亚麻酸含量最高,其次是油酸、亚油酸和硬脂酸,棕榈酸含量最低。棕榈酸和亚油酸在籽粒发育成熟的初期增长速度较快,含量较高,但随着籽粒逐渐发育成熟而下降,硬脂酸也如此,后者下降幅度较小。油酸和亚麻酸含量随着籽粒发育成熟进程而渐增,油酸含量增加幅度较小。不同品种的籽粒完全成熟时,棕榈酸、硬脂酸、亚油酸和亚麻酸含量有异,同一基因型的亚麻籽粒完全成熟时,开花晚的油酸含量较低,而亚麻酸含量较高。     

七种植物籽油中脂肪酸成分的比较分析(英文)

为寻求新的食用油资源,发展了一种快速可靠的气相色谱-质谱联用方法,用于植物籽油中脂肪酸成分的定性鉴定和含量测定。所建立的方法成功用于葡萄籽、南瓜籽和猕猴桃籽等七种植物籽油中的棕榈酸、十八烷酸、油酸、亚油酸和α-亚麻酸的定性定量分析。结果表明,刺葡萄籽油、普通葡萄籽油、国外葡萄籽油、南瓜籽油、枸杞籽油和西番莲籽油均具有相似的脂肪酸谱,尽管其中它们所含上述五种脂肪酸含量不同,由于均存在人体所必需的饱和与不饱和脂肪酸,故可以用作替代食用油。猕猴桃籽油因为其存在高含量的α-亚麻酸成分,可能是更好的食用油和营养油资源。本文首次对枸杞籽油、西番莲籽油和猕猴桃籽油脂肪酸成分进行绝对含量分析,为新的食用油资源的开发提供了重要的依据。     

Macrophages transfer [14C]-labelled fatty acids to pancreatic islets in culture

Macrophages are able to produce, export, and transfer fatty acids to lymphocytes in culture. The purpose of this study was to examine if labelled fatty acids could be transferred from macrophages to pancreatic islets in co-culture. We found that after 3 h of co-culture the transfer of fatty acids to pancreatic islets was: arachidonic > oleic > linoleic = palmitic. Substantial amounts of the transferred fatty acids were found in the phospholipid fraction; 87.6% for arachidonic, 59.9% for oleic, 53.1% for palmitic, and 36.9% for linoleic acids. The remaining radioactivity was distributed among the other lipid fractions analysed (namely polar lipids, cholesterol, fatty acids, triacylglycerol and cholesterol ester), varying with the fatty acid used. For linoleic acid, a significant proportion (63.1%) was almost equally distributed in these lipid fractions. Also, it was observed that transfer of fatty acids from macrophages to pancreatic islets is time-dependent up to 24 h, being constant and linear with time for palmitic acid and remaining constant after 12 h for oleic acid. These results lead us to postulate that in addition to the serum, circulating monocytes may also be a source of fatty acids to pancreatic islets, mainly arachidonic acid.     

世界红花种质的籽油脂肪酸组分评价

对引自 48个国家和地区在北京栽培的 2 0 48份红花 (CarthamustinctoriusL .)种质资源的籽油脂肪酸分析表明 ,棕榈酸、硬脂酸、油酸和亚油酸的平均含量分别为 7.30 %、1.2 8%、15 .76 %和 75 .33% ,其含量范围分别为 0 .99%～ 2 9.0 3%、0 .0 1%～ 5 .71%、5 .0 0 %～ 81.84%和 11.13%～ 88.30 %。来自不同地区的红花种质 ,各种脂肪酸的含量有较大的差异。来源于孟加拉国的红花 ,亚油酸平均含量为 5 0 .6 8% ,来源于奥地利的红花 ,亚油酸平均含量高达79.0 4%。通过评价 ,分别筛选出 10个高亚油酸和 10个高油酸的品种 ,高油酸的品种中有 3个来自孟加拉国 ,而高亚油酸的品种大多来自中国     

Interaction of rat liver microsomes containing saturated or unsaturated fatty acids with fatty acid binding protein: Peroxidation effect

In the studies described here rat liver microsomes containing labeled palmitic, stearic, oleic or linoleic acids were incubated with fatty acid binding protein (FABP) and the rate of removal of¹⁴C-labeled fatty acids from the membrane by the soluble protein was measured using a model system. More unsaturated than saturated fatty acids were removed from native liver microsomes incubated with similar amounts of FABP. Thein vitro peroxidation of microsomal membranes mediated by ascorbate-Fe⁺⁺, modified its fatty acid composition with a considerable decrease of the peroxidizability index. These changes in the microsomes facilitated the removal of oleic and linoeic acids by FABP, but the removal of palmitic and stearic acids was not modified. This effect is proposed to result from a perturbation of membrane structure following peroxidation with release of free fatty acids from susceptible domains.Abbreviations BSA bovine serum albumin - FABP fatty acid binding protein     

Responses to oleic,linoleic and α-linolenic acids in high-carbohydrate,high-fat diet-induced metabolic syndrome in rats

We investigated the changes in adiposity, cardiovascular and liver structure and function, and tissue fatty acid compositions in response to oleic acid-rich macadamia oil, linoleic acid-rich safflower oil and α-linolenic acid-rich flaxseed oil (C18 unsaturated fatty acids) in rats fed either a diet high in simple sugars and mainly saturated fats or a diet high in polysaccharides (cornstarch) and low in fat. The fatty acids induced lipid redistribution away from the abdomen, more pronounced with increasing unsaturation; only oleic acid increased whole-body adiposity. Oleic acid decreased plasma total cholesterol without changing triglycerides and nonesterified fatty acids, whereas linoleic and α-linolenic acids decreased plasma triglycerides and nonesterified fatty acids but not cholesterol. α-Linolenic acid improved left ventricular structure and function, diastolic stiffness and systolic blood pressure. Neither oleic nor linoleic acid changed the left ventricular remodeling induced by high-carbohydrate, high-fat diet, but both induced dilation of the left ventricle and functional deterioration in low fat-diet-fed rats. α-Linolenic acid improved glucose tolerance, while oleic and linoleic acids increased basal plasma glucose concentrations. Oleic and α-linolenic acids, but not linoleic acid, normalized systolic blood pressure. Only oleic acid reduced plasma markers of liver damage. The C18 unsaturated fatty acids reduced trans fatty acids in the heart, liver and skeletal muscle with lowered stearoyl-CoA desaturase-1 activity index; linoleic and α-linolenic acids increased accumulation of their C22 elongated products. These results demonstrate different physiological and biochemical responses to primary C18 unsaturated fatty acids in a rat model of human metabolic syndrome.     

Acyl-CoA Synthetase in Oilseeds: Fatty Acid Structural Requirements for Activity and Selectivity

The substrate specificities and selectivities of acyl-CoA synthetasesfrom maturing oilseeds were investigated to reveal fatty acidstructures that the enzymes recognize. The synthetases fromrapeseed (Brassica nap us) and castor bean (Ricinus communis)activated palmitic acid 16:0 most rapidly among the saturatedfatty acids tested. Native unsat-urated fatty acids, oleic 18:1cis-9, linoleic 18:2 cis-9,12 and linolenic acid 18:3 m-9,12,15,were all effectively utilized. Palmitoleic acid 16:1 cis-9 wasalso a good substrate, while myristoleic acid 14:1 cis-9 wasa poor substrate. The activation of erucic acid 22:1 cis-13was very slow. Elaidic acid 18:1 trans-9 was utilized at ratessimilar to those of the cis isomer. The efficiencies of petroselinicacid 18:1 cis-6 were half the efficiencies of oleic acid, whilethe rates of activation of m-vaccenic acid 18:1 cw-11 were comparableto those for oleic acid. These findings suggest that acyl-CoAsynthetases of oilseeds producing long-chain fatty acids strictlyrecognize the molecular structures of fatty acids, i.e., thecarbon-chain length between C¹⁶-C¹⁸ and the position of thefirst double bond (     

Piperine modulation of carcinogen induced oxidative stress in intestinal mucosa

The plasma-borne long-chain free fatty acids (FFA) enter skeletal muscle cells. Upon entering they are oxidized or esterified and a fraction remains free (non-esterified). The data on free fatty acids in skeletal muscles remain highly controversial. Furthermore, the composition of individual fatty acids in various lipid fractions including free fatty acids, monoglyceride and diglyceride in muscles has not been characterized. Also data on the composition of fatty acids esterified into muscle triglycerides and phospholipids are incomplete. The present study was undertaken to examine a composition of fatty acids in lipid fractions of different skeletal muscle types. For this purpose, samples of the rat soleus, red and white portions of gastrocnemius were excised, trimmed of visible fat and fascias and immediately frozen in liquid nitrogen. Samples were then pulverized and, lipids were extracted and fractionated by thin-layer chromatography. Individual long-chain fatty acids in different fractions were identified, characterized and quantitated by gas-liquid chromatography. FFA composition in the plasma was also determined. The total FFA content in the soleus, red and white gastrocnemius was 69.1 ± 10.8, 49.0 ± 13.6 and 22.7 ± 8.6 nmol/g, respectively. Palmitic and oleic acids were the major fatty acids in the muscles FFA fraction. Monoglyceride fraction of each muscle contained palmitic, stearic and linoleic acid as the major fatty acids, Diglyceride fraction contained mostly palmitic and oleic acid whereas triglyceride fraction mostly palmitic and linoleic acid.. The fraction of phospholipids was composed mostly of palmitic and linoleic acid but contained also considerable percentage of archidonic acid. Total plasma FFA/muscle FFA ratio depended on a muscle type and was: 2.4 in the soleus, 3.5 in the red and 7.4 in the white gastrocnemius. This assured transport of FFA to the myocytes. However, there were great differences in the ratio between particular FFA within the same muscle as well between the muscles. It indicates that individual FFA are either selectively transported from the plasma to the muscles or selectively used within the myocytes or both.     

Platelet membrane fatty acids in thrombocytosis due to myeloproliferative disorders

The fatty acid composition of platelet membranes has been analysed in patients with thrombocytosis due to myeloproliferative disorders, who had not taken any drugs. A significant increase in palmitic and oleic acid, together with a decrease in stearic, linoleic and arachidonic acids was observed. The fatty acid pattern of platelet membranes was also analysed in patients during treatment with ASA (acetylsalicylic acid). ASA ingestion completely normalizes the platelet content of palmitic acid and partially that of stearic and arachidonic acid, whereas it has no effect on the level of linoleic acid and raises that of oleic acid. The altered pattern of fatty acids observed in patients may interfere with platelet function by decreasing membrane fluidity. Treatment of patients with ASA seems to act on platelet membranes by partially normalizing the fatty acid composition.