Tissue culture of cocoa bean (Theobroma cacao L.): Incorporation of fatty acids into lipids of cultured cells

Suspension cell cultures of cocoa bean rapidly incorporated palmitic, stearic, oleic and linoleic acids into cellular lipids. Thus, 75 and 20% of [1-¹⁴C] palmitic acid was incorporated into polar lipids and triglycerides, respectively, after 48 hr. When [1-¹⁴C] oleic and [1-¹⁴C] linoleic acid were added separately, polar lipids consistently contained most of the radioactive fatty acids. Ca. 60% of the stearic acid accumulated as unesterified fatty acid in the cells. Palmitic and stearic acid were not desaturated, but oleic acid and linoleic acid were further desaturated. The kinetics of conversion of oleic acid and linoleic acid suggested a sequential desaturation pathway of 18∶1→18∶2→18∶3 in cocoa bean cell suspensions.     

微生物细胞脂肪酸的组成分析

应用气相色谱—质谱联用技术(GC-MS)对微生物细胞脂肪酸的组成进行了分析.结果表明,菌体的代谢状态分为两个时期:菌体生长期和油脂积累期;菌体细胞主要积累油酸(C18:1)、软脂酸(C16:0)和棕桐油酸(C16:1);通过发酵,最终得到的微生物油脂脂肪酸组成为:油酸(C18:1)64.80％、软脂酸(C16:0)19...     

Fatty acid specificity of glyceride synthesis by homogenates of bovine mammary tissue

Fatty acid esterification by cell free preparations of bovine mammary tissue was investigated to determine if the type of long chain fatty acid supplied might influence the rate of triglyceride synthesis by that tissue. Homogenates of lactating bovine mammary tissue esterified¹⁴C-fatty acids into glycerides at rates dependent upon chain length and degree of unsaturation. Palmitic, stearic, oleic and linoleic acids were esterified at rates consistent with their concentration in milk fat. A comparison of free fatty acid concentrations of mammary tissue with levels saturating esterification suggested that supply of fatty acids does not limit glyceride synthesis. Certain combinations of fatty acids were facilitory, competitive or inhibitory to esterification. Stearic acid complimented esterification of palmitic and oleic acids. Unlabeledtrans-11-octadecenoic acid did not compete with¹⁴C-palmitate as efficiently in the esterification process as did unlabeledcis-9-octadecenoic acid, indicating that the mammary gland may preferentially esterify thecis-isomer of C-18∶1. Linoleic acid inhibited esterification of palmitic, stearic and oleic acids. Michigan Agricultural Experiment Station Journal Article No. 5100.     

Triglyceride composition ofmadhuca butyraceae seed fat

Fatty acid and triglyceride compositions of phulwara butter (Madhuca butyraceae seed fat) have been determined by combination of the techniques of systematic crystallization at low temperatures, pancreatic lipase hydrolysis, and gas liquid chromatography of methyl esters. The percentages of individual fatty acids were found to be palmitic, 55.6; stearic, 5.2; oleic, 35.9; and linoleic, 3.3. The special characteristic of the phulwara butter is its content of POP, 52.5%; PLP, 4.9%; POSt, 8.6%; POO, 14.4% and PPP, 7.7% (P, palmitic; St. stearic; O, oleic; and L, linoleic). 2-Monoglycerides obtained by lipolysis of this fat and its least soluble fraction contained 13,0% and 29.3% saturated acids, respectively. Phulwara butter may be a potential source of palmitic acid for the pharmaceutical industry.     

Fatty Acid Composition of Winged Bean Seed Oil (Psophocarpus tetragonolobus)

Winged bean seeds (Psophocarpus tetragonolobus) were shown to contain 14.4% of oil on a dry weight basis. Fractionation of this oil by silicic acid column chromatography showed 72.7% neutral lipids, 2.8% of glycolipids and 24.5% of phospholipids. Fatty acid composition of total lipid, neutral and glycolipid showed palmitic acid (12.2-14.0%), stearic acid (3.5-4.3%), oleic acid (36-39%) and linoleic acid (39-42%) as major fatty acids. The phospholipid fraction was slightly different from the rest in containing higher palmitic and lower oleic and linoleic acids.     

Composition of the lipids in cabbage

Cabbage leaves contain 0.16% total lipids of which 51.02% are neutral lipids, 40.78% glycolipids, and 8.18% phospholipids. The predominant fatty acids in the total lipid analysis are linolenic, linoleic, oleic, palmitic, and stearic acids. Linolenic, palmitic, tridecanoic, and oleic are the principal components in the neutral lipid fraction while glycolipids are composed mainly of linolenic, palmitic, lauric, myristic, and tricosanoic acids. Phospholipids are high in palmitic, linolenic, and linoleic acids. Both glucose and galactose were observed in the glycolipid fraction.     

The fatty acid composition of small and large naturally occurring milk fat globules

Native milk fat globules of various mean diameters, ranging from d₄₃ = 1.5 to 7.3 μm, were obtained using microfiltration of raw whole milk acquired in winter and spring. After total lipid extraction, fatty acid composition was characterized by methyl and butyl ester analysis using gas chromatography. The oleic and linoleic acid content of milk obtained in winter increased with fat globule size, whereas myristic and palmitic acid decreased. There was significantly more lauric, myristic and palmitoleic acid, and less stearic acid in small fat globules compared to large fat globules in milk obtained in both winter and spring. The relative content of oleic and linoleic acids were found to depend on fat globule size and season. Results are interpreted on the basis of the relative content of milk fat globule membrane depending on fat globule size, and on consequences of compositional variations on milk fat globule melting behavior.     

两种不同酯化方法分析樱桃仁中的脂肪酸成分

以乙醚为溶剂,采用索氏抽提法提取樱桃仁粗脂肪油,分别用氢氧化钾/甲醇碱催化甲酯化法和N,O-二(三甲基硅烷)乙酰胺硅酯化法进行衍生化处理,通过气相色谱/质谱联用技术分析脂肪酸的组成。结果显示,粗脂肪油提取量24.6%,主要成分为亚油酸、油酸、棕榈酸、硬脂酸、亚麻酸以及二十碳二烯酸等,其中多不饱和脂肪酸占大部分,两种衍生化方法测得其总含量分别为79.21%和64.25%,三甲基硅酯化法是一种更全面的分析测定樱桃仁脂肪酸组成的衍生化方法。     

Influence of Temperature on the Fatty Acid Composition of the Oil From Sunflower Genotypes Grown in Tropical Regions

The influence of temperature on the fatty acid composition of the oils from conventional and high oleic sunflower genotypes grown in tropical regions was evaluated under various environmental conditions in Brazil (from 0° S to 23° S). The amounts of the oleic, linoleic, palmitic and stearic fatty acids from the sunflower oil were determined using gas chromatography (GC). The environment exhibited little influence on the amounts of oleic and linoleic fatty acids in high oleic genotypes of sunflower. In conventional genotypes, there was broad variation in the average amounts of these two fatty acids, mainly as a function of the minimum temperature. Depending on the temperature, especially during the maturation of the seeds, the amount of oleic acid in the oil of conventional sunflower genotypes could exceed 70 %. Higher temperatures led to average increases of up to 35 % for this fatty acid. Although the minimum temperature had the strongest effect on the fatty acid composition, locations at the same latitude with different minimum temperatures displayed similar values for both oleic acid and linoleic acid. Furthermore, minimum temperature had little influence on the amounts of palmitic and stearic fatty acids in the oil.     

A comparative study of the lipid composition of isolated rat sertoli and germinal cells

The lipid composition of enriched preparations of sertoli cells and of germinal cells, isolated from the testes of mature rats, has been investigated. Sertoli cells contained a much lower content of phospholipids (in particular, much less phosphatidylcholine and phosphatidylethanolamine) and a higher content of triacylglycerols than did germinal cells. In addition, the Sertoli cells had a higher ratio of esterified to unesterified cholesterol than did germinal cells. Total lipids of Sertoli cells contained considerably lower levels of palmitic and docosa-4,7,10,13,16-pentaenoic acids and higher levels of stearic and oleic acids than did the total lipids of germinal less palmitic and docosa-4,7,10,13,16-pentaenoic acids, more stearic and oleic acids and also more arachidonic acid than did the corresponding lipid classes of the germinal cells. Minor differences between cell types were also noted for the content of palmitoleic, linoleic, docosa-7,10,13,16-tetraenoic, docosa-4,7,10,13,16,19-hexaenoic and tetracosa-9,12,15,18-tetraenoic acids.     

Characterization of polar and nonpolar seed lipid classes from highly saturated fatty acid sunflower mutants

The seed lipids from five sunflower mutants, two with high palmitic acid contents, one of them in high oleic background, and three with high stearic acid contents, have been characterized. All lipid classes of these mutant seeds have increased saturated fatty acid content although triacylglycerols had the highest levels. The increase in saturated fatty acids was mainly at the expense of oleic acid while linoleic acid levels remained unchanged. No difference between mutants and standard sunflower lines used as controls was found in minor fatty acids: linolenic, arachidic, and behenic. In the high-palmitic mutants palmitoleic acid (16∶1n−7) and some palmitolinoleic acid (16∶2n−7, 16∶2n−4) also appeared. Phosphatidylinositol, the lipid with the highest palmitic acid content in controls, also had the highest content of palmitic or stearic acids, depending on the mutant type, suggesting that saturated fatty acids are needed for its physiological function. Positional analysis showed that mutant oils have very low content of saturated fatty acids in the sn-2 position of triacylglycerols, between the content of olive oil and cocoa butter.     

Definite influence of location and climatic conditions on the fatty acid composition of sunflower seed oil

Percentages of linoleic, oleic and stearic acids present significant differences between growing areas, whereas palmitic acid content remains practically constant, or at least presents no significant relation to the growing area. Nevertheless, palmitic acid appears to follow a pattern that relates its content to the total content of the other three major fatty acids. Seeds grown in the northern part of Spain presented a higher linoleic content than seeds grown in the South, which is in agreement with the general theory found in prior studies. Although there is an inverse correlation between oleic and linoleic content, we have found that the total content of both is neither constant nor independent of temperature, and increases when temperature and oleic acid increase. However, stearic content increases when the combination of linoleic and oleic acid decreases, suggesting a total constant value for the combination of these three acids. The average temperature of the are during development of the seed and the local climatic conditions have the greatest influence over fatty acid composition, while the seed variety presents limited influence.     

Effects of age,sex, and diet upon carcass and liver fatty acid composition of pitman-moore miniature pigs

Fatty acid composition of carcass and liver and proximate analysis of liver were studied in 14–28 day old Pitman-Moore miniature pigs, 26 sow-reared and 30 fed a semisynthetic diet in which the fat was lard. With increasing age, fat of carcass, but not of liver, became significantly more unsaturated. The percentage of palmitic acid (16∶0) and total saturated fatty acids was significantly greater and the percentage of linoleic acid (18∶2) and total unsaturated fatty acids significantly less in carcasses of male than of female pigs. No sex-related differences in proximate or fatty acid composition of the liver were noted. Carcasses of sow-reared pigs contained significantly greater percentages of myristic (14∶0), palmitoleic (16∶1), and linoleic acids and significantly lesser percentages of stearic (18∶0) and oleic (18∶1) acids than did those of pigs fed the semisynthetic diet. Diet-related differences in fatty acid composition of liver closely paralleled those of carcass, although liver contained markedly greater percentages of stearic and arachidonic (20∶4) acids and lesser percentages of palmitoleic and oleic acids than did carcass. Diet-related differences in fatty acid composition of carcass and liver are discussed in relation to the fatty acid composition of dietary fat (sow milk and lard).     

Mold induced changes in cacao lipids

The free fatty acid content of sound cacao beans of nine geographic orgins varied from 2.7 to 4.8 meq./100 g fat. Fungi grown on cacao beans under humid environmental conditions have remarkable lipolytic activity. Values as high as 200 meq. free acid/100 g fat were obtained for badly deteriorated samples. Titration of the free fatty acids of cacao fat is suggested as a simple control procedure for detecting cocao butter obtained from moldy beans. Percentage composition of the free fatty acid fraction changes as a result of mold growth. Stearic and palmitic acid increased while oleic and linoleic acids decreased. Tracer experiments show no observable conversion of oleic acid to stearic. The changes suggest oxidative reactions to form carbonyl compounds.     

Variation in Fatty Acid Composition of Mowrah Fat

The determination of the fatty acid composition of mowrah fat obtained from kernels of West Bengal, Bihar, Orissa and Madhya Pradesh shows that mowrah fat contains 37 to 51 % saturated acids and 49 to 63 unsaturated acids. Considerable variation is observed in the content of the four major fatty acids viz. palmitic from 15 to 32 %, stearic between 15.9 to 17.0 % and 20 to 26 %, oleic from 32.4 to 35.9 % and as high as 45 %, and linoleic from 13.9 to 17.7 %.     

Differential utilization of long chain fatty acids during triacylglycerol depletion. II. Rat liver after starvation

Rats starved for 96 hr were shown to have a 94% reduction in liver triacylglycerol. Among the long chain fatty acids in liver triacylglycerol, only stearic acid and arachidonic acid were proportionally increased (2.5 and 6 times, respectively); palmitic and linoleic acids were unchanged, and palmitoleic and oleic acids were proportionally decreased. Stearic and arachidonic acids (mg%) were correlated positively within the triacylglycerol fraction, and both fatty acids varied inversely with total triacylglycerol (mg/g) in fed and starved rats. The utilization of long chain fatty acids from liver triacylglycerol during starvation resulted in selective retention of arachidonic acid and stearic acid and suggests that differential hydrolysis of liver triacylglycerol by hepatic lipase may occur or selective reacylation of these specific fatty acids may occur during starvation.     

The lipids of the common house cricket,Acheta domesticus L. I. Lipid classes and fatty acid distribution

The lipids of the common house cricket,Acheta domesticus L., have been examined with the following results. The fatty acids associated with the lipid extracts do not change significantly from the third through the eleventh week of the crickets' postembryonic life. The major fatty acids are linoleic (30–40%), oleic (23–27%), palmitic (24–30%), and stearic acids (7–11%). There are smaller amounts of palmitoleic (3–4%), myristic (∼1%), and linolenic acids (<1%). The fatty acid composition of the cricket lipids reflects but is not identical to the fatty acids of the dietary lipids: linoleic (53%), oleic (24%), palmitic (15%), stearic (3%), myristic (2%), and linolenic acid (2%). The amount of triglycerides present in the crickets increases steadily from the second through the seventh or eighth week of postembryonic life, then drops sharply. Other lipid classes, such as hydrocarbons, simple esters, diglycerides, monoglycerides, sterols, and free fatty acids remain about constant. The composition of the fatty acids associated with the tri-, di-, and monoglycerides and the free fatty acid fraction are all about the same. The fatty acids associated with the simple esters are high in stearic acid. Postdoctoral Research Associate, Department of Chemistry, University of Michigan, 1965–1967.     

Lipid Profile and Fatty Acid Composition of Moth Bean (Vigna aconitefolia) Seeds

The seeds of moth bean (Vigna aconitefolia) were found to contain 4.5 % of lipid. Fractionation of this lipid by silicic acid column chromatography yielded 44.5 % neutral lipids (NL), 23.4 % glycolipids (GL) and 32.1 % phospholipids (PL). Fatty acid composition of the total lipid and lipid fractions showed that palmitic acid (37.3-54.7 %), stearic acid (7.8-8.0%) oleic acid (6.8-13.9 %) linoleic acid (23.1-35.6 %) and linolenic acid (3.0-10.0%) are the major fatty acids. The phospholipid fraction was found to be different from the rest in containing higher palmitic acid (54.7%) and lower unsaturated fatty acids.     

Pithecolobium dulce II: Lipoids from the Seed

The component fatty acids of P. dulce seed fat has been found to be palmitic 7.2%, stearic 7.1%, arachidic 1.4%, behenic 6.9%, lignoceric 6.2%, oleic 47.3%, linoleic 21.7% and linolenic 1.7%. The phosphatide fatty acids also showed the presence of behenic and lignoceric acids.     

Fatty acid composition of lymphocytes and macrophages from rats fed fiber-rich diets: A comparison between oat bran- and wheat bran-enriched diets

The effect of oat bran-(OBD) and wheat bran-enriched diets (WBD) on fatty acid composition of neutral lipids and phospholipids of rat lymphocytes and macrophages was investigated. In neutral lipids of lymphocytes, OBD reduced the proportion of palmitoleic acid (48%), whereas WBD reduced by 43% palmitoleic acid and raised oleic (18%), linoleic (52%), and arachidonic (2.5-fold) acids. In neutral lipids of macrophages, OBD increased palmitic (16%) and linoleic (29%) acids and slightly decreased oleic acid (15%). The effect of WBD, however, was more pronounced: It reduced myristic (60%), stearic (24%) and arachidonic (63%) acids, and it raised palmitic (30%) and linoleic (2.3-fold) acids. Neither OBD nor WBD modified the composition of fatty acids in phospholipids of lymphocytes. In contrast, both diets had a marked effect on composition of fatty acids in macrophage phospholipids. OBD raised the proportion of myristic (42%) and linoleic (2,4-fold) acids and decreased that of lauric (31%), palmitoleic (43%), and arachidonic (29%) acids. WBD increased palmitic (18%) and stearic (23%) acids and lowered palmitoleic (35%) and arachidonic (78%) acids. Of both cells, macrophages were more responsive to the effect of the fiber-rich diets on fatty aicd composition of phospholipids. The high turnover of fatty acids in macrophage membranes may explain the differences between both cells. The modifications observed due to the effects of both diets were similar in few cases: an increase in palmitic and linoleic acids of total neutral lipids occurred and a decrease in palmitoleic and arachidonic acids of phospholipid. Therefore, the mechanism involved in the effect of both diets might be different.