Absorption and metabolism of 1-14C-hydroxy octadecadienoate in the rat

The metabolism of 1-¹⁴C-9(13)-hydroxy octadecadienoic acid methyl ester (1-¹⁴C-HAME) by the rat was investigated in vivo and in liver slices. A 1.5 mg dose of 1-¹⁴C-HAME administered by stomach tube was efficiently hydrolyzed and absorbed from the intestinal tract. In comparison with 1-¹⁴C-methyl linoleate (1-¹⁴C-ML), 1-¹⁴C-HMAE was more extensively oxidized to¹⁴CO₂ in vivo and in vitro. After 1-¹⁴C-HAME administration as much as 50% of the radioactivity in the adipose tissue triglycerides was associated with¹⁴C-hydroxy fatty acids. The remaining activity was present in randomly labeled normal fatty acids. No evidence was obtained for the incorporation of¹⁴C-hydroxy acids into liver lipids; most of the radioactivity from 1-¹⁴C-HAME in this organ was recovered in saturated and monoenoic fatty acids. About 10% of the radioactivity 24 hr after 1-¹⁴C-HAME administration was associated with triglyceride trienoic acids, indicating that at least a portion of this acid was dehydrated in the liver. An unidentified polar acid was detected in the urine of the 1-¹⁴C-HAME-treated animals.     

Tissue culture of cocoa beans (Theobroma cacao L.): Incorporation of acetate and laurate into lipids of cultured cells

Suspension cultures of cocoa bean tissue readily incorporated exogenous acetate into lipids. The distribution of radioactivity from acetate in individual lipid classes after 48 hr was 20, 5, 1, 15, 25, and 35% in triglycerides, diglycerides, free fatty acids, sterol esters, sterols and polar lipids, respectively. The labeled acetate was rapidly incorporated into various fatty acids within 2 hr. The [1-¹⁴C] saturated fatty acids declined slightly after 4 hr, whereas [1-¹⁴C] oleate declined significantly after 2 hr. There was a concomitant increase in [1-¹⁴C] linoleate. The radioactivity associated with linolenate was relatively high up to 4 hr, declined by 24 hr, and then increased again. The kinetics of fatty acid labeling suggested that biosynthesis of linolenic acid in cocoa bean suspension culture may occur via the desaturation of linoleic acid and the chain elongation of dodecatrienoic acid. The patterns of fatty acid radiolabeling following incubation of cells with [1-¹⁴C] laurate was consistent with this mechanism.     

The in vivo incorporation of labeled linoleic acid, α-linolenic acid and arachidonic acid into rat liver lipids

The incorporation of 1-¹⁴C-linoleic acid, 1-¹⁴C-α-linolenic acid and 1-¹⁴C-arachidonic acid into rat liver lipids was measured and the per cent distribution of radioactivity into the different lipid fractions determined. Normal rats were injected into the portal vein with the labeled solutions during a one minute period. Livers were quickly frozen, pulverized, and the lipids extracted and fractioned by thin layer chromatography. No significant differences were observed in the amounts of labeled fatty acids incorporated per gram of rat liver. While 1-¹⁴C-linoleic acid and 1-¹⁴C-α-linolenic acid were found in appreciable amounts in the 1,2 diacylglycerol fraction, about one fifth as much 1-¹⁴C-arachidonic acid was esterified in this fraction. 1-¹⁴C-arachidonic acid was the leading acid esterified in the phospholipid fractions.     

Metabolism of 1-14C-methyl linoleate hydroperoxide in the rabbit

The metabolism of 1-¹⁴C-methyl linoleate hydroperoxide (1-¹⁴C-MLHP) by the rabbit was investigated. Administration of 1.1–1.9 mg of 1-¹⁴C-MLHP by ear vein injection proved lethal to four of the nine experimental animals. After 2 hr the lungs and liver contained 3.3% and 7.2%, respectively, of the dose. This radioactivity was found to be associated primarily with intact 1-¹⁴C-MLHP. The triglycerides from these tissues also contained¹⁴C-trienoic and¹⁴C-dienoic fatty acids. Of the dose, 68% was recovered as¹⁴CO₂ in 2 hr compared to 39% after 1-¹⁴C-methyl linoleate injection. The triglycerides from kidney adipose tissue contained a small amount of¹⁴C-hydroxy fatty acid, providing confirmation of previous evidence for the presence of a fatty acid hydroperoxide reductase in animal tissues.     

Plasma transport forms of ingested fatty alcohols in the rat

Previous studies have shown that ingested fatty alcohols are absorbed as fatty acids and fatty acid esters, particularly triglycerides. The present study was carried out to determine whether fatty alcohols are also transported as 0-alkyl glyceryl ethers, alk-1-enyl glyceryl ethers, and as wax esters. Oxidation of fatty alcohols to other lipids was assessed by using a mixture of [1-³H] hexadecanol and [1-¹⁴C] hexadecanol of predetermined ratio. The results indicate that the absorption of fatty alcohol, and of its transport forms, parallels the absorption of labeled fatty acids. Six to 25% of plasma radioactivity was present as 1-0-alkyl diacylglyceryl ethers with a smaller proportion of ether lipids in the phospholipid fraction. In addition, 4–13% of the ingested hexadecanol appeared in the plasma as a material having the chromatographic properties of wax ester. Fatty alcohols were not detected in the plasma as alk-1-enyl lipids.     

Nutrition and metabolic studies of methyl esters of dimeric fatty acids in the rat

Methyl esters of dimeric fatty acids were prepared by fractionating a mixture of conjugated linoleic and oleic acids that was heated for 24 hr at 300 C in the absence of air. Rats fed diets containing less than 1% dimers showed no significant difference (P<0.05) in the growth rate, feed efficiency, liver: body weight ratio, and lipid: liver weight ratio from those fed normal diets. A lymph cannulation study using¹⁴C labeled dimers showed that ca. 0.4% of the dimers fed were absorbed within 12 hr and were transported as free acids in the lymph. Within a 28 hr period, 2% of the labeled dimers fed by gastric intubation were oxidized to¹⁴CO₂, and 1% radioactivity was recovered from the urine. The metabolism of methyl oleate appeared normal for rats prefed diets containing dimers.     

Polyenoic acid metabolism in cultured human skin fibroblasts

The incorporation of [1-¹⁴C]linoleic acid, and [1-¹⁴C]linoleic acid into cellular lipids of cultured human skin fibroblasts was studied. Cultured cells took up both labeled fatty acids at nearly the same rate and incorporated them into a variety of lipid classes. At the end of 1 hr incubation with [1-¹⁴C]linoleic acid, radioactivity was found in the triacylglycerol (TG) and choline phosphoglyceride (CPG) pools preferentially. Incorporation into the TG fraction decreased rapidly, while the uptake into CPG, serine phosphoglyceride (SPG), and ethanolamine phosphoglyceride (EPG) fractions increased progressively with longer incubation times. Similar results were obtained with [1-¹⁴C]linoleic acid as precursor. At the end of 24 hr, desaturation and chain elongation of 18∶3 n−3 was more extensive than conversion of 18∶2 n−6 to higher polyenoic acids. During pulse-chase experiments with either fatty acid precursor, the incorporated radioactivity was progressively lost from cellular lipids, particularly from the TG and CPG fractions, but continued to increase in the SPG and EPG pools. The similar labeling pattern of cellular phospholipids with linoleic or linolenic acids, and data from pulse-chase studies suggest that a direct transfer of fatty acids from CPG to EPG is a likely pathway in fibroblast cultures. Incorporation into the EPG pool during the pulse-chase experiments paralleled extensive desaturation and elongation of linoleic acid into 20∶4 n−6, and 22∶4 n−6; and of linolenic acid into 22∶5 n−3 and 22∶6 n−3.     

Formation of diglycerides of long turnover time from labeled acetate and glucose in rat tissues

Rat adipose tissue pieces were incubated with acetate-2-¹⁴C and glucose-¹⁴C(U), respectively, and liver slices with acetate-2-¹⁴C. The labeled tissues were then reincubated in inactive medium, and the changes of radioactivity in the different lipid classes were determined. In all three experiments a significant amount of radioactivity was incorporated in the diglycerides. During 1 hr of reincubation in inactive medium the radioactivity of diglycerides decreased from 35 to 26% of the total lipid activity in the adipose tissue labeled with acetate. In the adipose tissue labeled with glucose radioactivity fell from 25 to 19%. In liver slices 11% of the labeled acetate was incorporated in the diglycerides, and during the 2 hr of reincubation this value fell to its half. The radioactivity of the uniformly labeled glucose was distributed equally in the fatty acids and the glycerol. The distribution of radioactive glycerol between diglycerides and triglycerides was similar to that of the labeled fatty acids. Triglyceride synthesis seems to always be accompanied by the formation of diglycerides with a lastint turnover time.     

Lipogenesis in the developing brain from intracranially administered [1-14C] acetate and [U-14C] glucose

Fifteen-day-old rats divided into two groups were given [1-¹⁴C]acetate or [U-¹⁴C] glucose by intracranial injection and were sacrificed after 1 hr. Analysis of lipids from the two groups showed differences in the incorporation of radioactivity in the polar lipids and cholesterol. Analysis of brain fatty acid showed that whereas radioactivity from acetate was incorporated into saturated, monoand polyunsaturated fatty acids, the radioactivity from [U-¹⁴C] glucose was found only in 16∶0, 18∶0, and 18∶1. No radioactivity was found in polyunsaturated fatty acids even after concentration of this fraction by AgNO₃:SiO₂ thin layer chromatographic method. This difference is discussed in hypothetical terms of nonhomogeneous acetyl CoA pool, formation of acetyl CoA from glucose exclusively inside the mitochondria, and activation of injected acetate to acetyl CoA.     

Metabolism of14C-labelled oleic acid,erucic acid and nervonic acid in rats

1-¹⁴C-Oleic acid, 2-¹⁴C-erucic acid and 2-¹⁴C-nervonic acid were administered to rats by tail-vein and the distribution of radioactivity in liver lipids was determined at intervals from 15 min to 6 hr after injection. High levels of activity were found after short time intervals which were mainly associated with triglycerides in the case of oleic acid and with free fatty acids in the case of erucic acid and nervonic acid. The activity in these lipids decreased with time and was later exceeded by that in more polar lipids. In rats given erucic acid or nervonic acid, sphingolipids were more highly labelled than glycerophosphatides. Nervonic acid showed little tendency to form a complex with serum albumin and erucic acid complexed less readily than palmitic acid. Presented at the AOCS Meeting in Houston, April 1965.     

Fatty acid biosynthesis and incorporation into lipid classes in seeds and seed tissues of flax

Fatty acid metabolism in developing flaxseeds was studied by incubating whole seeds or isolated seed tissues in buffered solutions of 1-¹⁴C-acetate, 2-¹⁴C-malonate and¹⁴CO₂. Lipid classes were separated by thin layer chromatography, and fatty acid labeling in phospholipids, diglycerides and triglycerides was determined by combined thin layer and gas liquid chromatographic techniques. Incorporation of¹⁴C from acetate into embryo lipids was very rapid with phospholipids and 1,2-diglycerides becoming highly labeled in treatment times as short as 5 min. Triglycerides were labeled more slowly. Phospholipid radioactivity was largely associated with the phosphatidyl choline fraction. Oleic acid had the highest specific activity of all major fatty acids in short treatment periods. This was followed in decreasing order of activity by palmitic, linoleic, stearic and linolenic acids. As the treatment period was lengthened to 90 min or longer, linoleic and linolenic activities were markedly increased. Use of malonate or CO₂ rather than acetate as the substrate increased the labeling of the saturated acids. Incorporation of¹⁴C from acetate into lipids of endosperm tissues and whole flax seeds was slower than incorporation into embryo lipids. Stearate had the highest specific activity of the fatty acids in endosperm and whole seeds. Presented in part at the AOCS Meeting in New York, October 1968.     

Is there an entero-hepatic circulation of the bile phospholipids?

Bile previously labeled with tritiated oleic acid (the main radioactivity was on bile phospholipids) was mixed with pure isolated phospholipids previously labeled with¹⁴C oleic acid; this mixture was perfused during 6 or 23 hr into the duodenum of test rats bearing a bile fistula. At the time of decapitation, in the small intestine a large hydrolysis of the¹⁴C phospholipids was found. In contrast no bile phospholipid hydrolysis was observed. In the collected bile samples of the test rats, no¹⁴C could be detected (this means a very large decrease of the¹⁴C fatty acids specific activities by the body fatty acids), and the tritiated fatty acids specific activities were only 2.5–12 times lower than in the perfused bile. These results can be explained, assuming that the bile phospholipids enter in an entero-hepatic circulation and are preserved from the dilution in a large pool of lipids.     

Pulmonary surfactant lipid synthesis from ketone bodies,lactate and glucose in newborn rats

The contribution of acetoacetate (AcAc), β-hydroxybutyrate (βOHB), lactate and glucose to pulmonary surfactant lipid synthesis in three-to five-day-old rats was measured. Minced lung tissue was incubated with³H₂O and [3-¹⁴C]AcAc, [3-¹⁴C]βOHB, [U-¹⁴C]lactate or [U-¹⁴C]glucose, and the radioactivity incorporated into surfactant lipids was measured. When expressed as nmol of substrate incorporated/g lung tissue per four hr, lactate was incorporated more rapidly than other substrates into total surfactant lipids and phosphatidylcholine (PC). There was no difference in the rates of incorporation of lactate, AcAc or glucose into disaturated PC (DSPC). Substrates other than glucose were incorporated almost exclusively into fatty acids, whereas 60–80% of glucose incorporated into surfactant phospholipids was found in fatty acids, with the remaining in glyceride-glycerol. When expressed as nmol acetyl units incorporated/g lung tissue per four hr, the rates of AcAc, lactate and glucose incorporation into total surfactant fatty acids were comparable. Glucose incorporation into DSPC and PC was greater than that of AcAc and lactate. When glucose was the only exogenous substrate added to the incubation medium, it contributed 37% of total surfactant fatty acids synthesized de novo. In the presence of other substrates, the contribution of glucose to de novo fatty acid synthesis dropped to 14–20%. In the presence of unlabeled glucose,¹⁴C-labeled AcAc, lactate and βOHB contributed 52%, 40% and 19%, respectively, of the total fatty acids synthesized de novo. The rate of βOHB incorporation into surfactant lipids was only about 50% that of other substrates and was accompanied by low activity of β-hydroxybutyrate dehydrogenase measured for newborn lung. These results demonstrate that AcAc and lactate are important precursors for surfactant lipids in neonatal rat lung.     

1-14C-Linoleic acid distribution in various tissue lipids of guinea pigs following an oral dose

A recent study on the metabolism of 1-¹⁴C-α-linolenic acid in the guinea pig revealed that the fur had the highest specific activity of all tissues examined, 48 h after dosing. The present study investigated the pattern of tissue lipid labeling following an oral dose of 1-¹⁴C-linoleic acid after the animals had been dosed for the same time as above. Guinea pigs were fed one of two diets with a constant linoleic acid content (18% total fatty acids) and a different content of α-linolenic acid (0.3 or 17.3%) from weaning for 3 wk and 1-¹⁴C-linoleic acid was given orally to each animal for 48 h prior to sacrifice. The most highly labeled tissues (dpm/mg of linoleic acid) were liver, followed by brain, lung and spleen, heart, kidney and adrenal and intestines, in both diet groups. The liver had almost a three-fold higher specific activity than skin and fur which was more extensively labeled than the adipose and carcass. Approximately two-thirds of the label in skin plus fur was found in the fur which, because of a low lipid mass, would indicate that the fur was highly labeled. All tissues derived from animals on the diet with the low α-linolenic acid level were significantly more labeled than the tissues from the animals on the high α-linolenic acid diet, by a factor of 1.5 to 3. The phospholipid fraction was the most highly labeled fraction in the liver, free fatty acids were the most labeled fraction in skin & fur, while triacyglycerols were the most labeled in the carcass and adipose tissue. In these tissues, more than 90% of the radioactivity was found in fatty acids with 2-double bonds in the tissue lipids. These data indicate that the majority of label found in guinea pig tissues 48 h after dosing was still associated with a fatty acid fraction with 2-double bonds, which suggests there was little metabolism of linoleic acid to more highly unsaturated fatty acids in this time frame. In this study, the labeling of guinea pig tissues with linoleic acid, 48 h after dosing, was quite different from the labeling with α-linolenic acid reported previously. The retention of the administered radioactivity from ¹⁴C-linoleic acid in the whole body lipids was 1.6 times higher in the group fed the low α-linolenic acid diet (diet contained a total of 1.8 g PUFA/100 g diet)compared with the group fed the high α-linolenic acid diet (diet contained 3.6 g PUFA/100 g diet). The lack of retention of ¹⁴C-labeled lipids in the whole body would be consistent with an increased rate of β-oxidation of the labeled fatty acid on the diet rich in PUFA, a result supported by other studies using direct measurement of labeled carbon dioxide.     

Biosynthesis of liver glycerolipids from normal and essential fatty acid-deficient rats:3H-glycerol and 1-14C linoleic acid incorporation

Normal and essential fatty acid (EFA)-deficient rats were injected via the portal vein with a labeled solution containing³H-glycerol and 1-¹⁴C-linoleic acid during a 1 min period. Livers were immediately frozen, pulverized, and the lipids extracted and fractioned by thin layer chromatography. The incorporation of³H-glycerol and 1-¹⁴C-linoleic acid into the different lipid fractions was measured, and the per cent distribution and specific radioactivity determined. A parallel increase was found between the specific activity and the amount of³H-glycerol incorporated into 1,2-diglycerides, triglycerides, lecithin and cephalin from EFA-deficient and normal rats. Since the amount of glycerol in each fraction studied was quite similar in both groups of rats, these findings can explain the increase in the specific activity observed in the EFA-deficient rats. Nevertheless these facts do not necessarily imply an increased turnover rate of these molecules, since we do not know the specific radioactivity of the 1,2-diacylglycerol precursors. A remarkable increase in the specific radioactivity of the¹⁴C-linoleic acid incorporated into lipid fractions from EFA-deficient rats compared with control rats was observed. While the amount of 1-¹⁴C-linoleic acid incorporated into neutral lipids was similar in both groups of rats, a statistically significant increase in the amount of the label incorporated into phospholipids from EFA-deficient rats was observed. These facts suggest an increased turnover rate of the radiolinoleic acid into phospholipid molecules from EFA-deficient rats via deacylation-reacylation pathway.     

Synthesis of phospholipids and phospholipid fatty acids by isolated perfused rat lung

Synthesis of phospholipids and phospholipid fatty acids in isolated perfused rat lung was studied. The perfusion fluid was a Krebs-Ringer bicarbonate buffer containing a¹⁴C labeled substrate. It was found that 1-¹⁴C-acetate, 1-¹⁴C-laurate, 1-¹⁴C-palmitate, 1-¹⁴C-stearate, 1-¹⁴C-oleate, or U-¹⁴C-D-glucose was incorporated into tissue lipids in the isolated perfused lung at a rate geeater than that in incubated minced tissue. However, the patterns of the newly synthesized lipids from these two systems were similar. In 1 hr of perfusion, 6.8, 3, 14.5, 7.5, 7, and 2% of the initial¹⁴C-radioactivity of 1-¹⁴C-acetate, 1-¹⁴C-laurate, 1-¹⁴C-palmitate, 1-¹⁴C-stearate, 1-¹⁴C-oleate, and U-¹⁴C-D-glucose, respectively, were incorporated into phospholipids. Phospholipid fatty acids accounted for 95–96% total phospholipids-¹⁴C when¹⁴C-substrates, other than glucose, were used. For glucose, only 20% phospholipids-¹⁴C was in phospholipid fatty acids. More than 80% phospholipid fatty acids-¹⁴C was in palmitic acid when 1-¹⁴C-acetate and U-¹⁴C-D-glucose were used, while 37, 61, 80, and 94% phospholipid fatty acid-¹⁴C from 1-¹⁴C-laurate, 1-¹⁴C-sterate, 1-¹⁴C-oleate, and 1-¹⁴C-palmitate, respectively were recovered in the original form of the fatty acid used. The newly synthesized phospholipid fatty acid (13–24%) from 1-¹⁴C-laurate, 1-¹⁴C-stearate, and 1-¹⁴C-oleate was palmitic, and 10% of phospholipid fatty acid from 1-¹⁴C-stearate was in oleic acid. Hydrolysis by phospholipase A showed that¹⁴C from perfused substrates was esterified to both α and β positions of phospholipids. It was found that positional selectivity of phospholipid fatty acids was determined by chain length, degree of unsaturation, and source of fatty acid.     

Positional specificity oftrans fatty acids in fetal lecithin

Differences in the positional incorporation of 9-trans[1-¹⁴C] octadecenoic (elaidic) and 9-trans,12-trans[1-¹⁴C] octadecadienoic (linoelaidic) acids in fetal lecithin of rats were demonstrated. On the 20th day of gestation, a¹⁴C-labeled albumin complex of elaidic or linoelaidic acid was injected into the jugular vein of pregnant rats. For comparative purposes, 9-cis[1-¹⁴C] octadecenoic (oleic) or 9-cis,12-cis[1-¹⁴C] octadecadienoic (linoleic acid) was injected into the maternal circulation of rats. Animals were killed 6 hr later. Distribution of label in total lipids and phospholipids (PL) of fetal tissue was measured by TLC. Irrespective of the label, the highest percentage of total radioactivity was associated with PL-59 to 67%. Within PL, the major portion of radioactivity was found in choline phosphoglycerides (CPG)-53 to 67%, and in ethanolamine phosphoglycerides (EPG)-18 to 33%. While linoelaidic acid was predominantly esterified in the 2-position of CPG, elaidic acid was nearly equally distributed between positions 1 and 2 of lecithin. Distribution of radioactivity within fatty acid methyl esters (FAME) of CPG measured by radio-GLC suggested that oleic and possibly linoleic acids may be converted to nervonic and arachidonic acid, respectively, in the rat by the 20th day of gestation. Following injection of elaidate, radioactivity of FAME was distributed between palmitate and elaidic acid indicating that rat fetal tissue may metabolize elaidic acid via β-oxidation. In contrast, following injection of linoelaidate, radioactivity of FAME was primarily associated withtt-18∶2, suggesting little biotransformation to other fatty acids by fetal tissues.     

Incorporation of [1-14C] acetate into phospholipids by soybean seedlings

Incorporation of [1-¹⁴C] acetate into lipids by slices of soybean seedlings was studied. The results were as follows: (a) the greatest amount of radioactivity was detected in the phospholipid fraction prepared from the main axis; (b) in the cotyledons, radioactivity was about the same in pigment, phosphatidylethanolamine, and phosphatidylglycerol; (c) phosphatidylcholine was the main phospholipid labeled in the axis; (d) the distribution of radioactive fatty acids in the axis suggested that this tissue has the capacity for both phospholipid synthesis and fatty acid desaturation.     

Incorporation of radioactive polyunsaturated fatty acids into liver and brain of developing rat

The incorporation of radioactivity from orally administered linoleic acid-1-¹⁴C, linolenic acid-1-¹⁴C, arachidonic acid-³Hg, and docosahexaenoic acid-¹⁴C into the liver and brain lipids of suckling rats was studied. In both tissues, 22 hr after dosing, 2 distinct levels of incorporation were observed: a low uptake (from 18∶2-1-¹⁴C and 18∶3-1-¹⁴C) and a high uptake (from 20∶4-³H₈ and 22∶6-¹⁴C). In adult rats, the incorporation of radioactivity into brain lipids from 18∶2-1-¹⁴C and 20∶4-³H was considerably lower than the incorporation into the brains of the young rats. In the livers of the suckling rats, the activity from the 18 carbon acids was associated mostly with the triglyceride fraction, whereas the activity from the 20∶4-³H₈ and 22∶6-¹⁴C was concentrated in the phospholipid fraction. In the brain lipids, the activity from the different fatty acids was associated predominantly with the phospholipids. In the liver and brain phospholipid fatty acids, some of the activity in the 18∶2-1-¹⁴C and 18∶3-1-¹⁴C experiments was associated with 20 and 22 carbon polyunsaturated fatty acids; however, radioactivity from orally administered 20∶4-³H₈ and 22∶6-¹⁴C was incorporated intact into the tissue phospholipid to a much greater extent compared with the incorporation of radioactivity into 20∶4 and 22∶6 in the experiments where 18∶2-1-¹⁴C and 18∶3-1-¹⁴C, respectively, were administered. Possible reasons for these differences are discussed. Rat milk contains a wide spectrum of polyunsaturated fatty acids, including linoleate, linolenate, arachidonate, and docosahexaenoate. During the suckling period in the rat, there is a rapid deposition of 20∶4 and 22∶6 in the brain. The results of the present experiments suggested that dietary 20∶4 and 22∶6 were important sources of brain 20∶4 and 22∶6 in the developing rat.     

In vivo incorporation of3H arachidonic acid and14C linoleic acid into liver lipids from essential fatty acid-deficient rats

Essential fatty acid (EFA)-deficient rats were injected intraportally with a labeled solution containing³H arachidonic acid and¹⁴C-linoleic acid during a 1 min period. Livers were quickly frozen, pulverized, and the lipids extracted and fractioned by thin layer chromatography. The incorporation of³H and¹⁴C into liver lipids was measured, and the per cent distribution of radioactivity into the different lipid fractions determined and compared with those previously obtained from normal rats. In contrast with normal rats, ca. 70% of the³H arachidonic acid and¹⁴C-linoleic acid incorporated into total lipids from EFA-deficient rats was recovered in the phospholipid fraction. From the results of this experiment, it is suggested that a more active deacylation-reacylation cycle in EFA-deficiency could be responsible for this increase.