Incorporation of [1-14C]Palmitic Acid into Neutral Lipids and Phospholipids of Rat Cerebral Cortex In Vitro

Abstract: Incorporation of [1-¹⁴C]palmitic acid into neutral lipids and phospholipids of rat cerebral cortex was examined in vitro in normal Krebs-Ringer bicarbonate buffer containing 3% (wthol) albumin and 0.75 mM palmitic acid. Under standard assay conditions, radioactivity in the triacylglycerol fraction increased rapidly during the first 30 min, and then decreased after 60 min, with corresponding increase in radioactivity in phosphatidyl choline, phosphatidyl ethanolamine, and a fraction of phosphatidyl inositol plus phosphatidyl serine. Diacylglycerol was shown to be an intermediate metabolite. Radioactivity increased in triacylglycerol, and decreased in phosphatidyl choline and phosphatidyl ethanolamine throughout incubation under NZ gas. In the fraction of phosphatidyl inositol plus phosphatidyl serine, radioactivity decreased after 30 min during incubation under N, gas. A possible acylation-deacylation cycle, in which triacylglycerol could be a source of free fatty acids for phospholipids, is discussed.     

Incorporation of acetate into fatty acids and lecithin by lung slices from fetal and newborn lambs

Incorporation of acetate-1-(14)C into phospholipids and fatty acids by lung slices from fetal and newborn lambs and from ewes was studied in vitro. The distribution of radioactivity in the fatty acids of neutral lipids, phospholipids, and lecithin was determined. Acetate-1-(14)C was incorporated into myristic, palmitic, and C(18) fatty acids. Of the lecithin fatty acids, myristic and palmitic were the major radioactive fatty acids. The results indicate that the lung of fetal lambs is able to synthesize lecithin containing saturated fatty acids, a major constituent of pulmonary surfactant. A marked increase in the rate of acetate incorporation into lecithin was observed during maturation, and these rates were higher than those obtained in the ewes. A possible relationship between developmental changes in lecithin biosynthesis and pulmonary surfactant is discussed.     

The turnover of myelin phospholipids in the adult and developing rat brain

1. Inorganic [(32)P]phosphate, [U-(14)C]glycerol and [2-(14)C]ethanolamine were injected into the lateral ventricles in the brains of adult rats, and the labelling of individual phospholipids was followed over 2-4 months in both a microsomal and a highly purified myelin fraction. 2. All the phospholipids in myelin became appreciably labelled, although initially the specific radioactivities of the microsomal phospholipids were somewhat higher. Eventually the specific radioactivities in microsomal and myelin phospholipids fell rapidly at a rate corresponding to the decline of radioactivity in the acid-soluble pools. 3. Equivalent experiments carried out in developing rats with [(32)P]phosphate administered at the start of myelination showed some persistence of phospholipid labelling in the myelin, but this could partly be attributed to the greater retention of (32)P in the acid-soluble phosphorus pool and recycling. 4. It is concluded that a substantial part of the phospholipid molecules in adult myelin membranes is readily exchangeable, although a small pool of slowly exchangeable material also exists. 5. A slow incorporation into or loss of labelled precursor from myelin phospholipids does not necessarily give a good indication of the rate of renewal of the molecules in the membrane. As presumably such labelled molecules originate by exchange with those in another membrane site (not necessarily where synthesis occurs) it is only possible to calculate the turnover rate in the myelin membrane if the behaviour of the specific radioactivity with time of the phospholipid molecules in the immediate precursor pool is known.     

Myristic acid, unlike palmitic acid, is rapidly metabolized in cultured rat hepatocytes

This study was designed to examine and compare the metabolism of myristic and palmitic acids in cultured rat hepatocytes. [1-(14)C]-Labeled fatty acids were solubilized with albumin at 0.1 mmol/L in culture medium. Incubation with 24-hr cultured hepatocytes was carried out for 12 hr. Myristic acid was more rapidly (P < 0.05) taken up by the cells than was palmitic acid (86.9 +/- 0.9% and 68.3 +/- 5.7%, respectively, of the initial radioactivity was cleared from the medium after 4 hr incubation). Incorporation into cellular lipids, however, was similar after the same time (33.4 +/- 2.8% and 34.9 +/- 9.3%, respectively, of initial radioactivity). In the early phase of the incubation (30 min), myristic acid was more rapidly incorporated into cellular triglycerides than was palmitic acid (7.4 +/- 0.9% and 3.6 +/- 1.9%, respectively, of initial radioactivity). However, after 12 hr incubation, the radioactivity of cellular triglycerides, cellular phospholipids, and secreted triglycerides was significantly higher with palmitic acid as precursor. Myristic acid oxidation was significantly higher than that of palmitic acid (14.9 +/- 2.2% and 2.3 +/- 0.6%, respectively, of the initial radioactivity was incorporated into the beta-oxidation products after 4 hr). Myristic acid was also more strongly elongated to radiolabeled palmitic acid (12.2 +/- 0.8% of initial radioactivity after 12 hr) than palmitic acid was to stearic acid (5.1 +/- 1.3% of initial radioactivity after 12 hr). The combination of elongation and beta-oxidation results in the rapid disappearance of C14:0 in hepatocytes whereas C16:0 is esterified to form glycerolipids. This study provides evidence that myristic acid is more rapidly metabolized in cultured hepatocytes than is palmitic acid.     

INCORPORATION OF [1-14C]OLEIC ACID AND [1-14C]ARACHIDONIC ACID INTO LIPIDS IN THE SUBCELLULAR FRACTIONS OF MOUSE BRAIN

Abstract— The distribution of radioactivity among lipids of subcellular membrane fractions was examined after intracerebral injections of [1-¹⁴C]oleic and [1-¹⁴C]arachidonic acids. Labelled free fatty acids were distributed among the synaptosomal-rich, microsomal, myelin and cytosol fractions at 1 min after injection. However, incorporation of the fatty acids into phospholipids and trïacylglycerols after pulse labelling occurred mainly in the microsomal and synaptosomal-rich fractions. With both types of labelled precursors, there was a higher percentage of radioactivity of diacyl-glycerophosphoryl-inositols in the synaptosomal-rich fraction as compared to the microsomal fraction. Radioactivity of [1-¹⁴C]oleic acid was effectively incorporated into the triacylglycerols in the microsomal fraction whereas radioactivity of the [1-¹⁴C]arachidonic acid was preferentially incorporated into the diacyl-glycerophosphorylinositols in the synaptosomal-rich fraction. Result of the study indicates that synaptosomal-rich fraction in brain is able to metabolize long chain free fatty acids in vivo and to incorporate these precursors into the membrane phosphoglycerides.     

L-tryptophan administration promotes the reversion of pre-established chronic liver injury in rats treated with carbon tetrachloride

We examined the effect of L-tryptophan (Trp) administration on the reversion of CCl(4)-induced chronic liver injury after hepatotoxicant withdrawal in rats. When rats treated with CCl(4) twice a week for 6 weeks were released from CCl(4) treatment for 2 weeks, there was an incomplete reversion of liver injury. The reversion was enhanced by 2 weeks of daily intraperitoneal administration of Trp (50 mg/kg body weight), starting just after CCl(4) withdrawal. There were increases in the levels of thiobarbituric acid reactive substances, an index of lipid peroxidation, Ca(2+), triglycerides, and Trp, and decreases in tryptophan 2,3-dioxygenase activity and serum triglyceride concentrations in the liver of rats treated with CCl(4) for 6 weeks. Serum albumin concentrations and in vitro hepatic protein synthesis activity did not change in the CCl(4)-treated rats. The changes in the CCl(4)-treated rats were partially attenuated 2 weeks after CCl(4) withdrawal. The attenuation was enhanced by 2 weeks of daily Trp administration. The increases in hepatic thiobarbituric acid reactive substances and triglycerides and the decreases in hepatic tryptophan 2,3-dioxygenase activity and serum triglyceride concentrations observed 2 weeks after CCl(4) withdrawal were almost completely attenuated by Trp administration. In vitro hepatic protein synthesis in CCl(4)-treated and untreated rats was increased by 2 weeks of daily Trp administration. These results indicate that Trp administration promotes the reversion of pre-established chronic liver injury in rats treated with CCl(4,) and suggest that Trp exerts this effect by enhancing the improvement of several parameters of liver dysfunction associated with chronic liver injury and by stimulating hepatic protein synthesis.     

Regional differences in lipid composition and incorporation of saturated and unsaturated fatty acids into microsomal membranes of rat small intestine

Incorporation of [1-14C]palmitic (16:0) and [1-14C]linoleic (18:2 omega 6) acids into microsomal membranes of proximal (jejunum) and distal (ileum) regions of rat small intestine was investigated, and the lipid composition, including fatty acid profiles of membrane phospholipids, was determined. Jejunal microsomes contained significantly higher amounts of total phospholipids, phosphatidylcholine, and phosphatidylinositol, and lower amounts of cholesterol and sphingomyelin when compared with ileal microsomes. Jejunal microsomal phospholipids contained higher levels of stearic (18:0), 18:2 omega 6, and eicosapentaenoic (20:5 omega 3) acids followed by reduced levels of oleic (18:1 omega 9), arachidonic (20:4 omega 6), and docosahexaenoic (22:6 omega 3) acids when compared with those from the ileum, except for phosphatidylinositol where no significant difference between 20:4 omega 6 content of each site was observed. In both jejunal and ileal microsomes, incorporation of [1-14C]18:2 omega 6 was significantly higher than that of [1-14C]16:0. Incorporation of both [1-14C]16:0 and [1-14C]18:2 omega 6 was significantly higher in jejunal microsomal lipid fractions (phospholipids, diacylglycerols, triacylglycerols) when compared with the ileal microsomal fraction. These data suggest that (1) jejunal and ileal microsomal membranes differ from each other in terms of lipid composition and lipid synthesis, (2) site variations in the specificity of acyltransferases for different fatty acids exist, and (3) higher delta 9-, delta 6-, delta 5-, and delta 4-desaturase activities exist in ileal compared with jejunal enterocytes.     

Preferential In Vivo Incorporation of [3H]Arachidonic Acid from Blood into Rat Brain Synaptosomal Fractions Before and After Cholinergic Stimulation

Abstract: Awake adult male rats were infused intravenously with [³H]arachidonic acid for 5 min, with or without prior administration of an M1 cholinergic agonist, arecoline (15 mg/kg i.p.). Methylatropine was also administered (4 mg/kg s.c.) to control and arecoline-treated animals. At 15 min postinfusion, the animals were killed, brains were removed and frozen, and subcellular fractions were obtained from homogenates of whole brain. Total radioactivity and radioactivity in various lipid classes were determined for each fraction following normalization for exposure by use of a unidirectional incorporation coefficient, k ^⋆_brain. In control animals, incorporation was greatest in synaptosomal and microsomal fractions, accounting for 50 and 30% of total label incorporated into membrane lipids, respectively. Arecoline increased incorporation in these two fractions by up to 400% but did not increase incorporation into the myelin, mitochondrial, or cytosolic fractions. Of the incorporated radioactivity, 50–80% was in phospholipid in microsomal and synaptosomal fractions, indicating that phospholipid is the major lipid affected by cholinergic stimulation. These results demonstrate that plasma [³H]arachidonic acid is preferentially incorporated into phospholipids of synaptosomal and microsomal fractions of rat brain. Cholinergic stimulation increases incorporation into these fractions, likely by activation of phospholipase A₂ and/or C in association with acyltransferase activity. Thus, intravenously infused radiolabeled arachidonic acid can be used to examine synapse-mediated changes in brain phospholipid metabolism in vivo.     

Effect of acute hypobaric hypoxia on 32-P incorporation into phospholipids of alveolar surfactant, lung, liver and plasma of rat.

Exposure of adult rats to hypobaric hypoxia caused hypolipidemia, hypotriglyceridemia and hypophospholipidemia. Hypobaric hypoxia produced an increase in liver triglyceride and cholesterol levels and a decrease in lung triglyceride, total phospholipid and phosphatidyl choline. The proportion of phosphatidyl choline in the pulmonary surfactant fraction I phospholipids (responsible for reducing surface tension) decreased (55.2% as compared to 80.4% in control animals). Incorporation of 32-P into liver phosphatidyl ethanolamine was significantly increased, incorporation into lung phosphatidyl choline and phosphatidyl ethanolamine was increased whereas a decreased incorporation into plasma phosphatidyl choline was observed. The data suggest an enhanced lipid synthesis in liver with a probable impairment of mobilization into plasma.     

Binding of products originating from the peroxidation of liver microsomal lipids to the non-lipid constituents of the microsomal membrane.

The binding of products derived from the peroxidation of liver microsomal lipids to the non-lipid constituents of the microsomes was studied. To this end arachidonic acid labelled with tritium at the positions of the double bonds was given to rats and allowed to incorporate into the membrane lipids of the liver cell. When liver microsomes containing labelled arachidonic acid were incubated aerobically in the NADPH-dependent system, a marked production of malonic dialdehyde (MDA) occurred and, concomitantly, there was a consistent release of radioactivity from the microsomes into the incubation medium. The addition of EDTA to the incubation medium prevented, to a large extent, both the MDA formation and the release of radioactivity. Chromatographic studies showed that the bulk of the radioactivity released from the incubated microsomes is not MDA. In the incubated microsomes, the radioactivity decreased in total lipids, while it increased by about 15 times in the non-lipoidal residue. A similar increase in radioactivity was seen in microsomal protein, while no increase was observed in microsomal RNA (the radioactivity was negligible in both the incubated and the non-incubated samples). It seems therefore that products originating from lipoperoxidation of arachidonic acid covalently bind to the microsomal protein. In order to investigate whether alterations similar to those observed in the in vitro peroxidation of liver microsomes could be detected in the in vivo intoxication with carbon tetrachloride, rats given labelled arachidonic acid as above, were poisoned with CCl4. Sixty minutes after poisoning, the radioactivity present in the microsomal lipids was generally lower in the intoxicated rats than in the controls, while the labelling of the non-lipoidal residue and of the protein was higher in the CCl4-poisoned rats.     

Incorporation of palmitic acid-1-14C into lipids of pharate adult tissues of Bombyx mori

Incorporation of palmitic acid-1-¹⁴C into pharate adult tissues and their lipid components of Bombyx mori was investigated. Rapid incorporation of radioactivity took place predominantly in fat body and haemolymph lipids, and partially in ovarian lipids immediately after the injection at the middle stage of pharate adult development. The major parts of the radioactivities in fat body, haemolymph and ovary were distributed in triglycerides and phospholipids, diglycerides, and triglycerides, respectively. The patterns of time course of incorporation of radioactivity into lipid components of pharate adult tissues suggest that the major form of lipid released from fat body may be diglycerides and the diglycerides in haemolymph are probably the main source of ovarian triglycerides.     

High-performance liquid chromatographic determination of phospholipid peroxidation products of rat liver after carbon tetrachloride administration

A method to detect and determine phospholipid peroxidation products in a biological system was developed using reversed-phase high performance liquid chromatography and normal-phase HPLC. Reversed-phase HPLC could separate phosphatidylcholine (PC) hydroperoxides and phosphatidylethanolamine (PE) hydroperoxides of rat liver from the respective phospholipids. A linear relationship was observed between these hydroperoxides and their peak areas on the chromatogram. In the experiment with rats administered CCl4, reversed-phase HPLC gave prominent, large peaks attributable to the peroxidation of phospholipids, and the peroxide level of the liver phospholipids was tentatively determined. Normal-phase HPLC analysis confirmed that both PC and PE in the liver phospholipids were peroxidized after CCl4 treatment. Neither the thiobarbituric acid value of the liver homogenate nor the fatty acid composition of the liver phospholipid fraction showed any significant difference between CCl4-treated and control rats. It is concluded that normal-phase HPLC and reversed-phase HPLC can complement each other to serve as a direct and sensitive method for the determination of lipid peroxide levels in a biological source. However, it was difficult to distinguish phospholipid hydroperoxides from their hydroxy derivatives.     

Lipogenesis from glucose-2- 14 C and acetate-1- 14 C in aorta

Lipogenesis was measured with glucose-2-(14)C and acetate-1-(14)C in the everted aortas of normal and atherosclerotic rabbits. More glucose-2-(14)C than acetate-1-(14)C was incorporated into lipids in both the normal and the atherosclerotic aorta. Radiocarbon from glucose-2-(14)C appeared mainly in triglycerides and phospholipids with a small amount in cholesteryl esters. Incorporation increased almost threefold with atherosclerosis, most of the radioactivity being in the glycerol moiety; radioactivity was predominantly in carbon 2 of glycerol. About 70% of the acetate-1-(14)C incorporated into phospholipids and triglycerides was in the fatty acids, and the remainder was in glyceride-glycerol; 98% of the radioactivity in cholesteryl esters was in the fatty acid moiety. Incorporation into cholesteryl esters was increased most during the development of atherosclerosis. Fatty acid synthesis was similar from both acetate-1-(14)C and the 2 carbon unit derived from glucose-2-(14)C, viz., predominantly de novo synthesis of fatty acids with 14 and 16 carbon atoms, and elongation for those of 18 carbons and longer.     

METABOLISM OF ARACHIDONOYL PHOSPHOGLYCERIDES IN MOUSE BRAIN SUBCELLULAR FRACTIONS

Abstract— Mouse brain subcellular fractions were prepared at 1, 12, and 24 h and 3 and 8 days after intracerebral injections of [1-¹⁴C]arachidonate. Initially, radioactivity was mainly distributed in the microsomal and synaptosomal fractions, but the proportion of radioactivity in the myelin increased from 5 to 16% within 8 days. Radioactivity of the microsomal lipids started to decline at 1 h after injection, and the decay was represented by two pools with half-lives of 19 h and 10 days, respectively. Radioactivity in the synaptosomal and myelin fractions did not reach a maximum until 24 h after injections. The half-life for turnover of synaptosomal lipids was 9 days.
The decline of radioactivity measured in the microsomal fraction was due mainly to diacyl-GPC and diacyl-GPI, since radioactivity of other phosphoglycerides (diacyl-GPS, diacyl-GPE and alkenyl-acyl-GPE) continued to increase for 12-24 h. In this fraction, half-lives of 10-14 h were obtained for the fast turnover pools of diacyl-GPC and diacyl-GPI, and slow turnover pools with half-lives of 7 days for diacyl-GPI and 10-14 days for other phosphoglycerides were also present. Among the synaptosomal phosphoglycerides, radioactivity of diacyl-GPI declined in a biphasic mode, thus exhibiting half-lives of 5 h and 5 days. Incorporation of labelled arachidonate into diacyl-GPE and diacyl-GPS in the synaptosomal fractions was observed for a period of 24 h. The half-lives for these phosphoglycerides ranged from 8 to 12 days. Results of the study have demonstrated the presence of small pools of arachidonoyl-GPI in synaptosomal and microsomal fractions which were metabolically more active than other arachidonoyl containing phosphoglycerides.     

Choline-deficiency fatty liver: impaired release of hepatic triglycerides

After intravenous injection of palmitate-1-(14)C to rats fed a choline-deficient (CD) or choline-supplemented (CS) diet for 15-18 hr, liver triglycerides became labeled very rapidly. In CS, but not in CD rats, there was a considerable loss, with time, of radioactivity from liver triglycerides. At the same time, significantly less radioactivity appeared in plasma triglycerides of CD rats than of CS animals. No difference was seen in the triglyceride content of microsomes isolated from the liver of rats fed the two diets. The lower radioactivity in plasma triglycerides of CD rats was essentially due to a lower level and specific activity of very low density lipoprotein triglycerides. After intravenous injection of Triton and labeled palmitate, considerably less radioactivity accumulated in plasma triglycerides and phospholipids of CD rats than of CS animals. Post-Triton hyperphospholipidemia was also less pronounced in CD rats. It was concluded that the fatty liver observed in CD rats results from an impaired release of hepatic triglycerides into plasma.     

Transient decrease of liver cytosolic glutathione S-transferase activities in rats given 1,2-dibromoethane or CCl4

In vivo treatment of fasted male rats with 1,2-dibromoethane (DBE) (0.4 mmol/kg) or carbon tetrachloride (CCl4) (4 mmol/kg) was found to rapidly alter the activities of liver cytosolic and microsomal glutathione S-transferases. Microsomal activities towards chloro-2,4-dinitrobenzene (CDNB) were increased 2 h after either treatment. Cytosolic activities towards CDNB and 3,4-dichloronitrobenzene (DCNB), but not 1,2-epoxy-3-(p-nitrophenoxy)-propane (ENPP), were selectively and transiently decreased after either treatment. Time course studies in DBE animals indicated that the decrease in cytosolic activity was not evident until 2 h although liver glutathione (GSH) concentrations were diminished within 15 min. In contrast, in CCl4 animals the decrease in cytosolic activity was evident within 15 min and was not accompanied by diminished GSH concentrations. By 4 h, cytosolic activities had rebounded to control levels in both DBE and CCl4-treated animals. Kinetic studies of the enzyme in liver cytosol from animals 2 h after treatment with DBE or CCl4 indicated that both treatments decreased the apparent Vmax while neither treatment altered the apparent Km. This pattern of change allows exclusion of a simple competitive mechanism of enzyme inhibition, but cannot distinguish between reversible non-competitive inhibition and irreversible inhibition. It is possible that the observed decreases in the activities of the abundant cytosal enzyme are due to 'sacrificial' covalent linkages between the enzyme and reactive metabolites of DBE or CCl4.     

Metabolism of fatty acids and their incorporation into phospholipids of the mitochondria and endoplasmic reticulum in isolated hepatocytes determined by isolation of fluorescence derivatives

Isolated hepatocytes were incubated in the presence of [14C]palmitic, [14C]linoleic or [14C]linolenic acid and the time-courses of incorporation of radioactivity into phosphatidylcholine and phosphatidylethanolamine of microsomes and mitochondria were followed. For this purpose a procedure was developed for HPLC separation of 9-diazomethylanthracene (ADAM) derivatives of fatty acids. When [14C]palmitic acid was used, the major product of elongation and desaturation was octadecadienoic acid, which accounted for 35-65% of the total radioactivity. Labeled palmitoleic, stearic and oleic acids could also be isolated. In fatty acids which do not participate to any large extent in deacylation-reacylation reactions, the pattern of incorporation was characteristic: a high rate of incorporation into microsomal and a low rate of incorporation into mitochondrial phospholipids during the first 40 min, followed by a decrease in the former and an increase in mitochondrial labeling. This pattern is consistent with the fact that de novo synthesis of these two phospholipids occurs in the endoplasmic reticulum in vivo. When cells were incubated in the presence of [14C]linoleic acid, 70-90% of the radioactivity recovered in phospholipids was in this same form, whereas the remaining label was mainly in arachidonic acid and, to some extent, in eicosatrienoic acid. When hepatocytes were incubated in the presence of [14C]linolenic acid, 70-85% of the radioactivity in isolated phospholipids was associated with linolenic acid. As much as 20% of the label was recovered in docosahexanoic acid and 5-10% in arachidonic acid. In the case of the two latter labeled substrates the exchange reactions seem to dominate over de novo synthesis. For phospholipids synthesized de novo the transfer from the endoplasmic reticulum to mitochondria requires about 3 h.     

The roles of ER stress and P450 2E1 in CCl(4)-induced steatosis

The role of ER stress on hepatic steatosis was investigated in a rat model. We injected CCl(4) into rats and found that CCl(4) could induce hepatic lipid accumulation, confirmed by Oil Red O staining and by measurement of triglyceride and cholesterol. The expression of ApoB, an apolipoprotein, was decreased in plasma and increased in the liver of CCl(4)-treated animals. The ER stress response was also significantly increased by CCl(4). P450 2E1 expression and activity were increased through interactions of P450 2E1 with NADPH-dependent P450 reductase (NPR) under CCl(4)-treated conditions. In HepG2 cells, intracellular lipid accumulation and its signaling were comparable to in vivo results. In order to elucidate the effect of the ER stress response itself, tunicamycin, an N-acetyl-glycosylation inhibitor, was injected into rats, followed by Oil Red O staining, lipid/triglyceride/cholesterol accumulation analysis, and examination of ApoB expression. Additionally, the ER stress response and upregulation of P450 2E1 were also confirmed in the tunicamycin-treated rats. All of the responses were similar to those seen with CCl(4). The P450 2E1 inhibitor diallyl sulphide (DAS), N-acetylcysteine (NAC), and reduced glutathione (GSH) antioxidants also regulated processes, including ApoB expression and lipid accumulation in CCl(4)-treated animals. In the presence of tunicamycin, DAS or NAC/GSH regulated all of the pathological phenomena with the exception of the ER stress response. In summary, CCl(4) induces liver steatosis, a process involving ER stress-induced P450 2E1 activation and ROS production.     

Oxygen-induced changes in pulmonary phospholipids in the rat.

The composition and synthesis of alveolar and lung tissue phospholipids were investigated in normal and oxygen-poisoned rat lungs. Sixty-hour exposure to oxygen increased the total amount of phospholipids in the endobronchial extracts and lung tissue. Phosphatidyl glycerol was identified in both endobronchial extracts and lung tissue. The amount of unsaturated fatty acids in surfactant lecithin and phosphatidyl glycerol was slightly increased in oxygen-poisoned lungs whereas the composition of phospholipids in the endobronchial extracts was not affected by oxygen. After intraperitoneal administration of [32P]phosphate the specific activities of surfactant lecithin and phosphatidyl glycerol were clearly lower in oxygen-treated animals whereas the specific activities of lung tissue lecithin and phosphatidyl glycerol remained unaffected. The synthesis of lecithin from [14C]methionine through N-methyltransferase pathway was markedly depressed in lung slices but increased in liver tissue taken from oxygen-poisoned rats and incubated under oxygen indicating a difference between lung and liver methyltransferase enzymes. In conclusion, the present work suggests impaired synthesis and removal of alveolar phospholipids in oxygen-poisoned rats.     

Phospholipid removal during degradation of rat plasma very low density lipoprotein in vitro.

The hydrolysis of glycerophospholipids in very low density lipoprotein by enzyme(s) released into circulation after the injection of heparin to rats was studied. [32P]Lysolecithin was formed rapidly from [32P]lecithin when very low density lipoprotein, labeled biosynthetically with 32P, was incubated with postheparin plasma. The [32P]lysolecithin was associated with the plasma protein fraction of density greater than 1.21 g/ml, whereas [32P]lecithin exchanged between very low and high density lipoproteins. Inhibition of the plasma lecithin: cholesterol acyl transferase activity did not change the excess [32P]lysolecithin formation in postheparin plasma, and only a negligible amount of radioactivity was associated with blood cells when the incubation was repeated in whole blood. Analysis of the results has demonstrated that phospholipids are removed from VLDL by two pathways: hydrolysis of glycerophospholipids by the heparin-releasable phospholipase activity (greater than50%) and transfer to high density lipoproteins (less than50%). The tissue origin of the postheparin phospholipase was studied in plasma obtained from intact rats and supradiaphragmatic rats using specific inhibitors of the extrahepatic lipase system (protamine sulfate and 0.5 M NaCl). The phospholipase activity could be ascribed to both the hepatic and extrahepatic lipase systems. It is concluded that hydrolysis of glycerophospholipids is the major mechanism responsible for the removal of phospholipids from very low density lipoprotein during the degradation of the lipoprotein. It is suggested that phospholipid hydrolysis occurs concomitantly with triglyceride hydrolysis, predominantly in extrahepatic tissues.