Distinctive selectivity for docosatetraenoic acid incorporation by Ehrlich ascites tumor cells

Regulation of the biosynthesis of platelet-activating factor in alveolar macrophages

Activities of enzymes which metabolize lysoplatelet-activating factor (lysoPAF) and platelet-activating factor (PAF) were studied in rabbit alveolar macrophage lysates. Substantial acetyltransferase activity was noted in the presence of 100 microM acetyl-coenzyme A (CoA), and this activity was increased in A23187-stimulated cell lysate. On the other hand, in the absence of exogenous acetyl-CoA, lysoPAF was mainly acylated through a transacylation pathway rather than by acetyltransferase in both control and A23187-stimulated cell lysates. We confirmed that the intracellular concentration of acetyl-CoA is relatively low. The observations suggest that the transacylation system may play an equally important role in the regulation of the availability of lysoPAF in intact cells. Intracellular lysoPAF was also maintained at relatively low levels. Interestingly, large amounts of PAF were produced even in unstimulated cells upon addition of an excess of exogenous lysoPAF, suggesting that generation of an adequate amount of lysoPAF within cells may be sufficient to trigger PAF synthesis in this type of cells.

Selective acyl transfer in the reacylation of brain glycerophospholipids. Comparison of three acylation systems for 1-alk-1'-enylglycero-3-phosphoethanolamine, 1-acylglycero-3-phosphoethanolamine and 1-acylglycero-3-phosphocholine in rat brain microsomes

The activities of three acylation systems for 1-alkenylglycerophosphoethanolamine (1-alkenyl-GPE), 1-acyl-GPE and 1-acylglycerophosphocholine (1-acyl-GPC) were compared in rat brain microsomes and the acyl selectivity of each system was clarified. The rate of CoA-independent transacylation of 1-[3H]alkenyl-GPE (approx. 4.5 nmol/10 min per mg protein) was about twice as high as in the case of 1-[3H]acyl-GPE and 1-[14C]acyl-GPC. On the other hand, the rates of CoA-dependent transacylation and CoA + ATP-dependent acylation (acylation of free fatty acids by acyl-CoA synthetase and acyl-CoA acyltransferase) of lysophospholipids were in the order 1-acyl-GPC greater than 1-acyl-GPE much greater than 1-alkenyl-GPE. HPLC analysis of newly synthesized molecular species revealed that the CoA-independent transacylation system exclusively esterified docosahexaenoate and arachidonate, regardless of the lysophospholipid class. The CoA-dependent transacylation and CoA + ATP-dependent acylation systems were almost the same with respect to the selectivities for unsaturated fatty acids when the same acceptor lysophospholipid was used, but some distinctive acyl selectivities were observed with different acceptor lysophospholipids. 1-Alkenyl-GPE selectively acquired only oleate in these two systems. 1-Acyl-GPE and 1-acyl-GPC showed selectivities for both arachidonate and oleate. In addition, an appreciable amount of palmitate was transferred to 1-acyl-GPC, not to 1-acyl-GPE, in CoA- or CoA + ATP-dependent manner. The acylation of exogenously added acyl-CoA revealed that the acyl selectivities of the CoA-dependent transacylation and CoA + ATP-dependent acylation systems may be mainly governed through the selective action of acyl-CoA acyltransferase. The preferential utilization of oleoyl-CoA by all acceptors and the different utilization of arachidonoyl-CoA between alkenyl and acyllysophospholipids indicated that there might be two distinct acyl-CoA:lysophospholipid acyltransferases that discriminate between oleoyl-CoA and arachidonoyl-CoA, respectively. Our present results clearly show that all three microsomal acylation systems can be active in the reacylation of three major brain glycerophospholipids and that the higher contribution of the CoA-independent system in the reacylation of ethanolamine glycerophospholipids, especially alkenylacyl-GPE, may tend to enrich docosahexaenoate in these phospholipids, as compared with in the case of diacyl-GPC.

Molecular species of glycerolipids of Ehrlich ascites cells and of their fat granules

Ehrlich ascites cells were grown in mice and were isolated by centrifugation of the ascites fluid. The cells were lysed with distilled water, and the floating fat particles were collected by centrifugation. The particles contained about 90% neutral and 10% polar lipid. The neutral lipid was made up of about 50% triacylglycerol, 30% alkyldiacylglycerol, 3% cholesteryl esters, 3% free cholesterol and 4% free diacylglycerols. The phospholipid fraction was comprised of about 50% phosphatidylcholine, 35% phosphatidylethanolamine, 10% sphingomyelin and small amounts (less than 5% total) of serine and/or inositol phosphatides. The triacylglycerol and alkyldiacylglycerol fractions possessed total carbon number and fatty acid compositions closely similar to those reported in the literature for whole ascites cells and for a cell membrane preparation. Likewise, the fatty acid composition of phospholipids from the granules in general was similar to that reported for Ehrlich ascites cells. On the basis of the polar and neutral lipid ratio, the lipid granules of the ascites cells were calculated to possess lipid core diameters of 30-50 nm, which were 40-70 times smaller than those (up to 2 mu) measured for the lipid granules of the intact cells by electron microscopy. The characterization of the lipid composition of the Ehrlich ascites lipid granules was completed by determining the molecular species composition of the diacyl, alkylacyl and alkenylacyl phosphatidylethanolamines and of the diacyl and alkylacyl phosphatidylcholines of the ascites cells. It is concluded that the alkyldiacylglycerols of the Ehrlich ascites cells occur largely in the cytoplasmic lipid granules, which appear to consist of many particles of the size and structure of very low density lipoproteins enclosed in membranous sacs.

Formation of diacyl and alkylacyl glycerophosphocholine in rabbit alveolar macrophages

The incorporation of various labeled precursors into alkenylacyl, alkylacyl and diacyl phospholipids in rabbit alveolar macrophages was studied. The incorporation rates of the individual precursors were shown to be quite different among the three subclasses of phospholipids. [3H]Glycerol, [14C]16:0, [14C]18:1, [14C]18:2 and [32P]-orthophosphate were preferentially incorporated into choline glycerophospholipids (CGP), especially into diacyl glycerophosphocholine (GPC), indicating that the de novo synthesis of diacyl GPC is extremely high. Considerable portions of the radioactivities of [14C]16:0, [14C]18:1, [14C]18:2 and [32P]orthophosphate were also found in alkylacyl GPC, the incorporation being higher than or comparable to that in the case of diacyl glycerophosphoethanolamine (GPE). We then examined the activities of cholinephosphotransferase and ethanol-aminephosphotransferase, and found that the activity of cholinephosphotransferase was remarkably high in macrophage microsomes compared with that in microsomes from several other tissues. This suggests that diradylglycerols were preferentially utilized by choline-phosphotransferase, which is consistent with the results obtained for intact cells. We confirmed that a considerably higher amount of diacyl GPC as well as alkylacyl GPC was formed through this enzyme reaction with macrophage microsomes than with brain microsomes. The high formation of alkylacyl GPC could be responsible, at least in part, for the accumulation of this unique ether phospholipid, a stored precursor form of platelet-activating factor in macrophages.

Selective transacylation of 1-O-alkylglycerophosphoethanolamine by docosahexaenoate and arachidonate in rat brain microsomes

The mechanism involved in the enzymic acylation of 1-[3H]alkylglycero-3-phosphoethanolamine (1-[3H]alkyl-GPE) in brain microsomes was investigated in comparison with the acylation of 1-[3H]alkylglycero-3-phosphocholine (1-[3H]alkyl-GPC). Both the alkyllsophospholipids were acylated without exogenously added cofactors to similar extents. The [14C]arachidonoyl moiety of exogenously added 1-stearoyl-2-[14C]arachidonoyl-GPC was transferred to the alkyllysophospholipids and the transfer was not inhibited by exogenously added free arachidonate. These results indicated that the transferase activity was due to a transacylase that catalyzes the transfer of fatty acids between intact phospholipids. The addition of CoA increased the acylation of 1-[3H]alkyl-GPC two or three times with a high acceptor concentration, and the highest rate of acylation of 1-[3H]alkyl-GPC was observed in the presence of CoA, ATP, and Mg2+. On the other hand, the addition of such cofactors only slightly increased the acylation of 1-[3H]alkyl-GPE. HPLC analysis revealed that docosahexaenoate and arachidonate were transferred to the second position of both [3H]alkyllysophospholipids without cofactors and that other fatty acids were transferred to much lower extents. With the addition of cofactors, the acylation of 1-[3H]alkyl-GPC by both docosahexaenoate and arachidonate increased 1.5-2 times, and high amounts of palmitate, oleate, and linoleate were newly transferred. High amounts of oleate were also transferred to 1-[3H]alkyl-GPE in the presence of cofactors but the acylation by both docosahexaenoate and arachidonate scarcely increased on the addition of these cofactors.(ABSTRACT TRUNCATED AT 250 WORDS)

Docosatetraenoic acid in endothelial cells: formation, retroconversion to arachidonic acid, and effect on prostacyclin production

Cultured bovine aortic endothelial cells convert arachidonic acid to docosatetraenoic acid and also take up docosatetraenoic acid from the extracellular fluid. After a 24-h incubation with biosynthetically prepared [3H]docosatetraenoic acid, about 20% of the cellular fatty acid radioactivity was converted to arachidonic acid. Furthermore, in pulse-chase experiments, the decrease in phospholipid docosatetraenoic acid content was accompanied by an increase in arachidonic acid, providing additional evidence for retroconversion. These findings suggest that one possible function of docosatetraenoic acid in endothelial cells is to serve as a source of arachidonic acid. The endothelial cells can release docosatetraenoic acid when they are stimulated with ionophore A23187, but they do not form appreciable amounts of eicosanoids from docosatetraenoic acid. Enrichment of the endothelial cells with docosatetraenoic acid reduced their capacity to produce prostacyclin (PGI2) in response to ionophore A23187. This may be related to the fact that docosatetraenoic acid enrichment caused a 40% reduction in the arachidonic acid content of the inositol phosphoglycerides. In addition, less prostacyclin was formed when the enriched cells were incubated with arachidonic acid, suggesting that docosatetraenoic acid also may act as an inhibitor of prostaglandin synthesis in endothelial cells.

Transacylation of 1-O-alkyl-SN-glycero-3-phosphocholine (lyso platelet-activating factor) and 1-O-alkenyl-SN-glycero-3-phosphoethanolamine with docosahexaenoic acid (22:6 omega 3)

[14C]22:6 (docosahexaenoic acid) was rapidly incorporated into cellular lipids in rabbit alveolar macrophages. After removal of free [14C]22:6, the radioactivity in diacyl-glycerophosphocholine (GPC) gradually decreased with a concomitant increase in [14C]22:6 in alkylacyl-GPC and alkenylacyl-glycerophosphoethanolamine (GPE), indicating that [14C]22:6 was transferred from diacyl-GPC to these ether lipid fractions. In fact, macrophage microsomes were shown to catalyze the transfer of [14C]22:6 from exogenously added diacyl-GPC to 1-alkyl-GPC (lyso platelet-activating factor) and 1-alkenyl-GPE. These results are the first evidence for the involvement of the transacylation system in the metabolism of C22 polyunsaturated fatty acids and lyso platelet-activating factor.

Identification of covalently attached fatty acids in the hydrophobic membrane-binding domain of human erythrocyte acetylcholinesterase

Human erythrocyte acetylcholinesterase is an amphipathic enzyme whose hydrophobic membrane-binding domain can be selectively labeled with a lipophilic photoreagent and removed by digestion with papain. In this paper we demonstrate that methanolysis releases covalently bound fatty acids from the hydrophobic domain and thus confirm that this domain is a covalently linked glycolipid at the enzyme subunit C-terminus. About one mole of saturated and one mole of unsaturated fatty acids were released per mole of domain. Since the predominant unsaturated fatty acids (22:4 and 22:5) are minor components of the esterified fatty acid pool in human erythrocyte membranes, assembly of the glycolipid must involve a selected unsaturated fatty acid pool.

Selective synthesis of the hexaenoic molecular species of ether-linked glycerophosphoethanolamine of Ehrlich ascites tumor cells

In a previous study [Waku, K. and Nakazawa, Y. (1978) Eur. J. Biochem. 88, 489-494], we observed the rapid turnover rate of the molecular species of alkylacyl glycerophosphoethanolamine (Gro-P-Etn) containing docosahexaenoic acid and the high selectivity for this molecular species of ethanolamine phosphotransferase was suggested. To clarify this point, the incorporation of [14C]ethanolamine and [14C]CDP-ethanolamine into the individual molecular species of alkenylacyl, alkylacyl and diacyl Gro-P-Etn has been determined in Ehrlich ascites tumor cells. [14C]Ethanolamine was highly incorporated into the pentaenoic + hexaenoic species of alkenylacyl, alkylacyl and diacyl Gro-P-Etn, whereas incorporation of [14C]ethanolamine into molecular species other than the pentaenoic + hexaenoic species was quite low. The selectivity of ethanolamine phosphotransferase to form the molecular species of alkylacyl and diacyl Gro-P-Etn was examined by incubation of [14C]CDP-ethanolamine and microsomes of Ehrlich ascites tumor cells. The incorporation of [14C]CDP-ethanolamine was found to occur most into the pentaenoic + hexaenoic species of both alkylacyl and diacyl Gro-P-Etn. The present results suggest that the pentaenoic + hexaenoic species are preferentially synthesized among the various kinds of molecular species of alkylacyl and diacyl Gro-P-Etn by the ethanolamine phosphotransferase in Ehrlich ascites tumor cells.

CoA-independent transfer of arachidonic acid from 1,2-diacyl-sn-glycero-3-phosphocholine to 1-O-alkyl-sn-glycero-3-phosphocholine (lyso platelet-activating factor) by macrophage microsomes

Macrophage microsomes catalyzed the transfer of arachidonic acid (20:4) from 1,2-diacyl-glycerophosphocholine (GPC) to 1-alkyl-GPC (lyso platelet-activating factor). This enzyme reaction did not require the presence of cofactors such as Co A. Free arachidonic acid or linoleic acid-labeled phospholipids failed to act as the acyl donor. These results suggest that the reaction is a CoA-independent direct transfer of arachidonic acid. This arachidonoyl transacylation system may play a very important role in the metabolism of lyso platelet-activating factor and also in the elimination or release of arachidonic acid from diacyl-GPC.

Turnover rates of the molecular species of ethanolamine plasmalogen of rat brain

1,2-Diradyl-3-acetylglycerols prepared from 1-O-alk-1'-enyl-2-acylglycero-3-phosphoethanolamine (alkenylacyl-GPE, ethanolamine plasmalogen) and 1-alkyl-2-acylglycero-3-phosphoethanolamine (alkylacyl-GPE) of rat brain at 18 days of age were subfractionated into six species by AgNO3-impregnated TLC. The percent compositions of substractions were compared with that of 1,2-diacylglycero-3-phosphoethanolamine (diacyl-GPE). The incorporation rate of [1-3H]glycerol into each molecular species was also estimated to examine the turnover rate and selective synthesis of molecular species of ethanolamine phosphoglycerides (EPG). Among the molecular species of EPG, a major proportion contained polyunsaturated fatty chains, and the sum of tetraene-, pentaene-, and hexaene-containing species was greater than 65% in common with three classes of EPG. It was possible to calculate the turnover time, synthesis rate, and synthesis rate constant of ethanolamine plasmalogen in myelinating rat brain by the equation of Zilversmit et al. since the time-dependent change of specific activity and the distribution of molecular species indicated that each molecular species of alkenylacyl-GPE is synthesized from the corresponding species of alkylacyl-GPE. The observed turnover time of ethanolamine plasmalogen was about 5 h. The observed turnover times of the various molecular species were of the order: tetraene greater than or equal to hexaene greater than pentaene greater than or equal to monoene greater than or equal to diene. The synthesis rate constants of each molecular species, in the formation of alkenylacyl-GPE from alkylacyl-GPE, were of the order: hexaene greater than tetraene greater than pentaene greater than diene greater than or equal to monoene.(ABSTRACT TRUNCATED AT 250 WORDS)