C20 polyunsaturated fatty acids and phorbol myristate acetate enhance agonist-stimulated synthesis of 1-radyl-2-acetyl-sn-glycero-3-phosphocholine in vascular endothelial cells

This study has investigated the effect of supplementation of vascular endothelial cells with arachidonate and other polyunsaturated fatty acids on the agonist-stimulated synthesis of platelet activating factor (PAF; 1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine; 1-alkyl-2-acetyl-GPC). Incubation of calf pulmonary artery endothelial cells for 48 h in medium containing 40 microM arachidonate resulted in a 2-3-fold enhancement of [3H]acetate incorporation into 1-radyl-2[3H]acetyl-GPC in response to either bradykinin or calcium ionophore A23187. The effects of arachidonate supplementation were both dose- and time-dependent, requiring a minimum exogenous arachidonate concentration of 2.5 microM and an incubation time of 4-6 h. Eicosapentaenoate and docosahexaenoate also enhanced the synthesis of 1-radyl-2-[3H]acetyl-GPC, but were less potent than arachidonate; alpha-linolenate, linoleate and oleate were without effect. Although not effective as an agonist, phorbol myristate acetate potentiated A23187- and bradykinin-stimulated synthesis of 1-radyl-2-[3H]acetyl-GPC. The effects of arachidonate supplementation were synergistic with potentiation by phorbol myristate acetate. Sphingosine inhibited agonist-stimulated incorporation of [3H]acetate into 1-radyl-2-[3H]acetyl-GPC both in the presence and absence of PMA. Characterization of the radiolabeled material indicated that the primary product was the acyl analogue of PAF (1-acyl-2-acetyl-GPC) rather than PAF. The results from this study suggest that agonist-stimulated synthesis of 1-radyl-2-acetyl-GPC in vascular endothelial cells is modulated both by cellular fatty acyl composition and activation of protein kinase C. Enrichment of vascular endothelial cells with fatty acids, which are mobilized by agonist-stimulated phospholipase A2, may enhance subsequent deacylation of choline phospholipids and, thus, increase synthesis of both 1-acyl-2-acetyl-GPC and PAF.     

Hormone selective lipase activation in the isolated rabbit heart

The synthesis and release of PGs by the isolated perfused rabbit heart upon bradykinin stimulation results from lipase stimulation which liberates arachidonic acid for PG biosynthesis. The [¹⁴C]-labelled fatty acids, arachidonate, linoleate, and oleate, when infused into the heart preparation, were efficiently incorporated into the phospholipid pool in the heart, mostly in the 2-position of phosphatidylcholine. On the other hand, [¹⁴C]-palmitate was esterified into both the 1- and the 2-position. Bradykinin released bioassayable PG when injected into the rabbit hearts regardless of which fatty acid label was incorporated into the phospholipid pool. However, only [¹⁴C]-arachidonic acid (but not [¹⁴C]-linoleate, oleate or palmitate) was liberated from the variously labelled hearts upon hormone stimulation. This selective bradykinin effect on fatty acid release suggests that hormone stimulation either activates a specific lipase that distinguishes different fatty acids in the 2-position or activates lipase which is selectively compartmented with arachidonate-containing phospholipids. Ischemia, on the other hand, appeared to non-specifically stimulate tissue lipases, resulting in a non-selective release of oleic as well as arachidonic acid. A disproportionally large release of arachidonic acid was observed accompanying a relatively small PG (10:1 arachidonate: PG ratio) production during ischemia, as compared to bradykinin (3:1 ratio), suggesting distinct mechanisms for PG biosynthesis induced by bradykinin and ischemia.This work was supported by NIH grants: SCOR-HL-17646, HE-14397, HL-20787, and Experimental Pathology training grant (WH) 5 TO1 GM00897-16. Address correspondence to Dr. Philip Needleman, Department of Pharmacology, Washington University Medical School, St. Louis, Missouri 63110.     

Arachidonic acid-induced swelling in incubated rat brain cortical slices

The influence of bovine serum albumin (BSA) on the rat brain cortical swelling induced by sodium arachidonate and polyunsaturated fatty acids has been studied. Coincubation of arachidonate with BSA at a molar ratio of 5 (arachidonate/BSA) or less greatly inhibited the arachidonate-induced swelling. As the molar ratio of arachidonate/BSA increased, the degree of swelling increased. The swelling was not reversed by BSA, although the BSA released 46% of the previously incorporated [³H]arachidonic acid from the cortical slices. The entry of [³H]arachidonate into the slice was completely abolished by 0.1 mM BSA or partially inhibited by exogenous arachidonate. It is concluded that the induction of brain swelling by arachidonate requires the intracellular transport of exogenous arachidonate.     

An arachidonoyl (polyenoic)-specific phospholipase A2 activity regulates the synthesis of platelet-activating factor in granulocytic HL-60 cells

Human promyelocytic leukemia cells (HL-60) were used as a cell model to determine how arachidonic acid stimulates the synthesis of platelet-activating factor (PAF) synthesized via the remodeling pathway. In these studies HL-60 cells were cultured over 30 passages in fatty acid-free medium to deplete them of arachidonic acid. Even though the phospholipid classes from these cells contained no arachidonate, they could still be differentiated into granulocytes by dimethyl sulfoxide (1.25%). When the differentiated HL-60 cells, depleted of arachidonic acid, were stimulated with calcium ionophore A23187 in the presence of Ca2+ and [3H]acetate, only minimal amounts of [3H]PAF were produced. In contrast, if the differentiated HL-60 cells were supplemented with 10 microM arachidonic acid for 24 h and then stimulated with the ionophore, there was a large amount of [3H]PAF formed. The increase in PAF synthesis depended on the length of time the cells were supplemented with arachidonic acid; only a small increase in PAF synthesis occurred during the early hours of supplementation whereas stimulation of PAF synthesis was maximal (3-5-fold) after a 24-h period of the 20:4 supplementation. Other polyenoic fatty acid supplements (20:5, 22:4, and 22:6 for 24 h) also stimulated PAF production in the ionophore-treated HL-60 cells depleted of 20:4, but the amount of PAF was significantly less than found for the supplements of 20:4 under identical experimental conditions. Also noteworthy is that undifferentiated cells supplemented with 20:4 or their unsupplemented controls could not be stimulated by the calcium ionophore to produce PAF. Addition of indomethacin (cyclooxygenase inhibitor), A63162 (5'-lipoxygenase inhibitor), or eicosatetraynoic acid (cyclooxygenase/lipoxygenase inhibitor) to the incubations caused little change in the production of [3H]PAF in the differentiated cells supplemented with 20:4 for 24 h. On the other hand, the addition of mepacrine, bromophenacyl bromide, or U26384 (phospholipase A2 inhibitors) resulted in very large decreases (80-90% lower than controls) in the amount of [3H]PAF produced under the same conditions. Analysis of the molecular species of [3H]alkylacyl-GroPCho (1-alkyl-2-acetyl-sn-glycero-3-phosphocholine, the precursor of PAF in the remodeling pathway) in 20:4-supplemented cells prelabeled with [3H]alkyl-lyso-GroPCho revealed that only the alkylarachidonoyl-GroPCho species were preferentially decreased after stimulation with the A23187 ionophore.These results demonstrate that arachidonate must be at the sn-2 position of alkylacyl-GroPCho in order for it to serve as a precursor of PAF.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effect of prolonged prostaglandin exposure on prostaglandin synthesis by human lung fibroblasts

Pretreatment of human lung fibroblasts with PGE₂ but not PGF_2α enhanced synthesis of prostaglandins (PGs). The effect of the pretreatment on PG synthesis was related to the concentration of PGE₂ that was added to the culture medium. Pretreatment with PGE₂ at 5 × 10⁻¹²M did not enhance PG synthesis whereas pretreatment with PGE₂ at 5 × 10⁻⁶M induced a maximal effect. Production of PGs was increased following 1 day of pretreatment with PGE₂ and was increased further following 3 days of pretreatment. The PGE₂ treated cells showed only a slight increase in the bradykinin-induced release of radioactivity from cells prelabeled with [³H]arachidonic acid but showed a dramatic increase in the bradykinin-induced synthesis of radio-labeled PGs. The conversion of free arachidonate to PGs in both intact cells and in a cell-free preparation was increased by PGE₂ pretreatment. The presence of cyclohexamide during the pretreatment did not inhibit the PGE₂-induced activation of PG synthesis. Taken together, the results indicate that pretreatment of cells with PGE₂ increased PG synthesis by augmenting the conversion of arachidonate to PGs.     

Bradykinin-stimulated release of [3H]arachidonic acid from phospholipids of HSDM1C1 cells: comparison of diacyl phospholipids and plasmalogens as sources of prostaglandin precursors

Ethanolamine plasmalogens (1-alk-1'-enyl-2-acyl-sn-glycero-3-phosphoethanolamines) of many tissues contain high levels of arachidonate at their 2-position, and in certain tissues have been implicated as possible donors of arachidonate required in the synthesis of prostaglandins and thromboxanes. In the present study, [3H]arachidonate-labeled phospholipids of HSDM1C1 cells, a cell line derived from a mouse fibrosarcoma, were examined to determine the donor of the arachidonic acid released upon bradykinin stimulation of the synthesis of PGE2. HSDM1C1 cells labeled with [3H]arachidonic acid for 24 hr in serum-free medium were used in most of the experiments and had the following distribution of label among the cellular lipids; phosphatidylcholine (33%), phosphatidylinositol (20%), diacyl-sn-glycero-3-phosphoethanolamine (15%), ethanolamine plasmalogen (15%), and less polar lipids )16%). Bradykinin treatment stimulated a rapid hydrolysis of [3H]arachidonate from the cellular lipids and conversion of the released acid to PGE2, which was secreted into the medium. The label was released predominantly from phosphatidylinositol and possibly from phosphatidylcholine with no detectable change in the labeling of diacyl- or 1-alk-1'-enyl-2-acyl-sn-glycero-3-phosphoethanolamine. The ethanolamine plasmalogens, therefore, do not appear to be involved in the stimulated release of arachidonate in the HSDM1C1 cells. Indomethacin blocked the bradykinin-stimulated synthesis of PGE2 and to a lesser degree inhibited the release of [3H]arachidonate from the cellular lipids into the medium.     

The participation of hydroperoxides and oxygen radicals in the control of prostaglandin synthesis

Our results demonstrate that the organic hydroperoxide t-butyl-hydroperoxide (TBHP) influences the synthesis of prostaglandins in the human embryo lung fibroblast. TBHP inhibits or stimulates prostaglandin synthesis as a function of its concentration. Regardless of the concentration employed in these experiments however, TBHP stimulated the release of arachidonate from lipid stores. When the arachidonate release step in prostaglandin (PG) synthesis was bypassed by the addition of free arachidonate to the cell cultures, t-butyl hydroperoxide further stimulated PG synthesis, indicating that the hydroperoxide activates arachidonate conversion to prostaglandins. 4-Hydroxy-2,2,6,6-tetramethylpiperidinoxy radical, a scavenger of oxygen radicals, when added to cell cultures alone had no measurable effect on either arachidonate release or prostaglandin synthesis. When 4-hydroxy-2,2,6,6-tetramethylpiperidinoxy radical was administered to cell cultures in combination with t-butyl hydroperoxide, it increased prostaglandin synthesis while inhibiting arachidonate release by the hydroperoxide. The participation of hydroperoxides and trappers of oxygen radicals in the regulation of PG synthesis is not unique to lung fibroblasts. Endothelial cells from the vasculature as well as fibroblasts from the cornea also appear to be affected by these compounds with respect to prostaglandin synthesis.     

Mass quantitation of agonist-induced arachidonate release and icosanoid production in a fibrosarcoma cell line. Effect of time of agonist stimulation, amount of cellular arachidonate, and type of agonist

The mass of total arachidonate released from phospholipids upon agonist stimulation of the cell and the fraction of released arachidonate which is converted to icosanoids are two parameters of arachidonate metabolism which have been difficult to quantitate because the mass of arachidonate released upon cell stimulation is very low. We have been able to quantitate both of these parameters under a variety of experimental conditions using a unique essential fatty acid-deficient mouse fibrosarcoma cell line (EFD-1), which when repleted with arachidonate, produces prostaglandin E2 (PGE2). Because there is no endogenous pool of arachidonate in these cells, the specific activity of exogenous arachidonate does not change upon incorporation into cells, an advantage which permits mass determination of very small quantities of arachidonate directly from radioactive counts. EFD-1 cells were incubated with various concentrations of [14C]arachidonate (for release studies) or unlabeled arachidonate (for PGE2 radioimmunoassays) for 24 h and then stimulated with bradykinin. The time courses for arachidonate release and PGE2 production demonstrated that free arachidonate was rapidly converted to PGE2 with plateau levels attained for both parameters within 240 s of agonist exposure for 2 microM and for 10 microM arachidonate-repleted cultures. There was a linear relationship (r = 0.94) between the mass of arachidonate in the cell and the mass of arachidonate released upon stimulation, up to a cellular concentration of 11 nmol of arachidonate/10(6) cells, a concentration 10-20% above normal for the parent mouse fibrosarcoma cell line (HSDM1C1) which is not essential fatty acid-deficient. Importantly, the percent of released arachidonate which was converted to PGE2 decreased from 90 to 15% with increasing concentrations of cellular arachidonate, because PGE2 production plateaued at greater than or equal to 6 nmol of arachidonate/10(6) cells, but total arachidonate release continued to rise. Finally, we demonstrated that agonist stimulation with thrombin, A23187, and bradykinin all showed the same percent conversion of released arachidonate to PGE2, implying that the determination of this fraction is not a function of the mechanism of release. These studies with our unique cell line indicate that, when the concentration of arachidonate in the cell is not elevated above amounts normally found in our HSDM1C1 cell line, released arachidonate is rapidly and almost quantitatively converted to PGE2, independent of the agonist used to stimulate the cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effects of bradykinin on DNA synthesis in resting NIL8 hamster cells and human fibroblasts

Bradykinin stimulates [3H]thymidine incorporation and DNA synthesis in resting, serum-deprived NIL8 hamster cells. The ED50 for this stimulation is 4.52 +/- 2.91 nM. Other kinin peptides including lys-bradykinin (kallidin) and met-lys-bradykinin also stimulate [3H]thymidine incorporation in the NIL8 cells, whereas desarg9-bradykinin is without effect, suggesting action of the kinin peptides through type B2 receptors. Bradykinin also stimulates DNA synthesis in IMR-90 human fibroblasts; however, this effect is observed only in the presence of indomethacin, which blocks prostaglandin synthesis. These results suggest that prostaglandins act as negative modulators of the growth-stimulatory effects of bradykinin in the fibroblasts. This conclusion is supported by the observation that exogenously added PGE1, PGE2, PGA1, PGA2, PGB1, and PGB2 strongly inhibit [3H]thymidine incorporation in the human fibroblasts. The direct effect of bradykinin observed in the NIL8 cells may be attributable to the relative resistance of these cells to growth inhibition by prostaglandins.     

Effects of platelet-activating factor on the release of arachidonic acid and prostaglandins by rabbit iris smooth muscle. Inhibition by calcium channel antagonists.

Addition of physiological concentrations (10(-12)-10(-8)M) of platelet-activating factor (PAF) to rabbit iris muscle induced a rapid release (in 15s) of prostaglandin (PG)E2 and 6-oxo-PGF1 alpha, measured by radioimmunoassay and rapid release of 14C-labelled arachidonate and PGE2 in muscle prelabelled with [14C]arachidonic acid, measured by radiochromatography. These PAF actions are concentration- and time-dependent. The effect of PAF on PG release is not mediated through the cyclo-oxygenase pathway. The studies on the properties and mechanism of arachidonate release from phosphatidylinositol and other phospholipids in prelabelled irides by PAF suggest the involvement of a phospholipase A2. This conclusion is supported by the findings: (a) that both the removal of arachidonate and formation of lysophosphatidylinositol, from phosphatidylinositol, by PAF occur concomitantly in a time-dependent manner, (b) that Ca2+ is required for the agonist-induced release of arachidonate and PGE2, and (c) that in contrast to the rapid release of [3H]myo-inositol phosphates by carbachol and other Ca2+-mobilizing agonists previously reported in the iris muscle [Akhtar & Abdel-Latif (1984) Biochem. J. 224, 291-300], PAF (10(-12)-10(-8)M) did not appreciably enhance the release of [14C]myo-inositol phosphates and 32P labelling of phosphatidate and phosphatidylinositol in this tissue. Ca2+-channel antagonists, such as nifedipine, verapamil, diltiazem and manganese inhibited PAF-induced arachidonate and PGE2 release in a dose-dependent manner. K+ depolarization, which causes influx of extracellular Ca2+ in smooth muscle, did not increase the release of arachidonate and PGE2. The ability of Ca2+ antagonists to inhibit arachidonate release by PAF in this tissue probably reflects interference with PAF binding to its receptor. The PAF-induced release of arachidonate and PGE2 occur independently of the cyclo-oxygenase and lipoxygenase pathways. Whether the PAF-induced release of arachidonate and PG in the iris muscle is involved in the pathogenesis of inflammatory and/or physiological reactions in the eye, and how much the inhibitory effects of Ca2+-entry blockers on the PAF actions contribute to the therapeutic use of these drugs, remain to be established.     

The effect of endogenous essential and nonessential fatty acids on the uptake and subsequent agonist-induced release of arachidonate

We have demonstrated that the uptake and agonist-induced release of a pulse of arachidonate are influenced by the size and composition of preexisting endogenous fatty acid pools. EFD-1 cells, an essential fatty acid-deficient mouse fibrosarcoma cell line, were incubated with radiolabeled (14C or 3H] arachidonate, linoleate, eicosapentaenoate (EPA), palmitate, or oleate in concentrations of 0-33 microM for 24 h. After 24 h, the cells were pulsed with 0.67 microM radiolabeled (3H or 14C, opposite first label) arachidonate for 15 min and then stimulated with 10 microM bradykinin for 4 min. Because EFD-1 cells contain no endogenous essential fatty acids, we were able to create essential fatty acid-repleted cells for which the specific activity of the newly constructed endogenous essential fatty acid pool was known. Loading the endogenous pool with the essential fatty acids arachidonate, eicosapentaenoate, or linoleate (15-20 nmol of fatty acid incorporated/10(6) cells) decreased the uptake of a pulse of arachidonate from 200 to 100 pmol/10(6) cells but had no effect on palmitate uptake. The percent of arachidonate incorporated during the pulse which was released upon agonist stimulation increased 2-fold (4-8%) as the endogenous pool of essential fatty acids was increased from 0 to 15-20 nmol/10(6) cells. This 8% release was at least 3-fold greater than the percent release from the various endogenous essential fatty acid pools. In contrast, loading the endogenous pool with the nonessential fatty acids oleate or palmitate to more than 2-3 times their preexisting cellular level had no effect on the uptake of an arachidonate pulse. Like the essential fatty acids, increasing endogenous oleate increased (by 2-fold) the percent release of arachidonate incorporated during the pulse, whereas endogenous palmitate had no effect on subsequent agonist-induced release from this arachidonate pool. These studies show that preexisting pools of essential and nonessential fatty acids exert different effects on the uptake and subsequent releasability of a pulse of arachidonate.     

Lipoxygenase products of arachidonic acid modulate biosynthesis of platelet-activating factor (1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine) by human neutrophils via phospholipase A2

When human neutrophils, previously labeled in their phospholipids with [14C]arachidonate, were stimulated with the Ca2+-ionophore, A23187, plus Ca2+ in the presence of [3H]acetate, these cells released [14C]arachidonate from membrane phospholipids, produced 5-hydroxy-6,8,11,14-[14C]eicosatetraenoic acid (5-HETE) and 14C-labeled 5S,12R-dihydroxy-6-cis,8,10-trans, 14-cis-eicosatetraenoic acid ([14C]leukotriene B4), and incorporated [3H]acetate into platelet-activating factor (PAF, 1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine). Ionophore A23187-induced formation of these radiolabeled products was greatly augmented by submicromolar concentrations of exogenous 5-hydroperoxy-6,8,11,14-eicosatetraenoic acid (5-HPETE), 5-HETE, and leukotriene B4. In the absence of ionophore A23187, these arachidonic acid metabolites were virtually ineffective. Nordihydroguaiaretic acid (NDGA) and several other lipoxygenase/cyclooxygenase inhibitors (butylated hydroxyanisole, 3-amino-1-(3-trifluoromethylphenyl)-2-pyrazoline and 1-phenyl-2-pyrazolidinone) caused parallel inhibition of [14C]arachidonate release and [3H]PAF formation in a dose-dependent manner. Specific cyclooxygenase inhibitors, such as indomethacin and naproxen, did not inhibit but rather slightly augmented the formation of these products. Furthermore, addition of 5-HPETE, 5-HETE, or leukotriene B4 (but not 8-HETE or 15-HETE) to neutrophils caused substantial relief of NDGA inhibition of [3H]PAF formation and [14C]arachidonate release. As opposed to [3H]acetate incorporation into PAF, [3H]lyso-PAF incorporation into PAF by activated neutrophils was little affected by NDGA. In addition, NDGA had no effect on lyso-PAF:acetyl-CoA acetyltransferase as measured in neutrophil homogenate preparations. It is concluded that in activated human neutrophils 5-lipoxygenase products can modulate PAF formation by enhancing the expression of phospholipase A2.     

Inflammation and the mechanism of action of anti-inflammatory drugs

Inflammation is caused by release of chemicals from tissues and migrating cells. Most strongly implicated are the prostaglandins (PGs), leukotrienes (LTs), histamine, bradykinin, and, more recently, platelet-activating factor (PAF) and interleukin-1. Evidence for their involvement comes from studies with competitive antagonists for their receptors and inhibitors of their synthesis. H1 histamine antagonists are effective for hay fever and some skin allergies such as urticaria, which indicates the importance of histamine in these conditions. Symptoms of rheumatoid arthritis are alleviated by the aspirinlike anti-inflammatory drugs, which inhibit the cyclo-oxygenase enzyme and reduce synthesis of prostanoids. Corticosteroids prevent the formation of both PGs and LTs by causing the release of lipocortin, which by inhibition of phospholipase A2 reduces arachidonic acid release. They suppress the inflammation of rheumatoid arthritis and asthma. Currently, high doses of nonsedating H1 antihistamines and PAF antagonists are being tested for the treatment of allergic asthma.     

Evidence that hydrolysis of ethanolamine plasmalogens triggers synthesis of platelet-activating factor via a transacylation reaction

Addition of 1-O-alk-1'-enyl-2-lyso-sn-glycero-3-phosphoethanolamine (alkenyl-lyso-GPE) to human neutrophil membrane preparations containing 1-O-[3H]hexadecyl-2-arachidonoyl-sn-glycero-3-phosphorylcholine (1-O-[3H]alkyl-2-arachidonoyl-GPC) resulted in rapid deacylation of the 1-O-[3H]alkyl-2-arachidonoyl-GPC to 1-O-[3H]alkyl-2-lyso-GPC (lyso-platelet-activating factor, lyso-PAF). When acetyl-CoA was included in the incubation mixture, the [3H]lyso-PAF was converted to [3H]PAF. Studies of [3H]arachidonate-labeled neutrophils permeabilized with Staphlococcus aureus alpha-toxin revealed a major shift of labeled [3H]arachidonate from the choline to the ethanolamine-containing phosphoglycerides upon addition of alkenyl-lyso-GPE. The studies indicated that lyso-PAF is formed in the system by the transfer of arachidonate from 1-O-alkyl-2-arachidonoyl-GPC to the alkenyl-lyso-GPE by a CoA-independent transacylase reaction. Mass measurements revealed a rapid loss of arachidonate from 1-radyl-2-acyl-GPE and a concomitant increase in alkenyl-lyso-GPE upon stimulation of the neutrophils by ionophore A23187. Based on these and other findings, a pathway is proposed that may play a significant, if not obligatory, role in the synthesis of PAF in intact stimulated neutrophils. It has been widely accepted that phospholipase A2 acts directly on 1-O-alkyl-2-arachidonoyl-GPC as the first step in the synthesis of PAF via formation of lyso-PAF. In the proposed scheme, phospholipase A2, upon stimulation, acts rapidly on ethanolamine plasmalogen selectively releasing arachidonic acid and generating alkenyl-lyso-GPE. The CoA-independent transacylase then selectively transfers arachidonate from 1-radyl-2-arachidonoyl-GPC to the alkenyl-lyso-GPE generating lyso-PAF, which is then acetylated to form PAF. The interactions outlined can account for the synthesis of 1-acyl-2-acetyl-GPC, 1-O-alk-1'-enyl-2-acetyl-GPE, and eicosanoids, in parallel with PAF.     

Stimulation of platelet-activating factor synthesis by a nonmetabolizable bioactive analog of platelet-activating factor and influence of arachidonic acid metabolites

Platelet-activating factor (PAF) is a potent neutrophil agonist operating through specific receptors located on the cell surface. Binding of PAF to its receptor may also stimulate further PAF synthesis, thus providing a means of amplifying the PAF signal for the cell of origin and/or other responsive cells. In this report we demonstrate that 1-O-alkyl-2-N-methylcarbamyl-sn-glycero-3-phosphocholine (C-PAF), a nonmetabolizable bioactive analog of PAF, stimulates human neutrophils to synthesize PAF, as detected by [3H]acetate incorporation into PAF. This approach allowed us to conclude that [3H]acetate-labeled PAF was formed from endogenous precursor rather than mere turnover of the stimulatory dose of PAF. PAF's ability to initiate further PAF synthesis was confirmed by measuring the PAF-stimulated conversion of 1-O-[3H]alkyl-2-acylglycerophosphocholine to 1-O-[3H]alkyl-2-acetylglycerophosphocholine by prelabeled human neutrophils and by determining the molecular species of 1-O-alkyl-2-[3H]acetylglycerophosphocholine produced by cells stimulated with a single molecular species of PAF (C15:0). Degradation of exogenously added [3H]PAF was not inhibited by C-PAF/5-hydroxyeicosatetraenoic acid treatment. Thus, inhibition of PAF degradation was ruled out as the mechanism accounting for the appearance of labeled PAF in the stimulated cells. Synthesis of PAF in response to C-PAF was not dependent on cytochalasin B pretreatment but was dramatically potentiated by 5-hydroxyeicosatetraenoic acid, which alone was without effect. Additionally, we have demonstrated that another major arachidonate metabolite of neutrophils, leukotriene B4, stimulates PAF production. Thus, at least three products of activated neutrophils, including PAF itself, can promote PAF synthesis by these cells. This positive feedback effect may amplify autacoid production and the final cellular response.     

Conversion of arachidonic acid to cyclooxygenase and lypoxygenase products,and incorporation into phospholipids in the mouse neuroblastoma clone,Neuro-2A

Arachidonic acid (AA) incorporation into phospholipids and cyclooxygenase and lipoxygenase mediated metabolism of arachidonic acid were studied in homogenized and intact Neuro-2A cells. When 3H8-AA was added to homogenized cells and incubated 20 minutes, 39% of the label was converted to prostaglandins (PGs), 10% to hydroxy-eicosatetraenoic acid (HETE) and 26% was incorporated into phospholipids. PGE2 and PGF2a were the major PGs produced. Synthesis of PGs was blocked by 10 microM indomethacin and synthesis of PGs and HETE was blocked by 10 microM eicosatetraynoic acid (ETYA). The cell homogenate produced the 13,14-dihydro-15-keto metabolites of PGE2 and PGF2a from 3H8-AA and also converted exogenous 3H7-PGE2 and 3H8-PGF2a to metabolites. When intact cells were labeled for 24 hours with 14C1-AA and the cells and media then analyzed, 75% of the radioactivity was incorporated into cellular phospholipids, 0.8% was converted to PGs and metabolites and 0.7% converted to HETE. Cells prelabeled for 24 hours were washed and incubated for 30 minutes in fatty acid free media. There was a 23% release of AA from phospholipids. One-fifth of the released AA was converted to HETE. PG synthesis in the intact resting cells was low. In summary, the Neuro-2A cell provides a good model system for studying arachidonic acid metabolism and incorporation into phospholipids in cells of neuronal origin.     

Reacylation of platelet activating factor with eicosapentaenoic acid in fish-oil-enriched monkey neutrophils

Platelet activating factor (PAF) is rapidly metabolized via a deacetylation: reacylation pathway which shows striking specificity for arachidonate at the sn-2 position of the 1-O-alkyl-2-acyl-GPC thus formed. We have now examined the effects of a diet enriched in fish oils on the metabolism of PAF and specificity for arachidonate in the reacylation reaction. [3H]PAF was incubated for various lengths of time with neutrophils from monkeys fed a control diet or one enriched in fish oils. The [3H]PAF added to the cell suspension was rapidly converted to 1-O-alkyl-2-acyl-GPC. Reverse-phase HPLC analysis of the acyl chains added at the sn-2 position revealed that arachidonate was the major fatty acid incorporated into the 1-O-alkyl-2-acyl-GPC formed by neutrophils from monkeys on the control diet. In contrast, both 1-O-alkyl-2-arachidonoyl-GPC and 1-O-alkyl-2-eicosapentaenoyl-GPC were formed by the fish-oil-enriched neutrophils. We also report on the fatty acid composition of neutrophil phospholipids during such a diet.     

Bradykinin-stimulated release of [3H]arachidonic acid from phospholipids of HSDM1C1 cells: Comparison of diacyl phospholipids and plasmalogens as sources of prostaglandin precursors

Ethanolamine plasmalogens (1-alk-1′-enyl-2-acyl-sn-glycero-3-phosphoethanolamines) of many tissues contain high levels of arachidonate at their 2-position, and in certain tissues have been implicated as possible donors of arachidonate required in the synthesis of prostaglandins and thromboxanes. In the present study, [³H]arachidonate-labeled phospholipids of HSDM₁C₁ cells, a cell line derived from a mouse fibrosarcoma, were examined to determine the donor of the arachidonic acid released upon bradykinin stimulation of the synthesis of PGE₂. HSDM₁C₁ cells labeled with [³H]arachidonic acid for 24 hr in serum-free medium were used in most of the experiments and had the following distribution of label among the cellular lipids; phosphatidylcholine (33%), phosphatidylinositol (20%), diacyl-sn-glycero-3-phosphoethanolamine (15%), ethanolamine plasmalogen (15%), and less polar lipids (16%). Bradykinin treatment stimulated a rapid hydrolysis of [³H]arachidonate from the cellular lipids and conversion of the released acid to PGE₂, which was secreted into the medium. The label was released predominantly from phosphatidylinositol and possibly from phosphatidylcholine with no detectable change in the labeling of diacyl- or 1-alk-1′-enyl-2-acyl-sn-glycero-3-phosphoethanolamine. The ethanolamine plasmalogens, therefore, do not appear to be involved in the stimulated release of arachidonate in the HSDM₁C₁ cells. Indomethacin blocked the bradykinin-stimulated synthesis of PGE₂ and to a lesser degree inhibited the release of [³H]-arachidonate from the cellular lipids into the medium.     

Metabolism of platelet-activating factor by arachidonic acid-depleted rat polymorphonuclear leukocytes

1-O-[3H]Alkyl-2-acetyl-sn-glycero-3-phosphocholine ([3H]PAF) and 1-O-[3H]alkyl-2-lyso-sn-glycero-3-phosphocholine ([3H]lyso-PAF) when incubated with rat polymorphonuclear leukocytes (PMN) were rapidly metabolized to 1-O-[3H]alkyl-2-acyl-sn-glycero-3-phosphocholine ([3H]alkyl-acyl-GPC) containing long chain acyl groups in the sn-2 position. The specificity and the absolute requirements of arachidonate (20:4) for acylation into PAF and lyso-PAF were investigated by comparing the rate of [3H]PAF and [3H]lyso-PAF metabolism by control rat PMN with that by rat PMN depleted of 20:4. Comparable rates of metabolism of [3H]PAF and [3H]lyso-PAF by both control and 20:4-depleted PMN were observed at all the concentrations of PAF and lyso-PAF studied. The nature of the fatty acyl group incorporated into the sn-2 position of the [3H]alkyl-acyl-GPC formed was analyzed by argentation chromatography. Dienoic fatty acids were the major fatty acid incorporated into the alkyl-acyl-GPC by both control and 20:4-depleted PMN at all the incubation times studied. At 3 min of incubation with [3H]PAF and [3H]lyso-PAF, control PMN had small but significant amounts of [3H]alkyl-acyl-GPC containing tetraenoic fatty acids, the concentration of which gradually increased as the incubation time progressed. On the other hand, under similar conditions, 20:4-depleted PMN had only trace amounts of the [3H]alkyl-acyl-GPC with tetraenoic fatty acid and the concentration of which remained at the low level throughout the incubation time. At 3 min of incubation, the 20:4-depleted PMN had small but significant amounts of [3H]alkyl-acyl-GPC with saturated fatty acids, the amount of which declined by 10 min and remained at that level as the incubation time progressed. While the concentration of [3H]alkyl-acyl-GPC with dienoic fatty acids in the 20:4-depleted cells gradually increased with the progress of incubation time, these molecular species of GPC in the control PMN remained more or less constant. In spite of a very high concentration (equivalent to that of 20:4 in control PMN) of eicosatrienoic acid (20:3 delta 5,8,11) in the 20:4-depleted PMN, no significant amounts of [3H]alkyl-acyl-GPC with trienoic fatty acid were formed by these cells. The rate of metabolism of [3H]PAF and [3H]lyso-PAF by the resident macrophages isolated from control and 20:4-depleted rats was similar.(ABSTRACT TRUNCATED AT 400 WORDS)