Effect of elastase on prostacyclin synthesis in aortic smooth muscle cells

The effects of elastase on prostacyclin biosynthesis in cultured rat aortic smooth muscle cells were investigated. Prostacyclin is the major product formed from arachidonic acid by aortic smooth muscle cells. When intact cells were incubated with elastase, a significant stimulatory effect on prostacyclin biosynthetic activity in cells was evident. However, the addition of elastase directly to the cell-free homogenates did not show any effects on prostacyclin biosynthesis. The maximal effect of elastase on the stimulation of prostacyclin biosynthesis without any cellular damage was observed at a concentration of 50 unit/ml elastase. Elastase also caused a marked release of arachidonic acid. At higher concentrations of elastase (75-100 units/ml), the release of arachidonic acid and prostacyclin synthesis was observed, but, at these concentrations of elastase, cells were slightly damaged. On the other hand, the releases of prostacyclin and arachidonic acid were markedly enhanced, when cells were preincubated with elastase (1 unit/ml) for 3 days. These results indicate that elastase, even at low concentrations, causes the releases of arachidonic acid and prostacyclin, especially when aortic smooth muscle cells are pre-treated with elastase.     

Effect of streptokinase on prostacyclin synthesis and phospholipase activity in cultured pulmonary artery endothelial cells

In this study, we examined the effects of streptokinase on arachidonic acid release and prostacyclin biosynthesis in cultured bovine pulmonary artery endothelial cells. When intact cells were incubated with streptokinase, a significant stimulatory effect on prostacyclin biosynthetic activity in cells was evident without any cellular damage at all concentrations used (1-10,000 units/ml). Streptokinase also caused a marked release of arachidonic acid. It induced rapid phospholipid hydrolysis, resulting in the release of up to 15% of incorporated [3H]arachidonic acid into the medium. After the addition of streptokinase, degradation of phosphatidylcholine and phosphatidylethanolamine was observed and lysophosphatidylcholine and lysophosphatidylethanolamine were produced. We also observed a transient rise in diacylglycerol after the addition of streptokinase. To test for phospholipase C activity, the release of incorporated [3H]choline, [3H]inositol and [3H]ethanolamine into the culture medium was determined. The level of radioactive inositol showed an increase, but the changes in choline and ethanolamine were comparatively small. An increase in inositol was detectable within 1 min after streptokinase addition and peaked after 15 min. Inositol phosphate and inositol trisphosphate were released, and these releases were suppressed by the addition of neomycin (50 microM). These results suggest that streptokinase stimulates phospholipase A2 and C activity, and that prostacyclin biosynthesis is subsequently increased in cultured endothelial cells.     

Effects of estradiol on the metabolism of arachidonic acid by aortas and platelets in rats

We have previously reported that estradiol treatment stimulates prostacyclin production by cultured rat aortic smooth muscle cells, through the stimulation of fatty acid cyclooxygenase and prostacyclin synthetase activities. In order to see whether estradiol stimulates the fatty acid cyclooxygenase activity in platelets, intact rats were treated with estradiol, and thromboxane biosynthesis in platelets and prostacyclin production by aortas were investigated. Estradiol significantly stimulates prostacyclin production by aortas. However, no significant effect on thromboxane biosynthesis in platelets is observed. Our present results support the idea that estradiol would be a protective hormone in atherosclerotic heart disease.     

Induction of prostacyclin formation by sodium n-butyrate in a cloned epithelial liver cell line

The effect of sodium n-butyrate on prostaglandin synthesis in cultured cells was examined. Exposure of BC-90 cells, a clone of an epithelial rat liver cell line, to 1 mM sodium n-butyrate for 40 h induced prostacyclin production. Prostacyclin synthesis was proved by demonstrating: (1) production of labeled 6-ketoprostaglandin F1 alpha by treating [14C]arachidonic acid pre-labeled cells with calcium ionophore A23187, (2) production of unstable substance that inhibited adenosine diphosphate-induced platelet aggregation, and (3) conversion of [14C]arachidonic acid to 6-ketoprostaglandin F1 alpha in homogenates of n-butyrate-treated cells. Untreated control cells showed negligible prostaglandin synthesis. Untreated cell homogenates did not convert [14C]arachidonic acid to any prostaglandins, but they converted [14C]prostaglandin H2 to prostacyclin. Induction of prostacyclin production by n-butyrate was also demonstrated with cells that had been treated with acetylsalicylic acid before n-butyrate treatment in acetylsalicylic acid-free medium. Incorporation of [3H]acetylsalicylic acid by sodium n-butyrate-treated cells increased in accordance with treatment time, while that of untreated cells did not change during culture. There was no difference in the phospholipase A2 activities of n-butyrate-treated and -untreated cells. From these findings, the possibility that n-butyrate induced prostacyclin in BC-90 cells through induction of fatty acid cyclooxygenase activity is discussed.     

Control of terminal differentiation of adipose precursor cells by glucocorticoids.

The role of glucocorticoids on adipose conversion has been studied using confluent Ob1771 mouse preadipose cells maintained in a serum-free culture medium able to support the emergence of early but not that of late markers of differentiation. Under these culture conditions, glucocorticoids play, at physiological concentrations, a permissive role for terminal differentiation, characterized by glycerol-3-phosphate dehydrogenase expression and triacylglycerol accumulation within 12 days, whereas progesterone, testosterone, and estradiol are inactive. Glucocorticoids behave as mitogenic-adipogenic stimuli able to trigger growth-arrested, early marker-expressing cells to enter the terminal phase of the differentiation program and thus appear to mimic the mitogenic-adipogenic activity already described for arachidonic acid and cyclic AMP-elevating agents, especially prostacyclin. When compared to corticosterone alone, exposure of Ob1771 cells to both corticosterone and arachidonic acid leads to an additional increase in the glycerol-3-phosphate dehydrogenase activity and number of differentiated cells; this potentiation is further enhanced when the culture medium is supplemented with the cyclic AMP phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine. This suggests indirectly the involvement of prostacyclin as a metabolite of arachidonic acid able to induce cyclic AMP accumulation. In agreement with this hypothesis, it is found that a promoting effect is exerted by corticosterone on the metabolism of arachidonic acid, leading in turn to an increase in the production of prostacyclin. These findings allow a better understanding of the role of glucocorticoids on adipose cell differentiation and explain a posteriori the effectiveness of the combination of dexamethasone-isobutyl-methylxanthine used in innumerable studies.     

Changes in prostacyclin and thromboxane biosynthesis and their catabolic enzyme activity in kidneys of aging rats

The effects of aging on the prostacyclin and thromboxane biosynthesis and prostaglandin catabolic enzyme activity in rat kidney were investigated. The prostacyclin biosynthesis, using arachidonic acid as substrate, was the greatest in young kidneys (2 months old) and then progressively decreased in mature (12 months old) and old (24 months old) kidneys, while thromboxane biosynthetic activity showed no significant change as a function of age. When prostaglandin H2 was used as substrate, the prostacyclin and thromboxane biosynthesis showed similar results as when arachidonic acid was used as substrate; the prostacyclin biosynthesis progressively decreased and thromboxane biosynthesis showed no significant change as a function of age. The fatty acid cyclooxygenase in kidney was measured by a specific radioimmunoassay. No significant change in renal fatty acid cyclooxygenase as a function of age was found. Thus, we concluded that the progressive decrease in renal prostacyclin biosynthesis as a function of age is due to a defect in prostacyclin synthetase in aged kidneys. The prostaglandin catabolic enzyme, NAD+-dependent 15-hydroxyprostaglandin dehydrogenase, in kidneys was also investigated. The enzyme activity progressively decreased as a function of age, which suggested a decrease in the metabolism of thromboxane A2 in aged kidneys. The present results, indicating a decrease in renal prostacyclin biosynthesis and renal 15-hydroxyprostaglandin dehydrogenase activity with aging, might contribute to a plausible explanation of the progressive decrease in renal functions in the elderly.     

The role of thrombin in the regulation of the endothelial prostaglandin production

Prostaglandin synthesis in endothelial cells may be initiated by the addition of exogenous substrate (arachidonic acid) or by addition of thrombin or the CA2+-ionophore A23187, which leads to prostacyclin formation from endogenous substrates. We noticed that endothelial cells produce more than twice the amount of prostacyclin when incubated with thrombin and arachidonic acid together than with arachidonic acid alone. In addition, it was found that the thrombin-induced conversion of endogenous substrates was inhibited by exogenous arachidonic acid. This means that the conversion of exogenous added arachidonic acid to prostacyclin was stimulated by thrombin. This activation of the enzymes involved in prostacyclin synthesis lasted about 5 min and could be inhibited by phospholipase inhibitors such as mepacrine and p-bromophenyl-acylbromide but not by the cAMP analogue dibutyryl cAMP, an inhibitor of arachidonic acid release from cellular phospholipids. These data demonstrate that, in addition to causing release of endogenous substrate, thrombin and the Ca2+-ionophore also activate the enzyme system involved in the further transformation of arachidonic acid.     

Arachidonic acid releasing systems in pig aorta endothelial cells

Endothelial cells synthesize prostacyclin both from platelet-derived endoperoxides and from the arachidonic acid released from its intracellular stores. The mechanisms controlling this release does not appear to be mediated through phospholipid methylation but by means of phosphoinositide hydrolysis. As yet two possible mechanisms have so far been proposed to regulate arachidonic acid release in a number of cellular systems: phospholipase C-controlled phospholipase A2 activity or phospholipase C-diglyceride lipase system. The results presented here show that using phospholipases inhibitors is not a reliable strategy to study arachidonic acid release in cultures of endothelial cells. Our data also strongly suggest that the release of prostacyclin may be accounted in these cells for by a phospholipase C-diglyceride lipase system.     

Kallikrein stimulates prostacyclin production in bovine vascular endothelial cells

Cultured endothelial cells isolated from bovine carotid aorta produce prostacyclin (prostaglandin I2) and a small amount of prostaglandin E2. The effects of kallikrein (EC 3.4.21.8) on the release of prostacyclin from the cells were studied with the radioimmunoassay technique. Kallikrein stimulated the release of prostacyclin in a dose-dependent manner. The maximal stimulation reached up to 9.2-fold at 0.1 micrograms/ml of kallikrein. The effect was not associated with the activation of the fatty acid cyclooxygenase, but with the stimulation of arachidonic acid release. But kallikrein itself did not have phospholipase activity. On the other hand, at the same doses, kallikrein failed to induce platelet aggregation or enhance platelet aggregation induced by collagen. Our findings suggest that the vasodilator effect of kallikrein is mediated in part by prostacyclin production. Furthermore, we investigated the possibility that the stimulatory effect of kallikrein on prostacyclin production in endothelial cells is associated with kinin formation. Bradykinin and lysylbradykinin (kallidin) also stimulated the release of prostacyclin, but the effects were far less than that of kallikrein. And the stimulation due to the addition of both kallikrein and bradykinin on prostacyclin and arachidonic acid release was not competitive or additive, but synergistic. Moreover, even if fetal calf serum was incubated with kallikrein, bradykinin was not detected at all. When kallikrein was pre-incubated with aporotinin, which is an inactivator of kallikrein, the effect of kallikrein was completely abolished. These findings suggest that the stimulatory effect of kallikrein on the release of prostacyclin from vascular cells is possibly not due to kinin formation, but to other substance(s) produced by this serine proteinase.     

Differential effects of nitric oxide on the activity of prostaglandin endoperoxide H synthase-1 and -2 in vascular endothelial cells

A number of studies have demonstrated that prostacyclin and nitric oxide (NO) regulate blood pressure, blood flow and platelet aggregation. In this paper, we have examined the possible relationship between NO and prostaglandin endoperoxide H synthase (PGHS)-1 and -2 activities in cultured bovine aortic endothelial cells. In the non-activated condition endothelial cells expressed PGHS-1 activity alone. When these cells were pretreated with aspirin to inactivate their PGHS-1 and then activated by serum and phorbol ester (TPA) for 6 h, the cells expressed PGHS-2 activity alone. The PGHS activity was assessed by the generation of 6-ketoprostaglandin F1alpha (6-ketoPGF1alpha), a stable metabolite of prostacyclin, after the treatment of these cells with arachidonic acid. The simultaneous addition of NOC-7, a NO donor, with arachidonic acid did not affect the production of 6-ketoPGF1alpha in PGHS-1 expressed cells, but attenuated it in PGHS-2-expressed cells. The inhibitory effect of NOC-7 on PGHS-2 activity was dose dependent, and the different effects of NOC-7 on the activities of PGHS isozymes were also observed in other NO donors. To confirm the different effect of NO on PGHS isozymes demonstrated in the cultured endothelial cells, we carried out an ex vivo perfusion assay in aorta isolated from normal and lipopolysaccharide (LPS)-treated rats. In the aortae isolated from normal rats, where dominant expression of PGHS-1 was expected, the NO donor did not affect the PGHS activity, while in aortae isolated from LPS-treated rats, where PGHS-2 was dominantly expressed, the NO donor dramatically inhibited the PGHS activity, suggesting that NO suppressed PGHS-2 activity alone. The inhibitory effect of NO on PGHS-2 activity was not mediated by cyclic GMP (cGMP), since (a) methylene blue, an inhibitor of soluble guanylate cyclase did not abolish the inhibitory effect of the NO donor on PGHS-2 activity, and (b) 8-Br-cGMP, a permeable cGMP analogue, failed to mimic the effect of NO donors. These data suggest that the effect of NO on prostacyclin production in endothelial cells was dependent on the expression rate of PGHS-1 and PGHS-2 in the cells.     

Effects of dexamethasone on prostacyclin biosynthesis in rabbit mesothelial cells

We investigated whether glucocorticoids reduce the formation of arachidonic acid metabolites in a non myeloid cell type, the mesothelial cell, which is functionally and embryologically related to the vascular endothelial cell and which forms almost exclusively prostacyclin from arachidonic acid. Preincubation of rabbit mesothelial cells with 2.5 microM dexamethasone suppressed basal as well as bradykinin- or thrombin-stimulated prostacyclin biosynthesis. In further experiments bradykinin was selected as stimulus. The inhibition by dexamethasone was dose-dependent between 0.025 and 2.5 microM. The minimum contact period required for expression of this effect was 30 min and after a contact period of 60 to 120 min the inhibition reached a maximum, but was never complete. After 240 min, sufficient activity was secreted in the extracellular medium for inhibition of the prostacyclin formation in untreated cells. Experiments with cycloheximide were somewhat confused by its direct effects on prostacyclin biosynthesis, but still suggested that the anti-prostacyclin effect of dexamethasone required de novo protein biosynthesis. Our experiments indicate that glucocorticoids induce the formation of lipocortin-like factor(s) in non-phagocytic mesothelial cells, thereby suppressing the formation of prostacyclin, their main arachidonic metabolite.     

Stimulation of prostaglandin E2 biosynthesis by estradiol in rat kidneys

The effect of estradiol administration on renal prostaglandin (PG) E2 biosynthetic activity in rats was studied. A specific radioimmunoassay for PGE2 was developed and applied in the quantitation of PGE2 biosynthesis in kidney. Conversion of exogenous arachidonic acid into PGE2 by renal microsomal fraction was assayed. Formation of PGE2 was linear in fashion up to 5 min incubation at 37 degrees C, and linear in fashion up to 3.5 mg of microsome used as enzyme source. The renal biosynthesis of PGE2 was significantly increased by estradiol treatment.     

Effect of hypoxia on prostacyclin production in cultured pulmonary artery endothelium

Exposure of cultured bovine pulmonary artery endothelial cells to varying levels of hypoxia (10% or 0% O2) for 4 hours resulted in a significant dose-dependent inhibition in endothelial prostacyclin synthesis (51% and 98%, at the 10% and 0% O2 levels respectively, p less than 0.05, compared to 21% O2 exposure values). Release of 3H-arachidonic acid from cellular pools was not altered by hypoxia. Some of the cells were incubated with arachidonic acid (20 microM for 5 min) or PGH2 (4 microM for 2 min) immediately after exposure. Endothelium exposed to 0% O2, but not to 10% O2, produced significantly less prostacyclin after addition of either arachidonic acid (25 +/- 5% of 21% O2 exposure values, n = 6, p less than 0.01) or PGH2 (31 +/- 3% of 21% O2 exposure values, n = 6, p less than 0.05). These results suggest that hypoxia inhibits cyclooxygenase at the 10% O2 level and both cyclooxygenase and prostacyclin synthetase enzymes at the 0% O2 exposure levels. Exposure of aortic endothelial cells resulted in a 44% inhibition of prostacyclin at the 0% exposure level. No significant alteration in prostacyclin production was found in pulmonary vascular smooth muscle cells exposed to hypoxia. These data suggest that the increased prostacyclin production reported in lungs exposed to hypoxia is not due to a direct effect of hypoxia on the main prostacyclin producing cells of the pulmonary circulation.     

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.     

Suppression of cholesteryl ester accumulation in cultured human monocyte-derived macrophages by lipoxygenase inhibitors

Atherosclerotic lesions and xanthomas are characterized by the occurrence of cholesteryl ester (CE)-laden foam cells, which partly originate from macrophages. Little is known about the role of cyclo-oxygenase or lipoxygenase metabolites of arachidonic acid in the development of foam cells. In this study we investigated the influence of prostaglandins and inhibitors of the cyclo-oxygenase or the lipoxygenase pathway on CE accumulation in cultured human monocyte-derived macrophages. Accumulation of CE was achieved by incubation of the cells with acetylated low density lipoprotein (AcLDL). The stable prostacyclin analogue ZK 36 374 and prostaglandin E2 showed no effect on cellular CE storage. Similarly, the cyclo-oxygenase inhibitor indomethacin failed to influence AcLDL-induced CE accumulation. By contrast, however, the inhibitors of lipoxygenase activity nordihydroguaiaretic acid (NDGA) and BW 755 C markedly suppressed the accumulation of CE in monocyte-derived macrophages. The inhibitory effect of NDGA was dose-dependent. Incubation of the cells with the anti-oxidant vitamin E gave no significant reduction of CE accumulation. Our results indicate that inhibition of the lipoxygenase pathway of arachidonic acid metabolism in cultured monocyte-derived macrophages effectively decreases the rate of experimentally-induced CE accumulation.     

Inhibition of prostacyclin synthesis in endothelial cells by methylisobutylxanthine is not mediated through elevated cAMP level

Methylisobutylxanthine (MIX) raised cAMP levels and inhibited prostacyclin synthesis and arachidonic acid release in endothelial cells from both pig aorta and human umbilical vein. These effects were reversible and dose dependent on MIX concentrations. Dibutyryl cAMP (3 mM) alone did not inhibit prostacyclin synthesis or arachidonic acid release. When added with MIX, dibutyryl cAMP did not enhance the inhibition elicited by MIX. MIX inhibited the formation of lysophospholipids, 1,2-diacylglycerol and phosphatidic acid in bradykinin-stimulated pig endothelial cells, suggesting that the inhibition of prostacyclin synthesis resulted from an apparent inhibition of both phospholipase A2 and phospholipase C. Other phosphodiesterase inhibitors, theophylline and mopidamole, also raised cAMP levels and inhibited arachidonic acid release. However, there was no correlation between cAMP levels and these inhibitions. Forskolin, an adenylate cyclase activator, elevated intracellular cAMP levels with no apparent inhibition on prostacyclin synthesis. We conclude that the inhibitory effect of MIX on phospholipase A2 and phospholipase C is probably through mechanisms other than the elevation of the cAMP level.     

Possible inhibitory function of endogenous 15-hydroperoxyeicosatetraenoic acid on prostacyclin formation in bovine aortic endothelial cells

Arachidonic acid is metabolized via the cyclooxygenase pathway to several potent compounds that regulate important physiological functions in the cardiovascular system. The proaggregatory and vasoconstrictive thromboxane A2 produced by platelets is opposed in vivo by the antiaggregatory and vasodilating activity of prostacyclin (prostaglandin I2) synthesized by blood vessels. Furthermore, arachidonic acid is metabolized by lipoxygenase enzymes to different isomeric hydroxyeicosatetraenoic acids (HETE's). This metabolic pathway of arachidonic acid was studied in detail in endothelial cells obtained from bovine aortae. It was found that this tissue produced 6-ketoprostaglandin F1 alpha as a major cyclooxygenase metabolite of arachidonic acid, whereas prostaglandins F2 alpha and E2 were synthesized only in small amounts. The monohydroxy fatty acids formed were identified as 15-HETE, 5-HETE, 11-HETE and 12-hydroxy-5,8,10-heptadecatrienoic acid (HHT). The latter two compounds were produced by cyclooxygenase activity. Nordihydroguaiaretic acid (NDGA), a rather selective lipoxygenase inhibitor and antioxidant blocked the synthesis of 15- and 5-HETE. It also strongly stimulated the cyclooxygenase pathway, and particularly the formation of prostacyclin. This could indicate that NDGA might exert its effect on prostacyclin levels by preventing the synthesis of 15-hydroperoxyeicosatetraenoic acid (15-HPETE), a potent inhibitor of prostacyclin synthetase. 15-HPETE could therefore act as an endogenous inhibitor of prostacyclin production in the vessel wall.     

Synthesis and metabolism of leukotrienes by human endothelial cells: influence on prostacyclin release

The synthesis and metabolism of leukotrienes (LTs) by endothelial cells was investigated using reverse-phase high-performance liquid chromatography. Cells were incubated with [14C]arachidonic acid. LTA4 or [3H]LTA4 and stimulated with ionophore A23187. The cells did not synthesize leukotrienes from [14C]arachidonic acid. LTA4 and [3H]LTA4 were converted to LTC4, LTD4, LTE4 and 5,12-diHETE. Endothelial cells metabolized [3H]LTC4 to [3H]LTD4 and [3H]LTE4. The metabolism of [3H]LTC4 was inhibited by L-serine-borate complex, phenobarbital and acivicin in a concentration-related manner, with maximal inhibition occurring at a concentration of 0.1 M, 0.01 M and 0.01 M, respectively. LTC4, LTB4 and LTD4 stimulated the synthesis of prostacyclin, measured by radioimmunoassays as 6-keto-PGF1 alpha. The stimulation by LTC4 was greater than that by LTD4 or LTB4. LTE4, 14,15-LTC4 and 14,15-LTD4 failed to stimulate the synthesis of prostacyclin. LTD4 and LTB4 also stimulated the release of PGE2, whereas LTC4 did not. Serine-borate and phenobarbital inhibited LTC4-stimulated synthesis of prostacyclin in a concentration-related manner. They also inhibited the release of prostacyclin by histamine, A23187 and arachidonic acid. Acivicin had no effect on the release of prostacyclin by LTC4, histamine or A23187. Furthermore, FPL-55712, an LT receptor antagonist, inhibited LTC4-stimulated prostacyclin synthesis but had no effect on histamine-stimulated release of prostacyclin or PGE2. Indomethacin inhibited both LTC4- and histamine-stimulated release. The results show that (a) endothelial cells metabolize LTA4, LTC4 and LTD4 but do not synthesize LTs from arachidonic acid; (b) LTC4 act directly at the leukotriene receptor to stimulation prostacyclin synthesis; (c) the presence of the glutathione moiety at the C-6 position of the eicosatetraenoic acid skeleton is necessary for leukotriene stimulation of prostacyclin release; and (d) the metabolism of LTC4 to LTD4 and LTE4 does not appear to alter the ability of LTC4 to stimulate the synthesis of PGI2.     

Control of arachidonic acid accumulation in bone marrow-derived macrophages by acyltransferases

The turnover of phospholipid fatty acid moieties of bone marrow-derived macrophages was analyzed by separate determination of degrading and acylating activities. Acylating activities were followed in intact cells by incubation with excess arachidonic acid and degradation of phospholipids was followed in cells prelabeled with fatty acids. Significant phospholipase A2 activity was detectable only if the reutilization of liberated fatty acid was inhibited , e.g. by p-chloromercuribenzoate. It was of interest that the divalent cation ionophore A 23187 and various antiphlogistic drugs like indomethacin, diclofenac, and acetylsalicylic acid were found to inhibit the acylation reaction. These compounds led to increased levels of free arachidonic acid in stimulated, as well as in unstimulated cells. Increased activities of phospholipase A2 were achieved by treatment with the bivalent cation ionophore A 23187 and with zymosan. The effect of zymosan obtained from various sources was found to be exclusively due to contamination of tee zymosan particles with phospholipase A2 activity. Even when the cellular phospholipase activity was increased by the addition of exogenous phospholipase activity contained in the zymosan particles, degradation of cellular phospholipids was not measurable unless the reacylation was inhibited. These results suggest that in the cells studied, the level of free arachidonic acid is mainly controlled by the activity of the lysophosphatide acyltransferase.     

Production of arachidonic acid metabolites by operationally defined macrophage subsets

The antitumor activity and arachidonic acid metabolism of operationally defined macrophage populations was examined. Macrophages from mice injected with Mycobacterium bovis (strain BCG) or with pyran-copolymer were cytotoxic for tumor cells. The major arachidonic acid metabolite of these cells was PGE2. Neither resident nor elicited macrophages were cytotoxic. However, elicited macrophages as well as macrophages from BCG injected mice inhibited tumor cell growth. The production of arachidonic acid metabolites by elicited cells, while low initially, was followed by a rapid increase in PGE2. The major metabolites of resident cells were PGE2 and prostacyclin. The cAMP:cGMP ratio correlated with the metabolic activity of the cells.