Kallikrein stimulates arachidonic acid release and production of prostaglandins from TEA3A1 endocrine thymic epithelial cells.

Using TEA3A1 rat endocrine thymic epithelial cells, we demonstrated that kallikrein (EC 3.4.21.35) not only stimulated the release of arachidonic acid (AA) and its metabolites from TEA3A1 cells but also enhanced the intracellular synthesis of prostaglandin E2 (PGE2) and thromboxane B2 (TXB2) by approx. 2-fold. The stimulatory effect of kallikrein was dose- and time-dependent and could be blocked by aprotinin, a kallikrein inhibitor. It was found that the phospholipase A inhibitors ONO RS082 [2-(p-amylcinnamoyl)amino-4-chlorobenzoic acid], and mepacrine (6-chloro-9-[(4-dimethylamino)-1-methyl)]amino-2-methoxyacridine; quinacrine) also inhibited the kallikrein-stimulated release of AA and its metabolites. It is suggested that the kallikrein-induced stimulatory effect might be mediated through a phospholipase A2 pathway. The effect of bradykinin was studied and no significant stimulation was observed, even at a high dose (10 micrograms/ml). This suggested that the formation of kinin does not have a role in the kallikrein-induced stimulation of AA release from TEA3A1 cells. Furthermore, the effect of kallikrein was also totally abolished by adding pepstatin A, a known inhibitor of renin, pepsin and cathepsin D which does not inhibit kallikrein itself. This indicates that kallikrein did not act on the phospholipase-like enzyme directly. There is at least one more enzyme, a pepstatin A-inhibitable proteinase, that acts as a mediator for kallikrein-induced regulation of AA release.     

Physiological concentrations of ADP stimulate the release of prostacyclin from bovine aortic endothelial cells

ADP (0.2-200 microM) stimulated the synthesis of prostacyclin (PGI2), as reflected by the release of 6-keto-prostaglandin F1 alpha (6-K-PGF1 alpha), in endothelial cells cultured from bovine aorta. This effect of ADP was mimicked by ATP, whereas AMP and adenosine were completely inactive. The release of 6-K-PGF1 alpha triggered by ADP was rapid and onset (within 5 min), transient (10 min) and followed by a period of refractoriness to a new ADP challenge. Growing and confluent cells were equally responsive to ADP. ADP stimulated the release of free arachidonic acid from the endothelial cells. ADP could thus exert two opposite actions on platelet aggregation in vivo: a direct stimulation and an inhibition mediated by PGI2. This last action might contribute to limit thrombus formation to areas of endothelial cell damage.     

The platelet cyclooxygenase metabolite 12-L-hydroxy-5, 8, 10-hepta-decatrienoic acid (HHT) may modulate primary hemostasis by stimulating prostacyclin production

Although HHT accounts for approximately one third of the arachidonic acid (AA) metabolites produced by stimulated platelets, no well defined function has been attributed to this product. We report that HHT stimulates prostacyclin production by endothelial cells, and have identified the mechanism for this effect. In human umbilical venous endothelial cells, HHT (0.5 and 1 microM) stimulated prostacyclin (RIA for 6KPGF1 alpha) by 32 +/- 22% (1SD) and 42 +/- 38% (P less than 0.05 and less than 0.01). Similar changes were observed when the effect of HHT on exogenous [1-14C] AA metabolism in fetal bovine aortic endothelial cells (FBAECs) was studied. Kinetic analyses revealed that HHT affected vascular cyclooxygenase. HHT (1 microM) increased Vmax in test microsomes (706 +/- 21 pmol/mg/min, mean +/- 1SE) when compared to controls (529 +/- 20; P less than 0.02). No concomitant effect on Km was observed. A further effect of HHT on AA release from endothelial cell membrane phospholipids was noted. Prelabeling experiments revealed that HHT (1 microM) increased the ionophore stimulated release of AA from FBAECs (20952 +/- 555 cpm/well control mean +/- 1SE vs 25848 +/- 557 for paired HHT treated cells; P less than 0.05). The effect of HHT on platelet AA metabolism was next studied. Preincubation of washed platelets with HHT (1 microM) did not enhance thrombin or arachidonic acid induced platelet TXB2 formation. In platelets prelabelled with [1-14C]AA, HHT (1 microM) had no effect on AA release post thrombin stimulation. Conversion to cyclooxygenase metabolites was also not enhanced. HHT stimulates vascular prostacyclin without a concomitant effect on platelet AA metabolism. HHT may thus be an important local modulator of platelet plug formation.     

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.     

Kallikrein activates bradykinin B2 receptors in absence of kininogen

Kallikreins cleave plasma kininogens to release the bioactive peptides bradykinin (BK) or kallidin (Lys-BK). These peptides then activate widely disseminated B2 receptors with consequences that may be either noxious or beneficial. We used cultured cells to show that kallikrein can bypass kinin release to activate BK B2 receptors directly. To exclude intermediate kinin release or kininogen uptake from the cultured medium, we cultured and maintained cells in medium entirely free of animal proteins. We compared the responses of stably transfected Chinese hamster ovary (CHO) cells that express human B2 receptors (CHO B2) and cells that coexpress angiotensin I-converting enzyme (ACE) as well (CHO AB). We found that BK (1 nM or more) and tissue kallikrein (1-10 nM) both significantly increased release of arachidonic acid beyond unstimulated baseline level. An enzyme-linked immunoassay for kinin established that kallikrein did not release a kinin from CHO cells. We confirmed the absence of kininogen mRNA with RT-PCR to rule out kininogen synthesis by CHO cells. We next tested an ACE inhibitor for enhanced BK receptor activation in the absence of kinin release and synthesized an ACE-resistant BK analog as a control for these experiments. Enalaprilat (1 microM) potentiated kallikrein (100 nM) in CHO AB cells but was ineffective in CHO B2 cells that do not bear ACE. We concluded that kallikrein activated B2 receptors without releasing a kinin. Furthermore, inhibition of ACE enhanced the receptor activation by kallikrein, an action that may contribute to the manifold therapeutic effects of ACE inhibitors.     

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.     

Effects of lysolecithin on aggregation of human platelets induced by arachidonic acid and A23187 role of prostaglandin intermediary metabolism.

Lysolecithin at non-cytotoxic concentrations (30–500 uM) was found capable of completely inhibiting the $\text{aggregation of human platelets}$ induced by arachidonic acid in the absence of any effect upon total platelet production of malondialdehyde, an end-product of platelet $\text{prostaglandin intermediary metabolism}$, and to inhibit platelet aggregation stimulated by the calcium ionophore, A23187. As the induction of platelet aggregation by arachidonic acid is dependent upon an intact prostaglandin biosynthetic pathway while that of A23187 is not and since lysolecithin-induced inhibition of arachidonic acid-stimulated platelet aggregation was evident in the absence of an effect upon platelet malondialdehyde production, it is suggested that lysolecithin inhibits the platelet release reaction and irreversible aggregation by a mechanism separable from a major affect upon prostaglandin intermediary metabolism.     

Neuropeptide Y stimulates prostacyclin production in porcine vascular endothelial cells

We investigated the effects of neuropeptide Y on the prostacyclin production of cultured porcine aortic endothelial cells by measuring the stable metabolite of prostacyclin, 6-keto-prostaglandin F1 alpha, by radioimmunoassay. Neuropeptide Y induced dose- and time-dependent stimulation of prostacyclin production by cultured porcine aortic endothelial cells. The lowest stimulatory concentration of neuropeptide Y was 10(-8) M and maximal response, a 2.8 fold rise, was obtained with 10(-6) M. The stimulation lasted at least 24 h. The effect was associated with the stimulation of arachidonic acid release. Our data suggest that neuropeptide Y may inhibit the development of atherosclerosis by stimulating prostacyclin synthesis.     

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.     

Differential effects of aspirin and dexamethasone on phospholipase A2 and C activities and arachidonic acid release from endothelial cells in response to bradykinin and leukotriene D4

The CPAE bovine endothelial cell line may be stimulated to produce eicosanoids. Leukotriene D4 increased the release of arachidonic acid primarily by activating phospholipase A2 while bradykinin activated the phospholipase C pathway. Cells pretreated with dexamethasone, a phospholipase A2 inhibitor, no longer responded to stimulation by LTD4 but did release arachidonic acid when treated with bradykinin. Aspirin blocked bradykinin-stimulated production of arachidonic acid but left the response to LTD4 unaffected. We conclude that these cells produce eicosanoids by activation of both PLA2 and PLC, and that the two different methods of arachidonic acid release can be distinguished by using the common anti-inflammatory drugs aspirin and dexamethasone.     

Physiological concentrations of ADP stimulate the release of prostacyclin from bovine aortic endothelial cells

ADP (0.2−200 μN) stimulated the synthesis of prostacyclin (PGI₂), as reflected by the release of 6-keto-prostaglandin F_1α (6-K-PGF_1α), in endothelial cells cultured from bovine orta. This effect of ADP was mimicked by ATP, whereas AMP and adenosine were completely inactive. The release of 6-K-PGF_1α triggered by ADP was rapid in onset (within 5 min), transient (10 min) and followed by a period of refractoriness to a new ADP challenge. Growing and confluent cells were equally responsive to ADP. ADP stimulated the release of free arachidonic acid from the endothelial cells. ADP could be thus exert two opposite actions on platelet aggregation in vivo: a direct stimulation and an inhibition mediated by PGI₂. This last action might contribute to limit thrombus formation to areas of endothelial cell damage.     

Arachidonic acid strongly stimulates prostaglandin I3 (PGI3) production from eicosapentaenoic acid in human endothelial cells

Eicosapentaenoic acid (EPA) is a prominent polyunsaturated fatty acid in fish oil which inhibits blood platelet aggregation and thromboxane A2 formation but not prostacyclin-like material generation from vascular endothelium. In this study we investigated interaction between EPA and arachidonic acid (AA) during their oxygenation by cultured endothelial cells. As measured by gas chromatography-mass spectrometry (GC-MS), AA increased markedly prostaglandin I3 (PGI3) production from EPA while that of PGI2 from AA was decreased by EPA. However, increasing the ratio AA/EPA over one almost suppressed the inhibition of PGI2 formation by EPA, and the stimulation of PGI3 production by AA was even higher. The effect of AA on EPA conversion to minor prostaglandins like PGE3 and PGF3 alpha was similar then confirming the stimulating effect and suggesting it is occurring at the cyclooxygenase instead of the prostacyclin synthase level. Altogether these data indicate that, in certain nutritional states where the liberation of EPA from endothelial cells will be accompanied with that of endogenous AA, substantial amounts of PGI3 could contribute to the prostacyclin-like activity of the vessel wall in addition to PGI2.     

Effects of bivalent cations on prostaglandin biosynthesis and phospholipase A2 activation in rabbit kidney medulla slices.

The bivalent cations Ca2+, Mg2+, Co2+, Mn2+, Sr2+ and Ba2+ were compared for their stimulatory or inhibitory effect on prostaglandin formation in rabbit kidney medulla slices. Ca2+, Mn2+ and Sr2+ ions stimulated prostaglandin generation up to 3--5-fold in a time- and dose-dependent manner (Ca2+ greater than Mn2+ congruent to Sr2+). The stimulation by Mn2+ (but not by Sr2+) was also observed in incubations of medulla slices in the presence of Ca2+. Mg2+ and Co2+ ions were without significant effects on either basal or Ca2+-stimulated prostaglandin synthesis. The stimulatory effects of Ca2+, Mn2+ and Sr2+ on medullary generation of prostaglandin E2 were found to correlate with their stimulatory effects on the release of arachidonic acid and linoleic acid from tissue lipids. The release of other fatty acids was unaffected, except for a small increase in oleic acid release. As both arachidonic acid and linoleic acid are predominantly found in the 2-position of the glycerol moiety of phospholipids, the stimulation by these cations of prostaglandin E2 formation appears to be mediated via stimulation of phospholipase A2 activity.     

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.     

Human platelet secreted proteins and prostacyclin production by bovine aortic endothelial cells

The effects of specific human platelet-secreted proteins on prostacyclin (PGI2) production by primary cultures of bovine aortic endothelial cells have been studied. Cells were incubated with various concentrations of highly purified preparations of platelet factor 4 (PF4), low-affinity platelet factor 4 (LA-PF4), beta-thromboglobulin (beta TG), platelet basic protein (PBP), and partially purified platelet-derived growth factor (PDGF) in the presence or absence of arachidonic acid (AA). The amount of 6-Keto-PGF1 alpha, the stable degradation product of PGI2, was determined in the cell incubation medium by means of a specific radioimmunoassay. Short-term (15 min) incubation of cell monolayers with either LA-PF4 or beta TG slightly reduced 6-keto-PGF1 alpha production. The effect was not dose-related and could not be observed after prolonged (24 hr) incubation of the cells with the same proteins. It was not seen in the cell suspensions. Moreover, 6-keto-PGF1 alpha production stimulated by AA was not affected by incubation with either of the proteins. PF4 and PBP had no significant effect on 6-keto-PGF1 alpha production by endothelial cells. Human PDGF showed a slight tendency to stimulate 6-keto-PGF1 alpha release when cells were incubated for 24 hr with the protein; however, PDGF did not potentiate the stimulatory effect of AA on 6-keto-PGF1 alpha release by the cells. We suggest that platelet-derived proteins exert only a moderate and possibly nonspecific effect on PGI2 production by endothelial cells.     

Eicosapentaenoic acid and prostacyclin production by cultured human endothelial cells

Human umbilical vein endothelial cells incorporate eicosapentaenoic acid (EPA) when this fatty acid is present in the culture medium. From 30 to 70% of the uptake remains as EPA, and much of the remainder is elongated to docosapentaenoic acid. All of the cellular glycerophospholipids become enriched with EPA and docosapentaenoic acid, with the largest increase in EPA occurring in the choline glycerophospholipids. When this fraction is enriched with EPA, it exhibits a large decrease in arachidonic acid content. Cultures exposed to tracer amounts of [1-14C]linolenic acid in 5% fetal bovine serum convert as much as 17% of the radioactivity to EPA. The conversion is reduced, however, in the presence of either 20% fetal bovine serum or 50 microM linolenic acid. Like arachidonic acid, some newly incorporated EPA was released from the endothelial cells when the cultures were exposed to thrombin. However, as compared with arachidonic acid, only very small amounts of EPA were converted to prostaglandins. Cultures enriched with EPA exhibited a 50 to 90% reduction in capacity to release prostacyclin (PGI2) when subsequently stimulated with thrombin, calcium ionophore A23187, or arachidonic acid. The degree of inhibition was dependent on the time of exposure to EPA and the EPA concentration, and it was not prevented by adding a reversible cyclooxygenase inhibitor, ibuprofen, during EPA supplementation. EPA appears to decrease the capacity of the endothelial cells to produce PGI2 in two ways: by reducing the arachidonic acid content of the cell phospholipid precursor pools and by acting as an inhibitor of prostaglandin production. These findings suggest that regimens designed to reduce platelet aggregation and thrombosis by EPA enrichment may also reduce the capacity of the endothelium to produce PGI2.     

Enrichment of human platelet phospholipids with linoleic acid diminishes thromboxane release

We have investigated whether exposure of human platelets to elevated concentrations of linoleic acid, the principal dietary polyunsaturate, would influence platelet thromboxane A₂ release. Platelets were incubated with albumin-bound linoleic acid at 30°C for 24 h, with prostaglandin E₁ added to prevent aggregation. The linoleic acid supplemented platelets released, on averaged, 50% less thromboxane A₂ in response to stimulation with thrombin than corresponding control platelets. Other fatty acids were without appreciable effect. The inhibition of thrombin-stimulated thromboxane A₂ release was dependent on the time and temperature of incubation, as well as on the concentration of added linoleic acid. Supplementation increased the amount of linoleic acid in the platelet phospholipids, but the arachidonic acid content of the phospholipids was reduced. [1-¹⁴C]Linoleic acid was not converted to arachidonic acid by the platelets. Linoleic acid was released exclusively form the inositol phosphoglycerides when the enriched platelets were stimulated with thrombin. The linoleate-enriched platelets converted less [1-¹⁴C]arachidonic acid to all prostaglandin products, suggesting that the platelet cyclooxygenase was partially inhibited.     

Prostaglandin production by the pregnant and non-pregnant rabbit uterus

We have studied the prostaglandin synthesis of the pregnant and non-pregnant rabbit uterus in a microsomal membrane preparation, and in an ex vivo perfused uterus preparation which retains agonist stimulated prostaglandin production. In both the microsomal and isolated perfused system, prostacyclin was the major arachidonic acid metabolite produced; PGE2 was also produced in substantial quantities while TxB2 and PGF2 alpha were not detectable. Moreover, oxytocin was a specific stimulus of PGE2 release. The steroid hormone milieu influenced the level of agonist stimulated prostaglandin release; in general, ovariectomized, estrogen treated animals were more responsive to agonist stimulation than those treated with estrogen followed by progesterone. The microsomal studies indicated that the pregnant animal had a greatly enhanced capacity to metabolize arachidonic acid when compared with the non-pregnant animal. However, this was not reflected in the ability of agonists to stimulate prostaglandin release in the ex vivo perfused preparation.     

Differential effects of aspirin and dexamethasone on phospolipase A2 and C activities and arachidonic acid release from endothelial cells in respose to bradykinin and leukotriene D4

The CPAE bovine endothelial cell line may be stimulated to produce eicosanoids. Leukotriene D₄ increased the release of arachidonic acid primarily by activating phospholipase A₂ while bradykinin activated the phospholipase C pathway. Cells pretreated with dexamethasone, a phospholipase A₂ inhibitor, no longer responded to stimulation by LTD₄ but did release arachidonic acid when treated with bradykinin. Aspirin blocked bradykinin-stimulated production of arachidonic acid but left the response to LTD₄ unaffected. We conclude that these cells produce eicosanoids by activation of both PLA₂ and PLC, and that the two different methods of arachidonic acid release can be distinguished by using the common anti-inflammatory drugs aspirin and dexamethasone.