Increased pulmonary vascular resistance and permeability due to arachidonate metabolism in isolated rabbit lungs

Liberation and metabolism of arachidonic acid may be the common final pathway of different stimuli on the pulmonary vascular bed. In a model of isolated, ventilated rabbit lungs, perfused with Krebs Henseleit albumin buffer in a recirculating system, changes of pulmonary vascular resistance and of vascular permeability are monitored continuously. The addition of free arachidonic acid or of the Ca-ionophore A 23187 to the perfusion fluid consistently evokes a biphasic increase in vascular resistance as well as an initially reversible increase in vascular permeability, followed by pulmonary edema. Both phases of increased vascular resistance are completely suppressed by inhibition of the cyclooxygenase, decreased to a large degree by inhibitors of thromboxane synthetase, and markedly augmented by short preincubation of arachidonic acid with ram seminal vesicular microsomes and by sulfhydryl reagents. The increased pulmonary vascular permeability is augmented by inhibition of cyclooxygenase and reduced by simultaneous lipoxygenase inhibition. Antagonists of histamine, serotonin and sympathic or parasympathic activity do not have any influence. PG F2alpha., TxB2, PG E2 and PG I2 alter the pulmonary vascular resistance, but do not increase vascular permeability. In conclusion, increased availability of free arachidonic acid evokes a rise in pulmonary vascular resistance, which can be ascribed to cyclooxygenase products, especially to thromboxane, and causes a rise in vascular permeability which can be ascribed to lipoxygenase products. The findings may be related to acute pulmonary lesions with increase in vascular resistance and with vascular leakage.     

Increased pulmonary vascular resistance and permebility due to arachidonate metabolism in isolated rabbit lungs

Liberation and metabolism of arachidonic acid may be the common final pathway of different stimuli on the pulmunary vascular bed. In a model of isolated, ventilated rabbit lungs, perfused with krebs Henseleit albumin buffer in a recirculating system, changes of pulmonary vascular resistance and of vascular permeability are monitored continously. The addition of free arachidonic acid or of the Ca-ionophore A 23187 to the perfusion fluid consistently evokes a biphasic increases in vascular resistance as well as an initially reversible increase in vascular permeability, followed by pulmonary edema. Both phases of increased vascular resistance are completely suppressed by inhibition of the cyclooxygenase, decreased to a large degree by inhibitors of thromnoxane synthetase, and markedly augmented by short preincubation of arachidonic acid with ram seminal vescular microsomes and by sulfhydryl reagents. The increased pulmonary vascular permeability is augmented by inhibition of cyclooxygenase and reduced by simulteneous lipoxygenase inhibition. Antagonists of histamine, serotonin and sympathic or parasympathic activity do not have any influence.PG F_2α, TxB E₂ and PG I₂ alter the pulmonary vascular resistance, but do not increase vascular permeability.In inclusion, increased availability of free arachidonic acid evokes a rise in pulmonary vascular resistance, which can be ascribed to cyclooxygenase products, especially to thromboxane, and causes a rise in vascular permeability which can be ascribed to lipoxygenase products.The findings may be related to acute pulmonary lesions with increase in vascular resistance and with vascular leakage.     

Endotoxin-induced lung injury in rats: role of eicosanoids

We studied lung vascular injury and quantitated lung eicosanoids in rats after intraperitoneal injection of Salmonella enteritidis endotoxin. Within 40 min after endotoxin injection (20 mg/kg), lung tissue thromboxane B2 doubled, although 6-ketoprostaglandin F1 alpha (6-keto-PGF1 alpha) increased by 8- to 10-fold. Lung 5-hydroxyeicosatetraenoic acid and leukotriene C4 were variably increased by endotoxin. The levels of all eicosanoids returned to base line 6 h after endotoxin challenge. Lung vascular injury, as assessed by the extravascular accumulation of 125I-albumin and water in isolated perfused lungs, was observed 90 min after endotoxin injection (0.02-20 mg/kg) in vivo. Inhibition of the cyclooxygenase pathway with indomethacin and the lipoxygenase pathway with diethylcarbamazine and 2-(12-hydroxydodeca-5,10-dinyl)-3,5,6-trimethyl-1,4-benzoqui none failed to attenuate endotoxin-induced lung injury. In addition, essential fatty acid deficiency, which markedly reduced lung tissue levels of 6-keto-PGF1 alpha, thromboxane B2, and leukotriene C4, did not protect against endotoxin injury. We conclude that although lung eicosanoids are activated during endotoxemia, they do not play a crucial role in the development of acute lung vascular injury in rats.     

A formyl peptide contracts guinea pig lung: role of arachidonic acid metabolites

We studied the role of cyclooxygenase and lipoxygenase products of arachidonic acid metabolism in mediating N-formyl-methionyl-leucyl-phenylalanine- (FMLP) induced contractions of guinea pig lung parenchymal strips. The cyclooxygenase inhibitors indomethacin (10(-5) M) and aspirin (3 X 10(-5) to 10(-4) M), the lipoxygenase inhibitor nordihydroguaiaretic acid (10(-5) to 3 X 10(-5) M), and the combined cyclooxygenase/lipoxygenase inhibitors 1-phenyl-3-pyrazolidinone (Phenidone) (3 X 10(-5) to 3 X 10(-4) M) and BW 755C (10(-5) to 10(-4) M) each caused a decrease in the maximum force induced by FMLP (Fmax) and an increase in the concentration of FMLP required to produce 50% of Fmax (EC50). The thromboxane synthesis inhibitor imidazole (3 X 10(-3) M) also decreased Fmax. The leukotriene D4 receptor antagonist FPL 55712 (5.7 X 10(-6) to 1.9 X 10(-5) M) increased the EC50 for FMLP, whereas desensitization of lung parenchymal strips to leukotriene B4 by pretreatment with this leukotriene (10(-7) M) had no effect on FMLP-induced contraction. After exposure to FMLP (10(-6) M), guinea pig lung produced (as determined by high-performance liquid chromatography and radioimmunoassay) leukotrienes C4 and B4, thromboxane A2 (as measured by its stable degradation product thromboxane B2), and prostaglandin F2 alpha. Lung strips not exposed to FMLP showed no evidence of leukotriene production. We conclude that thromboxane A2 and leukotriene C4 generated in response to FMLP mediate a substantial fraction of the force induced by this peptide in guinea pig lung parenchymal strips.     

Edema from cyclooxygenase products of endogenous arachidonic acid in isolated lung

We infused A23187, a calcium ionophore, into the pulmonary circulation of dextran-salt-perfused isolated rabbit lungs to release endogenous arachidonic acid. This led to elevations in pulmonary arterial pressure and to pulmonary edema as measured by extravascular wet-to-dry weight ratios. The increase in pressure and edema was prevented by indomethacin, a cyclooxygenase enzyme inhibitor, and by 1-benzylimidazole, a selective inhibitor of thromboxane (Tx) A2 synthesis. Transvascular flux of 125I-albumin from vascular to extravascular spaces of the lung was not elevated by A23187 but was elevated by infusion of oleic acid, an agent known to produce permeability pulmonary edema. We confirmed that A23187 leads to elevations in cyclooxygenase products and that indomethacin and 1-benzylimidazole inhibit synthesis of all cyclooxygenase products and TxA2, respectively, by measuring perfusate levels of prostaglandin (PG) I2 as 6-ketoprostaglandin F1 alpha, PGE2, and PGF2 alpha and TxA2 as TxB2. We conclude that release of endogenous pulmonary arachidonic acid can lead to pulmonary edema from conversion of such arachidonic acid to cyclooxygenase products, most notably TxA2. This edema was most likely from a net hydrostatic accumulation of extravascular lung water with an unchanged permeability of the vascular space, since an index of permeability-surface area product (i.e., transvascular albumin flux) was not increased.     

Mechanisms of pulmonary vasoconstriction induced by chemotactic peptide FMLP in isolated rabbit lungs.

The chemotactic peptide N-formyl-methionyl-leucyl-phenylalanine (FMLP) has been shown to constrict both bronchial and coronary vascular smooth muscle through the action of cyclooxygenase or lipoxygenase products. We observed that intravenous FMLP increased pulmonary vascular resistance (PVR) in isolated buffer-perfused rabbit lungs. FMLP increased the PVR (primarily in the middle segment of the pulmonary vascular bed) at concentrations greater than or equal to 10(-7) M. Maximum vasoconstriction occurred at 5 min and then slowly declined to a level that remained above baseline at 30 min. Tachyphylaxis was observed in response to FMLP. When polymorphonuclear leukocytes (PMNs) were added to the perfusate, FMLP caused a greater increase in PVR. PMN depletion with dimethylmyleran significantly reduced the PVR response to FMLP. Pretreatment with two dissimilar cyclooxygenase inhibitors, meclofenamate and ibuprofen, and the leukotriene synthesis blocker MK 886 had no effect on the FMLP-induced vasoconstriction. However, the reactive oxygen species scavenger catalase significantly reduced the vasoconstriction. These results suggest that FMLP induces vasoconstriction that is dependent on PMNs and mediated by reactive oxygen species with no involvement of cyclooxygenase or lipoxygenase products.     

Thromboxane-induced pulmonary vasoconstriction: involvement of calcium

Infusion of tert-butyl hydroperoxide (t-bu-OOH) or arachidonic acid into rabbit pulmonary arteries stimulated thromboxane B2 (TxB2) production and caused pulmonary vasoconstriction. Both phenomena were blocked by cyclooxygenase inhibitors or a thromboxane synthase inhibitor. The increase in pulmonary arterial pressure caused by either t-bu-OOH or arachidonic acid infusion correlated with the concentration of TxB2 in the effluent perfusate. The concentration of TxB2 in the effluent perfusate, however, was always 10-fold greater after arachidonic acid infusion. In the rabbit pulmonary vascular bed lipoxygenase products did not appear involved in the vasoactive response to t-bu-OOH or exogenous arachidonic acid infusion. Calcium entry blockers or a calcium-free perfusate prevented the thromboxane-induced pulmonary vasoconstriction. Calmodulin inhibitors also blocked the pulmonary vasoconstriction induced by t-bu-OOH without affecting the production of TxB2 or prostacyclin. These results suggest that thromboxane causes pulmonary vasoconstriction by increasing cytosol calcium concentration.     

Leukotriene F4 and the release of arachidonic acid metabolites from perfused guinea pig lungs in vitro

Radioimmunoassay and bioassay techniques have been used to investigate the ability of leukotriene (LT)F4 to release products of arachidonic acid metabolism from guinea pig isolated lungs perfused via the pulmonary artery. Also, the abilities of LTC4, LTD4, LTE4 and LTF4 to contract guinea pig ileal smooth muscle (GPISM) was studied. Each of the LT's contracted GPISM. The rank order of potency was LTD4 greater than LTC4 greater than LTE4 much greater than LTF4 in a ratio of 1:7:170:280 respectively. Bioassay of pulmonary effluents indicated the passage of LTF4 through the lungs caused a contraction of rabbit aorta as well as an FPL-55712 sensitive contraction of GPISM. The contractions of rabbit aorta were inhibited by pretreatment of the lungs with Indomethacin but not with the thromboxane synthetase inhibitor Dazoxiben. Radioimmunoassay of the lung effluents indicated LTF4 to cause a 70-fold increase in thromboxane B2 (TXB2), 4-fold increase in prostaglandin (PG)E2 and a 16-fold increase in 6-keto PGF1 alpha levels. The LTF4-induced increments of these immunoreactive metabolites was inhibited by pretreatment of the lungs with Indomethacin. Pretreatment of lungs with Dazoxiben inhibited the LTF4-induced increment in TXB2 and enhanced the effluent levels of PGE2 24-fold (compared with untreated lungs). There were no detectable differences in either immunoreactive LTC4 or immunoreactive LTB4 levels. It is concluded LTF4 is a relatively weak agonist on GPISM and can induce the release of cyclooxygenase products of arachidonic acid metabolism from guinea pig perfused lung.     

Pulmonary hypertensive response to foreign body microemboli

Pulmonary hypertension and foreign body granulomas are recognized sequelae of chronic intravenous drug abuse. We have recently described the development of transient pulmonary hypertension and increased permeability pulmonary edema after the intravenous injection of crushed, suspended pentazocine tablets in both humans and dogs. To determine the role of vasoactive substances in the development of this transient pulmonary hypertension, we measured pulmonary hemodynamics and accumulation of arachidonic acid metabolites in dogs during the infusion of indomethacin, a cyclooxygenase inhibitor, diethylcarbamazine (DEC), a lipoxygenase inhibitor, and FPL 55712, a receptor antagonist for leukotriene C4/D4 (LTC4/D4). Following the intravenous administration of crushed, suspended pentazocine tablets (3-4 mg/kg of body weight), mean pulmonary artery pressure increased from 14 +/- 2 mmHg to 30 +/- 6 mmHg (p less than 0.05) at 60 secs with a concomitant increase in plasma concentrations of 6-keto-PGF1 alpha from 187 +/- 92 pg/ml to 732 +/- 104 pg/ml and thromboxane B2 from 206 +/- 83 pg/ml to 1362 +/- 117 pg/ml (both p less than 0.05). Indomethacin prevented the increase in both cyclooxygenase metabolites, but had no effect on the pulmonary hypertension. In contrast, DEC had no effect on the increase in cyclooxygenase products, but blocked the pulmonary hypertension. FPL 55712 did not effect either the increase in cyclooxygenase metabolites or the pulmonary hypertension. We conclude that the transient pulmonary hypertension, induced by the intravenous injection of crushed, suspended pentazocine tablets, is not mediated by cyclooxygenase products but may be mediated by lipoxygenase product(s) other than LTC4/D4.     

Determination of leukotriene B4, 6-keto-prostaglandin F1 alpha and thromboxane B2 in peritoneal lavage fluid of sham-operated and adrenalectomized rats

In macrophages, isolated from the peritoneal fluid of rats, after activation, formation of metabolites of arachidonic acid occurs both by the cyclooxygenase and lipoxygenase pathways. The cells of normal animals produce mainly cyclooxygenase products. After adrenalectomy, a considerable increase occurs in the formation of lipoxygenase products, and less in those of the cyclooxygenase (1). In the experiments described here, the effect of adrenalectomy on the presence of leukotriene B4 (LTB4), 6-keto-PGF1 alpha and thromboxane B2 (TxB2) in the peritoneal fluid is determined.     

PAF potentiates protamine-induced lung edema: role of pulmonary venoconstriction

We studied the synergistic interaction between platelet-activating factor (PAF) and protamine sulfate, a cationic protein that causes pulmonary endothelial injury, in isolated rat lungs perfused with a physiological salt solution. A low dose of protamine (50 micrograms/ml) increased pulmonary artery perfusion pressure (Ppa) but did not increase wet lung-to-body weight ratio after 20 min. Pretreatment of the lungs with a noninjurious dose of PAF (1.6 nM) 10 min before protamine markedly potentiated protamine-induced pulmonary vasoconstriction and resulted in severe lung edema and increased lung tissue content of 6-keto-prostaglandin F1 alpha, thromboxane B2, and leukotriene C4. Pulmonary microvascular pressure (Pmv), measured by double occlusion, was markedly increased in lungs given PAF and protamine. These potentiating effects of PAF were blocked by WEB 2086 (10(-5) M), a specific PAF receptor antagonist. Pretreatment of the lungs with a high dose of histamine (10(-4) M) failed to enhance the effect of protamine on Ppa, Pmv, or wet lung-to-body weight ratio. Furthermore, PAF pretreatment enhanced elastase-, but not H2O2-, induced lung edema. To assess the role of hydrostatic pressure in edema formation, we compared lung permeability-surface area products (PS) in papaverine-treated lungs given either protamine alone or PAF + protamine and tested the effect of mechanical elevation of Pmv on protamine-induced lung edema. In the absence of vasoconstriction, PAF did not potentiate protamine-induced increase in lung PS. On the other hand, mechanically raising Pmv in protamine-treated lungs to a level similar to that measured in lungs given PAF + protamine did not result in a comparable degree of lung edema. We conclude that PAF potentiates protamine-induced lung edema predominantly by enhanced pulmonary venoconstriction. However, a pressure-independent effect of PAF on lung vasculature cannot be entirely excluded.     

Increase in the formation of leukotriene B4 and other lipoxygenase products in peritoneal macrophages of adrenalectomized rats

The effect of adrenalectomy on the formation of cyclooxygenase and lipoxygenase products by activated peritoneal rat macrophages was determined. After isolation, the cells were incubated with [1-14C]arachidonic acid and the calcium ionophore A23187 and the metabolites isolated by HPLC chromatography. The main components formed in the controls are 6-keto-prostaglandin F1 alpha, thromboxane B2 and 12-HETE. One peak represents 5,12-di-HETE. Smaller amounts of prostaglandin F2 alpha, prostaglandin E2, prostaglandin D2, leukotriene B4 and 15-HETE are also present. After adrenalectomy, a considerable increase occurs in the amounts of leukotriene B4, 15-HETE and 12-HETE. The increase in the prostaglandins is smaller. The compounds formed from endogenous arachidonic acid are also determined. In the cells of the controls, 6-keto-prostaglandin F1 alpha and thromboxane B2 are produced in higher amounts than leukotriene B4. After adrenalectomy, the formation of leukotriene B4 is much more increased than that of 6-keto-prostaglandin F1 alpha. These effects are most probably related to a diminished amount or inactivation of lipocortin, a glucocorticosteroid-induced peptide with phospholipase A2 inhibitory activity in adrenalectomized animals.     

Platelet lipoxygenase-dependent oxygen burst. Evidence for differential activation of lipoxygenase in intact and disrupted human platelets

The metabolism of arachidonic acid in platelets by both cyclooxygenase and lipoxygenase involves the rapid consumption of molecular oxygen. However, selective inhibition of cyclooxygenase completely abolishes the arachidonate-induced oxygen burst in intact platelets. This is in contrast to platelet lysates, in which approximately 50% of the arachidonate-induced oxygen burst remains detectable following inhibition of cyclooxygenase with acetylsalicylic acid. This lipoxygenase oxygen burst is blocked by preincubation of the platelets with ETYA, which inhibits both cyclooxygenase and lipoxygenase. In cell-free 100000 x g supernatants of platelet lysates, which contain only lipoxygenase activity, arachidonate induces an oxygen burst which is not blunted by preincubation with aspirin but is completely abolished by preincubation with ETYA. The finding of a lipoxygenase-dependent oxygen burst in platelet lysates but not in intact platelet suspensions suggests differential activation or differential availability of platelet lipoxygenase in intact and disrupted platelets. This was confirmed by a 5 min lag in the generation of [14C]HETE (the major lipoxygenase product) from [14C]arachidonic acid in intact platelets, but an almost immediate initiation of [14C]HETE production in platelet lysates. In contrast, the synthesis of [14C]thromboxane B2 (the major cyclooxygenase product) from [14C]arachidonic acid began immediately in both intact and disrupted platelet preparations and peaked within 5 min. These observations provide new insight into factors controlling platelet hydroxy acid production and help to explain the nature of the platelet oxygen burst.     

Thromboxane increase in irradiated animals is caused by stimulation of cyclooxygenase activity.

The irradiation of whole body of rabbits with a dose of 6.0 Gy causes an increase in thromboxane synthesis from exogenous arachidonic acid. The uptake of [14C]arachidonic acid and the total amount of radioactivity released during collagen stimulated aggregation of platelets are not changed following the exposure of animals. The irradiation changes the relation between released arachidonic acid and synthesized thromboxane. The amount of 12-hydroxyeicosatetraenoic acid remains unchanged. The results indicate that the increase in thromboxane synthesis is not associated with the activation of phospholipase but is caused by stimulation of cyclooxygenase activity.     

Hemodynamic effects of oleic acid in newborn lambs: role of arachidonic acid metabolites.

Oleic acid injection produces acute lung injury and pulmonary hypertension in adult animals. In other types of acute lung injury, such as that caused by E. coli endotoxin, metabolites of arachidonic acid are important mediators of pulmonary hypertension. In order to understand the hemodynamic response of newborn animals to oleic acid injection and the contribution of arachidonic acid metabolites to that response, we injected oleic acid into awake, chronically instrumented newborn lambs. The hemodynamic response of lambs to injections of oleic acid alone was compared to their response after pretreatment with either FPL57231, a putative leukotriene receptor antagonist, or indomethacin, a cyclooxygenase synthesis inhibitor. Oleic acid caused acute pulmonary hypertension associated with an increase in protein-rich lung lymph fluid. Systemic hemodynamic effects were variable. FPL57231 completely blocked the oleic acid-induced pulmonary hypertension while indomethacin significantly attenuated the response. Therefore, metabolites of arachidonic acid metabolism appear to be important mediators of oleic acid-induced pulmonary hypertension in newborn lambs.     

Pulmonary microvascular responses to arachidonic acid in isolated perfused guinea pig lung

We examined the effects of arachidonic acid (AA) on pulmonary hemodynamics and fluid balance in Ringer- and blood-perfused guinea pig lungs during constant-flow conditions. Mean pulmonary arterial (Ppa), venous (Pv), and capillary pressures (Pcap, estimated by the double-occlusion method) were measured, and arterial (Ra) and venous resistances (Rv) were calculated. Bolus AA injection (500 micrograms) caused transient increases (peak response 1 min post-AA) in Ppa, Pcap, and Rv without affecting Ra in both Ringer- and blood-perfused lungs. The response was sustained in blood-perfused lungs. AA had no effect on the capillary filtration coefficient in either Ringer- or blood-perfused lungs. AA stimulated the release of thromboxane B2 and 6-ketoprostaglandin F1 alpha in both Ringer- and blood-perfused lungs, but the responses were sustained only in the blood-perfused lungs. Meclofenamate (1.5 X 10(-4) M), a cyclooxygenase inhibitor, abolished the AA-induced pulmonary hemodynamic responses in both Ringer- and blood-perfused lungs, whereas U-60257 (10 microM), a lipoxygenase inhibitor, attenuated the response only in the blood-perfused lungs. In conclusion, AA does not alter pulmonary vascular permeability to water in either Ringer- or blood-perfused lungs. AA mediates pulmonary venoconstriction and thus contributes to the rise in Pcap. The venoconstriction results from the generation of cyclooxygenase-derived metabolites from lung parenchymal cells and blood-formed elements. Lipoxygenase metabolites may also contribute to the vasoconstriction in the blood-perfused lungs.     

Hydroperoxide-induced chemiluminescence in rabbit lungs: role of arachidonic acid enzymes

Low-level chemiluminescence (C) is thought to be an index of oxidant stress. We measured the relationship between low-level C, pulmonary arterial pressure, and perfusate concentration of thromboxane B2 (TxB2) in isolated perfused rabbit lungs during challenge with tert-butyl hydroperoxide (t-bu-OOH). We also measured glutathione release as another index of oxidant stress. We found that C was correlated with each variable, suggesting that oxidant stress measured by C and by glutathione release stimulated TxB2 production and pulmonary vasoconstriction. We also investigated the contribution of active O2 metabolites produced by prostaglandin (PG) peroxidase to oxidant stress by studying the effects of t-bu-OOH before and after the use of cyclooxygenase and lipoxygenase inhibitors. We found that C was augmented after inhibition, perhaps due to metabolism of t-bu-OOH by peroxidases of both arachidonic acid (AA) metabolic pathways in the absence of their normal substrates. We studied phenylbutazone, thought to inhibit peroxidases, and AA. C during t-bu-OOH administration was not augmented after phenylbutazone and was markedly inhibited after AA administration perhaps because AA competes with t-bu-OOH. To further study the role of peroxidases we pretreated the lungs with the antioxidant dithiothreitol, which inhibits peroxidases involved in both the cyclooxygenase and lipoxygenase pathways. Dithiothreitol nearly abolished C produced by t-bu-OOH and also prevented the increased light caused by eicosatetrynoic acid. We directly tested the hypothesis that C occurred as a result of the interaction of t-bu-OOH and the cyclooxygenase and lipoxygenase enzymes; we measured C when t-bu-OOH was added to purified PGH2 synthase or soybean lipoxygenase. The combination of t-bu-OOH with PGH2 synthase or lipoxygenase led to C that was inhibited by dithiothreitol and by the antioxidant phenol. These results suggest that enzymes involved in AA metabolism can interact with t-bu-OOH and that the action of these enzymes on t-bu-OOH leads to C. The results may mean that lipid peroxides can indirectly contribute to tissue oxidant stress due to production of active O2 metabolites as by-products of their metabolism by AA peroxidases.     

Effect of inhibition of 5-lipoxygenase metabolism of arachidonic acid on response to endotoxemia in sheep

We studied the effects of a 5-lipoxygenase inhibitor, L-651,192, on the pulmonary dysfunction caused by endotoxemia in chronically instrumented unanesthetized sheep. The efficacy and selectivity of L-651,392 were tested by measuring in vivo production of leukotriene B4 (LTB4) and cyclooxygenase products of arachidonic acid after endotoxemia before and after pretreatment with L-651,392 and ex vivo from granulocytes and whole blood stimulated with calcium ionophore from sheep before and 24 h after pretreatment with L-651,392. A novel assay for LTB4 by high-performance liquid chromatography/gas chromatography/mass spectrometry techniques was developed as a measure of 5-lipoxygenase metabolism of arachidonic acid. L-651,392 proved to be an effective in vivo 5-lipoxygenase inhibitor in sheep. L-651,392 blocked the increase in LTB4 observed in lung lymph after endotoxemia in vivo in sheep as well as inhibited by 80% the ex vivo production of LTB4 by granulocytes removed from sheep treated 24 h earlier with L-651,392. Although L-651,392 blocked the increase in cyclooxygenase products of arachidonic acid observed in lung lymph after endotoxemia in vivo in sheep, the drug probably did not function directly as a cyclooxygenase inhibitor. L-651,392 did not attenuate the ex vivo production of thromboxane B2 by whole blood from sheep treated 24 h earlier with the drug. L-651,392 attenuated the alterations in pulmonary hemodynamics, lung mechanics, oxygenation, and lung fluid and solute exchange observed after endotoxemia in sheep. We speculate that 5-lipoxygenase products are a major stimulus for cyclooxygenase metabolism of arachidonic acid after endotoxemia in sheep.     

Action of arachidonic acid in ureteral-ligated kidney of the anesthetized canine: possible lipoxygenase activity

In anesthetized dogs 48 h after unilateral ureteral ligation, intra-arterial injection of arachidonic acid produced a transient increase followed by a prolonged decrease of resistance in the ureteral-ligated kidney; whereas, in the control kidney, only the prolonged decrease in resistance was observed in response to arachidonate. Indomethacin blocked not only the arachidonate-induced renal efflux of both immunoreactive 6-keto-prostaglandin F1 alpha and thromboxane B2 but also vasodilation in both kidneys. In contrast, the initial vasoconstriction in the obstructed kidney was not affected by pretreatment with the cyclo-oxygenase inhibitor. Infusion of 5,8,11,14-eicosatetraynoic acid, an inhibitor of lipoxygenase activity, into the ureteral-ligated kidney after indomethacin markedly reduced the initial vasoconstrictor response to arachidonate. These data demonstrate that vascular reactivity to arachidonic acid is altered in the ureteral-obstructed kidney and are consistent with the hypothesis that formation of lipoxygenase as well as cyclooxygenase derivatives may participate in the hemodynamic responses to arachidonic acid in this pathophysiologic model.     

Alteration of alveolar surfactant function after exposure to oxidative stress and to oxygenated and native arachidonic acid in vitro

Alveolar surfactant is known to be impaired after inhalation of various oxidizing agents (NO2, ozone) as well as in inflammatory lung processes, in which leucocyte-derived active oxygen species or arachidonic acid oxygenation products may be involved. The effect of lipid peroxidation, oxygen-free radicals and oxygenated versus native arachidonic acid on the surface tension behaviour of natural surfactant was tested in vitro. The studies were performed on pooled surfactant material, obtained from bronchoalveolar lavage of rabbit lungs, in a Langmuir trough/Wilhelmy balance system. Initiation of lipid peroxidation with FeCl3/ascorbate or UV radiation and the generation of OH.(FeCl2/EDTA/H2O2), O2-. (xanthine/xanthine oxidase) and 1O2 (NaOCl/H2O2) provoked a common profile of changes: delayed reduction of surface tension during compression with an increase in minimal compressibility accelerated decrease of film pressure during expansion, reduction of hysteresis area and markedly augmented monolayer collapse rate. Addition of arachidonic acid resulted in decreased minimal compressibility, stability index and hysteresis area. Incubation with the arachidonic acid cyclooxygenase products, prostaglandin E2, I2, F2 alpha or thromboxane B2, with soybean lipoxygenase or with H2O2 and O2-exposure caused only moderate or no alteration of surfactant behaviour in vitro. Conclusion: oxidative stress, but not arachidonic acid oxygenation products, provoked altered surface tension behaviour of natural surfactant in vitro.