Release of peptide leukotrienes from rat Kupffer cells

Kupffer cells isolated from the normal rat liver were incubated with calcium ionophore A23187, and the levels of peptide leukotrienes (LTC4, LTD4, and LTE4) contained in the culture supernatant were determined by the combined technique of reverse-phase high-performance liquid chromatography and radioimmunoassay. In response to A23187, Kupffer cells released LTC4, LTD4, and LTE4. After 10 min-preincubation of Kupffer cells with AA861, a 5-lipoxygenase inhibitor, the generation of LTC4, LTD4, and LTE4 from A23187-stimulated Kupffer cells was significantly suppressed. Platelet activating factor (PAF), a phospholipid mediator, significantly enhanced the release of LTC4, LTD4, and LTE4 from Kupffer cells stimulated with A23187. These results suggested that Kupffer cells may participate in inflammatory and immunologic events in the liver tissue by the release of peptide leukotrienes.     

Comparative studies on the leukotriene D4-metabolizing enzyme of different types of leukocytes

1. The leukotriene (LT) D4-metabolizing enzyme which catalyzes the conversion of LTD4 to LTE4, was investigated in various types of leukocytes from guinea pigs and humans. 2. In guinea pigs, the enzyme activity was present in macrophages but was hardly present in neutrophils, lymphocytes and eosinophils. 3. In humans, neutrophils, lymphocytes and macrophages all possessed the enzyme activity. However, enzyme activity varied with cell types and macrophages showed the highest enzyme activity among the leukocytes. 4. The subcellular localization of the LTD4-metabolizing enzyme was studied and leukocytes were divided into two groups: one which has the enzyme activity exclusively on the cell surface and the other which has the activity both on the cell surface and in the granules of leukocytes. 5. The enzyme activity was remarkably inhibited by o-phenanthroline and dithiothreitol and the inactivated enzyme was considerably reactivated by Co2+ and Zn2+, suggesting that the LTD4-metabolizing enzyme of leukocytes is a metalloenzyme.     

Conjunctival goblet cell secretion stimulated by leukotrienes is reduced by resolvins D1 and E1 to promote resolution of inflammation

The conjunctiva is a mucous membrane that covers the sclera and lines the inside of the eyelids. Throughout the conjunctiva are goblet cells that secrete mucins to protect the eye. Chronic inflammatory diseases such as allergic conjunctivitis and early dry eye lead to increased goblet cell mucin secretion into tears and ocular surface disease. The purpose of this study was to determine the actions of the inflammatory mediators, the leukotrienes and the proresolution resolvins, on secretion from cultured rat and human conjunctival goblet cells. We found that both cysteinyl leukotriene (CysLT) receptors, CysLT(1) and CysLT(2,) were present in rat conjunctiva and in rat and human cultured conjunctival goblet cells. All leukotrienes LTB(4), LTC(4), LTD(4), and LTE(4), as well as PGD(2), stimulated goblet cell secretion in rat goblet cells. LTD(4) and LTE(4) increased the intracellular Ca(2+) concentration ([Ca(2+)](i)), and LTD(4) activated ERK1/2. The CysLT(1) receptor antagonist MK571 significantly decreased LTD(4)-stimulated rat goblet cell secretion and the increase in [Ca(2+)](i). Resolvins D1 (RvD1) and E1 (RvE1) completely reduced LTD(4)-stimulated goblet cell secretion in cultured rat goblet cells. LTD(4)-induced secretion from human goblet cells was blocked by RvD1. RvD1 and RvE1 prevented LTD(4)- and LTE(4)-stimulated increases in [Ca(2+)](i), as well as LTD(4) activation of ERK1/2. We conclude that cysteinyl leukotrienes stimulate conjunctival goblet cell mucous secretion with LTD(4) using the CysLT(1) receptor. Stimulated secretion is terminated by preventing the increase in [Ca(2+)](i) and activation of ERK1/2 by RvD1 and RvE1.     

Conversion of leukotriene C4 to leukotriene D4 by a cell-surface enzyme of rat macrophages

Leukotriene (LT) C4-metabolizing enzyme was studied using rat leukocytes. Neutrophils and lymphocytes hardly metabolized LTC4, whereas macrophages rapidly converted LTC4 to LTD4. The LTC4-metabolizing enzyme of macrophages was present in the membrane fraction but not in the nuclear, granular and cytosol fractions. When macrophages were modified chemically with diazotized sulfanilic acid, a poorly permeant reagent which inactivates cell-surface enzymes selectively, the LTC4-metabolizing activity of macrophages decreased significantly (greater than 90%). These findings suggest that rat macrophages possess the LTC4-metabolizing enzyme which converts LTC4 to LTD4, on the cell surface membrane.     

Leukotriene C4 metabolism by hepatoma cells deficient in the uptake of cysteinyl leukotrienes

Uptake and metabolism of the cysteinyl leukotrienes C4 and E4 (LTC4 and LTE4) were studied in AS-30D hepatoma cell suspensions and compared with rat hepatocytes. The hepatoma cells were deficient in the uptake of [3H]LTC4 and [3H]LTE4 but took up, in control experiments, L-[14C]glutamine and [14C]adenosine in a time-dependent manner. By contrast, isolated hepatocyte suspensions incubated under the same conditions took up [3H]LTC4 and [3H]LTE4 as well as L-[14C]glutamine and [14C]adenosine. The hepatoma cells deficient in the uptake of cysteinyl leukotrienes metabolized extracellular [3H]LTC4 to [3H]LTD4 and to [3H]LTE4. Addition of acivicin, an inhibitor of gamma-glutamyltransferase, largely prevented metabolism of [3H]LTC4 by the hepatoma cells. Sonication of the cells did not enhance the formation of [3H]LTD4 and [3H]LTE4 from [3H]LTC4. We conclude that ectoenzymes of AS-30D hepatoma cells catalyze the conversion of LTC4 to LTE4 via LTD4. As compared to hepatocytes, these neoplastic cells have lost the uptake system for cysteinyl leukotrienes and may serve in studies on leukotriene metabolism by cell-surface enzymes.     

SCF-induced airway hyperreactivity is dependent on leukotriene production

Stem cell factor (SCF) is directly involved in the induction of airway hyperreactivity during allergen-induced pulmonary responses in mouse models. In these studies, we examined the specific mediators and mechanisms by which SCF can directly induce airway hyperreactivity via mast cell activation. Initial in vitro studies with bone marrow-derived mast cells indicated that SCF was able to induce the production of bronchospastic leukotrienes, LTC(4) and LTE(4). Subsequently, when SCF was instilled in the airways of naive mice, we were able to observe a similar induction of LTC(4) and LTE(4) in the bronchoalveolar lavage (BAL) fluid and lungs of treated mice. These in vivo studies clearly suggested that the previously observed SCF-induced airway hyperreactivity may be related to the leukotriene production after SCF stimulation. To further investigate whether the released leukotrienes were the mediators of the SCF-induced airway hyperreactivity, an inhibitor of 5-lipoxygenase (5-LO) binding to the 5-LO activating protein (FLAP) was utilized. The FLAP inhibitor MK-886, given to the animals before intratracheal SCF administration, significantly inhibited the release of LTC(4) and LTE(4) into the BAL fluid. More importantly, use of the FLAP inhibitor nearly abrogated the SCF-induced airway hyperreactivity. In addition, blocking the LTD(4)/E(4), but not LTB(4), receptor attenuated the SCF-induced airway hyperreactivity. In addition, the FLAP inhibitor reduced other mast-derived mediators, including histamine and tumor necrosis factor. Altogether, these studies indicate that SCF-induced airway hyperreactivity is dependent upon leukotriene-mediated pathways.     

Generation of leukotriene C4, leukotriene B4, and prostaglandin D2 by immunologically activated rat intestinal mucosa mast cells

Mucosal mast cells (MMC) were isolated from the intestine of Nippostrongylus brasiliensis-infected rats and then activated with Ag or with anti-IgE in order to assess their metabolism of arachidonic acid to leukotriene (LT) C4, LTB4, and prostaglandin D2 (PGD2). After challenge of MMC preparations of 19 +/- 1% purity with five worm equivalents of N. brasiliensis Ag, the net formation of immunoreactive equivalents of LTC4, LTB4, and PGD2 was 58 +/- 8.3, 22 +/- 4.5, and 22 +/- 3.4 ng/10(6) mast cells, respectively (mean +/- SE, n = 7). When MMC preparations of 56 +/- 9% purity were activated by Ag, the net generation of immunoreactive equivalents of LTC4, LTB4, and PGD2/10(6) MMC was 107 +/- 15, 17 +/- 5.4, and 35 +/- 18 ng, respectively. These data indicate that the three eicosanoids originated from the MMC rather than from a contaminating cell. Analysis by reverse phase HPLC of the C-6 sulfidopeptide leukotrienes present in the supernatants of the activated MMC preparations of lower purity revealed LTC4, LTD4, and LTE4. In a higher purity MMC preparation only LTC4 was present, suggesting that other cell types in the mucosa are able to metabolize LTC4 to LTD4 and LTE4. The release of histamine and the generation of eicosanoids from intestinal MMC and from peritoneal cavity-derived connective tissue-type mast cells (CTMC) isolated from the same N. brasiliensis-infected rats were compared. When challenged with anti-IgE, these MMC released 165 +/- 41 ng of histamine/10(6) mast cells, and generated 29 +/- 3.6, 12 +/- 4.2, and 4.7 +/- 1.0 ng (mean +/- SE, n = 3) of immunoreactive equivalents of LTC4, LTB4, and PGD2/10(6) mast cells, respectively. In contrast, CTMC isolated from the same animals and activated with the same dose of anti-IgE released approximately 35 times more histamine (5700 +/- 650 ng/10(6) CTMC), generated 7.5 +/- 2.3 ng of PGD2/10(6) mast cells, and failed to release LTC4 or LTB4. These studies establish, that upon immunologic activation, rat MMC and CTMC differ in their quantitative release of histamine and in their metabolism of arachidonic acid to LTC4 and LTB4.     

Hyperoxic lung damage in mice: appearance and bioconversion of peptide leukotrienes

High concentrations of oxygen damage the lung and increase bronchoalveolar lavage (BAL) fluid levels of leukotrienes. We sought to identify the specific leukotrienes produced and their relationship to the severity of the lung damage and the inflammatory cell populations by exposing mice to 100% oxygen for up to 4 days. Leukotrienes were not detected in BAL fluid from air-exposed mice. Leukotriene D4 (LTD4) was found after 2 days of exposure to 100% oxygen, increased with longer periods of exposure, and then decreased while LTE4 appeared when the lung damage became severe. LTB4 and LTC4 were not found at any time. Neutropenic mice had identical results, indicating that neutrophils were not the source of the leukotrienes. To determine why LTC4 was not found and why LTD4 decreased and LTE4 increased on day 4, we measured the metabolic capacity of BAL supernatant for leukotrienes. Incubation of LTD4 in BAL supernatant from air-exposed mice resulted in the conversion of LTD4 to LTE4, which was blocked by L-cysteine, a dipeptidase inhibitor. Faster conversion occurred after exposure to 100% oxygen for 3 and 4 days. The rate of bioconversion correlated with the BAL protein concentration (r = 0.756, P less than 0.001), and it was similar in neutropenic and nonneutropenic mice. Little LTC4 and no LTE4 were converted in BAL supernatant from air- or oxygen-exposed mice. The early and progressive increase in LTD4 suggests that sulfidopeptide leukotrienes may play a role in the pathogenesis of hyperoxic lung damage. The increased dipeptidase activity during hyperoxic exposure may serve a protective role by converting the more potent LTD4 to the less potent LTE4.     

Mast cell mediators stimulate synthesis of arachidonic acid metabolites in macrophages

Mast cells and macrophages were isolated from human lung tissues by using density gradient centrifugation, cell sorter, and adherence techniques. Passively sensitized mast cells in the absence of exogenous arachidonic acid (AA) released leukotriene (LT)C4, LTD4, PGD2, and thromboxane-B2 when challenged with Ag, and in the presence of AA, released 5-hydroxyeicosatetraenoic acid (HETE) and 15-HETE in addition to the above metabolites. Passively sensitized macrophages did not release significant amounts of AA metabolites when challenged with Ag. However, these cells released LTB4, LTC4, LTD4, LTE4, 5-HETE, PGE2 and 6-keto-PGF1 alpha when co-incubated with activated mast cells. During co-incubation, mast cells also generated greater amount of AA metabolites than when they were activated alone. The stimulatory action of mast cells on macrophages was shown to be due to the extracellular factor(s) present in the supernatant of the activated mast cells. Both heat and trypsin inhibited the biologic activity of mast cell-derived stimulatory factor. In addition, extraction of mast cells' materials with chloroform or ether showed no activity associated with the organic phase, suggesting it possibly possesses a protein nature, such as peptides, protease, or peptidase. These results suggest that mast cell-macrophage interaction might be important in the generation of multiple mediators in the airways during immediate hypersensitivity reactions.     

Targeted gene disruption reveals the role of cysteinyl leukotriene 1 receptor in the enhanced vascular permeability of mice undergoing acute inflammatory responses

The cysteinyl leukotrienes (cysLTs), leukotriene (LT) C(4), LTD(4), and LTE(4), are proinflammatory lipid mediators generated in the mouse by hematopoietic cells such as macrophages and mast cells. There are two mouse receptors for the cysLTs, CysLT(1) receptor (CysLT(1)R) and CysLT(2)R, which are 38% homologous and are located on mouse chromosomes X and 14, respectively. To clarify the different roles of the CysLT(1)R and CysLT(2)R in inflammatory responses in vivo, we generated CysLT(1)R-deficient mice by targeted gene disruption. These mice developed normally and were fertile. In an intracellular calcium mobilization assay with fura-2 acetoxymethyl ester, peritoneal macrophages from wild-type littermates, which express both CysLT(1)R and CysLT(2)R, responded substantially to 1 x 10(-6) m LTD(4) and slightly to 1 x 10(-6) m LTC(4), whereas the macrophages from CysLT(1)R-deficient mice did not respond to either LTD(4) or LTC(4). Plasma protein extravasation, but not neutrophil infiltration, was significantly reduced in CysLT(1)R-deficient mice subjected to zymosan A-induced peritoneal inflammation. Plasma protein extravasation was also significantly diminished in CysLT(1)R-deficient mice undergoing IgE-mediated passive cutaneous anaphylaxis as compared with the wild-type mice. Thus, the cysLTs generated in vivo by either monocytes/macrophages or mast cells utilize CysLT(1)R for the response of the microvasculature in acute inflammation.     

Metabolism of cysteinyl leukotrienes by the isolated perfused rat kidney.

The metabolism of cysteinyl leukotrienes by the isolated perfused rat kidney was investigated. For this purpose LTC4, LTD4 or LTE4 were studied in separate experiments. The isolated perfused rat kidney metabolized all cysteinyl leukotrienes to the final metabolite N-acetyl-LTE4. In the presence of 5% albumin 50% of LTC4 was metabolized to LTD4 (22%), LTE4 (15%) and N-acetyl-LTE4 (13%) within 60 min. Excretion of radioactivity into urine was less than 1%. In contrast, in the absence of albumin, LTC4 was completely metabolized within 45 min to N-acetyl-LTE4, the sole and final metabolite of LTC4 found in the perfusion medium as well as in urine. After 60 min 19% and 42% of total radioactivity were found in the perfusion medium and in urine, respectively. Isolated glomeruli metabolized LTC4 to LTD4 and to LTE4 but not to N-acetyl-LTE4 at a rate comparable to the rate observed by the isolated perfused kidney in the absence of albumin. In contrast to isolated glomeruli isolated tubuli metabolized LTE4 to N-acetyl-LTE4 at a rate comparable to that observed by the isolated perfused kidney in the absence of albumin. The present study shows that the isolated perfused rat kidney metabolizes cysteinyl leukotrienes to the sole and final metabolite N-acetyl-LTE4. In the presence of albumin metabolism is slowed down and excretion of N-acetyl-LTE4 into urine is prevented.     

Difference in the in vitro metabolism of leukotrienes in the exudates from allergic and nonallergic rat pleurisies

The metabolism of leukotrienes (LTs) in the cell-containing inflammatory exudate of rat pleurisy was studied in vitro. The exudates of both nonallergic carrageenin-induced pleurisy and IgG immune complex-mediated pleurisy converted 3H-LTB4 to 20-OH LTB4, but virtually did not metabolized 3H-LTC4 or 3H-LTE4 up to 2 hrs. 3H-LTD4 was changed to LTC4 by the exudate of non-allergic pleurisy, whereas 3H-LTD4 was metabolized to LTE4 by that of allergic pleurisy. Reflecting on the different metabolism, the gamma-glutamyl transpeptidase activity in the exudate of carrageenin-induced pleurisy was significantly higher than that in IgG immune complex mediated pleurisy. The enzyme activity was not derived from the blood itself, but from the infiltrated polymorphonuclear leukocytes. The activity of the cell homogenate in both exudates was not significantly different. Thus, it could be concluded that the difference in the metabolism of LTD4 between the nonallergic and allergic pleural exudates in vitro was mainly attributable to the enhanced activity of the gamma-glutamyl transpeptidase released in the exudate.     

Leukotriene biosynthesis and metabolism detected by the combined use of HPLC and radioimmunoassay

A radioimmunoassay for leukotriene D4 (LTD4) has been developed which exhibits sufficiently high sensitivity to be useful in conjunction with RP-HPLC in the detection of LTC4, LTD4 and LTE4 in physiological samples. The detection limit of the assay was approximately 240 amoles, using antiserum TG1 at a dilution of 6 X 10(3), with 50% displacement at 70 fmoles. Antiserum NW1, also at a dilution of 6 X 10(3), displayed a detection limit of 9 fmoles with 50% displacement at 100 fmoles. The two antisera have similiar crossreactivities, both manifesting useful affinities for LTE4 and LTC4, and low or negligible affinities for other arachidonic acid metabolites, or their derivatives. The radioimmunoassay was used to detect 1) LTC4, LTD4 and LTE4 released from perfused rat lung in response to platelet-activating factor (PAF) stimulation, 2) conversion of exogenous LTD4 to LTE4 in human blood, and 3) endogenous leukotrienes in human blood samples.     

Influences of salts on high-performance liquid chromatography of leukotrienes

The effects of concentrations and kinds of salts on the resolution of leukotrienes (LT) C4, D4, E4, and B4 were investigated by two kinds of reversed-phase high-performance liquid chromatography columns (muBondapak C18 and Novapak C18). When a mobile phase (acetonitrile/methanol/water) with a lower concentration of acetic acid (0.02-0.1%) at pH 5.6 was used, LTC4 and LTD4 were not eluted from the muBondapak column. On the Novapak column, LTC4 and LTD4 were eluted, but they were poorly resolved. When the concentration of acetic acid in the mobile phase was raised to 1.0% and adjusted to pH 5.6 with ammonium hydroxide or triethylamine, excellent resolution of LTs was obtained. Sodium hydroxide was, to some extent, useful for the pH adjustment of the mobile phase. Sodium chloride could not be substituted for acetic acid-ammonium hydroxide or -triethylamine salt. The resolution of LTC4, LTD4, and LTE4 was affected more strongly than that of LTB4 by changes of concentrations and kinds of salts. When the acetonitrile/methanol/water/acetic acid solvent system adjusted to pH 5.6 with triethylamine was applied to the analysis of the leukotrienes produced from rat peritoneal cells with stimulation of calcium ionophore A23187, de novo-synthesized LTC4, LTD4, LTB4, and isomers were clearly separated. This solvent system may be useful for the investigation of variations in the synthesis of subclasses of LTs with different stimuli and under different circumstances.     

The effect of vasoactive intestinal peptide and calcitonin gene-related peptide on peptidoleukotriene release from platelet activating factor stimulated rat lungs and ionophore stimulated guinea pig lungs

The effect of four neuropeptides and acetylcholine on the release of leukotrienes LTC4, LTD4 and LTE4 from platelet activating factor-stimulated rat lung and ionophore A23187-stimulated guinea pig lung, as detected by the combined use of HPLC and radioimmunoassay, was studied. Both vasoactive intestinal peptide and calcitonin gene-related peptide were found to inhibit the release of leukotrienes in both preparations. This effect was most marked in platelet activating factor-stimulated rat lung, where inhibition of LTC4 release was more pronounced than either inhibition of LTD4 or LTE4 production. The effect of vasoactive intestinal peptide on LTC4 biosynthesis was dose-related in rat lung. Neither substance P nor beta-endorphin were found to inhibit leukotriene release in rat lung. Vasoactive intestinal peptide inhibition of leukotriene release is independent from its actions on the muscarinic receptor, since acetylcholine was found to have no effect in the same preparation.     

Metabolism of cysteinyl leukotrienes in non-recirculating rat liver perfusion. Hepatocyte heterogeneity in uptake and biliary excretion

1. The uptake, metabolism and biliary excretion of the cysteinyl leukotrienes LTC4, LTD4 and LTE4, were studied in a non-recirculating rat liver perfusion system at constant flow in both antegrade (from the portal to the caval vein) and retrograde (from the caval to the portal vein) perfusion directions. During a 5-min infusion of [3H]LTC4, [3H]LTD4 and [3H]LTE4 (10 nmol/l each) in antegrade perfusions single-pass extractions of radioactivity from the perfusate were 66%, 81% and 83%, respectively. Corresponding values for LTC4 and LTD4 in retrograde perfusions were 83% and 93%, respectively, indicating a more efficient uptake of cysteinyl leukotrienes in retrograde than in antegrade perfusions. The concentrations of unmetabolized leukotrienes in the effluent perfusate were 8-12% in antegrade and 2-4% in retrograde perfusions. [14C]Taurocholate extraction from the perfusate was inhibited by LTC4 by only 3%, suggesting that an opening of portal-venous/hepatic-venous shunts does not explain the effects of perfusion direction on hepatic LTC4 uptake. 2. Following infusion of [3H]LTC4 and [3H]LTD4, in the antegrade perfusion direction, about 80% and 87%, respectively, of the radiolabel taken up by the liver was excreted into bile. In retrograde perfusions, however, only 40% and 57%, respectively, was excreted into bile and the remainder was slowly redistributed into the perfusate, indicating that leukotrienes were taken up into a hepatic compartment with less effective biliary elimination or converted to metabolites escaping biliary excretion. The metabolite pattern found in bile was not affected by the direction of perfusion. Biliary products of LTC4 were polar metabolites (31-38%), LTD4 (27-30%), LTE4 (about 1%) and N-acetyl-LTE4 (3-4%) in addition to unmodified LTC4 (17-18%). 3. LTC4 was identified as a major metabolite of [3H]LTD4 in bile, amounting to about 20% of the total radioactivity excreted into bile. This is probably due to a gamma-glutamyltransferase-catalyzed glutamyl transfer from glutathione in the biliary compartment, as demonstrated in in vitro experiments. The presence of sinusoidal gamma-glutamyltransferase activity in perfused rat liver was shown in experiments on the hydrolysis of infused gamma-glutamyl-p-nitroanilide. 90% inhibition of this enzyme activity by AT-125 did not affect the metabolism of LTC4. 4. When [3H]LTE4 was infused in the antegrade perfusion direction, biliary metabolites comprised N-acetyl-LTE4 (24%) and polar components (60%).(ABSTRACT TRUNCATED AT 400 WORDS)     

Comparative study of the pulmonary effects of intravenous leukotrienes and other bronchoconstrictors in anaesthetized guinea pigs

Pulmonary responses to intravenous leukotrienes C4, D4 and E4 administered as a bolus injection and by continuous infusion were studied in anesthetized guinea pigs. LTD4, LTC4 and LTE4 (respective ED50 of 0.21 +/- .1, 0.64 +/- .2 and 2.0 +/- .1 microgram kg-1) produced dose-dependent increases in insufflation pressure when given as a bolus injection to anesthetized guinea pigs (Konzett-R?ssler). Bronchoconstriction was antagonized by FPL-55712 (50-200 micrograms kg-1), and indomethacin (50-200 micrograms kg-1) but was not significantly altered by mepyramine (1.0 mg kg-1), methysergide (0.1 mg kg-1), intal (10 mg kg-1) mepacrine (5 mg kg-1) or dexamethasone (10 mg kg-1). The beta adrenoceptor blocker, timolol (5 micrograms kg-1) produced a significantly greater potentiation of the responses to the leukotrienes than to arachidonic acid, histamine and acetylcholine. Responses to bolus injection of LTE4 but not LTD4 or LTC4 were partially antagonized by atropine (100 micrograms kg-1) and bilateral vagotomy. In experiments of a different design, continuous infusion of LTD4 and LTE4 (2.8-3.2 micrograms kg-1 min-1) into indomethacin-treated animals produced slowly developing increases in pulmonary resistance and decreases in compliance. The increase in resistance produced by LTE4 and LTD4 was partly reversed by intravenous FPL-55712 (1.0 mg kg-1) and atropine (100 micrograms kg-1) but was almost completely reversed by FPL-55712 (3 - 10 mg kg-1). These findings indicate that leukotrienes can produce bronchoconstriction in guinea pigs through cyclooxygenase-dependent and cyclooxygenase independent mechanisms both of which are blocked by FPL-55712. Cholinergic mechanisms are involved in the mediation of part of the response to bolus injection of LTE4 as well as a small part of the initial response to continuous infusion of LTD4 and LTE4. Intrinsic beta adrenoceptor activation serves to down modulate responses to the leukotrienes to a greater extent than responses to arachidonic acid, histamine and acetylcholine.     

Leukotriene uptake by hepatocytes and hepatoma cells.

The uptake of tritiated cysteinyl leukotrienes (LTC4, LTD4, LTE4) and LTB4 was investigated in freshly isolated rat hepatocytes and different hepatoma cell lines under initial-rate conditions. Leukotriene uptake by hepatocytes was independent of an Na+ gradient and a K+ diffusion potential across the hepatocyte membranes as established in experiments with isolated hepatocytes and plasma membrane vesicles. Kinetic experiments with isolated hepatocytes indicated a low-Km system and a non-saturable system for the uptake of cysteinyl leukotrienes as well as LTB4 under the conditions used. AS-30D hepatoma cells and human Hep G2 hepatoma cells were deficient in the uptake of cysteinyl leukotrienes, but showed significant accumulation of LTB4. Moreover, only LTB4 was metabolized in Hep G2 hepatoma cells. Competition studies on the uptake of LTE4 and LTB4 (10 nM each) indicated inhibition by the organic anions bromosulfophthalein, S-decyl glutathione, 4,4'-diisothiocyanato-stilbene-2,2'-disulfonate, probenecid, docosanedioate, and hexadecanedioate (100 microM each), but not by taurocholate, the amphiphilic cations verapamil and N-propyl ajmaline, and the neutral glycoside ouabain. Cholate and the glycoside digitoxin were inhibitors of LTB4 uptake only. Bromosulfophthalein, the strongest inhibitor of leukotriene uptake by hepatocytes, did not inhibit LTB4 uptake by Hep G2 hepatoma cells under the same experimental conditions. Leukotriene-binding proteins were analyzed by comparative photoaffinity labeling of human hepatocytes and Hep G2 hepatoma cells using [3H]LTE4 and [3H]LTB4 as the photolabile ligands. Predominant leukotriene-binding proteins with apparent molecular masses in the ranges of 48-58 kDa and 38-40 kDa were labeled by both leukotrienes in the particulate and in the cytosolic fraction of hepatocytes, respectively. In contrast, no labeling was obtained with [3H]LTE4 in Hep G2 cells. With [3H]LTB4 a protein with a molecular mass of about 48 kDa was predominantly labeled in the particulate fraction of the hepatoma cells, whereas in the cytosolic fraction a labeled protein in the range of 40 kDa was detected. Our results provide evidence for the existence of distinct uptake systems for cysteinyl leukotrienes and LTB4 at the sinusoidal membrane of hepatocytes; however, some of the inhibitors tested interfere with both transport systems. Only LTB4, but not cysteinyl leukotrienes, is taken up and metabolized by the transformed hepatoma cells.     

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.     

The presence of ANP in rat peritoneal mast cells

Atrial natriuretic peptide （ANP） is an important component of the natriuretic peptide system. A great role in many regulatory systems is played by mast cells. Meanwhile involvement of these cells in ANP activity is poorly studied. In this work, we have shown the presence of ANP in rat peritoneal mast cells. Pure fraction of mast cells was obtained by separation of rat peritoneal cells on a Percoll density gradient. By Westem blotting, two ANP-immunoreactive proteins of molecular masses of 2.5 kDa and 16.9 kDa were detected in lysates from these mast cells. Electron microscope immunogold labeling has revealed the presence of ANP-immunoreactive material in storage, secreting and released granules of mast cells. Our findings indicate the rat peritoneal mast cells to contain both ANP prohormone and ANP. These both peptides are located in mast cell secretory granules and released by mechanism of degranulation. It is discussed that many mast cell functions might be due to production of natriuretic peptides by these cells.