Different mechanisms between thromboxane A2- and leukotriene D4-induced nasal blockage in guinea pigs

Although thromboxane (TX)A2 is involved in allergic rhinitis, the mechanisms inducing nasal blockage have not been elucidated. We evaluated the roles of nasal mucosal vascular changes following intranasal instillation of the TXA2 analog U-46619 or leukotriene (LT)D4 to induce nasal blockage in a guinea pig model of allergic rhinitis. Both U-46619- and LTD4-induced nasal blockages in sensitized animals were swiftly and completely suppressed by a vasoconstrictor, naphazoline. The nitric oxide synthase inhibitor N(omega)-nitro-l-arginine methyl ester relieved LTD4-induced nasal blockage, but not U-46619-induced nasal blockage. Although both agonists produced vasodilatation of nasal mucosa in vivo, LTD4 caused vasodilatation while U-46619 caused vasoconstriction in vitro. Both LTD4- and U-46619-induced nasal blockages in vivo should depend on vasodilatation of nasal mucosa. LTD4-induced nasal blockage is induced by direct vasodilatation via nitric oxide. In contrast, U-46619-induced nasal blockage may be associated with contraction of a certain vein that should exist at the exit of capacitance vessels, leading to congestion of the nasal mucosa.     

Mechanism of A23187-induced airway obstruction in the guinea pig

Exposure of conscious guinea pigs to A23187 aerosol produced a concentration-related increase of excised lung gas volume (ELGV), . ., postmortem pulmonary gas trapping. Measurements of ELGV were highly correlated with measurements of dynamic compliance (C_dyn) and total pulmonary resistance (R_L) and were used as an indication of airway obstruction. We pretreated guinea pigs intravenously with the following drugs: atropine; LY163443, a selective LTD₄/E₄ antagonist; indomethacin; propranolol; and pyrilamine. The guinea pigs were exposed for 8 minutes to the A23187 aerosol, and ELGV measurements were then made. Atropine or pyrilamine prevented the A23187-induced gas trapping. Indomethacin or propranolol tended to potentiate the response and when combined, they potentiated the gas trapping by 80%. LY163443 had no effect alone, but when combined with indomethacin, propranolol, and pyrilamine, inhibited A23187-induced gas trapping by 67%. We conclude that cholinergic and histaminergic mechanisms play major roles in the ionophore-induced pulmonary gas trapping of the guinea pig. With appropriate pretreatment, sulfidopeptide leukotrienes may produce a substantial effect.     

Mechanism of A23187-induced airway obstruction in the guinea pig

Exposure of conscious guinea pigs to A23187 aerosol produced a concentration-related increase of excised lung gas volumes (ELGV), i.e., postmortem pulmonary gas trapping. Measurements of ELGV were highly correlated with in vivo measurements of dynamic compliance (Cdyn) and total pulmonary resistance (RL) and were used as an indication of in vivo airway obstruction. We pretreated guinea pigs intravenously with the following drugs: atropine; LY163443, a selective LTD4/E4 antagonist; indomethacin; propranolol; and pyrilamine. The guinea pigs were exposed for 8 minutes to the A23187 aerosol, and ELGV measurements were then made. Atropine or pyrilamine prevented the A23187-induced gas trapping. Indomethacin or propranolol tended to potentiate the response and when combined, they potentiated the gas trapping by 80%. LY163443 had no effect alone, but when combined with indomethacin, propranolol, and pyrilamine, inhibited A23187-induced gas trapping by 67%. We conclude that cholinergic and histaminergic mechanisms play major roles in the ionophore-induced pulmonary gas trapping of the guinea pig. With appropriate pretreatment, sulfidopeptide leukotrienes may produce a substantial effect.     

Secondary release of thromboxane A2 in aerosol leukotriene C4-induced bronchoconstriction in guinea pigs

Effect of a thromboxane synthetase inhibitor (OKY-046) on bronchoconstriction induced by aerosol leukotriene C4 and histamine was studied in anesthetized, artificially ventilated guinea pigs in order to examine whether secondary release of thromboxane A2 is produced by aerosol leukotriene C4 or not. 0.01-1.0 micrograms/ml of leukotriene C4 and 12.5-400 micrograms/ml of histamine inhaled from ultrasonic nebulizer developed for small animals caused dose-dependent increase of pressure at airway opening (Pao) which is considered to be an index representing bronchial response. Pretreatment of the animals with intravenous OKY-046 (100mg/kg) significantly reduced the airway responses produced by inhalation of 0.1, 0.33 and 1.0 micrograms/ml of leukotriene C4, while the pretreatment did not affect the histamine dose-response curve. Based on these findings and previous reports (6,7), it is suggested that aerosol leukotriene C4 activates arachidonate cyclooxygenase pathway including thromboxane A2 synthesis and the released cyclooxygenase products have bronchodilating effect as a whole.     

Secondary release of thromboxane A2 in aerosol leukotriene C4-induced bronchoconstriction in guinea pigs

Effect of a thromboxane synthetase inhibitor (OKY-046) on bronchoconstriction induced by aerosol leukotriene C4 and histamine was studied in anesthetized, artificially ventilated guinea pigs in order to examine whether secondary release of thromboxane A2 is produced by aerosol leukotriene C4 or not. 0.01–1.0μg/ml of leukotriene C4 and 12.5–400μg/ml of histamine inhaled from ultrasonic nebulizer developed for small animals caused dose-dependent increase of pressure at airway opening (Pao) which is considered to be an index representing bronchial response. Pretreatment of the animals with intravenous OKY-046 (100mg/kg) significantly reduced the airway responses produced by inhalation of 0.1, 0.33 and 1.0μg/ml of leukotriene C4, while the pretreatment did not affect the histamine dose-response curve. Based on these findings and previous reports (6, 7), it is suggested that aerosol leukotriene C4 activates arachidonate cyclooxygenase pathway including thromboxane A2 synthesis and the released cyclooxygenase products have bronchodilating effect as a whole     

Influence of platelet-activating factor on leukotriene D4-induced contractions of the guinea pig parenchymal strip

Platelet-activating factor (PAF) and sulphidopeptide leukotrienes, such as leukotriene D4 (LTD4), are potent constrictors that are probably released simultaneously in a variety of inflammatory respiratory events. The purpose of the present study was to determine whether LTD4-induced contractions of guinea pig parenchymal lung strips (GPPS) are modified in the presence of PAF. The contractile responses of isolated GPPS to cumulative doses of LTD4, acetylcholine, histamine, and potassium chloride in the presence of PAF (0.1 nM, 0.1 microM) were compared with parallel controls. There was no significant alteration of the response to acetylcholine and potassium chloride and the PAF-induced inhibition of the response to histamine, although significant, was not concentration dependent. In contrast, PAF in a concentration range from 0.1 nM to 1.0 microM caused a marked, concentration-dependent reduction of LTD4-induced contractions. Pretreatment with the PAF receptor antagonist, BN52021, prevented the attenuation of LTD4-induced contraction by PAF. The attenuation of LTD4-induced contraction by PAF was also prevented by pretreatment with indomethacin or with the thromboxane synthase inhibitor U63,557A, but not by pretreatment with the lipoxygenase inhibitors BW755c or nordihydroguaiaretic acid. Thus inhibition of LTD4-induced GPPS contraction by PAF is receptor dependent and probably secondary to thromboxane generation. The respiratory smooth muscle response to leukotrienes may be modified significantly by concomitant PAF release.     

Elevating dietary salt exacerbates hyperpnea-induced airway obstruction in guinea pigs.

Previous studies have indicated that increased dietary salt consumption worsens postexercise pulmonary function in humans with exercise-induced asthma (EIA). It has been suggested that EIA and hyperpnea-induced airway obstruction (HIAO) in guinea pigs (an animal model of EIA) are mediated by similar mechanisms. Therefore, the purpose of this study was to determine whether altering dietary salt consumption also exacerbated HIAO in guinea pigs. Furthermore, the potential pathway of action of dietary salt was investigated by blocking leukotriene (LT) production during HIAO in guinea pigs. Thirty-two male Hartley strain guinea pigs were split into two groups. One group (n = 16) of animals ingested a normal-salt diet (NSD) for 2 wk; the other group (n = 16) ingested a high-salt diet (HSD) for 2 wk. Thereafter, animals were anesthetized, cannulated, tracheotomized, and mechanically ventilated during a baseline period and during two dry gas hyperpnea challenges. After the first challenge, the animals were administered either saline or nordihydroguaiaretic acid, a LT inhibitor. Bladder urine was analyzed for electrolyte concentrations and urinary LTE(4). The HSD elicited higher airway inspiratory pressures (Ptr) than the NSD (P < 0.001) postchallenge. However, after infusion of the LT inhibitor and a second hyperpnea challenge, HIAO was blocked in both diet groups (P < 0.001). Nonetheless, the HSD group continued to demonstrate slightly higher Ptr than the NSD group (P < 0.05). Urinary LTE(4) excretion significantly increased in the HSD group compared with the NSD group within treatment groups. This study has demonstrated that dietary salt loading exacerbated the development of HIAO in guinea pigs and that LT release was involved in HIAO and may be moderated by changes in dietary salt loading.     

Both inhalant and intravenous uroguanylin inhibit leukotriene C4-induced airway changes

Uroguanylin, a well-known ligand of guanylyl cyclase C receptor in the gastrointestinal tissue, has recently been reported to have pulmonary effects. We investigated the inhibitory effects of uroguanylin against leukotriene C4-induced bronchoconstriction and airway microvascular leakage. Anesthetized guinea pigs, ventilated via a tracheal cannula in a plethysmograph box, were measured by pulmonary mechanics for 10 min after i.v. administering 2 microg/kg leukotriene C4. Airway microvascular leakage was assessed by extravasation of Evans blue dye into airway tissues. Both inhalant and i.v. pretreatment of uroguanylin significantly inhibited leukotriene C4-induced pulmonary changes in a dose-dependent manner, suggesting its effectiveness against an asthmatic condition.     

Cyclooxygenase mediated airway response to leukotriene D4 in the cat

The effects of leukotriene D4 (LTD4) on pulmonary mechanics were investigated in anesthetized, paralyzed cats under conditions of controlled ventilation. Intravenous injections of LTD4 in doses of 3, 10, and 30 micrograms caused significant increases in transpulmonary pressure (PTP) and lung resistance (RL) while decreasing dynamic compliance (Cdyn). LTD4 also increased systemic arterial pressure (PAo). The changes in PTP, RL, and Cdyn in response to LTD4 were blocked by sodium meclofenamate, a cyclooxygenase inhibitor. However, there was no significant change in the increase in PAo following cyclooxygenase blockade. U 46619, a thromboxane mimic, was 30 to 100 times more potent than LTD4 in increasing PTP, RL and decreasing Cdyn in the cat. These data show that LTD4 has significant smooth muscle constrictor activity in central airways as well as peripheral portions of the feline lung. In addition, these data suggest that in the cat the actions of intravenously administered LTD4 on lung mechanics are mediated by release of cyclooxygenase products while the systemic pressor effects are not dependent upon the integrity of the cyclooxygenase pathway.     

Distribution and metabolism of leukotriene C4 after cisternal injection in guinea pigs

Following cisternal injection of [3H8]LTC4 into guinea pigs, leukotriene metabolites were identified in the brain, cerebellum, perilymph, blood, liver and kidneys. LTC4 was metabolized into LTD4 and LTE4 in the cerebrospinal fluid and LTE4 was transported into the blood for general circulation and uptake into the liver and kidneys. The excretion of LTE4 from CNS to blood seemed to be the rate-limiting step in the elimination of leukotrienes from the body. Leukotrienes were also transported into the perilymph. The conversion of LTC4 into LTD4 and LTE4 was lower in perilymph as compared to the cerebrospinal fluid, suggesting a rate limiting function of the cochlear aqueduct that can be defined as a cerebrospinal fluid-labyrinth barrier.     

Effects of timolol, indomethacin, and MK-571 on bronchoconstriction to infused leukotriene D4 in guinea pigs

Continuous intravenous infusions of leukotriene D4 produced a prolonged but variable bronchoconstriction (approximately a 200% increase in lung resistance (RL) and a 50% decrease in dynamic compliance (Cdyn] in anesthetized and paralysed guinea pigs that peaked within 1-1.5 min and was followed by a somewhat smaller secondary plateau response. The overall response was delayed (time to peaks) but not significantly reduced by pretreatment with the cyclooxygenase inhibitor indomethacin (1 mg/kg), was markedly potentiated by the beta-adrenoceptor antagonist timolol (5 micrograms/kg), and was partially and completely blocked by pretreatment with 0.1 and 1.0 mg/kg, respectively, of the leukotriene D4 receptor antagonist MK-571. MK-571 prevented the response in indomethacin-treated guinea pigs but was considerably more active at preventing and reversing the potentiated responses (lower dose of leukotriene D4) in animals treated with indomethacin and timolol. Additional studies in indomethacin- and timolol-treated animals demonstrated that MK-571 was active with good duration of action by the aerosol route of administration (30 min and 4 h pretreatment). The technique of infusing leukotrienes into untreated, indomethacin-treated, and indomethacin- and timolol-treated guinea pigs is a useful method to study the action and interaction of leukotriene receptor antagonists.     

Identification of leukotriene D4 receptor binding sites in guinea pig lung homogenates using [3H]leukotriene D4

We have characterized [3H]leukotriene D4 binding to guinea pig lung homogenates. Both biphasic dissociation kinetics and curvilinear Scatchard plots indicated the presence of [3H]leukotriene high and low affinity states of the binding sites. The rank order of potency for the competition study was leukotriene C4 = leukotriene D4 greater than leukotriene E4 much greater than arachidonic acid, and for their contractile effect on lung strips was leukotriene C4 = leukotriene D4 = leukotriene E4 much greater than arachidonic acid. FPL-55712 was the only other agent tested that inhibited binding. These results suggest that binding of [3H]leukotriene D4 to the homogenate is consistent with its binding to specific leukotriene D4 receptor sites.     

Ebselen suppresses late airway responses and airway inflammation in guinea pigs

Although ebselen, a seleno-organic compound, inhibits inflammation in various animal models, its efficacy as an anti-asthma drug remains to be clarified. In this study, we investigated the inhibitory effect of ebselen on a guinea pig asthma model. Ebselen was orally administered at dosages of 1-20 mg/kg 2 h before an ovalbumin (OA) challenge, and then airway responses, airway inflammation, the generation of superoxide, H(2)O(2), and nitrotyrosine, and the induction of inducible nitric oxide synthase (iNOS) were evaluated. Sensitized animals challenged with OA aerosol showed dual airflow limitations, i.e., immediate and late airway responses (IAR and LAR). Ebselen significantly inhibited LAR at dosages greater than 10 mg/kg, but did not inhibit IAR at any dosage. Bronchoalveolar lavage (BAL) examination showed that airway inflammation was significantly suppressed by ebselen at 10 mg/kg. The generation of superoxide and H(2)O(2) occurred on endothelial cells of LAR bronchi, and was inhibited by 10 mg/kg of ebselen. Superoxide generation was inhibited by diphenyleneiodonium chloride (DPI), a NAD(P)H oxidase inhibitor, but not by allopurinol, a xanthine oxidase inhibitor. Immunoreactivities for iNOS and nitrotyrosine were also observed on endothelial cells of LAR bronchi and were abolished in ebselen-treated animals. The present findings suggest that ebselen can be applied as a new therapeutic agent for asthma. The possible mechanisms by which ebselen inhibits LAR likely involve suppression of oxidant formation and iNOS induction in endothelial cells.     

Propranolol potentiates leukotriene D4-induced bronchoconstriction and enhances antagonism by FPL 55712

Aerosol LTD4-induced bronchoconstriction in anesthetized, spontaneously breathing guinea pigs was potentiated by either pretreatment with propranolol or bilateral adrenalectomy, whereas bilateral vagotomy did not affect the LTD4 response. The dose-response curve describing LTD4-induced changes in dynamic lung compliance (CDYN) and pulmonary resistance (RL) [as reflective indices of bronchoconstriction] was shifted to the left by approximately 20-fold by propranolol. Against an equal degree of LTD4-induced bronchoconstriction, the leukotriene antagonist, FPL 55712, had an apparent 20-fold greater potency in propranolol-pretreated animals vis a vis saline-treated controls. The duration of action of aerosol FPL 55712 was similar in both propranolol-treated and saline-treated animals. These results demonstrate that aerosol LTD4-induced bronchoconstriction is modulated by an adrenergic compensatory bronchodilator mechanism that is apparently dependent upon the adrenals and independent of vagal influences. Inhibition of the effect of this reflex with propranolol also enhances the apparent potency of an aerosol leukotriene antagonist, FPL 55712, presumably reflecting a constant LTD4 to antagonist ratio in the saline-treated and propranolol-pretreated guinea pigs.     

Anesthesia protocol for hyperpnea-induced airway obstruction in the guinea pig

Guinea pigs (GP; Cavia porcellus) are used extensively as an experimental animal model in a wide range of disciplines including respiratory physiology. Guinea pigs are difficult to anesthetize, and many investigators use paralytic agents to eliminate spontaneous respiratory movements; however, strict federal regulations and institutional policies governing use of paralytic agents are few. We report an anesthesia protocol, using the injectable anesthetic agents sodium pentobarbital (SP) and xylazine (XYL) for the GP that induces consistent anesthesia while eliminating use of paralytic agents. Sixty percent of the calculated SP dose (45 mg/kg of body weight) was given for anesthesia induction, followed by 50% of the calculated XYL dose (7 mg/kg) 15 min later. Depth of anesthesia was monitored by response to toe pinch, ECG, and spontaneous respiratory movements. The animals were given additional boosts of SP (5 to 15% of the original dose, i.p. or i.v.) if a change in anesthesia depth was noted. Thirty-one animals completed the hyperpnea-induced bronchoconstriction (HIB) study with no fatalities. Using this protocol, we collected consistent, repeatable, and reliable data without use of propranolol or skeletal muscle paralytics. We believe that this protocol is not restricted to the GP and could be adapted for use in other terminal experiments.     

Pranlukast protects leukotriene C4- and D4-induced epithelial cell impairment of the nasal mucosa in vitro

To investigate the effect of pranlukast on leukotriene- induced airway mucosal epithelial dysfunction, samples of human nasal mucosa obtained during surgery for facial trauma were exposed to leukotriene C4 and/or D4 and observed on a TV screen magnified x 2,500. Leukotriene C4- and D4-induced ciliary inhibition and delayed mucosal surface alterations appeared several hours later. Pranlukast prevented both the mucosal epithelial cell dysfunction and the delayed epithelial cell alteration.     

Acute effects of prostaglandin D2 to induce airflow obstruction and airway microvascular leakage in guinea pigs: role of thromboxane A2 receptors

BACKGROUND: Although prostaglandin D2 (PGD2), a mast cell-derived inflammatory mediator, may trigger allergic airway inflammation, its potency and the mechanism by which it induces airway microvascular leakage, a component of airway inflammation, is not clear. OBJECTIVE: We wanted to evaluate the relative potency of PGD2 to cause microvascular leakage as compared to airflow obstruction, because both responses were shown to occur simultaneously in allergic airway diseases such as asthma. The role of thromboxane A2 receptors (TP receptors) in inducing these airway responses was also examined. METHODS: Anesthetized and mechanically ventilated guinea pigs were given i.v. Evans blue dye (EB dye) and, 1 min later, PGD2 (30, 100, 300 or 1,000 nmol/kg). For comparison, the effect of 150 nmol/kg histamine or 2 nmol/kg leukotriene D4 (LTD4) was also examined. Lung resistance (R(L)) was measured for 6 min (or 25 min for selected animals) and the lungs were removed to calculate the amount of extravasated EB dye into the airways as a marker of leakage. In some of the animals, specific TP receptor antagonists, S-1452 (10 microg/kg) or ONO-3708 (10 mg/kg), or a thromboxane A2 synthase inhibitor, OKY-046 (30 mg/kg), was pretreated before giving PGD2. RESULTS: Injection of PGD2 produced an immediate and dose-dependent increase in RL (peaking within 1 min), which was significant at all doses studied. At 1,000 nmol/kg, PGD2 induced a later increase in R(L), starting at 3 min and reaching a second peak at 8 min. By contrast, only PGD2 at doses of 300 and 1,000 nmol/kg produced a significant increase in EB dye extravasation. The relative potency of 1,000 nmol/kg PGD2 to induce leakage as compared to airflow obstruction was comparable to histamine at most of airway levels, but less than LTD4. Both responses caused by PGD2 were completely abolished by S-1452 and ONO-3708, but not by OKY-046. CONCLUSION: PGD2 may induce airway microvascular leakage by directly stimulating TP receptors without generating TXA2 in guinea pigs. Microvascular leakage may play a role in the development of allergic airway inflammation caused by PGD2.     

Effect of a peptide leukotriene antagonist, ONO-1078 on antigen-induced airway microvascular leakage in actively sensitized guinea pigs.

We examined the effect of ONO-1078, a peptide leukotriene antagonist, on antigen-induced airway microvascular leakage in ovalbumin-sensitized guinea pigs. When guinea pigs were pretreated with mepyramine, ovalbumin challenge increased vascular permeability to Evans blue dye in trachea, main bronchi and intrapulmonary airways. Oral administration of ONO-1078 significantly reduced microvascular leakage in intrapulmonary airways at doses more than 3 mg/kg, but not in trachea. Moreover, oral administration of ONO-1078 significantly reduced SRS-A mediated microvascular leakage into all airway tissues and was more effective in intrapulmonary airways at 3 mg/kg. Simultaneously, ONO-1078 also inhibited SRS-A mediated bronchoconstriction. On the other hand, azelastine (10 mg/kg, p.o.), an anti-asthma agent, failed to inhibit microvascular leakage into the airways. These results suggest that peptide leukotrienes may be important mediators of airway microvascular leakage, and that the inhibitory effect of ONO-1078 on antigen-induced airway microvascular leakage in addition to the blockade of bronchoconstriction may have therapeutic implications for bronchial asthma.