Absence of Tachykinin Involvement in Leukotriene D4 and Antigen-Induced Contraction of Guinea Pig Isolated Bronchus

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Vol. 283, Issue 3, 1102-1109, 1997

Absence of Tachykinin Involvement in Leukotriene D₄ and Antigen-Induced Contraction of Guinea Pig Isolated Bronchus¹

Susan M. Cibulsky and David C. Thompson

Department of Pharmaceutical Sciences, University of Colorado School of Pharmacy, Denver, Colorado

	Abstract

Abstract Introduction Materials & Methods Results Discussion References

In guinea pig airways, contractions induced by leukotriene D₄ or antigen are thought to be mediated primarily by an actionof the agonist or of released mast cell-derived mediators directlyon the airway smooth muscle cell. An indirect contractile actionmediated by endogenous tachykinins also has been described forboth of these stimuli. The present study evaluated the contributionof endogenous tachykinins to ovalbumin- and leukotriene D₄-inducedcontractions in the guinea pig bronchus by modulating the concentrationsof tachykinins within the tissues and by using neurokinin receptorantagonists. Acute depletion of tachykinins with capsaicin hadno effect on responses elicited by either stimulus. Similarly,tetrodotoxin treatment failed to influence leukotriene D₄-inducedcontractions. Inhibitors of neutral endopeptidase (thiorphan)and angiotensin-converting enzyme (lisinopril) enhanced neurallymediated tachykininergic responses and potentiated leukotrieneD₄. The latter effect persisted in the presence of tetrodotoxinor the neurokinin antagonists CP99994 and SR48968 and in tissuestreated acutely with capsaicin. The potentiation was absent, however,from bronchi incubated with L-cysteine. Ovalbumin-induced contractionswere unaltered by inhibition of neutral endopeptidase and angiotensin-convertingenzyme. These observations suggest that tachykinins are not involvedin mediation of leukotriene D₄- or antigen-induced contractionsof the guinea pig bronchus. The ability of protease inhibitorsto potentiate leukotriene D₄ but not antigen-induced responsesis therefore ascribed to inhibition of bioinactivation of leukotrieneD₄ to leukotriene E₄.

	Introduction

Abstract Introduction Materials & Methods Results Discussion References

Guinea pig central airways are well supplied with tachykinin-containing nerves (Lundberg et al., 1984; Manzini et al., 1989).A variety of pharmacological agents have been shown to stimulatethe release of tachykinins from guinea pig airways. These includemuscarinic and nicotinic cholinoceptor agonists (Kizawa and Takayanagi,1985; Saria et al., 1988; Martins et al., 1991), bradykinin (Sariaet al., 1988), histamine (Saria et al., 1988; Martins et al.,1991), platelet-activating factor (Martins et al., 1991) and leukotrieneD₄ (Bloomquist and Kream, 1990; Martins et al., 1991). Given thatthe tachykinins, substance P and neurokinin A, are potent contractileagonists on airway smooth muscle (Saria et al., 1988), it is conceivablethat contractions of airway smooth muscle by the aforementionedpharmacological agonists could be supplemented or mediated indirectlyby tachykinins released from intrinsic airway nerves. Severalstudies support this contention. First-generation tachykinin antagonistsabolish nicotine-induced contraction of the guinea pig bronchus(Kizawa and Takayanagi, 1985) and attenuate contractions of theguinea pig trachea caused by leukotriene D₄ (Bloomquist and Kream,1990). Depletion of endogenous tachykinins by acute capsaicintreatment prevents the contractile activity of nicotine in theguinea pig bronchus (Kizawa and Takayanagi, 1985). Furthermore,inhibition of tachykinin metabolism enhances increases in guineapig airway opening pressure induced by histamine and methacholine(Martins et al., 1991) and augments antigen- and leukotriene C₄-inducedcontractions of the guinea pig bronchus (Kohrogi et al., 1991).Employing pharmacological tools used by previous investigatorsand newer, more selective neurokinin antagonists, the presentstudy re-evaluates the contribution of an indirect tachykinin-dependentmechanism to the mediation of contractions induced by leukotrieneD₄, an agonist for which there is the greatest functional evidenceof tachykinin involvement. Given the contribution of leukotrienesto antigen-induced responses, we also assessed the role of tachykininsin ovalbumin-induced contractions in airway tissue obtained fromsensitized guinea pigs.

	Materials and Methods

Abstract Introduction Materials & Methods Results Discussion References

Animal sensitization. Male guinea pigs (200-250 g) were sensitized to ovalbumin using the method of Andersson (1980). In summary, ovalbumin wasadsorbed to aluminum hydroxide (10 mg/ml) and administered asa single i.p. dose (40 µg/kg). Fourteen to 21 days later, animalswere used in experiments in which antigen-induced effects wereexamined.

In experiments on the effects of leukotrienes, male Hartley guinea pigs that weighed 250 to 450 g, were anesthetized usingsodium pentobarbital (100 mg/kg i.p.). Upon attainment of surgicalanesthesia, the trachea and lungs were removed en bloc and placedin KHS of the following composition (mM): NaCl, 118.2; KCl, 4.74;CaCl₂, 2.54; KH₂PO₄, 1.19; MgSO₄, 1.19; NaHCO₃, 26.2; D(+)-glucose,11.1. Indomethacin (2.8 µM) was included in the KHS to abolishthe influence of cyclooxygenase products on tissue responses.Right and left main stem bronchial ring preparations, obtainedimmediately distal to the tracheal bifurcation, were isolatedfrom each animal. Tissue segments were cleaned of extraneous connectivetissue and mounted on stainless steel tissue hooks in 15-ml glass-jacketedorgan baths containing KHS maintained at 37°C and gassed with5% CO₂ in O₂. An initial load of 6 g was placed on bronchial segments.Tissues were allowed to equilibrate for 60 min, during which timethe bathing solution was exchanged at 10-min intervals. Upon attainmentof a stable base-line tone, a maximal contractile concentrationof ACh (1 mM) was administered to all tissues. After the ACh responsehad stabilized, the tissues underwent a 60-min "washout period"during which the bathing solution was exchanged at 10-min intervals.Upon reattainment of a steady base-line tone, tissues were subjectedto various treatments as noted below.

(1) Depletion of endogenous tachykinins. Endogenous tachykinins were depleted using acute capsaicin treatment (Kizawa andTakayanagi, 1985

; Thompson et al., 1987

). One of the pair of airwaypreparations was exposed to capsaicin (10 µM) for 60 min, theother to capsaicin vehicle (15 µl of ethanol) for 60 min. Tissuesthen underwent a 60-min "washout period" during which the bathingsolution was exchanged at 10-min intervals.

(2) Protease inhibition. One of the pair of airway preparations was exposed to a neutral endopeptidase inhibitor, thiorphan(10 µM), to an angiotensin-converting enzyme inhibitor, lisinopril(10 µM), or to their combination, and the other of the pair wasexposed to an equivalent volume of inhibitor vehicle. An incubationperiod of 30 min was then allowed before leukotriene D₄ or ovalbuminwas applied to the tissues.

(3) Inhibition of action potential conduction. One of the pair of airway preparations was exposed to tetrodotoxin (10 µM),the other to an equivalent volume of inhibitor vehicle. An incubationperiod of 30 min was then allowed before leukotriene D₄ or ovalbuminwas applied to the tissues.

(4) Inhibition of neurokinin receptors. One of the pair of airway preparations was exposed to NK₁ antagonist, CP99994 (1 µM)(McKee et al., 1993

), and to NK₂ antagonist, SR48968 (10 µM) (Advenieret al., 1992

), and the other of the pair was exposed to an equivalentvolume of inhibitor vehicle. An incubation period of 30 min wasthen allowed before leukotriene D₄ or ovalbumin was applied tothe tissues.

(5) Inhibition of conversion of leukotriene D₄ to leukotriene E₄. Tissues were treated with L-cysteine (3 mM) 30 min beforecommencement of the leukotriene D₄ concentration-response curveto prevent metabolism of leukotriene D₄ to leukotriene E₄ by tissueaminopeptidases (Snyder et al., 1984

; Snyder and Krell, 1984

After the appropriate treatment regimen, a concentration-response curve to ovalbumin (antigen) or leukotriene D₄ was elicitedby the cumulative addition of agonist to the bathing solution.

Experimental protocols were designed on a paired basis such that one of each pair of tissues from each animal (e.g., leftor right hilar bronchus) acted as a control (vehicle or no treatment)while the other of the pair was subjected to treatment. Experimentswere designed such that equivalent numbers of each airway segmentwere assigned to control and test groups. No differences in responsivenessof left and right hilar bronchus were evident. Neurally mediatedtachykininergic responses were induced in bronchial preparationstreated with atropine (1 µM), guanethidine (10 µM), propranolol(1 µM) (to abolish cholinergic and adrenergic neural influences)and thiorphan (10 µM) and lisinopril (10 µM) (to inhibit tachykinindegradation). Pseudo-cumulative frequency-response curves forelectrical field stimulation (0.1-80 Hz, pulse duration 0.3 ms,pulse amplitude 10 V, 5 s stimulation duration/60 s) were appliedto preparations using rectangular wave pulses generated by a GrassS-88 stimulator in series with a signal conditioner (Stimu-Splitter,Med. Lab. Instruments, Fort Collins, CO). All responses were measuredisometrically using force-displacement transducers (Grass FT.03c)and were displayed on a Maclab8 (ADI Instruments, Sydney, Australia)/Macintosh(Apple Computer Corp., Cupertino, CA) computer system.

Materials. All reagents were of analytical grade. Drugs were obtained from the following sources: ACh perchlorate, capsaicin, L-cysteine,leukotriene D₄, leukotriene E₄, ovalbumin (grade V), tetrodotoxin,thiorphan (Sigma Chemical Co., St. Louis, MO); CP99994, lisinopril,SR48968 (Merck Frosst, Kirkland, Québec, Canada). Indomethacinwas initially dissolved in 0.1 M Na₂CO₃ and diluted 10,000-foldin KHS. Capsaicin, CP99994 and SR48968 were dissolved in ethanoland diluted in KHS. All other drugs were dissolved in distilledwater and diluted in KHS.

Statistical analysis. Data are presented as means and associated S.E.M. The negative logarithmic values of the concentrations of contractile agonistthat produced a 40% maximal ACh response are denoted as log EC_40 ACh.This concentration was selected (rather than log EC₅₀ or pD₂)because the maximal effect of leukotriene D₄ was usually not obtainedin experiments. Nevertheless, in the presence of L-cysteine (wherea maximum did appear to be achieved), the maximal effect of leukotrieneD₄ was $approx$ 80% ACh maximum. Accordingly, the leukotriene D₄ log EC_40 AChapproximates the leukotriene D₄ log EC₅₀. Log EC_40 AChvalues were determined by regression analysis and interpolationof the linear portions of individual concentration-response curves.Statistical comparisons of concentration-response curves wereconducted using two-way analysis of variance (ANOVA). Post-hocStudent's unpaired t tests were used to compare responses at specificagonist concentrations. P < .05 was considered significant.

	Results

Abstract Introduction Materials & Methods Results Discussion References

Initial studies were conducted to verify the efficacy of treatments. A combination of the protease inhibitors thiorphan andlisinopril enhanced neurally mediated tachykininergic responsesin the guinea pig bronchus (fig. 1). These inhibitor-augmentedresponses were absent from tissues treated with the neurokininreceptor antagonists CP99994 and SR48968 (fig. 1). This same neurokininantagonist combination induced a 57-fold rightward shift of thesubstance P concentration-response curve (control, $-$ 7.97 ± 0.17;treated, $-$ 6.22 ± 0.08, mean log EC₅₀ ± S.E.M.). Acute capsaicintreatment also abolished neurally mediated tachykininergic responses(data not shown).

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Fig. 1. Modulation of neurally mediated tachykininergic responses by protease inhibition and neurokinin receptor antagonism. Neurallymediated tachykininergic responses were induced by electricalfield stimulation (EFS) in bronchi treated with inhibitors ofadrenergic and cholinergic nerve function. Frequency-responsecurves for EFS were obtained in control preparations (open circles),in preparations incubated with thiorphan (10 µM) and lisinopril(10 µM) (closed circles) and in tissues incubated with thiorphan(10 µM), lisinopril (10 µM) and the neurokinin antagonists CP99994(1 µM) and SR48968 (10 µM) (closed squares). Responses were expressedas a percentage of the response to ACh (1 mM). Data representthe mean with one S.E.M. from four experiments.

Leukotriene D₄ induced concentration-dependent contraction of the guinea pig bronchus, threshold responses becoming manifestat about 1 nM. In bronchi from sensitized animals, ovalbumin evokedconcentration-dependent contractions with a threshold of 0.1 ng/ml.Acute capsaicin exposure had no influence on either the leukotrieneD₄ (P = .18, ANOVA) or the ovalbumin (P = .17, ANOVA) concentration-responserelationships in the bronchus (fig. 2). Similarly, neither contractileresponses induced by leukotriene D₄ (P = .25, ANOVA) nor thoseinduced by ovalbumin (P = .50, ANOVA) were affected by CP99994and SR48968 (fig. 3) or by tetrodotoxin (P = .66, ANOVA for leukotrieneD₄) (data not shown). By contrast, treatment of tissues with thecombination of thiorphan and lisinopril resulted in marked potentiationof leukotriene D₄ at all concentrations except the maximal concentrationtested, 0.1 µM (fig. 4). Neither inhibitor alone, however, alteredthe leukotriene D₄ concentration-response curve (P = .71 for lisinopril;P = .91 for thiorphan, ANOVA) (fig. 5). The combination of thiorphanand lisinopril failed to influence ovalbumin (P = .88, ANOVA)-or ACh (P = .73, ANOVA)-induced contractions (fig. 6).

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Fig. 2. Lack of effect of acute capsaicin treatment on contractions elicited by leukotriene D₄ and antigen. Leukotriene D₄ was administeredin a cumulative manner to bronchial preparations (upper diagram).Antigen-induced responses were obtained by cumulative applicationof ovalbumin to bronchi from sensitized animals (lower diagram).Responses were obtained in control preparations (open symbols)and in preparations exposed previously to capsaicin (10 µM) (closedsymbols) and were expressed as a percentage of the response toACh (1 mM). Data represent the mean with one S.E.M. from 5 to6 experiments.

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Fig. 3. Neurokinin receptor blockade does not alter leukotriene D₄ or antigen-induced responses. Leukotriene D₄ was administered ina cumulative manner to bronchial preparations (upper diagram).Antigen-induced responses were obtained by cumulative applicationof ovalbumin to bronchi from sensitized animals (lower diagram).Responses were obtained in control preparations (open symbols)and in preparations treated with NK₁ antagonist (CP99994, 1 µM)and NK₂ antagonist (SR48968, 10 µM) (closed symbols) and wereexpressed as a percentage of the response to ACh (1 mM). Datarepresent the mean with one S.E.M. from 4 to 6 experiments.

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Fig. 4. Potentiation of leukotriene D₄ by protease inhibition. Leukotriene D₄ was administered in a cumulative manner to control preparations(open circles) and to preparations incubated with the proteaseinhibitors thiorphan (10 µM) and lisinopril (10 µM) (closed circles).Responses were expressed as a percentage of the response to ACh(1 mM). Data represent the mean with one S.E.M. from six experiments.*P < .05, unpaired Student's t test, compared with the responseat the same leukotriene D₄ concentration in control preparations.

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Fig. 5. Individual protease inhibitors fail to potentiate leukotriene D₄. Leukotriene D₄ was administered in a cumulative manner tocontrol preparations (open circles) and to preparations incubatedwith thiorphan (10 µM) (closed circles, upper diagram) or lisinopril(10 µM) (closed circles, lower diagram). Responses were expressedas a percentage of the response to ACh (1 mM). Data representthe mean with one S.E.M. from six experiments.

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Fig. 6. Lack of effect of protease inhibitors on antigen- or ACh-induced contractions. Antigen-induced responses were obtained bycumulative application of ovalbumin to bronchi from sensitizedanimals (upper diagram). ACh was administered in a cumulativemanner to bronchial preparations (lower diagram). Responses wereobtained in control preparations (open symbols) and in preparationstreated with the protease inhibitors thiorphan (10 µM) and lisinopril(10 µM) (closed symbols) and were expressed as a percentage ofthe response to ACh (1 mM). Data represent the mean with one S.E.M.from 5 to 6 experiments.

The mechanism of the potentiation of leukotriene D₄ by the combination of thiorphan and lisinopril was examined further inadditional experiments. The potentiation persisted in tissuestreated with tetrodotoxin (fig. 7) or with the neurokinin antagonistsCP99994 and SR48968 (fig. 7) and in those tissues that had undergoneacute capsaicin treatment (fig. 8). Conducting experiments inthe presence of L-cysteine resulted in abolition of the potentiation(P = .85, ANOVA) (fig. 9). It should be noted, however, that L-cysteinetreatment alone served to enhance the potency of leukotriene D₄independently of the presence of thiorphan and lisinopril (controllog EC_40 ACh = $-$ 7.78 ± 0.08 vs. L-cysteine control logEC_40 ACh = $-$ 8.24 ± 0.25). Contractions induced by leukotrieneE₄ were unaltered by thiorphan and lisinopril (P = .53, ANOVA)(fig. 10).

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Fig. 7. Inactivity of inhibition of action potential conduction or neurokinin antagonism on protease inhibitor-induced potentiationof leukotriene D₄. Leukotriene D₄ was administered in a cumulativemanner to tissues treated with tetrodotoxin (10 µM) (upper figure)and to tissues treated with NK₁ antagonist (CP99994, 1 µM) andNK₂ antagonist (SR48968, 10 µM) (lower figure). Preparations wereincubated with vehicle (control, open circles) or with the proteaseinhibitors thiorphan (10 µM) and lisinopril (10 µM) (closed circles).Responses were expressed as a percentage of the response to ACh(1 mM). Data represent the mean with one S.E.M. from 4 to 6 experiments.*P < .05, unpaired Student's t test, compared with the responseat the same leukotriene D₄ concentration in control preparations.

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Fig. 8. Failure of acute capsaicin treatment to prevent protease inhibitor-induced potentiation of leukotriene D₄. Leukotriene D₄was administered in a cumulative manner to bronchial preparationsexposed previously to capsaicin (10 µM). Responses were obtainedin control preparations (open circles) and in preparations incubatedwith the protease inhibitors thiorphan (10 µM) and lisinopril(10 µM) (closed symbols) and were expressed as a percentage ofthe response to ACh (1 mM). Data represent the mean with one S.E.M.from eight experiments.

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Fig. 9. L-Cysteine treatment prevents protease inhibitor-induced potentiation of leukotriene D₄. Leukotriene D₄ was administered ina cumulative manner to bronchial preparations incubated with L-cysteine(3 mM) to prevent metabolism to leukotriene E₄. Responses wereobtained in control preparations (open circles) and in preparationsincubated with the protease inhibitors thiorphan (10 µM) and lisinopril(10 µM) (closed symbols) and were expressed as a percentage ofthe response to ACh (1 mM). Data represent the mean with one S.E.M.from five experiments.

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Fig. 10. Protease inhibition has no effect on leukotriene E₄-induced contractions. Leukotriene E₄ was administered in a cumulativemanner to control preparations (open circles) and to preparationsincubated with the protease inhibitors thiorphan (10 µM) and lisinopril(10 µM) (closed circles). Responses were expressed as a percentageof the response to ACh (1 mM). Data represent the mean with oneS.E.M. from six experiments.

	Discussion

Abstract Introduction Materials & Methods Results Discussion References

Leukotriene D₄ is a potent constrictor of airway smooth muscle. In the present study, leukotriene D₄ induced concentration-dependentcontraction in the guinea pig bronchus in the range 1 to 100 nM.The contractile actions of leukotriene D₄ on the airway smoothmuscle were thought to be mediated directly via a specific leukotrienereceptor (Mong et al., 1985). However, a more recent study hasimplicated an additional indirect mechanism that involves therelease of endogenous tachykinins, the contractile activity ofwhich reinforces or supplements leukotriene D₄ receptor-mediatedcontraction of the guinea pig trachea (Bloomquist and Kream, 1990).The tachykinins, substance P and neurokinin A, are localized inunmyelinated sensory nerves, afferent C-fibers, innervating theairways (Lundberg et al., 1984). A variety of stimuli are knownto activate C-fibers in the airways in vivo (Coleridge and Coleridge,1984), and many of these, including bradykinin, capsaicin andhistamine, elicit tachykinin release from guinea pig airways invitro (Saria et al., 1988; Martins et al., 1991). Given that tachykinins,such as substance P and neurokinin A, exert contractile effectson the guinea pig airway smooth muscle (Saria et al., 1988; Buckneret al., 1991), it is reasonable to expect that tachykinins releasedby contractile agonists contribute to the overall contractileresponse. The possible contribution of endogenous tachykininsto the manifestation of contractions elicited by leukotriene D₄was investigated because there is evidence linking this agonistto tachykinins or tachykinin-containing nerves (Stewart et al.,1984; Bloomquist and Kream, 1990; Martins et al., 1991). In thepresent study, we evaluated the role of tachykinins by pharmacologicallymodulating the concentrations of endogenous tachykinins withinguinea pig bronchus or by antagonizing neurokinin receptors thatmediate tachykinin effects. The guinea pig bronchus was chosenbecause it possesses a denser tachykininergic nervous innervationthan the guinea pig trachea (Manzini et al., 1989). The role oftachykinins in antigen-induced responses was also assessed, becausecontractions in the guinea pig airways are mediated primarilyby leukotrienes and histamine (Undem et al., 1989), two mediatorsthat have been shown to elicit the release of tachykinins (Sariaet al., 1988; Bloomquist and Kream, 1990; Martins et al., 1991).

Capsaicin administered acutely to guinea pig airway tissue results in the abolition of tachykinin-mediated nonadrenergic noncholinergicexcitatory responses induced by electrical field stimulation (Kizawaand Takayanagi, 1985; Thompson et al., 1987). This treatment hadno effect on the concentration-response relationships for antigen(ovalbumin) or leukotriene D₄, which suggests that endogenoustachykinins of C-fiber origin (or other agents subject to capsaicin-induceddepletion) do not contribute to the contractile responses elicitedby these agents. To evaluate more directly the contribution oftachykinins to ovalbumin- and leukotriene D₄-induced contractions,we examined the inhibitory effects of newer, more selective antagonistsof NK₁ (i.e., CP99994) and NK₂ (i.e., SR48968) receptors. In thesestudies, concentrations of CP99994 and SR48968 that abolishedneurally mediated tachykininergic responses failed to influencecontractions elicited by either ovalbumin or leukotriene D₄. Theseresults contrast with those obtained by Bloomquist and Kream (1990),wherein the substance P antagonist [D-Pro⁴, D-Trp^7,9]-substance P 4-11 was shown to inhibit leukotriene D₄-inducedcontractile responses in the guinea pig trachea. These variantresults may reflect a tissue-dependent difference in the roleof tachykinins in leukotriene D₄-induced contraction; Bloomquistand Kream utilized the trachea, whereas the present study wasconducted in the bronchus. However, the possibility that [D-Pro⁴, D-Trp^7,9]-substance P 4-11 acted as a leukotriene receptor antagonistwas not excluded by Bloomquist and Kream (1990). The lack of inhibitoryactivity of CP99994 and SR48968 on leukotriene D₄ responses excludedsuch a possibility in the present study.

The airway contractile actions of the tachykinins are modulated by tissue enzymes, including NEP and ACE, such that the potencyof the endogenously released or exogenously applied tachykininsare enhanced in preparations in which these enzymes are inhibited(Djokic et al., 1988; Thompson et al., 1989; Warner et al., 1990).Alterations in tissue expression of NEP or ACE also appear toregulate the biological activity of the tachykinins. For example,viral or cigarette smoke exposure enhances the airway smooth musclecontractile activity of endogenous and exogenous tachykinins bydown-regulating NEP expression (Dusser et al., 1989a,b). To enhancethe potential for tachykinin involvement in contractions, experimentswere repeated in the presence of thiorphan and lisinopril, inhibitorsof NEP and ACE, respectively. Initial studies verified that neurallymediated tachykininergic responses in the guinea pig bronchuswere enhanced by such treatment, as were contractile responsesinduced by substance P and neurokinin A (Thompson et al., 1989).In the presence of both of these inhibitors, leukotriene D₄ waspotentiated, which suggests that tachykinins released by leukotrieneD₄ contribute to the contractile response but normally do notdo so as a result of rapid degradation by tissue proteases. Itis notable that leukotriene D₄-induced responses were not affectedby the individual application of thiorphan or lisinopril. A similarrequirement for the combination of both inhibitors for enhancementof neurally mediated tachykininergic responses in the guinea pigbronchus has been noted previously (Thompson et al., 1989).

The potentiation of leukotriene D₄ by thiorphan and lisinopril provided circumstantial evidence in favor of a role for tachykinins.However, it is possible that other substances, such as calcitoningene-related peptide, were protected from proteolysis by theseinhibitors and contributed to the response (Martling et al., 1988;Tschirhart et al., 1990; Katayama et al., 1991). Accordingly,we further examined the role of neurally released tachykininsusing other pharmacological tools shown in initial experimentsto abolish neurally mediated tachykininergic responses. The potentiationof leukotriene D₄ was not prevented by either acute capsaicindesensitization or the selective neurokinin receptor antagonists,a result that argues strongly against tachykinins contributingto the enhancement of leukotriene D₄-induced responses by thiorphanand lisinopril. Clearly, had tachykinins been implicated in thepotentiation, these treatments would have prevented it, particularlywhen the concentrations used were sufficient to prevent neurallymediated tachykininergic responses and/or elicit a 57-fold rightwardshift of the substance P concentration-response curve. It shouldbe noted that prevention by acute capsaicin desensitization ofNEP inhibitor-induced enhancement of antigen-induced responseshas been used as evidence of tachykinin involvement in the guineapig bronchus (Kohrogi et al., 1991).

The enhancing action of thiorphan and lisinopril appeared specific for leukotriene D₄ because contractions induced by AChor antigen were unaffected by these inhibitors. In guinea pigairways, leukotriene D₄ can be metabolized to leukotriene E₄ byan aminopeptidase (Snyder et al., 1984; Aharony et al., 1985).This represents a bioinactivation step insofar as the contractilepotency of leukotriene D₄ in guinea pig airways is enhanced whenconversion to leukotriene E₄ is prevented by L-cysteine, an inhibitorof the aminopeptidase (Snyder et al., 1984; Snyder and Krell,1984). Inhibition of leukotriene D₄ metabolism by thiorphan andlisinopril could therefore underlie the observed potentiation.The present study reproduced the results of previous studies inthat L-cysteine potentiated leukotriene D₄ in the bronchus. Underthese conditions, however, thiorphan and lisinopril failed toaffect leukotriene D₄-induced contractions. L-Cysteine did notprevent the combination of thiorphan and lisinopril from enhancingsubstance P-induced contractions of the bronchus (data not shown),and this excludes the possibility that L-cysteine was interferingwith thiorphan or lisinopril in a physicochemical manner. Finally,leukotriene E₄-induced contractions were not altered by thiorphanand lisinopril, which makes it unlikely that the observed potentiationof leukotriene D₄ was due to protease inhibitor-induced potentiationof its metabolite, leukotriene E₄. Taken together, these resultsprovide evidence that potentiation of leukotriene D₄ in the guineapig bronchus involves inhibition of the conversion of leukotrieneD₄ to leukotriene E₄.

Leukotrienes mediate, at least in part, contractions elicited by antigen in sensitized guinea pig airways (Undem et al., 1989;Ro et al., 1991). Given the potentiating action of lisinopriland thiorphan on leukotriene D₄, a similar effect might have beenanticipated on antigen-induced responses. Indeed, NEP inhibitorshave been shown previously to enhance contractions induced bya single ovalbumin concentration (10 µg/ml) in sensitized guineapig bronchi (Kohrogi et al., 1991). In their studies, the NEPinhibitors, thiorphan and phosphoramidon, did not affect the peakof the antigen-induced contraction but rather augmented the waningphase of the antigen response, i.e., after attainment of the peakcontraction. In the present study, thiorphan and lisinopril hadno effect on contractions induced by the cumulative addition ofantigen. These differing results may be related to the means ofantigen application, i.e., single (Kohrogi and colleagues, 1991)vs. cumulative (present study) addition. However, cumulative additioninvolves the administration of an incrementally increasing antigenconcentration to an established antigen-induced contraction. Iftachykinins did contribute to maintenance of the antigen-inducedcontraction in the presence of NEP inhibitor, one would expectresponses in the cumulative curve to be increased, because subsequentantigen additions would be made to an augmented response. An alternativeexplanation for the disparate findings involves the importanceof leukotrienes in mediation of antigen-induced contractions inbronchi obtained from animals subjected to different sensitizationregimens. In the present study, tissues were obtained from animalssensitized to produce IgE and IgG₁ antibodies (Andersson, 1980).By contrast, Kohrogi and colleagues (1991) sensitized animalsusing higher antigen doses (milligram range), a procedure thatis likely to lead to the preferential development of IgG antibodies(Andersson, 1980). Antigen-induced leukotriene release is lowerfrom tracheae obtained from IgE-sensitized guinea pigs than fromthose obtained from IgG-sensitized guinea pigs, even though thecontractile responses do not differ substantially (Ro et al.,1991). The failure of L-cysteine to enhance the antigen-inducedcontraction in either IgE- or IgG₁-sensitized tissues (Ro et al.,1991) brings into question the importance of leukotriene D₄ (atleast) in mediation of these responses. The absence of an effectof thiorphan and lisinopril on antigen-induced contractions wouldbe consistent with the results of Ro and colleagues (1991) ifinhibition of metabolism underlies the enhancement of leukotrieneD₄ by these protease inhibitors.

Much interest has been shown in the possibility that an "axon reflex" exists in the airways such that stimulation of a nerveending in the tachykinin-containing C-fiber network results inthe spread of action potentials throughout the local C-fiber networkand causes the release of tachykinins from the C-fiber nerve endings,which could then induce bronchoconstriction (in addition to otherbiological actions) (Barnes, 1986). Tetrodotoxin is a nerve toxinthat abolishes action potentials by blockade of sodium channels(Catterall, 1980). In the present study, leukotriene D₄-inducedcontractions were unaffected by tetrodotoxin treatment, as wasthe potentiation of leukotriene D₄ by the protease inhibitors.In the guinea pig trachea, tetrodotoxin inhibited maximal contractileresponses induced by leukotriene D₄ (Bloomquist and Kream, 1990).It could be argued that the failure to identify such an effectin bronchi in the present study may be related to the use of insufficientconcentrations of leukotriene D₄ to elicit a maximal response.However, 0.1 µM leukotriene D₄ applied to L-cysteine-treated bronchiappeared to elicit a near-maximal contractile effect that wasnot affected by the protease inhibitors. If a tachykinin-dependent,tetrodoxin-sensitive component contributed to the contraction,protease inhibition would have been expected to augment the response.

In summary, the present results using more selective neurokinin antagonists argue that endogenous tachykinins do not contributeto contractions induced by antigen or leukotriene D₄ in the guineapig bronchus, a tissue that is well endowed with tachykinin-containingnerves.

	Acknowledgments

The authors wish to thank Dr. I. W. Rodger of Merck Frosst for the generous gift of CP99994 and SR48968, Dr. R. J. Altierefor constructive comments and Glenda Tate for technical assistance.

	Footnotes

Accepted for publication August 15, 1997.

Received for publication April 30, 1997.

¹ This work was supported by National Heart, Lung and Blood Institute Grant HL-47101.

Send reprint requests to: David C. Thompson, Ph.D., Department of Pharmaceutical Sciences, University of Colorado School of Pharmacy, 4200 East 9th Avenue, Denver, Colorado, 80262-0238.

	Abbreviations

KHS, Krebs-Henseleit solution; NEP, neutral endopeptidase; NK, neurokinin.

	References

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Absence of Tachykinin Involvement in Leukotriene D4 and Antigen-Induced Contraction of Guinea Pig Isolated Bronchus1

Absence of Tachykinin Involvement in Leukotriene D₄ and Antigen-Induced Contraction of Guinea Pig Isolated Bronchus¹