PC20 Adenosine 5'-Monophosphate Is More Closely Associated with Airway Inflammation in Asthma Than PC20 Methacholine

PC₂₀ Adenosine 5'-Monophosphate Is More Closely Associated with Airway Inflammation in Asthma Than PC₂₀ Methacholine

MAARTEN Van Den BERGE, RONALD J. MEIJER, HUIB A. M. KERSTJENS, DOROTHEA M. de REUS, GERARD H. KOËTER, HENK F. KAUFFMAN, and DIRKJE S. POSTMA

Departments of Pulmonology and Allergology, University Hospital Groningen, Groningen, The Netherlands

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Inhalation of a direct stimulus such as histamine or methacholine is generally used to measure bronchial hyperresponsiveness(BHR). Provocation with adenosine 5'-monophosphate (AMP), an indirectairway challenge, has been suggested to be a better marker ofairway inflammation than direct challenges. However, so far littleinformation on this subject is available. The aim of our studywas to assess whether the concentration of AMP causing the FEV₁to drop by 20% (PC₂₀) is more closely associated with inflammatoryparameters in asthma than PC₂₀ methacholine. In 120 patients withatopic asthma (median FEV₁ 81% predicted [pred], median age 27yr), PC₂₀ methacholine and PC₂₀ AMP as well as sputum induction,blood sampling, and measurement of nitric oxide in exhaled airwere performed. PC₂₀ methacholine was predominantly predictedby FEV₁ %pred (explained variance [ev] = 18%) with the percentageof peripheral blood monocytes being a weak additional independentpredictor (total ev = 23%). By contrast, PC₂₀ AMP was predominantlypredicted by the percentage of eosinophils in sputum (ev = 25%),while FEV₁ %pred was only an additional independent predictor(total ev = 36%). PC₂₀ AMP reflects more closely the extent ofairway inflammation due to asthma than PC₂₀methacholine.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Bronchial hyperresponsiveness (BHR) and airway inflammation are both characteristic features of asthma. Histamine and methacholine,stimuli that mainly act directly on airway smooth muscle, aregenerally used to measure the presence and severity of BHR. Althoughthe presence and severity of BHR are related to smooth musclecontraction, airway inflammation also contributes to BHR. Thereforeindirect stimuli that exert their effect on inflammatory cells,subsequently leading to smooth muscle contraction and edema, mayprovide additional information. Adenosine 5'-monophosphate (AMP)is such an indirect stimulus, as it has little effect on airwaysmooth muscle contraction in vitro (1). A major action of AMPappears to involve the release of histamine and other preformedmediators from "primed" mast cells, as AMP-induced bronchoconstrictionis associated with a rise of histamine in plasma and bronchoalveolarlavage fluid (2, 3). Moreover, the concentration of AMPcausing FEV₁ to drop by 20% (PC₂₀) is inhibited up to 80% by pretreatmentwith antihistamines (4). AMP may have some additional actionson neural pathways as the airway response is partially attenuatedby atropine and ipratropium bromide (5, 6).

Previous studies have shown that PC₂₀ AMP improves to a larger extent with the use of inhaled corticosteroids than PC₂₀ methacholine(7). Furthermore, in a study by Aalbers and colleagues theimprovement of BHR after a stay of 1 mo in a hypoallergenic environmentin Switzerland could be detected with AMP but not with methacholine(10). These findings suggest that PC₂₀ AMP is more closely associatedwith airway inflammation in patients with asthma than PC₂₀ methacholine.However, no formal study has investigated this hypothesis so farin the sense of actually collecting data on inflammation in sputumor airway wallbiopsy.

The aim of the present study was to investigate whether PC₂₀ AMP is more closely associated with airway inflammation comparedwith PC₂₀ methacholine. To this end, we tapered down inhaled corticosteroidsin a large group of 120 subjects with asthma. Thereafter, we assessedthe relationship between PC₂₀ methacholine as well as PC₂₀ AMPwith FEV₁ %predicted (pred) and inflammatory markers in sputum,blood, and exhaledair.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Patients

Patients with a diagnosis of asthma, 18-65 yr old, were included if they met the following criteria: PC₂₀ methacholine $=<$ 8mg/ml, at least one positive skin prick test out of 17 commonaeroallergens, reversibility to $beta$ ₂-agonist $>=$ 9% of the predictedFEV₁, and ability to expectorate sputum after hypertonic salineinhalation.

Study Design

Inhaled corticosteroids were tapered and when possible discontinued completely in 3 wk. Patients were asked to visit the hospitalon two consecutive days when they had discontinued their inhaledcorticosteroids completely for 3 wk, or earlier, if they experienced(subjective) symptoms of a pending asthma exacerbation for whichthey felt that treatment with corticosteroids was desirable. Onthe first day lung function, exhaled nitric oxide (NO), bloodsampling, and sputum induction were performed. On the second daybronchial hyperresponsiveness was measured by methacholine challengeand after 1 h a second challenge with AMP was done. The studyprotocol was approved by the local medical ethics committee andall participants gave their written informedconsent.

Exhaled Nitric Oxide

Exhaled nitric oxide (NO) was measured by tidal breathing as previously described by Alving and coworkers (11).

Lung Function

FEV₁ was measured with a calibrated water-sealed spirometer according to standardized guidelines as described previously (7).PC₂₀ methacholine followed by PC₂₀ AMP 1 h later were performedwith a 2-min tidal breathing method. Adenosine and methacholinewere prepared in 0.9% saline to produce a range of concentrationsfrom 0.04 to 320 mg /ml for adenosine and 0.038 to 8 mg/ml formethacholine.

Sputum Induction and Sputum Processing

Sputum was induced by inhalation of hypertonic saline aerosols as previously described (7). Fifteen minutes after salbutamol(200 µg) inhalation, hypertonic saline (3%, 4%, and 5%) was nebulizedfor each concentration during 7 min. Whole samples were processedaccording to the method of Fahy and coworkers with some modifications(7, 12).

Biochemical Assays

The concentrations of eosinophilic cationic protein (ECP) in serum and sputum were measured using a fluoroenzyme assay, theImmunoCAP ECP (provided by Pharmacia, Uppsala, Sweden). The concentrationof interleukin 8 (IL-8) in sputum was measured using an availableELISA kit (CLB,Amsterdam).

Statistical Methods

All calculations of PC₂₀ were performed with the base-2 logarithm (log₂) as this reflects doubling concentrations and normalizesthe distribution. Patients already responding to saline were assigneda PC₂₀ value half of the lowest concentration applied (13).Patients not responding to the highest concentration of methacholineor AMP were assigned a value twice the highest concentration applied.Normality of distributions was assessed using the Kolmogorov-Smirnovtest. If this test resulted in a p value < 0.05, normalizationby logarithmic transformation was attempted. Correlations betweenvariables were calculated by Pearson's correlation test in caseof normal distribution or by Spearman's correlations test otherwise.To determine independent prognostic factors of PC₂₀ methacholineand PC₂₀ AMP multiple regression analysis was employed, in thestepwise algorithm (SPSS PC⁺ 9.0). In this analysis, the use of corticosteroids (yes/no),and the number of days corticosteroids had been stopped at thetime of measurement were entered ascovariates.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Patient Characteristics

One hundred and twenty patients with mild to moderately severe asthma were enrolled in the study. Baseline characteristicsare presented in Table 1. In this study, it was aimed for thatpatients completely discontinued their inhaled corticosteroidsfor at least 3 wk. During the steroid tapering period, 16 patientsreturned to the hospital earlier due to symptoms of a pendingasthma exacerbation. From these 16 patients, 6 patients stillused inhaled corticosteroids (3 patients 400 µg/d budesonide orbeclomethasone, 2 patients 250 µg/d fluticasone, and 1 patient800 µg/d budesonide). The remaining 10 patients had not used inhaledcorticosteroids for a median period of 12 d (range 2-21 d). Itwas not possible to measure the PC₂₀ AMP in all patients, dueto asthma symptoms and low FEV₁ (the lowest FEV₁ was 15 %pred).Thus, we were able to measure PC₂₀ AMP in 114 (95%) patients,respectively. All patients were, by design, responsive to methacholine(PC₂₀ $=<$ 8 mg /ml), whereas 102 of the 114 (89%) patients wereresponsive to AMP (PC₂₀ $=<$ 320 mg/ml). Of the 16 patients who returnedto the hospital before they had completely discontinued theirinhaled corticosteroids for at least 3 wk, the PC₂₀ AMP couldnot be measured in 2 patients, 13 patients were responsive toAMP, and 1 patient was not responsive to AMP.

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TABLE 1

CHARACTERISTICS AND CELL COUNT DATA OF THE STUDY POPULATION (n = 120)^*

Individual Correlations of PC₂₀ Methacholine and PC₂₀ AMP with Clinical and Inflammatory Parameters

A high correlation for both PC₂₀ methacholine and PC₂₀ AMP was found with FEV₁ %pred, correlations being very comparable (r= 0.45, p < 0.01, and r = 0.43, p < 0.01 respectively) (Table2 and Figure 1). There was an inverse correlation between percentageof sputum eosinophils and PC₂₀ methacholine as well as PC₂₀ AMP,the correlation being stronger with PC₂₀ AMP ( $rho$ = $-$ 0.49, p < 0.01)than with PC₂₀ methacholine ( $rho$ = $-$ 0.29, p < 0.01) (Figure 2).Furthermore PC₂₀ methacholine was significantly correlated withthe percentage of lymphocytes and ECP per eosinophil in sputum,whereas PC₂₀ AMP significantly correlated with ECP per eosinophilin sputum, ECP in sputum, number of eosinophils in blood, andECP in blood.

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TABLE 2

CORRELATION OF CLINICAL AND INFLAMMATORY PARAMETERS WITH PC₂₀ METHACHOLINE AND PC₂₀ AMP

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Figure 1. Unadjusted relationship between PC₂₀ methacholine and PC₂₀ AMP with the level of FEV₁, %pred.

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Figure 2. Unadjusted relationship between PC₂₀ methacholine and PC₂₀ AMP with the percentage of sputum eosinophils.

Independent Correlates of PC₂₀ Methacholine and PC₂₀ AMP in a Multiple Linear Regression Model

In a multiple linear stepwise regression model, PC₂₀ methacholine was predominantly predicted by FEV₁ %pred, whereas the numberof peripheral blood monocytes was an independent additional predictor(Table 3). In contrast, PC₂₀ AMP was predominantly predictedby the percentage eosinophils in sputum, whereas FEV₁ %pred wasan additional independent predictor for the level of PC₂₀ AMP.The total percentage explained variance was larger for PC₂₀ AMP(36%) than for PC₂₀ methacholine (23%). When the use of corticosteroids(yes/no) and the number of days corticosteroids had been stoppedat the time of measurement were entered as covariates, their regressioncoefficients were not significant.

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TABLE 3

MULTIPLE LINEAR REGRESSION MODELS FOR PC₂₀ METHACHOLINE AND PC₂₀ AMP^*

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

This study in a large group of patients with asthma demonstrates that the levels of PC₂₀ methacholine and PC₂₀ AMP are bothassociated with baseline level of FEV₁ %pred. PC₂₀ AMP providesa better reflection of airway inflammation than PC₂₀ methacholine,as the percentage of sputum eosinophils does explain 25% of thevariance in PC₂₀ AMP but is not a significant independent predictorfor PC₂₀ methacholine. These results were independent of whetherpatients were still using inhaled corticosteroids at the timeofmeasurement.

A positive association between the severity of bronchial hyperresponsiveness and the level of FEV₁ has been observed before(14). It can be explained by the fact that a given stimuluswill result in a larger bronchoconstrictor response in a subjectwith more severe airway obstruction than in a subject with lesssevere obstruction, resulting in a lower provocative concentrationof the stimulus under study causing a 20% reduction in FEV₁ (15).Thus, it was expected that both the severity of PC₂₀ methacholineand PC₂₀ AMP would be associated with the level of FEV₁ %pred.

The observed association between more severe bronchial hyperresponsiveness to both PC₂₀ methacholine and PC₂₀ AMP and moreextensive airway inflammation, that is, the percentage of eosinophilsin sputum, was to be expected. Worsening of asthma following viralinfection or antigen exposure is associated with an increase inbronchial hyperresponsiveness and in case of experimental rhinovirusaccompanied by an increase in sputum eosinophils and ECP (18,19). Furthermore, bronchial hyperresponsiveness and sputum eosinophiliaimprove after therapy with inhaled corticosteroids (7). Activationof different inflammatory cells leads to airway wall edema witha concomitant increase in airway wall thickness. In addition,smooth muscle cells become more sensitive to contracting stimuli,all contributing to an increase in bronchial responsiveness (20,21).

In our study, we found a dichotomy in the factors explaining the severity of PC₂₀ methacholine and PC₂₀ AMP. The level ofFEV₁ %pred was the most important explanatory factor for the severityof PC₂₀ methacholine. Although the level of FEV₁ %pred was alsoa significant factor in explaining the severity of PC₂₀ AMP, greatercontribution was derived from the percentage of sputum eosinophils.Therefore PC₂₀ AMP, which acts indirectly via the release of mediatorsfrom primed mast cells, reflects to a larger extent the cellularactivation state in asthma than PC₂₀ methacholine. There are twopossible explanations for the finding that PC₂₀ AMP is more closelyassociated with eosinophilic airway inflammation than PC₂₀ methacholine.First, an increased number of eosinophils may reflect an overallincreased inflammatory activity resulting in an increased productionof cytokines that stimulate mast cell chemotaxis, maturation,or activation directly or indirectly (22). Second, it can bespeculated that the exposure to aeroallergens in subjects withallergy activates mast cells through immunoglobulin E (IgE)-dependentpathways resulting in the release of mediators that are responsiblefor an influx of eosinophils in sputum. We hypothesize that iftryptase or another marker of mast cell activity was to be measurablein sputum or blood, a closer association might be demonstrablefor PC₂₀ AMP with sputum tryptase than for PC₂₀ AMP with the percentageof sputumeosinophils.

Polosa and colleagues recently reported an association between the number of eosinophils in sputum and PC₂₀ AMP, but not PC₂₀methacholine in 12 subjects with allergic rhinitis in whom thediagnosis of asthma was specifically excluded (23). Althoughasthma and allergic rhinitis may be different diseases, patientswith allergic rhinitis without clinical evidence of asthma havebeen shown to exhibit airway inflammation as reflected by an increaseof eosinophils in sputum (24). Thus, the data of Polosa andcoworkers (23) are compatible with ours. We extended their observationin two ways. First, we measured sputum ECP and showed in a simpleregression that activation of eosinophils, as measured by ECP,was associated with more severe responsiveness to AMP but notto methacholine. This did not, however, contribute significantlyin the multiple regression analysis. Multiple regression was notperformed by Polosa and coworkers. The current analysis for thefirst time clearly showed that PC₂₀ AMP is more closely associatedwith eosinophils in sputum than PC₂₀methacholine.

The observation that a lower number of peripheral blood monocytes is independently associated with more severe responsivenessto methacholine was not expected. In a previous study, Sont andcoworkers also found an association between peripheral blood monocytesand bronchial hyperresponsiveness to hypertonic saline (25).It has been suggested that peripheral blood monocytes may playa role in immune responses (26). To date, however, relativelylittle is known about the modulatory role of peripheral bloodmonocytes in airway inflammation. Therefore this finding is ofinterest and merits furtherinvestigation.

In our study, PC₂₀ AMP but not PC₂₀ methacholine was associated equally strongly with the number of peripheral blood eosinophilsand with the concentration of ECP in serum. Peripheral blood eosinophilshave been shown to be associated with the severity of symptoms,the level of FEV₁, and bronchial hyperresponsiveness to methacholineand histamine (27- 30). Furthermore, serum ECP has been shownto reflect the degree of eosinophil activation (31). Thus, ithas been suggested that both peripheral blood eosinophils andserum ECP may be indirect markers of airway inflammation in asthma(24). However, both the number of peripheral blood eosinophilsand the concentration of ECP in serum did not contribute to abetter prediction of PC₂₀ AMP in multiple regression analysis.The probable explanation for this finding is that the percentageof eosinophils in sputum, the number of peripheral blood eosinophils,and serum ECP provide overlapping information about the inflammatoryactivation state inasthma.

Finally, we did not find exhaled NO to be related to either PC₂₀ methacholine or PC₂₀ AMP. It has been suggested that theconcentration of exhaled NO reflects airway inflammation. Patientswith asthma have a higher concentration of exhaled NO comparedwith normal individuals, which is reduced after treatment withcorticosteroids. However, the direct association between the concentrationof exhaled NO and airway inflammation as reflected by the numberof eosinophils in bronchial biopsies or sputum has been a matterof controversy (32, 33). Therefore, the absence of an associationbetween the concentration of exhaled NO and PC₂₀ AMP does notexclude PC₂₀ AMP as a marker of airwayinflammation.

In conclusion, the results of this study show for the first time that PC₂₀ AMP is more closely associated with airway inflammationthan PC₂₀ methacholine. Therefore, PC₂₀ AMP provides both cliniciansand researchers with a noninvasive marker of disease activity.Further studies have to assess whether reduction of airway wallinflammation in asthma (e.g., by corticosteroids) is also moreclosely associated with improvement in PC₂₀ AMP than PC₂₀methacholine.

	Footnotes

Correspondence and requests for reprints should be addressed to D.S. Postma, M.D, Ph.D., Department of Pulmonary Diseases, University Hospital Groningen, Hanzeplein 1, 9700 RB, Groningen, The Netherlands. E-mail: D.S.Postma{at}int.azg.nl

(Received in original form October 26, 2000 and in revised form February 2, 2001).

Acknowledgments: The authors thank Pharmacia Uppsala for generously providing the kits for ECP determination and B. Dijkhuizen and J. Zonderlandfor their laboratoryassistance.

This study was supported by grants from the University of Groningen, the University Hospital of Groningen, and fromGlaxowellcome.

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Repeated Dosing Effects of Mediator Antagonists in Inhaled Corticosteroid-Treated Atopic Asthmatic Patients
Chest, April 1, 2004; 125(4): 1372 - 1377.
[Abstract] [Full Text] [PDF]

J. Joseph-Bowen, N. H. de Klerk, M. J. Firth, G. E. Kendall, P. G. Holt, and P. D. Sly
Lung Function, Bronchial Responsiveness, and Asthma in a Community Cohort of 6-Year-Old Children
Am. J. Respir. Crit. Care Med., April 1, 2004; 169(7): 850 - 854.
[Abstract] [Full Text] [PDF]

L. Prieto, L. Bruno, V. Gutierrez, S. Uixera, C. Perez-Frances, A. Lanuza, and A. Ferrer
Airway Responsiveness to Adenosine 5'-Monophosphate and Exhaled Nitric Oxide Measurements: Predictive Value as Markers for Reducing the Dose of Inhaled Corticosteroids in Asthmatic Subjects
Chest, October 1, 2003; 124(4): 1325 - 1333.
[Abstract] [Full Text] [PDF]

W M A J Miesen, S van der Heide, H A M Kerstjens, A E J Dubois, and J G R de Monchy
Occupational asthma due to IgE mediated allergy to the flower Molucella laevis (Bells of Ireland)
Occup. Environ. Med., September 1, 2003; 60(9): 701 - 703.
[Abstract] [Full Text] [PDF]

G.F. Joos and B. O'Connor
Indirect airway challenges
Eur. Respir. J., June 1, 2003; 21(6): 1050 - 1068.
[Abstract] [Full Text] [PDF]

G. P. Currie, D. K. C. Lee, K. Haggart, C. E. Bates, and B. J. Lipworth
Effects of Montelukast on Surrogate Inflammatory Markers in Corticosteroid-treated Patients with Asthma
Am. J. Respir. Crit. Care Med., May 1, 2003; 167(9): 1232 - 1238.
[Abstract] [Full Text] [PDF]

A.M. Landstra, H.M. Boezen, D.S. Postma, and W.M.C. van Aalderen
Effect of intravenous hydrocortisone on nocturnal airflow limitation in childhood asthma
Eur. Respir. J., April 1, 2003; 21(4): 627 - 632.
[Abstract] [Full Text] [PDF]

J. W. Ramsdell
Adenosine Airways Responsiveness: What Does It Mean?
Chest, April 1, 2003; 123(4): 971 - 973.
[Full Text] [PDF]

L. Prieto, V. Gutierrez, S. Uixera, and J. M. Berto
Effect of Cigarette Smoking on Airway Responsiveness to Adenosine 5'-Monophosphate in Subjects With Allergic Rhinitis
Chest, April 1, 2003; 123(4): 993 - 997.
[Abstract] [Full Text] [PDF]

M. van den Berge, H.A.M. Kerstjens, D.M. de Reus, H.F. Kauffman, G.H. Koeter, and D.S. Postma
Provocation With Adenosine 5'-Monophosphate Increases Sputum Eosinophils
Chest, March 1, 2003; 123(2007): 417S - 417S.
[Full Text] [PDF]

G. P. Currie and B. J. Lipworth
Bronchoprotective Effects of Leukotriene Receptor Antagonists in Asthma* : A Meta-analysis
Chest, July 1, 2002; 122(1): 146 - 150.
[Abstract] [Full Text] [PDF]

R Polosa, S Rorke, and S T Holgate
Evolving concepts on the value of adenosine hyperresponsiveness in asthma and chronic obstructive pulmonary disease
Thorax, July 1, 2002; 57(7): 649 - 654.
[Abstract] [Full Text] [PDF]

L. Prieto, V. Gutierrez, and S. Uixera
Exhaled Nitric Oxide and Bronchial Responsiveness to Adenosine 5'-Monophosphate in Subjects With Allergic Rhinitis*
Chest, June 1, 2002; 121(6): 1853 - 1859.
[Abstract] [Full Text] [PDF]

R. Polosa, M. van den Berge, H. A. M. Kerstjens, and D. S. Postma
ADENOSINE MONOPHOSPHATE CHALLENGE AND MONITORING OF AIRWAY RESPONSE TO ANTIINFLAMMATORY THERAPY
Am. J. Respir. Crit. Care Med., May 1, 2002; 165(9): 1336 - 1336.
[Full Text] [PDF]

S Chinn
Comparing and combining studies of bronchial responsiveness
Thorax, May 1, 2002; 57(5): 393 - 395.
[Abstract] [Full Text] [PDF]

M. J. TOBIN
Asthma, Airway Biology, and Nasal Disorders in AJRCCM 2001
Am. J. Respir. Crit. Care Med., March 1, 2002; 165(5): 598 - 618.
[Full Text] [PDF]

P. Zanen, M. Van Den Berge, H. A. M. Kerstjens, and D. S. Postma
PC20 ADENOSINE 5'-MONOPHOSPHATE IS MORE CLOSELY ASSOCIATED WITH AIRWAY INFLAMMATION IN ASTHMA THAN PC20 METHACHOLINE
Am. J. Respir. Crit. Care Med., March 1, 2002; 165(5): 730a - 730.
[Full Text] [PDF]

S. T. Holgate
Adenosine Provocation: A New Test for Allergic Type Airway Inflammation
Am. J. Respir. Crit. Care Med., February 1, 2002; 165(3): 317 - 318.
[Full Text] [PDF]