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Neutrophil survival is prolonged in the airways of healthy infants and infants with RSV bronchiolitis

¹ University Institute of Child Health, Division of Clinical Sciences (S) and ² Dept of Respiratory Medicine, Sheffield Children's Hospital, Western Bank, Sheffield, UK

CORRESPONDENCE: M.L. Everard, Dept Respiratory Medicine, Sheffield Children's Hospital, Western Bank, Sheffield, S10 2TH, UK. Fax: 44 1142730522. E-mail: m.l.everard@sheffield.ac.uk

Keywords: apoptosis, neutrophil, respiratory syncytial virus

Received: September 7, 2001
Accepted February 21, 2002

This study was partly funded by the Sheffield Hospital Children's Fund and The Action Laboratory Charity.

	Abstract

TOP Abstract Materials and methods Results Discussion Acknowledgements References

 
Large numbers of neutrophils in the airway of infants infected by respiratory syncytial virus (RSV) are recruited by chemokines, such as interleukin-8, and specific inflammatory molecules can delay apoptosis increasing their longevity. The aim of this study was to investigate whether airway secretions in RSV bronchiolitis contain factors that influence neutrophil apoptosis.

Nasal lavage fluid (NLF) was obtained from 24 infants with RSV bronchiolitis (31 infant controls and 12 adults). Neutrophils isolated from healthy adult volunteers were incubated with the NLF in Dulbecco modified Eagle medium (DMEM) for 24 h, and apoptosis and necrosis were quantified using Hoechst 33342 and propidium iodide viability dyes. The presence of putative factors that delay neutrophil apoptosis was investigated using inhibitors to leukotriene-B₄, lipopolysaccharide and the IL-8 receptor CXCR2, and blocking antibodies to granulocyte-monocyte colony-stimulating factor. Characterisation of NLF involved tests of thermal instability, proteolysis, deoxyribonuclease digestion and molecular filtration.

NLF from infants with RSV bronchiolitis and controls significantly delayed neutrophil apoptosis, whereas NLF from healthy adults did not. None of these inhibitor molecules blocked this delay in apoptosis but activity was heat liable and >3 kDa.

The study showed that nasal lavage fluid from infants significantly delays neutrophil apoptosis. The speculation is that the prolonged survival of neutrophils in the infant airway contributes to the characteristic accumulation of neutrophils in the airways of infants with respiratory infections.

Respiratory syncytial virus (RSV) is responsible for annual epidemics of respiratory disease affecting the whole population 1–3 and particularly infants of whom the majority are infected during their first winter 1, 4, 5. Of these, 20–30% develop lower respiratory tract symptoms and 0.5–2% are hospitalised with RSV bronchiolitis 1, 2, 4, 5. It is increasingly recognised that RSV is a major cause of respiratory morbidity in the elderly 6, 7. Several prospective studies have also indicated that lower respiratory tract RSV infections in hospitalised 8 and nonhospitalised 9 infants, result in an excess of recurrent lower respiratory tract symptoms in subsequent years. These symptoms decline progressively over the first decade of life but the cause for this excess morbidity remains unclear 10.

There has been much speculation regarding the nature of the host/virus interaction 3, 11 and more than 30 yrs ago it was proposed that RSV bronchiolitis is a consequence of a specific immunopathology. Despite much research to demonstrate this, no distinct immunopathological process has been identified. The current authors have shown that neutrophils are the predominant inflammatory cell in the upper and lower airway in RSV infections in infants, accounting for 80% of cells recovered from the tracts 12. These finding have been subsequently replicated by others 13. Increased protease activity in airway secretions from these infants, with neutrophil elastase (NE) accounting for most of this protease activity 14, and the presence of degraded fibronectin in the lavage samples have also been demonstrated 15. NE may play a role in the genesis of recurrent symptoms by directly damaging the immature airway, inducing airways hyperreactivity and inducing glandular and goblet cell hyperplasia 16. The role of neutrophils in virus clearance, if any, is unclear.

Neutrophil accumulation within the airway can be influenced by their rate of migration and longevity. Interleukin (IL)-8 is a major chemokine for neutrophils in this condition and RSV infection stimulates IL-8 release from various cells in vitro, including epithelial cells, macrophages, and neutrophils 17, 18. The current authors have reported elevated IL-8 in nasal lavage fluid (NLF) from babies with acute RSV bronchiolitis 19. There may also be a correlation between disease severity and IL-8 concentration 20, although it is unclear whether the IL-8 levels reflect or contribute to disease severity. Neutrophil lifespan is regulated by apoptosis 21. Apoptotic neutrophils can be phagocytosed by resident macrophages via the vitronectin or phosphatidylserine receptor 22, therefore limiting the release of harmful neutrophil products into the airways, which would occur if the neutrophils died by necrosis. A number of factors likely to be present in airway secretion of infants with RSV bronchiolitis, such as IL-8, leukotriene-B₄ (LTB₄) and granulocyte-monocyte colony-stimulating factor (GM-CSF), inhibit neutrophil apoptosis 21, 23, thereby prolonging cell survival. A previous group studying neutrophils recovered from the airways of infants with RSV bronchiolitis have suggested that neutrophil apoptosis may be accelerated in this condition 24. However, this study assessed the rate of apoptosis in neutrophils already resident in the airways for an unknown duration and compared this to the survival of circulating neutrophils. Without knowing how long these neutrophils have been resident in the airways it is difficult to determine whether their survival has been shortened or prolonged.

The aim of this study was to determine whether factors released into the airway secretions of infants with RSV bronchiolitis influence the rate of apoptosis of neutrophils. Additional studies were performed in an attempt to identify factor(s) that may be responsible for these effects.

	Materials and methods

TOP Abstract Materials and methods Results Discussion Acknowledgements References

 
Subjects
NLF was obtained from infants hospitalised with RSV bronchiolitis (RSV-NLF), who were confirmed positive for RSV by indirect immunofluorescence on nasopharyngeal aspirates before they were recruited. NLF was also obtained from healthy infants and adults. The healthy infants were recruited at routine "well-baby clinics" having no past history of respiratory or other clinical illness at the time of sampling. Parents were contacted 2–3 days later to ensure that these infants were not incubating a respiratory illness at the time of sampling. The adults were healthy volunteers with no history of respiratory problems.

Ethical approval (South Sheffield Ethics Committee, Sheffield, UK) and informed consent was obtained from the parents of the infants and from the adult volunteers.

Collection and processing of nasal lavage fluid
NLF was collected as described by Noah et al. 25, by introducing 5 mL sterile isotonic saline into one nostril while holding the infant's head tilted to the opposite side. The saline drained into the opposite nostril and was collected in a container. The process was then repeated for the opposite nostril. The 10 mL of NLF were pooled, centrifuged at 875xg for 5 min at 4°C, and stored in aliquots at –70°C. The protein concentration of each NLF sample from both the infants and adults was determined using a sensitive Bicinchoninic acid protein assay (BCA assay; Pierce, IL, USA).

Isolation of neutrophils
Neutrophils were isolated from the peripheral whole blood of healthy adult volunteers as described by Smith et al. 26, layered on Histopaque-1077 (Sigma Chemical Company Ltd, Poole, UK) and centrifuged. Pelleted cells were collected and washed in endotoxin-free phosphate buffered saline (BioWhittaker, MD, USA). The erythrocytes were then lysed in ammonium chloride solution, and the neutrophils were centrifuged at 160xg for 8 min to pellet.

The viability of the neutrophil preparation was routinely >95% and purity, as assessed by automated haemocytometer analysis, was >95%, with the total yield varying between 0.75–1.5x10⁶·mL^–1 of blood for these donors.

Incubation of neutrophils with nasal lavage fluid
The purified neutrophils were resuspended at 1x10⁶·mL^–1 in Dulbecco modified Eagle medium (DMEM; Sigma Chemical Company Ltd) with 2 mM glutamine and 100 µg·mL^–1 penicillin and 50 µg·mL^–1 streptomycin (termed DMEM-AP). Some of these neutrophils were resuspended in 20% autologous plasma (removed at the time of centrifugation). The antibiotics were also added to the NLF samples.

The authors seeded 1x10⁵ neutrophils in 100 µL aliquots into wells of a 96-well tissue culture dish (Corning Costar Ltd, High-Wycombe, UK) in triplicate for each sample/treatment, added a further 100 µL of neat, diluted, or treated NLF and gently mixed the contents. The viability of the neutrophils was measured in 200 µL of DMEM-AP in each experiment. The cells were incubated at 37°C in a humidified 95% air, 5% carbon dioxide in an incubator (Sanyo, Osaka, Japan) for 24 h.

Assessment of neutrophil viability
After 24-h incubation at 37°C, neutrophils were stained with 8 µM Hoechst 33342 (Sigma Chemical Company Ltd) and 5 µM propidium iodide (Molecular Probes, Cambridge Biochemicals, Cambridge, UK) for 15 min at 37°C. They were then examined without further manipulation using a fluorescent inverted Leica DMIRB microscope (Leica, Wetzlar, Germany). The morphology and characteristics of the viable and apoptotic cells (Hoechst stained) and necrotic cells (propidium iodide stained) are shown in figures 1a and b. Both fluorescent dyes were visible under the ultraviolet filter and could be counted simultaneously. The incidence of viable, apoptotic and necrotic cells was obtained by counting using a Whipple graticule in five separate random grid areas in each of three wells for each treatment.

View larger version (56K): [in this window] [in a new window]   Fig. 1.— Viable (V), apoptotic (A), and necrotic (N) donor neutrophils stained with fluorescent deoxyribonucleic acid binding dyes Hoechst 33342 (Sigma Chemical Company Ltd) and propidium iodide (Molecular Probes, Cambridge Biochemical). Freshly isolated neutrophils a) after 3 h in culture without nasal lavage fluid (NLF), b) after 24 h in medium culture without NLF and c) after 24 h in medium with 50:50 dilution of NLF obtained from infants hospitalised with respiratory syncytial virus bronchiolitis. Scale bars=25 µM.

To determine whether the activity affecting apoptosis was labile, RSV-NLF (n=5) was frozen in liquid nitrogen and thawed in five repeated cycles. RSV-NLF (n=5) was also heated to 90°C for 15 min, cooled, and then used in the viability assay.

Bacterial deoxyribonucleic acid (DNA) has potential pro-inflammatory properties but degraded host DNA is reported to have immunosuppressive actions 27. To determine whether DNA released from damaged respiratory tract cells affected neutrophil apoptosis, pooled RSV-NLF (n=5) was digested for 2 h at 37°C with 500 µg·mL^–1 deoxyribonuclease (DNAse) type I (Sigma Chemicals Ltd). The degradative activity of the DNAse was confirmed using calf sperm DNA under similar conditions and demonstrating smearing following separation on 1% agarose gels stained with ethidium bromide.

RSV-NLF (n=5) was subjected to limited digestion in 0.5% bovine trypsin (Sigma Chemical Company Ltd) for 2 h at 37°C to investigate the role of proteins in the NLF. The trypsin activity was stopped with 100 µg·mL^–1 of Soybean trypsin inhibitor (Sigma Chemical Company Ltd). Limited proteolysis was confirmed by examining the digested NLF on a 10% sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE) gels stained with silver. Controls included the addition of the trypsin and soya bean trypsin inhibitor complex but with no NLF.

To determine whether NLF contained low molecular weight activity, 0.5 mL samples of RSV-NLF were subjected to centrifugal filtration using 3 K molecular weight Centricon cut-off filters (Amicon, Millipore Inc., Bedford, MA, USA). The volumes of the filtrate and retentate were accurately measured and both made up to 500 µL using sterile saline solution. Five-hundred µL of unfiltered NLF was also diluted by an equivalent amount using sterile saline. The filtrate, retentate and unfiltered NLF were then incubated with the neutrophils.

Characterisation of LTB₄, IL-8, GM-CSF, and LPS activity in the NLF samples
These factors have been reported to delay neutrophil apoptosis in experimental models 21, 23 and were examined for their contribution to the activity of NLF.

The leukotriene LTB₄ inhibitor VML 295 (LY29311; gift from G. Parker, Vanguard Medica, Surrey, UK) was dissolved in dimethyl sulfoxide (DMSO). VML 295 (10 µM and 100 µM) was dissolved in pooled and individual NLF samples and then added to the neutrophils.

SB-237844 (gift from S. Sarau, SmithKline Beecham, King of Prussia, USA), a competitive antagonist of the CXCR2 IL-8 receptor, was dissolved in DMSO and added to the neutrophils from 10–0.05 µM for 5 min before the addition of pooled and individual sample NLF.

The lipopolysaccharide (LPS) inhibitor Polymyxin-B was added at 1–100 µg·mL^–1 to the neutrophils for 5 min before the addition of pooled or individual NLF samples. The effect of Polymyxin-B was confirmed by its inhibition of 10 µg·mL^–1 Escherichia coli LPS (serotype 0.26:B6; Sigma Chemical Company Ltd), which was shown to significantly delay the rate of neutrophil apoptosis.

To block the cytokine GM-CSF, 10 µg·mL^–1, 50 µg·mL^–1 and 100 µg·mL^–1 of a blocking goat immunoglobulin (Ig) G antihuman GM-CSF (R&D Systems, Cambridge Biochemical, Cambridge, UK) was incubated with pooled or individual NLF for 30 min at 37°C. The NLF antibody mixture was then added to the neutrophils. Controls for these inhibition experiments included equivalent dilutions of solvents used for some of the compounds and nonimmune goat IgG at similar dilutions as for the GM-CSF blocking experiments.

Statistical analysis of data
Differences between and within groups were analysed by nonparametric Mann-Whitney U-test and by Kruskal-Wallis nonparametric tests, respectively. The relationship between the level of apoptosis and protein content of the nasal lavage samples was examined by the Spearman correlation coefficient. Significant differences were taken at p<0.05. The data is shown in the text as the mean±95% confidence limits.

	Results

TOP Abstract Materials and methods Results Discussion Acknowledgements References

 
Subjects
Twenty-four infants admitted to hospital with RSV bronchiolitis were recruited with a median age of 120 days (range 33–242) and samples were obtained at a median of 3 days after onset of symptoms (range 1–4). Control samples were obtained from 31 infants (median age 149 days (range 19–433)) and 12 adults (median age 38 yrs (range 21–48)) with no symptomatic evidence of airway infection. Thirty-three per cent of the infants with bronchiolitis and 27% of infant controls were passively exposed to smoke. None of the adults were smokers.

Nasal lavage fluid protein content
The median protein concentration of the NLF samples from the infants with RSV bronchiolitis was 55.9 µg·mL^–1 (range 7.6–386.5). The value for infant controls was 62.3 µg·mL^–1 (19.9–212.0 range) and the value for adult controls was 19.5 µg·mL^–1 (3.1–53.1 range), and they were significantly lower (p<0.001) than the two infant groups.

Effect of nasal lavage fluid on neutrophil survival
Neutrophils were incubated in medium alone or with RSV-NLF, control infants' NLF and healthy adults' NLF, and after 24-h changes to cell viability were determined. The mean amount of viable cells in the medium alone was 27.5% (±3.3), with 49.3% of the cells being apoptotic (±3.1) and 23.4% being necrotic (±3.5), as shown in figure 2a. Following the addition of RSV-NLF, there was a significant increase to 77.5% (±3.3) viable cells, and a decrease to 19.5% apoptotic (±2.9) and 3.0% necrotic (±0.9), compared to medium alone (fig. 2b). These changes were also seen in the neutrophils incubated in the NLF from the infant controls, where 76.3% (±5.3) of cells were viable, 20.4% (±3.3) apoptotic and 3.3% (±1.4) necrotic, compared to the medium alone (fig. 2c). However, when incubated in NLF from adults, the patterns were comparable to cells in medium alone, with 33.2% (±2.1) of cells viable, 54.5% (±2.2) apoptotic, and a small but significant decrease to 12.1% (±1.6) necrotic cells (fig. 2d).

View larger version (13K): [in this window] [in a new window]   Fig. 2.— Measurement of the percentage of viable, apoptotic and necrotic neutrophils in Dulbecco modified Eagle medium after 24 h of incubation at 37°C. a) Medium only (n=13). b) Nasal lavage fluid (NLF) obtained from infants hospitalised with respiratory syncytial virus bronchiolitis (RSV-NLF) (n=25 samples). c) Infant control NLF (n=19 samples). d) Adult control NLF (n=18 samples). Each sample data point is shown with the median (thick bars) and 95% confidence limits (thin bars) shown for each data set. Each cell count (viable, apoptotic and necrotic) for each sample group (RSV-NLF, infant NLF and adult NLF) was compared to cells grown in medium alone. **: p<0.01, obtained by Mann-Whitney tests.

Repeated freeze thawing of the samples did not change the capacity of RSV-NLF to delay neutrophil apoptosis.

DNAse digestion
Treatment of pooled (n=5) RSV-NLF samples with DNAse did not reduce the anti-apoptotic effects compared to nontreated RSV-NLF (91.2% (±7.0) versus 89.2% (±8.7) viable cells).

Diafiltration
Pooled RSV-NLF (n=5) was subjected to diafiltration using an 3 kDa cut-off pore membrane to establish whether there were low molecular weight constituents of NLF, such as ions, that influenced the rate of apoptosis. The filtrate from the RSV-NLF did not increase the viability of the neutrophils (6.3% (±6.0)), suggesting that the apoptosis inhibiting activity was >3 kDa. The RSV-NLF above the filter supported an increase in neutrophil viability (38.8% (±24.1)) compared to medium alone (17% (±3.6)), but was less active than the unfiltered NLF (viability of 91% (±8.0)).

Effects of blocking LTB₄, GM-CSF, LPS and IL-8
In all of these experiments, a concentration range consistent with effective activity but minimal toxicity was first determined by adding these agents to neutrophils incubated in medium alone.

LTB₄ inhibitor
No decrease in the viability of neutrophils was seen when the LTB₄ inhibitor was added to pooled (n=8) RSV-NLF at 10 µM (79.2% (±8.3)) or 100 µM (85.4% (±13.5)), compared to the effect of the sample alone (74.3% (±16.5)).

GM-CSF inhibitor
A nonsignificant increase in the viability (81.0% (±14.2)) of neutrophils was seen when 100 µg·mL^–1 of the blocking antibody to GM-CSF was added to RSV-NLF (n=8), compared to RSV-NLF alone (72% (±22.1)). No significant differences were observed using the antibody at other concentrations. Nonimmune goat IgG at equivalent concentration also had no affect upon the levels of viability in RSV-NLF.

Polymixin B
LPS (10 µg·mL^–1) alone significantly (p<0.01) increased the viability (82.6 (±6.6)) of the neutrophils compared to cells maintained only in medium (33.6 (±14.2)). Polymixin (10 µg·mL^–1) decreased (p<0.01) neutrophil viability (66.7% (±9.4)) in the presence of pooled RSV-NLF (n=5), compared to RSV-NLF alone (80.0±(8.6)), but this change was not significant. At this concentration, there were no toxic effect of Polymyxin when added to neutrophils cultured in medium alone (viability 53% (±19.3)), compared to cells in medium alone (42.5 (±16.8)).

CXCR2 (IL-8) receptor inhibitor
IL-8 added to neutrophils from 5–100 ng·mL^–1 supported a dose-dependent increase in viability and reduced cell death with increasing concentration of the cytokine (fig. 3). In the presence of a low (5 ng·mL^–1) or a high concentration (100 ng·mL^–1) of IL-8, the CXCR2 inhibitor (from 0.05–10 µM) showed no reversal of the effects of IL-8. The CXCR2 inhibitor also had no effect on the activity of RSV-NLF, e.g. with 100 µM of the inhibitor the viability was 82% (±8.4) versus 72.1% (±24.8) for RSV-NLF alone.

View larger version (23K): [in this window] [in a new window]   Fig. 3.— Measurement (n=8) of the percentage of viable (), apoptotic () and necrotic () neutrophils in Dulbecco modified Eagle medium after 24 h incubation at 37°C in the presence of increasing concentrations of interleukin (IL)-8. Addition of increasing IL-8 dose resulted in significant differences (p<0.01) for each of these viability indices as demonstrated by the Kruskal-Wallis procedure.

	Discussion

TOP Abstract Materials and methods Results Discussion Acknowledgements References

Whilst other studies have shown anti-apoptotic effects of LTB₄, IL-8, GM-CSF and lipopolysacaride 21, 23, these agents have been studied in isolation in vitro. The inability of these inhibitors to significantly affect the prolonged survival of neutrophils incubated with NLF from infants, suggests that in vivo this effect may be mediated either by a combination of pro-inflammatory factors or by another as yet unidentified factor. One nonspecific factor that may influence the survival of these neutrophils is the protein concentration of the NLF. Although the median protein content of the adult NLF samples was less than those of the two infant groups, there was considerable overlap at the individual level and no significant correlation between protein concentration and levels of apoptosis were observed for any of the study groups. Furthermore, the current authors have recently developed a defined serum-free medium to support optimal survival of neutrophils. In these experiments, it was found that protein (albumin) concentrations of >2 mg·mL^–1 were required to enhance survival by 10%. The median protein concentrations seen in the infant NLF samples were 40-times lower than this (60 µg·mL^–1), while the infant NLF samples increased the neutrophil survival from 27% to 77%, indicating that the prolonged survival was not attributable to nonspecific effects of increased protein in the infant samples.

The results indicate prolonged neutrophil survival in infants with RSV bronchiolitis and would therefore appear to contradict the results of Wang et al. 24. However, these two observations may not be contradictory if a prolonged life span results in an eventual increase in the proportion of neutrophils undergoing apoptosis within the airway. Wang et al. 24 suggested that accelerated apoptosis could protect the airways by limiting the release of inflammatory products. However, the present study could suggest the opposite, i.e. neutrophils accumulate in the airways explaining the increase in neutrophil elastase activity measured in infants particularly those with RSV bronchiolitis 14, 15, 19. Prolonged neutrophil survival and function could contribute to the symptoms characteristic of RSV infection. Interestingly, studies have indicated that neutrophil chemotaxis in the immediate postnatal period is relatively impaired 29, possibly explaining why acute bronchiolitis is uncommon in the first month of life.

The observation that NLF from apparently healthy infants inhibited apoptosis to a similar degree to RSV-NLF, suggests there are age-related developmental changes promoting inflammatory cell survival in the infant airway. Prolonged survival of these cells could act as a nonspecific defence mechanism aimed at countering the frequent respiratory infections experienced in early life. Further work is required to explore this possibility in more detail and would involve obtaining samples from infants and young children. One, albeit very unlikely, alternative is that all of the healthy control infants were experiencing subclinical infections. The follow-up telephone contacts confirmed that none of these infants were at a preclinical stage of an overt respiratory illness when sampled.

Neutrophilic inflammation is a recognised characteristic response to a number of respiratory viruses 30, and 15–25% of bronchiolitis is due to viruses other than RSV. Therefore, it is likely that no specific immunopathology exists in the airway of infants with RSV bronchiolitis, and the high prevalence of infant bronchiolitis every winter suggests that there is no effective herd immunity to this virus. As a consequence, RSV infects most infants each winter, a minority of whom develop severe lower respiratory tract symptoms requiring hospitalisation.

In summary, nasal lavage fluid obtained from infants, including those with respiratory syncytial virus bronchiolitis, significantly delayed apoptosis in neutrophils. This could account for the characteristic accumulation of these cells in the airways during respiratory syncytial virus bronchiolitis and may also promote a prolonged lifespan for these cells to protect the airway against infection by pathogens entering the healthy infant airway.

	Acknowledgements

TOP Abstract Materials and methods Results Discussion Acknowledgements References

 
The authors would like to thank G. Parker (Vanguard Medica, Surrey, UK) and E. Lilly for making VML 295 (LY293111) available and S. Sarau (SmithKline Beecham, King of Prussia, USA) for SB-237844.

	Footnotes

 
For editorial comments see page 515.

	References

TOP Abstract Materials and methods Results Discussion Acknowledgements References

 

1. Kim HW, Arrobio JO, Brandt CD, et al. Epidemiology of respiratory syncytial virus infection in Washington DC. 1. Importance of the virus in different respiratory tract disease syndromes and temporal distribution of infection. Am J Epidemiol 1973;98:2l6–225.
2. Everard ML. Respiratory syncytial virus bronchiolitis and pneumonia In: Taussig L, Landau L, editors. Textbook of Paediatric Respiratory MedicineSt. Louis, Mosby, 1998.
3. Gilchrist S, Torok TJ, Gary HE Jr, Alexander JP, Anderson LJ. National surveillance for respiratory syncytial virus, United States, 1985–1990. J Inf Dis 1994;170:986–990.[Web of Science][Medline] [Order article via Infotrieve]
4. Clarke SKR, Corner BD, Haines C. Respiratory syncytial virus infection: admissions to hospital in industrial, urban and rural areas. Report to the MRC Subcommittee on Respiratory Syncytial Virus Vaccines. BMJ 1978;2:796–798.
5. Glezen WP, Taber LH, Frank AL, Kasel JA. Risk of primary infection and re-infection with respiratory syncytial virus. Am J Dis Child 1986;140:543–546.[Abstract/Free Full Text]
6. Fleming DM, Cross KW. Respiratory syncytial virus or influenza. Lancet 1993;342:1507–1510.[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
7. Falsey AR, Walsh EE. Respiratory syncytial virus infection in adults. Clin Microbiol Rev 2000;13:371–384.[Abstract/Free Full Text]
8. Pullan CR, Hey EW. Wheezing, asthma and pulmonary dysfunction 10 year after infection with respiratory syncytial virus in infancy. BMJ l982;284:1665–1669.
9. Stein RT, Sherrill D, Morgan WJ, et al. Respiratory syncytial virus in early life and risk of wheeze and allergy by age 13. Lancet 1999;354:541–545.[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
10. Everard ML. What link between early respiratory viral infections and atopic asthma. Lancet 1999;354:527–528.[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
11. Ruuskanen O, Ogra PL. Respiratory syncytial virus. Curr Probl Pediat 1993;23:50–79.
12. Everard ML, Swarbrick A, Wrightham M, et al. Analysis of cells obtained by bronchial lavage of infants with respiratory syncytial virus infection. Arch Dis Child 1994;71:428–432.[Abstract/Free Full Text]
13. Smith P, Wang SZ, Dowling K, Forsyth K. Leukocyte populations in respiratory syncytial virus-induced bronchiolitis. J Paediatr Child Health 2001;37:146–151.[CrossRef][Medline] [Order article via Infotrieve]
14. Evans GS, Pettitt E, Elphick HE, Jones A, Everard ML. Identification of neutrophil elastase as the major uninhibited protease in the airways of children with RSV positive bronchiolitis. Am J Respir Crit Care Med 1999;159:A189.
15. Evans GS, Pettitt E, Jones A, Elphick HE, Everard ML. Fibronectin degradation is associated with raised neutrophil elastase activity in the upper airways of infants with viral induced wheeze and RSV bronchiolitis. Eur Respir J 1999;14:Suppl. 30, s21.
16. Blyth DI, Pedrick MS, Savage TJ, Bright H, Beesley JE, Sanjar S. Induction, duration, and resolution of airway goblet cell hyperplasia in a murine model of atopic asthma: effect of concurrent infection with respiratory syncytial virus and response to dexamethasone. Am J Respir Cell Mol Biol 1998;19:38–54.[Abstract/Free Full Text]
17. Becker S, Quay J, Soukup J. Cytokine (tumor necrosis factor, IL-6, IL-8) production by respiratory syncytial virus-infected human alveolar macrophages. J Immunol 1991;147:4307–4312.[Abstract]
18. Arnold R, Humbert B, Werchau H, Gallati H, Konig W. Interleukin-8, interleukin-6, and soluble tumour necrosis factor receptor type 1 release from a human pulmonary epithelial cell line (A549) exposed to respiratory syncytial virus. Immunology 1994;82:126–133.[Web of Science][Medline] [Order article via Infotrieve]
19. Abu-Harb M, Bell F, Rao WH, et al. IL-8 and neutrophil inflammatory mediators in the upper respiratory tract of infants with RSV bronchiolitis. Eur Respir J 1999;14:150–154.[Abstract]
20. Schultz C, Richter N, Moller JC, Bucsky P. IFN-gamma response and IL-8 plasma levels in neonates with respiratory syncytial virus bronchiolitis. Eur Respir J 2000;17:321–324.[CrossRef]
21. Lee A, Whyte MK, Haslett C. Inhibition of apoptosis and prolongation of neutrophil functional longevity by inflammatory mediators. J Leukocyte Biol 1993;54:283–288.[Abstract]
22. Fadok VA, Savill JS, Haslett C, et al. Different populations of macrophages use either the vitronectin receptor or the phosphatidylserine receptor to recognise and remove apoptotic cells. J Immunol 1992;149:4029–4035.[Abstract]
23. Sampson AP. The role of eosinophils and neutrophils in inflammation. Clin Exp Allergy 2000;30:Suppl. 1, 22–27.
24. Wang SZ, Smith PK, Lovejoy M, Bowden JJ, Alpers JH, Forsyth KD. The apoptosis of neutrophils is accelerated in respiratory syncytial virus (RSV)-induced bronchiolitis. Clin Exp Immunol 1998;114:49–54.[CrossRef][Medline] [Order article via Infotrieve]
25. Noah TL, Henderson FW, Henry MM, Peden DB, Develin RB. Nasal lavage cytokines in normal, allergic and asthmatic school-age children. Am J Respir Crit Care Med 1995;152:1290–1296.[Abstract]
26. Smith JD, Cortes NJ, Evans GS, Read RC, Finn A. Induction of ß2 integrin-dependent neutrophil adhesion to human alveolar epithelial cells by type 1 Streptococcus pneumoniae and derived soluble factors. J Inf Dis 1998;177:977–985.[Medline] [Order article via Infotrieve]
27. Pisetsky DS. Antibody responses to DNA in normal immunity and aberrant immunity. Clin Diagn Lab Immunol 1998;5:1–6.[Free Full Text]
28. White JR, Lee JM, Young PR, et al. Identification of a potent, selective nonpeptide CXCR2 antagonist that inhibits interleukin-8-induced neutrophil migration. J Biol Chem 1998;273:10095–10098.[Abstract/Free Full Text]
29. Carr R, Pumford D, Davies JM. Neutrophil chemotaxis and adhesion in preterm babies. Arch Dis Child 1992;67:813–817.[Abstract/Free Full Text]
30. Turner RB. The role of neutrophils in the pathogenesis of rhinovirus infections. Ped Inf Dis J 1990;9:832–835.

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