Increased airway epithelial and T-cell apoptosis in COPD remains despite smoking cessation

Immunological reagents

The following monoclonal antibodies (MAbs) and reagents were employed: CD45(PE-CY5), CD3(PE-CY5) (Immunotech/Coulter, Marseille, France), CD3(PE), p53(PE) (BD Biosciences, CA, USA), Bcl-2(FITC) (Dako, Glostrup, Denmark), Bax (unconjugated) (Oncogene Science, NY, USA), rabbit anti-mouse immunoglobulin (Ig)G (RAM, PE; BD Biosciences), IgG1(PE) (as negative control; BD Biosciences), Annexin V(FITC) (BD Biosciences), 7-amino-actinomycin D (7-AAD) (Sigma, Sydney, Australia), CaspACE FITC-VAD-FMK (Promega, WI, USA), unconjugated antibody to single-stranded DNA (ssDNA) (MAB3299 (F7-26); Chemicon, CA, USA) and goat anti-mouse IgM(FITC) (Rockland, PA, USA).

Subject population

COPD patients undergoing fibreoptic bronchoscopy for diagnostic purposes (predominantly because of lesions suspicious of carcinoma on chest radiograph) were invited to participate in the study and fully informed consent was obtained. There was no exacerbation of COPD for 6 weeks prior to involvement in the study. Ethics approval was obtained from the Royal Adelaide Hospital, Adelaide, Australia. The diagnosis of moderate COPD was established using the Global Initiative for Chronic Obstructive Lung Disease criteria 13 of a relevant history and post-bronchodilator forced expiratory volume in one second (FEV₁) 30–80% of predicted and FEV₁/forced vital capacity <70%.

Bronchial brushings were collected from 29 patients with COPD (brushing group) (table 1⇓). Sixteen patients were ex-smokers (>1 yr abstinence) and 13 current smokers.

BAL was collected from 20 patients with COPD (BAL group) (there was overlap between this group and the brushing group due to unsuitability or unavailability of occasional specimens of BAL or bronchial brushing) (table 1⇑). In total, 13 patients were ex-smokers (>1 yr abstinence) and seven current smokers.

Specimens were also obtained from 20 nonsmoking volunteers (table 1⇑). In total, 10 of these controls were healthy, recruited volunteers with no history of airways disease and 10 were undergoing bronchoscopy for other clinically indicated reasons. Typically, these were patients with chronic cough, which proved to be related to gastro-oesophageal reflux or sinus disease, or with minor probable haemoptysis for which no pulmonary cause could be found. These subjects enabled the power of the study to be improved and fulfilled the criteria for normal control (normal lung function, no evidence of any lung disease, no history of asthma or allergy, nonsmokers, normal bronchoscopy). Most of the controls were included in both the BAL and brushing studies, apart from a few subjects in whom either the BAL or brush was inadequate for technical reasons. Importantly, there were no significant differences between these two groups of controls for any of the parameters investigated in this study. The first phase of the study investigated apoptosis in brushing-derived epithelial cells and BAL-derived T-cells. For this phase of the study the two control groups were pooled into a single control group.

Bronchoscopy procedure

Fibreoptic bronchoscopy was performed as previously described 11. Brushings and BAL were obtained from the right-sided airways, unless there was other pathology in this area, when the left-sided airways were sampled. Particular attention was given to use a minimal amount of lignocaine (100 mg) in the airways in view of the adverse effect it has on cell viability 14.

Preparation of ex vivo samples

Cells were prepared as previously described 11, 15 and re-suspended to a cell count of 4×10⁵ cells·mL⁻¹ with RPMI 1640 media. Investigation of apoptosis of airway T-cells and epithelial cells was performed within 1 h. For investigation of Bcl-2, Bax and p53 by BAL-derived T-cells, BAL samples were stimulated with phytohaemagglutin for 18 h, as previously reported 9.

Measurement of LDH levels in BAL

When the cells of a tissue become damaged or necrotic, their contents leak out into the extracellular fluid. Thus, the existence of secondary necrosis in the airways can be inferred by the presence of lactic dehydrogenase (LDH) in BAL. LDH levels were measured in BAL from the 10 volunteer control subjects and 10 of the COPD subjects (five smokers, five ex-smokers) using a Beckman Synchron CX^R System (Beckman Instruments Brea, CA, USA), following instructions supplied with the reagent kit.

Identification of cell types

Surface staining to identify cell types was carried out using flow-cytometry, as previously described 16, 17 and is shown in figures 1⇓ and 2⇓. Leukocytes were excluded from analysis of airway epithelial cells based on bright staining with CD45 (fig. 1b⇓). T-cells were gated based on known staining characteristics with CD3 PC5 versus side scatter (fig. 2b⇓). As both 7-AAD and PC5 fluoresce in fluorescence channel 3 (FL3), CD3 PE (FL2) versus side scatter was used for identification of T-cells prior to staining with 7-AAD.

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Fig. 1—

Flow cytometry gating strategies for brushing-derived airway epithelial cells. a) Red blood cells and debris were excluded from Region (R)1 based on forward scatter (FSC) and side scatter characteristics. All subsequent analysis was carried out on cells from this region. b) Contaminating leukocytes identified by bright staining with CD45 and excluded from airway epithelial cells in R2. All subsequent analysis carried out on cells from R1 and R2. c and d) 7-AAD staining of apoptotic brushing-derived airway epithelial cells. Representative dot plots showing FSC versus 7-AAD staining to distinguish viable (7-AAD negative staining) and apoptotic (7-AAD bright staining) epithelial cells. Control subject: 14% apoptotic (c); chronic obstructive pulmonary disease subject: 32% apoptotic (d).

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Fig. 2—

Flow cytometry gating strategies for bronchiolar lavage-derived T-cells. a) Red blood cells and debris were excluded from Region (R)1 based on forward scatter (FSC) and side scatter characteristics. All subsequent analysis carried out on cells from this region. b) T-cells gated in R2 based on bright staining with CD3 and low side scatter. All subsequent analysis carried out on cells from R1 and R2. (CD45 PE was also applied to confirm the gating (data not shown)). c and d) 7-AAD staining of apoptotic brushing-derived airway epithelial cells. Representative dot plots showing FSC versus 7-AAD staining to distinguish viable (7-AAD negative staining) and apoptotic (7-AAD bright staining) epithelial cells. Control subject: 5% apoptotic (c); chronic obstructive pulmonary disease subject: 18% apoptotic (d).

Apoptosis of BAL-derived leukocytes and brushing-derived airway epithelial cells

Effects of glucocorticosteroids on apoptosis of airway-derived T-cells and epithelial cells

Glucocorticosteroids (GCS) have been reported to induce apoptosis of airway epithelial cells and T-cells 19, 20. To investigate this possibility in a preliminary fashion, COPD subjects with similar lung function were grouped based on GCS or bronchodilator treatment, (brushing group: 13 GCS-treated and 16 subjects using bronchodilator medication only; BAL group: 11 GCS-treated and nine subjects using bronchodilator only). Apoptosis was assessed as described above, and results compared for the two groups. However, the subjects were heterogeneous with respect to the type of inhaled steroid being used, the dose, and furthermore no guarantees could be given as regard their compliance with medication. Thus, a more definitive analysis of the effects of GCS on apoptosis in COPD awaits further study.

Effect of age on apoptosis of airway-derived T-cells and epithelial cells

There have been some reports of increased apoptosis of peripheral blood T-cells with increasing age 21. To investigate this possibility the control group was divided into two age categories, those aged <50 yrs and those aged 55–70 yrs. Apoptosis was calculated as described above, and results compared for the two groups.

Effect of smoking on apoptosis of airway-derived T-cells and epithelial cells

COPD subjects with similar lung function were grouped based on smoking status (fig. 1⇑), apoptosis of airway epithelial cells and T-cells assessed as described above, and results compared for the two groups.

Bax, Bcl-2 and p53 expression by airway-derived T-cells and epithelial cells in COPD

Staining for cell type identification was carried out as described above. Bax, Bcl-2 and p53 were stained using a direct flow-cytometric staining technique. Aliquots of 1×10⁶ cells were washed with calcium and magnesium-free PBS and 200 μL of membrane permeabilising solution (0.5% Triton X-100 (Sigma), 0.2 μg·mL⁻¹ Na₂EDTA, 2H2O (APS Chemicals, NSW, Australia), 1% BSA in PBS) added to the cell pellet for 15 min. Cells were stained with MAbs to Bax (5 μL), Bcl-2 (10 μL) or p53 (5 μL). Irrelevant antibodies of the same isotypes were used as negative controls. For Bcl-2 and p53, analysis of unwashed, unfixed cells was carried out immediately by flow-cytometry. For Bax, cells were further stained with 5 μL PE-conjugated rat-anti-mouse Mab, washed and analysed by flow-cytometry (fig. 1⇑).

Statistical analysis

The Mann-Whitney U-test was used to analyse data. p-Values <0.05 were considered significant.

Apoptosis of BAL-derived leukocytes and brushing-derived airway epithelial cells

As previously reported for peripheral blood T-cells and neutrophils 9, 18, there was good correlation between Annexin V staining and 7-AAD staining for the detection of apoptosis of brushing-derived epithelial cells (R² = 0.8).

Typical scatter patterns of forward scatter versus 7-AAD are presented in figure 1⇑ and typical histograms presented in figure 3⇓. The percentage of apoptotic airway epithelial cells was significantly higher for patients with COPD than controls for each of the techniques used (table 2⇓). The mean increase in apoptosis across the techniques was 87% (calculated as (COPD–control)/control). In agreement with results from analysis of percentage changes, there were significantly more absolute numbers of apoptotic airway epithelial cells in COPD (control: 0.06×10⁹·L⁻¹ versus COPD: 0.10×10⁹·L⁻¹; p = 0.03).

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Fig. 3—

Apoptosis of brushing-derived airway epithelial cells measured by different techniques. Representative histograms show: a) Annexin V staining of phosphatidylserine on the cell membrane (20.0% apoptotic); b) 7-AAD staining due to nonfunctional membrane pump action (22.3% apoptotic); c) staining of intranuclear single-standed DNA in early apoptosis (27.3% apoptotic); and d) staining of intracellular caspase activation in early apoptosis (37.6% apoptotic).

Disruption of epithelial cells from the basement membrane has been reported to induce apoptosis 22. In addition, the local anaesthetic, lignocaine, has been reported to diminish epithelial cell viability, in vitro 14. Staining with Annexin V and 7-AAD relies on changes to the cell membrane, but it was considered that any confounding factor due to technical issues would similarly affect the COPD and control groups. Nevertheless, to investigate whether cell removal or use of lignocaine (used at a minimum dose, 100 mg) caused artefactual membrane damage during the bronchoscopy procedure, techniques were further applied to specifically detect apoptosis, based on changes that did not involve the cell membrane (ssDNA and caspase) (fig. 3⇑). These again confirmed higher rates of apoptosis in COPD.

Consistent with findings for peripheral blood-derived T-cells from COPD patients 9, BAL-derived T-cells showed increased apoptosis, with a mean increase of 103% across the techniques used (table 2⇑). The absolute numbers of apoptotic T-cells (adjusted for total lymphocte numbers) were significantly increased in COPD (control: 0.003×10⁹·L⁻¹ versus COPD: 0.02×10⁹·L⁻¹; p = 0.01).

Effects of age on apoptosis of airway-derived T-cells and epithelial cells

There were no significant changes in apoptosis of airway epithelial cells or BAL-derived T-cells with increasing age (epithelial cells: controls aged <50 yrs, 7-AAD 20.0±11.6% (mean±sd) versus controls aged 55–75 yrs, 20.0±14.6%; T-cells: controls aged <50 yrs, 7-AAD 19.9±11.6% versus controls aged 55–75 yrs 17.2±12.6%). Annexin V staining supported these findings (data not shown).

Effects of smoking on apoptosis of airway-derived T-cells and epithelial cells

There were no significant differences in apoptosis of airway epithelial cells or BAL-derived T-cells between smoking and nonsmoking COPD subjects (fig. 4⇓).

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Fig. 4—

Apoptosis of a) bronchoalveolar lavage-derived T-cells and b) brushing-derived airway epithelial cells measured by 7-AAD staining and flow cytometry in controls, chronic obstructive pulmonary disease (COPD) subjects (total group), and smokers and ex-smokers with COPD. *: significant difference between COPD and control groups p≤0.05; ^#: no significant difference between smokers and ex-smokers with COPD.

Bax, Bcl-2 and p53 expression by airway-derived T-cells and epithelial cells in COPD

Expression of Bax, Bcl-2 and p53 was analysed by flow-cytometry. There was no significant change in the percentage of airway epithelial cells or T-cells expressing Bcl-2 or Bax in COPD compared with controls (table 3⇓). Similarly, the median fluorescence intensity of staining was not significantly different (data not shown). P53 expression by BAL-derived CD3+ T-cells and brushing-derived airway epithelial cells was significantly increased in COPD compared with controls (table 3⇓).

LDH levels in BAL in COPD

To determine if secondary necrosis of airway-derived cells was apparent, LDH levels were measured in BAL from the 10 normal volunteer subjects and 10 COPD subjects (five of the smokers and five of the ex-smokers). LDH levels were significantly higher in BAL from COPD subjects compared with controls (1.9±2.9 IU·L⁻¹ versus 0.1±0.3 IU·L⁻¹; p = 0.040).