Background
COPD is predicted to be the 3rd leading cause of death worldwide by 2020 [
1]. Existing treatments are largely symptomatic and the only approved anti-inflammatory medication, corticosteroids, has no proven disease modifying effect [
1]. Inhaled corticosteroids have major benefits for the treatment of airway inflammation in asthma, but the reason for their relative lack of efficacy in COPD is both poorly understood and a major limiting factor in COPD treatment. Thus, better understanding of the mechanisms underlying steroid resistance in COPD, and a way to circumvent this to take better advantage of existing therapies would have an immediate clinical impact.
COPD is a systemic disease and may represent a “spill-over” of inflammatory events occurring in the lungs [
2]. In this regard we have previously shown an increase in pro-inflammatory/cytotoxic T cells, NKT-like and NK cells in the peripheral blood and airways in COPD patients compared with non-COPD smokers where some changes were only noted in the lungs compared with healthy controls [
3‐
5].
P-glycoprotein 1 (Pgp1) is a transmembrane efflux pump well characterised in drug resistant cancer cells [
6]. We hypothesized that Pgp1 may play a role in steroid resistance and would be increased in peripheral blood T, NKT-like and NK cells in patients with COPD, and that this would be accompanied by increased expression of IFNγ, TNFα and granzyme B. We further hypothesized that treatment with low dose cyclosporine A, a Pgp1 inhibitor, would render cells more sensitive to treatment with corticosteroids.
Pgp1, granzyme B, IFNγ and TNFα expression were measured in peripheral blood T, NK and NKT-like cells from COPD patients and control subjects (± cyclosporine A and prednisolone) following in vitro stimulation and results correlated with uptake of efflux dye calcein AM using flow cytometry.
Methods
Patient and control groups
COPD patients and controls were recruited for the study and fully informed consent 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. The diagnosis of moderate COPD was established using the GOLD criteria [
7] of a relevant history and post bronchodilator FEV1 30-80% of predicted and FEV1/FVC < 70%.
Blood was collected from 10 patients with COPD (Table
1) of whom all were ex-smokers (at least one year).
Table 1
Demographic details of the COPD and control subjects
No. of subjects | 14 | 10 |
Age (years) | 56 (± 8) | 58 (± 16) |
FEV1, % pred | 110.4 (± 9) | 60.5 (± 20) |
FEV1, % FVC | 96 (± 12) | 58 (± 15)* |
Male/Female | 8/6 | 6/4 |
Blood was also obtained from 14 non-smoking volunteers (Table
1) with no history of airways disease and normal lung function).
Leucocyte counts
Full blood counts, including white cell differential counts, were determined on blood specimens using a CELL-DYN 4000 (Abbot Diagnostics, Sydney, Australia). Blood films were stained by the May-Grunwald-Giemsa method and white cell differential counts checked by morphological assessment microscopically.
CD3, CD4 and CD8 cell counts
The percentages of CD3, CD4 and CD8 lymphocytes were calculated using flow cytometry. One hundred microlitre of peripheral blood were stained with appropriately diluted fluorescently conjugated monoclonal antibodies as previously described [
3].
Granzyme B expression by T, NKT-like and NK cells
The percentages of T, NKT-like and NK cells expressing granzyme B, was determined as previously reported [
5].
Leucocyte stimulation
Leucocyte stimulation was required for both intracellular cytokine and Pgp1 expression by T, NKT-like and NK cells. One mL aliquots of blood (diluted 1:2 with RPMI 1640 medium) were placed in a 10 mL sterile conical PVC tubes (Johns Professional Products, Sydney, Australia). Phorbol myristate (25 ng/mL) (Sigma, Sydney, Australia) and ionomycin (1 μg/mL) (Sigma) was added. Brefeldin A (10 μg/mL) was added as a “Golgi block” (Sigma) and the tubes re-incubated in a humidified 5% CO2/95% air atmosphere at 37°C for 16 h.
Intracellular IFNγ and TNFα expression by T, NKT-like and NK cells
Three hundred and fifty μL of stimulated peripheral blood cells were stained with appropriately diluted fluorescently conjugated monoclonal antibodies as previously reported [
3‐
5] to IFNγ FITC (BD Biosciences, Sydney, Australia) (BD), CD3 perCP.Cy5.5 (BD), CD56 APC (Beckman Coulter, Sydney, Australia), TNFα V450, granzyme B V450 and CD45 V500 (BD). Samples were analysed by gating using forward scatter (FSC) versus side scatter (SSC) to exclude platelets and debris. Gated cells were analysed with CD45 V500 (BD) to ascertain that cells were of lymphoid origin. A minimum of 500,000 CD45 positive, low SSC events were acquired on a FACSCanto II (BD) in list-mode format for analysis using FACSDiva software (BD). T cells were identified as events that were CD3 + CD56-, NK cells as CD3-CD56+ and NKT-like cells as CD3 + CD56+ events as previously reported [
5].
Pgp1 expression by T, NK and NKT-like cells
Preliminary experiments showed that cells required stimulation for significant Pgp1 molecule expression by T, NKT-like and NK cells. Following stimulation as described above, 350 μL aliquots of cells were treated with 2 mL FACSLyse for 10 min. Cells were centrifuged, supernatant discarded and 500 mL FACSPerm added for 10 min. Two mL 0 · 5% bovine serum albumin (BSA) (Sigma) in IsoFlow (Beckman Coulter) was then added and the tubes centrifuged at 300 g for 5 min. After decanting supernatant, Fc receptors were blocked with 10 mL human immunoglobulin (Intragam, CSL, Melbourne, Australia) for 10 min at room temperature. Five μL of appropriately diluted CD3 perCP.Cy5.5 (BD), Pgp1 PE (BD) CD56 APC (Beckman Coulter) and CD45 V500 (BD) or isotype control (BD) were added for 15 min in the dark at room temperature. Cells were washed and events acquired and analyzed as described above.
Pgp1, IFNγ, TNFα and granzyme B expression by T, NKT-like and NK cells
To determine possible association of pro-inflammatory cytokines and granzyme B expression with Pgp1 expression by T, NKT-like and NK cells, whole blood was stimulated as described above. Following stimulation and processing, 5 μL of appropriately diluted IFNγ FITC (BD), granzyme B FITC (BD), Pgp1 PE (BD), CD3 perCP.Cy5.5 (BD), TNFα V450 (BD) and CD45 V500 (BD) were added for 15 min in the dark at room temperature. Cells were washed and events acquired and analyzed as described above.
Uptake of Calcein-AM by T, NKT-like and NK cells
To determine functional Pgp1 activity, efflux of Calcein-AM was analysed in T, NKT-like and NK cells as previously published [
8] from a cohort of COPD patients and control subjects. Briefly, following stimulation of cells as described above, 5 nM Calcein-AM (eBioscience, San Diego, CA, USA) was added and cells re-incubated in a humidified 5% CO
2/95% air atmosphere at 37°C for 30 min. Aliquots were washed twice with wash buffer to remove free Calcein-AM and cells processed for Pgp1 expression as described above.
Effect of methylprednisolone and Cyclosporin A on Pgp1, IFNγ, TNFα and granzyme B expression by T, NKT-like and NK cells
To determine the effects of methylprednisolone and Cyclosporin A on Pgp1, IFNγ, TNFα and granzyme B expression by T, NKT-like and NK cell subsets, one mL aliquots of blood (diluted 1:2 with RPMI 1640 medium) were placed in a 10 mL sterile conical PVC tubes with 10-6 M methylprednisolone and/or various concentrations of Cyclosporin A (0, 1, 2.5, 5, 10, 50, 100, 200 and 250 ng/mL) for 24 h in a humidified 5% CO2/95% air atmosphere at 37°C. Blood cultures were then stimulated as described above for 16 h and processed for Pgp1, IFNγ, TNFα, granzyme B and perforin expression by T, NKT-like and NK subsets as described above.
Statistical analysis
Statistical analysis was performed using Mann–Whitney and Spearman Rho correlation tests using SPSS software and differences between groups of P < 0.05 considered significant.
Discussion
This is the first study to show differential expression of the drug efflux pump Pgp1 by T, NKT-like and NK cells from COPD patients compared with healthy control subjects. COPD is a systemic disease [
2] and we have previously shown increased IFNγ and TNFα by T cells [
3], granzyme B by NK and NKT-like cells [
5] and granzyme B by T cells [
4] in the peripheral blood and lungs of COPD patients. Our novel findings that Pgp1 is up-regulated in NKT-like and NK cells in patients with COPD and that this is associated with increased pro-inflammatory and cytotoxic molecules in T, NKT-like and NK cells have important implications for treatment strategies to target these cells.
The relative lack of corticosteroid efficacy in COPD has been poorly understood and a major limiting factor in COPD treatment [
2]. We now show that production of IFNγ and TNFα and granzyme B by T and NKT-like subsets of lymphocytes are not inhibited with therapeutic doses of methylprednisolone, a commonly used corticosteroid
in vitro, confirming clinical findings. Importantly we show that by targeting Pgp1 with a low dose of the inhibitor, cyclosporine A, production of the pro-inflammatory cytokines IFNγ and TNFα are significantly inhibited. Further, a combination of very low dose cyclosporine A (2.5 ng/mL) with standard dose methylprednisolone (10
-6 M), results in synergistic inhibition of these pro-inflammatory cytokines known to have systemic effects in patients with COPD [
2]. The excellent negative correlation between efflux of Calcein-AM, previously shown to identify Pgp1 function in cells [
8] and our findings of Pgp1 expression in T, NKT-like and NK cells confirms these novel findings.
Our group has undertaken pioneering work on the role of T-cell pro-inflammatory cytokines, particularly TNFα and IFNγ, and their role in COPD [
3]. T cells are a major inflammatory cell type present in the lung in COPD patients. Our findings in 2007 were the first comprehensive report of intracellular pro- and anti-inflammatory T cell cytokines in the separate compartments of blood, bronchoalveolar lavage and intraepithelial T cells from bronchial brushings from COPD subjects and smokers. Interestingly, T-cell derived TNFα has been shown to cause apoptosis of airway epithelial cells and impair the clearance of these cells by alveolar macrophages [
10]. Recently, TNFα has been described as the “driving force behind COPD” [
11], and induction of TNFα in the lung has been shown to result in emphysema in the mouse model [
9]. TNFα has also been shown to induce IL-2Rs and IFNγ production by T cells and activate neutrophils, macrophages, endothelial cells and fibroblasts [
12]; cells that play important roles in the pathogenesis of COPD [
2]. Recently it has been shown that fractalkine, a potent chemoattractant for monocytes and T cells produced by airway smooth muscle cells, was induced in the presence of both IFNγ and TNFα [
13]. Furthermore, increased TNFα levels have been shown to be increased in diseases associated with COPD such as cardiovascular disease and as such, systemic treatment with low dose Cyclosporin A and prednisolone may result in improvements of a broad range of inflammatory conditions associated with COPD [
14].
An important extension of this work would be to study T, NKT-like and NK cells in both the airways and lung tissue of COPD patients as we have previously done [
5,
15] to determine the role Pgp1 may play in steroid resistance in these compartments. If this hypothesis is correct, targeting the airways with inhaled low dose CsA combined with steroid may be the treatment of choice to inhibit these pro-inflammatory molecules associated with COPD disease.
It would also be of interest to study Pgp1 expression in lymphocyte subsets in the peripheral blood of smokers who have not progressed to COPD. Our previous findings of increased T-cell production of IFNγ and TNFα in the peripheral blood of COPD patients but not smokers without COPD suggests Pgp1 may not be upregulated in smokers who have not progressed to COPD. However, there may be a subset of susceptible smokers who do have increased Pgp1 in these cells who have an increased risk of developing COPD and further studies are warranted to investigate this hypothesis.
Our present findings show that there was a significant increase in Pgp1 expression by T and NKT-like cells compared with NK cells suggesting these subsets of lymphocytes may be the most resistant to effects of therapeutic drugs.
We showed that the cytotoxic molecule, granzyme B is unaltered by standard dose methylprednisolone and requires much higher concentrations of cyclosporine usually used for immunosuppression in patients such as those following lung transplantation [
16]. Our results suggest that patients with high levels of this cytotoxic molecule may require treatment with higher dose Cyclosporin A. Further, identification of patients with high levels of granzyme B and response following treatment may allow tailoring therapeutics to individual patients using these techniques, to optimize immunosuppression as to possibly avoid problems associated with over-immunosuppression (e.g., infection and malignancy) and under-immunosuppression with worsening of COPD symptoms.
Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
GH performed the concept and design of experiments, analysis and interpretation of data and manuscript preparation; MH supplied and characterized patient specimens and helped draft the manuscript; HJ supplied and characterized patient specimens and helped draft the manuscript; PNR supplied and characterized patient specimens and helped draft the manuscript; SH helped with study design, statistical analysis and helped draft the manuscript. All authors read and approved the final manuscript.