Abstract
Circulating CD34+ cells are haemopoietic progenitors that may play a role in tissue repair. No data are available on circulating progenitors in chronic obstructive pulmonary disease (COPD).
Circulating CD34+ cells were studied in 18 patients with moderate-to-severe COPD (age: mean±sd 68±8 yrs; forced expiratory volume in one second: 48±12% predicted) and 12 controls, at rest and after endurance exercise. Plasma concentrations of haematopoietic growth factors (FMS-like tyrosine kinase 3 (Flt3) ligand, kit ligand), markers of hypoxia (vascular endothelial growth factor (VEGF)) and stimulators of angiogenesis (VEGF, hepatocyte growth factor (HGF)) and markers of systemic inflammation (tumour necrosis factor (TNF)-α, interleukin (IL)-6, IL-8) were measured.
Compared with the controls, the COPD patients showed a three-fold reduction in CD34+ cell counts (3.3±2.5 versus 10.3±4.2 cells·µL−1), and a 50% decrease in AC133+ cells. In the COPD patients, progenitor-derived haemopoietic and endothelial cell colonies were reduced by 30–50%. However, four COPD patients showed progenitor counts in the normal range associated with lower TNF-α levels. In the entire sample, CD34+ cell counts correlated with exercise capacity and severity of airflow obstruction. After endurance exercise, progenitor counts were unchanged, while plasma Flt3 ligand and VEGF only increased in the COPD patients. Plasma HGF levels were higher in the COPD patients compared with the controls and correlated inversely with the number of progenitor-derived colonies.
In conclusion, circulating CD34+ cells and endothelial progenitors were decreased in chronic obstructive pulmonary disease patients and could be correlated with disease severity.
The systemic effects of chronic obstructive pulmonary disease (COPD) have been studied with regards to inflammation, chronic oxidative stress and skeletal muscle dysfunction 1. Despite evidence of neutrophils activation in peripheral blood of COPD patients 2, inflammatory infiltration of the airways in severe disease 3, and smoking-induced increase in granulocyte turnover, little is known about the effects of COPD at the level of bone marrow 4. Data on the erythrocyte lineage have shown that anaemia occurs in 13% of COPD patients and is associated with increased inflammatory markers 5, and may predict poor survival 6. Data on other blood lineages are scarce due to the need of invasive techniques to obtain bone marrow samples.
This difficulty can be partly overcome by studying circulating bone marrow-derived progenitors. These cells are positive for CD34 and other markers (CD38, human leukocyte antigen (HLA)-DR) acquired during differentiation 7, and yield indirect information on haemopoiesis. Circulating CD34+ cells are also believed to be involved in tissue repair. Bone marrow-derived progenitors can engraft in several organs including the lungs 8, 9 and skeletal muscle 10. The latter finding is of interest in COPD, given the frequent occurrence of skeletal muscle dysfunction associated with increased muscle apoptosis 11, fibrosis 12 and inflammatory activation 13.
At least part of the repair potential of CD34+ cells may depend on the AC133+ endothelial progenitor cell (EPC) subpopulation 14. EPCs have been used to treat patients with myocardial 15 and vascular 16 disease. Low circulating EPC counts were found in patients with cardiovascular risk factors 17, and bone marrow CD34+ cells showed a low proliferative capacity in patients with chronic ischemic heart disease 18. However, exercise training increased EPCs 19. Whether COPD affects circulating EPCs and/or CD34+ cell proliferative capabilities is unknown.
Exercise might be a useful model to study circulating progenitors. Long-distance runners showed increased circulating CD34+ cells and exercise-induced release of factors/cytokines active on the bone marrow (FMS-like tyrosine kinase 3 (Flt3) ligand, interleukin (IL)-6, granulocyte colony-stimulating factor (G-CSF), tumour necrosis factor (TNF)-α) 20, 21. Mobilisation of endothelial progenitor cells also occurred after exercise in middle-aged untrained subjects 22, but little is known on the relationship between circulating progenitors and exercise limitation in COPD, or on the effects of inflammatory activation on progenitors.
Finally, COPD may affect haemopoietic and endothelial progenitors through alterations in arterial blood gases or inflammatory mediators. In vitro, very low arterial oxygen tension preserved early haemopoietic progenitors 23, while promoting their differentiation 24. No study addressed the effects of mild hypoxaemia on circulating CD34+ cells and subpopulations in vivo in COPD patients.
The present study was designed to answer whether or not COPD affects circulating progenitor cell numbers and frequency.
SUBJECTS AND METHODS
In total, 18 ex-smokers with COPD and 12 age-matched nonsmokers (controls) were studied (table 1⇓). Inclusion criteria for patients were: 1) COPD of moderate severity (Global Initiative for Chronic Obstructive Lung Disease stage 2); 2) stable clinical conditions (i.e. no change in pulmonary function tests or exacerbation in the 4 weeks preceding the study); and 3) mild, resting hypoxaemia (arterial oxygen tension: Pa,O2 >7.89 kPa). No patient was receiving systemic steroids at the time of the study. Inclusion criteria for controls were: 1) age ≥50 yrs; 2) a sedentary lifestyle; 3) normal spirometry and arterial blood gases; 4) no other clinically evident disease; and 5) a wish to participate in the study. Patients with cardiovascular, cerebrovascular, neuromuscular, rheumatological and/or metabolic disorders, as assessed by clinical and standard laboratory findings tests, were excluded from the studies. Patients were also excluded if they suffered from any disease precluding execution of exercise tests.
Anthropometric characteristics and pulmonary function data of chronic obstructive pulmonary disease(COPD) patients and control subjects
The protocol was approved by the Ethical Committee of the University of Rome (Italy), and all subjects gave their informed consent.
Study protocol
Each subject visited the laboratory three times. At the first visit, a complete clinical assessment and pulmonary function tests (Quark PFT; COSMED, Rome, Italy) were obtained. A sample was drawn from the radial artery for arterial blood gas determination at rest while breathing room air. At the second visit each subject underwent an incremental exercise stress test on the cycle ergometer (Ergoline 800, Bitz, Germany) to determine peak oxygen uptake (V′O2peak) and lactic threshold. Pulmonary gas exchange indexes were measured breath-by-breath by a computerised system as previously described 25. Oxygen uptake (V′O2; at standard temperature and pressure, dry (STPD)), CO2 output (V′CO2; STPD), minute ventilation (V′E; at body temperature and pressure, saturated with water vapour) and respiratory frequency were measured. Heart rate (HR) was derived from R–R intervals measured from a 12-lead ECG. At the third visit, each subject performed a submaximal exercise test on a cycle ergometer at a work-rate corresponding to 70% of V′O2peak for 20 min (endurance test). Exercise sessions were planned a minimum of 48 h apart. All tests were obtained while the subjects breathed room air.
Venous blood samples (20 mL) were drawn before and immediately after the endurance test for analysis of blood cell counts and CD34+ cells. Total blood cell counts were determined by standard haemocytometry. Peripheral blood mononuclear cells (PBMCs) were obtained by standard Ficoll gradient centrifugation. The cells were carefully washed with PBS, resuspended in PBS containing 2 mg·mL−1 bovine serum albumin and labelled for 30 min at 4°C with the following antibodies: 1) anti-CD34 conjugated with phycoerythrin (PE); 2) anti-CD38; or 3) anti-HLA-DR, all labelled with fluoresceine isothiocyanate (FITC; Becton Dickinson–Pharmingen, Lincoln Park, NJ, USA). In some experiments PBMCs were labelled with anti-CD34 (FITC-conjugated) and either anti-very late activation antigen (VLA)-4 or anti-Flt3 (both PE-conjugated). For a negative control, the cells were labelled with isotype-matched mouse immunoglobulin labelled with either PE or FITC. After two washings in cold PBS, the cells were analysed for fluorescence in a fluorescence-activated cell sorter flow cytometer (Becton-Dickinson). The level of positivity of entire body was evaluated as “dim” or “bright” according to the fluorescence labelling intensity. CD34+ cells and their subpopulations were expressed as percentage of total PBMCs. In some experiments PBMCs were labelled with PE-conjugated anti-AC133 monoclonal antibodies (Miltenyi Biotech, Bergisch Gladbach, Germany).
Flow cytometry analysis was carried out using software gating on lymphocytes. At least 105 gated events were acquired for each determination.
For the colony forming unit (CFU) assay, PBMCs were seeded at 3×105 cells·mL−1·dish−1 (Falcon 1008; Becton Dickinson) in 0.9% methylcellulose and 40% foetal calf serum (Gibco, Grand Island, NY, USA) in Iscove's modified Dulbecco's medium (Gibco), which was supplemented with 1.5 IU·mL−1 erythropoietin for erythrocyte burst-forming units (E-BFU) colonies and 10 ng·mL−1 of both granulocyte-monocyte colony-stimulating factor and G-CSF for granulocyte-monocyte CFU (GM-CFU) colonies. Colonies were counted under an inverted microscope after 14–16 days of culture.
For endothelial progenitor colony assay, PBMCs were resuspended in EndoCultTM liquid medium (Stem Cell Technologies, Vancouver, BC, Canada) and plated (5×106 cells) on fibronectin-coated 6-well dishes. After 2 days of culture at 37°C, nonadherent cells were collected and 1×106 cells·well−1 were plated in duplicate on fibronectin-coated 24-well dishes. After 3–5 additional days of culture, endothelial cell CFUs (EC-CFU) were counted under an inverted microscope.
Biochemical analyses
These assays were performed in 17 COPD patients and six control subjects. Aliquots of serum were prepared and stored at −80°C for determination by immunoassay (ELISA, R&D Systems, Minneapolis, MN, USA) of the following. 1) Flt3 ligand and kit ligand (KL), both acting on early haemopoietic stages (detection limit: 5.0 pg·mL−1 for both) 26. 2) Vascular endothelial growth factor (VEGF), as a marker of tissue hypoxia and angiogenesis (detection limit: 5.0 pg·mL−1) 27. 3) Hepatocyte growth factor (HGF), a mediator known to activate proliferation and migration of endothelial cells and induce angiogenesis 28 (detection limit: 20 pg·mL−1). 4) TNF-α (detection limit 0.2 pg·mL−1), and IL-8 (detection limit: 0.2 pg·mL−1) as markers of systemic inflammation. As well as IL-6 (detection limit: 0.16 pg·mL−1), which is known to be released during prolonged exercise 29. The serum concentration of cortisol and muscle enzymes (lactic dehydrogenase, creatine phosphokinase) as markers of muscle damage was determined using standard methods.
Statistics
Data are expressed as means±sd. ANOVA and t-test or Wilcoxon test were used to compare experimental conditions. Paired t-tests were used in each group to compare baseline and post-exercise data. Unpaired t-tests were used to compare the COPD and control groups. When data appeared to be abnormally distributed, Wilcoxon or Mann-Whitney U-tests were used for paired or unpaired comparisons, respectively. Linear regression was used to assess relationships between variables. The level of significance was set at p<0.05.
RESULTS
Subjects and functional data
Table 1⇑ summarises anthropometric and pulmonary function data and arterial blood gas measurements. COPD patients showed moderate-to-severe functional deterioration. During maximal exercise stress test (table 2⇓) COPD patients attained lower V′O2, V′E and HR at peak exercise than controls.
Exercise data# in chronic obstructive pulmonary disease (COPD) patients and control subjects
Endurance test
Mean±sd workload was 133±18 W in controls, and 92±15 W in COPD patients (p<0.001 by unpaired t-test). All normal subjects and 17 COPD patients completed the 20-min exercise test. One patient stopped at 10 min because of intolerable dyspnoea.
Red blood cells and platelet counts were similar in the control subjects and COPD patients, both pre- and post-exercise (table 3⇓). A slightly anaemic state (haemoglobin concentration <13.5 mg·dL−1) was found in one COPD patient and one control subject.
Blood cell counts in control subjects and in chronic obstructive disease(COPD) patients at baseline (BL) and after endurance exercise (Exe)
White blood cell (WBC) counts were in the normal range in both groups. However, COPD patients showed slightly higher WBC (fig. 1a⇓) and neutrophil differential counts compared with controls at baseline (table 3⇑). The latter difference between groups was not found in the post-exercise samples.
a) White blood cells (WBC) and b) CD34+ cells at baseline (BL) and after endurance exercise (Exe) in chronic obstructive pulmonary disease (COPD) patients (•) and in control subjects (○). Note the marked uniform reduction in CD34+ cells in COPD patients compared with the control subjects. *: p<0.001, COPD versus controls.
Circulating CD34+ cells, clonogenetic assays and haemopoietic growth factors
Circulating CD34+ cells as the percentage of lymphocytes were approximately three times lower in the COPD patients when compared with the normal subjects at rest (0.22±0.19 versus 0.57±0.26%), and were unaffected by endurance exercise in either group (COPD: 0.21±0.16%; controls: 0.61±0.28%). These differences were of the same magnitude when CD34+ cells were expressed as absolute numbers per μL blood volume, both at rest (3.3±2.5 versus 10.3±4.2; p<0.001) and after endurance exercise (3.8±3.1 versus 11.2±5.4; p<0.001; fig. 1b⇑). In addition, double labelling experiments with anti-CD34 and anti-CD38 or anti-HLA-DR monoclonal antibodies have been performed to allow the identification of immature (34+/38− and 34+/HLA-DR-) and mature (34+/38+ and 34+/HLA-DR+) haemopoietic progenitors 7. CD34+ cell subpopulations (34+/38-, 34+/38+, 34+/HLA-D-, 34+/HLA-DR+) were uniformly decreased in COPD patients compared with the controls (figs 2⇓, 3⇓; table 4⇓). The endurance exercise did not change the number of circulating CD34+ cells (fig. 4⇓; table 4⇓).
Representative flow cytometry analyses of CD34+ subpopulations in one control subject (a–d) and two chronic obstructive pulmonary disease patients (e–l), at rest. Peripheral blood mononuclear cells have been labelled either with irrelevant mouse immunoglobulins conjugated with: phycoerythrin (PE); fluorescein isothiocyanate (FITC) fluorochromes; PE-conjugated anti-CD34+ monoclonal antibodies (mAb) and FITC-conjugated anti-human lymphocyte antigen-DR; FITC-conjugated anti-CD45; or FITC-conjugated anti-CD38 mAb.
Representative flow cytometry analyses of CD34+ subpopulations in one control subject (a–d) and two chronic obstructive pulmonary disease patients (e–l), after endurance exercise. Peripheral blood mononuclear cells have been labelled either with irrelevant mouse immunoglobulins conjugated with: phycoerythrin (PE); fluorescein isothiocyanate (FITC) fluorochromes; PE-conjugated anti-CD34+monoclonal antibodies (mAb) and FITC-conjugated anti-human lymphocyte antigen-DR; FITC-conjugated anti-CD45; or FITC-conjugated anti-CD38 mAb.
a) Erythrocyte burst forming units E-BFU; b) plasma Flt3 ligand; c) granulocyte-monocyte colony-forming units (GM-CFU); and d) plasma kit ligand, at baseline (BL) and after endurance exercise (Exe) in chronic obstructive pulmonary disease (COPD) patients (░) and in control subjects (□). Note the marked reduction in E-BFU and GM-CFU in COPD patients at BL and after Exe compared with normal subjects. *: p<0.05 COPD versus controls; #: p<0.05 Exe versus BL.
CD34+ subpopulations# in control subjects and in chronic obstructive pulmonary disease patients (COPD) at baseline (BL) and after endurance exercise (Exe)
In some COPD patients (n = 4, 22% of the sample) CD34+ cell counts were in the normal range (0.56±0.14% of lymphocytes) as opposed to the mean value of 0.12±0.03% in the rest of the COPD group (n = 14). The patients with normal CD34+ cell counts could not be identified based on anthropometric characteristics or COPD severity. They only showed a trend towards a higher V′O2peak (21.5±3.1 versus 18.9±2.1 mL·kg−1·min−1; p = 0.07) and lower plasma TNF-α levels (rest: 1.78±0.79 versus 2.30±1.22 pg·mL−1; post-exercise: 1.11±0.11 versus 1.96±0.77 pg·mL−1, p<0.05).
Given the decrease in the number of circulating CD34+ cells in COPD patients, the current authors evaluated whether the number of circulating haemopoietic progenitor cells, as measured by standard clonogenetic assays, were correspondingly decreased. COPD patients displayed a significantly reduced number of CFUs compared with the controls (fig. 4a⇑ and 4c⇑). In both groups, E-BFU and GM-CFU numbers, after endurance exercise, were similar to those observed at rest (fig. 4a⇑ and 4c⇑). It is of interest to note that the majority of COPD patients displayed not only a reduced colony number, but also smaller E-BFU and GM-CFU compared with the controls (fig. 5⇓). In figure 5⇓ the representative pictures of individual E-BFU and GM-CFU colonies derived from the blood of a control subject (fig. 5c⇓), a COPD patient with a normal CD34+ cell count (fig. 5b⇓) and a COPD patient with a low CD34+ cell count (fig. 5a⇓) are shown. The size of individual E-BFU colonies (each included in a separate box) and of GM-CFU colonies are smaller in COPD patients with low CD34+ cell counts (fig. 5a⇓, observe the three individual E-BFUs and the two GM-CFU colonies), compared with those observed for E-BFU and GM-CFU colonies derived from normal controls (fig. 5c⇓) or COPD patients with normal CD34+ cell count (fig. 5b⇓).
Representative pictures of single colonies of erythrocyte burst forming units (E-BFU) and granulocyte-monocyte colony-forming units (GM-CFU) obtained in clonogenetic culture from the following. a) A chronic obstructive pulmonary disease (COPD) patient with a low CD34+ cell count. b) A COPD patient with a normal CD34+ cell count. c) A control subject. For E-BFU each box represents an individual E-BFU colony, therefore, the E-BFU colonies from the COPD patient with low CD34+ cells (a) are markedly smaller than those observed in controls (c) or in a COPD patient with normal CD34+ cell count (b).
Given the reduced number of circulating haemopoietic progenitors in COPD, the current authors evaluated the plasma concentration of several cytokines normally involved in the survival and proliferation of haemopoietic progenitors. In this context, the current authors' focused on the Flt3 ligand and KL. Flt3 ligand expression on CD34+ cell surface did not differ between COPD patients and controls (data not shown). Plasma Flt3 ligand concentration was similar in COPD patients and controls at baseline; it increased significantly after endurance exercise in COPD patients only (fig. 4b⇑). Plasma KL levels, did not differ between groups or experimental conditions (fig. 4d⇑).
In the entire group of subjects studied (i.e. COPD patients and controls) circulating CD34+ cell counts correlated directly with V′O2peak (fig 6d⇓; r2 = 0.37, p<0.05), resting Pa,O2 (6a; r2 = 0.30, p<0.05) and with the severity of airway obstruction assessed as forced expiratory volume in one second (FEV1)/forced vital capacity (6c; r2 = 0.39; p<0.05). No correlation was found between CD34+ cell counts and carbon dioxide arterial tension (fig. 6b⇓). The r2 values were calculated for the entire group of subjects studied (i.e. COPD patients and controls combined).
Correlations between CD34+ versus: a) arterial oxygen tension (Pa,O2; r2 = 0.30, p<0.05); b) carbon dioxide arterial tension (Pa,CO2); c) forced expiratory volume in one second (FEV1)/forced vital capacity (FVC); and d) peak oxygen uptake (V′O2peak). •: chronic obstructive pulmonary disease (COPD) patients; ○: control subjects. 1 mmHg = 0.133 kPa.
Circulating AC133+ cells, endothelial cell progenitors and angiogenetic growth factors
Circulating AC133+ cells, in COPD patients at rest, were approximately half the value found in control subjects and were unaffected by endurance exercise in either group (fig. 7a⇓). The decrease in AC133+ cells was also evident when expressed as absolute cell count per μL of blood volume both at rest (COPD: 2.5±1.7 cells·μL−1; control: 6.1±3.0) and after endurance exercise (COPD: 2.7±1.8 cells·μL−1; control: 6.5±3.1 cells·μL−1). Weak but significant direct relationships were found in the entire group between baseline AC133+ cell counts and Pa,O2 (r2 = 0.21, p<0.05), FEV1 (r2 = 0.19, p<0.05) and the fitness level expressed as maximal load in W (r2 = 0.236, p<0.05).
a) AC133+ cells, b) plasma vascular endothelial growth factor (VEGF), c) endothelial cell colony-forming units (EC-CFU, reported as colony number per mL of blood) and d) plasma hepatocyte growth factor (HGF), at baseline (BL) and after endurance exercise (Exe), in chronic obstructive pulmonary disease (COPD) patients (░) and in control subjects (□). Note the marked reduction in AC133+ and EC-CFU cells in COPD patients versus control subjects, and the increase in plasma HGF in COPD patients at BL and at Exe compared with normal subjects. In addition note the increase in plasma VEGF levels in COPD patients at Exe compared with COPD at BL. *: p<0.05, COPD versus controls; #: p<0.05, Exe versus BL.
A consistent decrease in the number of circulating endothelial progenitors per mL of blood in COPD patients was also found. A specific clonogenic assay showed that their number was significantly decreased in COPD patients at rest (COPD patients: 18.2±7.2 EC-CFU ·mL−1 of blood; control subjects: 30±4 EC-CFU ·mL−1 of blood) and after exercise (COPD patients: 20.1±8.4 CFU-EC·mL−1 of blood; control subjects: 32.2±8.2 EC-CFU ·mL−1 of blood; fig. 7c⇑).
As for changes in plasma concentration of endothelial growth factors, VEGF and HGF showed some marked and interesting differences (fig. 7b⇑ and d). Plasma VEGF concentration was higher in COPD patients than in control subjects at rest (COPD patients: 69±68 pg·mL−1; control subjects: 26±8 pg·mL−1), and increased further after exercise (COPD patients: 201±205 pg·mL−1; control subjects: 27±2 pg·mL−1). Plasma HGF levels at rest were higher in COPD patients when compared with the control subjects, but remained unchanged in either group after exercise (fig. 7d⇑). HGF, but not VEGF, levels correlated inversely with the results of clonogenetic tests (fig. 8⇓).
Correlation between plasma hepatocyte growth factor (HGF; a, c, e) and vascular endothelial growth factor (VEGF; b, d, f) versus a) erythrocyte burst forming units (E-BFU: r2 = 0.55, p<0.0001); b) E-BFU (r2 = 0.10, p = 0.06, not significant); c) granulocyte-monocyte colony-forming units (GM-CFU: r2 = 0.64, p<0.0001); d) GM-CFU (r2 = 0.10, p = 0.06, not significant); e) endothelial cell colony-forming units (EC-CFU: r2 = 0.46, p<0.0005); and f) EC-CFU (r2 = 0.09, not significant). ○: chronic obstructive pulmonary disease (COPD) patients at baseline; •: control subjects at baseline; ▵: COPD patients after exercise; ▴: control subjects after exercise. The r2 values are for the entire group of subjects studied (i.e. COPD patients and control subjects combined).
Other biochemical measurements
Muscle enzymes (lactate dehydrogenase and creative kinase) and cortisol levels were similar in COPD patients and control subjects and remained unchanged in post-exercise samples (table 5⇓). Plasma TNF-α concentration did not differ significantly between COPD and control groups, even though some differences were found between COPD patients with normal and low CD34+ cell counts as reported previously in the results section.
Biochemical analyses on plasma/serum in chronic obstructive pulmonary disease (COPD) patients and control subjects at baseline (BL) and after endurance exercise (Exe)
Plasma IL-6 levels were increased in COPD patients compared with controls (p<0.01 by ANOVA; table 5⇑). IL-8 values did not differ significantly between groups but showed a large dispersion, with some COPD patients showing very high plasma concentrations at rest.
DISCUSSION
In COPD patients with moderate-to-severe respiratory impairment, blood cell counts were normal while circulating haemopoietic and endothelial progenitor counts were greatly decreased, when compared with control subjects. The number of progenitor-derived colonies was correspondingly low (-30– -50%) in the COPD group. However, ∼20% of COPD patients, clinically and functionally similar to the rest of the group, showed normal progenitor counts associated with less inflammatory activity as estimated by plasma TNF-α concentrations. Endurance exercise did not affect circulating CD34+ cells in either COPD patients or control subjects. The post-exercise increase in plasma VEGF suggested activation of the hypoxic pathway in COPD patients, but not in the control subjects. The endurance exercise in COPD patients appears to make the initial hypoxic condition, observed at rest, more severe and, therefore, stimulates VEGF release. In the entire sample, circulating progenitor counts correlated directly with V′O2peak and indices of COPD severity such as FEV1 and Pa,O2 tension. Overall, the current data indicates that the bone marrow is an important, previously unrecognised, systemic target in the pathophysiology of COPD.
To the best of the authors' knowledge, this study is the first to report that circulating progenitors are decreased in moderate-to-severe COPD. However, the current data only allow the indirect estimation of haemopoietic function, and detailed investigations on possible mechanism(s) will require invasive bone marrow sampling. Despite this limitation, the current results do provide some information. Normal peripheral blood cell counts in COPD patients do not support decreased cell production and/or release, as a likely explanation for the current authors findings, at least where the haemopoietic compartment is concerned. WBC counts were higher in COPD patients than control subjects and platelet counts were in the normal range. Only one subject in each group showed slightly reduced haemoglobin concentration, confirming the low prevalence of anaemia in COPD 5, whereas 80% of the COPD patients showed greatly reduced CD34+ cells compared with the control subjects.
Low circulating progenitor counts may be secondary to defects in cell mobilisation mechanisms. The current authors tested this hypothesis, but found normal expression of adhesion molecules implicated in progenitor homing and migration (very late activation antigen-4 (VLA-4), chemokine (CC motif) receptor 5 (CCR5), C-X-C motif chemokine receptor 4 (CXCR4)) on CD34+ cells, lymphocytes and monocytes of COPD patients (unpublished observations: Testa U., Istituto Superiore di Sanita', Rome, Italy). The data in COPD patients, herefore, mimicked the low proliferation of CD34+ cells recently found in patients with chronic ischemic heart disease 18, which occurred in the absence of obvious mobilisation defects.
The present authors also tested whether insufficient haemopoietic stimulation may occur in COPD patients. Plasma Flt3 ligand and KL concentrations, both being important haemopoietic growth factors 26, were similar in COPD patients and controls. Furthermore, Flt3 ligand concentrations increased after exercise in COPD patients, similar to data obtained in athletes after intense exercise 20, 21. No difference was found in Flt3 ligand expression on CD34+ cells or monocytes between COPD and controls (data not shown), discounting the possibility that the increase in Flt3 ligand could be secondary to a lack of receptors in COPD patients. Altogether, insufficient bone marrow stimulation in COPD is not supported by the current results.
Inflammatory mediators could be involved in the pathogenesis of low circulating precursor counts in COPD. The evidence in favour of this hypothesis is that COPD patients with CD34+ cells in the normal range tended to show lower TNF-α values. In addition, IL-6 and IL-8 concentrations were, on average, higher in COPD patients than in the control subjects. No clear relationship was found between inflammatory marker concentrations and circulating progenitors. Therefore, more data are necessary to confirm the role of inflammation in modulating CD34+ cells in COPD.
Circulating EPCs were also assessed in the current study, with a special regard to exercise, since it is a known physiological stimulus for their release 22. Similar to haemopoietic cells, EPCs decreased in COPD patients and showed decreased proliferation when compared with the control subjects. A decreased number of EPCs was also observed in other pathological conditions, including coronary artery diseases 17, chronic ischemic heart disease 18, congestive heart failure 30, rheumatoid arthritis 31 and haemodialysis patients 32, all these conditions are associated with an increased cardiovascular risk. It was suggested in these pathological conditions that the decreased number of circulating EPCs might be related to impaired neovascularisation and could contribute to the increased cardiovascular risk observed in these conditions. Importantly, a recent study by Werner et al. 33 provided clear evidence that the level of circulating EPCs predicts the occurrence of cardiovascular events and death from cardiovascular causes and helps to identify patients who are at an increased cardiovascular risk. The same could apply for COPD patients. In congestive heart failure 30 and rheumatoid arthritis 31, it was proposed as playing an inhibitory role for TNF-α. The biochemical mechanisms responsible for the decreased EPC number in COPD patients remains to be determined.
Exercise did not increase EPCs in either group, possibly because of insufficient intensity and/or duration of the test. However, the pattern of release of pro-angiogenetic factors differed greatly between COPD patients and controls. COPD patients showed two-fold increase in VEGF and HGF levels compared with the control subjects at rest, but only VEGF increased further after exercise. HGF, but not VEGF, concentrations correlated inversely with the results of the clonogenic tests. Both VEGF 27 and HGF 28 are pro-angiogenetic factors, but their action profiles are different. VEGF is a marker of activation of the hypoxic pathway 34, and its increase in COPD patients suggests the occurrence of tissue hypoxia, especially post-exercise.
HGF is a growth factor for hepatocytes, melanocytes, keratinocytes and endothelial cells 35, and is a pulmotrophic factor for the regeneration of an injured lung 36, 37. Through its c-met receptor, HGF exerts multiple biological activities, such as stimulation of epithelial alveolar proliferation and mobility 38, and the induction of branching tubule formation. In the lung, alveolar macrophages, endothelial cells 39, bronchial cells 40 and fibroblasts 38 produce HGF. Due to the increased secretion in an injured lung, HGF is presumed to have an important role in the wound healing of pulmonary epithelium 41. Thus, plasma HGF levels have been found to increase in vascular occlusion 42, COPD 43, lung inflammatory diseases 44 and idiopathic lung fibrosis 43. In addition to the effect of HGF on alveolar epithelium, HGF stimulates the recruitment of EPCs in the injured lung and stimulates the proliferation of bone marrow derived and resident endothelial cells 45. The stimulatory effect of HGF on endothelial proliferation is greatly potentiated when it acts in combination with VEGF 46.
In addition to the increase in angiogenetic mediators, progenitor counts showed a relationship with the severity of hypoxaemia. The effects of low oxygen tensions on progenitors in vivo are poorly defined, but the human bone marrow is known to be a relatively hypoxic environment under physiological conditions 47. In addition, hypoxic gradients may be important in regulating progenitor trafficking 48. Exposure to hypoxia in vitro increased the maturation rate of CD34+ cells, while maintaining early precursors in a quiescent state 23, 24. The current authors did not observe preferential release of less immature precursors in more hypoxaemic COPD patients; rather, all CD34+ subpopulations tested were uniformly decreased (table 4⇑).
Depression in the number and function of circulating progenitors also correlated with the severity of airway obstruction and the degree of physical fitness, suggesting that depletion of CD34+ cells may be proportional to COPD severity. A large number of patients with COPD at different stages need to be studied to confirm this hypothesis.
Finally, CD34+ cells may be low in COPD patients due to an increase in peripheric utilisation. The current authors hypothesise that a high turnover of precursors may occur in COPD, possibly related to tissue repair. Skeletal muscle may be a potential target tissue for progenitors for the following reasons. 1) CD34+ cells can migrate into muscle connective tissue and satellite cell niches 49. 2) Exercising mice showed a higher percentage of bone marrow-derived muscle cells compared with sedentary mice 10, indicating precursor engraftment in response to muscle injury. In the current authors' previous study, decreased CD34+ cell counts were found a few hours after a marathon race, suggesting peripheral utilisation of precursors 20. Alternatively, decreased EPCs in COPD patients may blunt the increase in muscle perfusion evoked by hypoxia 27. Unfortunately, muscle biopsies were not obtained in the present study and association between low-progenitor counts and muscle damage remains speculative.
The major limitation of the present study is that the group of subjects studied was small and far from representative of the entire clinical spectrum of COPD. Nevertheless, the difference in CD34+ cells between COPD patients and age-matched controls was large, indicating a likely relevant effect of the disease on circulating precursors.
In conclusion, circulating CD34+ cells and endothelial progenitor counts were decreased in most patients with moderate-to-severe chronic obstructive pulmonary disease and correlated with hypoxaemia, severity of airway obstruction, and peak oxygen consumption. The current data suggests a possible link between systemic inflammation and a decrease in circulating progenitors, as suggested in other pathological conditions. The current authors conclude that bone marrow should be considered as a previously unrecognised systemic target of chronic obstructive pulmonary disease.
- Received October 22, 2004.
- Accepted October 15, 2005.
- © ERS Journals Ltd
References
