Impact of heterozygote CFTR Mutations in COPD patients with Chronic Bronchitis

UAB Institutional Review Board approved the use of human cells. Primary human bronchial epithelial cells (HBE) were obtained from lung explants. Genetic analysis was performed to identify cells with expression of wild type CFTR (CFTR +/+) and those heterozygous for non-functional (i.e. F508del) CFTR mutations (CFTR +/-) following previously described methods [28]. After expanding isolated HBE cells, first or second passage cells were seeded on permeable support filters (Corning, Lowell, MA) coated with NIH 3 T3 fibroblast conditioned media. HBE cells were grown in differentiating media for 6 weeks until terminally differentiated, as previously described [14].

HBE cells were exposed to WCS from one 3R4F research cigarette (University of Kentucky, Lexington, KY) for 10 min. WCS was generated via an automated cigarette smoke generator (Scireq InExpose model, Toronto, Canada) at 1 puff/min at a flow rate of 3 L/min, as previously described [19]. Controls cells were similarly exposed to room air.

CFTR-dependent short circuit current was measured in Ussing chambers under voltage clamp conditions using MC8 voltage clamps and P2300 Ussing chambers (Physiologic Instruments, San Diego, CA) [14]. CFTR activity was measured by the change in Isc upon stimulation with forskolin (10 μM) in the setting of amiloride (100 μM). A Cl^- secretory gradient was used, where indicated; CFTR_Inh-172 (10 μM) was used to confirm CFTR dependence [29].

Animal protocols were approved by the UAB Institutional Animal Care and Use Committee. Age and sex matched congenic C57BL/6 J mice expressing wild type CFTR (CFTR +/+) or heterozygous for CFTR knock out (CFTR +/-, C57BL/6 J Cftrtm1Unc/J) were used. Mice were exposed in whole-body chambers (28″ × 19″ × 15″) to mainstream cigarette smoke (200 μg/l of total particulate matter, 35-ml puffs of 2-s duration at a rate of 3 L/sec each minute for 20 min) from 4 3R4F reference cigarettes (Univ. of Kentucky, Lexington, KY) twice daily for 2 weeks using an automated cigarette smoking apparatus (SCIREQ, InExpose model, Toronto, Canada). Control mice were exposed to room air under similar conditions [19, 30].

Murine CFTR function was assessed by nasal potential difference measurements. Under anesthesia, CFTR-dependent anion transport was measured in the murine nasal epithelium as a change in potential difference following perfusion with chloride free forskolin (10 μM) in the setting of amiloride (100 μM), as previously described [19, 29].

Mice were euthanized and tracheas were harvested by clean surgical techniques. Tracheal epithelia were mounted and tested as full-thickness tissue. Isc was measured under voltage clamp conditions as performed in cells using P2307 Ussing chamber sliders. Mounted tissues were bathed on both sides with identical Ringers solutions gassed with 95% O₂:5% CO₂ and then treated with amiloride (100 μM) followed by the CFTR agonists forskolin (10 μM) and IBMX (100 μM); bumetanide (10 μM) and glybenclamide (100 μM) were added to the mucosal solution at the end of experiments to block CFTR-dependent Isc. Results are expressed as the change in Isc with agonist stimulation [19, 31].

We performed a case control study to detect the prevalence of CFTR mutations in COPD patients with symptoms of chronic bronchitis. The UAB IRB approved use of clinical specimens for the research study. COPD cases were selected from participants in the NIH COPD Clinical Research Network’s Azithormycin in COPD Study who had blood stored for genetic analysis [32]. Cases were non-Hispanic Caucasians, age 40 to 80 with FEV₁/FVC < 0.70 and FEV₁ < 60% predicted, and chronic bronchitis defined by productive cough “most days a week” or “several days of the week” on the St. George Respiratory Questionnaire (SGRQ). The control population was 32,900 Caucasian women who had CFTR analyzed for prenatal genetic testing, N = 32,900. No further demographic characteristics are available for this population.

DNA testing was performed by the Baylor College of Medicine Genetics Laboratory using a CFTR related disorders mutation panel. This is an allele-specific genotyping technique for 89 mutations (Table 1) performed by MALDI-TOF mass spectrometry and includes testing for mutations common in human populations and reflex testing of the 5 T allele. The method has an 88% CFTR mutation detection rate in the non-Hispanic Caucasian population. Additional data collected on COPD cases included age, sex, smoking status, smoking intensity (pack-years), FEV₁% predicted, and the number of COPD exacerbations requiring treatment in the year prior to enrollment in the azithromycin trial. The sample size of 127 patients had 80% power to detect a mutation rate in COPD patients of 10.5% as compared to a presumed frequency of 4.5% in controls with an alpha of 0.05.

Since smokers with and without COPD exhibit reduced CFTR mediated anion transport [14‐17, 19], and this is associated with chronic bronchitis [14, 15, 19], we hypothesized that acquired CFTR dysfunction may also be influenced by the presence of congenital CFTR mutations. As a test of this hypothesis, we exposed primary HBE cells heterozygous for the F508del CFTR mutation to whole cigarette smoke and compared this to the degree of CFTR decrement observed in HBE cells without CFTR mutations (e.g. wild-type expressing monolayers). As expected based on genotype-phenotype correlations in the disease [33], HBE cells derived from a F508del CFTR heterozygote had slightly lower CFTR activity at baseline than wild type monolayers as measured by response to forskolin stimulation (49.3 ± 11.5 μA/cm² in CFTR (+/+) vs. 40.5 ± 5.3 μA/cm² in CFTR (+/-), although this was not statistically significant (Figure 1A,B). WCS caused a pronounced reduction (27.3 ± 3.1 μA/cm²) in CFTR activity in CFTR (+/+) monolayers (P < 0.05), consistent with prior studies using WCS [17, 19, 30, 34, 35] and CSE [14, 36]. WCS also caused a significant decrement in CFTR (+/-) cells (18.8 ± 2.4 μA/cm²; P < 0.005). Both the relative decrement (44.7% vs. 53.5%, P < 0.93) and the degree of residual CFTR activity in CFTR (+/+) and CFTR (+/-) cells following WCS exposure (22.1 ± 3.0 μA/cm² in CFTR +/+ vs. 21.6 ± 3.8 μA/cm² in CFTR +/-) was indistinguishable, indicating the presence of a single F508del CFTR mutation did not meaningfully alter the CFTR decrement from environmental exposure to WCS in vitro.

To better understand findings in human bronchial epithelial cells and provide definitive evidence regarding the contribution of heterozygous CFTR mutations to cigarette smoke induced CFTR dysfunction, we next used an animal model of cigarette smoke exposure. Congenic wild type (CFTR +/+) and heterozygote (CFTR +/-, C57BL/6 J Cftrtm1Unc/J) CF57BL/6 J mice were exposed in whole body chambers to cigarette smoke twice daily for 2 weeks, and then CFTR activity was measured in the respiratory tract by nasal potential difference (NPD) and short circuit current analysis of freshly excised trachea. As expected based on genotype-phenotype correlations in the disease, and observed in prior NPD studies in humans [33], NPD in heterozygote CFTR (+/-) mice had slightly lower CFTR activity when compared to the wild type mice (-12.1 ± 1.8 mV in CFTR (+/+) vs. -8.7 ± 0.6 mV in CFTR (+/-)), although this was not statistically significant (P < 0.14, Figure 2). Cigarette smoke exposure caused a significant decrease in CFTR-mediated ion transport in the nasal airway that was similar in severity to the observations in HBE cells (Figure 2). WCS caused a pronounced reduction (-11.1 mV) in CFTR activity in CFTR (+/+) mice (P < 0.005), a finding recapitulated in CFTR (+/-) mice (-4.1 mV; P < 0.05). Although the absolute reduction in CFTR activity was less prominent in heterozygous mice, the residual cAMP dependent CFTR activity in CFTR (+/+) and CFTR (+/-) mice following WCS exposure were no different and favored heterozygous animals (-0.99 ± 2.07 mV in CFTR (+/+) vs. -4.57 ± 2.05 mV in CFTR (+/-), P = 0.26). Analysis of short-circuit current of excised trachea demonstrated a similar trend, with reduced CFTR dependent ion transport observed in both wild type and heterozygous trachea following WCS exposure that was not meaningfully different (Figure 3). The lack of statistically significant reduction in trachea CFTR activity following a 2-week exposure to WCS is consistent with previously reported data since this tissue exhibits time-dependent decrements [19]. Taken together, these data provide evidence that heterozygosity imposed by the presence of one CFTR mutation does not increase the susceptibility or magnitude of CFTR dysfunction following cigarette smoke exposure.

The lack of the expected increase in susceptibility to cigarette smoke induced CFTR dysfunction due to the absence of one copy of CFTR prompted us to determine the prevalence of CFTR mutations among COPD patients with chronic bronchitis in comparison to the general Caucasian population. We evaluated 127 individuals with COPD and chronic bronchitis who participated in the Azithromycin in COPD Study sponsored by the COPD Clinical Research Network [37]. To enrich the population for those likely to exhibit CFTR abnormality, and assure best matching with our control group, we restricted the analysis to individuals with COPD, chronic bronchitis and of Caucasian descent. As shown in Table 2, the population had a slight male predominance, and 25% were current smokers. The mean FEV₁% predicted reflected a moderate to severely ill population. There was a high frequency of health care utilization for respiratory symptoms and pulmonary exacerbations. Five of the 127 subjects (3.9%) had detectable CFTR mutations based on a genetic panel containing 89 mutations. The frequency of CFTR mutations among those with COPD and chronic bronchitis was no different than the mutation rate seen in the control population (1356 of 32900, 4.1%; P = NS; Table 3). Limiting the analysis to the F508del CFTR mutation, only 2 (1.5%) of cases were positive, which was again no different than controls (2.7%; P = NS).