Targeting TRP channels in airway disorders.

Novel effective therapeutic agents are actively sought for the treatment of a broad spectrum of respiratory diseases which collectively significantly impact on mortality, morbidity and quality of life of hundreds of millions of people world-wide. These include asthma, allergic rhinitis, chronic obstructive pulmonary disease, cough, idiopathic pulmonary fibrosis, pulmonary arterial hypertension, cystic fibrosis and acute lung injury. TRP channels are broadly distributed throughout the respiratory tract and play an important physiological role in sensing and subsequently responding to a wide variety of stimuli, for example temperature, osmolarity and oxidant stress. In the context of respiratory disease however TRP channel function may be altered, eg: under conditions of oxidative stress, inflammation, hypoxia and mechanical stress. In addition there is evidence that the expression/activity of TRP channels can be affected in the disease setting. Modulators of TRP channel function are therefore under investigation for a range of diseases including disorders of the respiratory system. Several excellent review articles have discussed in detail evidence that modulation of specific TRP channels may be of benefit in specific respiratory diseases. In this article we have taken the approach of reviewing evidence that modulation of TRP channel function may be able to affect common and over-lapping characteristic features of respiratory diseases, for example bronchoconstriction, airways hyper-responsiveness, cough, airways inflammation, mucus hyper-secretion, exacerbations, lung injury, hypoxia and airways re-modelling. The therapeutic potential of TRP channel modulators, the status of these agents in the clinic along with the challenges posed in this rapidly advancing field are also discussed in this review.

Involvement of IL-13 in tobacco smoke-induced changes in the structure and function of rat intrapulmonary airways.

Chronic obstructive pulmonary disease (COPD) involves disease of small airways with an increase in airway smooth muscle sensitivity to spasmogens and with structural changes described as airway remodeling. We investigated the effect of tobacco smoke (TS) exposure on the structure and function of small airways in rats and the role of IL-13 in this response. Precision-cut lung slices (230-280 microm) were prepared from male Sprague-Dawley rats after acute (3 d) or chronic (8 or 16 wk) daily exposure to TS or air. Carbachol (CCh) and 5-hydroxytryptamine (5HT) concentration responses were performed on airways (50-400 microm diameter). The effect of IL-13 in vitro on small airway sensitivity to CCh and 5HT was also determined. Acute exposure to TS did not affect the sensitivity of the intrapulmonary airways to either spasmogen. After 8 weeks of TS exposure, airway hyperresponsiveness (AHR) to CCh was evident (log EC(50) CCh: air = 0.22 microM; TS = -0.12 microM; P = 0.019); AHR to 5HT was also observed after the 16-week exposure to TS (air = -0.85 microM; TS = -1.06 microM; P = 0.038). Chronic TS exposure increased airway wall SMA content, which correlated with increased expression of IL-13 and transforming growth factor (TGF)-beta(1) in the lung tissues. In vitro incubation with IL-13, but not TGF-beta(1), induced changes in small airway sensitivity to CCh and 5HT. Chronic TS exposure induces increased responsiveness in intrapulmonary airways of rats that may be mediated in part by an increase in IL-13.

Expression of transient receptor potential C6 channels in human lung macrophages.

Chronic obstructive pulmonary disease (COPD) is associated with pulmonary inflammation with increased numbers of macrophages located in the parenchyma. These macrophages have the capacity to mediate the underlying pathophysiology of COPD; therefore, a better understanding of their function in chronic inflammation associated with this disease is vital. Ion channels regulate many cellular functions; however, their role in macrophages is unclear. This study examined the expression and function of transient receptor potential (TRP) channels in human macrophages. Human alveolar macrophages and lung tissue macrophages expressed increased mRNA and protein for TRPC6 when compared with monocytes and monocyte-derived macrophages. Moreover, TRPC6 mRNA expression was significantly elevated in alveolar macrophages from patients with COPD compared with control subjects. There were no differences in mRNA for TRPC3 or TRPC7. Although mRNA for TRPM2 and TRPV1 was detected in these cells, protein expression could not be determined. Fractionation of lung-derived macrophages demonstrated that TRPC6 protein was more highly expressed by smaller macrophages compared with larger macrophages. Using whole-cell patch clamp electrophysiology, TRPC6-like currents were measured in both macrophage subpopulations with appropriate biophysical and basic pharmacological profiles. These currents were active under basal conditions in the small macrophages. These data suggest that TRPC6-like channels are functional on human lung macrophages, and may be associated with COPD.

Membrane capacitance and conductance changes parallel mucin secretion in the human airway epithelium.

Measurement of the magnitude and kinetics of exocytosis from intact epithelia has historically been difficult. Using well-differentiated cultures of human bronchial epithelial cells, we describe the use of transepithelial impedance analysis to enable the real-time quantification of mucin secretagogue-induced changes in membrane capacitance (surface area) and conductance. ATPgammaS, UTP, ionomycin, and PMA induced robust increases in total cellular capacitance that were demonstrated to be dominated by a specific increase in apical membrane surface area. The UTP-induced increase in capacitance occurred in parallel with goblet cell emptying and the secretion of mucin and was associated with decreases in apical and basolateral membrane resistances. The magnitude and kinetics of the capacitance increases were dependent on the agonist and the sidedness of the stimulation. The peak increase in capacitance induced by UTP was approximately 30 mucin granule fusions per goblet cell. Secretagogue-induced decreases in apical membrane resistance were independent of exocytosis, although each of the secretagogues induced profound reductions in basolateral membrane resistance. Transepithelial impedance analysis offers the potential to study morphological and conductance changes in cultured human bronchial epithelial cells.

P2Y2-receptor-mediated activation of a contralateral, lanthanide-sensitive calcium entry pathway in the human airway epithelium.

1. Receptor-mediated calcium entry (RMCE) was examined in well-differentiated cultures of normal human bronchial epithelial cells (HBECs). Changes in intracellular free Ca(2+) ([Ca(2+)](i)) were quantified using fluorescence ratio imaging of Fura-2-loaded cells during perfusion with Ca(2+) mobilizing agonists. 2. Initial studies revealed an agonist potency of ATP=uridine triphosphate (UTP) >ADP=uridine diphosphate, consistent with purinergic activation of an apical P2Y(2)-receptor mediating the increase in [Ca(2+)](i) in HBECs. 3. Apical UTP (30 microm) induced a sustained period of elevated [Ca(2+)](i) between 300 and 600 s following agonist stimulation that extracellular Ca(2+) free studies indicated was dominated by Ca(2+) influx. 4. RMCE was inhibited by 100 nm La(3+) (83+/-3%) or Gd(3+) (95+/-7%) (P<0.005, n=4-11) and was partially attenuated by Ni(2+) (1 mm) (58.7+/-5.0%, P<0.005, n=9). 5. RMCE was also partially sensitive (< 25% inhibition, P<0.01) to the cation channel blockers SKF96365 (30 microm) and econazole (30 microm), but was insensitive to both verapamil (1 microm) and ruthenium red (10 microm). 6. Using either a sided Ca(2+) readdition protocol or unilateral La(3+), established that the RMCE pathway was located exclusively on the basolateral membrane. 7. The pharmacological sensitivity of the P2Y(2)-receptor activated Ca(2+) entry pathway in the human airway epithelium is inconsistent with the established profile of TRP channel families and is therefore likely to be of an as-yet uncharacterized molecular identity.

Preliminary pharmacological characterisation of an interleukin-13-enhanced calcium-activated chloride conductance in the human airway epithelium.

Interleukin (IL)-13 (10 ng/ml for 48 h) treatment of human bronchial epithelial cells induced a hypersecretory ion transport phenotype. Ussing chamber experiments demonstrated that this phenotypic change was characterised by an almost complete inhibition of the amiloride-sensitive short circuit current (ISC) and the appearance of an enhanced calcium-activated chloride conductance (CaCC). The peak increases in ISC (anion secretion) in response to UTP and ionomycin were increased by >8 fold and >13 fold respectively following IL-13 treatment. Changes in intra-cellular Ca(2+) levels following agonist exposure were not different between control and IL-13 treatments. The sensitivity of this IL-13-enhanced CaCC to several chloride channel-blocking molecules was determined following permeabilisation of the basolateral membrane and the establishment of a basolateral to apical chloride gradient. Under these conditions changes in ISC were regulated exclusively by the apical membrane and the current stimulated by ionomycin was sensitive to the chloride channel blockers diisothocyanatostilbene-2,2'-disulfonic acid (DIDS), dinitrostilben-2,2'-disulfonic acid (DNDS) and 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB) but was insensitive to tamoxifen. An understanding of the pharmacological profile of this conductance will ultimately aid in the determination of its molecular identity and function in the human airway epithelium.

Interleukin-13 induces a hypersecretory ion transport phenotype in human bronchial epithelial cells.

Interleukin (IL)-13 has been associated with asthma, allergic rhinitis, and chronic sinusitis, all conditions where an imbalance in epithelial fluid secretion and absorption could impact upon the disease. We have investigated the effects of IL-13 on the ion transport characteristics of human bronchial epithelial cells cultured at an apical-air interface. Ussing chamber studies indicated that 48 h pretreatment with IL-13 or IL-4 significantly reduced the basal short-circuit current (I(sc)) and inhibited the amiloride-sensitive current by >98%. Furthermore, the I(sc) responses were increased by more than six- and twofold over control values when stimulated with UTP or forskolin, respectively, after cytokine treatment. The IL-13-enhanced response to UTP/ionomycin was sensitive to bumetanide and DIDS and was reduced in a low-chloride, bicarbonate-free solution. Membrane permeablization studies indicated that IL-13 induced the functional expression of an apical Ca(2+)-activated anion conductance and that changes in apical or basolateral K(+) conductances could not account for the increased I(sc) responses to UTP or ionomycin. The results indicate that IL-13 converts the human bronchial epithelium from an absorptive to a secretory phenotype that is the result of loss of amiloride-sensitive current and an increase in a DIDS-sensitive apical anion conductance.