Effects of PM2.5 components in the release of amphiregulin by human airway epithelial cells.

Exposure to ambient particulate matter (PM) is responsible for airway inflammation and tissue remodeling. Urban PM(2.5) (aerodynamic diameter <2.5microm) is a complex mixture rich in soots and containing hydrosoluble and organic components. We previously showed that the exposure of airway epithelial cells to PM(2.5) triggers the release of amphiregulin (AR), ligand of the epidermal growth factor receptor (EGFR) involved in proinflammatory and repair responses. The effect of Paris PM(2.5) organic and aqueous fractions in AR expression and secretion was investigated on the bronchial epithelial cell line 16HBE and normal human nasal epithelial (NHNE) cells. Both a macroarray specific for inflammation pathways and RT-PCR showed an AR upregulation in organic extract-treated 16HBE cells. AR release is induced in 16HBE and NHNE cells grown on plastic and exposed to native PM(2.5), organic extract and to a lesser extent washed PM(2.5) (deprived of its hydrosoluble content) and aqueous extract. Furthermore, as assessed by using NHNE cells grown on Transwell inserts, this secretion is polarized toward the basolateral side where the EGFR is expressed. To conclude, both PM(2.5) organic and hydrosoluble components are involved in the expression and secretion of AR; organic compounds exhibiting a strong effect when they are easily bioavailable.

Responses of well-differentiated nasal epithelial cells exposed to particles: role of the epithelium in airway inflammation.

Numerous epidemiological studies support the contention that ambient air pollution particles can adversely affect human health. To explain the acute inflammatory process in airways exposed to particles, a number of in vitro studies have been performed on cells grown submerged on plastic and poorly differentiated, and on cell lines, the physiology of which is somewhat different from that of well-differentiated cells. In order to obtain results using a model system in which epithelial cells are similar to those of the human airway in vivo, apical membranes of well-differentiated human nasal epithelial (HNE) cells cultured in an air-liquid interface (ALI) were exposed for 24 h to diesel exhaust particles (DEP) and Paris urban air particles (PM(2.5)). DEP and PM(2.5) (10-80 microg/cm(2)) stimulated both IL-8 and amphiregulin (ligand of EGFR) secretion exclusively towards the basal compartment. In contrast, there was no IL-1beta secretion and only weak non-reproducible secretion of TNF-alpha. IL-6 and GM-CSF were consistently stimulated towards the apical compartment and only when cells were exposed to PM(2.5). ICAM-1 protein expression on cell surfaces remained low after particle exposure, although it increased after TNF-alpha treatment. Internalization of particles, which is believed to initiate oxidative stress and proinflammatory cytokine expression, was restricted to small nanoparticles (< or =40 nm). Production of reactive oxygen species (ROS) was detected, and DEP were more efficient than PM(2.5). Collectively, our results suggest that airway epithelial cells exposed to particles augment the local inflammatory response in the lung but cannot alone initiate a systemic inflammatory response.

TGF-beta 1 downregulates CFTR expression and function in nasal polyps of non-CF patients.

Nasal polyposis is a chronic inflammatory disease of the upper airways. It has been suggested that ion transports and CFTR expression could be modified in epithelial cells from nasal polyps of non-cystic fibrosis patients. We compared human nasal epithelial cells from nasal polyps (NP) with control nasal mucosa (CM). The level of CFTR mRNA was studied by Northern blot analysis and protein expression was studied by immunoprecipitation both ex vivo and in vitro in primary cultures of human nasal epithelial cells at the air-liquid interface. Ion transports were evaluated by short-circuit measurements in vitro. CFTR gene and protein expressions were significantly decreased in NP native tissues and in culture on day 4, when a global defect of ion transports was observed in NP cultures, but not in CM. We evaluated the effect of transforming growth factor (TGF)-beta 1 on CFTR expression and function in NP cultures on day 14 and showed, for the first time, that TGF-beta 1 was able to significantly downregulate the level of CFTR mRNA and cAMP-dependent current in NP cultures. Finally, we showed that the effects of TGF-beta 1 on ion transports could be reversed after 48-h removal of TGF-beta1 in NP cultures. In conclusion, our data strongly suggest that chronic inflammation in nasal polyposis downregulates CFTR gene and protein expression.

The toxicity of H2O2 on the ionic homeostasis of airway epithelial cells in vitro.

Oxygen species may be formed in the air spaces of the respiratory tract in response to environmental pollution such as particulate matter. The mechanisms and target molecules of these oxidants are still mainly unknown but may involve modifications of the ionic homeostasis in epithelial cells. Cytosolic concentrations of Ca2+ (Fura2) and Na+ (SBFI) and short-circuit current (Isc) were followed in primary cultures of human nasal epithelial cells and in the cell line 16HBE14o- after exposure to H2O2 or *OH (H2O2 + Fe2+). Cells were grown on glass coverslips for ionic imaging or on permeable snapwell inserts for Isc studies. Exposure of the apical as well as the basal side of the cultures to H2O2 or *OH induced a concentration-dependent transient increase in Isc which is due to a transient secretion of Cl-. Cai also increased transiently with approximately the same kinetics. The response was dependent on the release of calcium from intracellular stores. Nai on the contrary increased steadily over more than an hour. When the apical membrane was permeabilized with gramicidin, *OH inhibited the Na+ current (a measure of Na(+)-K(+)-ATPase activity in the baso-lateral membrane). The arrest of the pump was significant after 30 min exposure to oxidant. On the other hand no increase in the apical or baso-lateral sodium conductances could be detected. The progressive arrest of the Na+/K(+)-pump may contribute to the sustained elevation of Nai. This strong modification in the cellular ionic homeostasis may participate in the stress response of the respiratory epithelium through alterations in signal transduction pathways.

Effects of hydrogen peroxide and hydroxyl radicals on the cytosolic side of a non-selective cation channel in the cultured human bronchial epithelial cell line 16HBE14o-.

Respiratory tissues can be damaged by the exposure of airway epithelial cells to reactive oxygen species (ROS) that generate an oxidative stress. We studied the effects of the hydroxyl radical *OH, for which there is no natural intra- or extracellular scavenger, on a Ca2+-activated, non-selective cation channel (NSC(Ca)) which might participate in the transepithelial Na+ fluxes involved in the maintenance of the cytosolic [Na+] ([Na+]i). We identified and characterized NSC(Ca) in inside-out excised membrane patches from cells of the human bronchial cell line 16HBE14o- and exposed the cytoplasmic side of NSC(Ca) to H2O2 or *OH created in front of the patch pipette. In these cells, the NSC channel was Ca2+ (above 0.1 microM) and voltage dependent. The channel's low open probability ( P(o)) at hyperpolarized voltages increased rapidly to a very high value upon short exposure (seconds) to *OH or to H2O2 in a bath solution containing millimolar [Ca2+]. This sensibility to ROS was reversible on wash-out of the oxidants. Long exposure (several minutes) to *OH in a bath solution containing 10(-7) M Ca2+ activated the channel irreversibly, a finding that has pathophysiological implications. The functioning of the NSC(Ca) protein channel may be modified by the intracellular redox status and the reversibility of the sensitivity to ROS depends on [Ca2+]i. The role of NSC(Ca) channels in airway epithelia is not yet understood, but might conform to what might be expected of an NSC channel: increase in [Na]i following intracellular exposure to *OH or H2O2. Reversible or irreversible excessive opening of cation channels may induce gradual cellular responses, including changes in Na+/K+-ATPase activity, cell volume regulation, membrane polarization, activation of transcription factors required for the expression of genes of cytokines or chemokines, apoptosis and necrosis, thus triggering inflammation.