Odile Houcine

Diesel exhaust particles are taken up by human airway epithelial cells in vitro and alter cytokine production

The involvement of diesel exhaust particles (DEPs) in respiratory diseases was evaluated by studying their effects on two in vitro models of human airway epithelial cells. The cytotoxicity of DEPs, their phagocytosis, and the resulting immune response were investigated in a human bronchial epithelial cell line (16HBE14o-) as well as in human nasal epithelial cells in primary culture. DEP exposure induced a time- and dose-dependent membrane damage. Transmission electron microscopy showed that DEPs underwent endocytosis by epithelial cells and translocated through the epithelial cell sheet. Flow cytometric measurements allowed establishment of the time and dose dependency of this phagocytosis and its nonspecificity with different particles (DEPs, carbon black, and latex particles). DEPs also induced a time-dependent increase in interleukin-8, granulocyte-macrophage colony-stimulating factor, and interleukin-1beta release. This inflammatory response occurred later than phagocytosis, and its extent seems to depend on the content of adsorbed organic compounds because carbon black had no effect on cytokine release. Furthermore, exhaust gas posttreatments, which diminished the adsorbed organic compounds, reduced the DEP-induced increase in granulocyte-macrophage colony-stimulating factor release. These results suggest that DEPs could 1) be phagocytosed by airway epithelial cells and 2) induce a specific inflammatory response.The involvement of diesel exhaust particles (DEPs) in respiratory diseases was evaluated by studying their effects on two in vitro models of human airway epithelial cells. The cytotoxicity of DEPs, their phagocytosis, and the resulting immune response were investigated in a human bronchial epithelial cell line (16HBE14o-) as well as in human nasal epithelial cells in primary culture. DEP exposure induced a time- and dose-dependent membrane damage. Transmission electron microscopy showed that DEPs underwent endocytosis by epithelial cells and translocated through the epithelial cell sheet. Flow cytometric measurements allowed establishment of the time and dose dependency of this phagocytosis and its nonspecificity with different particles (DEPs, carbon black, and latex particles). DEPs also induced a time-dependent increase in interleukin-8, granulocyte-macrophage colony-stimulating factor, and interleukin-1β release. This inflammatory response occurred later than phagocytosis, and its extent seems to depend on the content of adsorbed organic compounds because carbon black had no effect on cytokine release. Furthermore, exhaust gas posttreatments, which diminished the adsorbed organic compounds, reduced the DEP-induced increase in granulocyte-macrophage colony-stimulating factor release. These results suggest that DEPs could 1) be phagocytosed by airway epithelial cells and 2) induce a specific inflammatory response.

IL-13 alters mucociliary differentiation and ciliary beating of human respiratory epithelial cells.

In animal models of asthma, interleukin-13 (IL-13) induces goblet cell metaplasia, eosinophil infiltration of the bronchial mucosa, and bronchial hyperreactivity, but the basis of its effects on airway epithelia remain unknown. Lesions of the epithelial barrier, frequently observed in asthma and other chronic lung inflammatory diseases, are repaired through proliferation, migration, and differentiation of epithelial cells. An inflammatory process may then, therefore, influence epithelial regeneration. We have thus investigated the effect of IL-13 on mucociliary differentiation of human nasal epithelial cells in primary culture. We show that IL-13 alters ciliated cell differentiation and increases the proportion of secretory cells. IL-13 downregulates the actin-binding protein ezrin and other cytoskeletal components. IL-13 also impairs lateral cell contacts and interferes with the apical localization of ezrin seen in differentiated ciliated cells. In addition, an IL-4 antagonistic mutant protein (Y124D), which binds to the IL-4 receptor alpha subunit, a common chain of IL-4 and IL-13 receptors, inhibits IL-13s effects. IL-13 also decreases ciliary beat frequency in a time- and dose-dependent manner. These results suggest that, in human allergic asthmatic responses, IL-13 affects both ciliated and secretory cell differentiation, leading to airway damage and obstruction.

Experimental dissociation between wakefulness and paradoxical sleep hippocampal theta.

Abstract The effects of electrolytic lesions of the septum on the theta activity of the dorsal hippocampus were studied in the chronically implanted rat during both wakefulness and paradoxical sleep. The experimental results show that depending on their localization, septal lesions can either: (1) eliminate the wakefulness theta rhythm without suppressing that of paraoxical sleep; (2) eliminate the paradoxical sleep theta rhythm without suppressing that of wakefulness. These results suggest that there are two kinds of theta activity having different anatomophysiological bases and a different functional significance: one associated with wakefulness and the other, with paradoxical sleep.

Effects of selective lesions of Fimbria-Fornix on learning set in the rat

The effects of selective partial lesions of the Fimbria-Fornix (FiFx) on reversal and place learning sets were investigated in rats by using a T-maze and a semi-circular multiple discrimination apparatus. Lesions restricted to the Fimbria (Fi) produced a significant deficit in reversal and place learning set, whereas lesions to the Fornix (Fx) only disturbed the learning set based on a reversal procedure. Combined Fi + Fx lesions resulted in impairment in the retention of spatial discrimination tested in the two mazes. Ventral Hippocampal Commissure (vhc) had no significant effect on reversal learning set. These results confirm previous data that the hippocampal formation is involved in learning transfer, and suggest that the Fi and the Fx may play a role in learning set. Our data also confirm previous demonstrations of the ability of rats to rapidly acquire place learning set.

Extracellular matrix-dependent differentiation of rabbit tracheal epithelial cells in primary culture

SummaryThe differentiation of tracheal epithelial cells in primary culture was investigated according to the nature of the extracellular matrix used. Cultures obtained by the explant technique were realized on a type I collagen substratum either as a thin, dried coating or as a thick, hydrated gel supplemented with culture medium and serum. These two types of substratum induced distinct cell morphology and cytokeratin expression in the explant derived cells. Where cells are less proliferating (from Day 7 to 10 of culture), differentiation was evaluated by morphologic ultrastructural observations, immunocytochemical detection of cytokeratins, and determination of cytokeratin pattern by biochemical analysis.The epithelium obtained on gel was multilayered, with small, round basal cells under large, flattened upper cells. The determination of the keratin pattern expressed by cells grown on gel revealed an expression of keratin 13, already considered as a specific marker of squamous metaplasia, that diminished with retinoic acid treatment. Present results demonstrated by confocal microscopy that K13-positive cells were large upper cells with a dense keratin network, whereas lower cells were positively stained with a specific monoclonal antibody to basal cells (KB37). Moreover, keratin neosynthesis analysis pointed out a higher expression of K6, a marker of hyperproliferation, on gel than on coating. All these data suggest a differentiation of rabbit tracheal epithelial cells grown on gel toward squamous metaplasia. By contrast, the epithelium observed on coating is nearly a monolayer of very large and spread out cells. No K13-positive cells were observed, but an increase in the synthesis of simple epithelium marker (K18) was detected. These two substrata, similar in composition and different in structure, induce separate differentiation and appear as good tools to explore the mechanisms of differentiation of epithelial tracheal cells.

Differential effects of several retinoid receptor-selective ligands on squamous differentiation and apoptosis in airway epithelial cells

Abstract. The roles of the different retinoid receptors on the differentiation of rabbit tracheal epithelial (RbTE) cells in primary culture were analysed using selective agonists for the retinoid acid receptor subtypes RARα (CD336), RARβ (CD2019), RARγ (CD437), an RAR panagonist (CD367), a retinoid X receptor RXR panagonist (CD2624) and an antagonist for RARβ/γ (CD2665). Squamous differentiation was assessed via expression of cytokeratins CK13/CK4 and transglutaminase I (TGI), specific markers of metaplasia. Treatment with RARα and β agonists or RAR panagonist, but not the RARγ agonist or RXR agonist, is required for the inhibition of squamous metaplasia, evidenced by inhibition of CK13/CK4 and TGI expression. The expression of CK10 cytokeratin of keratinizing epithelia, CK14/CK5 basal cell cytokeratins, and CK6 marker of cell proliferation decreases upon exposure of the RARα/β and RXR agonists. The RARγ agonist CD437, inactive in the decrease in CK13/CK4, CK10 and CK14, reduces CK5/CK6 amounts. CD437 is responsible for a dose-dependent apoptotic response. Nuclear labelling with propidium iodide (PI) and electron microscopy revealed chromatin condensation and nuclear fragmentation. DNA cleavage and cell fragmentation were confirmed by enzyme-linked immunosorbent assay (ELISA) and flow cytometry. The RARβγ antagonist was also slightly active. The results indicate that CD437 causes growth arrest in the early S-phase of the cell cycle and prevents the transition G1–S-phase. CD437 was demonstrated to induce apoptosis in the S-phase cells identified by bromodeoxyuridine (BrdU) incorporation. In conclusion, RARα/β ligands are effective inhibitors of squamous differentiation. On the contrary, RARγ ligand appears to be inefficient in metaplasia inhibition, but the selective RARγ agonist CD437 induces growth arrest and apoptosis of basal proliferative cells.

Similar cellular effects induced by diesel exhaust particles from a representative diesel vehicle recovered from filters and Standard Reference Material 1650

Standard reference diesel exhaust particles (DEP) SRM 1650 are often used to evaluate the toxicity of DEP. However, these particles did not necessarily reflect the effects of DEP representative of present diesel automobiles. This study was designed to compare the effects of SRM 1650 to DEP from representative cars (RC-DEP) on airway epithelial cells. Therefore we established a method to recover RC-DEP impacted on filters after emission from diesel automobiles on test beds. Electron microscopy and flow cytometry showed that these two types of particles were phagocytosed to the same extent by epithelial cells. This phagocytosis is not dependent on the adsorbed organic compounds in contrast to the cytotoxic effect evaluated by measurements of LDH release. This is emphasized by the fact that RC-DEP equipped with an oxidation catalyst are less cytotoxic than particles from a non-equipped vehicle or SRM 1650. This type of catalyst also reduces significantly the release of GM-CSF by bronchial epithelial cells. We have shown in the present paper that SRM 1650 may be used as a surrogate of DEP. However, exhaust gas post-treatment devices of current diesel automobiles reduce the cytotoxicity as well as the inflammatory response of these particles.

Toxic effects of mechlorethamine on mammalian respiratory mucociliary epithelium in primary culture.

Mechlorethamine (HN2) is an alkylating agent usually used in cancer chemotherapy. Nevertheless, HN2 is extremely toxic and its use is accompanied by severe side-effects that may cause lung complications. Many studies report the morphological and biochemical modifications induced by sulfur mustard (SM) but no report has been published concerning the toxic effects of HN2 on the ultrastructural and functional activity of surface respiratory epithelial cells. This study was performed on rabbit tracheal epithelium (RTE) cells in primary culture. The functional activity of the culture was evaluated by measuring the ciliary beating frequency (CBF) of the ciliated cells using a videomicroscopic method, and the culture growth was determined by an image analysis system. The morphological aspects of the cells were analyzed by light, scanning electron, and transmission electron microscopy. An important inhibition of cell growth was observed associated with a detachment of the outgrowth cells. Morphological changes were expressed by vacuolization, increases in the intercellular spaces, and by disorganization of the cytoskeleton associated with a specific attack of the ciliated cells that show ciliary blebbing. The sudden CBF inhibition is more likely due to the detachment and the death of the ciliated cells than to a specific ciliotoxic effect of HN2. All these observations demonstrated the high sensitivity of respiratory epithelial cells to HN2 and showed that HN2-induced injuries were irreversible, and time- and dose-dependent.

Responses of the rabbit tracheal epithelium in vitro to H2O2-induced oxidative stress

A model of rabbit tracheal epithelial (RTE) cells in primary culture was used to characterize specific and repair responses of airway epithelial cells to oxidative stress. Two well-known reactive oxygen species (ROS) generating systems were used: H(2)O(2) alone or in combination with Fe(2+) to produce the hydroxyl radical. RTE cells exhibited lipid peroxidation when exposed to H(2)O(2) + Fe(2+). Moreover, catalase (CAT) activity decreased after a 1-hour treatment in 3-day-old cultures but increased in 7-day-old cultures which have higher antioxidant enzyme activities. Superoxide dismutase (SOD) activity was never affected. In addition, RTE cells displayed a repair response leading to squamous metaplasia. H(2)O(2) + Fe(2+) treatment resulted in a time-dependent increase in the steady-state level of c-myc mRNA while c-jun and c-fos were not activated. Moreover, a chronic exposure induced the expression of the squamous phenotype characterized by the expression of the cytokeratin 13 confirmed both at the message and protein levels. RTE cells in primary culture react early to H(2)O(2) + Fe(2+) exposure by an increase in c-myc expression and by modifications in CAT activity. Further, a lipid peroxidation occurs and the tracheal epithelium evolves to squamous metaplasia.

In vitro exposure of rabbit tracheal epithelium to SO2: Effects on morphology and ciliary beating

The aim of this in vitro study was to characterize the direct effects of short-term exposure to low concentrations of sulfur dioxide (SO(2)) on both the morphology and the physiology of rabbit tracheal primary cultures. Scanning electron microscopy (SEM) studies revealed that ciliated cells exposed for 1 hr to 10 ppm or 30 ppm SO(2) exhibited aggregated cilia. Transmission electron microscopy revealed numerous swollen mitochondria in cells exposed to 30 ppm SO(2) for 1 hr. This morphological damage to cells was coupled with physiological alterations. A 25% decrease in ciliary beat frequency (CBF) was measured in cells exposed to 30 ppm SO(2). This inhibition was partially reversible within 24 hr. This SO(2) concentration also induced a significant depletion of cellular ATP content which was completely restored after a 24-hr recovery period. A correlation was found between cellular ATP level depletion and CBF decrease.