The distribution and structure of cells in the tracheal epithelium of the mouse

Summary The tracheal epithelium of the mouse is a single layer of columnar cells resting on a basement membrane. Many of the cell types resemble those of other species. However, goblet cells are rare and ciliated cells occur only in scattered patches. Submucosal glands are absent from all but the highest reaches of the airway.The major proportion of the epithelial cells are non-ciliated. These usually project into the lumen of the trachea. Large amounts of smooth endoplasmic reticulum and many secretory vesicles occur within the cytoplasm. Secretory activity of these cells may be either apocrine or merocrine and these cells may transform into other cell types.It is suggested that these non-ciliated cells are Clara cells and that the mouse tracheal epithelium may make a useful model for the study of this type of cell.     

Phenotype and distribution of dendritic cells in the porcine small intestinal and tracheal mucosa and their spatial relationship to epithelial cells

Dendritic cells (DC) as key mediators of tolerance and immunity perform crucial immunosurveillance functions at epithelial surfaces. In order to induce an immune response, the DC have to gain access to antigens present at the luminal surface of mucosal epithelia. The mechanisms of this process are still largely unclear. We have therefore analysed the distribution of DC in the porcine intestinal and respiratory mucosa and their spatial relationship to epithelial cells by immunohistology. Immunofluorescence analysis of cryosections taken from jejunal Peyer’s patches and double-stained for DC and M cells (specialised for antigen uptake) have revealed that 35.2±3.9% of M cells are located directly adjacent to DC in the subepithelial domes, representing possible antigen transfer sites. In normal jejunal villi, a rare population of lamina propria DC extending cytoplasmic processes between enterocytes has been identified as a possible correlate for direct luminal antigen uptake. Like small intestinal DC, DC in the porcine trachea mostly co-express CD16 with MHC-II. Tracheal DC have been found at high densities both above and below the basement membrane (BM) of the tracheal epithelium, with 32.4 DC/mm BM and 23.0 DC/mm BM, respectively. The intraepithealial DC population forms a dense network, with many of the cytoplasmic processes being directed towards the tracheal lumen. Our morphological analyses indicate that DC at mucosal epithelial sites are ideally positioned for the uptake of luminal antigens.This work was supported by the EU (5th framework programme “Healthypigut” QLK5-CT-2000-00522 and 6th framework programme “Feed for Pig Health” FOOD-CT 2004-506144).     

The effects of carbon monoxide and hypoxic hypoxia on amine-containing cells in the tracheal epithelium of young rabbits

Summary Endogenously fluorescent, singly occurring, amine-containing cells in tracheal epithelium were examined in 3-, 10-, and 28-day-old rabbits. These cells are pyramidal in shape with the apex projected toward the tracheal lumen. The cytoplasm exhibits a yellow fluorescence which is predominantly supranuclear. Occasional, infranuclear, fluorescent cytoplasmic processes project from the cells. The numbers of fluorescent cells per unit length of trachea increase with age. Acute exposure of 10-day-old rabbits to 13% O₂ decreases the number of detectable fluorescent cells in the trachea compared to controls exposed to room air. Similarly, exposure to 750 ppm carbon monoxide decreases the number of fluorescent epithelial cells appearing in tracheas of 10- and 28-day-old rabbits. These results suggest that the amine-containing epithelial cells of the trachea respond to tissue hypoxia and that decreased airway pO₂ is not necessary to elicit a response.Supported by a grant from The Council for Tobacco Research, U.S.A., Inc. We are grateful to Margaret Hogan and Scott Pine for technical assistance     

Regulation of dendritic cell recruitment into resting and inflamed airway epithelium: use of alternative chemokine receptors as a function of inducing stimulus.

Dendritic cells (DC) were purified by flow cytometry from rat tracheal mucosa; they exhibited the phenotypic characteristics of immature DC including high endocytic activity, low CD80/86 expression, and in vitro responsiveness to a broad range of CC chemokines. Daily treatment of adult rats with the selective CCR1 and CCR5 antagonist Met-RANTES reduced baseline numbers of tracheal intraepithelial DC by 50-60%, and pretreatment of animals with Met-RANTES before inhalation of aerosol containing heat-killed bacteria abolished the rapid DC influx into the epithelium that occurred in untreated controls, implicating CCR1 and CCR5 and their ligands in recruitment of immature DC precursors into resting airway tissues and during acute bacterial-induced inflammation. Comparable levels of DC recruitment were observed during airway mucosal Sendai virus infection and after aerosol challenge of sensitized animals with the soluble recall Ag OVA. However, Met-RANTES did not affect these latter responses, indicating the use of alternative chemokine receptors/ligands for DC recruitment, or possibly attraction of different DC subsets, depending on the nature of the eliciting stimulus.     

Effects of unilateral nasal occlusion on ventilation and pulmonary resistance in infants

There is evidence implying an active role of airway epithelium in the modulation of bronchomotor tone. To study this phenomenon, we designed an in vitro system allowing pharmacological stimulation of either the inside or outside of the airway lumen. Rat tracheas were excised, cannulated, and their inside and outside perfused independently with Krebs solution. Two hooks were inserted through opposite sides of the tracheal wall, the lower one was attached to a fixed point, while the upper one was connected to a force transducer. Isometric contractions of the tracheal muscle were elicited by carbachol solution perfused in single and cumulative concentrations. In one-half of the preparations the epithelium was mechanically removed. Stimulation of the inside or outside of the trachea produced equal maximal tracheal muscle tension [1.55 +/- 0.14 and 1.2 +/- 0.09 (SE) g in and out, respectively]. The time course of tension development was longer when carbachol was administered inside the trachea: an effect that was abolished when the epithelium was removed. In addition, removal of the epithelium was found 1) to increase the maximal tension irrespective of the route of carbachol perfusion and 2) to increase the sensitivity of the preparation to carbachol stimulation.     

Murine nasal septa for respiratory epithelial air-liquid interface cultures

Air-liquid interface models using murine tracheal respiratory epithelium have revolutionized the in vitro study of pulmonary diseases. This model is often impractical because of the small number of respiratory epithelial cells that can be isolated from the mouse trachea. We describe a simple technique to harvest the murine nasal septum and grow the epithelial cells in an air-liquid interface. The degree of ciliation of mouse trachea, nasal septum, and their respective cultured epithelium at an air-liquid interface were compared by scanning electron microscopy (SEM). Immunocytochemistry for type IV beta-tubulin and zona occludens-1 (Zo-1) are performed to determine differentiation and confluence, respectively. To rule out contamination with olfactory epithelium (OE), immunocytochemistry for olfactory marker protein (OMP) was performed. Transepithelial resistance and potential measurements were determined using a modified vertical Ussing chamber SEM reveals approximately 90% ciliated respiratory epithelium in the nasal septum as compared with 35% in the mouse trachea. The septal air-liquid interface culture demonstrates comparable ciliated respiratory epithelium to the nasal septum. Immunocytochemistry demonstrates an intact monolayer and diffuse differentiated ciliated epithelium. These cultures exhibit a transepithelial resistance and potential confirming a confluent monolayer with electrically active airway epitheliumn containing both a sodium-absorptive pathway and a chloride-secretory pathway. To increase the yield of respiratory epithelial cells harvested from mice, we have found the nasal septum is a superior source when compared with the trachea. The nasal septum increases the yield of respiratory epithelial cells up to 8-fold.     

Tracheal Dysplasia Precedes Bronchial Dysplasia in Mouse Model of N-Nitroso Trischloroethylurea Induced Squamous Cell Lung Cancer

Squamous cell lung cancer (SCC) is the second leading cause of lung cancer death in the US and has a 5-year survival rate of only 16%. Histological changes in the bronchial epithelium termed dysplasia are precursors to invasive SCC. However, the cellular mechanisms that cause dysplasia are unknown. To fill this knowledge gap, we used topical application of N-nitroso-tris chloroethylurea (NTCU) for 32 weeks to induce squamous dysplasia and SCC in mice. At 32 weeks the predominant cell type in the dysplastic airways was Keratin (K) 5 and K14 expressing basal cells. Notably, basal cells are extremely rare in the normal mouse bronchial epithelium but are abundant in the trachea. We therefore evaluated time-dependent changes in tracheal and bronchial histopathology after NTCU exposure (4, 8, 12, 16, 25 and 32 weeks). We show that tracheal dysplasia occurs significantly earlier than that of the bronchial epithelium (12 weeks vs. 25 weeks). This was associated with increased numbers of K5⁺/K14⁺ tracheal basal cells and a complete loss of secretory (Club cell secretory protein expressing CCSP⁺) and ciliated cells. TUNEL staining of NTCU treated tissues confirmed that the loss of CCSP⁺ and ciliated cells was not due to apoptosis. However, mitotic index (measured by bromodeoxyuridine incorporation) showed that NTCU treatment increased proliferation of K5⁺ basal cells in the trachea, and altered bronchial mitotic population from CCSP⁺ to K5⁺ basal cells. Thus, we demonstrate that NTCU-induced lung epithelial dysplasia starts in the tracheal epithelium, and is followed by basal cell metaplasia of the bronchial epithelium. This analysis extends our knowledge of the NTCU-SCC model by defining the early changes in epithelial cell phenotypes in distinct airway locations, and this may assist in identifying new targets for future chemoprevention studies.     

Ultrastructure of the mouse tracheal epithelium

The ultrastructure of mouse tracheal epithelium was examined. The three cell types, basal cells, ciliated cells and goblet cells, described for other mammalian trachea were found to be present although goblet cells occurred only rarely. A cell type, termed the nonciliated cell, not described in other mammalian trachea was frequently found in mouse tracheal epithelium. These cells contained abundant smooth and rough endoplasmic reticulum, free ribosomes, a large Golgi complex, and many mitochondria. There were many vesciles containing an electron dense material near the luminal surface of these cells; these cells were positive for PAS. These features suggested a secretory function for the cells. This, along with the scarcity of goblet cells, suggested that the nonciliated cells of mouse tracheal epithelium fulfill the function of the goblet cells found in other mammalian trachea.     

Histochemical methods for characterizing secretory and cell surface sialoglycoconjugates

Paraffin sections of trachea, sublingual gland, and pancreas from rats, mice, and hamsters were stained with peanut agglutinin (PNA) or Dolichos biflorus agglutinin (DBA) conjugated to horseradish peroxidase before or after enzymatic removal of sialic acid. Adjacent sections were oxidized with periodate prior to incubation with sialidase and staining with PNA and DBA. PNA binding demonstrated terminal beta-galactose in secretions, at the basolateral plasmalemma of mouse tracheal serous cells, in or at the surface of zymogen granules, and at the apical and basolateral surface of mouse and hamster pancreatic acinar cells. Sialidase digestion revealed PNA binding, demonstrative of penultimate beta-galactose, in secretions of mucous cells in tracheal and sublingual glands and at the apical glycocalyx of ciliated and secretory cells in the tracheal surface epithelium of all the rodents studied. Sialidase also imparted PNA affinity to endothelium in all three species and to secretions and the basolateral plasmalemma of tracheal serous cells and pancreatic acinar cells in the rat. Periodate oxidation blocked the enzymatic removal of N-acetylneuraminic acid as judged by prevention of staining with the sialidase-PNA procedure. Sites in which periodate prevented sialidase-PNA staining included pancreatic islet cells and at the luminal glycocalyx of ciliated and secretory cells in tracheal surface epithelium in all three rodents, most sublingual mucous cells in the hamster, pancreatic acinar cells in the rat, and endothelium, except that of the rat. Glycoconjugate in other sites remained positive with the periodate-sialidase-PNA sequence. Resistance to periodate was interpreted as evidence for the presence of terminal sialic acid with an O-acetylated polyhydroxyl side chain. DBA binding demonstrated terminal alpha-N-acetylgalactosamine in the secretion of all mucous cells in the hamster trachea and 50-90% of those in the rat, secretion and the basolateral plasmalemma of all glandular serous cells in the mouse trachea, at the apical surface of most secretory cells lining the lumen of the rat and hamster trachea, and cilia of 5-10% of ciliated cells in the rat trachea. Periodate oxidation and sialidase digestion demonstrated N-acetylneuraminic acid and penultimate alpha-N-acetylgalactosamine in cilia in the mouse trachea and sialic acid containing O-acetylated polyhydroxyl side chains subtended by N-acetylgalactosamine in the secretion of all mucous cells in the rat and hamster trachea and of 80-90% of mucous cells in the hamster sublingual gland.(ABSTRACT TRUNCATED AT 400 WORDS)     

XB130 Deficiency Affects Tracheal Epithelial Differentiation during Airway Repair

The repair and regeneration of airway epithelium is important for maintaining homeostasis of the respiratory system. XB130 is an adaptor protein involved in the regulation of cell proliferation, survival and migration. In the human trachea, XB130 is expressed on the apical site of ciliated epithelial cells. We hypothesize that XB130 may play a role in epithelial repair and regeneration after injury. Xb130 knockout (KO) mice were generated, and a mouse isogenic tracheal transplantation model was used. Adult Xb130 KO mice did not show any significant anatomical and physiological phenotypes in comparison with their wild type (WT) littermates. The tracheal epithelium in Xb130 KO mice, however, was significantly thicker than that in WT mice. Severe ischemic epithelial injury was observed immediately after the tracheal transplantation, which was followed by epithelial cell flattening, proliferation and differentiation. No significant differences were observed in terms of initial airway injury and apoptosis. However, at Day 10 after transplantation, the epithelial layer was significantly thicker in Xb130 KO mice, and associated with greater proliferative (Ki67+) and basal (CK5+) cells, as well as thickening of the connective tissue and fibroblast layer between the epithelium and tracheal cartilages. These results suggest that XB130 is involved in the regulation of airway epithelial differentiation, especially during airway repair after injury.     

In vivo differentiation potential of tracheal basal cells: evidence for multipotent and unipotent subpopulations

The composition of the conducting airway epithelium varies significantly along the proximal to distal axis, with that of the tracheal epithelium exhibiting the greatest complexity. A number of progenitor cells have been proposed to contribute to the maintenance of this cellular diversity both in the steady state and in response to injury. However, individual roles for each progenitor cell type are poorly defined in vivo. The present study was undertaken to investigate the hypothesis that basal cells represent a multipotent progenitor cell type for renewal of the injured tracheal epithelium. To understand their contribution to epithelial repair, mice were exposed to naphthalene to induce airway injury and depletion of the secretory cell progenitor pool. Injury resulted in a rapid induction of cytokeratin 14 (K14) expression among the majority of GSI-B4-reactive cells and associated hyperplasia of basal cells. Restoration of depleted secretory cells occurred after 6 days of recovery and was associated with regression of the basal cell hyperplasia, suggesting a progenitor-progeny relationship. Multipotent differentiation of basal cells was confirmed using a bitransgenic ligand-regulated Cre-loxP reporter approach in which expression of a ubiquitously expressed LacZ reporter was activated within K14-expressing progenitor cells during airway repair. With the use of this approach, it was determined that K14-expressing cells include subsets capable of either multipotent or unipotent differentiation in vivo. We conclude that basal cells have the capacity for restoration of a fully differentiated epithelium.     

Differential expression of a WD protein during squamous differentiation of tracheal epithelial cells

The lining of the trachea consists of a pseudostratified, mucociliary epithelium that under a variety of conditions, such as vitamin A deficiency, toxic and mechanical injury, becomes a stratified squamous epithelium. Several in vitro cell culture models have been established to study the process of differentiation of airway epithelium. Such studies have indicated that mucosecretory differentiation of tracheal epithelial cells can be modulated by substratum. This study was undertaken to understand molecular mechanisms of squamous differentiation in tracheal epithelia. Primary cultured tracheal cells grown on uncoated filters were differentiated to single layer of squamous cells, whereas cells were grown as stratified columnar cells on collagen-I coated filters. The responses to secretagogues were altered according to culture conditions. DD-PCR revealed that FAK and a WD protein expression was increased in squamous tracheal epithelia. Expression of a WD protein was changed by the treatment of retinoic acid in various epithelial cells. These results indicated that squamous differentiation of tracheal cells changes the expression of a variety of genes, and that the experimental model for this study can be employed to study molecular mechanisms of squamous differentiation in airway epithelial cells.     

Histochemical localization of carbonic anhydrase in the trachea of the guinea pig

 Tissue specimens from guinea pigs were examined using an enzyme-histochemical reaction to explore the presence of carbonic anhydrase (CA) activity in the trachea. CA activity was detected in a group of morphologically distinct epithelial cells, in goblet cells, and in glands of the tracheal mucosa. The epithelial cells showing CA activity were distributed singly and sparsely throughout the entire trachea. These cells showed a wide morphological variability and were clearly different from those forming the pseudostratified ciliated epithelium. Their number was higher in sections closer to the tracheal bifurcation than in those near the larynx. Although the nature of these cells is unknown, based on their morphological and histochemical characteristics and their distribution, they may represent a specialized chemoreceptor. To our knowledge, this is the first report of CA localized in tracheal epithelial cells. Accepted: 6 March 1996     

X-ray microanalysis of airway surface liquid in the mouse

The ionic composition of airway surface liquid (ASL) has been debated, and, in particular for the mouse, a wide range of values has been published. Two techniques were developed to measure the elemental composition of the ASL. X-ray microanalysis of ASL was carried out at low temperature on trachea removed from isoflurane-anesthetized animals and shock-frozen. In the second technique, dextran beads were placed on top of the epithelium of the trachea removed from pentobarbital-anesthetized animals, left to equilibrate with the ASL, dried, and subjected to X-ray microanalysis. Both techniques showed that mouse tracheal ASL has significantly lower concentrations of Na and Cl (approximately 60-80 mM) than serum. Differences between the two techniques were due to different sampling of mucus. CFTR(-/-) mice had significantly higher concentrations of Na and Cl in their ASL than age-matched controls. Pilocarpine or isoproterenol stimulation significantly reduced the ion concentrations in tracheal ASL. ASL was also collected with the dextran bead method from the nasal cavity in situ in pentobarbital-anesthetized animals. In control animals, the elemental composition of nasal fluid was similar to that of tracheal ASL. Pilocarpine stimulation caused a significant increase in Na, Cl, and K; stimulation with isoproterenol or phenylephrine caused a significant increase only in K. It is concluded that mouse ASL under unstimulated conditions is hypotonic, which may be related to the relative paucity of submucosal glands in the mouse trachea.     

Tracheal telocytes

Recently, a novel type of stromal cell - the telocytes (TC) - was identified in mouse trachea. These cells are known to possess the ultrastructural characteristics, which support their role in intercellular signaling. We found TC in all stromal compartments of the tracheal wall. TC with long prolongations (telopodes, Tp) were lining longitudinally the collagen bundles, and were serially arranged (end-to-end connections of Tp were found). Noteworthy, Tp frequently establish stromal synapses with mast cells (MC). Primary cilia were also identified in TC. In conclusion, tracheal TC could be involved in the tracheal regulation (e.g. secretion, contractility). The tandem TC-MC deserves further investigations.     

The effect of verapamil is reduced in isolated airway smooth muscle preparations lacking the epithelium

The effect of epithelium removal on the reactivity of rabbit airway smooth muscle to bronchoactive agents and on the effect of verapamil was studied in vitro using preparations from several levels within the respiratory tree, i.e., trachea, primary (10) and secondary (20) bronchus. Methacholine contracted tissues from all three levels of airway. Histamine contracted strips from 20 bronchus, had an inconsistent action in strips from 10 bronchus and was without effect in tracheal preparations. K+ contracted tissues from the trachea and 10 bronchus, and had a mixed action in 20 bronchial strips. Removal of the epithelial cell layer variably affected the reactivity of the smooth muscle to the three agents studied. In 20 bronchus, epithelium removal potentiated responses to histamine and methacholine. In 10 bronchus, only responses to methacholine were consistently augmented. In tracheal preparations epithelium removal did not alter the reactivity of the tissue to any agent examined. Verapamil (1 microM) attenuated responses to all agents and increased in its potency from tracheal through 10 to 20 bronchial preparations. Following epithelium removal, verapamil was substantially less effective in 20 bronchi, yet its effects were unchanged in the trachea. The results indicate that the epithelial cell layer modulates airway smooth muscle reactivity; this phenomenon is apparently widespread in mammals, the modulatory effect is more prominent in the smaller airways, and the magnitude of the effect of verapamil on airway smooth muscle is, in part, related to the presence of the epithelium.     

Effects of vitamin A-deficiency and inflammation on the conducting airway epithelium of Syrian golden hamsters

The effects of vitamin A-deficiency and inflammation were studied in the conducting airways of Syrian golden hamsters. An important goal of the study was to characterize epithelial changes that occur early in vitamin A-deficiency, that might precede yet predispose to infection, and precipitate inflammatory changes in the lungs. Age-matched vitamin A-replete control and vitamin A-deprived hamsters were killed at 33 days of age (preweight-plateau); at 41 days of age (weight plateau-early weight loss); and at 48-55 days of age (prolonged weight plateau followed by weight loss). A tablet containing bromodeoxyuridine (BrdU) was implanted subcutaneously into each hamster 7 h before it was killed. No changes were seen in the conducting airway epithelium of vitamin A-deprived hamsters in the preweight plateau. However, labelling of secretory cells for BrdU was reduced 6-7 fold in the epithelium lining the lobar bronchus (p less than 0.0002) and the bronchioles (p less than 0.0001), and the proportions of ciliated cells were decreased (p less than 0.0001) at both airway levels in vitamin A-deficient hamsters in the weight plateau-early weight loss stage. Changes in cellular morphology were minimal in the intrapulmonary airway epithelium at this time but a few small focal patches of epidermoid metaplasia were seen in the tracheal epithelium. Small foci of inflammation were closely associated with the airways in the weight plateau, and the inflammation became more widespread when the deficiency was prolonged. The results suggest that the defense of the lungs to infection was impaired initially in the vitamin A-deficient hamsters by a widespread reduction in the numbers of ciliated cells throughout the epithelium of the conducting airways (trachea, bronchi, bronchioles). At the foci of inflammation, labelling of epithelial secretory cells for BrdU was greatly increased at all airway levels. A highly stratified cornifying epidermoid metaplasia developed in the tracheal epithelium, and goblet cell metaplasia developed in the cranial portion of the lobar bronchus, in association with submucosal inflammation. Goblet cell metaplasia appeared to be the only abnormality that was not reversed when vitamin A was restored to the diet.     

Circulating progenitor epithelial cells traffic via CXCR4/CXCL12 in response to airway injury

Recipient airway epithelial cells are found in human sex-mismatched lung transplants, implying that circulating progenitor epithelial cells contribute to the repair of the airway epithelium. Markers of circulating progenitor epithelial cells and mechanisms for their trafficking remain to be elucidated. We demonstrate that a population of progenitor epithelial cells exists in the bone marrow and the circulation of mice that is positive for the early epithelial marker cytokeratin 5 (CK5) and the chemokine receptor CXCR4. We used a mouse model of sex-mismatched tracheal transplantation and found that CK5+ circulating progenitor epithelial cells contribute to re-epithelialization of the airway and re-establishment of the pseudostratified epithelium. The presence of CXCL12 in tracheal transplants provided a mechanism for CXCR4+ circulating progenitor epithelial cell recruitment to the airway. Depletion of CXCL12 resulted in the epithelium defaulting to squamous metaplasia, which was derived solely from the resident tissue progenitor epithelial cells. Our findings demonstrate that CK5+CXCR4+ cells are markers of circulating progenitor epithelial cells in the bone marrow and circulation and that CXCR4/CXCL12-mediated recruitment of circulating progenitor epithelial cells is necessary for the re-establishment of a normal pseudostratified epithelium after airway injury. These findings support a novel paradigm for the development of squamous metaplasia of the airway epithelium and for developing therapeutic strategies for circulating progenitor epithelial cells in airway diseases.