Phenotypical changes in a differentiating immortalized bronchial epithelial cell line after exposure to mainstream cigarette smoke and e-cigarette vapor.

3D constructs composed of differentiated immortalized primary normal human bronchial epithelial (NHBE) cells (CL-1548) were repeatedly exposed at the air-liquid interface to non-lethal concentrations of mainstream cigarette smoke (4 cigarettes a day, 5days/week, 8 repetitions in total) and e-cigarette vapor (50 puffs a day, 5 days/week, 8 repetitions in total) to build up a permanent burden on the cells. Samples were taken after 4, 6 and 8 times of repeated smoke exposure and the cultures were investigated using histopathological methods Compared to the clean air-exposed cultures (process control) and incubator control, the aerosol-exposed cultures showed a reduction of ciliated, mucus-producing and club cells. At the end of the exposure phase, we even found metaplastic areas positive for CK13 antibody in the cultures exposed to mainstream cigarette smoke and e-liquid vapor, commonly seen in squamous cells as a marker for non-cornified squamous epithelium. The control cultures (incubator cells) showed no comparable phenotypical changes. In conclusion, our in vitro model presents a valuable tool to study the induction of phenotypical changes after exposure to hazardous airborne material.

Metaplastic phenotype in human primary bronchiolar epithelial cells after repeated exposure to native mainstream smoke at the air-liquid interface.

3D constructs composed of primary normal differentiated human bronchiolar epithelial (NHBE) cells as mono- or co-culture in combination with normal human lung fibroblasts were exposed repeatedly at the air-liquid interface with non-lethal concentrations of mainstream cigarette smoke (4 cigarettes a day, 5days/week, 13 times repetition in total) to build up a permanent burden on the cells. Samples were taken after 4, 8 and 13 times of repeated smoke exposure and the cultures were analyzed by histopathological methods In comparison with the clean air exposure (process control) and incubator control cells the cigarette smoke exposed cultures showed a reduction of cilia bearing as well as mucus producing cells. In both mono- as well as co-cultures, hyperplasia was induced showing different histological cell types (undifferentiated secretory and squamous cell types). At the end of the exposure phase, we observed the development of non-hyperplastic areas strongly positive to CK13 antibody, commonly seen in squamous cells as a marker for non-cornified squamous epithelium, thus suggesting a transition of the normal bronchial epithelial cells towards metaplastic cells. The control cultures (clean air exposed and incubator cells) showed no comparable phenotypic changes. In conclusion, our in vitro model presents a valuable tool to study the induction of metaplastic alterations after exposure to airborne material.

A new computer-controlled air-liquid interface cultivation system for the generation of differentiated cell cultures of the airway epithelium.

The increased application of in vitro systems in pharmacology and toxicology requires cell culture systems that facilitate the cultivation process and ensure stable, reproducible and controllable cultivation conditions. Up to now, some devices have been developed for the cultivation of cells under submersed conditions. However, systems meeting the requirements of an air-liquid interface (ALI) cultivation for the special needs of bronchial epithelial cells for example are still lacking. In order to obtain in vivo like organization and differentiation of these cells they need to be cultivated under ALI conditions on microporous membranes in direct contact with the environmental atmosphere. For this purpose, a Long-Term-Cultivation system was developed (CULTEX(®) LTC-C system) for the computer-controlled cultivation of such cells. The transwell inserts are placed in an incubator module (24 inserts), which can be adjusted for the medium level (ultrasonic pulse-echosensor), time and volume-dependent medium exchange, and frequency for mixing the medium with a rotating disc for homogeneous distribution of medium and secretion components. Normal primary freshly isolated bronchial epithelial cells were cultivated for up to 38 days to show the efficiency of such a cultivation procedure for generating 3D cultures exhibiting in vivo-like pseudostratified organization of the cells as well as differentiation characteristics like mucus-producing and cilia-forming cells.

Ciliatoxicity in human primary bronchiolar epithelial cells after repeated exposure at the air-liquid interface with native mainstream smoke of K3R4F cigarettes with and without charcoal filter.

Mucociliary clearance is the primary physical mechanism to protect the human airways against harmful effects of inhaled particles. Environmental factors play a significant role in the impairment of this defense mechanism, whereas cigarette smoke is discussed to be one of the clinically most important causes. Impaired mucociliary clearance in smokers has been connected to changes in ciliated cells such as decreased numbers, altered structure and beat frequency. Clinical studies have shown that cilia length is reduced in healthy smokers and that long-term exposure to cigarette smoke leads to reduced numbers of ciliated cells in mice. We present an in vitro model of primary normal human bronchiolar epithelial (NHBE) cells with in vivo like morphology to study the influence of cigarette mainstream smoke on ciliated cells. We exposed mucociliary differentiated cultures repeatedly to non-toxic concentrations of mainstream cigarette smoke (4 cigarettes, 5 days/week, 8 repetitions in total) at the air-liquid interface. Charcoal filter tipped cigarettes were compared to those being equipped with standard cellulose acetate filters. Histopathological analyses of the exposed cultures showed a reduction of cilia bearing cells, shortening of existing cilia and finally disappearance of all cilia in cigarette smoke exposed cells. In cultures exposed to charcoal filtered cigarette smoke, little changes in cilia length were seen after four exposure repetitions, but those effects were reversed after a two day recovery period. Those differences indicate that volatile organic compounds, being removed by the charcoal filter tip, affect primary bronchiolar epithelial cells concerning their cilia formation and function comparable with the in vivo situation. In conclusion, our in vitro model presents a valuable tool to study air-borne ciliatoxic compounds.

Target cell types with stem/progenitor function to isolate for in vitro reconstruction of human bronchiolar epithelia.

Recent advancement in research on stem/progenitor cells of respiratory organs is breathtaking, benefiting from the rapid development of technology to create transgenic mice. There is now a great deal of knowledge capable of direct translation from mice to humans. Nevertheless, one has to be careful, since there may be unexpected pitfalls. First of all, there are differences anatomically, histologically and ultrastructurally in the airway epithelia of the two species. In parallel with these structural differences, regionally specific cell types behave and function, particularly in regenerative instances, differently between the two species, at least to some extent. From the viewpoint of important human respiratory diseases, one of the most susceptible regions of the respiratory tract is the bronchiole. In our approach to develop in vitro systems utilizing human bronchiolar epithelial cells, we are currently leaning on the data obtained from mouse studies in spite of the above-mentioned species differences. With the help of such in vitro systems we should be able to investigate the damaging effects and mechanisms of environmental pollutants in the human respiratory epithelium and consequently achieve results useful for quantitative analyses of the impact on human respiratory health. While pursuing this goal, the mouse data have suggested that it should be worthwhile to pay close attention to the stem/progenitor cells contained in the human bronchiolar epithelia and eventually make use of them. The mouse data have further shown that these stem/progenitor cells possess a very close association with the immature and variant club cells and the neuroendocrine cells, and our own unpublished preliminary data with human cells are, apparently, at least partly consistent with what the mouse data are telling us.

Promoter methylation of PARG1, a novel candidate tumor suppressor gene in mantle-cell lymphomas.

BACKGROUND AND OBJECTIVES: Mantle cell lymphoma (MCL), a mature B-cell neoplasm, is genetically characterized by the translocation t(11;14)(q13;q32). However, secondary alterations are required for malignant transformation. The identification of inactivated tumor suppressor genes contributing to the development of MCL may lead to further elucidation of the biology of this disease and help to identify novel targets for therapy. DESIGN AND METHODS: Whole genome microarray-based gene expression profiling on treated versus untreated MCL cell lines was used to identify genes induced by 5-aza-2'-deoxycytidine. The degree of promoter methylation and transcriptional silencing of selected genes was then proven in MCL cell lines and primary cases by methylation-specific polymerase chain reaction (PCR) techniques, real-time PCR and gene expression profiling. RESULTS: After 5-aza-2'-deoxycytidine treatment, we identified more than 1000 upregulated genes, 16 of which were upregulated > or =3-fold. Most of them were not known to be silenced by methylation in MCL. A low expression of ING1, RUNX3 and BNIP3L was observed in three of the five the MCL cell lines. In addition, the expression of PARG1, which is located in the frequently deleted region 1p22.1, was substantially reduced and displayed at least partial promoter methylation in all investigated MCL cell lines as well as in 31 primary MCL cases. INTERPRETATION AND CONCLUSIONS: In summary, we identified interesting novel candidate genes that probably contribute to the progression of MCL and suggest that PARG1 is a strong candidate tumor suppressor gene in MCL.

Engraftment of adult human lung tissue in nonobese diabetic/severe combined immunodeficient mice: a novel lung epithelial regeneration model.

OBJECTIVES: Injury causes the disruption of homeostatic cell-cell interactions and epithelial regeneration is part of the threshold response. Due to the lack of a good animal model for the investigation of these mechanisms, the kinetics of cell proliferation after injury to the human respiratory tract are poorly understood. METHODS: To create a better model of human bronchioloalveolar epithelial regeneration, we engrafted adult human lung tissue into nonobese diabetic/severe combined immunodeficient (NOD/SCID) mice. Then the lung tissue was studied at various times up to 20 weeks after implantation. RESULTS: The xenografts of bronchiolar epithelium showed characteristic features, including positivity for specific human antigens, and extensive regeneration was observed within 8 weeks after implantation. In addition, a few alveolar type II epithelial cells expressing prosurfactant protein C were detected in some areas. The distal alveolar spaces were filled with protein-rich material and were markedly dilated. Abundantly ciliated secretory epithelium, which was similar to normal adult bronchiolar epithelium, was observed within 16 weeks after implantation in the mice. All of the human lung tissue specimens that were implanted subcutaneously into the backs of the mice developed well and remained viable for 20 weeks. Each type of adult human lung epithelial cell showed a different mode of proliferation. Bronchiolar epithelial cells proliferated earlier, with MIB-1 labeling of up to 20% of the cells in the grafts at 8 weeks, while alveolar type II cells proliferated later, with labeling of up to 5% of graft cells at 12 weeks. CONCLUSION: This model seems to allow adult human lung epithelial regeneration to be investigated in vivo over the long term.

Bone-marrow-derived myofibroblasts contribute to the cancer-induced stromal reaction.

To confirm whether human cancer-induced stromal cells are derived from bone marrow, bone marrow (BM) cells obtained from beta-galactosidase transgenic and recombination activating gene 1 (RAG-1) deficient double-mutant mice (H-2b) were transplanted into sublethally irradiated severe combined immunodeficient (SCID) mice (H-2d). The human pancreatic cancer cell line Capan-1 was subcutaneously xenotransplanted into SCID recipients and stromal formation was analyzed on day 14 and on day 28. Immunohistochemical and immunofluorescence studies revealed that BM-derived endothelial cells (X-gal/CD31 or H-2b/CD31 double-positive cells) and myofibroblasts (X-gal/alpha-smooth muscle actin or H-2b/alpha-smooth muscle actin double-positive cells) were present within and around the cancer nests. On day 14, the frequencies of BM-derived endothelial cells and BM-derived myofibroblasts were 25.3+/-4.4% and 12.7+/-9.6%, respectively. On day 28, the frequency of BM-derived endothelial cells was 26.7+/-9.7%, which was similar to the value on day 14. However, the frequency of BM-derived myofibroblasts was significantly higher (39.8+/-17.1%) on day 28 than on day 14 (P<0.05). The topoisomerase IIalpha-positive ratio was 2.2+/-1.2% for the H-2b-positive myofibroblasts, as opposed to only 0.3+/-0.4% for the H-2b-negative myofibroblasts, significant proliferative activity was observed in the BM-derived myofibroblasts (P<0.05). Our results indicate that BM-derived myofibroblasts become a major component of cancer-induced stromal cells in the later stage of tumor development.

Stem cells of the respiratory tract.

Childhood respiratory diseases are accompanied by various forms of epithelial repair and remodelling. Respiratory stem cells are likely to be of great importance in these processes but their identification remains uncertain. By contrast, an enormous effort has been made to identify specific markers of stem cells of other organs; this has given rise to the new concept of plasticity. This proposes that stem cell differentiation is influenced by the niches in which the cells reside rather than their site of origin. Many studies provide evidence in support of this concept, including one demonstrating that respiratory epithelium can arise from bone marrow stem cells. Recent findings from human and animal studies suggest that Clara cell-specific protein-expressing cells with pre-Clara cell phenotypes may be candidate stem cells for the entire respiratory tract.

DEVELOPMENT OF ENDOTHELIA AND ERYTHROID CELLS IN THE MOUSE METANEPHROGENIC MESENCHYME IN CULTURE WITH THE FETAL LIVER.

Histogenetic response in vitro of cells of the mouse metanephrogenic mesenchyme to different kinds of tissues was studied by means of transfilter induction technique. When the metanephrogenic mesenchyme obtained from 11-day mouse embryos was cultivated for 7 days in combination with the fetal liver or the primary differentiated hepatoma tissue, cell islets in which cells were arranged in a pavement-like or radial fashion, sinusoid endothelia and erythroid cells were induced in the culture, while in combination with the adult liver, no particular structures were. The number of the cell islets, which were absolutely absent in the initial culture, increased with time of the fetal liver-combined cultivation. When the mesenchyme was cultivated for 7 days in combination with the spinal cord and simultaneously with the fetal liver, new structures which were somewhat different from but faintly reminiscent of tubules and glomeruli were formed. Such structures seemed to be intermediate in appearance between the tubules and the sinusoids, and were formed largely at the expense of normal development of cell islets, sinusoid endothelia, erythroid cells, tubules and glomeruli.