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OBJECTIVE To evaluate the effects of MUC18 on IL-13-mediated airway inflammatory responses in human airway epithelial cells and in mice. MATERIALS Primary normal human tracheobronchial epithelial (HTBE) cells,wild-type (WT) and Muc18 knockout (KO) mice,and mouse tracheal epithelial cells (mTECs) were utilized. TREATMENT Cultured HTBE cells treated with MUC18 siRNA or MUC18 expressing lentivirus were incubated with IL-13 (10 ng/mL) for 24 h. Mice were intranasally instilled with 500 ng of IL-13 for 3 days. mTECs were treated with IL-13 (10 ng/mL) for 3 days. METHODS PCR was used to measure mRNA expression. Western Blot and ELISAs were used to quantify protein expression. Cytospins of bronchoalveolar lavage (BAL) cells were used to obtain leukocyte differentials. RESULTS MUC18 siRNA reduced IL-13-mediated eotaxin-3 (183 ± 44 vs. 380 ± 59 pg/mL,p < 0.05),while MUC18 overexpression increased IL-13-mediated eotaxin-3 (95 ± 3 vs. 58 ± 3 pg/mL,p < 0.05) in HTBE cells. IL-13-treated Muc18 KO mice had a lower percentage of neutrophils in BAL than WT mice (25 ± 3 vs. 35 ± 3%,p = 0.0565). CONCLUSIONS These results implicate MUC18 as a potential enhancer of airway inflammation in a type 2 cytokine (e.g.,IL-13) milieu. View Publication

Neutrophil breach of the mucosal surface is a common pathological consequence of infection. We present an advanced co-culture model to explore neutrophil transepithelial migration utilizing airway mucosal barriers differentiated from primary human airway basal cells and examined by advanced imaging. Human airway basal cells were differentiated and cultured at air-liquid interface (ALI) on the underside of 3 μm pore-sized transwells,compatible with the study of transmigrating neutrophils. Inverted ALIs exhibit beating cilia and mucus production,consistent with conventional ALIs,as visualized by micro-optical coherence tomography (μOCT). μOCT is a recently developed imaging modality with the capacity for real time two- A nd three-dimensional analysis of cellular events in marked detail,including neutrophil transmigratory dynamics. Further,the newly devised and imaged primary co-culture model recapitulates key molecular mechanisms that underlie bacteria-induced neutrophil transepithelial migration previously characterized using cell line-based models. Neutrophils respond to imposed chemotactic gradients,and migrate in response to Pseudomonas aeruginosa infection of primary ALI barriers through a hepoxilin A3-directed mechanism. This primary cell-based co-culture system combined with μOCT imaging offers significant opportunity to probe,in great detail,micro-anatomical and mechanistic features of bacteria-induced neutrophil transepithelial migration and other important immunological and physiological processes at the mucosal surface. View Publication

To better characterize biological responses to atmospheric organic aerosols,the efficient delivery of aerosol to in vitro lung cells is necessary. In this study,chamber generated secondary organic aerosol (SOA) entered the commercialized exposure chamber (CULTEX® Radial Flow System Compact) where it interfaced with an electrostatic precipitator (ESP) (CULTEX® Electrical Deposition Device) and then deposited on a particle collection plate. This plate contained human lung cells (BEAS-2B) that were cultured on a membrane insert to produce an air-liquid interface (ALI). To augment in vitro assessment using the ESP exposure device,the particle dose was predicted for various sampling parameters such as particle size,ESP deposition voltage,and sampling flowrate. The dose model was evaluated against the experimental measured mass of collected airborne particles. The high flowrate used in this study increased aerosol dose but failed to achieve cell stability. For example,RNA in the ALI BEAS-2B cells in vitro was stable at 0.15 L/minute but decayed at high flowrates. The ESP device and the resulting model were applied to in vitro studies (i.e.,viability and IL-8 expression) of toluene SOA using ALI BEAS-2B cells with a flowrate of 0.15 L/minute,and no cellular RNA decay occurred. View Publication

Asthma is highly prevalent,but current therapies cannot influence the chronic course of the disease. It is thus important to understand underlying early molecular events. In this study,we aimed to use microRNAs (miRNAs) - which are critical regulators of signaling cascades - to identify so far uncharacterized asthma pathogenesis pathways. Therefore,deregulation of miRNAs was assessed in whole lungs from mice with ovalbumin (OVA)-induced allergic airway inflammation (AAI). In silico predicted target genes were confirmed in reporter assays and in house-dust-mite (HDM) induced AAI and primary human bronchial epithelial cells (NHBE) cultured at the air-liquid interface. We identified and validated the transcription factor cAMP-responsive element binding protein (Creb1) and its transcriptional co-activators (Crtc1-3) as targets of miR-17,miR-144,and miR-21. Sec14-like 3 (Sec14l3) - a putative target of Creb1 - was down-regulated in both asthma models and in NHBE cells upon IL13 treatment,while it's expression correlated with ciliated cell development and decreased along with increasing goblet cell metaplasia. Finally,we propose that Creb1/Crtc1-3 and Sec14l3 could be important for early responses of the bronchial epithelium to Th2-stimuli. This study shows that miRNA profiles can be used to identify novel targets that would be overlooked in mRNA based strategies. View Publication

The respiratory tract with its ease of access,vast surface area and dense network of antigen-presenting cells (APCs) represents an ideal target for immune-modulation. Bio-mimetic nanocarriers such as virosomes may provide immunomodulatory properties to treat diseases such as allergic asthma. In our study we employed a triple co-culture model of epithelial cells,macrophages and dendritic cells to simulate the human airway barrier. The epithelial cell line 16HBE was grown on inserts and supplemented with human blood monocyte-derived macrophages (MDMs) and dendritic cells (MDDCs) for exposure to influenza virosomes and liposomes. Additionally,primary human nasal epithelial cells (PHNEC) and EpCAM+ epithelial progenitor cell mono-cultures were utilized to simulate epithelium from large and smaller airways,respectively. To assess particle uptake and phenotype change,cell cultures were analyzed by flow cytometry and pro-inflammatory cytokine concentrations were measured by ELISA. All cell types internalized virosomes more efficiently than liposomes in both mono- and co-cultures. APCs like MDMs and MDDCs showed the highest uptake capacity. Virosome and liposome treatment caused a moderate degree of activation in MDDCs from mono-cultures and induced an increased cytokine production in co-cultures. In epithelial cells,virosome uptake was increased compared to liposomes in both mono- and co-cultures with EpCAM+ epithelial progenitor cells showing highest uptake capacity. In conclusion,all cell types successfully internalized both nanocarriers with virosomes being taken up by a higher proportion of cells and at a higher rate inducing limited activation of MDDCs. Thus virosomes may represent ideal carrier antigen systems to modulate mucosal immune responses in the respiratory tract without causing excessive inflammatory changes. View Publication

BACKGROUND The Rhinovirus C (RV-C),first identified in 2006,produce high symptom burdens in children and asthmatics,however,their primary target host cell in the airways remains unknown. Our primary hypotheses were that RV-C target ciliated airway epithelial cells (AECs),and that cell specificity is determined by restricted and high expression of the only known RV-C cell-entry factor,cadherin related family member 3 (CDHR3). METHODS RV-C15 (C15) infection in differentiated human bronchial epithelial cell (HBEC) cultures was assessed using immunofluorescent and time-lapse epifluorescent imaging. Morphology of C15-infected differentiated AECs was assessed by immunohistochemistry. RESULTS C15 produced a scattered pattern of infection,and infected cells were shed from the epithelium. The percentage of cells infected with C15 varied from 1.4 to 14.7% depending on cell culture conditions. Infected cells had increased staining for markers of ciliated cells (acetylated-alpha-tubulin [aat],p < 0.001) but not markers of goblet cells (wheat germ agglutinin or Muc5AC,p = ns). CDHR3 expression was increased on ciliated epithelial cells,but not other epithelial cells (p < 0.01). C15 infection caused a 27.4% reduction of ciliated cells expressing CDHR3 (p < 0.01). During differentiation of AECs,CDHR3 expression progressively increased and correlated with both RV-C binding and replication. CONCLUSIONS The RV-C only replicate in ciliated AECs in vitro,leading to infected cell shedding. CDHR3 expression positively correlates with RV-C binding and replication,and is largely confined to ciliated AECs. Our data imply that factors regulating differentiation and CDHR3 production may be important determinants of RV-C illness severity. View Publication

Multiciliated cells (MCCs) promote fluid flow through coordinated ciliary beating,which requires properly organized basal bodies (BBs). Airway MCCs have large numbers of BBs,which are uniformly oriented and,as we show here,align linearly. The mechanism for BB alignment is unexplored. To study this mechanism,we developed a long-term and high-resolution live-imaging system and used it to observe green fluorescent protein"centrin2"labeled BBs in cultured mouse tracheal MCCs. During MCC differentiation,the BB array adopted four stereotypical patterns,from a clustering floret? pattern to the linear alignment.? This alignment process was correlated with BB orientations,revealed by double immunostaining for BBs and their asymmetrically associated basal feet (BF). The BB alignment was disrupted by disturbing apical microtubules with nocodazole and by a BF-depleting Odf2 mutation. We constructed a theoretical model,which indicated that the apical cytoskeleton,acting like a viscoelastic fluid,provides a self-organizing mechanism in tracheal MCCs to align BBs linearly for mucociliary transport. View Publication

BACKGROUND: The collagen gel contraction assay measures gel size to assess the contraction of cells embedded in collagen gel matrices. Using the assay with lung fibroblasts is useful in studying the lung tissue remodeling process in wound healing and disease development. However,the involvement of bronchial epithelial cells in this process should also be investigated. METHODS: We applied a layer of mucociliary differentiated bronchial epithelial cells onto collagen gel matrices with lung fibroblasts. This co-culture model enables direct contact between epithelial and mesenchymal cells. We stimulated the culture with transforming growth factor (TGF) beta1 as an inducer of tissue remodeling for 21 days,and measured gel size,histological changes,and expression of factors related to extracellular matrix homeostasis. RESULTS: TGF-beta1 exerted a concentration-dependent effect on collagen gel contraction and on contractile myofibroblasts in the mesenchymal collagen layer. TGF-beta1 also induced expression of the mesenchymal marker vimentin in the basal layer of the epithelium,suggesting the induction of epithelial-mesenchymal transition. In addition,the expression of various genes encoding extracellular matrix proteins was upregulated. Fibrotic tenascin-C accumulated in the sub-epithelial region of the co-culture model. CONCLUSION: Our findings indicate that TGF-beta1 can affect both epithelial and mesenchymal cells,and induce gel contraction and structural changes. Our novel in vitro co-culture model will be a useful tool for investigating the roles of epithelial cells,fibroblasts,and their interactions in the airway remodeling process. View Publication

Effective derivation of functional airway organoids from induced pluripotent stem cells (iPSCs) would provide valuable models of lung disease and facilitate precision therapies for airway disorders such as cystic fibrosis. However,limited understanding of human airway patterning has made this goal challenging. Here,we show that cyclical modulation of the canonical Wnt signaling pathway enables rapid directed differentiation of human iPSCs via an NKX2-1+progenitor intermediate into functional proximal airway organoids. We find that human NKX2-1+progenitors have high levels of Wnt activation but respond intrinsically to decreases in Wnt signaling by rapidly patterning into proximal airway lineages at the expense of distal fates. Using this directed approach,we were able to generate cystic fibrosis patient-specific iPSC-derived airway organoids with a defect in forskolin-induced swelling that is rescued by gene editing to correct the disease mutation. Our approach has many potential applications in modeling and drug screening for airway diseases. View Publication