Asthmatic Airway Epithelium Is Intrinsically Inflammatory and Mitotically Dyssynchronous

Freishtat, Robert J.; Watson, Alan M.; Benton, Angela S.; Iqbal, Sabah; Pillai, Dinesh K.; Rose, Mary C.; Hoffman, Eric P.

doi:10.1165/rcmb.2010-0029oc

Cited by 67 publications

(69 citation statements)

References 49 publications

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“…Both the asthmatic grafted epithelium and the asthmatic human lung biopsy tissue show decreased E-cadherin expression. This is all consistent with our previous work showing that, when differentiated at air-liquid interface culture, asthmatic-derived epithelial cells are less differentiated in comparison to nonasthmatic-derived cells, as demonstrated by increased basal cell number and lack of E-cadherin (5,6,11,19).…”

Section: Discussionsupporting

confidence: 93%

“…We and others (6,11,41) have shown previously that basolateral secretion of TGF-b1 is increased from asthmatic airway epithelium in vitro. The current study furthers that work by demonstrating increased TGF-b1 in asthmatic xenografts, an in vivo system.…”

Section: Discussionmentioning

confidence: 64%

“…These repair processes are defective in asthma, as evidenced by a reduction in the cell-cell adhesion proteins involved in barrier function (5), asynchrony in mitotic cell division, and increased production of inflammatory mediators and growth factors, such as transforming growth factor (TGF)-b1 (6)(7)(8)(9).…”

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confidence: 99%

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A Heterotopic Xenograft Model of Human Airways for Investigating Fibrosis in Asthma

Hackett

Ferrante²,

Hoptay³

et al. 2017

Am J Respir Cell Mol Biol

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Limited in vivo models exist to investigate the lung airway epithelial role in repair, regeneration, and pathology of chronic lung diseases. Herein, we introduce a novel animal model in asthma-a xenograft system integrating a differentiating human asthmatic airway epithelium with an actively remodeling rodent mesenchyme in an immunocompromised murine host. Human asthmatic and nonasthmatic airway epithelial cells were seeded into decellularized rat tracheas. Tracheas were ligated to a sterile cassette and implanted subcutaneously in the flanks of nude mice. Grafts were harvested at 2, 4, or 6 weeks for tissue histology, fibrillar collagen, and transforming growth factor-b activation analysis. We compared immunostaining in these xenografts to human lungs. Grafted epithelial cells generated a differentiated epithelium containing basal, ciliated, and mucus-expressing cells. By 4 weeks postengraftment, asthmatic epithelia showed decreased numbers of ciliated cells and decreased E-cadherin expression compared with nonasthmatic grafts, similar to human lungs. Grafts seeded with asthmatic epithelial cells had three times more fibrillar collagen and induction of transforming growth factor-b isoforms at 6 weeks postengraftment compared with nonasthmatic grafts. Asthmatic epithelium alone is sufficient to drive aberrant mesenchymal remodeling with fibrillar collagen deposition in asthmatic xenografts. Moreover, this xenograft system represents an advance over current asthma models in that it permits direct assessment of the epithelial-mesenchymal trophic unit.Keywords: asthma; remodeling; lung Clinical RelevanceWe developed a human asthmatic airway epithelial xenograft system as an animal model in asthma and demonstrate that the asthmatic airway epithelium alone can drive airway remodeling. This xenograft model is an advance over current animal models for asthma in that it permits direct assessment of the epithelial-mesenchymal trophic unit.

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Section: Discussionsupporting

confidence: 93%

Section: Discussionmentioning

confidence: 64%

See 1 more Smart Citation

A Heterotopic Xenograft Model of Human Airways for Investigating Fibrosis in Asthma

Hackett

Ferrante²,

Hoptay³

et al. 2017

Am J Respir Cell Mol Biol

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“…After 14-21 days (EpiAirway) or 20-45 days (MucilAir) of culture the epithelia are fully ciliated and electrically tight (TEER≈450 Ω cm 2 ). EpiAirway cultures are available in a number of useful insert formats, and have been successfully utilized for numerous applications including airway drug delivery (Agu et al, 2006;Leonard et al, 2005Leonard et al, , 2007, airway disease modelling (Bai et al, 2015;Freishtat et al, 2011; ALI cultures have provided insights into pathogenetic mechanisms, for example the ability of Th2 cytokines, IL-4 and IL-13, to skew bronchial epithelial cell differentiation towards goblet cell hyperplasia, increased mucin gene expression and mucous hypersecretion (Kanoh et al, 2011;Thavagnanam et al, 2011;Zuyderduyn et al, 2011). Furthermore, use of ALI cultures has allowed for comparisons of barrier properties, mucus production and other responses of epithelial cells from asthmatic and healthy subjects, as well as the demonstration that tight junctions are reduced and mucus production and inflammatory cytokine induction are increased in cultures from asthmatic subjects (as observed in vivo).…”

Section: Fully Differentiated 3d Human Airway Epithelial Modelsmentioning

confidence: 99%

“…Furthermore, use of ALI cultures has allowed for comparisons of barrier properties, mucus production and other responses of epithelial cells from asthmatic and healthy subjects, as well as the demonstration that tight junctions are reduced and mucus production and inflammatory cytokine induction are increased in cultures from asthmatic subjects (as observed in vivo). Such changes have been seen to correspond to an increase in ionic and macromolecular permeability (Xiao et al, 2011;Bai et al, 2015;Freishtat et al, 2011;Watson et al, 2010). It has also been shown that the permeability of the bronchial epithelial cell layer is only increased in asthmatic subjects after exposure to ozone or nitrogen dioxide (Bayram et al, 2002), and that mediator release is altered after exposure of ALI cultures from asthmatic donors to respiratory syncytial virus (RSV) or particulate matter (Hackett et al, 2011b).…”

Section: Fully Differentiated 3d Human Airway Epithelial Modelsmentioning

confidence: 99%

Non-animal models of epithelial barriers (skin, intestine and lung) in research, industrial applications and regulatory toxicology

Gordon

Daneshian

Bouwstra

et al. 2015

ALTEX

118

103

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SummaryModels of the outer epithelia of the human body -namely the skin, the intestine and the lung -have found valid applications in both research and industrial settings as attractive alternatives to animal testing. A variety of approaches to model these barriers are currently employed in such fields, ranging from the utilization of ex vivo tissue to reconstructed in vitro models, and further to chip-based technologies, synthetic membrane systems and, of increasing current interest, in silico modeling approaches. An international group of experts in the field of epithelial barriers was convened from academia, industry and regulatory bodies to present both the current state of the art of non-animal models of the skin, intestinal and pulmonary barriers in their various fields of application, and to discuss research-based, industry-driven and regulatory-relevant future directions for both the development of new models and the refinement of existing test methods. Issues of model relevance and preference, validation and standardization, acceptance, and the need for simplicity versus complexity were focal themes of the discussions. The outcomes of workshop presentations and discussions, in relation to both current status and future directions in the utilization and development of epithelial barrier models, are presented by the attending experts in the current report.

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The human secretome atlas initiative: Implications in health and disease conditions

Brown

Seol

Pillai

et al. 2013

Biochimica et Biophysica Acta (BBA) - Proteins and Proteomics

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Proteomic analysis of human body fluids is highly challenging, therefore many researchers are redirecting efforts towards secretome profiling. The goal is to define potential biomarkers and therapeutic targets in the secretome that can be traced back in accessible human body fluids. However, currently there is a lack of secretome profiles of normal human primary cells making it difficult to assess the biological meaning of current findings. In this study we sought to establish secretome profiles of human primary cells obtained from healthy donors with the goal of building a human secretome atlas. Such an atlas can be used as a reference for discovery of potential disease associated biomarkers and eventually novel therapeutic targets. As a preliminary study, secretome profiles were established for six different types of human primary cell cultures and checked for overlaps with the three major human body fluids including plasma, cerebrospinal fluid and urine. About 67% of the 1054 identified proteins in the secretome of these primary cells occurred in at least one body fluid. Furthermore, comparison of the secretome profiles of two human glioblastoma cell lines to this new human secretome atlas enabled unambiguous identification of potential brain tumor biomarkers. These biomarkers can be easily monitored in different body fluids using stable isotope labeled standard proteins. The long term goal of this study is to establish a comprehensive online human secretome atlas for future use as a reference for any disease related secretome study.

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Asthmatic Airway Epithelium Is Intrinsically Inflammatory and Mitotically Dyssynchronous

Cited by 67 publications

References 49 publications

A Heterotopic Xenograft Model of Human Airways for Investigating Fibrosis in Asthma

A Heterotopic Xenograft Model of Human Airways for Investigating Fibrosis in Asthma

Non-animal models of epithelial barriers (skin, intestine and lung) in research, industrial applications and regulatory toxicology

The human secretome atlas initiative: Implications in health and disease conditions

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