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Proteomic Analysis of Primary Human Airway Epithelial Cells Exposed to the Respiratory Toxicant Diacetyl
- Foster, Matthew W., Gwinn, William M., Kelly, Francine L., Brass, David M., Valente, Ashlee M., Moseley, M. Arthur, Thompson, J. Will, Morgan, Daniel L., Palmer, Scott M.
- Journal of Proteome Research 2017 v.16 no.2 pp. 538-549
- bronchiolitis, cilia, crosslinking, diacetyl, epithelial cells, epithelium, fibrosis, fluorescent antibody technique, humans, keratin, models, monitoring, pathogenesis, phosphopeptides, phosphorylation, proteome, proteomics, rodents, staining, toxicity, vapors
- Occupational exposures to the diketone flavoring agent, diacetyl, have been associated with bronchiolitis obliterans, a rare condition of airway fibrosis. Model studies in rodents have suggested that the airway epithelium is a major site of diacetyl toxicity, but the effects of diacetyl exposure upon the human airway epithelium are poorly characterized. Here we performed quantitative LC–MS/MS-based proteomics to study the effects of repeated diacetyl vapor exposures on 3D organotypic cultures of human primary tracheobronchial epithelial cells. Using a label-free approach, we quantified approximately 3400 proteins and 5700 phosphopeptides in cell lysates across four independent donors. Altered expression of proteins and phosphopeptides were suggestive of loss of cilia and increased squamous differentiation in diacetyl-exposed cells. These phenomena were confirmed by immunofluorescence staining of culture cross sections. Hyperphosphorylation and cross-linking of basal cell keratins were also observed in diacetyl-treated cells, and we used parallel reaction monitoring to confidently localize and quantify previously uncharacterized sites of phosphorylation in keratin 6. Collectively, these data identify numerous molecular changes in the epithelium that may be important to the pathogenesis of flavoring-induced bronchiolitis obliterans. More generally, this study highlights the utility of quantitative proteomics for the study of in vitro models of airway injury and disease.