Pharmacologically-induced mitotic synchrony in airway epithelial cells as a mechanism of action of anti-inflammatory drugs

Pharmacologically-induced mitotic synchrony in airway epithelial cells as a mechanism of action of anti-inflammatory drugs

Mitotic synchrony is the synchronous progression of a population of cells through the cell cycle and is characteristic of non-diseased airway epithelial cells. However, we previously showed that asthmatic airway epithelial cells are characterized by mitotic asynchrony and are pro-inflammatory as a r...

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Published in:Respiratory research Vol. 16; no. 1; p. 132
Main Authors: Freishtat, R J, Nino, G, Tsegaye, Y, Alcala, S E, Benton, A S, Watson, A M, Reeves, E K M, Haider, S K, Damsker, J M
Format: Journal Article
Language:English
Published: England BioMed Central 29-10-2015
Subjects:
Anti-inflammatory agents
Anti-Inflammatory Agents - pharmacology
Asthma - drug therapy
Asthma - metabolism
Asthma - pathology
Case-Control Studies
Cells, Cultured
Cytokines - metabolism
Dexamethasone - pharmacology
Epithelial Cells - drug effects
Epithelial Cells - pathology
Glucocorticoids - pharmacology
Humans
Inflammation Mediators - metabolism
Lung - drug effects
Lung - metabolism
Lung - pathology
Mitosis - drug effects
Pregnadienediols - pharmacology
Pulmonary Fibrosis - metabolism
Pulmonary Fibrosis - pathology
Pulmonary Fibrosis - prevention & control
Side effects
Time Factors
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Summary:Mitotic synchrony is the synchronous progression of a population of cells through the cell cycle and is characteristic of non-diseased airway epithelial cells. However, we previously showed that asthmatic airway epithelial cells are characterized by mitotic asynchrony and are pro-inflammatory as a result. Glucocorticoids can induce mitotic synchrony that in turn suppresses the pro-inflammatory state of diseased cells, suggesting a novel anti-inflammatory mechanism of action. Herein, we benchmarked traditional glucocorticoids against the ability of a new clinical-stage dissociative steroidal drug, VBP15, for mitotic resynchronization and associated anti-inflammatory activity in asthmatic airway epithelial cells. Primary airway epithelial cells differentiated at air-liquid interface were exposed to VBP15, dexamethasone or vehicle following in vitro mechanical injury. Basolateral cytokine secretions (TGF-β1, IL-6, IL-10, IL-13, and IL-1β) were analyzed at different time points using cytometric bead assays and mitosis was examined by flow cytometry. VBP15 improved mitotic synchrony of proliferating asthmatic cells in air-liquid interface cultures compared to vehicle-exposed cultures. VBP15 also significantly reduced the basolateral secretion of pro-inflammatory (i.e. IL-1β) and pro-fibrogenic cytokines (i.e. TGF-β1) in air-liquid interface-differentiated asthmatic epithelial cultures following mechanical injury. VBP15 improves mitotic asynchrony and injury-induced pro-inflammatory and fibrogenic responses in asthmatic airway epithelial cultures with efficacy comparable to traditional glucocorticoids. As it is predicted to show superior side effect profiles compared to traditional glucocorticoids, VBP15 holds potential for treatment of asthma and other respiratory conditions.
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ISSN:1465-993X
1465-9921
1465-993X
1465-9921
DOI:10.1186/s12931-015-0293-4