TY - JOUR
T1 - Azithromycin induces epidermal differentiation and multivesicular bodies in airway epithelia
AU - Arason, Ari Jon
AU - Jóelsson, Jón Pétur
AU - Valdimarsdóttir, Bryndís
AU - Sigurdsson, Snaevar
AU - Guðjónsson, Alexander
AU - Halldorsson, Skarphedinn
AU - Jóhannsson, Freyr
AU - Rolfsson, Óttar
AU - Lehmann, Fredrik
AU - Ingthorsson, Saevar
AU - Cherek, Paulina
AU - Gudmundsson, Gudmundur H
AU - Garðarsson, Friðrik R.
AU - Page, Clive P.
AU - Baldursson, Ólafur
AU - Gudjonsson, Thorarinn
AU - Kricker, Jennifer
AU - Gudjonsson, Alexander
AU - Gardarsson, Fridrik R
PY - 2019/6/24
Y1 - 2019/6/24
N2 - BACKGROUND: Azithromycin (Azm) is a macrolide recognized for its disease-modifying effects and reduction in exacerbation of chronic airway diseases. It is not clear whether the beneficial effects of Azm are due to its anti-microbial activity or other pharmacological actions. We have shown that Azm affects the integrity of the bronchial epithelial barrier measured by increased transepithelial electrical resistance. To better understand these effects of Azm on bronchial epithelia we have investigated global changes in gene expression. METHODS: VA10 bronchial epithelial cells were treated with Azm and cultivated in air-liquid interface conditions for up to 22 days. RNA was isolated at days 4, 10 and 22 and analyzed using high-throughput RNA sequencing. qPCR and immunostaining were used to confirm key findings from bioinformatic analyses. Detailed assessment of cellular changes was done using microscopy, followed by characterization of the lipidomic profiles of the multivesicular bodies present. RESULTS: Bioinformatic analysis revealed that after 10 days of treatment genes encoding effectors of sterol and cholesterol metabolism were prominent. Interestingly, expression of genes associated with epidermal barrier differentiation, KRT1, CRNN, SPINK5 and DSG1, increased significantly at day 22. Together with immunostaining, these results suggest an epidermal differentiation pattern. We also found that Azm induced the formation of multivesicular and lamellar bodies in two different airway epithelial cell lines. Lipidomic analysis revealed that Azm was entrapped in multivesicular bodies linked to different types of lipids, most notably palmitate and stearate. Furthermore, targeted analysis of lipid species showed accumulation of phosphatidylcholines, as well as ceramide derivatives. CONCLUSIONS: Taken together, we demonstrate how Azm might confer its barrier enhancing effects, via activation of epidermal characteristics and changes to intracellular lipid dynamics. These effects of Azm could explain the unexpected clinical benefit observed during Azm-treatment of patients with various lung diseases affecting barrier function.
AB - BACKGROUND: Azithromycin (Azm) is a macrolide recognized for its disease-modifying effects and reduction in exacerbation of chronic airway diseases. It is not clear whether the beneficial effects of Azm are due to its anti-microbial activity or other pharmacological actions. We have shown that Azm affects the integrity of the bronchial epithelial barrier measured by increased transepithelial electrical resistance. To better understand these effects of Azm on bronchial epithelia we have investigated global changes in gene expression. METHODS: VA10 bronchial epithelial cells were treated with Azm and cultivated in air-liquid interface conditions for up to 22 days. RNA was isolated at days 4, 10 and 22 and analyzed using high-throughput RNA sequencing. qPCR and immunostaining were used to confirm key findings from bioinformatic analyses. Detailed assessment of cellular changes was done using microscopy, followed by characterization of the lipidomic profiles of the multivesicular bodies present. RESULTS: Bioinformatic analysis revealed that after 10 days of treatment genes encoding effectors of sterol and cholesterol metabolism were prominent. Interestingly, expression of genes associated with epidermal barrier differentiation, KRT1, CRNN, SPINK5 and DSG1, increased significantly at day 22. Together with immunostaining, these results suggest an epidermal differentiation pattern. We also found that Azm induced the formation of multivesicular and lamellar bodies in two different airway epithelial cell lines. Lipidomic analysis revealed that Azm was entrapped in multivesicular bodies linked to different types of lipids, most notably palmitate and stearate. Furthermore, targeted analysis of lipid species showed accumulation of phosphatidylcholines, as well as ceramide derivatives. CONCLUSIONS: Taken together, we demonstrate how Azm might confer its barrier enhancing effects, via activation of epidermal characteristics and changes to intracellular lipid dynamics. These effects of Azm could explain the unexpected clinical benefit observed during Azm-treatment of patients with various lung diseases affecting barrier function.
KW - Air-liquid interface
KW - Airway
KW - Azithromycin
KW - Epidermal differentiation
KW - Epithelia
KW - Gene expression
KW - Genarannsóknir
KW - Öndunarfæri
KW - Öndunarfærasjúkdómar
KW - Sýklalyf
KW - Respiratory Tract Diseases
KW - Air-liquid interface
KW - Airway
KW - Azithromycin
KW - Epidermal differentiation
KW - Epithelia
KW - Gene expression
KW - Genarannsóknir
KW - Öndunarfæri
KW - Öndunarfærasjúkdómar
KW - Sýklalyf
KW - Respiratory Tract Diseases
U2 - 10.1186/s12931-019-1101-3
DO - 10.1186/s12931-019-1101-3
M3 - Article
C2 - 31234850
SN - 1465-9921
VL - 20
JO - Respiratory Research
JF - Respiratory Research
IS - 1
ER -