BRD4 promotes endodermal cell fate during mammalian lung development
Hongbo Wen, Derek C. Liberti, Prashant Chandrasekaran, Shahana Parveen, Kwaku K. Quansah, Mijeong Kim, Ana N. Lange, Abigail T. Marquis, Sylvia N. Michki, Annabelle Jin, MinQi Lu, Ayomikun A. Fasan, Sriyaa Suresh, Shawyon P. Shirazi, Lisa R. Young, Jennifer M.S. Sucre, Maria C. Basil, Rajan Jain, David B. Frank
Hongbo Wen, Derek C. Liberti, Prashant Chandrasekaran, Shahana Parveen, Kwaku K. Quansah, Mijeong Kim, Ana N. Lange, Abigail T. Marquis, Sylvia N. Michki, Annabelle Jin, MinQi Lu, Ayomikun A. Fasan, Sriyaa Suresh, Shawyon P. Shirazi, Lisa R. Young, Jennifer M.S. Sucre, Maria C. Basil, Rajan Jain, David B. Frank
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Research Article Development Pulmonology

BRD4 promotes endodermal cell fate during mammalian lung development

Abstract

Lung development relies on diverse cell intrinsic and extrinsic mechanisms to ensure proper cellular differentiation and compartmentalization. In addition, it requires precise integration of multiple signaling pathways to temporally regulate morphogenesis and appropriate cell specification. To accomplish this, organogenesis relies on epigenetic and transcriptional regulators to promote cell fate and inhibit alternative cell fates. Using genetic mouse and human embryonic stem cell (hESC) differentiation models, tissue explants, and single-cell transcriptomic analysis, we demonstrated that Bromodomain Containing Protein 4 (BRD4) is required for mammalian lung morphogenesis and cell fate. Endodermal deletion of BRD4 impaired epithelial-mesenchymal crosstalk, leading to disrupted proximal-distal patterning and branching morphogenesis. Moreover, temporal deletion of BRD4 revealed developmental stage–specific defects in airway and alveolar epithelial cell specification with a predominant role in proximal airway cell fate. Similarly, BRD4 promoted lung endodermal cell differentiation into airway lineages in a hESC-derived lung organoid model. Together, these data demonstrate that BRD4 orchestrates early lung morphogenesis and separately regulates cell specification, indicating a multifunctional and evolutionarily conserved role for BRD4 in mammalian lung development.

Authors

Hongbo Wen, Derek C. Liberti, Prashant Chandrasekaran, Shahana Parveen, Kwaku K. Quansah, Mijeong Kim, Ana N. Lange, Abigail T. Marquis, Sylvia N. Michki, Annabelle Jin, MinQi Lu, Ayomikun A. Fasan, Sriyaa Suresh, Shawyon P. Shirazi, Lisa R. Young, Jennifer M.S. Sucre, Maria C. Basil, Rajan Jain, David B. Frank

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Figure 6

BRD4 promotes lung basal cell differentiation in extra- and intrapulmonary proximal airways.

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BRD4 promotes lung basal cell differentiation in extra- and intrapulmona...
(A) IHC for TRP63, KRT5, and SOX2 in control and BRD4 mutant E18.5 trachea (top and middle panels) and extrapulmonary proximal airway (top and bottom panels). Boxed areas on top panels represent magnified areas presented in the middle and bottom panels. Scale bar: 200 μm (top panels), 50 μm (middle and bottom panels). (B) IHC for TRP63, KRT5, and SOX2 in control and BRD4 mutant E18.5 extra- and intrapulmonary proximal airways leading into the lungs. Boxes represent magnified areas in the right panels. Scale bar: 200 μm (left panels), 25 μm (right panels). (C) IHC for TRP63, KRT5, and SOX2 in control and BRD4 mutant E18.5 intrapulmonary proximal airways. Scale bar: 100 μm. (D) Quantification of the percentages of SOX2+ airway epithelium that are basal cells in trachea, extrapulmonary, and intrapulmonary proximal airways. Quantification data are represented as mean ± SEM. Two tailed t tests: **P ≤ 0.01, n ≥ 4.