Histone deacetylase 9 promotes endothelial-mesenchymal transition and an unfavorable atherosclerotic plaque phenotype
Laura Lecce, … , Emily Bernstein, Jason C. Kovacic
Laura Lecce, … , Emily Bernstein, Jason C. Kovacic
Published August 2, 2021
Citation Information: J Clin Invest. 2021;131(15):e131178. https://doi.org/10.1172/JCI131178.
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Research Article Cardiology Vascular biology

Histone deacetylase 9 promotes endothelial-mesenchymal transition and an unfavorable atherosclerotic plaque phenotype

Abstract

Endothelial-mesenchymal transition (EndMT) is associated with various cardiovascular diseases and in particular with atherosclerosis and plaque instability. However, the molecular pathways that govern EndMT are poorly defined. Specifically, the role of epigenetic factors and histone deacetylases (HDACs) in controlling EndMT and the atherosclerotic plaque phenotype remains unclear. Here, we identified histone deacetylation, specifically that mediated by HDAC9 (a class IIa HDAC), as playing an important role in both EndMT and atherosclerosis. Using in vitro models, we found class IIa HDAC inhibition sustained the expression of endothelial proteins and mitigated the increase in mesenchymal proteins, effectively blocking EndMT. Similarly, ex vivo genetic knockout of Hdac9 in endothelial cells prevented EndMT and preserved a more endothelial-like phenotype. In vivo, atherosclerosis-prone mice with endothelial-specific Hdac9 knockout showed reduced EndMT and significantly reduced plaque area. Furthermore, these mice displayed a more favorable plaque phenotype, with reduced plaque lipid content and increased fibrous cap thickness. Together, these findings indicate that HDAC9 contributes to vascular pathology by promoting EndMT. Our study provides evidence for a pathological link among EndMT, HDAC9, and atherosclerosis and suggests that targeting of HDAC9 may be beneficial for plaque stabilization or slowing the progression of atherosclerotic disease.

Authors

Laura Lecce, Yang Xu, Bhargavi V’Gangula, Nirupama Chandel, Venu Pothula, Axelle Caudrillier, Maria Paola Santini, Valentina d’Escamard, Delaine K. Ceholski, Przemek A. Gorski, Lijiang Ma, Simon Koplev, Martin Mæng Bjørklund, Johan L.M. Björkegren, Manfred Boehm, Jacob Fog Bentzon, Valentin Fuster, Ha Won Kim, Neal L. Weintraub, Andrew H. Baker, Emily Bernstein, Jason C. Kovacic

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Figure 4

In vivo establishment and validation of Endo-Hdac9KO mouse model.

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In vivo establishment and validation of Endo-Hdac9KO mouse model. All co...
All comparisons in this figure are using endothelial-specific Hdac9 knockout mice (Endo-Hdac9KO) versus littermate controls (Hdac9fl/fl). All mice received tamoxifen. (A) For Hdac9 knockout validation, endothelial cells were harvested from a variety of tissues from nonatherosclerotic Endo-Hdac9KO mice or littermate controls. (B) Hdac9 knockout validation: qRT-PCR analysis of the expression levels of Hdac9 in CD31+CD45 endothelial cells from the aorta, heart, and lungs and CD31CD45+ leukocytes from blood in Endo-Hdac9KO mice compared with littermate controls 3 weeks after tamoxifen administration. n = 3. (C) Breeding and generation of atherosclerotic Endo-Hdac9KO mouse model. (D) Representative immunofluorescence staining images for HDAC9- (green), CD31- (red), and DAPI-stained nuclei (blue) in plaques from the aortic root. (E) Representative immunofluorescence staining images for αSMA- (green), CD31- (red), HDAC9- (white), and DAPI-stained nuclei (blue) in aortic root plaques and quantification. Scale bars: 50 μm. n = 10 controls versus n = 9 Endo-Hdac9KO mice. **P ≤ 0.01; ***P ≤ 0.001; ****P ≤ 0.0001. All analyses performed using unpaired Student’s t test except CD31+αSMA+HDAC9+ cells/CD31+ (E), for which Mann-Whitney U test was used.