HDAC9 complex inhibition improves smooth muscle–dependent stenotic vascular disease
Christian L. Lino Cardenas, Chase W. Kessinger, Elizabeth Chou, Brian Ghoshhajra, Ashish S. Yeri, Saumya Das, Neal L. Weintraub, Rajeev Malhotra, Farouc A. Jaffer, Mark E. Lindsay
Christian L. Lino Cardenas, Chase W. Kessinger, Elizabeth Chou, Brian Ghoshhajra, Ashish S. Yeri, Saumya Das, Neal L. Weintraub, Rajeev Malhotra, Farouc A. Jaffer, Mark E. Lindsay
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Research Article Cardiology

HDAC9 complex inhibition improves smooth muscle–dependent stenotic vascular disease

Abstract

Patients with heterozygous missense mutations in the ACTA2 or MYH11 gene are known to exhibit thoracic aortic aneurysm and a risk of early-onset aortic dissection. However, less common phenotypes involving arterial obstruction are also observed, including coronary and cerebrovascular stenotic disease. Herein we implicate the HDAC9 complex in transcriptional silencing of contractile protein–associated genes, known to undergo downregulation in stenotic lesions. Furthermore, neointimal formation was inhibited in HDAC9- or MALAT1-deficient mice with preservation of contractile protein expression. Pharmacologic targeting of the HDAC9 complex through either MALAT1 antisense oligonucleotides or inhibition of the methyltransferase EZH2 (catalytic mediator recruited by the HDAC9 complex) reduced neointimal formation. In conclusion, we report the implication of the HDAC9 complex in stenotic disease and demonstrate that pharmacologic therapy targeting epigenetic complexes can ameliorate arterial obstruction in an experimental system.

Authors

Christian L. Lino Cardenas, Chase W. Kessinger, Elizabeth Chou, Brian Ghoshhajra, Ashish S. Yeri, Saumya Das, Neal L. Weintraub, Rajeev Malhotra, Farouc A. Jaffer, Mark E. Lindsay

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Figure 5

Pharmacologic inhibition of the Hdac9-Brg1-Malat1 complex inhibits neointimal formation.

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Pharmacologic inhibition of the Hdac9-Brg1-Malat1 complex inhibits neoin...
(A) Upper panel: Treatment strategy of experimental carotid artery stenosis with GapmeR-Malat1 or GSK343. Lower panel: qPCR analysis demonstrates Malat1 mRNA levels in aortic and liver tissues from vehicle- (n = 5) and GapmeR-Malat1–treated (n = 4) mice. (B) Histological and immunofluorescence analysis of ligated carotids of vehicle-, GapmeR-Malat1–, and GSK343-treated mice. Scale bars: 50 μm, zoom 3-fold magnification. (C) Quantification plot of vehicle (n = 6 male and 6 female), GapmeR-Malat1 (n = 3 male and 3 female), and GSK343 (n = 6 male and 6 female) treatment groups show significant inhibition of neointimal formation. (D) Detection of GapmeR-Malat1 molecule conjugated with 3′-FAM fluorophore in ligated carotid of GapmeR-Malat1–treated mice but not in vehicle- and GSK343-treated mice. Scale bars: 50 μm, zoom 5-fold magnification. (E) Inhibition of Mmp activity in ligated aortas of GapmeR-Malat1– and GSK343-treated mice. Mice were tail vein injected with MMPSense 750 FAST, a near-infrared fluorescence sensor for MMP2 and MMP9 activity, 24 hours prior to sacrifice, dissection, and imaging. Significance was calculated using 1-way ANOVA with Tukey’s multiple comparisons test.