Reversal of pathological cardiac hypertrophy via the MEF2-coregulator interface
Jianqin Wei, … , Lin Chen, Nanette H. Bishopric
Jianqin Wei, … , Lin Chen, Nanette H. Bishopric
Published September 7, 2017
Citation Information: JCI Insight. 2017;2(17):e91068. https://doi.org/10.1172/jci.insight.91068.
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Research Article Cardiology Cell biology

Reversal of pathological cardiac hypertrophy via the MEF2-coregulator interface

Abstract

Cardiac hypertrophy, as a response to hemodynamic stress, is associated with cardiac dysfunction and death, but whether hypertrophy itself represents a pathological process remains unclear. Hypertrophy is driven by changes in myocardial gene expression that require the MEF2 family of DNA-binding transcription factors, as well as the nuclear lysine acetyltransferase p300. Here we used genetic and small-molecule probes to determine the effects of preventing MEF2 acetylation on cardiac adaptation to stress. Both nonacetylatable MEF2 mutants and 8MI, a molecule designed to interfere with MEF2-coregulator binding, prevented hypertrophy in cultured cardiac myocytes. 8MI prevented cardiac hypertrophy in 3 distinct stress models, and reversed established hypertrophy in vivo, associated with normalization of myocardial structure and function. The effects of 8MI were reversible, and did not prevent training effects of swimming. Mechanistically, 8MI blocked stress-induced MEF2 acetylation, nuclear export of class II histone deacetylases HDAC4 and -5, and p300 induction, without impeding HDAC4 phosphorylation. Correspondingly, 8MI transformed the transcriptional response to pressure overload, normalizing almost all 232 genes dysregulated by hemodynamic stress. We conclude that MEF2 acetylation is required for development and maintenance of pathological cardiac hypertrophy, and that blocking MEF2 acetylation can permit recovery from hypertrophy without impairing physiologic adaptation.

Authors

Jianqin Wei, Shaurya Joshi, Svetlana Speransky, Christopher Crowley, Nimanthi Jayathilaka, Xiao Lei, Yongqing Wu, David Gai, Sumit Jain, Michael Hoosien, Yan Gao, Lin Chen, Nanette H. Bishopric

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Figure 6

8MI and HDAC inhibition prevent cardiac hypertrophy by different mechanisms.

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8MI and HDAC inhibition prevent cardiac hypertrophy by different mechani...
(A) 8MI blocks induction of p300 by serum. Neonatal rat ventricular myocytes (NRVMs) were exposed to 5% fetal calf serum (FCS) in the presence of 8MI (5 and 10 μM), trichostatin A (TSA; 0.1 and 0.2 μM), MC1568 (5 and 10 μM), or their vehicle (0) as indicated. Control cells received fresh serum-free media (TIB). Protein levels of p300 and β-actin were assayed by immunoblot. Above: Representative immunoblots. Below: Quantification of 3 independent experiments. n = at least 3 biological replicates; exact P values are indicated (2-way ANOVA with post-hoc testing for multiple comparisons). (B) 8MI does not prevent serum-induced phosphorylation of histone deacetylase 4 (Hdac4). Quantification of p-Ser-Hdac4 (p-Hdac4) and Hdac4 immunoblots as shown in A. Graph displays full data range with mean. n = 3; *P < 0.05, **P < 0.01 (2-way ANOVA with post-hoc testing for multiple comparisons). (C) 8MI blocks nuclear export of Hdac4. Serum-starved NRVMs were fed with 5% FCS or fresh serum-free media in the presence of 8MI, TSA, or their vehicle DMSO as indicated. Hdac4, F-actin (Actin), and nuclear DNA (DAPI) were visualized as described in Methods. Scale bars: 20 μm. Representative images shown; n = 3 independent experiments. (D) 8MI reverses effects of stress on Hdac-Mef2 interaction. Myocardial lysates from sham-operated mice (S) and mice subjected to transverse aortic coarctation (T) were immunoprecipitated with anti-Mef2 (upper panel) or anti-Hdac4 (lower panel) antibodies and immunoblotted with Hdac4 and Mef2 as indicated. Anti-IgG was used as a control (IgG). Ponceau S staining was used to confirm protein loading. Representative blots of 3 independent experiments.