Your search keyword '"Chen, Jinghai"' showing total 3 results

1. EED orchestration of heart maturation through interaction with HDACs is H3K27me3-independent

Author

Ai, Shanshan, Peng, Yong, Li, Chen, Gu, Fei, Yu, Xianhong, Yue, Yanzhu, Ma, Qing, Chen, Jinghai, Lin, Zhiqiang, Zhou, Pingzhu, Xie, Huafeng, Prendiville, Terence W, Zheng, Wen, Liu, Yuli, Orkin, Stuart H, Wang, Da-Zhi, Yu, Jia, Pu, William T, and He, Aibin

Subjects

cardiology, gene regulation, chromatin, heart development, Mouse

Abstract

In proliferating cells, where most Polycomb repressive complex 2 (PRC2) studies have been performed, gene repression is associated with PRC2 trimethylation of H3K27 (H3K27me3). However, it is uncertain whether PRC2 writing of H3K27me3 is mechanistically required for gene silencing. Here, we studied PRC2 function in postnatal mouse cardiomyocytes, where the paucity of cell division obviates bulk H3K27me3 rewriting after each cell cycle. EED (embryonic ectoderm development) inactivation in the postnatal heart (EedCKO) caused lethal dilated cardiomyopathy. Surprisingly, gene upregulation in EedCKO was not coupled with loss of H3K27me3. Rather, the activating histone mark H3K27ac increased. EED interacted with histone deacetylases (HDACs) and enhanced their catalytic activity. HDAC overexpression normalized EedCKO heart function and expression of derepressed genes. Our results uncovered a non-canonical, H3K27me3-independent EED repressive mechanism that is essential for normal heart function. Our results further illustrate that organ dysfunction due to epigenetic dysregulation can be corrected by epigenetic rewiring. DOI: http://dx.doi.org/10.7554/eLife.24570.001

Published

2017

2. Trbp regulates heart function through miRNA-mediated Sox6 repression

Author

Ding, Jian, Chen, Jinghai, Wang, Yanqun, Kataoka, Masaharu, Ma, Lixin, Zhou, Pingzhu, Hu, Xiaoyun, Lin, Zhiqiang, Nie, Mao, Deng, Zhong-Liang, Pu, William T, and Wang, Da-Zhi

Abstract

Cardiomyopathy is associated with altered expression of genes encoding contractile proteins. Here we show that Trbp (Tarbp2), an RNA binding protein, is required for normal heart function. Cardiac-specific inactivation of Trbp (TrbpcKO) caused progressive cardiomyopathy and lethal heart failure. Trbp loss of function resulted in upregulation of Sox6, repression of genes encoding normal cardiac slow-twitch myofiber proteins, and pathologically increased expression of skeletal fast-twitch myofiber genes. Remarkably, knockdown of Sox6 fully rescued the Trbp mutant phenotype, whereas Sox6 overexpression phenocopied the TrbpcKO phenotype. Trbp inactivation was mechanistically linked to Sox6 upregulation through altered processing of miR-208a, which is a direct inhibitor of Sox6. Transgenic overexpression of miR-208a sufficiently repressed Sox6, restored the balance of fast- and slow- twitch myofiber gene expression, and rescued cardiac function in TrbpcKO mice. Together, our studies reveal a novel Trbp-mediated microRNA processing mechanism in regulating a linear genetic cascade essential for normal heart function.

Published

2015

3. Modeling the mitochondrial cardiomyopathy of Barth syndrome with iPSC and heart-on-chip technologies

Author

Wang, Gang, McCain, Megan L., Yang, Luhan, He, Aibin, Pasqualini, Francesco Silvio, Agarwal, Ashutosh, Yuan, Hongyan, Jiang, Dawei, Zhang, Donghui, Zangi, Lior, Geva, Judith, Roberts, Amy E., Ma, Qing, Ding, Jian, Chen, Jinghai, Wang, Da-zhi, Li, Kai, Wang, Jiwu, Wanders, Ronald J. A., Kulik, Wim, Vaz, Frédéric M., Laflamme, Michael A., Murry, Charles E., Chien, Kenneth R., Kelley, Richard I., Church, George M., Parker, Kevin Kit, and Pu, William T.

Abstract

Studying monogenic mitochondrial cardiomyopathies may yield insights into mitochondrial roles in cardiac development and disease. Here, we combine patient-derived and genetically engineered iPSCs with tissue engineering to elucidate the pathophysiology underlying the cardiomyopathy of Barth syndrome (BTHS), a mitochondrial disorder caused by mutation of the gene Tafazzin (TAZ). Using BTHS iPSC-derived cardiomyocytes (iPSC-CMs), we defined metabolic, structural, and functional abnormalities associated with TAZ mutation. BTHS iPSC-CMs assembled sparse and irregular sarcomeres, and engineered BTHS “heart on chip” tissues contracted weakly. Gene replacement and genome editing demonstrated that TAZ mutation is necessary and sufficient for these phenotypes. Sarcomere assembly and myocardial contraction abnormalities occurred in the context of normal whole cell ATP levels. Excess levels of reactive oxygen species mechanistically linked TAZ mutation to impaired cardiomyocyte function. Our study provides new insights into the pathogenesis of Barth syndrome, suggests new treatment strategies, and advances iPSC-based in vitro modeling of cardiomyopathy.

Published

2014