MED12 regulates a transcriptional network of calcium-handling genes in the heart
Kedryn K. Baskin, Catherine A. Makarewich, Susan M. DeLeon, Wenduo Ye, Beibei Chen, Nadine Beetz, Heinrich Schrewe, Rhonda Bassel-Duby, Eric N. Olson
Kedryn K. Baskin, Catherine A. Makarewich, Susan M. DeLeon, Wenduo Ye, Beibei Chen, Nadine Beetz, Heinrich Schrewe, Rhonda Bassel-Duby, Eric N. Olson
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Research Article Cardiology Cell biology

MED12 regulates a transcriptional network of calcium-handling genes in the heart

Abstract

The Mediator complex regulates gene transcription by linking basal transcriptional machinery with DNA-bound transcription factors. The activity of the Mediator complex is mainly controlled by a kinase submodule that is composed of 4 proteins, including MED12. Although ubiquitously expressed, Mediator subunits can differentially regulate gene expression in a tissue-specific manner. Here, we report that MED12 is required for normal cardiac function, such that mice with conditional cardiac-specific deletion of MED12 display progressive dilated cardiomyopathy. Loss of MED12 perturbs expression of calcium-handling genes in the heart, consequently altering calcium cycling in cardiomyocytes and disrupting cardiac electrical activity. We identified transcription factors that regulate expression of calcium-handling genes that are downregulated in the heart in the absence of MED12, and we found that MED12 localizes to transcription factor consensus sequences within calcium-handling genes. We showed that MED12 interacts with one such transcription factor, MEF2, in cardiomyocytes and that MED12 and MEF2 co-occupy promoters of calcium-handling genes. Furthermore, we demonstrated that MED12 enhances MEF2 transcriptional activity and that overexpression of both increases expression of calcium-handling genes in cardiomyocytes. Our data support a role for MED12 as a coordinator of transcription through MEF2 and other transcription factors. We conclude that MED12 is a regulator of a network of calcium-handling genes, consequently mediating contractility in the mammalian heart.

Authors

Kedryn K. Baskin, Catherine A. Makarewich, Susan M. DeLeon, Wenduo Ye, Beibei Chen, Nadine Beetz, Heinrich Schrewe, Rhonda Bassel-Duby, Eric N. Olson

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Figure 6

MED12 coordinates calcium cycling in cardiomyocytes.

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MED12 coordinates calcium cycling in cardiomyocytes. Proper Ca2+ cycling...
Proper Ca2+ cycling and Ca2+-dependent signaling is required to maintain normal cardiac contractility. Excitation-contraction (EC) coupling is initiated by an action potential which depolarizes the sarcolemma by rapid sodium influx through sodium channels (Scn10a). Depolarization activates voltage-gated L-type Ca2+ channels, and Ca2+ influx triggers calcium-induced calcium release from the SR via the ryanodine receptor (Ryr2). Rapid release of Ca2+ from the SR increases free intracellular Ca2+, enabling muscle contraction. Gap junctions comprised of connexin complexes (Gja1 and Gja5) connect neighboring cells and facilitate the dispersion of action potentials throughout the heart. Cardiomyocyte relaxation is regulated by signaling pathways that restore intracellular and SR Ca2+ to resting concentrations. Ca2+-activated kinases phosphorylate phospholamban (Pln), relieving its repression on SERCA2a (Atp2a2). Consequently, SERCA2a rapidly imports Ca2+ into the SR, decreasing the intracellular Ca2+ concentration. Na+/Ca2+ exchangers (NCX) (Slc8a2) are allosterically activated by Ca2+ and aid in restoring resting Ca2+ concentrations, and decreased cytosolic Ca2+ leads to relaxation of the sarcomere. Genes downregulated in Med12cKO hearts are denoted by a blue downward arrow and genes upregulated are denoted by a red upward arrow.