In vivo, cardiomyocytes comprise a heterogeneous population of contractile cells defined by unique electrophysiologies, molecular markers and morphologies. The mechanisms directing myocardial cells to specific sub-lineages remain poorly understood. Here we report that overexpression of TGFβ-Activated Kinase (TAK1/Map3k7) in mouse embryonic stem (ES) cells faithfully directs myocardial differentiation of embryoid body (EB)-derived cardiac cells toward the sinoatrial node (SAN) lineage. Most cardiac cells in Map3k7-overexpressing EBs adopt markers, cellular morphologies, and electrophysiological behaviors characteristic of the SAN. These data, in addition to the fact that Map3k7 is upregulated in the sinus venous—the source of cells for the SAN—suggest that Map3k7 may be an endogenous regulator of the SAN fate

Brown, Kemar

Christini, David J.

Dai, Yunkai

Doss, Michael Xavier

Foley, Ann C.

Legros, Stephanie

Ortega, Francis A.

Robinson, Richard B.

English

Kemar Brown

Stephanie Legros

Francis A. Ortega

Yunkai Dai

Michael Xavier Doss

David J. Christini

Richard B. Robinson

Ann C. Foley

Crossref

PLoS ONE

Overexpression of Map3k7 activates sinoatrial node-like differentiation in mouse ES-derived cardiomyocytes

<div>In vivo, cardiomyocytes comprise a heterogeneous population of contractile cells defined by unique electrophysiologies, molecular markers and morphologies. The mechanisms directing myocardial cells to specific sub-lineages remain poorly understood. Here we report that overexpression of TGFβ-Activated Kinase (TAK1/Map3k7) in mouse embryonic stem (ES) cells faithfully directs myocardial differentiation of embryoid body (EB)-derived cardiac cells toward the sinoatrial node (SAN) lineage. Most cardiac cells in Map3k7-overexpressing EBs adopt markers, cellular morphologies, and electrophysiological behaviors characteristic of the SAN. These data, in addition to the fact that Map3k7 is upregulated in the sinus venous—the source of cells for the SAN—suggest that Map3k7 may be an endogenous regulator of the SAN fate.</div

Kemar Brown (239315)

Stephanie Legros (239322)

Francis A. Ortega (732794)

Yunkai Dai (4720785)

Michael Xavier Doss (30403)

David J. Christini (121102)

Richard B. Robinson (4720788)

Ann C. Foley (239331)

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Overexpression of Map3k7 activates sinoatrial node-like differentiation in mouse ES-derived cardiomyocytes

A. Diagram of the major transcriptional regulators of SAN differentiation in the mouse embryo. Tbx5 activates Shox2, Tbx3 and SAN-specific markers, including Hcn2 and Hcn4. In addition, Shox2 inhibits Nkx2.5 expression, and Tbx3 inhibits markers for the working myocardium. B. qRT-PCR data showing changes in the expression or timing of SAN related genes. Blue line indicates relative gene expression normalized to expression of Gapdh over time in wild-type R1 EBs and red lines indicate gene expression in Map3k7-overexpressing EBs. Error bars indicate standard error from three technical replicates. Upregulation or downregulation of each gene was considered relevant only if relative expression trends were the same in each of a minimum of three biological replicates. Error bars represent standard error from three technical replicates. Statistical significance was determined by t-test. (*) represent p<0.006.</p

Overexpression of Map3k7 activates sinoatrial node-like differentiation in mouse ES-derived cardiomyocytes - Fig 3

In vivo, cardiomyocytes comprise a heterogeneous population of contractile cells defined by unique electrophysiologies, molecular markers and morphologies. The mechanisms directing myocardial cells to specific sub-lineages remain poorly understood. Here we report that overexpression of TGFβ-Activated Kinase (TAK1/Map3k7) in mouse embryonic stem (ES) cells faithfully directs myocardial differentiation of embryoid body (EB)-derived cardiac cells toward the sinoatrial node (SAN) lineage. Most cardiac cells in Map3k7-overexpressing EBs adopt markers, cellular morphologies, and electrophysiological behaviors characteristic of the SAN. These data, in addition to the fact that Map3k7 is upregulated in the sinus venous-the source of cells for the SAN-suggest that Map3k7 may be an endogenous regulator of the SAN fate

Francis A Ortega

David J Christini

Richard B Robinson

Ann C Foley

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Overexpression of Map3k7 activates sinoatrial node-like differentiation in mouse ES-derived cardiomyocytes.

Columbia University Academic Commons

A. Schematic of lentiviral construct used to create an ES cell line stably overexpressing Map3k7. B-D. Flow cytometry analysis comparing green fluorescent protein (GFP) in Map3k7-overexpressing ES cells (B) to unmodified R1 cells (C). D. Cell count as compared to GFP fluorescence in untransduced (purple) and transduced (green) cells. E. qRT-PCR data showing overall Map3k7 expression during EB differentiation (red line) as compared to unmodified ES cells. Error bars indicate standard deviation of three technical replicates from a single differentiation. F-G. Growth curves comparing rate of growth in Map3k7-overexpressing cells (red) as compared to unmodified R1 cells, when grown as ES cells (tan) (F) and during EB differentiation (G). Error bars indicate standard deviation across three biological replicates.</p

Overexpression of Map3k7 activates sinoatrial node-like differentiation in mouse ES-derived cardiomyocytes - Fig 1

A. Beat Rate Data showing quartile beat rate data for 100 beating foci for two wild type mouse strains and Map3k7 overexpressing cells. B. Immunocytochemistry showing overlap of the cardiac reporter with the SAN specific marker Hcn4. C. Summary of this data showing the % of Hcn4 expressing cardiomyocytes is dramatically increased in the Map3k7-overexpressing cells. D. Perforated patch recording of automaticity and pacemaker current in mCherry expressing cardiomyocytes derived from Map3k7-overexpressing ES cells. Left: Spontaneous APs. Middle: Pacemaker current recorded from the same cell. Right: calculated activation relation from the same cell, showing current activation within the diastolic potential range. E. Calcium transients in cardiomyocytes derived from Map3k7-overexpressing ES cells before (red trace) and after (blue trace) treatment with either 1μM norepinephrine or 0.01μM acetylcholine, as indicated. Beating in these cardiomyocytes accelerates in response to norepinephrine and slows down in response to acetylcholine.</p

Overexpression of Map3k7 activates sinoatrial node-like differentiation in mouse ES-derived cardiomyocytes - Fig 4

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Overexpression of Map3k7 activates sinoatrial node-like differentiation in mouse ES-derived cardiomyocytes

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