Cardiomyocyte adhesion and hyperadhesion differentially require ERK1/2 and plakoglobin
Maria Shoykhet, Sebastian Trenz, Ellen Kempf, Tatjana Williams, Brenda Gerull, Camilla Schinner, Sunil Yeruva, Jens Waschke
Maria Shoykhet, Sebastian Trenz, Ellen Kempf, Tatjana Williams, Brenda Gerull, Camilla Schinner, Sunil Yeruva, Jens Waschke
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Research Article Cardiology

Cardiomyocyte adhesion and hyperadhesion differentially require ERK1/2 and plakoglobin

Abstract

Arrhythmogenic cardiomyopathy (AC) is a heart disease often caused by mutations in genes coding for desmosomal proteins, including desmoglein-2 (DSG2), plakoglobin (PG), and desmoplakin (DP). Therapy is based on symptoms and limiting arrhythmia, because the mechanisms by which desmosomal components control cardiomyocyte function are largely unknown. A new paradigm could be to stabilize desmosomal cardiomyocyte adhesion and hyperadhesion, which renders desmosomal adhesion independent from Ca2+. Here, we further characterized the mechanisms behind enhanced cardiomyocyte adhesion and hyperadhesion. Dissociation assays performed in HL-1 cells and murine ventricular cardiac slice cultures allowed us to define a set of signaling pathways regulating cardiomyocyte adhesion under basal and hyperadhesive conditions. Adrenergic signaling, activation of PKC, and inhibition of p38MAPK enhanced cardiomyocyte adhesion, referred to as positive adhesiotropy, and induced hyperadhesion. Activation of ERK1/2 paralleled positive adhesiotropy, whereas adrenergic signaling induced PG phosphorylation at S665 under both basal and hyperadhesive conditions. Adrenergic signaling and p38MAPK inhibition recruited DSG2 to cell junctions. In PG-deficient mice with an AC phenotype, only PKC activation and p38MAPK inhibition enhanced cardiomyocyte adhesion. Our results demonstrate that cardiomyocyte adhesion can be stabilized by different signaling mechanisms, which are in part offset in PG-deficient AC.

Authors

Maria Shoykhet, Sebastian Trenz, Ellen Kempf, Tatjana Williams, Brenda Gerull, Camilla Schinner, Sunil Yeruva, Jens Waschke

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Figure 5

Effect of Dsg2, N-Cad, Jup, or Dp knockdown on F/R-, Iso-, PMA-, or SB20-mediated increase in cardiomyocyte cohesion.

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Effect of Dsg2, N-Cad, Jup, or Dp knockdown on F/R-, Iso-, PMA-, or SB20...
(A) Representative Western blots confirming decreased levels of DSG2, N-CAD, PG, and DP after siRNA-mediated knockdown. (B) Dissociation assay under basal conditions following siNT, siDsg2, siN-Cad, siJup, and siDp treatments. *P ≤ 0.05, 1-way ANOVA with Holm-Šidák correction, n = 6. (C) Dissociation assays showing fold changes in fragments as compared with the respective controls in HL-1 cells following siNT, siDsg2, siJup, or siDp treatments and administration of F/R, Iso, PMA, or SB20. DMSO serves as control for SB20. *P ≤ 0.05, 1-way ANOVAs with Holm-Šidák correction, n = 6. (D) Immunohistochemistry of ventricular cardiac slices obtained from WT and PG-deficient mice (Jup-KO) stained for PG protein. Scale bar: 50 μm. n = 6. (E) H&E and Picrosirius red stainings of cardiac slices obtained from WT and Jup-KO mice. Scale bar: 1 mm; 50 µm (high-magnification views). (F) Total collagen content of cardiac slices obtained from WT and Jup-KO mice. *P ≤ 0.05, Student’s t test with Welch correction, n = 6. (G) Dissociation assays in murine cardiac slice cultures comparing the number of dissociated cells in WT and Jup-KO cardiac slices. *P ≤ 0.05, unpaired Student’s t test, n = 6. (H) Dissociation assays in murine cardiac slices obtained from Jup-KO mice following F/R, Iso, PMA, SB20, and Aniso treatments. *P ≤ 0.05, 1-way ANOVA with Holm-Šidák correction, n = 6.