Expression of the hyperpolarization-activated cyclic nucleotide-gated cation channel HCN4 during mouse heart development

Introduction: Mammalian heart possesses regenerative potential immediately after birth and lost by one week of age. The mechanisms that govern neonatal cardiomyocyte proliferation and regenerative capacity are poorly understood. Recent reports indicate that Yap-Tead transcriptional complex is necessary and sufficient for cardiomyocyte proliferation. During postnatal development, N-cadherin/catenin adhesion complex becomes concentrated at termini of cardiomyocytes facilitating maturation of a specialized intercellular junction structure, the intercalated disc (ICD). This process coincides with the time cardiomyocytes exit cell cycle soon after birth. Hypothesis: We hypothesize that coincident with maturation of ICD α-catenins sequester transcriptional coactivator Yap in cytosol thus preventing activation of genes critical for cardiomyocyte proliferation. Methods: We deleted αE-catenin / αT-catenin genes (α-cat DKO) in perinatal mouse heart and knockdown (KD) α-catenins in neonatal rat cardiomyocytes to study functional impact of α-catenins ablation on ICD maturation. Results: We previously demonstrated that adult α-cat DKO mice exhibited decrease in scar size and improved function post myocardial infarction. In present study, we investigated function of α-catenins during postnatal heart development. We found increase in the number of Yap-positive nuclei (58.7% in DKO vs. 35.8 % in WT, n=13, p<0.001) and PCNA (53.9% in DKO vs. 47.8%, n=8, p<0.05) at postnatal day 1 and day 7 of α-cat DKO heart, respectively. Loss of α-catenins resulted in reduction in N-cadherin at ICD at day 14. We observed an increase number of mononucleated myocytes and decrease number of binucleated myocytes in α-cat DKO compared to controls. Using siRNA KD, we were able to replicate α-cat DKO proliferative phenotype in vitro. The number of BrdU-positive cells was decreased in α-cat KD after interfering with Yap expression (2.91% in α-cat KD vs. 2.02% in α-cat/Yap KD, n>2500 cells, p<0.05), suggesting α-catenins regulate cell proliferation through Yap in neonatal cardiomyocytes. Conclusion: Our results suggest that maturation of ICD regulates α-catenin-Yap interactions in cytosol, thus preventing Yap nuclear accumulation and cardiomyocyte proliferation.

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Abstract 255: A Fibroblast Population Shares A Developmental Origin With Cardiovascular Lineages

Circulation Research ◽

10.1161/res.115.suppl_1.255 ◽

2014 ◽

Vol 115 (suppl_1) ◽

Author(s):

Sara Ranjbarvaziri ◽

Shah Ali ◽

Mahmood Talkhabi ◽

Peng Zhao ◽

Young-Jae Nam ◽

...

Keyword(s):

Heart Development ◽

Cardiac Fibroblasts ◽

Immunohistochemical Analysis ◽

Cell Types ◽

Mouse Heart ◽

Developmental Potential ◽

Reporter Mice ◽

Significant Difference ◽

Definition Of

Rationale: The traditional definition of “cardiovascular” lineages describes the eponymous cell types - cardiomyoctes, endothelial cells, and smooth muscle cells - that arise from a common mesodermal progenitor cell during heart development. Fibroblasts are an abundant mesenchymal population in the mammalian heart which may have multiple, discrete developmental origins. Mesp1 represents the earliest marker of cardiovascular progenitors, contributing to the majority of cardiac lineages. To date no link between Mesp1 and fibroblast generation has been reported. Objective: We hypothesized progenitor cells expressing Mesp1 can also give rise to cardiac fibroblasts during heart development. Methods and Results: We generated Mesp1cre/+;R26RmTmG reporter mice where Cre-mediated recombination results in GFP activation in all Mesp1 expressing cells and their progeny. To explore their developmental potential, we isolated GFP+ cells from E7.5 Mesp1cre/+;R26RmTmG mouse. In vitro culture and transplantation studies into SCID mouse kidney capsule as wells as chick embryos showed fibroblastic adoption. Results showed that at E9.5 Mesp1+ and Mesp1- progenitors contributed to the proepicardium organ and later at E11.5 they formed epicardium. Analysis of adult hearts demonstrated that the majority of cardiac fibroblasts are derived from Mesp1 expressing cells. Immunohistochemical analysis of heart sections demonstrated expression of fibroblast markers (including DDR2, PDGFRα and Col1) in cells derived from both Mesp1+ and Mesp1- progenitors. Additionally, we investigated whether the two distinct fibroblast populations have different potency towards reprogramming to cardiomyocytes. Results showed no significant difference between Mesp1 and non-Mesp1 isolated fibroblasts to convert to cardiomyocyte fate. Conclusions: Our data demonstrates that cardiovascular progenitors expressing Mesp1 contribute to the proepicardium. These cells, as cardiovascular progenitors, also give rise to the highest portion of cardiac fibroblasts in the mouse heart.

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