TY - JOUR
T1 - Reduced matrix rigidity promotes neonatal cardiomyocyte dedifferentiation, proliferation and clonal expansion.
AU - Yahalom-Ronen, Yfat
AU - Rajchman, Dana
AU - Sarig, Rachel
AU - Geiger, Benjamin
AU - Tzahor, Eldad
N1 - This work was supported by grants to ET from the European Research Council (ERC Grant 281289, CMturnover) and the Israel Science Foundation, and FP7 grants to BG: EU 710639 (NanoCARD), an ERC project (294852, SynAd), and the Israel Science Foundation. We thank Dr. Shalev Itzkovitz for his help in providing the R26R-confetti reporter mice, and Ayal Ronen and Barbara Morgenstern for expert editorial assistance. We also thank Omri Yahalom, who assisted with the statistical methodology. BG holds the Erwin Neter Chair in Cell and Tumor Biology.
PY - 2015
Y1 - 2015
N2 - Cardiomyocyte (CM) maturation in mammals is accompanied by a sharp decline in their proliferative and regenerative potential shortly after birth. In this study, we explored the role of the mechanical properties of the underlying matrix in the regulation of CM maturation. We show that rat and mouse neonatal CMs cultured on rigid surfaces exhibited increased myofibrillar organization, spread morphology, and reduced cell cycle activity. In contrast, compliant elastic matrices induced features of CM dedifferentiation, including disorganized sarcomere network, rounding, and conspicuous cell-cycle re-entry. The rigid matrix facilitated nuclear division (karyokinesis) leading to binucleation, while compliant matrices promoted CM mitotic rounding and cell division (cytokinesis), associated with loss of differentiation markers. Moreover, the compliant matrix potentiated clonal expansion of CMs that involves multiple cell divisions. Thus, the compliant microenvironment facilitates CM dedifferentiation and proliferation via its effect on the organization of the myoskeleton. Our findings may be exploited to design new cardiac regenerative approaches.
AB - Cardiomyocyte (CM) maturation in mammals is accompanied by a sharp decline in their proliferative and regenerative potential shortly after birth. In this study, we explored the role of the mechanical properties of the underlying matrix in the regulation of CM maturation. We show that rat and mouse neonatal CMs cultured on rigid surfaces exhibited increased myofibrillar organization, spread morphology, and reduced cell cycle activity. In contrast, compliant elastic matrices induced features of CM dedifferentiation, including disorganized sarcomere network, rounding, and conspicuous cell-cycle re-entry. The rigid matrix facilitated nuclear division (karyokinesis) leading to binucleation, while compliant matrices promoted CM mitotic rounding and cell division (cytokinesis), associated with loss of differentiation markers. Moreover, the compliant matrix potentiated clonal expansion of CMs that involves multiple cell divisions. Thus, the compliant microenvironment facilitates CM dedifferentiation and proliferation via its effect on the organization of the myoskeleton. Our findings may be exploited to design new cardiac regenerative approaches.
U2 - https://doi.org/10.7554/eLife.07455
DO - https://doi.org/10.7554/eLife.07455
M3 - مقالة
SN - 2050-084X
VL - 4
JO - eLife
JF - eLife
ER -