Aims: Cardiomyocyte (CM) cell cycle arrest, decline of mononucleated-diploid CMs, sarcomeric maturation, and extracellular matrix remodeling are implicated in loss of cardiac regenerative potential in mice after birth. Recent studies show a 3-day neonatal regenerative capacity in pig hearts similar to mice, but postnatal pig CM growth dynamics are unknown. We examined cardiac maturation in postnatal pigs and mice, to determine the relative timing of developmental events underlying heart growth and regenerative potential in large and small mammals.
Methods and Results:Left ventricular tissue from White Yorkshire-Landrace pigs at postnatal day (P)0 to 6 months (6mo) was analyzed to span birth, weaning, and adolescence in pigs, compared to similar physiological timepoints in mice. Collagen remodeling increases by P7 in postnatal pigs, but sarcomeric and gap junctional maturation only occur at 2mo. Also, there is no postnatal transition to beta-oxidation metabolism in pig hearts. Mononucleated CMs, predominant at birth, persist to 2mo in swine, with over 50% incidence of mononucleated-diploid CMs at P7-P15. Extensive multinucleation with 4-16 nuclei per CM occurs beyond P30. Pigs also exhibit increased CM length relative to multinucleation, preceding increase in CM width at 2mo-6mo. Further, robust CM mitotic nuclear pHH3 activity and cardiac cell cycle gene expression is apparent in pig left ventricles up to 2mo. By contrast, in mice, these maturational events occur concurrently in the first two postnatal weeks alongside loss of cardiac regenerative capacity.Conclusions: Cardiac maturation occurs over a 6mo postnatal period in pigs, despite a similar early-neonatal heart regenerative window as mice. Postnatal pig CM growth includes increase in CM length alongside multinucleation, with CM cell cycle arrest and loss of mononucleated-diploid CMs occurring at 2mo-6mo. These CM characteristics are important to consider for pig preclinical studies and may offer opportunities to study aspects of heart regeneration unavailable in other models..
During the postnatal period, mammalian cardiomyocytes undergo numerous maturational changes associated with increased cardiac function and output, including hypertrophic growth, cell cycle exit, sarcomeric protein isoform switching, and mitochondrial maturation. These changes come at the expense of loss of regenerative capacity of the heart, contributing to heart failure after cardiac injury in adults. While most studies focus on the transcriptional regulation of embryonic or adult cardiomyocytes, the transcriptional changes that occur during the postnatal period are relatively unknown. In this review, we focus on the transcriptional regulators responsible for these aspects of cardiomyocyte maturation during the postnatal period in mammals. By specifically highlighting this transitional period, we draw attention to critical processes in cardiomyocyte maturation with potential therapeutic implications in cardiovascular disease.
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