Background: Much is known about the differences between adult and immature fetal cardiac myocytes. For example, the switch from glycolysis to oxidative phosphorylation, the increase in sarcomere distance and cell size, along with changes in mitochondrial structure and organization are all known to occur at some point between late embryonic development and adulthood. However, the precise timing of when these changes take place is ill-defined. Here, we report in high temporal resolution when hallmarks of maturation develop to provide a timeline and the order of events that are necessary for structural and physiological cardiomyocyte maturation. Methods and Results: Using murine samples from embryonic day 15 all the way to adulthood, we performed characterization of basic organelles, contractile machinery, and extracellular matrix composition, all shown to be necessary for cardiac maturation. We observed clear differences in when maturation hallmarks became established. Features that increased continuously include growth of the size of the heart and cardiomyocytes. Accompanying cell size changes, an increase in endothelial cell count was observed, although cardiomyocyte growth continued after the endothelial cell population reached a plateau. Seahorse assays revealed that mitochondrial respiration increased continuously over time for Complex 1 and 2 until about postnatal day 15, with complex 4 being relatively stable throughout maturation. Lipid droplets appeared at a higher frequency in ventricular tissue starting at postnatal day 5, coinciding with an increase in sarcomere length. T-tubules began to appear at postnatal day 7 alongside changes in calcium handling genes. Mitochondrial size was found to increase rapidly at postnatal day 19. Discussion: Overall, we found that multiple stages of development seem important to target for enhancing maturation as not all changes occur in a linear fashion. Ultimately, knowledge of when maturational hallmarks develop might inform strategies to enhance maturation of human induced pluripotent stem cell derived cardiomyocytes. T32 Minnesota Muscle Training Grant; Summer’s Wish; Regenerative Medicine Minnesota; Stem Cell Institute Predoctoral Infuse Award. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.
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