Abstract 401: Polyploidy Increases in Murine Cardiomyocytes Following Myocardial Infarction

Abstract

Introduction: De novo cardiomyogenesis versus polyploidy in myocardial homeostasis, aging, and response to injury is a controversial research area of intense investigation. Our lab recently created the Fluorescent Ubiquitin Cell Cycle Indicator transgenic (FUCCI-Tg) mouse model to study cardiomyocyte (CM) cell cycle progression. Therefore, the FUCCI-Tg model was used to track CM cell cycle correlated to ploidy state in response to myocardial infarction (MI). Hypothesis: Adult FUCCI-Tg cardiomyocytes progress into S/G2/M phase of cell cycle by 10 days after infarction resulting in binucleation rather than de novo cardiomyogenesis. Methods and Results: CMs isolated from FUCCI-Tg were analyzed 3 and 10 days following MI using confocal microscopy and flow cytometry. At 3 days post-MI, the ratio of mono- to binucleated CMs remained unchanged from non-injury CMs. At day 10 post-MI, frequency of mononuclear CMs significantly decreased compared to normal or 3-day post-MI CMs. Coincident with nucleation state, myocytes were only found to enter S/G2/M phase at day 10 post-MI. These results were verified by visualization of FUCCI in isolated CMs using Amnis ImageStream flow cytometry. Ploidy state and CM size was assessed in the infarction / border (left ventricle (LV)) and remote zone (right ventricle (RV)) at day 10 post-MI and compared to the normal and sham LV and RV. Binucleation significantly increased in the LV after MI compared to normal LV, whereas RV CM binucleation and size significantly increased in both sham and MI at 10 days after MI compared to normal RV. Conclusion: Adult murine CMs enter cell cycle in response to MI but primarily undergo endomitosis / endoreplication rather than complete cell cycle reflecting increases in nucleation and/or myocyte size rather than de novo cardiomyogenesis. Future studies will assess CM ploidy in mouse strains purported to possess enhanced cardiomyogenesis following MI injury and the biological significance of ploidy for mediating myocardial repair.