Abstract Body: Mammalian cardiomyocytes undergo a loss of proliferative capacity due to cell division failure, leading to polyploidy (genome duplication) during postnatal maturation. Centrosomes, primary microtubule organizing centers (MTOCs) in animal cells comprised of centrioles and pericentriolar matrix (PCM), play a crucial role in cell division. In differentiated cells, non-centrosomal (nc) MTOCs can reorganize microtubules, with cellular localization varying between cell types to mediate specialized functions. The specific role of ncMTOCs in cardiomyocyte division and maturation remains unknown.
This study investigates the formation and function of ncMTOCs in cardiomyocytes, aiming to elucidate the regulating mechanism. Our results demonstrate that during the maturation of human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs), centrosomes disassemble, and their PCM translocates to the nuclear envelope, establishing perinuclear ncMTOCs. Furthermore, maturing CMs with ncMTOCs often exhibit polyploidy, indicating incomplete cell division. Microtubule dynamic experiments reveal that ncMTOCs serve as organizing centers for microtubules, promoting their assembly around the nucleus in maturing cardiomyocytes.
To understand the mechanism regulating the transition from centrosomes to ncMTOCs in cardiomyocytes, we identified a significant downregulation of the nuclear lamina protein Lamin B2 (LMNB2) during CM maturation. Our results indicate that LMNB2 is essential for mitotic spindle formation in CMs but not in stem cells, suggesting a distinct role for LMNB2 in CMs. Our results also suggest an increased centrosome to ncMTOC transition in LMNB2-depleted CMs at an early differentiation stage.
Ongoing research aims to investigate the impact of perinuclear ncMTOCs on cardiomyocyte proliferation through pericentriolar matrix knockdown in hiPSC-CMs. Additionally, the study seeks to further elucidate the role of Lamin B2 in the transition of centrosome proteins and its underlying mechanism.