Department of Cell Biology, Neurobiology, and Anatomy, Medical College of Wisconsin, Milwaukee, Wisconsin, United States.
Cardiovascular Center, Medical College of Wisconsin, Milwaukee, Wisconsin, United States.
Am J Physiol Heart Circ Physiol. 2024 Aug 1;327(2):H377-H389. doi: 10.1152/ajpheart.00782.2023. Epub 2024 Jun 7.
Factors responsible for cardiomyocyte proliferation could serve as potential therapeutics to stimulate endogenous myocardial regeneration following insult, such as ischemic injury. A previously published forward genetics approach on cardiomyocyte cell cycle and ploidy led us to the transcription factor, . Here, we examine the effect of on cardiomyocyte cell cycle during postnatal development and cardiac regeneration using cardiomyocyte-specific gain- and loss-of-function mouse models. RUNX1 is expressed in cardiomyocytes during early postnatal life, decreases to negligible levels by 3 wk of age, and increases upon myocardial injury, all consistent with observed rates of cardiomyocyte cell-cycle activity. Loss of transiently stymied cardiomyocyte cell-cycle activity during normal postnatal development, a result that corrected itself and did not extend to the context of neonatal heart regeneration. On the other hand, cardiomyocyte-specific overexpression resulted in an expansion of diploid cardiomyocytes in uninjured hearts and expansion of 4 N cardiomyocytes in the context of neonatal cardiac injury, suggesting overexpression is sufficient to induce cardiomyocyte cell-cycle responses. Persistent overexpression of for >1 mo continued to promote cardiomyocyte cell-cycle activity resulting in substantial hyperpolyploidization (≥8 N DNA content). This persistent cell-cycle activation was accompanied by ventricular dilation and adverse remodeling, raising the concern that continued cardiomyocyte cell cycling can have detrimental effects. is sufficient but not required for cardiomyocyte cell cycle.
导致心肌细胞增殖的因素可作为潜在的治疗方法,以刺激内源性心肌再生,如缺血损伤。我们之前发表的一项关于心肌细胞细胞周期和倍性的正向遗传学方法使我们发现了转录因子 RUNX1。在这里,我们使用心肌细胞特异性的 gain-of-function 和 loss-of-function 小鼠模型来研究 RUNX1 在出生后发育和心脏再生过程中对心肌细胞细胞周期的影响。RUNX1 在出生后的早期阶段在心肌细胞中表达,在 3 周龄时降至可忽略的水平,并在心肌损伤时增加,所有这些都与观察到的心肌细胞细胞周期活性的速率一致。RUNX1 的缺失在正常的出生后发育过程中暂时阻碍了心肌细胞的细胞周期活性,但这种情况会自行纠正,并且不会扩展到新生儿心脏再生的情况下。另一方面,心肌细胞特异性的 RUNX1 过表达导致未受伤心脏中二倍体心肌细胞的扩张和新生儿心脏损伤情况下 4N 心肌细胞的扩张,表明 RUNX1 过表达足以诱导心肌细胞的细胞周期反应。超过 1 个月的 RUNX1 持续过表达继续促进心肌细胞的细胞周期活性,导致显著的超多倍体化(≥8N DNA 含量)。这种持续的细胞周期激活伴随着心室扩张和不良重塑,这引起了人们的关注,即持续的心肌细胞细胞周期活动可能会产生有害影响。RUNX1 是心肌细胞细胞周期所必需的,但不是充分的。
