Browsing by Subject "ihmisen monikykyisistä kantasoluista erilaistetut sydänlihassolut"

Ischemic heart disease (IHD) and subsequent heart failure are caused by irreversible loss of contractile cardiomyocytes due to low oxygen supply to the heart. As the leading cause of death worldwide, IHD raises an urgent need for regenerative therapies that prevent or reverse loss of cardiomyocytes. The fetal mammalian heart grows by cardiomyocyte proliferation and utilizes glycolysis as main energy metabolism pathway, until it is introduced to increased oxygen and fatty acid supply at birth. Subsequently, cardiac energy metabolism shifts from glycolysis to β-oxidation of fatty acids and cardiomyocytes exit the mitotic cell cycle. Due to cessation of proliferation the heart can no longer regenerate after ischemic injury and responds to it by introduction of maladaptive pathological processes leading to heart failure. To gain deeper insight on the roles of cardiac metabolism pathways and hypoxia in cell cycle activation, we evaluated the effects of pharmacological metabolic modulation and oxygen supply on cardiomyocyte phenotype and hypoxia response. Furthermore, we studied the changes in the metabolic genotype of cardiomyocytes under alterations of oxygen supply. We utilized quantitative reverse transcription PCR (qRT-PCR) to evaluate the effects of hypoxia and metabolic maturation on the expression of genes involved in hypoxia signaling and metabolism of human induced pluripotent stem cell derived cardiomyocytes (hiPSC-CMs). Additionally, we investigated the effects of five metabolism-modulating compounds on cell cycle and phenotype of both metabolically matured and unmatured hiPSC-CMs, by utilizing high content analysis. We observed presence of hypoxia signaling as an increase in vascular endothelial growth factor A (VEGFA) expression following 3-hour hypoxic exposure. High expression of succinate dehydrogenase complex flavoprotein subunit A (SDHA) in hiPSC-CMs, which was downregulated at hypoxia, confirmed occurrence of oxidative metabolism induced by metabolic maturation. Surprisingly, metabolic maturation tended to increase proliferation and decrease stress response signaling of hiPSC-CMs. Introduction of the TCA cycle intermediate succinate decreased proliferation of metabolically unmatured hypoxic hiPSC-CMs by 8.2 %. Finally, inhibition of the mevalonate pathway and ketogenesis caused no alterations in hiPSC-CM phenotype or cell cycle, but introduction of the ketone body β-hydroxybutyrate tended to increase proliferation, supporting current evidence that ketogenesis plays a role in cardiomyocyte cell cycle regulation. Our observations suggest that hypoxic hiPSC-CMs can be useful in investigating gene expression and phenotype. Even so, additional methodologies are needed for in-depth evaluation of metabolic reprogramming and its effects on cardiomyocyte phenotype.