Antihypertrophic Effects of Small Molecules that Maintain Mitochondrial ATP Levels Under Hypoxia.

Since impaired mitochondrial ATP production in cardiomyocytes is thought to lead to heart failure, a drug that protects mitochondria and improves ATP production under disease conditions would be an attractive treatment option. In this study, we identified small-molecule drugs, including the anti-parasitic agent, ivermectin, that maintain mitochondrial ATP levels under hypoxia in cardiomyocytes. Mechanistically, transcriptomic analysis and gene silencing experiments revealed that ivermectin increased mitochondrial ATP production by inducing Cox6a2, a subunit of the mitochondrial respiratory chain. Furthermore, ivermectin inhibited the hypertrophic response of human induced pluripotent stem cell-derived cardiomyocytes. Pharmacological inhibition of importin ß, one of the targets of ivermectin, exhibited protection against mitochondrial ATP decline and cardiomyocyte hypertrophy. These findings indicate that maintaining mitochondrial ATP under hypoxia may prevent hypertrophy and improve cardiac function, providing therapeutic options for mitochondrial dysfunction.

Fasiglifam (TAK-875) has dual potentiating mechanisms via Gαq-GPR40/FFAR1 signaling branches on glucose-dependent insulin secretion.

Fasiglifam (TAK-875) is a free fatty acid receptor 1 (FFAR1)/G-protein-coupled receptor 40 (GPR40) agonist that improves glycemic control in type 2 diabetes with minimum risk of hypoglycemia. Fasiglifam potentiates glucose-stimulated insulin secretion (GSIS) from pancreatic ß-cells glucose dependently, although the precise mechanism underlying the glucose dependency still remains unknown. Here, we investigated key cross-talk between the GSIS pathway and FFAR1 signaling, and Ca(2+) dynamics using mouse insulinoma MIN6 cells. We demonstrated that the glucose-dependent insulinotropic effect of fasiglifam required membrane depolarization and that fasiglifam induced a glucose-dependent increase in intracellular Ca(2+) level and amplification of Ca(2+) oscillations. This differed from the sulfonylurea glimepiride that induced changes in Ca(2+) dynamics glucose independently. Stimulation with cell-permeable analogs of IP3 or diacylglycerol (DAG), downstream second messengers of Gαq-FFAR1, augmented GSIS similar to fasiglifam, indicating their individual roles in the potentiation of GSIS pathway. Intriguingly, the IP3 analog triggered similar Ca(2+) dynamics to fasiglifam, whereas the DAG analog had no effect. Despite the lack of an effect on Ca(2+) dynamics, the DAG analog elicited synergistic effects on insulin secretion with Ca(2+) influx evoked by an L-type voltage-dependent calcium channel opener that mimics glucose-dependent Ca(2+) dynamics. These results indicate that the Gαq signaling activated by fasiglifam enhances GSIS pathway via dual potentiating mechanisms in which IP3 amplifies glucose-induced Ca(2+) oscillations and DAG/protein kinase C (PKC) augments downstream secretory mechanisms independent of Ca(2+) oscillations.