Restoration of Ca2+-inhibited oxidative phosphorylation in cardiac mitochondria by mitochondrial Ca2+ unloading

Mitochondria, the major source of cellular ATP, display high vulnerability to metabolic stress, in particular to excessive Ca2+ loading. Here, we show that Ca2+-inhibited mitochondrial ATP generation could be restored through stimulated Ca2+ discharge from mitochondrial matrix. This was demonstrated using a Ca2+ ionophore or through Na+/Ca2+ exchange-mediated decrease of mitochondrial Ca2+ load. Furthermore, diazoxide, a mitochondrial potassium channel opener, which maintained mitochondrial Ca2+ homeostasis, also restored Ca2+-inhibited ATP synthesis and preserved the structural integrity of Ca2+-challenged mitochondria. Thus, under conditions of excessive mitochondrial Ca2+ overload targeting mitochondrial Ca2+ transport pathways restores oxidative phosphorylation required for vital cellular processes. This study, therefore, identifies an effective strategy capable to rescue Ca2+-disrupted mitochondrial energetics.