Glycolysis Supports Calcium Uptake by the Sarcoplasmic Reticulum in Skinned Ventricular Fibres of Mice Deficient in Mitochondrial and Cytosolic Creatine Kinase

E. Boehm, R. Ventura-Clapier, P. Mateo, P. Lechène and V. Veksler. Glycolysis Supports Calcium Uptake by the Sarcoplasmic Reticulum in Skinned Ventricular Fibres of Mice Deficient in Mitochondrial and Cytosolic Creatine Kinase. Journal of Molecular and Cellular Cardiology (2000) 32, 891–902. Several works have shown the importance of the creatine kinase (CK) system for cardiac energetics and Ca2+homeostasis. Nevertheless, CK-deficient mice have cardiac function close to normal, at least under conditions of low or moderate workload. To characterize possible adaptive changes of the sarcoplasmic reticulum (SR) and potential role of glycolytic support in cardiac contractility we used the skinned fibre technique to study properties of the SR and myofibrils, in control and muscle-type homodimer (MM-/mitochondrial-CK)-deficient mice. In control fibres, SR Ca2+loading with ATP and phosphocreatine (solution PL) was significantly better than loading with ATP alone (solution AL), as determined by analysis of caffeine-induced tension transients. Loading in the presence of ATP and glycolytic intermediates (solution GL) was not significantly different from solution PL. These data indicate that Ca2+uptake by the SR in situ depends on a local ATP:ADP ratio that is controlled by both CK and glycolytic enzymes. In CK-deficient mice, Ca2+loading was impaired in solution PLdue to the absence of CK. In solution GL, loading was significantly increased, such that calculated Ca2+release parameters were normalized to those in control fibres in solution PL. In CK-deficient mice, fibre kinetic parameters of tension recovery were impaired after quick stretch in solution PLand were not improved in solution GL. These results show that in CK-deficient mice, at least under basal conditions, glycolysis can replace the CK system in fueling the SR Ca2+ATPase, but not the myosin ATPase, and may in part explain the limited phenotypic alterations seen in the hearts of these mice.