Modular organization of cardiac energy metabolism: energy conversion, transfer and feedback regulation.

To meet high cellular demands, the energy metabolism of cardiac muscles is organized by precise and coordinated functioning of intracellular energetic units (ICEUs). ICEUs represent structural and functional modules integrating multiple fluxes at sites of ATP generation in mitochondria and ATP utilization by myofibrillar, sarcoplasmic reticulum and sarcolemma ion-pump ATPases. The role of ICEUs is to enhance the efficiency of vectorial intracellular energy transfer and fine tuning of oxidative ATP synthesis maintaining stable metabolite levels to adjust to intracellular energy needs through the dynamic system of compartmentalized phosphoryl transfer networks. One of the key elements in regulation of energy flux distribution and feedback communication is the selective permeability of mitochondrial outer membrane (MOM) which represents a bottleneck in adenine nucleotide and other energy metabolite transfer and microcompartmentalization. Based on the experimental and theoretical (mathematical modelling) arguments, we describe regulation of mitochondrial ATP synthesis within ICEUs allowing heart workload to be linearly correlated with oxygen consumption ensuring conditions of metabolic stability, signal communication and synchronization. Particular attention was paid to the structure-function relationship in the development of ICEU, and the role of mitochondria interaction with cytoskeletal proteins, like tubulin, in the regulation of MOM permeability in response to energy metabolic signals providing regulation of mitochondrial respiration. Emphasis was given to the importance of creatine metabolism for the cardiac energy homoeostasis.

Systems bioenergetics of creatine kinase networks: physiological roles of creatine and phosphocreatine in regulation of cardiac cell function.

Physiological role of creatine (Cr) became first evident in the experiments of Belitzer and Tsybakova in 1939, who showed that oxygen consumption in a well-washed skeletal muscle homogenate increases strongly in the presence of creatine and with this results in phosphocreatine (PCr) production with PCr/O(2) ratio of about 5-6. This was the beginning of quantitative analysis in bioenergetics. It was also observed in many physiological experiments that the contractile force changes in parallel with the alteration in the PCr content. On the other hand, it was shown that when heart function is governed by Frank-Starling law, work performance and oxygen consumption rate increase in parallel without any changes in PCr and ATP tissue contents (metabolic homeostasis). Studies of cellular mechanisms of all these important phenomena helped in shaping new approach to bioenergetics, Molecular System Bioenergetics, a part of Systems Biology. This approach takes into consideration intracellular interactions that lead to novel mechanisms of regulation of energy fluxes. In particular, interactions between mitochondria and cytoskeleton resulting in selective restriction of permeability of outer mitochondrial membrane anion channel (VDAC) for adenine nucleotides and thus their recycling in mitochondria coupled to effective synthesis of PCr by mitochondrial creatine kinase, MtCK. Therefore, Cr concentration and the PCr/Cr ratio became important kinetic parameters in the regulation of respiration and energy fluxes in muscle cells. Decrease in the intracellular contents of Cr and PCr results in a hypodynamic state of muscle and muscle pathology. Many experimental studies have revealed that PCr may play two important roles in the regulation of muscle energetics: first by maintaining local ATP pools via compartmentalized creatine kinase reactions, and secondly by stabilizing cellular membranes due to electrostatic interactions with phospholipids. The second mechanism decreases the production of lysophosphoglycerides in hypoxic heart, protects the cardiac cells sarcolemma against ischemic damage, decreases the frequency of arrhythmias and increases the post-ischemic recovery of contractile function. PCr is used as a pharmacological product Neoton in cardiac surgery as one of the components of cardioplegic solutions for protection of the heart against intraoperational injury and injected intravenously in acute myocardial ischemic conditions for improving the hemodynamic response and clinical conditions of patients with heart failure.