The effect of anthracyclines on heart mitochondria respiration during the action of creatine phosphokinase

It was shown that during glutamate+malate oxidation in the presence of creatine, antitumour anthracycline antibiotics strongly inhibit the rate of oxygen uptake by rat heart mitochondria; ADP excess activated the respiration up to the initial level, i.e., that observed after the first addition of ADP. Carboxyatractyloside addition to a system containing creatine (or hexokinase+glucose) results in the stimulation of rubomycin-induced mitochondrial respiration. Substitution of carboxyatractyloside by oligomycin gives very similar results. It is supposed that anthracycline antibiotics exert a manyfold effect on heart mitochondrial membranes which results in impaired compartmentation of enzymatic systems providing for oxidative phosphorylation.     

The lack of direct coupling between ATP-ADP translocase and creatine phosphokinase in isolated rabbit heart mitochondria

The formation of creatine phosphate by isolated rabbit heart mitochondria in the presence of creatine, α-ketoglutarate, ATP, and inorganic phosphate was studied. Creatine phosphate formation was inhibited by oligomycin. This was most probably due to increased concentration of ADP favoring the reverse reaction (formation of creatine and ATP from phosphocreatine and ADP). The inhibitory effect of oligomycin disappeared in the presence of phosphoenolpyruvate and pyruvate kinase. The results do not indicate any direct coupling between mitochondrial creatine phosphokinase and ATP-ADP translocase as has been suggested for rat heart mitochondria.     

Purification of creatine kinase from beef heart mitochondria]

53-fold purified creatine kinase is isolated from beef heart mitochondria by phosphate buffer extraction followed by chromatography on DEAE-cellulose and KM-cellulose and preparative electrophoresis in phosphate buffer density gradient. The purified enzyme was homogenous under electrophoresis in agarose gel and moved to cathode. The enzyme did not enter into separating gel under disc electrophoresis in conditions for the separation of neutral anc acid proteins, while under conditions for separating alkaline proteins it produced five fractions. The stability of creatine kinase under storage considerably decreased after the purification.     

Role of creatine phosphokinase in the energy supply of the pumping function of the heart]

The cardiac output of isolated working rat heart and left ventricular pressure were estimated in either almost complete inhibition of creatine kinase by iodoacetamide or predominant fall in adenine nucleotides (AdN) content induced by 2-deoxyglucose treatment. In the former case, a profound cardiac pump failure was observed despite almost normal levels of myocardial AdN and phosphocreatine. Those hearts could not maintain the aortic output at standard load due to lower LV systolic pressure, that was accompanied by increased minimal and maximal diastolic pressures by 5-7 mm Hg as well as by LV diastolic stiffness. As LV systolic pressure in those hearts was unchanged in retrogradely perfused and unloaded hearts it might be suggested that the cardiac pump failure was caused by the decreased LV distensibility. On the contrary, deoxyglucose treatment that resulted in 70% fall in the AdN content was accompanied by only moderate reduction of the cardiac output and insignificant changes in LV diastolic pressure and stiffness. The results suggested that creatine kinase plays a crucial role in the maintenance of normal myofibrillar compliance, which is necessary for cardiac filling and pump function.     

In situ study of myofibrils,mitochondria and bound creatine kinases in experimental cardiomyopathies

Human cardiomyopathy has been extensively studied in the last decade, and knowledge of the functional and structural alterations of the heart has grown. However, understanding of the pathogenesis has come mostly from experimental studies. A number of work have been designed to elucidate if alterations of the contractile apparatus of cardiac cells contribute to the impairment of heart mechanics in cardiomyopathies. As well, an important question is to be solved: whether energy supply of the contraction-relaxation cycle is sufficient in the myopathic heart. Use of cardiac fibers skinned by different techniques allows to evaluate functional ability of myofibrils, mitochondria and bound creatine kinase which plays an important role in cardiomyocyte energy metabolism. The data presented in this chapter show that experimental cardiomyopathies of various types have some common features. These are an increase in calcium sensitivity of myofibrils and a depression of functional activity of mitochondrial creatine kinase. Possible mechanisms and physiological significance of these changes are discussed.     

The functional coupling between Ca2+-ATPase and creatine phosphokinase in heart muscle sarcoplasmic reticulum]

The functional role of creatine phosphokinase (CPK) in the process of energy supply for the Ca2+-ATPase reaction and ion transport across the membrane of heart sarcoplasmic reticulum (SR) has been studied. It has been shown that isolated and purified preparations of heart SR contain significant activity of CPK. The localization of CPK on the membrane of SR has been revealed also by an electron microscopic histochemical method. Under conditions of the Ca+-ATPase reaction in the presence of creatine phosphate the release of creatine into the reaction medium is observed, the rate of the latter process being dependent upon the MgATP concentration in accordance with the kinetic parameters of the Ca2+-ATPase reaction. CPK localized on the SR membrane is able to maintain higher rate of calcium uptake by SR vesicles, as compared to that with added ATP-regenerating system. The results obtained demonstrate the close functional coupling between CPK and Ca2+-ATPase in the membrane of SR.     

The functional coupling between MM isozyme of creatine phosphokinase (EC 2.7.3.2.) and MgATPase of myofibrils and (Na, K)ATPase of plasma membrane in heart cells]

The functional role of particulate MM isozyme of creatine phosphokinase (CPK) bound to heart myofibrils has been studied. It has been shown that in the presence of heart myofibrils and MgATP creatine phosphate can be used to rephosphorylate ADP formed in the MgATPase reaction. The rate of creatine phosphate splitting is determined by the kinetic properties of myofibrillar MgATPase and by the kinetic parameters of myofibrillar CPK. It has been found that a purified heart plasma membrane preparation contains high CPK activity. CPK isozyme bound to plasma membrane of heart cells is identical to MM isozyme of CPK and is able to rephosphorylate effectively ADP, formed in the (Na K)ATPase reaction. The rate of creatine phosphate splitting in these coupled reactions is sensitive to ouabain and is determined by the kinetic parameters both of the (Na, K)ATPase and plasma membrane CPK. The results obtained indicate the important role of myofibrillar and plasma membrane CPK in the intracellular energy transport processes.     

An electron microscopic histochemical investigation of the localization of creatine phosphokinase in heart cells

The results of an electron microscopic histochemical investigation performed in the current study indicate that in heart cells creatine phosphokinase is localized:(1) inside mitochondria on the cristae membranes, (2) on the membrane of the sarcoplasmic reticulum, (3) on myofbrils (and in cytoplasm), (4) on the plasma membrane of the cells, (5) on the membrane of the cell nuclei.     

Localization of creatine kinase isoenzymes in myofibrils. II. Chicken heart muscle

Chicken heart muscle contains almost exclusively the BB isoenzyme of creatine kinase (CK), its myofibrils, moreover, lack an M-line. This tissue thus provides an interesting contrast to skeletal muscle, in which some of the MM-CK present as predominant CK isoenzyme is bound at the myofibrillar M-line. Approx. 2% of the total CK activity in a chicken heart homogenate remains bound to the myofibrillar fraction after repeated washing cycles; both the fraction and the absolute amount of CK bound are about threefold lower than in skeletal muscle. Almost all of the bound enzyme is located within the Z-line region of each sarcomere, as revealed by indirect fluorescent-antibody staining with antiserum against purified chicken BB-CK. After incubation with exogenous purified MM-CK, positive immunofluorescent staining for M- type CK at the H-region of heart myofibrils was observed, along with weaker fluorescence in the Z-line region. Chicken heart myofibrils may thus possess binding sites for both M and B forms of CK.     

Binding of creatine kinase to heart and liver mitochondria in vitro

Phosphate extraction of heart mitochondria results in the release of creatine kinase. Under appropriate conditions phosphate-extracted mitochondria are able to rebind the creatine kinase, either from crude extracts or as the purified enzyme. Heart mitochondria are able to bind up to sevenfold more creatine kinase than they originally contained. The association is specific since the cytoplasmic isozyme from heart (MM) does not bind, and does not interfere with the binding of the mitochondrial isozyme even when MM is present in large excess. It is interesting that although liver mitochondria do not contain the mitochondrial isozyme of creatine kinase they are able to bind approximately the same amount of the enzyme as the heart mitochondria.     

Intimate coupling of creatine phosphokinase and myofibrillar adenosinetriphosphatase

ATPase and creatine phosphokinase (CPK) activities of isolated cardiac myofibrils were determined with ³²P γ-labeled ATP alone and with the addition of phosphorylcreatine (PC). With ATP and PC as substrates the label in the inorganic phosphate formed is greatly diluted indicating that the ATP formed by PC through CPK can reach the ATPase active site more readily than labeled ATP from the medium. The tight coupling of the ATPase and CPK activities further strengthens our view that PC serves an important role as high energy carrier between the energy producing sites (mitochondria) and the energy utilizing sites (myofibrils).