Nefroloogia

Eesti Arst 2014; 93(10):59

Intracellular diffusion of adenosine phosphates is locally restricted in cardiac muscle.

International audienceRecent studies have revealed the structural and functional interactions between mitochondria, myofibrils and sarcoplasmic reticulum in cardiac cells. Direct channeling of adenosine phosphates between organelles identified in the experiments indicates that diffusion of adenosine phosphates is limited in cardiac cells due to very specific intracellular structural organization. However, the mode of diffusion restrictions and nature of the intracellular structures in creating the diffusion barriers is still unclear, and, therefore, a subject of active research. The aim of this work is to analyze the possible role of two principally different modes of restriction distribution for adenosine phosphates (a) the uniform diffusion restriction and (b) the localized diffusion limitation in the vicinity of mitochondria, by fitting the experimental data with the mathematical model. The reaction-diffusion model of compartmentalized energy transfer was used to analyze the data obtained from the experiments with the skinned muscle fibers, which described the following processes: mitochondrial respiration rate dependency on exogenous ADP and ATP concentrations; inhibition of endogenous ADP-stimulated respiration by pyruvate kinase (PK) and phosphoenolpyruvate (PEP) system; kinetics of oxygen consumption stabilization after addition of 2 mM MgATP or MgADP; ATPase activity with inhibited mitochondrial respiration; and buildup of MgADP concentration in the medium after addition of MgATP. The analysis revealed that only the second mechanism considered--localization of diffusion restrictions--is able to account for the experimental data. In the case of uniform diffusion restrictions, the model solution was in agreement only with two measurements: the respiration rate as a function of ADP or ATP concentrations and inhibition of respiration by PK + PEP. It was concluded that intracellular diffusion restrictions for adenosine phosphates are not distributed uniformly, but rather are localized in certain compartments of the cardiac cells

Calcium-induced contraction of sarcomeres changes the regulation of mitochondrial respiration in permeabilized cardiac cells.

International audienceThe relationships between cardiac cell structure and the regulation of mitochondrial respiration were studied by applying fluorescent confocal microscopy and analysing the kinetics of mitochondrial ADP-stimulated respiration, during calcium-induced contraction in permeabilized cardiomyocytes and myocardial fibers, and in their 'ghost' preparations (after selective myosin extraction). Up to 3 microm free calcium, in the presence of ATP, induced strong contraction of permeabilized cardiomyocytes with intact sarcomeres, accompanied by alterations in mitochondrial arrangement and a significant decrease in the apparent K(m) for exogenous ADP and ATP in the kinetics of mitochondrial respiration. The V(max) of respiration showed a moderate (50%) increase, with an optimum at 0.4 microm free calcium and a decrease at higher calcium concentrations. At high free-calcium concentrations, the direct flux of ADP from ATPases to mitochondria was diminished compared to that at low calcium levels. All of these effects were unrelated either to mitochondrial calcium overload or to mitochondrial permeability transition and were not observed in 'ghost' preparations after the selective extraction of myosin. Our results suggest that the structural changes transmitted from contractile apparatus to mitochondria modify localized restrictions of the diffusion of adenine nucleotides and thus may actively participate in the regulation of mitochondrial function, in addition to the metabolic signalling via the creatine kinase system

Altered mitochondrial apparent affinity for ADP and impaired function of mitochondrial creatine kinase in gluteus medius of patients with hip osteoarthritis.

International audienceThe cellular energy metabolism in human musculus gluteus medius (MGM) under normal conditions and hip osteoarthritis (OA) was explored. The functions of oxidative phosphorylation and energy transport systems were analyzed in permeabilized (skinned) muscle fibers by oxygraphy, in relation to myosin heavy chain (MHC) isoform distribution profile analyzed by SDS-PAGE, and to creatine kinase (CK) and adenylate kinase (AK) activities measured spectrophotometrically in the intact muscle. The results revealed high apparent Km for ADP in regulation of respiration that decreased after addition of creatine in MGM of traumatic patients (controls). OA was associated with increased sensitivity of mitochondrial respiration to ADP, decreased total activities of AK and CK with major reduction in mi-CK fraction, and attenuated effect of creatine on apparent Km for ADP compared with control group. It also included a complete loss of type II fibers in a subgroup of patients with the severest disease grade. It is concluded that energy metabolism in MGM cells is organized into functional complexes of mitochondria and ATPases. It is suggested that because of degenerative remodeling occurring during development of OA, these complexes become structurally and functionally impaired, which results in increased access of exogenous ADP to mitochondria and dysfunction of CK-phosphotransfer system

Compartmentation of energy metabolism in atrial myocardium of patients undergoing cardiac surgery.

International audienceThe parameters of oxidative phosphorylation and its interaction with creatine kinase (CK)- and adenylate kinase (AK)-phosphotransfer networks in situ were studied in skinned atrial fibers from 59 patients undergoing coronary artery bypass surgery, valve replacement/correction and atrial septal defect correction. In atria, the mitochondrial CK and AK are effectively coupled to oxidative phosphorylation, the MM-CK is coupled to ATPases and there exists a direct transfer of adenine nucleotides between mitochondria and ATPases. Elimination of cytoplasmic ADP with exogenous pyruvate kinase was not associated with a blockade of the stimulatory effects of creatine and AMP on respiration, neither could it abolish the coupling of MM-CK to ATPases and direct transfer of adenine nucleotides. Thus, atrial energy metabolism is compartmentalized so that mitochondria form functional complexes with adjacent ATPases. These complexes isolate a part of cellular adenine nucleotides from their cytoplasmic pool for participating in energy transfer via CK- and AK-networks, and/or direct exchange. Compared to atria in sinus rhythm, the fibrillating atria were larger and exhibited increased succinate-dependent respiration relative to glutamate-dependent respiration and augmented proton leak. Thus, alterations in mitochondrial oxidative phosphorylation may contribute to pathogenesis of atrial fibrillation

Oxidative phosphorylation and its coupling to mitochondrial creatine and adenylate kinases in human gastric mucosa.

International audienceEnergy metabolism in gastrobiopsy specimens of the antral and corpus mucosa, treated with saponin to permeabilize the cells, was studied in patients with gastric diseases. The results show twice lower oxidative capacity in the antral mucosa than in the corpus mucosa and the relative deficiency of antral mitochondria in complex I. The mucosal cells expressed mitochondrial and cytosolic isoforms of creatine kinase and adenylate kinase (AK). Creatine (20 mM) and AMP (2 mM) markedly stimulated mitochondrial respiration in the presence of submaximal ADP or ATP concentrations, and creatine reduced apparent Km for ADP in stimulation of respiration, which indicates the functional coupling of mitochondrial kinases to oxidative phosphorylation. Addition of exogenous cytochrome c increased ADP-dependent respiration, and the large-scale cytochrome c effect (>or=20%) was associated with suppressed stimulation of respiration by creatine and AMP in the mucosal preparations. These results point to the impaired mitochondrial outer membrane, probably attributed to the pathogenic effects of Helicobacter pylori. Compared with the corpus mucosa, the antral mucosa exhibited greater sensitivity to such type of injury as the prevalence of the large-scale cytochrome c effect was twice higher among the latter specimens. Active chronic gastritis was associated with decreased respiratory capacity of the corpus mucosa but with its increase in the antral mucosa. In conclusion, human gastric mucosal cells express the mitochondrial and cytosolic isoforms of CK and AK participating in intracellular energy transfer systems. Gastric mucosa disease is associated with the altered functions of these systems and oxidative phosphorylation

Structure-function relationships in the regulation of energy transfer between mitochondria and ATPases in cardiac cells

The present study discusses the role of structural organization of cardiac cells in determining the mechanisms of regulation of oxidative phosphorylation and interaction between mitochondria and ATPases. In permeabilized adult cardiomyocytes, the apparent Km (Michaelis-Menten constant) for ADP in the regulation of respiration is far higher than in mitochondria isolated from the myocardium. Respiration of mitochondria in permeabilized cardiomyocytes is effectively activated by endogenous ADP produced by ATPases from exogenous ATP, and the activation of respiration is associated with a decrease in the apparent Km for ATP in the regulation of ATPase activity compared with this parameter in the absence of oxidative phosphorylation. It has also been shown that a large fraction of the endogenous ADP stimulating respiration remains inaccessible for the exogenous ADP trapping system, consisting of pyruvate kinase and phosphoenolpyruvate, unless the mitochondrial structures are modified by controlled proteolysis. These data point to the endogenous cycling of adenine nucleotides between mitochondria and ATPases. Accordingly, the current hypothesis is that in cardiac cells, mitochondria and ATPases are compartmentalized into functional complexes (ie, intracellular energetic units [ICEUs]), which appear to represent a basic pattern of organization of energy metabolism in these cells. Within the ICEUs, the mitochondria and ATPases interact via different routes: creatine kinase-mediated phosphoryltransfer; adenylate kinase-mediated phosphoryltransfer; and direct ATP and ADP channelling. The function of ICEUs changes not only after selective proteolysis, but also during contraction of cardiomyocytes caused by an increase in cytosolic Ca2+ concentration up to micromolar levels. In these conditions, the apparent Km for exogenous ADP and ATP in the regulation of respiration markedly decreases, and more ADP becomes available for the exogenous pyruvate kinase-phosphoenolpyruvate system, which indicates altered barrier functions of the ICEUs. Thus, structural changes transmitted from the contractile apparatus to mitochondria clearly participate in the regulation of mitochondrial function due to alterations in localized restriction of the diffusion of adenine nucleotides. The importance of strict structural organization in cardiac cells emerged drastically from experiments in which the regulation of mitochondrial respiration was assessed in a novel cardiac cell line, that is, beating and nonbeating HL-1 cells. In these cells, the mitochondrial arrangement is irregular and dynamic, whereas the sarcomeric structures are either absent (in nonbeating HL-1 cells) or only rarely present (in beating HL-1 cells). In parallel, the apparent Km for exogenous ADP in the regulation of respiration was much lower than that in permeabilized primary cardiomyocytes, and trypsin treatment exerted no impact on the low Km value for ADP, in contrast to adult cardiomyocytes where it caused a marked decrease in this parameter. The HL-1 cells were also characterized by the absence of direct exchange of adenine nucleotides. The results further support the concept that the ICEUs in adult cardiomyocytes are products of complex structural organization developed to create the most optimal conditions for effective energy transfer and feedback between mitochondria and ATPases