Impaired Intracellular Energetic Communication in Muscles from Creatine Kinase and Adenylate Kinase (M-CK/AK1) Double Knock-out Mice*

Previously we demonstrated that efficient coupling between cellular sites of ATP production and ATP utilization, required for optimal muscle performance, is mainly mediated by the combined activities of creatine kinase (CK)- and adenylate kinase (AK)-catalyzed phosphotransfer reactions. Herein, we show that simultaneous disruption of the genes for the cytosolic M-CK- and AK1 isoenzymes compromises intracellular energetic communication and severely reduces the cellular capability to maintain total ATP turnover under muscle functional load. M-CK/AK1 (MAK=/=) mutant skeletal muscle displayed aberrant ATP/ADP, ADP/AMP and ATP/GTP ratios, reduced intracellular phosphotransfer communication, and increased ATP supply capacity as assessed by 18O labeling of [Pi] and [ATP]. An analysis of actomyosin complexes in vitro demonstrated that one of the consequences of M-CK and AK1 deficiency is hampered phosphoryl delivery to the actomyosin ATPase, resulting in a loss of contractile performance. These results suggest that MAK=/= muscles are energetically less efficient than wild-type muscles, but an apparent compensatory redistribution of high-energy phosphoryl flux through glycolytic and guanylate phosphotransfer pathways limited the overall energetic deficit. Thus, this study suggests a coordinated network of complementary enzymatic pathways that serve in the maintenance of energetic homeostasis and physiological efficiency.

[1]  H. Eppenberger,et al.  In situ compartmentation of creatine kinase in intact sarcomeric muscle: The acto-myosin overlap zone as a molecular sieve , 1992, Journal of Muscle Research & Cell Motility.

[2]  H. Eppenberger,et al.  Isoenzyme-specific localization of M-line bound creatine kinase in myogenic cells , 1983, Journal of Muscle Research & Cell Motility.

[3]  Jan W. P. Kuiper,et al.  Two structurally distinct and spatially compartmentalized adenylate kinases are expressed from the AK1 gene in mouse brain , 2004, Molecular and Cellular Biochemistry.

[4]  T. Hornemann,et al.  Coupling of creatine kinase to glycolytic enzymes at the sarcomeric I-band of skeletal muscle: a biochemical study in situ , 2004, Journal of Muscle Research & Cell Motility.

[5]  D. Pette,et al.  Immunofluorescent localization of glycogenolytic and glycolytic enzyme proteins and of malate dehydrogenase isozymes in cross-striated skeletal muscle and heart of the rabbit , 2004, Histochemistry.

[6]  A. Terzic,et al.  Adenylate Kinase 1 Deficiency Induces Molecular and Structural Adaptations to Support Muscle Energy Metabolism* , 2003, The Journal of Biological Chemistry.

[7]  A. Terzic,et al.  Energetic communication between mitochondria and nucleus directed by catalyzed phosphotransfer , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[8]  Andre Terzic,et al.  Coupling of Cell Energetics with Membrane Metabolic Sensing , 2002, The Journal of Biological Chemistry.

[9]  R. Bassel-Duby,et al.  Regulation of Mitochondrial Biogenesis in Skeletal Muscle by CaMK , 2002, Science.

[10]  A. Koretsky,et al.  Transgenic livers expressing mitochondrial and cytosolic CK: mitochondrial CK modulates free ADP levels. , 2002, American journal of physiology. Cell physiology.

[11]  A. Terzic,et al.  Cellular Energetics in the Preconditioned State , 2001, The Journal of Biological Chemistry.

[12]  M. Black,et al.  The mouse guanylate kinase double mutant E72Q/D103N is a functional adenylate kinase. , 2001, Protein engineering.

[13]  B. Smeets,et al.  Changes in mRNA expression profile underlie phenotypic adaptations in creatine kinase‐deficient muscles , 2001, FEBS letters.

[14]  Gregory J. Crowther,et al.  Limits to sustainable muscle performance: interaction between glycolysis and oxidative phosphorylation. , 2001, The Journal of experimental biology.

[15]  A. de Groof,et al.  Changes in glycolytic network and mitochondrial design in creatine kinase–deficient muscles , 2001, Muscle & nerve.

[16]  Ave Minajeva,et al.  Energetic Crosstalk Between Organelles: Architectural Integration of Energy Production and Utilization , 2001, Circulation research.

[17]  G. Vrbóva,et al.  Deficiency in parvalbumin increases fatigue resistance in fast-twitch muscle and upregulates mitochondria. , 2001, American journal of physiology. Cell physiology.

[18]  A. Terzic,et al.  Adenylate kinase phosphotransfer communicates cellular energetic signals to ATP-sensitive potassium channels , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[19]  Edwin Janssen,et al.  Compromised Energetics in the Adenylate Kinase AK1Gene Knockout Heart under Metabolic Stress* , 2000, The Journal of Biological Chemistry.

[20]  Arend Heerschap,et al.  Adenylate kinase 1 gene deletion disrupts muscle energetic economy despite metabolic rearrangement , 2000, The EMBO journal.

[21]  T. Wallimann,et al.  Octamers of Mitochondrial Creatine Kinase Isoenzymes Differ in Stability and Membrane Binding* , 2000, The Journal of Biological Chemistry.

[22]  A. Terzic,et al.  Failing energetics in failing hearts , 2000, Current cardiology reports.

[23]  Katherine A. Sheehan,et al.  Functional coupling between glycolysis and excitation—contraction coupling underlies alternans in cat heart cells , 2000, The Journal of physiology.

[24]  P W Hochachka,et al.  The metabolic implications of intracellular circulation. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[25]  D. Lazarević,et al.  wt p53 dependent expression of a membrane-associated isoform of adenylate kinase , 1999, Oncogene.

[26]  A. Heerschap,et al.  Effects of ischemia on skeletal muscle energy metabolism in mice lacking creatine kinase monitored by in vivo 31P nuclear magnetic resonance spectroscopy , 1999, NMR in biomedicine.

[27]  A. Terzic,et al.  Adenylate kinase-catalyzed phosphotransfer in the myocardium : increased contribution in heart failure. , 1999, Circulation research.

[28]  A. Karlsson,et al.  Identification of a novel human adenylate kinase. cDNA cloning, expression analysis, chromosome localization and characterization of the recombinant protein. , 1999, European journal of biochemistry.

[29]  T. Yoneda,et al.  Identification of a novel adenylate kinase system in the brain: cloning of the fourth adenylate kinase. , 1998, Brain research. Molecular brain research.

[30]  A. Terzic,et al.  Phosphotransfer reactions in the regulation of ATP‐sensitive K+ channels , 1998, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[31]  A. Koretsky,et al.  Absence of myofibrillar creatine kinase and diaphragm isometric function during repetitive activation. , 1998, Journal of applied physiology.

[32]  Arend Heerschap,et al.  Altered Ca2+ Responses in Muscles with Combined Mitochondrial and Cytosolic Creatine Kinase Deficiencies , 1997, Cell.

[33]  D. Pette,et al.  Enhanced catalytic activity of hexokinase by work‐induced mitochondrial binding in fast‐twitch muscle of rat , 1997, FEBS letters.

[34]  A. Terzic,et al.  Reversal of the ATP-liganded State of ATP-sensitive K+ Channels by Adenylate Kinase Activity* , 1996, The Journal of Biological Chemistry.

[35]  W. Welte,et al.  Complexes between kinases, mitochondrial porin and adenylate translocator in rat brain resemble the permeability transition pore , 1996, FEBS letters.

[36]  T. Wallimann,et al.  Differential effects of creatine depletion on the regulation of enzyme activities and on creatine-stimulated mitochondrial respiration in skeletal muscle, heart, and brain. , 1996, Biochimica et biophysica acta.

[37]  M. Inouye,et al.  Adenylate kinase complements nucleoside diphosphate kinase deficiency in nucleotide metabolism. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[38]  P. Dzeja,et al.  Suppression of Creatine Kinase-catalyzed Phosphotransfer Results in Increased Phosphoryl Transfer by Adenylate Kinase in Intact Skeletal Muscle* , 1996, The Journal of Biological Chemistry.

[39]  C. Reggiani,et al.  Molecular diversity of myofibrillar proteins: gene regulation and functional significance. , 1996, Physiological reviews.

[40]  P. Korge,et al.  Factors Limiting Adenosine Triphosphatase Function During High Intensity Exercise , 1995, Sports medicine.

[41]  Philippe Mateo,et al.  Muscle Creatine Kinase-deficient Mice , 1995, The Journal of Biological Chemistry.

[42]  P. Dzeja,et al.  Adenylate Kinase-catalyzed Phosphoryl Transfer Couples ATP Utilization with Its Generation by Glycolysis in Intact Muscle (*) , 1995, The Journal of Biological Chemistry.

[43]  D. Brdiczka Function of the outer mitochondrial compartment in regulation of energy metabolism. , 1994, Biochimica et biophysica acta.

[44]  Arend Heerschap,et al.  Skeletal muscles of mice deficient in muscle creatine kinase lack burst activity , 1993, Cell.

[45]  M. Yamada,et al.  Tissue-specific and developmentally regulated expression of the genes encoding adenylate kinase isozymes. , 1993, Journal of biochemistry.

[46]  C. Mathews,et al.  Nucleoside diphosphokinase: a functional link between intermediary metabolism and nucleic acid synthesis. , 1992, Current topics in cellular regulation.

[47]  M. Wyss,et al.  Intracellular compartmentation, structure and function of creatine kinase isoenzymes in tissues with high and fluctuating energy demands: the 'phosphocreatine circuit' for cellular energy homeostasis. , 1992, The Biochemical journal.

[48]  N D Goldberg,et al.  Kinetics and compartmentation of energy metabolism in intact skeletal muscle determined from 18O labeling of metabolite phosphoryls. , 1991, The Journal of biological chemistry.

[49]  H. Eppenberger,et al.  Muscle-type MM creatine kinase is specifically bound to sarcoplasmic reticulum and can support Ca2+ uptake and regulate local ATP/ADP ratios. , 1990, The Journal of biological chemistry.

[50]  S. Dawis,et al.  Evidence for compartmentalized adenylate kinase catalysis serving a high energy phosphoryl transfer function in rat skeletal muscle. , 1990, The Journal of biological chemistry.

[51]  A. From,et al.  ATP synthesis kinetics and mitochondrial function in the postischemic myocardium as studied by 31P NMR. , 1988, The Journal of biological chemistry.

[52]  S. Bessman,et al.  Myokinase and contractile function of glycerinated muscle fibers. , 1986, Biochemical medicine and metabolic biology.

[53]  S. Bessman,et al.  The creatine-creatine phosphate energy shuttle. , 1985, Annual review of biochemistry.

[54]  D. E. Atkinson Cellular Energy Metabolism and its Regulation , 1977 .

[55]  J. Ottaway,et al.  The role of compartmentation in the control of glycolysis. , 1977, Current topics in cellular regulation.

[56]  R. Lewis,et al.  Biochemical and morphological correlates of cardiac ischaemia: Contractile proteins. , 1976, Cardiovascular research.

[57]  C. Honig,et al.  Depression of myosin B by catecholamine analogs: mechanism and in vivo significance. , 1968, The American journal of physiology.