The metabolic implications of intracellular circulation.

Two views currently dominate research into cell function and regulation. Model I assumes that cell behavior is quite similar to that expected for a watery bag of enzymes and ligands. Model II assumes that three-dimensional order and structure constrain and determine metabolite behavior. A major problem in cell metabolism is determining why essentially all metabolite concentrations are remarkably stable (are homeostatic) over large changes in pathway fluxes-for convenience, this is termed the [s] stability paradox. For muscle cells, ATP and O(2) are the most perfectly homeostatic, even though O(2) delivery and metabolic rate correlate in a 1:1 fashion. In total, more than 60 metabolites are known to be remarkably homeostatic in differing metabolic states. Several explanations of [s] stability are usually given by traditional model I studies-none of which apply to all enzymes in a pathway, and all of which require diffusion as the means for changing enzyme-substrate encounter rates. In contrast, recent developments in our understanding of intracellular myosin, kinesin, and dyenin motors running on actin and tubulin tracks or cables supply a mechanistic basis for regulated intracellular circulation systems with cytoplasmic streaming rates varying over an approximately 80-fold range (from 1 to >80 micrometer x sec(-1)). These new studies raise a model II hypothesis of intracellular perfusion or convection as a primary means for bringing enzymes and substrates together under variable metabolic conditions. In this view, change in intracellular perfusion rates cause change in enzyme-substrate encounter rates and thus change in pathway fluxes with no requirement for large simultaneous changes in substrate concentrations. The ease with which this hypothesis explains the [s] stability paradox is one of its most compelling features.

[1]  Raul K. Suarez,et al.  Integrating metabolic pathway fluxes with gene-to-enzyme expression rates , 1998 .

[2]  G. Dobson,et al.  Role of glycolysis in adenylate depletion and repletion during work and recovery in teleost white muscle. , 1987, The Journal of experimental biology.

[3]  G. Betts,et al.  The rationalization of high enzyme concentration in metabolic pathways such as glycolysis. , 1991, Journal of theoretical biology.

[4]  A. Cornish-Bowden,et al.  Control of Metabolic Processes , 1990, NATO ASI Series.

[5]  P. W. Hochachka,et al.  Role of O2 in regulating tissue respiration in dog muscle working in situ. , 1992, Journal of applied physiology.

[6]  Staples,et al.  Honeybee flight muscle phosphoglucose isomerase: matching enzyme capacities to flux requirements at a near-equilibrium reaction , 1997, The Journal of experimental biology.

[7]  B. Wittenberg,et al.  1H nuclear magnetic resonance studies of sarcoplasmic oxygenation in the red cell-perfused rat heart. , 1995, Biophysical journal.

[8]  P. Arthur,et al.  Effect of gradual reduction in O2 delivery on intracellular homeostasis in contracting skeletal muscle. , 1996, Journal of applied physiology.

[9]  L. Pagliaro,et al.  Metabolic compartmentation in living cells: structural association of aldolase. , 1997, Experimental cell research.

[10]  J. F. Staples,et al.  Relationships between enzymatic flux capacities and metabolic flux rates: nonequilibrium reactions in muscle glycolysis. , 1997, Proceedings of the National Academy of Sciences of the United States of America.

[11]  J. Leigh,et al.  Myoglobin O2 desaturation during exercise. Evidence of limited O2 transport. , 1995, The Journal of clinical investigation.

[12]  J. R. Abney,et al.  Dynamics, structure, and function are coupled in the mitochondrial matrix. , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[13]  D N Wheatley,et al.  What determines the basal metabolic rate of vertebrate cells in vivo? , 1994, Bio Systems.

[14]  P. Vollenweider,et al.  Evidence for an insulin receptor substrate 1 independent insulin signaling pathway that mediates insulin-responsive glucose transporter (GLUT4) translocation. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[15]  R. Richardson,et al.  Human muscle performance and PCr hydrolysis with varied inspired oxygen fractions: a 31P-MRS study. , 1999, Journal of applied physiology.

[16]  T. Hornemann,et al.  Some new aspects of creatine kinase (CK): compartmentation, structure, function and regulation for cellular and mitochondrial bioenergetics and physiology , 1998, BioFactors.

[17]  F. Young Biochemistry , 1955, The Indian Medical Gazette.

[18]  H. Wieczorek,et al.  Animal plasma membrane energization by chemiosmotic H+ V-ATPases. , 1997, The Journal of experimental biology.

[19]  K. Schmidt-Nielsen,et al.  Scaling, why is animal size so important? , 1984 .

[20]  Peter W. Hochachka,et al.  Metabolic Arrest and the Control of Biological Time , 1987 .

[21]  I. Boldogh,et al.  Interaction between Mitochondria and the Actin Cytoskeleton in Budding Yeast Requires Two Integral Mitochondrial Outer Membrane Proteins, Mmm1p and Mdm10p , 1998, The Journal of cell biology.

[22]  H. P. Kao,et al.  Determinants of the translational mobility of a small solute in cell cytoplasm , 1993, The Journal of cell biology.

[23]  C. Honig,et al.  O2 transport and its interaction with metabolism; a systems view of aerobic capacity. , 1992, Medicine and science in sports and exercise.

[24]  G. Dobson,et al.  On the role of actomyosin ATPases in regulation of ATP turnover rates during intense exercise. , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[25]  C. R. Taylor,et al.  Design of the oxygen and substrate pathways. I. Model and strategy to test symmorphosis in a network structure. , 1996, The Journal of experimental biology.

[26]  H. Sugi,et al.  The force-velocity relationship of the ATP-dependent actin-myosin sliding causing cytoplasmic streaming in algal cells, studied using a centrifuge microscope. , 1995, The Journal of experimental biology.

[27]  G. Langford Actin- and microtubule-dependent organelle motors: interrelationships between the two motility systems. , 1995, Current opinion in cell biology.

[28]  P. W. Hochachka Oxygen—A Key Regulatory Metabolite in Metabolic Defense Against Hypoxia , 1997 .

[29]  E. Newsholme,et al.  Changes in the contents of adenine nucleotides and intermediates of glycolysis and the citric acid cycle in flight muscle of the locust upon flight and their relationship to the control of the cycle. , 1979, The Biochemical journal.

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

[31]  J. Mccormack,et al.  The role of mitochondrial Ca2+ transport and matrix Ca2+ in signal transduction in mammalian tissues. , 1990, Biochimica et biophysica acta.

[32]  K. Sekizawa,et al.  Cytoplasmic motility reflects phagocytic activity in alveolar macrophages from dog lungs. , 1995, Respiration physiology.

[33]  V. Mermall,et al.  Unconventional myosins in cell movement, membrane traffic, and signal transduction. , 1998, Science.

[34]  J. Lighton,et al.  Energy metabolism, enzymatic flux capacities, and metabolic flux rates in flying honeybees. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[35]  G. Gros,et al.  Diffusivity of myoglobin in intact skeletal muscle cells. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[36]  U. Flögel,et al.  Disruption of myoglobin in mice induces multiple compensatory mechanisms. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[37]  M. Krendel,et al.  Disassembly of actin filaments leads to increased rate and frequency of mitochondrial movement along microtubules. , 1998, Cell motility and the cytoskeleton.

[38]  Ravi S. Menon,et al.  31P magnetic resonance spectroscopy of the Sherpa heart: a phosphocreatine/adenosine triphosphate signature of metabolic defense against hypobaric hypoxia. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[39]  H. Kawaguchi,et al.  Activation of human neutrophils by Arg-Gly-Asp-Ser immobilized on microspheres. , 1994, Journal of biomedical materials research.

[40]  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.

[41]  C. R. Taylor,et al.  The concept of symmorphosis: a testable hypothesis of structure-function relationship. , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[42]  P. W. Hochachka,et al.  Modeling the effects of hypoxia on ATP turnover in exercising muscle. , 1992, Journal of applied physiology.

[43]  N. Slepecky,et al.  Flight muscle function in Drosophila requires colocalization of glycolytic enzymes. , 1997, Molecular biology of the cell.

[44]  D N Wheatley,et al.  Diffusion theory, the cell and the synapse. , 1998, Bio Systems.

[45]  P W Hochachka,et al.  Cellular metabolic homeostasis during large-scale change in ATP turnover rates in muscles. , 1997, The Journal of experimental biology.

[46]  D. Fell,et al.  Control of glucose utilization in working perfused rat heart. , 1994, The Journal of biological chemistry.

[47]  N. A. Walker,et al.  The regulation of ammonia uptake in Chara australis , 1994 .

[48]  U. Kreutzer,et al.  Myoglobin and hemoglobin rotational diffusion in the cell. , 1997, Biophysical journal.

[49]  D E Koshland,et al.  The Era of Pathway Quantification , 1998, Science.

[50]  D. Fell,et al.  A control analysis exploration of the role of ATP utilisation in glycolytic-flux control and glycolytic-metabolite-concentration regulation. , 1998, European journal of biochemistry.

[51]  P. Hollenbeck The pattern and mechanism of mitochondrial transport in axons. , 1996, Frontiers in bioscience : a journal and virtual library.

[52]  C. Hanstock,et al.  Residual dipolar coupling of the Cr/PCr methyl resonance in resting human medial gastrocnemius muscle , 1999, Magnetic resonance in medicine.

[53]  Andrew Huxley,et al.  How molecular motors work in muscle , 1998, Nature.

[54]  Peter W. Hochachka,et al.  Muscles as Molecular and Metabolic Machines , 1994 .