Synthesis and accumulation of an extremely stable high-energy phosphate compound by muscle, heart, and brain of animals fed the creatine analog, 1-carboxyethyl-2-iminoimidazolidine (homocyclocreatine)

A new creatine analog, 1-carboxyethyl-2-iminoimidazolidine (homocyclocreatine), has been synthesized and compared with other synthetic analogs of creatine as a substrate for creatine kinase under both in vitro and in vivo conditions. Reactivity with rabbit muscle creatine kinase at 2 mM and pH 7.0 occurred in the order: creatine greater than cyclocreatine (1-carboxymethyl-2-iminoimidazolidine) greater than N-ethylguanidinoacetate greater than N-propylguanidinoacetate greater than guanidinoacetate greater than N-methyl-3-guanidinopropionate greater than 3-guanidinopropionate greater than homocyclocreatine. Homocyclocreatine was 10,000-fold less active than creatine. In the reverse direction at 0.2 mM and pH 7.0: creatine-P greater than N-ethylguanidinoacetate-P greater than cyclocreatine-P much greater than homocyclocreatine-P. Homocyclocreatine-P was 200,000-fold less active than creatine-P. The phosphoryl group transfer potential of homocyclocreatine-P was estimated to be 2 kcal/mol lower than that of creatine-P. Chicks fed 5% homocyclocreatine for 16 days synthesized and accumulated homocyclocreatine-P in breast muscle (32 mumol/g wet wt), leg muscle (24 mumol/g), heart (7 mumol/g), intestine (8.5 mumol/g), and brain (2.4 mumol/g). During ischemia homocyclocreatine-P was utilized by muscle much more slowly for the regeneration of ATP than was creatine-P or cyclocreatine-P. Our results suggest that in tissues of homocyclocreatine-fed animals subjected to a sudden large increase in work load or to ischemia, the residual creatine-P system would rapidly equilibrate with the adenylate system at the new lower cytosolic phosphorylation potential, whereas in the same cytosol the (homocyclocreatine-P)/(homocyclocreatine) ratio would exhibit a hysteresis or memory effect and reflect for a considerable period of time the earlier higher (ATP)/(free ADP) ratio rather than the actual lower (ATP)/(free ADP) ratio.     

Enhanced ability of skeletal muscle containing cyclocreatine phosphate to sustain ATP levels during ischemia following beta-adrenergic stimulation

Breast muscle of young chicks fed chow diets containing the creatine analog 1-carboxymethyl-2-iminoimidazolidine (cyclocreatine) accumulated up to 40 mumol/g wet weight of the synthetic phosphagen 1-carboxymethyl-2-imino-3-phosphonoimidazolidine (cyclocreatine-P2-). ATP levels were sustained at high values substantially longer in breast muscle of cyclocreatine-fed chicks, compared to control-fed chicks, during total ischemia initiated 2 h after injection of both groups with the beta-adrenergic agonist isoproterenol (5 mg/kg subcutaneous). For example, in chicks fed 0.5% cyclocreatine for 10-19 days ATP levels in isoproterenol-stimulated breast muscles after 1 h of ischemia at 37 degrees C were 6.1 mumol/g, compared to 1.9 mumol/g for the control-fed group, and after 2 h of ischemia were 3.5 mumol/g compared to 0.6 mumol/g for controls. Creatine-P reserves in isoproterenol-stimulated breast muscles of all dietary groups were essentially exhausted within the first hour of ischemia. In contrast, breast muscle of chicks fed either 1 or 0.5% cyclocreatine still contained 28 and 19 mumol/g of cyclocreatine-P, respectively, after 1 h of ischemia; after 2 h of ischemia, the respective cyclocreatine-P values were 20 and 13 mumol/g. Isoproterenol-stimulated chick breast muscle provides the first skeletal muscle model system for studying the molecular mechanisms by which dietary cyclocreatine helps sustain ATP levels during ischemia. Although adaptive factors are also involved, it is suggested that a significant portion of the ATP-sustaining activity of dietary cyclocreatine in ischemic breast muscle can be attributed to the unique thermodynamic properties of the accumulated cyclocreatine-P. These properties enable cyclocreatine-P to continue to thermodynamically buffer the adenylate system and transport high energy phosphate throughout the long muscle fibers at cytosolic pH values and phosphorylation potentials well below the range where the creatine-P system can function effectively. Synergism between glycolysis and this long-acting synthetic phosphagen might well help delay depletion of ATP levels in skeletal muscles during ischemia. Cyclocreatine feeding provides a unique experimental tool for quantitative evaluation of the proposed protective role of ATP against irreversible cellular damage in skeletal and cardiac muscles during ischemic episodes.     

Higher homolog and N-ethyl analog of creatine as synthetic phosphagen precursors in brain, heart, and muscle, repressors of liver amidinotransferase, and substrates for creatine catabolic enzymes

Tissues of chicks fed 5% N-methyl-3-guanidinopropionate (N-amidino-N-methyl-beta-alanine) for 12 days accumulated the following amounts of free plus phosphorylated derivatives as mumol/g, wet weight: brain, 5.5; heart, 7.3; leg muscle, 21.0; and breast muscle, 24.4. Since total creatine levels remained nearly the same in brain, N-methyl-3-guanidinopropionate-P provided brain with a supplemental reservoir of high energy phosphate. Tissues of rats fed 2% N-ethylguanidinoacetate (N-amidino-N-ethylglycine) accumulated large amounts of N-ethylguanidinoacetate-P, which has thermodynamic properties similar to creatine-P and is the kinetically most reactive synthetic phosphagen yet described. N-Ethylguanidinoacetate derivatives replaced creatine derivatives mole-for-mole, and the fraction of synthetic to total phosphagen after 19 days was 60% in heart, 54% in slow oxidative muscle, 42% in fast glycolytic muscles, and 22% in brain. N-Ethylguanidinoacetate served as a false end product co-repressor of liver arginine:glycine amidinotransferase levels in both chicks and chick embryos; N-methyl-3-guanidinopropionate and N-propylguanidinoacetate were relatively inactive. Creatinine amidohydrolase reversibly cyclized both N-ethylguanidinoacetate and N-propylguanidinoacetate with even lower Km values than for creatine derivatives, but it did not react significantly with N-methyl-3-guanidinopropionate, 3-guanidinopropionate, or 1-carboxy-methyl-2-imino-imidazolidine (cyclocreatine). Creatine amidinohydrolase also hydrolyzed N-acetimidoylsarcosine, but was relatively unreactive toward N-ethylguanidinoacetate, N-methyl-3-guanidinopropionate, 3-guanidinopropionate, and cyclocreatine. Amidinohydrolase can therefore be used to remove interfering creatine in assays of tissues for coexisting N-ethylguanidinoacetate or N-methyl-3-guanidinopropionate. Assays are now available to follow changes during metabolic stresses of any combination or all of the following phosphagens accumulated by the same tissue: creatine-P, N-ethylguanidinoacetate-P, cyclocreatine-P, N-methyl-3-guanidinopropionate-P, and homocyclocreatine-P.     

Utilization of Cyclocreatine Phosphate, an Analogue of Creatine Phosphate, by Mouse Brain During Ischemia and Its Sparing Action on Brain Energy Reserves

Abstract: Brains of mice fed the creatine analogue cyclocreatine accumulated 10 γmol/g fresh wt. of cyclocreatine, of which 93% occurred as the synthetic phosphagen, cyclocreatine-P (l-carboxymethyl-2-imino-3-phosphonoimidazolidine). In brains containing cyclocreatine-P^2-, creatine-P (phosphocreatine) levels were lowered 40%; levels of ATP, P₁, and glucose were not altered: glutamate levels were lowered 17%: and aspartate levels were lowered 56%, relative to controls. When cyclocreatine was removed from the diet, brain cyclocreatine levels decreased with a half-life of 17 to 28 days. Ischemia was initiated in brains by decapitation of mice previously injected with the centrally acting muscle relaxant mephenesin. The initial creatine-P pool of 2-3 γmol/g was completely depleted within 1 min in ischemic brains of both control and cyclocreatine-fed mice. In brains of cyclocreatine-fed mice, the much larger cyclocreatine-P pool of 9.3 γmol/g decreased to 6 γmol/g after 2 min and to 2.2 γrnol/g after 4 min of ischemia, with a correspondingly increased accumulation of P₁. Levels of total cellular ATP were sustained slightly longer during ischemia in brains containing cyclocreatine-P. Available energy reserves of control brains were almost completely depleted after 2 min of ischemia, whereas generation and utilization of high-energy phosphate continued for more than 3 min after initiation of ischemia in brains of cyclocreatine-fed mice. These data suggest that during ischemic episodes cyclocreatine-P can function as a supplemental reservoir of high-energy phosphate and prolong the time required to exhaust the available energy stores of ischemic brain.     

Postmortem metabolism of short-finned squid muscle (Illex illecebrosus)

Postmortem biochemical changes were examined in the mantle muscle of the short-finned squid (Illex illecebrosus) in relation to the physical events associated with rigor. Unlike mammalian muscle, the major muscle phosphagen is arginine phosphate rather than creatine phosphate. Arginine phosphate levels did not change dramatically during the progress of rigor development. ATP depletion was found to be closely related to glycogen depletion as is often observed in mammalian muscle. The postmortem accumulation of octopine was related to the initial muscle glycogen content at death but a significant lag in its production was observed. The postmortem conversion of glucose to glucose-6-phosphate appeared to be the rate-limiting step in the overall conversion of glycogen to octopine. The intermediates found in the postmortem catabolism of squid muscle ATP were ADP, AMP, IMP Ino and Hx. Unlike most vertebrate fishes, AMP was found to accumulate in squid before conversion to IMP whereas accumulations of IMP and Ino were less than those normally found in vertebrate muscle.     

NMR-invisible ATP in rat heart and its change in ischemia

The subcellular compartmentalization of adenosine 5'-triphosphate (ATP) in isolated perfused rat heart and its relation to energy depletion in ischemia were examined by 31P nuclear magnetic resonance (31P-NMR) spectroscopy and chemical analyses. The signal intensities of the beta-phosphate of ATP and creatine phosphate in the 31P-NMR were standardized by the intracellular volume ratio measured with 23Na-NMR to determine the actual content of each. During aerobic perfusion the ATP content determined by NMR (13.7 +/- 2.2 mumol/g dry weight) was significantly lower than that found by chemical analysis (22.4 +/- 0.7 mumol/g dry weight), while the creatine phosphate contents determined by the two methods were the same. During ischemia at 33 degrees C, the signal of the beta-phosphate of ATP in the 31P-NMR spectrum decreased progressively, disappearing completely after 16 min. But at this time 5.7 +/- 1.7 mumol/g dry weight of myocardial ATP was still detected by chemical analysis. These results indicated that there were two different compartments of intracellular ATP in the heart, only one of which is detectable by 31P-NMR spectroscopy, and that during ischemia the ATP that is detectable, which seems to be the free ATP in the cytosol, decreased more rapidly than the ATP in the other compartment.     

Adenine nucleotides and the adenylate kinase equilibrium in livers of foetal and newborn rats

1. Measurements of ATP, ADP and AMP concentrations in livers of rats that had been delivered by Caesarian section indicate a rapid shift from a low to a high [ATP]/[AMP] ratio. This change is consistent with the cessation of glycolysis and the initiation of gluconeogenesis at birth. 2. When newborn animals are exposed to a 100% nitrogen atmosphere the hepatic ATP concentration falls and AMP increases. 3. Calculations of the [ATP][AMP]/[ADP](2) ratio give values that are close to the equilibrium constant of adenylate kinase except when the ATP concentration is high. 4. This difference cannot be accounted for by the preferential binding of available Mg(2+) to ATP(4-) rather than ADP(3-). It is concluded that the relative proportions of adenine nucleotides at any level of phosphorylation are only partly regulated by adenylate kinase.     

Energy metabolism and contractile function of the heart in diabetic cardiomyopathy: effect of ischemia and reperfusion]

Physiological parameters, rates of mitochondrial respiration, high energy phosphate levels and creatine phosphokinase (CPK) activity were investigated in the hearts from control and alloxan-induced diabetic rabbits before and after 40-min total ischemia and reperfusion. Diabetic hearts demonstrated significant decreases in the rates of contraction (+dP/dt) and relaxation (-dP/dt), heart rates and cardiac work compared to control hearts. Determination of mitochondrial respiration rates in saponin-skinned fibers showed a low mitochondrial respiratory function in diabetic hearts. It was found that the ATP and ADP levels and the total and mitochondrial isoenzyme activities of CPK in diabetic hearts were lowered in comparison with control. A post-ischemic recovery of cardiac performance for diabetic hearts was better than in controls. After reperfusion diabetic hearts had increased ATP levels. The data obtained demonstrate some abnormalities of both cardiac performance and energy metabolism in the hearts of diabetic animals and a decreased sensitivity of the latter to ischemic injury.     

Glucose requirement for postischemic recovery of perfused working heart

The quantitative importance of glycolysis in cardiomyocyte reenergization and contractile recovery was examined in postischemic, preload-controlled, isolated working guinea pig hearts. A 25-min global but low-flow ischemia with concurrent norepinephrine infusion to exhaust cellular glycogen stores was followed by a 15-min reperfusion. With 5 mM pyruvate as sole reperfusion substrate, severe contractile failure developed despite normal sarcolemmal pyruvate transport rate and high intracellular pyruvate concentrations near 2 mM. Reperfusion dysfunction was characterized by a low cytosolic phosphorylation potential [( ATP]/[( ADP][Pi]) due to accumulations of inorganic phosphate (Pi) and lactate. In contrast, with 5 mM glucose plus pyruvate as substrates, but not with glucose as sole substrate, reperfusion phosphorylation potential and function recovered to near normal. During the critical ischemia-reperfusion transition at 30 s reperfusion the cytosolic creatine kinase appeared displaced from equilibrium, regardless of the substrate supply. When under these conditions glucose and pyruvate were coinfused, glycolytic flux was near maximum, the glyceraldehyde-3-phosphate dehydrogenase/3-phosphoglycerate kinase reaction was enhanced, accumulation of Pi was attenuated, ATP content was slightly increased, and adenosine release was low. Thus, glucose prevented deterioration of the phosphorylation potential to levels incompatible with reperfusion recovery. Immediate energetic support due to maximum glycolytic ATP production and enhancement of the glyceraldehyde-3-phosphate dehydrogenase/3-phosphoglycerate kinase reaction appeared to act in concert to prevent detrimental collapse of [ATP]/[( ADP][Pi]) during creatine kinase dysfunction in the ischemia-reperfusion transition. Dichloroacetate (2 mM) plus glucose stimulated glycolysis but failed fully to reenergize the reperfused heart; conversely, 10 mM 2-deoxyglucose plus pyruvate inhibited glycolysis and produced virtually instantaneous de-energization during reperfusion. The following conclusions were reached. (1) A functional glycolysis is required to prevent energetic and contractile collapse of the low-flow ischemic or reperfused heart (2). Glucose stabilization of energetics in pyruvate-perfused hearts is due in part to intensification of glyceraldehyde-3-phosphate dehydrogenase/3-phosphoglycerate kinase activity. (3) 2-Deoxyglucose depletes the glyceraldehyde-3-phosphate pool and effects intracellular phosphate fixation in the form of 2-deoxyglucose 6-phosphate, but the cytosolic phosphorylation potential is not increased and reperfusion failure occurs instantly. (4) Consistent correlations exist between cytosolic ATP phosphorylation potential and reperfusion contractile function. The findings depict glycolysis as a highly adaptive emergency mechanism which can prevent deleterious myocyte deenergization during forced ischemia-reperfusion transitions in presence of excess oxidative substrate.     

FORMATION OF A SUPPLEMENTAL LONG TIME-CONSTANT RESERVOIR OF HIGH ENERGY PHOSPHATE BY BRAIN IN VIVO AND IN VITRO AND ITS REVERSIBLE DEPLETION BY POTASSIUM DEPOLARIZATION

—Brains of mice fed a diet containing 1% cyclocreatine (1-carboxymethyl-2-iminoimidazolidine) accumulated the high energy phosphate compound cyclocreatine-P (1-carboxymethyl-2-imino-3-phosphonoimidazolidine), an analogue of creatine-P (phosphocreatine). During a 50-day feeding period mouse brain cyclocreatine-P increased linearly to 14 μmol/g fresh wt; during this time the total phosphagen level of brain, creatine-P plus cyclocreatine-P, increased from 3 to 15 μmol/g. When the blood-brain barrier was circumvented, a more rapid accumulation of synthetic phosphagen was achieved. Minced brain preparations from 11 to 15-day chick embryos incubated in vitro with 30 mm -cyclocreatine accumulated 10 μmol/g of cyclocreatine-P in 90 min, and this novel high energy phosphate pool could be depleted by incubation with 105 mm -potassium ions or 3 μm -valinomycin. Subsequent regeneration of the depleted pools could also be demonstrated. Brain tissue containing a supplemental reservoir of cyclocreatine-P, which is utilized to regenerate ATP much more slowly than creatine-P, might be better able to withstand anoxia and certain other metabolic stresses, but this has not been established. However, the marked delay of onset of rigor previously shown to occur in ischemic heart and skeletal muscle of cyclocreatine-fed animals is compatible with this suggestion.     

Pyruvate-enhanced phosphorylation potential and inotropism in normoxic and postischemic isolated working heart. Near-complete prevention of reperfusion contractile failure

Bioenergetic and hemodynamic consequences of cellular redox manipulations by 0.2-20 mM pyruvate were compared with those due to adrenergic stress (0.7-1.1 microM norepinephrine) using isolated working guinea-pig hearts under the conditions of normoxia, low-flow ischemia, and reperfusion. 5 mM glucose (+ 5 U/l insulin) + 5 mM lactate were the basal energy-yielding substrates. To stabilize left ventricular enddiastolic pressure, ventricular filling pressure was held at 12 cmH2O under all conditions; this preload control minimized Frank-Starling effects on ventricular inotropism. Global low-flow ischemia was induced by reducing aortic pressure to levels (20-10 cmH2O) below the coronary autoregulatory reserve. Reactants of the creatine kinase, including H+ and other key metabolites, were measured by enzymatic, HPLC, and polarographic techniques. In normoxic hearts, norepinephrine stimulations of inotropism, heart rate x pressure product, and oxygen consumption (MVO2) were associated with a fall in the cytosolic phosphorylation potential [( ATP]/[( ADP].[Pi]] as judged by the creatine kinase equilibrium. In contrast, infusion of excess pyruvate (5 mM) markedly increased [ATP]/[( ADP].[Pi]) and ventricular work output, while intracellular phosphate decreased; MVO2 remained constant under the same conditions. During reperfusion following ischemia, pyruvate effected striking and concentration-dependent increases in MVO2, phosphorylation potential, and inotropism. Pyruvate dehydrogenase flux was augmented during reperfusion hyperemia followed by near-complete recoveries of [ATP]/([ADP].[Pi]), contractile force, heart rate x pressure product, and MVO2 in the presence of 5-10 mM pyruvate. Pyruvate also attenuated ischemic adenylate degradation. Omission of glucose from the perfusion medium rendered pyruvate ineffective in postischemic hearts. Similarly, excess lactate (5-15 mM) or acetate (5 mM) failed to reenergize reperfused hearts and severe depressions of MVO2 and inotropism developed despite the presence of glucose. Apparently, subcellular redox manipulations by pyruvate dissociated stimulated mitochondrial respiration and increased inotropism from low cytosolic phosphorylation potentials. This was evidence against the extramitochondrial [ADP].[Pi]/[ATP] ratio being the primary factor in the control of mitochondrial respiration. The mechanism of pyruvate enhancement of inotropism during normoxia and reperfusion is probably multifactorial. Thermodynamic effects on subcellular [NADH]/[NAD+] ratios are coupled with a rise in the cytosolic [ATP]/[( ADP].[Pi]) ratio at constant (normoxia) or increased (reperfusion) MVO2.(ABSTRACT TRUNCATED AT 400 WORDS)     

Free ADP levels in transgenic mouse liver expressing creatine kinase. Effects of enzyme activity, phosphagen type, and substrate concentration

ADP is an important regulator of hepatic metabolism. Despite its importance the level of free ADP in the liver remains controversial. Recently, we engineered transgenic mice which express high levels of creatine kinase in liver. The reaction catalyzed by creatine kinase was assumed to be at equilibrium and used to calculate a free ADP level of 0.059 mumol/g wet weight. In this report we test the equilibrium assumption by studying the free ADP level as a function of enzyme activity or substrate content. Over a 5-fold range of creatine kinase activity, from 150-800 mumol/min/g wet weight, there was no change in the free ADP level. The average value of ADP for these mice was 0.061 +/- 0.016 mumol/g wet weight. Similarly, altering hepatic creatine content from 1.6 to 30 mumol/g wet weight had no effect on the calculated total free ADP level. The average value of ADP for the creatine levels was 0.048 +/- 0.015 mumol/g wet weight. Finally, the free ADP level was calculated using the equilibrium with cyclocreatine rather than creatine as substrate. The equilibrium of the reaction with cyclocreatine lies 30 times more toward phosphorylation than does the equilibrium with creatine. A free ADP level of 0.063 +/- 0.031 mumol/g wet weight was calculated using cyclocreatine. This value is not different from that found with creatine. These results show that the equilibrium assumption used to calculate free ADP levels in transgenic mouse liver is valid, and the presence of creatine kinase does not affect ADP levels.     

Relationships Among ATP Synthesis, K+ Gradients, and Neurotransmitter Amino Acid Levels in Isolated Rat Brain Synaptosomes

Correlations were made among ATP synthesis, transmembrane K+ gradients, and leakage of three amino acid neurotransmitters, gamma-aminobutyric acid (GABA), aspartate, and glutamate, in rat brain synaptosomes incubated under normoxic and respiration-limited conditions. Even under normoxic conditions, a substantial proportion of total ATP synthesis (8%) was provided by glycolysis. Limitation of respiration by approximately 30% through addition of amobarbital (Amytal) caused a twofold decrease in the creatine phosphate/creatine ([CrP]/[Cr]) ratio, and consequently the [ATP]/[ADP] ratio, and a threefold increase in lactate production. There was a detectable decrease in intracellular [K+] and small rises in external GABA, aspartate, and glutamate concentrations. More severe limitations in ATP synthesis caused larger declines in the [CrP]/[Cr] ratio and progressive leakage of K+ and neurotransmitter amino acids. A comparison of delta GATP and delta GNa, K showed the former to be larger by 6 kcal, which indicates that the plasma membrane Na+/K+ pump operates at far from equilibrium. Under respiration-limited conditions, even when total ATP synthesis decreased by approximately 80% and [ATP] declined to less than 0.4 mM, delta GATP was still larger than delta GNa,K. It is suggested that during hypoxia and ischemia, the activity of the plasma membrane Na+/K+ pump in brain becomes limited by [ATP], which falls below the Km value for the low-affinity regulatory site on the enzyme. This failure of the pump and consequent collapse of the ion gradients may contribute to the leakage of neurotransmitter amino acids that occurs in these pathological states.     

Regulation of energy flux through the creatine kinase reaction in vitro and in perfused rat heart. 31P-NMR studies

Fluxes catalyzed by soluble creatine kinase (MM) in equilibrium in vitro and by the creatine kinase system in perfused rat hearts were studied by 31P-NMR saturation transfer method. It was found that in vitro both forward and reverse fluxes through creatine kinase at equilibrium were almost equal and very stable to changes in phosphocreatine/creatine ratio (from 0.2 to 3.0) as well as to changes in pH (from 7.4 to 6.5 or 8.1), free Mg2+ concentration and 2-fold decrease of total adenine nucleotides and creatine pools (from 8.0 to 4.0 mM and from 30 to 14 mM, respectively). In the rat hearts perfused by the Langendorff method the creatine kinase-catalyzed flux from phosphocreatine to ATP was increased by 50% when oxygen consumption grew from 8 to 55 mumol/min per g of dry wt. due to transition from rest to high workload. These changes could not be exclusively explained on the basis of the equilibrium model by activation of heart creatine kinase due to some decrease in [phosphocreatine]/[creatine] ratio (from 1.8 to 0.8) observed during transition from rest to high workload. Analysis of our data showed that an increase in the flux via creatine kinase is correlated with an increase in the rate of ATP synthesis with a linearity coefficient higher than 1.0. These data are more consistent with the concept of energy channeling by phosphocreatine shuttle than with that of the creatine kinase equilibrium in the heart.     

Effect of transient focal ischemia of mouse brain on energy state and NAD levels: no evidence that NAD depletion plays a major role in secondary disturbances of energy metabolism

It has been proposed that NAD depletion resulting from excessive activation of poly(ADP-ribose) polymerase is responsible for secondary energy failure after transient cerebral ischemia. However, this hypothesis has never been verified by measurement of ATP and NAD levels in the same tissue sample. In this study, we therefore investigated the effect of transient focal cerebral ischemia on the temporal profiles of changes in the levels of energy metabolites and NAD. Ischemia was induced in mice by occluding the left middle cerebral artery using the intraluminal filament technique. Animals were subjected to 1-h ischemia, followed by 0, 1, 3, 6, or 24 h of reperfusion. During ischemia, ATP levels, total adenylate pool, and adenylate energy charge dropped to approximately 20, 50, and 40% of control, respectively, whereas NAD levels remained close to control. Energy state recovered transiently, peaking at 3 h of recovery (ATP levels and total adenylate pool recovered to 78 and 81% of control). In animals subjected to reperfusion of varying duration, the extent of ATP depletion was clearly more pronounced than that of NAD. The results imply that depletion of NAD pools did not play a major role in secondary disturbances of energy-producing metabolism after transient focal cerebral ischemia. Changes in ATP levels were closely related to changes in total adenylate pool (p<0.001). The high energy charge after 6 h of reperfusion (0.90 versus a control value of 0.93) and the close relationship between the decline of ATP and total adenylate pool suggest that degradation or a washout of adenylates (owing to leaky membranes) rather than a mismatch between energy production and consumption is the main causative factor contributing to the secondary energy failure observed after prolonged recovery.     

Combined glyceraldehyde-3-phosphate dehydrogenase/phosphoglycerate kinase in catecholamine-stimulated guinea-pig cardiac muscle. Comparison with mass-action ratio of creatine kinase.

The steady-state reactant levels of triose-phosphate isomerase and the glyceraldehyde-3-phosphate dehydrogenase/phosphoglycerate kinase system were examined in guinea-pig cardiac muscle. Key glycolytic intermediates, including glyceraldehyde 3-phosphate were directly measured and compared with those of creatine kinase. Non-working Langendorff hearts as well as isolated working hearts were perfused with 5 mM glucose (plus insulin) under normoxia conditions to maintain lactate dehydrogenase near-equilibrium. The cytosolic phosphorylation potential ([ATP]/([ADP].[Pi])) was derived from creatine kinase and the free [NAD+]/([NADH].[H+]) ratio from lactate dehydrogenase. In Langendorff hearts glycolysis was varied from near-zero flux (hyperkalemic cardiac arrest) to higher than normal flux (normal and maximum catecholamine stimulation). The triose-phosphate isomerase was near-equilibrium only in control or potassium-arrested Langendorff hearts as well as in postischemic 'stunned' hearts. However, when glycolytic flux increased due to norepinephrine or due to physiological pressure-volume work the enzyme was displaced from equilibrium. The alternative phosphorylation ratio [ATP]'/([ADP]).[Pi]) was derived from the magnesium-dependent glyceraldehyde-3-phosphate dehydrogenase/phosphoglycerate kinase system assigning free magnesium different values in the physiological range (0.1-2.0 mM). As predicted, [ATP]/([ADP].[Pi]) and [ATP]'/([ADP]'.[Pi]') were in excellent agreement when glycolysis was virtually halted by hyperkalemic arrest (flux approximately 0.2 mumol C3.min-1.g dry mass-1). However, the equality between the two phosphorylation ratios was not abolished upon resumption of spontaneous beating and also not during adrenergic stimulation (flux approximately 5-14 mumol C3.min-1.g dry mass-1). In contrast, when flux increased due to transition from no-work to physiological pressure-volume work (rate increase from approximately 3 to 11 mumol C3.min-1.g dry mass-1), the two ratios were markedly different indicating disequilibrium of the glyceraldehyde-3-phosphate dehydrogenase/phosphoglycerate kinase. Only during adrenergic stimulation or postischemic myocardial 'stunning', not due to hydraulic work load per se, glyceraldehyde-3-phosphate levels increased from about 4 microM to greater than or equal to 16 microM. Thus the guinea-pig cardiac glyceraldehyde-3-phosphate dehydrogenase/phosphoglycerate kinase system can realize the potential for near-equilibrium catalysis at significant flux provided glyceraldehyde-3-phosphate levels rise, e.g., due to 'stunning' or adrenergic hormones.     

Modulation by citrate of glycolytic oscillations in skeletal muscle extracts.

Oscillatory behavior of glycolysis in cell-free extracts of skeletal muscle involves repeated bursts of phosphofructokinase activity and associated oscillations in the [ATP]/[ADP] ratio. Addition of citrate, a potent physiological inhibitor of phosphofructokinase, decreased the frequency of the oscillations and delayed the first burst of phosphofructokinase activity in a dose-dependent manner. Citrate decreased the trigger point [ATP]/[ADP] ratio at which bursts of phosphofructokinase activity were initiated but had a much smaller effect on the average [ATP]/[ADP] ratio and did not decrease the peak values of the ratio. When oscillations were prevented by addition of fructose-2,6-P2, the decrease in the [ATP]/[ADP] ratio caused by citrate in the steady state system was similar to the decrease in the trigger point [ATP]/[ADP] ratio in the oscillatory system. The decrease in the average [ATP]/[ADP] ratio was greater in the steady state system than in the oscillating system. These results demonstrate advantages of oscillatory behavior of glycolysis in the regulation of carbohydrate utilization and the maintenance of a high [ATP]/[ADP] ratio.     

Metabolic recovery in herring larvae following strenuous activity

Larvae of spring spawning Clyde herring Clupea harengus L. were reared at 5 and 12° C. Metabolism following burst swimming was studied in 7-day-old larvae at their respective rearing temperatures. Escape responses were repeatedly elicited using tactile stimulation for a period of 3 min. Larval herring were hard to fatigue and still responded to tactile stimuli after 3 min. Whole larvae were freeze-quenched in liquid nitrogen, either immediately after exercise, or after periods of recovery of up to 24 h. Samples were freeze-dried and analysed for whole body creatine (Cr), phosphocreatine (PCr), ATP, ADP, AMP, lactate, glucose, and glycogen using high performance liquid chromatography and enzymatic methods. The exercise regime resulted in a marked decrease in PCr, ATP and glycogen concentrations and an increase in creatine, glucose and lactate concentrations whereas there was no significant change in either AMP or ADP concentrations. The extent of phosphagen hydrolysis (approx. 110 to 15μmol PCr g ⁻¹ dry body mass) and lactate accumulation (approx. 7 to 40 μmol lactate g⁻¹ dry body mass) over the exercise period was similar at the two temperatures, consistent with a relatively constant degree of effort. The rates of recovery of PCr and ATP were essentially the same at 5 and 12° C; returning to resting levels after approximately 30 min. Lactate and glycogen concentrations were restored 60 min after exercise at both temperatures. Maximum lactate clearance rates (1.2 μmol min ⁻¹ g ⁻¹ wet muscle mass) were an order of magnitude faster than reported for adult fish in the literature.     

Energy relationships between ATP synthesis and K+ gradients in cultured glial-derived cell line

In C6 astrocytoma cells respiring with glucose, 40% of the total production of ATP was provided by glycolysis. Anaerobiosis in the presence of glucose, reduced ATP synthesis by approximately 50%, increased lactate production by 30% and caused a 3-fold decline in [creatine phosphate]/[creatine] and consequently [ATP]free[ADP]free. There was no change in [K+]i which suggests that glycolytic production of ATP provides sufficient energy to ensure normal operation of the Na+/K+ pump. In the absence of glucose, [creatine phosphate]/[creatine] declined to less than 0.1 in 15 min and there was a loss of K+ from cells. A comparison of delta GATP and delta GNa,K under aerobic conditions with and without glucose, showed the former to be larger by 1 - 2 kcal. However, under O2-limited, glucose-restricted conditions delta GATP fell below the level necessary to maintain operation of the Na+/K+ pump and led to a collapse in ionic gradients.     

Ischemia-induced activation of AMPK does not increase glucose uptake in glycogen-replete isolated working rat hearts

Alterations in myocardial glucose metabolism are a key determinant of ischemia-induced depression of left ventricular mechanical function. Since myocardial glycogen is an important source of endogenous glucose, we compared the effects of ischemia on glucose uptake and utilization in isolated working rat hearts in which glycogen content was either replete (G replete, 114 micromol/g dry wt) or partially depleted (G depleted, 71 mumol/g dry wt). The effects of low-flow ischemia (LFI, 0.5 ml/min) on glucose uptake, glycogen turnover (glycogenolysis and glycogen synthesis), glycolysis, adenosine 5'-monophosphate-activated protein kinase (AMPK) activity, and GLUT4 translocation were measured. Relative to preischemic values, LFI caused a time-dependent reduction in glycogen content in both G-replete and G-depleted groups due to an acceleration of glycogenolysis (by 12-fold and 6-fold, respectively). In G-replete hearts, LFI (15 min) decreased glucose uptake (by 59%) and did not affect GLUT4 translocation. In G-depleted hearts, LFI also decreased initially glucose uptake (by 90%) and glycogen synthesis, but after 15 min, when glycogenolysis slowed due to exhaustion of glycogen content, glucose uptake increased (by 31%) in association with an increase in GLUT4 translocation. After 60 min of LFI, glucose uptake, glycogenolysis, and glycolysis recovered to near-preischemic values in both groups. LFI increased AMPK activity in a time-dependent manner in both groups (by 6-fold and 4-fold, respectively). Thus, when glycogen stores are replete before ischemia, ischemia-induced AMPK activation is not sufficient to increase glucose uptake. Under these conditions, an acceleration of glycogen degradation provides sufficient endogenous substrate for glycolysis during ischemia.