THE EFFECT OF PORTA-CAVAL ANASTOMOSIS UPON THE ENERGY STATE AND UPON ACID-BASE PARAMETERS OF THE RAT BRAIN

Abstract— In order to evaluate the influence of porta-caval anastomosis upon the energy state of the brain, lightly anaesthetized rats were studied either 1 or 5 weeks after the shunting procedure and the brains (frontal lobe, cerebellum and brainstem) were analysed for carbohydrate substrates and organic phosphates. The ammonia contents of arterial blood, cerebrospinal fluid (CSF) and tissue increased progressively in the shunted groups and at 5 weeks the increases were three- to six-fold. In all brain structures studied there were decreases in the glucose and in the aspartate contents but regional differences existed for glucose-6-phosphate, α-ketoglutaratc and glutamate. In the brainstem the tissue contents of glucose-6-phosphate and α-ketoglutarate fell while glutamate was unchanged. Calculation of the cytoplasmatic redox state from the lactate dehydrogenase (LDH) and the malate dehydrogenase (MDH) equilibria indicated that the NADH/NAD⁺ ratio increased in the shunted groups. However, since there was no significant fall in the calculated adenylate energy charge, it is concluded that porta-caval anastomosis, and the accompanying hyperammonemia, do not disrupt the balance between production and utilization of energy in the brain.     

ACUTE HYPERCAPNIA AND BRAIN ENERGY STATE IN SUSTAINED HYPERAMMONAEMIA

Abstract— The effect of acute hypercapnia upon the energy state of the brain in sustained hyperammonaemia was evaluated in lightly (N₂O) anaesthetized rats. No significant changes occurred in the high energy phosphates (phosphocreatine, ATP, ADP, and AMP) despite a fourfold increase in the ammonia content and a 50 per cent reduction in the total α-ketoglutarate content. It is concluded that brain tissue maintains energy homeostasis in hypercapnic hyperammonaemia.     

Early alterations of brain cellular energy homeostasis in Huntington disease models

Brain energy deficit has been a suggested cause of Huntington disease (HD), but ATP depletion has not reliably been shown in preclinical models, possibly because of the immediate post-mortem changes in cellular energy metabolism. To examine a potential role of a low energy state in HD, we measured, for the first time in a neurodegenerative model, brain levels of high energy phosphates using microwave fixation, which instantaneously inactivates brain enzymatic activities and preserves in vivo levels of analytes. We studied HD transgenic R6/2 mice at ages 4, 8, and 12 weeks. We found significantly increased creatine and phosphocreatine, present as early as 4 weeks for phosphocreatine, preceding motor system deficits and decreased ATP levels in striatum, hippocampus, and frontal cortex of R6/2 mice. ATP and phosphocreatine concentrations were inversely correlated with the number of CAG repeats. Conversely, in mice injected with 3-nitroproprionic acid, an acute model of brain energy deficit, both ATP and phosphocreatine were significantly reduced. Increased creatine and phosphocreatine in R6/2 mice was associated with decreased guanidinoacetate N-methyltransferase and creatine kinase, both at the protein and RNA levels, and increased phosphorylated AMP-dependent protein kinase (pAMPK) over AMPK ratio. In addition, in 4-month-old knock-in Hdh(Q111/+) mice, the earliest metabolic alterations consisted of increased phosphocreatine in the frontal cortex and increased the pAMPK/AMPK ratio. Altogether, this study provides the first direct evidence of chronic alteration in homeostasis of high energy phosphates in HD models in the earliest stages of the disease, indicating possible reduced utilization of the brain phosphocreatine pool.     

Control of barley root respiration

Evidence from barley [ Hordeum distichum (L.) Lam. cv. Maris Mink], and from many other species, suggests that respiration is controlled by either supply of carbohydrate or demand for ATP. The relationship between root respiration rate (measured as O₂ consumption or CO₂ production) and ethanol-soluble carbohydrate content altered with time following selective pruning, and the change could not be accounted for by buffering of the cytoplasmic carbohydrate concentration by sugars in the vacuole. Exogenous sucrose supplied to the roots prevented any decline of the respiration rate in shoot-pruned plants, and if supplied for 24 h stimulated the respiration rate after any treatment. Root extension responded to sucrose in a similar manner. We suggest that respiration is under fine control by adenylates, but the capacity of the respiratory system is fixed by the supply of sucrose, possibly via coarse control of the respiratory machinery, or of the processes requiring metabolic energy.     

Effect of chronic hypernatremic dehydration and rapid rehydration on brain carbohydrate, energy, and amino acid metabolism in weanling mice

Abstract: This is a study of the effects of chronic hypernatremic dehydration and rehydration on carbohydrate, energy, and amino acid metabolism in the brains of weanling mice. Chronic hypernatremic dehydration induced by 4 days of water deprivation and salt loading was associated with severe weight loss (no other observed clinical effects), increased brain Na⁺ levels, and a decreased brain water content. Changes in the concentrations of brain glucose, glycolytic and citric acid cycle metabolic intermediates, and phosphocreatine were compatible with reduced cerebral metabolic rate. In adaptation to chronic hypernatremia, there was a significant increase in the content of the measured brain amino acids. Rapid rehydration over a 4-h period with 2.5% dextrose in water returned plasma Na⁺ levels and brain Na⁺ and water contents to normal. After rehydration, metabolites were altered in a manner consistent with increased fluxes through the glycolytic pathway and citric acid cycle; the brain glycogen content almost tripled. Brain taurine and glutamine levels were not lowered by rehydration, and the total content of the measured amino acids in brain was still significantly higher than in controls. We speculate that these metabolic perturbations may relate to the development of cerebral edema and seizures or coma following rapid rehydration of humans with chronic hypernatremic dehydration.     

31P NMR Relaxation Does Not Affect the Quantitation of Changes in Phosphocreatine, Inorganic Phosphate, and ATP Measured In Vivo During Complete Ischemia in Swine Brain

Abstract: Ischemia-induced changes in ³¹P NMR relaxation were examined in 16 piglets. NMR spectra were acquired under control conditions and during complete cerebral ischemia induced via cardiac arrest. Changes in T ₁ were assessed directly in six animals during control conditions and after 30–45 min of complete ischemia when changes in brain P₁ levels had reached a plateau. The T ₁ for P₁ did not change, i.e., 2.3 ± 0.5 s during control conditions versus 2.4 ± 1.0 s during ischemia. To evaluate phosphocreatine and ATP, two types of spectra, with a long (25-s) or short (1-s) interpulse delay time, were collected during the first 10 min of ischemia (n = 10). Both types of spectra showed the same time course of changes in phosphocreatine and ATP levels, implying that the T ₁ relaxation times do not change during ischemia. There were no changes in the linewidths of phosphocreatine, ATP, or P₁ during ischemia, implying that the T *₂ values remain constant. Our results suggest that the ³¹P T ₁ and T *₂ for phosphocreatine, P_i, and ATP do not change during ischemia, and therefore changes in ³¹P NMR peak intensity accurately reflect changes in metabolite concentrations.     

Dexamethasone Prevents Hypoxia/Ischemia-Induced Reductions in Cerebral Glucose Utilization and High-Energy Phosphate Metabolites in Immature Brain

Abstract: We examined the potential importance of dexamethasone-mediated alterations in energy metabolism in providing protection against hypoxic-ischemic brain damage in immature rats. Seven-day-old rats (n = 165) that had been treated with dexamethasone (0.1 mg/kg, i.p.) or vehicle were assigned to control or hypoxic-ischemic groups (unilateral carotid artery occlusion plus 2–3 h of 8% oxygen at normothermia). The systemic availability of alternate fuels such as β-hydroxybutyrate, lactate, pyruvate, and free fatty acids was not altered by dexamethasone treatment, and, except for glucose, brain levels were also unaffected. At the end of hypoxia, levels of cerebral high-energy phosphates (ATP and phosphocreatine) were decreased in vehicle- but relatively preserved in dexamethasone-treated animals. The local cerebral metabolic rate of glucose utilization (lCMRgl) was decreased modestly under control conditions in dexamethasone-treated animals, whereas cerebral energy use measured in a model of decapitation ischemia did not differ significantly between groups. The lCMRgl increased markedly during hypoxia-ischemia ( p < 0.05) and remained elevated throughout ischemia in dexamethasone-but not vehicle-treated groups, indicating an enhanced glycolytic flux with dexamethasone treatment. Thus, dexamethasone likely provides protection against hypoxic-ischemic damage in immature rats by preserving cerebral ATP secondary to a maintenance of glycolytic flux.     

Role of phosphocreatine in energy transport in skeletal muscle of bullfrog studied by 31P-NMR

To evaluate the energy-shuttle hypothesis of the phosphocreatine/creatine kinase system, diffusion rates for ATP, phosphocreatine and flux through the creatine kinase reaction were determined by 31P-NMR in resting bullfrog biceps muscle. The diffusion coefficient of phosphocreatine measured by 31P-pulsed gradient NMR was 1.4-times larger than ATP in the muscle, indicating the advantage of phosphocreatine molecules for the intracellular energy transport. The flux of the creatine kinase reaction measured by 31P-saturation transfer NMR was 3.6 mmol/kg wet wt. per s in the resting muscle. The flux is equal to the turnover rate of ATP, ADP, phosphocreatine and creatine molecules, therefore, the life-times of these substrates and the average distance traversed after the life-times by the diffusing molecules were calculated using the diffusion coefficients obtained by 31P-NMR. The mean square length of one-dimensional diffusion was 22 microns in ATP molecules and the minimum diffusion length was 1.8 microns in ADP molecules. The latter was calculated using free ADP concentration, 30 mumol/kg wet wt., obtained from the equilibrium constant of the creatine kinase reaction and the diffusion coefficient assumed to be the same of ATP in muscle. Similar diffusion lengths of ADP were calculated using the reported values for the flux of the creatine kinase reaction in heart and smooth-muscle. The diffusion lengths of all substrates involved in the creatine kinase reaction were larger than the radii of myofibrils. Therefore, in the muscles with an alternating arrangement of mitochondria and myofibrils, such as heart and certain skeletal muscles, ATP and ADP molecules can move freely between myofibrils and mitochondria without the aid of the creatine kinase reaction; thus, we conclude that the energy-shuttle hypothesis is not obligatory for energy transport between the mitochondria and the myofibrils.     

Bioenergetic consequences of cardiac phosphocreatine depletion induced by creatine analogue feeding

To further evaluate the bioenergetic role of phosphocreatine, we assessed several parameters in normal and depleted rat hearts. Rats were fed (8 weeks) a diet containing either 1% beta-guanidinoproprionic acid or 2% beta-guanidinobutyric acid (beta-GBA), resulting in an 80% phosphocreatine depletion compared to controls. Left ventricular pressure-volume curves were obtained to determine contractile function. At any volume, the developed pressure in depleted hearts was lower than in controls. At the plateau, the rate-pressure product was between 37-45% lower: 34,000 (beta-GBA), 30,174 (beta-guanidinoproprionic acid) versus 54,400 (control). 31P NMR spectroscopy on beta-GBA-treated hearts obtained the [ATP] and [phosphocreatine], which with saturation transfer estimated the rates of creatine kinase and ATP production. In depleted hearts, the rate constant for ATP synthesis from phosphocreatine was increased 33%. However, the flux was 72% lower. ATP production from ADP and Pi were similar under normal conditions, in spite of higher rates of oxygen consumption in the depleted hearts. The addition of 50 mM creatine to control perfusate had no effect on function or high energy phosphates. In contrast, a 28% increase in function and a 52% increase in [phosphocreatine] was seen in beta-GBA hearts. There was a marked increase in free [ADP] in beta-GBA hearts, resulting in a lower estimated ATP phosphorylation potential. Overall, the results suggest that phosphocreatine may play an important function by optimizing the thermodynamics of cardiac high energy phosphate utilization.     

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.     

Dynamics of cerebral metabolism during moderate hypercapnia.

The effects of hypercapnia on the kinetics of cerebral energy metabolism were evaluated in adult rats by the closed system method of LOWRY et al. (1964). Moderate hypercapnia with a Pa_co2 of 61 torr sustained for 20 min resulted in intracellular brain acidosis (7.07-6.97). During hypercapnia the tissue content of glucose increased whereas phosphocreatine, ADP, pyruvate and lactate contents, and the lactate/pyruvate ratio decreased. The ATP/ADP ratio increased from 7.7 to 9.0; the cytoplasmic NADH/NAD + ratio decreased from 2.06 × 10^-3 to 1.49 × 10^-3. There was no change in Energy Charge. Turnover rate of phosphocreatine increased from 3.84 to 4.62 mmol/kg/min, but the turnover rates of ATP, glucose and glycogen were reduced (from 1.98 to 1.86, 6.24 to 4.80, and 3.96 to 2.94 mmol/kg/min, respectively). The utilization rate of total high energy phosphate decreased from 30.6 to 25.4 mmol/kg/min while the post-decapitation EEG during hypercapnia persisted longer than during normocapnia. These results indicate that moderate hypercapnia reduces the overall kinetic activity of cerebral energy metabolism. The steady Energy Charge suggests that the reduction in the rate of high energy phosphate use is proportionally balanced by a lowered production rate of ATP.     

Regulation of intermediary metabolism in rat cardiac myocyte by extracellular glycerol

In the human heart, although all substrates compete for energy production, fatty acids (FA) represent the main substrate for ATP production. In the healthy heart, a balance between FA and carbohydrate utilization ensures that energy supply matches demand. This study was carried out to evaluate, in a model of spontaneously beating neonatal rat cardiomyocytes in culture, the hypothesis that glycerol could play a central role in the metabolic control of the routes involving long chain FAs and may then affect the balance between beta-oxidation and glucose oxidation. The intracellular-free glycerol significantly increased with extracellular glycerol concentration (0 to 660 microM). The synthesis of phospholipids was significantly increased in parallel with both extracellular glycerol (1.5 and 14.8 nmol glycerol/mg protein, at 82 and 660 microM of extracellular glycerol, respectively). The oxidation of glycerol increased proportionally to extracellular glycerol concentration (from 1 to 3 nmol glycerol/mg protein, at 82 microM and 660 microM extracellular glycerol, respectively, P<0.001). At its maximum, this oxidation represented 15% of the glucose oxidation, which was not affected by glycerol extracellular supply or intracellular availability. Conversely, extracellular glycerol significantly reduced the palmitate oxidation above (-47% at 660 microM glycerol), but not octanoate oxidation. Investigations on the mechanism of the decreased palmitate oxidation reveals a glycerol-dependent increase in malonyl-CoA associated with a significant decrease in CPT-1 activity which accounts for the difference between palmitate and octanoate. These results clearly demonstrate the importance of glycerol in regulating the cardiac metabolic pathways and energy balance.     

The role of pH on the thermodynamics and kinetics of muscle biochemistry: an in vivo study by (31)P-MRS in patients with myo-phosphorylase deficiency

In this study we assessed ΔG'(ATP) hydrolysis, cytosolic [ADP], and the rate of phosphocreatine recovery using Phosphorus Magnetic Resonance Spectroscopy in the calf muscle of a group of patients affected by glycogen myo-phosphorylase deficiency (McArdle disease). The goal was to ascertain whether and to what extent the deficit of the glycogenolytic pathway would affect the muscle energy balance. A typical feature of this pathology is the lack of intracellular acidosis. Therefore we posed the question of whether, in the absence of pH decrease, the rate of phosphocreatine recovery depends on the amount of phosphocreatine consumed during exercise. Results showed that at the end of exercise both [ADP] and ΔG'(ATP) of patients were significantly higher than those of matched control groups reaching comparable levels of phosphocreatine concentration. Furthermore, in these patients we found that the rate of phosphocreatine recovery is not influenced by the amount of phosphocreatine consumed during exercise. These outcomes provide experimental evidence that: i) the intracellular acidification occurring in exercising skeletal muscle is a protective factor for the energy consumption; and ii) the influence of pH on the phosphocreatine recovery rate is at least in part related to the kinetic mechanisms of mitochondrial creatine kinase enzyme.     

Impact of low-flow ischemia on substrate oxidation and glycolysis in the isolated perfused rat heart

Interventions that stimulate carbohydrate oxidation appear to be beneficial in the setting of myocardial ischemia or infarction. However, the mechanisms underlying this protective effect have not been defined, in part because of our limited understanding of substrate utilization under ischemic conditions. Therefore, we used (1)H and (13)C NMR spectroscopy to investigate substrate oxidation and glycolytic rates in a global low-flow model of myocardial ischemia. Isolated male Sprague-Dawley rat hearts were perfused for 30 min under conditions of normal flow (control) and low-flow ischemia (LFI, 0.3 ml/min) with insulin and (13)C-labeled lactate, pyruvate, palmitate, and glucose at concentrations representative of the physiological fed state. Despite a approximately 50-fold reduction in substrate delivery and oxygen consumption, oxidation of all exogenous substrates plus glycogen occurred during LFI. Oxidative metabolism accounted for 97% of total calculated ATP production in the control group and approximately 30% in the LFI group. For controls, lactate oxidation was the major source of ATP; however, in LFI, this shifted to a combination of oxidative and nonoxidative glycogen metabolism. Interestingly, in the LFI group, anaplerosis relative to citrate synthase increased sevenfold compared with controls. These results demonstrate the importance of oxidative energy metabolism for ATP production, even during very-low-flow ischemia. We believe that the approach described here will be valuable for future investigations into the underlying mechanisms related to the protective effect of increasing cardiac carbohydrate utilization and may ultimately lead to identification of new therapeutic targets for treatment of myocardial ischemia.     

Increase in Chloride-Dependent l-Glutamate Transport Activity in Synaptic Membrane After In Vitro Ischemic Treatment

Abstract: The effect of energy failure on Cl⁻-dependent l -glutamate ( l -Glu) transport was examined with an in vitro preparation. Rat brain slices were incubated in low oxygen and glucose-deprived medium (in vitro ischemia), and a synaptic membrane fraction was prepared from the slices. Cl⁻-dependent l -[³H]Glu uptake into vesicles increased about twofold after 20 min of in vitro ischemia. The increased l -[³H]Glu uptake was inhibited by l -Glu, dl -2-amino-4-phosphonobutyrate, l -homocysteic acid, l -cystine, 4,4'-diisothiocyano-2,2'-disulfonic stilbene, and removal of Cl⁻. Uptakes of Na⁺-dependent l -[³H]-Glu, [³H]GABA, and [³H]taurine were not changed by the in vitro ischemia. In vitro ischemia increased the V _max value without affecting the K _m value. The increased l -[³H]Glu uptake by in vitro ischemia was reduced by subsequent incubation in a normoxic glucose-containing solution. ATP content in brain slices decreased to <10% of control values by in vitro ischemia for 10 min. The decrease in ATP content was restored by subsequent incubation in normoxic glucose-containing solution. Treatment with veratrine, 2,4-dinitrophenol, carbonyl cyanide m -chlorophenylhydrazone, and NaCN in normoxic conditions increased l -[³H]Glu uptake with a concomitant decrease in ATP content in slices. These results suggest that Cl⁻-dependent l -Glu transport activity in synaptic membranes increases in ischemia- or hypoxia-induced brain energy failures.     

A 31P-NMR saturation transfer study of the regulation of creatine kinase in the rat heart

(1) ³¹P nuclear magnetic resonance was used to measure the creatine kinase-catalysed fluxes in Langendorff-perfused rat hearts consuming oxygen at different rates and using either of two exogenous substrates (11 mM glucose or 5 mM acetate). (2) Fluxes in the direction of ATP synthesis were between 3.5–12-times the steady-state rates of ATP utilization (estimated from rates of O₂-consumption), demonstrating that the reaction is sufficiently rapid to maintain the cytosolic reactants near their equilibrium concentrations. (3) Under all conditions studied, the cytosolic free [ADP] was primarily responsible for regulating the creatine kinase fluxes. The enzyme displayed a K_m for cytosolic ADP of 35 μM and an apparent V_max of 5.5 mM/s in the intact tissue. (4) Although the reaction is maintained in an overall steady-state, the measured ratio of the forward flux (ATP synthesis) to the reverse flux (phosphocreatine synthesis) was significantly greater than unity under some conditions. It is proposed that this discrepancy may be a consequence of participation of ATP in reactions other than the PCr /ag ATP or ATP /ag ADP + P_i interconversions specifically considered in the analysis. (5) The results support the view that creatine kinase functions primarily to maintain low cytosolic concentrations of ADP during transient periods in which energy utilization exceeds production.     

Cerebral energy metabolism during experimental status epilepticus.

—The concentration of ATP, ADP, AMP, phosphocreatine and of 5 intermediates of carbohydrate metabolism were determined in rodent brain after single and repeated seizures induced by either electroshock (ES), flurothyl or pentylenetetrazol (PTZ). In paralysed-ventilated rats, one ES produced a 4–5 fold increase in cortical glycolytic flux (estimated from changes in glucose and lactate), and associated increases in pyruvate and in the lactate/pyruvate ratio. Total high energy phosphates declined during the seizure; a decrease was also calculated in cortical tissue pH and in the cytoplasmic [NAD⁺]/[NADH] ratio. Similar changes in brain were observed in ventilated mice after ES, but in paralysed animals, no decrease in high energy phosphates occurred during the first seizure. More vigorous and prolonged chemically-induced seizures in both rats and mice elicited a decrease in the cerebral energy reserves with a rise in lactate and in the lactate/pyruvate ratio. At all times during the seizures the cerebral venous blood had a higher oxygen tension than that of control animals (rats) or was visibly reddened (mice), implying that oxygen availability to brain exceeded metabolic demands. It is proposed that the development of‘non-hypoxic’cerebral lactacidosis during seizures is part of the overall metabolic response of the brain to an abrupt increase in energy consumption. The response constitutes a homeostatic influence which promotes cerebral vasodilatation, thereby increasing blood flow and the delivery of substrates. With repeated seizures, delivered 2 min apart, glycogen declined progressively, but concentrations of the adenine nucleotides appeared to plateau, suggesting that a new energy balance had been established. However, after 20–25 seizures, the attacks became self-generating and there was a further reduction in the tissue high energy phosphate stores, a fall in brain glucose and in the brain/blood glucose ratio. It is concluded that the brain possesses a limited capacity to adjust its metabolism to meet the increased energy requirements of single or repeated seizures, but that this mechanism ultimately fails during status epilepticus unless the abnormal electrical discharges, themselves, are brought under control.     

A P-NMR saturation transfer study of the regulation of creatine kinase in the rat heart

(1) ³¹P nuclear magnetic resonance was used to measure the creatine kinase-catalysed fluxes in Langendorff-perfused rat hearts consuming oxygen at different rates and using either of two exogenous substrates (11 mM glucose or 5 mM acetate). (2) Fluxes in the direction of ATP synthesis were between 3.5–12-times the steady-state rates of ATP utilization (estimated from rates of O₂-consumption), demonstrating that the reaction is sufficiently rapid to maintain the cytosolic reactants near their equilibrium concentrations. (3) Under all conditions studied, the cytosolic free [ADP] was primarily responsible for regulating the creatine kinase fluxes. The enzyme displayed a K_m for cytosolic ADP of 35 μM and an apparent V_max of 5.5 mM/s in the intact tissue. (4) Although the reaction is maintained in an overall steady-state, the measured ratio of the forward flux (ATP synthesis) to the reverse flux (phosphocreatine synthesis) was significantly greater than unity under some conditions. It is proposed that this discrepancy may be a consequence of participation of ATP in reactions other than the PCr /ag ATP or ATP /ag ADP + P_i interconversions specifically considered in the analysis. (5) The results support the view that creatine kinase functions primarily to maintain low cytosolic concentrations of ADP during transient periods in which energy utilization exceeds production.     

In vivo and in vitro assessment of brain bioenergetics in aging rats

Brain energy disorders can be present in aged men and animals. To this respect, the mitochondrial and free radical theory of aging postulates that age‐associated brain energy disorders are caused by an imbalance between pro‐ and anti‐oxidants that can result in oxidative stress. Our study was designed to investigate brain energy metabolism and the activity of endogenous antioxidants during their lifespan in male Wistar rats. In vivo brain bioenergetics were measured using ³¹P nuclear magnetic resonance (NMR) spectroscopy and in vitro by polarographic analysis of mitochondrial oxidative phosphorylation. When compared to the young controls, a significant decrease of age‐dependent mitochondrial respiration and adenosine‐3‐phosphate (ATP) production measured in vitro correlated with significant reduction of forward creatine kinase reaction (kfor) and with an increase in phosphocreatine (PCr)/ATP, PCr/Pi and PME/ATP ratio measured in vivo. The levels of enzymatic antioxidants catalase, GPx and GST significantly decreased in the brain tissue as well as in the peripheral blood of aged rats. We suppose that mitochondrial dysfunction and oxidative inactivation of endogenous enzymes may participate in age‐related disorders of brain energy metabolism.     

Effect of oxygen concentration on the senescence and energy metabolism of cut carnation flowers

The effect of O₂ concentration on energy metabolism and senescence has been studied in cut flowers of Dianthus caryophyllus L. cv. Scania. As compared to the control (21% O₂), 5% O₂ delays flower senescence as well as decay of nucleotide level and AEC (adenylate energy charge). An atmosphere of 100% O₂ accelerates senescence as well as the decrease of nucleotide level and AEC. While anoxia brings about a faster decrease of ATP and AEC than of total nucleotides, hyperoxia brings about a faster decrease in adenyl nucleotides than in ATP and AEC values. Petal oxygen uptake is over 90% of the maximal value under 4% O₂ and saturates at 10% O₂. The development of senescence is dicussed as a two phase process (first phase-progressive and second phase-catastrophic) triggered by the action of hyperoxia, first on the system for energy utilization and later on the system for energy production, the degradation of which seems to be linked with increase in membrane permeability and withering.