Thermodynamics of Mg and Ca complexation with AMP,ADP, ATP

The thermodynamic parameters (ΔG, ΔH, ΔS) of complexation have been measured by potentiometric and calorimetric titration for formation of ML and MHL (M  Mg²⁺, Ca²⁺; L  AMP²⁻, ADP³⁻, ATP⁴−). The parameters are interpreted to support a model of inner sphere complexation of the metal cations to the phosphate groups with no evidence of metal-ring interaction in the ML complexes. In the MHL complexes, the protonation (of a ring nitrogen) seemingly leads to ‘backfolding’ interaction between the metal and the ring system in addition to the interaction between the metal and the phosphate groups.     

The effect of hormones on metal and metal-ATP interactions with fat cell adenylate cyclase.

1-adrenaline, ACTH and glucagon activate the adenylate cyclase of rat adipocytes by decreasing its S_0.5(Mg²⁺) (concentration yielding 0.5 V_max) from its basal value of 11.5 to 1.2, 0.3 and 1.8 mM and by increasing its K_i(ATP^4?) from 0.03 to 0.25; 0.62 and 0.16 mM respectively. The kinetic properties of the enzyme are regulated by its state of saturation with ATP^4? or Mg²⁺; its saturation with ATP^4? and citrate^3? suppressed its basal and hormone-dependent activities. The hormone-dependent decrease in K_m and increase in V_max of the enzyme occur when shifting from suboptimal low concentrations of hormone and Mg²⁺ to optimal conditions, i.e., high concentration of hormone and low concentration of Mg²⁺. The increase in the state of saturation of the enzyme with Mg²⁺ decreases the hormone-dependent effects on V_max and results in identical values of K_m (0.14 mM) for its basal and 1-adrenaline dependent activities. CaCl₂ saturation curves at 5 mM ATP with either 5, 10 or 20 mM MgCl₂ show that the substitution of 5 mM MgCl₂ by 10 mM and 20 mM MgCl₂ increased the K_i(Ca²⁺) of the enzyme from 0.19 to 0.49 and 0.94 mM but decreased its K_i(CaATP) from 0.42 to 0.19 and 0.14 mM respectively. Only when the concentration of MgCl₂ exceeded that of ATP did 1-adrenaline and ACTH activate the enzyme by increasing its K_i(Ca²⁺), although only ACTH increased its K_i(CaATP). An increase in energy charge would decrease the intracellular concentrations of Mg²⁺ and Ca²⁺ because ATP^4? has stronger binding constants for Mg²⁺ and Ca²⁺ than ADP^3? and AMP^2?. Hence, the reported properties of the enzyme suggests that changes in energy charge may allow for metabolic feedback control of the hormonal responsiveness of the Mg²⁺, Ca²⁺, ATP^4? -sensitive adenylate cyclase.     

Control of mitochondrial respiration: a quantitative evaluation of the roles of cytochrome c and oxygen.

The dependence of the mitochondrial respiratory rate on the reduction of cytochrome c has been measured as a function of the exogenous $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{][}\text{P}{}_{\mathrm{i}}\text{]}$ ratio and pH. The respiratory rate at $\text{[}\text{ADP}\text{]}\text{[}\text{ADP}\text{][}\text{P}{}_{\mathrm{i}}\text{]}$ values of less than 10^-1m^-1 is proportional to the reduction of cytochrome c and independent of pH from pH 6.5 to pH 8.O. The maximal turnover number (at 100% reduction) for cytochrome c is approximately 70 s^?1. As the $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{][}\text{P}{}_{\mathrm{i}}\text{]}$ ratio is increased from 10^?1m^?1 to 10⁴m^?1, the respiration at any given level of reduction of cytochrome c is progressively inhibited. Greater inhibition is observed at more oxidized levels of cytochorme c with respiratory control values for oxidation of reduced cytochrome c exceeding 10. The behavior of mitochondrial respiratory control is shown to be quantitatively consistent with a proposed mechanism in which the regulation occurs in the reaction of oxygen with cytochrome oxidase. A steady-state rate expression is derived which fits the mitochondrial respiratory rate dependence on (i) the extramitochondrial $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{][}\text{P}{}_{\mathrm{i}}\text{]}$ ratio; (ii) the level of reduction of cytochrome c (or the intramitochondrial $\text{[}\text{NAD}{}^{\mathrm{+}}\text{]}\text{[NADH])}$ at different $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{][}\text{P}{}_{\mathrm{i}}\text{]}$ values; (iii) the pH of the suspending medium. This rate expression appears to correctly predict the relationships of the cytoplasmic $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{][}\text{P}{}_{\mathrm{i}}\text{]}$ ratio, the mitochondrial $\text{[}\text{NAD}{}^{\mathrm{+}}\text{]}\text{[}\text{NADH}\text{]}$ ratio, and the mitochondrial respiratory rate in intact cells as well as suspensions of isolated mitochondria.     

Self-association of nucleotides

The self-association of nucleosides decreases within the series adenosine>guanosine>inosine>cytidine ≈uridine. The same trend is observed for the corresponding nucleotides, though less pronounced, as the charge effect governs series like adenosine ? AMP^2?>ADP^3??ATP^4?. Protonation of adenosine considerably reduces its self-stacking tendency: this is different with ATP^4?, where a maximum is reached for H₂(ATP)^2? caused by additional ionic interactions in the [H₂(ATP)]₂ ^4? dimer. Metal ion coordination may promote self-association, e.g., of ATP^4? via (mainly) charge neutralization (Mg²⁺) and the formation of intermolecular bridges in dimeric stacks (Zn²⁺, Cd²⁺). These results allow definition of conditions with negligible self-association and thus the determination of the stability and structure of monomeric nucleotide complexes in aqueous solution, e.g., quantification of macrochelate formation in M(ATP)^2? complexes. Some biological implications of the results are indicated.     

Effect of glucose on AMP-catabolite release during fatty acid perfusion in normal and ischemic rat hearts

Isolated rat hearts were perfused retrogradely with a modified, oxygenated Tyrode solution containing 0.5 mM palmitate (complexed to albumin in a molar ratio of 6:1) with or without 11mM glucose. Fatty acid perfusion induced a decrease in contractile behaviour which was partly counteracted by glucose. The energy charge $\text{{([}\text{ATP}\text{] +}\text{1}\text{2}\text{[}\text{ADP}\text{])/([}\text{ATP}\text{] + [}\text{ADP}\text{] + [}\text{AMP}\text{]}}$ of the tissue was not altered although a significant drop was observed in creatine phosphate/ATP ratio in the absence of glucose. The release of AMP-catabolites, adenosine, inosine and hypoxanthine, occurring during fatty acid perfusion was reduced by glucose. In the absence of glucose fatty acids still induce lactate release indicating an enhanced glycogenolysis. In ischemic hearts the fatty acid-induced decrease in mechanical performance was significantly more severe when glucose was absent, while the glucose protection could also be observed in the energy charge of the ischemic tissue and the release of AMP-catabolites in the coronary effluent. The results suggest that loss of adenosine, inosine and hypoxanthine might contribute to the detrimental actions of a high fatty acid/albumin ratio upon the myocardium and confirms the protective action of glucose.     

Changes in predominant energy substrate after hepatectomy

The changes in the energy substrate utilized by the remnant liver were studied in relation to the changes in the cellular energy status of 25 and 70% hepatectomized rabbits. In 25% hepatectomized rabbits, the energy charge $\text{(}\text{(}\text{ATP}\text{+0.5}\text{ADP}\text{)}\text{(}\text{ATP}\text{+}\text{ADP}\text{+}\text{AMP}\text{)}\text{)}$ level of the remnant liver remained unchanged, the energy substrate of which was predominantly glucose, rather than fatty acid. In contrast, in 70% hepatectomized rabbits, the energy production by the mitochondria was mainly dependent upon fatty acid oxidation at the early period after hepatectomy when the energy charge level decreased remarkably, and then upon glucose oxidation, concomitant with the restoration of the energy charge. It is suggested that the changes in the energy substrate utilized are closely related to those in the energy charge level and the mitochondrial phosphorylative activity of the remnant liver following hepatectomy.     

Adenine nucleotide control of the rate of oxygen uptake by rat heart mitochondria over a 15- to 20-fold range

Rat heart mitochondria oxidizing pyruvate (in the presence of 20% as much malate) took up nearly the amount of oxygen required for complete oxidation to CO₂. Thus pyruvate, a physiological substrate of the citrate cycle, is oxidized through the entire cycle in these mitochondria, and they seem suitable for study of regulation of integrated mitochondrial energy transduction. By addition of graded amounts of hexokinase or pyruvate kinase to the suspending medium (in the presence of excess glucose or phosphoenolpyruvate), a wide range of steady-state values of the $\text{ATP}\text{ADP}$ concentration ratio was obtained. At a constant concentration of phosphate, the steady-state rate of oxygen uptake by rat heart mitochondria oxidizing pyruvate was a function of the adenylate energy charge or of the $\text{ATP}\text{ADP}$ ratio, and relatively independent of the absolute concentrations of these nucleotides. The oxygen uptake rates typically spanned a range of about 20-fold. At very high values of the $\text{ATP}\text{ADP}$ ratio, the rate of oxygen uptake is much lower than the “state 4” rate seen after added ADP has been phosphorylated. This result suggests that “state 4” respiration, at least in these freshly prepared mitochondria, measures the rate at which ADP is made available by ATPase activity, rather than indicating uncoupling of electron transport from phosphorylation. The concentration of orthophosphate affected the rate of oxygen uptake and the pattern of response to the $\text{ATP}\text{ADP}$ ratio or the energy charge, but the effects did not seem interpretable in terms of the mass-action expression for hydrolysis of ATP, $\text{(ATP}\text{ADP)}$ (P_i.     

Equilibration of Adenylates by Maize Leaf Adenylate Kinase: Effects of Magnesium on Apparent and True Equilibria

In this study, the effect of magnesium on equilibration of adenylatesby purified maize leaf adenylate kinase (AK) was investigated.The equilibration was expressed in terms of either apparentequilibrium constant, defined as K_app=(ATP_total)(AMP_total)/(ADP_total)²,or true equilibrium constant, defined as K_true=(Mg-ATP)(AMP_free)/(Mg-ADP)(ADP_free).At a fixed concentration of free magnesium (1?8–1?9 mM),the K_app, and K_true were constant at 0?76?0?10 and 6?02?0?75,respectively. On the other hand, at the free magnesium rangeof 0?00l4 to 8?3 mM, the K_app varied from 0?30 to 1?27, whileremained constant at 5?93?0?31. The data indicate that, contraryto previous speculations, leaf AK does not maintain an equilibriumof total adenylates. Rather, the enzyme governs an equilibriumof Mg-ADP, free ADP, Mg-ATP, and free AMP, which are the truesubstrates/products of the AK reaction. Some implications ofthis finding for studies on energy metabolism in plant tissuesare discussed. Key words: Adenylate kinase, adenylate energy charge, adenylates, C₄-photosynthesis, magnesium     

Coordination of adenylate energy charge and phosphorylation state during ischemia and under physiological conditions in rat liver and kidney

The relation of the adenylate energy charge $\text{(}\text{ATP}\text{+}\text{1}\text{2}\text{ADP/ATP}\text{+}\text{ADP}\text{+}\text{AMP}\text{)}$ to the phosphorylation state (ATP)/(ADP)(HPO₄^2?) in rat liver and kidney was analyzed. Under physiological conditions and in ischemia, the two regulatory parameters, calculated from reported values for adenine nucleotides and inorganic phosphate (P_i) and from new observations, were closely coordinated. Energy charge was an inverse linear function of P_i and -log (1 - energy charge) was a positive linear function of log phosphorylation state. To evaluate experimental data with known energy charge, but unknown P_i, and to determine the theoretical relation between energy charge and phosphorylation state, P_i was estimated from a) the regression equation: P_i, μmol/g wet wt tissue = 1.05 - energy charge/0.073 and b) the empirical relationship: (P_i/2P_a) + energy charge = k, where P_a = σAMP + 2ADP + 3ATP and k = 1. With both estimates, the relation between phosphorylation state and energy charge for the experimental data was, within error, the same as that observed with measured P_i and concordant with theoretical values. Over the physiological range of energy charge (～0.85 – 0.95, log phosphorylation state ～3.3 – 4.3), apparent ΔG_ATP (×2) was closer to the range of ΔG observed by Wilson $\text{et al}$ (Biochem. J. $\text{140}$:57, 1974) for transfer of two electrons from mitochondrial NAD to the cytochrome c couple than the ΔG_ATP (×2) they reported, supporting their conclusion that near-equilibrium exists between the mitochondrial respiratory chain and the cytoplasmic phosphorylation state under physiological conditions. From evidence presented, it is postulated that the phosphorylation state is regulated by the adenylate energy charge.     

Modulation of the organization of erythrocyte membrane phospholipids by cytoplasmic ATP. The susceptibility of isoionic human erythrocyte ghosts to attack by detergents and phospholipase C

Human erythrocyte ghosts were prepared in media of physiological ionic composition, and these “isoionic” ghosts were then lysed and resealed in media of varying Ca²⁺, Mg²⁺ and ATP concentrations. The susceptibilities of these ghosts to limited attack by various detergents and by phospholipases C were then compared with the susceptibilities of intact cells to similar attack: attack was assessed by measurements of lysis and of phospholipid hydrolysis. Ghosts were more readily attacked than cells by anionic detergents (cholate, glycocholate, dodecyl sulphate) and by phospholipases C, but Triton X-100 and cetyltrimethylammonium attacked cells and ghosts to the same extent. Mg · ATP^2? partially protected ghosts from attack by the anionic detergents and by the phospholipases C of Bacillus cereus and of Clostridium perfringens. Protection by Mg · ATP^2? occurred only if Mg · ATP^2? had access to the cytoplasmic surface of the membrane. Adenylyl(β-γ-methylene)diphosphonate, a non-hydrolysable ATP analogue, protected as effectively as did Mg · ATP^2?. Internal Mg · ATP^2? caused a marked reduction in the hydrolysis by phospholipases of phosphatidylethanolamine and sphingomyelin, but had no appreciable effect upon the simultaneous hydrolysis of phosphatidylcholine. It therefore seems that interaction of ATP with sites on the cytoplasmic surface of the erythrocyte membrane can, without ATP hydrolysis, cause changes in the organization of the outer surface of the membrane that specifically render phosphatidylethanolamine and sphingomyelin less accessible to attack by extracellular phospholipases.     

Coordination of magnesium with adenosine 5′-diphosphate and triphosphate

³¹P NMR chemical shifts of salts of adenosine 5′-triphosphate and diphosphate: ATPH^2?₂2(Me₄N⁺) · H₂O, ATPH^2?₂2 Na⁺ · 3.5 H₂O, ATPH^2?₂Mg²⁺ · 4 H₂O, ATPH^2?₂Ca²⁺ · 2 H₂O, ADPH^2?2(Me₄N⁺) · H₂O and ADPH^2?Mg²⁺ · 4 H₂O have been measured in 0.02 M ²H₂O solutions at 145.7 MHz (22° C) at constant p²H values (8.20 and 6.20). The results are compared with those obtained from salts of adenosine 5′-monophosphate and other simpler phosphomonoesters, e.g. AMP^2?2(Me₄N⁺), AMP^2?Mg²⁺, AMPH^?Me₄N⁺ and (AMPH^?)₂Mg²⁺. It is concluded that the effects exerted by Mg²⁺ and Ca²⁺ on the ³¹P NMR shifts of dipoly- and tripolyphosphates relative to monovalent cations are due mainly to changes in conformation of the polyphosphate chain rather than to purely electronic factors associated with the binding of divalent cations to the phospho-oxyanions. The data are consistent with the existence of the following complexes at p²H 8.20: (MgP_αP_β)ADP^? and (MgP_αP_γ)ATP^2?af (MgP_αP_β)ATP^2?af (MgP_βP_γ)ATP^2? with the latter equilibrium relatively fast in the NMR time scale. Monoprotonation of the terminal phosphate appears to weaken the Mg²⁺-polyphosphate binding, particularly at P_β of MgADPH and at P_β and P_γ of MgATPH^?. The Mg²⁺-polyphosphate binding weakens further at p²H 3.70, i.e. in MgATPH₂. Possible implications of the results in the mechanism of actomyosin Mg²⁺-ATPase in muscle contraction are discussed.     

Studies on adenosine triphosphate transphosphorylases. XVIII. Synthesis and preparation of peptides and peptide fragments of rabbit muscle ATP-AMP transphosphorylase (adenylate kinase) and their nucleotide-binding properties

Two peptide fragments, derived from the head and tail of rabbit muscle myokinase, were found to possess remarkable and specific ligand-binding properties (Hamadaet al., 1979).By initiating systematic syntheses and measurements of equilibrium substrate-binding properties of these two sets of peptides, or portions thereof, which encompass the binding sites for (a) the magnesium complexes of the nucleotide substrates (MgATP^2– and MgADP^–) and (b) the uncomplexed nucleotide substrates (ADP^3– and AMP^2–) of rabbit muscle myokinase, some of the requirements for binding of the substrates to ATP-AMP transphosphorylase are being deduced and chemically outlined. One requirement for tight nucleotide binding appears to be a minimum peptide length of 15–25 residues. In addition, Lys-172 and/or Lys-194 may be involved in the binding of AMP.The syntheses are described as a set of peptides corresponding to residues 31–45, 20–45, 5–45, and 1–45, and a set of peptides corresponding to residues 178–192, 178–194, and 172–194 of rabbit muscle adenylate kinase. The ligand-binding properties of the first set of synthetic peptides to the fluorescent ligands: MgATP/ATP and MgADP/ADP are quantitatively presented in terms of their intrinsic dissociation constants (K_d) and values ofN (maximal number of moles bound per mole of peptide); and compared with the peptide fragment MT-I (1–44) obtained from rabbit muscle myokinase (Kubyet al., 1984) and with the native enzyme (Hamadaet al., 1979). In addition, the values ofN andK_d are given for the second set of synthetic peptides to the fluorescent ligands AMP and ADP as well as for the peptide fragments MT-XII(172–194) and CB-VI(126–194) (Kuby et al., 1984) and, in turn, compared with the native enzyme.A few miscellaneous dissociation constants which had been derived kinetically are also given for comparison (e.g., theK _i for AMP and the value of obtained for the native enzyme) (Hamada and Kuby, 1978), and theK'_d measured for Cr³⁺ and the synthetic peptide I_1–45 (Fryet al., 1985b).Paper XVII of this series is Kubyet al. (1983).     

Regulation of cellular energy metabolism. The Crabtree effect

The Crabtree effect (inhibition of respiration by glycolysis) is observed in cells with approximately equal glycolytic and respiratory capacities for ATP synthesis. Addition of glucose to aerobic suspensions of glucose-starved cells (Sarcoma 180 ascites tumor cells) causes a burst of respiration and lactate production due to ATP utilization for glucose phosphorylation by hexokinase and phosphofructokinase. This burst of activity is followed by inhibition of both respiration and glycolysis, the former to below the value before glucose addition (Crabtree effect). Both the respiratory rate and the glycolytic flux appear to be regulated by the cytosolic $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{][}\text{P}{}_{\mathrm{i}}\text{]}$ albeit by completely different mechanisms. Respiration is regulated by the free energy of hydrolysis of ATP, such that the rate increases as the $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{][}\text{P}{}_{\mathrm{i}}\text{]}$ decreases and decreases as the $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{][}\text{P}{}_{\mathrm{i}}\text{]}$ increases. The regulatory enzymes of glycolysis are activated by ADP (AMP) and P_i and inhibited by ATP. Thus both respiration and glycolysis increase or decrease as the $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{][}\text{P}{}_{\mathrm{i}}\text{]}$ decreases or increases. The parallel regulation of both ATP-producing pathways by this common metabolite ratio is consistent with the cytoplasmic $\text{[}\text{ATP}\text{]}\text{[}\text{ADP}\text{][}\text{P}{}_{\mathrm{i}}\text{]}$ being an important determinant of homeostatic regulation of cellular energy metabolism.     

Effect of the oral hypoglycemic agent 2-tetradecylglycidic acid on fatty acid oxidation in suckling rats in vivo and in perfused liver

The hypoglycemic agent, 2-tetradecylglycidic acid (TDGA), administered in vivo lowered the concentration of plasma glucose and ketone bodies but raised the concentration of liver and plasma triglycerides in 10-day-old suckling rats. Phospholipid and cholesterol content of the plasma and liver were unaffected by drug treatment. TDGA inhibited the in vivo oxidation of [1-¹⁴C]palmitate but not that of [1-¹⁴C]decanoate. In suckling rat liver perfusion, TDGA totally inhibited ketone body formation from palmitate and depressed ketone body production from decanoate by 20%. Liver ATP and ADP content in the presence of TDGA decreased although this was probably a reflection of the increased triglyceride content of the liver since the $\text{ATP}\text{ADP}$ was the same as control livers. The results are discussed in relation to the diet and to the inhibition of carnitine acyl transferase in suckling rats.     

Changes in nucleotide concentrations in the erythrocytes of man, rabbit and rat during short-term storage

The $\text{ATP}\text{ADP}$ ratio, measured by high performance liquid chromatography, has been used as an indicator of stability of erythrocyte nucleotides. The nucleotides from human, rabbit and rat whole blood, but not separated erythrocytes were stable for maximum periods of 40, 20 and 15 min respectively after venepuncture. The ratios then declined rapidly from 9 to 5, 12 to 4 and 9 to 1 respectively during 2h storage at room temperature. Similar changes occurred in $\text{GTP}\text{GDP}$ ratios. The relevance of these observations to metabolic studies in intact cells, nucleotide analyses in the clinical situation and comparative studies in other species is discussed.     

Coordinate control of intermediary metabolism in rat liver by the insulin/glucagon ratio during starvation and after glucose refeeding. Regulatory significance of long-chain acyl-CoA and cyclic AMP.

The levels of serum insulin, glucagon, and free fatty acids (FFA) and the tissue concentrations of hepatic cyclic AMP, long-chain acyl-CoA (LCA), adenine nucleotides, inorganic phosphate, the intermediates of the Embden-Meyerhof pathway, the citric acid cycle (including acetyl-CoA and free CoA), and the cytoplasmic and mitochondrial redox couples were determined in the rat 12, 24, and 48 h after food withdrawal and 5, 10, 20, 40, 60, and 120 min after the refeeding of glucose. Using the measured metabolite contents in the liver, the alterations in the concentration of malate, oxaloacetate, citrate, and α-ketoglutarate and the changes in the energy state of the adenine nucleotide system and the redox state of the NAD system were attributed to the cytoplasmic and mitochondrial compartments by applying established calculation methods. Glucose refeeding provoked significant alterations in all parameters investigated. These changes occurred within minutes, reversing the hormone and metabolite pattern which had developed within 24 h in response to food withdrawal. Particularly, glucose refeeding resulted in a drastic increase in the insulin/glucagon ratio. Simultaneously, the level of serum FFA and the concentration of LCA in the liver declined. The latter alteration was accompanied by an increase in the cytoplasmic and a decrease in the mitochondrial $\text{ATP}\text{ADP}\text{×}\text{P}$ ratios. Moreover, the redox state of the cytoplasmic NAD system was shifted toward the oxidized state. When the appropriate data were plotted against each other, highly significant correlations were obtained (i) between the insulin/glucagon ratio and the serum FFA concentration, (ii) between the serum FFA concentration and the concentration of hepatic LCA, (iii) between the hepatic LCA concentration and the cytoplasmic energy state, and (iv) between the cytoplasmic energy state and the redox state of the cytoplasmic NAD system. These findings are interpreted to support the hypothesis derived from experiments carried out in vitro that the insulin/glucagon ratio via the FFA-dependent concentration of hepatic LCA might affect the translocation of adenine nucleotides between the cytoplasmic and the mitochondrial compartment, thereby regulating the cytoplasmic energy state and the redox state of the cytoplasmic NAD system, consequently. Glucose refeeding provoked rapid coordinate changes in the concentration of the intermediates of both the citric acid cycle and the Embden-Meyerhof chain, indicating the altered substrate flow through these pathways. Those metabolites, known to modulate the activity of key regulatory enzymes in vitro, were analyzed with respect to their suggested regulatory function. As to the established shift from pyruvate carboxylation to pyruvate decarboxylation after glucose refeeding, the data revealed that the decrease in pyruvate carboxylase activity can be attributed to the decrease in the intramitochondrial $\text{ATP}\text{ADP}$ ratio and the simultaneous fall in acetyl-CoA concentration, while the coordinate increase in pyruvate dehydrogenase activity can be ascribed to the decline in the concentration of LCA and, consequently, in the ratios of $\text{ATP}\text{ADP}$, $\text{NADH}\text{NAD}$, and acetyl-$\text{CoA}\text{CoA}$ within the mitochondria. As for the citric acid cycle, increased citrate synthesis from acetyl-CoA and oxaloacetate was supported by the rapid drop in the concentration of the established inhibitor of citrate synthesis, LCA. In contrast, the concentration of succinyl-CoA, an inhibitor of the enzyme in vitro, remained practically constant, questioning its regulatory function under the present experimental conditions. In addition to the activation of citrate synthase, the coordinate activation of isocitrate dehydrogenase was indicated by the LCA-mediated decline in both the mitochondrial $\text{ATP}\text{ADP}$ and the $\text{NADH}\text{NAD}$ ratios. Glucose refeeding immediately reduced urea excretion to basal values. This alteration was preceded by a drastic fall in the tissue concentration of cyclic AMP, supporting the physiological role of the nucleotide in the control of hepatic gluconeogenesis. In contrast, the observed changes in the concentration of the effectory acting metabolites (ATP, AMP, fructose 1,6-diphosphate, citrate, and alanine) were incompatible with the suggested function of these intermediates in switching over the substrate flow through the Embden-Meyerhof pathway from gluconeogenesis to glycolysis. The results are discussed in reference to the known rapid stimulation of fatty acid biosynthesis in the liver and to the transfer of reducing equivalents by the different shuttles of the inner mitochondrial membrane. In summary, it can be concluded that the insulin/glucagon ratio in a moment-to-moment fashion controls the glucose balance across the liver by regulating hepatic intermediary metabolism via the concentration of both LCA and cyclic AMP.     

In vivo nuclear magnetic resonance studies on the lugworm Arenicola marina. I. Free inorganic phosphate and free adenylmonophosphate concentrations in the body wall and their dependence on hypoxia

The cytoplasmic concentrations of free inorganic phosphate and free AMP in the body wall of the lugworm Arenicola marina were estimated in order to verify their proposed regulatory role in glycogenolysis during anaerobiosis (Kamp 1993). Using in vivo ³¹P nuclear magnetic resonance spectroscopy the concentration of free inorganic phosphate was determined to be 4.7±0.7 mmol·1^-1 (±standard deviation, n=3) varying with season (Juretschke and Kamp 1995). These values were two to three times lower than those measured in perchloric acid extracts. In contrast, values for the phosphagen phosphotaurocyamine assessed biochemically in the extracts and by in vivo nuclear magnetic resonance were very similar. During the transition from normoxia to hypoxia the concentration of free inorganic phosphate increased to the same extent and at the same rate as the concentration of phosphotaurocyamine decreased. A discrepancy was also found for the biochemically determined AMP and ADP concentrations in the extract and those derived from the equilibrium constants of the taurocyamine kinase (ADP_free) and adenylate kinase (AMP_free) reactions. Calculated concentrations of ADP_free and AMP_free in normoxic specimens were about two or even four orders of magnitude lower than the values determined in extracts. During hypoxia the concentrations of AMP and ADP increase moderately when measured biochemically in extracts, while the values for ADP_free and AMP_free rise three- and nine-fold during the first 3 h of hypoxia. Thereafter, the levels stay constant due to a progressive acidosis. If during hypoxia pH_i is stabilized by addition of buffering substances to the incubation medium, both ADP_free and AMP_free rise continuously. The significant changes found for the concentrations of free inorganic phosphate and AMP_free support their assumed regulatory role in glycogenolysis during anaerobiosis, though these AMP_free values seem too low to actually activate glycogen phosphorylase. The strong effect of pH_i on the levels of ADP_free and AMP_free suggest a mechanism by which acidosis prevents a continuing increase of glycogenolysis (ATP-producing pathway) during prolonged anaerobiosis (protective effect of acidosis).Abbreviations ADP _free cytoplasmic adenosine diphosphate - AK adenylate kinase - AMP _free cytoplasmic adenosine monophosphate - CK creatine kinase - GPase glycogen phosphorylase - MW molecular weight - Int P _i integral of P_i-signal - NMR nuclear magnetic resonance - P _i-free cytoplasmic inorganic phosphate - PCA perchlori acid - PFK 6-phosphofructokinase - PME phosphomonoester - PPA phenylphosphonic acid - (P)Tc (phospho)taurocyamine - S _f saturation factor - Sw sea water - TcK taurocyamine kinase - TRA triethanolamine - TRIS tris(hydroxymethyl)aminomethane     

Light scattering,chlorophyll fluorescence and state of the adenylate system in illuminated spinach leaves

Scattering of green light and chlorophyll fluorescence by spinach leaves kept in a stream of air or nitrogen were compared with leaf adenylate levels during illumination with blue, red or far-red light. Energy charge and ATP-ADP ratios exhibited considerable variability in different leaves both in the dark and in the light. Variability is explained by different possible states of the reaction oxidizing triose phosphate or reducing 3-phosphoglycerate. Except when oxygen levels were low, there was an inverse relationship between light scattering and chlorophyll fluorescence during illumination with blue or red light. When CO₂ was added to a stream of CO₂-free air, chlorophyll fluorescence increased, sometimes after a transient decrease, and both light scattering and leaf $\text{ATP}\text{ADP}$ ratios decreased. Similar observations were made when air was replaced by nitrogen under blue or high-intensity red light. Under these conditions, over-reduction caused inhibition of electron transport and phosphorylation in chloroplasts. However, when air was replaced by nitrogen during illumination with low-intensity red light or far-red light, light scattering increased instead of decreasing. Under these light conditions, $\text{ATP}\text{ADP}$ ratios were maintained in the light. They decreased drastically only after darkening. Although $\text{ATP}\text{ADP}$ ratios responded faster than light scattering or the slow secondary decline of chlorophyll fluorescence due to illumination, it appeared that in the steady state, light scattering and chlorophyll fluorescence are useful indicators of the phosphorylation state of the leaf adenylate system at least under aerobic conditions, when chloroplast and extrachloroplast adenylate systems can effectively communicate.