Thermodynamics of oxidative phosphorylation in bovine heart submitochondrial particles.

The rates of both forward and reverse electron transfer in phosphorylating submitochondrial particles from bovine heart can be controlled by the thermodynamic phosphorylation potential (deltaGp) of the adenine nucleotide system. deltaGp is the Gibbs free energy of ATP synthesis and is defined by the relationship deltaGp = -deltaG'o + RTln([ATP]/[ADP][Pi]) where deltaG'o is the standard free energy of ATP hydrolysis. Studies of the effects of deltaGp on NADH respiration and the reduction of NAD+ by succinate show that increasing values of deltaGp cause an inhibition of forward electron transfer and a stimulation of reverse electron transfer. Between deltaGp values of 7.6 and 13.0 kcal/mol the rate of NADH respiration decreased 3-fold and the rate of NAD+ reduction by succinate increased 3-fold. Indirect phosphorylation potential titration experiments as well as direct chemical measurements indicate that steady state levels of ATP, ADP, and Pi are established during NADH respiration which correspond to a deltaGp equal to 10.7 to 11.4 kcal/mol.     

Thermodynamics of the slow–fast transition in bacteriophage T2L

We have measured the thermodynamic parameters of the slow-fast tail-fiber reorientation transition on T2L bateriophage. Proportions of the virus in each form were determined from peak-height measurements in sedimention-velocity runs and from average diffusion coefficients obtained by quasielastic laser light scattering. Computer simulation of sedimentation confirmed that there were no undetected intermediates in the transition, which was analyzed as a two-state process. Van't Hoff-type plots of the apparent equilibrium constant and of the pH midpoint of the transition as function of reciprocal temperature led to the following estimates of the thermodynamic parameters for the transition at pH 6.0 and 20°C: ΔH° = ?139 ± 18Kcal mol^?1, ΔS° = ?247 ± 46 cal K^?1 mol^?1, and ΔG° = ?66 ± 22 kcal mol^?1. Per mole of protons taken up in the transition, the analogous quantities were ?15.9 ± 1.7 kcal mol^?1, ?26.3 ± 2.2 cal K^?1 mol^?1, and ?8.22 ± 1.8 kcal mol^?1. The net number of protons taken up was about 8.5 ± 1.5. The large values of the thermodynamic functions are consistent with a highly cooperative reaction and with multiple interactions between the fibres and the remainder of the phage. The negative entropy of the transition is probably due to immobilization of the fibres.     

Kinetic properties of arginine phosphokinase from honeybees, Apis mellifera L. (Hymenoptera, Apidae)

The kinetic properties of honeybee arginine phosphokinase (APK), which catalyzes the reaction: Arginine phosphate + ADP + H⁺ ? arginine + ATP, have been studied.In the direction of ATP synthesis, the pH optimum was around pH 7.2 and the activation energy over the range 18–44 °C was about 10,500 cal/mole. The optimum ratio of Mg²⁺:ADP was about 4:1.In the direction of arginine phosphate (AP) synthesis, the enzyme had a pH optimum around pH 8.3. The energy of activation for the reaction over the range 22–39 °C was about 7500 cal/mole. The optimum ratio of Mg²⁺:ATP was about 1:1.The initial velocities of the reactions in the direction of ATP and AP synthesis were measured at varying concentrations of one substrate while the concentration of the other substrate was held constant at several levels. The double reciprocal plots of the data obtained yielded a series of intersecting lines, indicating that the enzyme has a sequential mechanism. Radioisotope exchange experiment showed that arginine phosphokinase did not catalyze ATP ? ADP exchange in the absence of arginine. Product inhibition studies showed that arginine was competitive with AP and noncompetitive with ADP; whereas ATP was competitive with ADP and noncompetitive with arginine. The results from initial velocity, radioisotope exchange, and product inhibition studies suggested that the enzyme has a rapid equilibrium, random mechanism.     

Thermodynamics of the electrochemical proton gradient in bovine heart submitochondrial particles.

The electrical and chemical components of the electrochemical proton gradient of submitochondrial particles can be monitored simultaneously by continuously recording optical signals from the probes oxonol-VI and 9-aminoacridine. Either respiration or ATP hydrolysis causes a red shift in the absorption spectrum of oxonol-VI indicative of a membrane potential and a decrease of the fluorescence of 9-aminoacridine indicative of a pH gradient. The magnitude of the membrane potential and pH gradient formed by respiring submitochondrial particles can be modulated by the thermodynamic phosphorylation potential (deltaGp) of the adenine nucleotide system. deltaGp is the Gibbs free energy of ATP synthesis and is defined by the relationship deltaGp = -deltaG'o + RTln([ATP]/[ADP][Pi] where deltaG'o is the standard free energy of ATP hydrolysis. Increasing values of deltaGp cause an increase in the steady state magnitudes of both the membrane potential and pH gradient. Thermodynamic phosphorylation potential titration experiments indicate that the electrochemical proton gradient normally maintained by respiring submitochondrial particles has an energy equivalent to 10.5 to 10.9 kcal/mol.     

Control of cellular redox potential as measured in a steady-state, cell-free system

A cell-free system consisting of rat liver mitochondria, liver cytosol, lactate, and the substrates intrinsic to the malate-aspartate shuttle was reconstituted for studies of steady-state substrate fluxes and, more specifically, to evaluate further the mechanism of control of the intra- and extramitochondrial steady states of the free NAD+/NADH ratios. Soluble (F1) ATPase or 2,4-dinitrophenol (DNP) were added in varying amounts to alter substrate fluxes and the constant energy state of this 'open' metabolizing system. The steady-state redox segregation (1.36 log NAD+/NADH ratio out vs NAD+/NADH in the mitochondrial matrix) was maximally about 3 kcal, and declined together with the membrane potential (delta psi) and log ATP/ADP, which obtain on imposing an increasing energy load on the system. It is concluded that transmembrane movement of reducing equivalents is coupled to electron transfer through delta psi, mediated by the electrogenic exchange of glutamate and aspartate. When delta psi was high (near State 4), delta G redox was approximately the same as that generated without flux of reducing equivalents [E. J. Davis, J. Bremer, and K. E. Akerman (1980) J. Biol. Chem. 255, 2277-2283], suggesting that delta Gredox is in near thermodynamic equilibrium with delta psi. If the steady-state ATP/ADP ratio was altered with an energy load (F1-ATPase), delta Gredox decreased more steeply than delta psi (tetraphenyl phosphonium-sensitive electrode used to measure delta psi). At comparable ranges of ATP/ADP, both delta Gredox and delta psi decreased more steeply with uncoupler than with an external ADP-regenerating system.     

Integrated thermodynamic analysis of electron bifurcating [FeFe]-hydrogenase to inform anaerobic metabolism and H2 production

Electron bifurcating, [FeFe]-hydrogenases are recently described members of the hydrogenase family and catalyze a combination of exergonic and endergonic electron exchanges between three carriers (2 ferredoxin_red⁻ + NAD(P)H + 3 H⁺ = 2 ferredoxin_ox + NAD(P)⁺ + 2 H₂). A thermodynamic analysis of the bifurcating, [FeFe]-hydrogenase reaction, using electron path-independent variables, quantified potential biological roles of the reaction without requiring enzyme details. The bifurcating [FeFe]-hydrogenase reaction, like all bifurcating reactions, can be written as a sum of two non-bifurcating reactions. Therefore, the thermodynamic properties of the bifurcating reaction can never exceed the properties of the individual, non-bifurcating, reactions. The bifurcating [FeFe]-hydrogenase reaction has three competitive properties: 1) enabling NAD(P)H-driven proton reduction at pH₂ higher than the concurrent operation of the two, non-bifurcating reactions, 2) oxidation of NAD(P)H and ferredoxin simultaneously in a 1:1 ratio, both are produced during typical glucose fermentations, and 3) enhanced energy conservation (~10 kJ mol⁻¹ H₂) relative to concurrent operation of the two, non-bifurcating reactions. Our analysis demonstrated ferredoxin E°′ largely determines the sensitivity of the bifurcating reaction to pH₂, modulation of the reduced/oxidized electron carrier ratios contributed less to equilibria shifts. Hydrogenase thermodynamics data were integrated with typical and non-typical glycolysis pathways to evaluate achieving the ‘Thauer limit’ (4 H₂ per glucose) as a function of temperature and pH₂. For instance, the bifurcating [FeFe]-hydrogenase reaction permits the Thauer limit at 60 °C if pH ₂ ≤ ~10 mbar. The results also predict Archaea, expressing a non-typical glycolysis pathway, would not benefit from a bifurcating [FeFe]-hydrogenase reaction; interestingly, no Archaea have been observed experimentally with a [FeFe]-hydrogenase enzyme.     

Identification of an unusual AT(D)Pase-like activity in multifunctional NAD glycohydrolase from the venom of Agkistrodon acutus

NAD-glycohydrolases (NADases) are ubiquitous enzymes that possess NAD glycohydrolase, ADPR cyclase or cADPR hydrolase activity. All these activities are attributed to the NADase-catalyzed cleavage of C-N glycosyl bond. AA-NADase purified from the venom of Agkistrodon acutus is different from the known NADases, for it consists of two chains linked with disulfide-bond(s) and contains one Cu(2+) ion. Here, we show that AA-NADase is not only able to cleave the C-N glycosyl bond of NAD to produce ADPR and nicotinamide, but also able to cleave the phosphoanhydride linkages of ATP, ADP and AMP-PNP to yield AMP. AA-NADase selectively cleaves the P-O-P bond of ATP, ADP and AMP-PNP without the cleavage of P-O-P bond of NAD. The hydrolysis reactions of NAD, ATP and ADP catalyzed by AA-NADase are mutually competitive. ATP is the excellent substrate for AA-NADase with the highest specificity constant k(cat)/K(m) of 293+/-7mM(-1)s(-1). AA-NADase catalyzes the hydrolysis of ATP to produce AMP with an intermediate ADP. AA-NADase binds with one AMP with high affinity determined by isothermal titration calorimetry (ITC). AMP is an efficient inhibitor against NAD. AA-NADase has so far been identified as the first unique multicatalytic enzyme with both NADase and AT(D)Pase-like activities.     

Similar affinities of ADP and ATP for G-actin at physiological salt concentrations

The equilibrium constant for the exchange of ATP and ADP at G-actin was determined by fluorimetric titration of G-actin-bound ε-ATP by ATP or ADP. The affinity of ATP for G-actin was found to be only about 3-fold higher than the affinity of ADP for G-actin at 37°C, pH 7.5 and physiologically relevant salt concentrations (100 mmol K⁺/l, 0.8 mmol Mg²⁺/l, <0.01 mmol Ca²⁺/l).     

Reconstitution and characterization of the adenine nucleotide transporter derived from bovine heart mitochondria.

1. Adenine nucleotide exchange-transport was reconstituted in vesicles prepared from phospholipids and protein fractions derived from bovine heart submitochondrial particles. The transport, which was specific for ATP and ADP was measured either as ADP/ADP, ATP/ATP, or ADP/ATP exchange. The highest specific activity (370 nanomoles of ADP/ADP exchange/min/mg of protein at room temperature) was obtained with a protein fraction prepared by cholate extraction of partly resolved submitochondrial particles followed by ammonium sulfate fractionation. 2. At 200 muM external nucleotide, the exchange reactions were inhibited by low concentrations of bongkrekate, atractyloside, and palmitoyl-CoA, with Ki values of 1.8, 3.0, and 7.5 muM, respectively. The ADP/ADP nucleotide exchange was stimulated about 5-fold by 500 muM MgCl2 or MnCl2(km of 40 muM) and about 3-fold by 500 muM CaCl2(Km of 90 muM). It was optimal between pH 6.0 and 7.0 and decreased rapidly above pH 7.5. Arrhenius plots between 0 degrees and 40 degrees showed a break point at 15 degrees with soybean phospholipids and an activation energy of 29.5 kcal/mole from 0 degrees-15 degrees and 9.0 kcal/mole from 15 degrees-40 degrees. With mitochondrial phospholipids the break point was at 9 degrees and activation energies were 42.4 kcal/mole from 0 degrees-9 degrees and 7.6 kcal/mole from 9 degrees-40 degrees. 3. The phospholipid requirements for adenine nucleotide exchange were similar to those of oxidative phosphorylation. Optimal rates were observed with a phosphatidylethanolamine to phosphatidylcholine ratio of 4:1. Cardiolipin had a slight stimulatory effect. 4. The uptake of ADP into vesicles containing ATP was stimulated by KCl or by KPi as well as by hexafluoracetonylacetone, and uncoupler of oxidative phosphorylation. The uptake of ATP into vesicles containing ADP was inhibited by KCl or by KPi, but was also stimulated by hexafluoracetonylacetone. In both cases valinomycin reversed the effects of KCl, while mersalyl or N-ethylmaleimide prevented the effects of KPi. In contrast, none of these salts nor hexafluoracetonylactone affected the ADP/ADP or ATP/ATP exchange. These findings suggest that in the reconstituted system the ADP/ATP exchange is electrogenic.     

Biochemical characterization and kinetic/thermodynamic study of Aspergillus tamarii URM4634 β-fructofuranosidase with transfructosylating activity

This study reports on the biochemical characterization as well as the kinetic and thermodynamic study of Aspergillus tamarii URM4634 β-fructofuranosidase (FFase) with transfructosylating activity. Conditions for FFase activity were optimized by means of a central composite rotational design using pH and temperature as the independent variables, while residual activity tests carried out in the temperature range of 45–65°C enabled us to investigate FFase thermostability and estimate the kinetic and thermodynamic parameters of enzyme denaturation. Optimal conditions for sucrose hydrolysis and fructosyl transfer catalyzed by crude FFase were 50°C, and pH 6.0 and 7.4, respectively. The thermodynamic properties of irreversible enzyme inactivation were found to be activation energy of 293.1 kJ mol⁻¹, and activation enthalpy, entropy, and Gibbs free energy in the ranges 290.3–290.4 kJ mol⁻¹, 568.7–571.0 J mol⁻¹ K⁻¹, and 97.9–108.8 kJ mol⁻¹, respectively. The results obtained in this study point out satisfactory enzyme activity and thermostability at temperatures commonly used for industrial fructo-oligosaccharide (FOS) synthesis; therefore, this novel FFase appears to be a promising biocatalyst with great potential for long-term FOS synthesis and invert sugar production. To the best of our knowledge, this is the first report on kinetic and thermodynamic parameters of an A. tamarii FFase.     

Thermodynamic Prediction of Glycine Polymerization as a Function of Temperature and pH Consistent with Experimentally Obtained Results

Prediction of the thermodynamic behaviors of biomolecules at high temperature and pressure is fundamental to understanding the role of hydrothermal systems in the origin and evolution of life on the primitive Earth. However, available thermodynamic dataset for amino acids, essential components for life, cannot represent experimentally observed polymerization behaviors of amino acids accurately under hydrothermal conditions. This report presents the thermodynamic data and the revised HKF parameters for the simplest amino acid “Gly” and its polymers (GlyGly, GlyGlyGly and DKP) based on experimental thermodynamic data from the literature. Values for the ionization states of Gly (Gly⁺ and Gly^?) and Gly peptides (GlyGly⁺, GlyGly^?, GlyGlyGly⁺, and GlyGlyGly^?) were also retrieved from reported experimental data by combining group additivity algorithms. The obtained dataset enables prediction of the polymerization behavior of Gly as a function of temperature and pH, consistent with experimentally obtained results in the literature. The revised thermodynamic data for zwitterionic Gly, GlyGly, and DKP were also used to estimate the energetics of amino acid polymerization into proteins. Results show that the Gibbs energy necessary to synthesize a mole of peptide bond is more than 10 kJ mol^?1 less than previously estimated over widely various temperatures (e.g., 28.3 kJ mol^?1 → 17.1 kJ mol^?1 at 25 °C and 1 bar). Protein synthesis under abiotic conditions might therefore be more feasible than earlier studies have shown.     

The phosphorylation potentials generated by respiring Ehrlich ascites tumor mitochondria

The extra- and intramitochondrial phosphorylation potentials (ΔG_p(out) and ΔG_p(in), respectively) generated by respiring Ehrlich ascites tumor mitochondria were determined, using succinate, pyruvate + malate, ascorbate + N,N,N′,N′-tetramethyl-p-phenylenediamine, and ascorbate + ferrocyanide as substrate systems. Values of ΔG_p(out) exceeding 15 kcal mol^?1 (62.8 kJ mol^?1) in post-ADP state 4 respiration were found with succinate as substrate, in agreement with data on normal rat liver mitochondria. ΔG_p(out) values exceeding 15 kcal mol^?1 (62.8 kJ mol^?1) were also observed with ascorbate + TMPD or ascorbate + ferrocyanide as substrates. Slightly lower values of ΔG_p(out) were found with the NAD-linked substrates pyruvate + malate. The intramitochondrial ΔG_p(in) developed by respiring Ehrlich ascites tumor mitochondria respiring on succinate approached 12 kcal mol^?1 (50.2 kJ mol^?1), in agreement with reported values on rat liver mitochondria. The prior accumulation of Ca²⁺ and phosphate by the Ehrlich cell mitochondria did not lower the extramitochondrial ΔG_p(out) developed after a subsequent addition of ADP. Although the rate of oxidative phosphorylation of Ehrlich ascites tumor cells is reduced by intramitochondrial Ca²⁺ and phosphate (Villalobo and Lehninger (1980) J. Biol. Chem., 255, 2457–2464) they are still capable of generating ATP in the suspending medium against a high thermodynamic gradient, as expressed by the [ATP]/[ADP][P_i]mass action ratio.     

Synthesis and hydrolysis of ATP and the phosphate-ATP exchange reaction in soluble mitochondrial F1 in the presence of dimethylsulfoxide.

In medium containing 40% dimethylsulfoxide, soluble F1 catalyzes the hydrolysis of ATP introduced at concentrations lower than that of the enzyme [Al-Shawi, M.K. & Senior, A.E. (1992), Biochemistry 31, 886-891]. At this concentration of dimethylsulfoxide, soluble F1 also catalyzes the spontaneous synthesis of a tightly bound ATP to a level of approximately 0.15 mol per mol F1 [Gómez-Puyou, A., Tuena de Gómez-Puyou, M. & de Meis, L. (1986) Eur. J. Biochem. 159, 133-140]. The mechanisms that allow soluble F1 to carry out these apparently opposing reactions were studied. The rate of hydrolysis of ATP bound to F1 under uni-site conditions and that of synthesis of ATP were markedly similar, indicating that the two ATP molecules lie in equivalent high affinity catalytic sites. The number of enzyme molecules that have ATP at the high affinity catalytic site under conditions of synthesis or uni-site hydrolysis is less than the total number of enzyme molecules. Therefore, it was hypothesized that when the enzyme was treated with dimethylsulfoxide, a fraction of the F1 population carried out synthesis and another hydrolysis. Indeed, measurements of the two reactions under identical conditions showed that different fractions of the F1 population carried out simultaneously synthesis and hydrolysis of ATP. The reactions continued until an equilibrium level between F1.ADP + Pi <--> F1.ATP was established. At equilibrium, about 15% of the enzyme population was in the form F1.ATP. The DeltaG degrees of the reaction with 0.54 microM F1, 2 mM Pi and 10 mM Mg2+ at pH 6.8 was -2.7 kcal.mol-1 in favor of F1.ATP. The DeltaG degrees of the reaction did not exhibit important variations with Pi concentration; thus, the reaction was in thermodynamic equilibrium. In contrast, DeltaG degrees became significantly less negative as the concentration of dimethylsulfoxide was decreased. In water, the reaction was far to the left. The equilibrium constant of the reaction diminished linearly with an increase in water activity. The effect of solvent is fully reversible. In comparison to other enzymes, F1 seems unique in that solvent controls the equilibrium that exists within an enzyme population. This results from the effect of solvent on the partition of Pi between the catalytic site and the medium, and the large energetic barrier that prevents release of ATP from the catalytic site. In the presence of dimethylsulfoxide and Pi, ATP is continuously hydrolyzed and synthesized with formation and uptake of Pi from the medium. This process is essentially an exchange reaction analogous to the phosphate-ATP exchange reaction that is catalyzed by the ATP synthase in coupled energy transducing membranes.     

Oxidative phosphorylation in pea cotyledon submitochondrial particles

Mitochondria and submitochondrial particles (SMP) from pea cotyledons were shown to catalyze oxidative phosphorylation as measured by ³²Pi uptake into phosphate esters. ATP synthesis was sensitive to the electron transport inhibitor KCN, the uncoupler carbonyl cyanide m-chlorophenylhydrazone, and the coupling factor inhibitor oligomycin. Experiments with the adenine nucleotide translocator inhibitor atractyloside indicated the SMP were inside-out. Mersalyl completely inhibited ATP synthesis by SMP, and a separate experiment indicated that mersalyl has a direct effect on the ATPase complex. The kinetics of ATP synthesis indicated a high affinity for phosphate (K_m = 0.18 millimolar). ADP kinetics gave a biphasic curve with K_m values of about 4.8 and 160 micromolar. O₂ uptake and ATP synthesis had a pH maximum of 7.6 while the ratio of micromoles phosphate esterified to microatoms O₂ taken up was highest at pH 7.2. Sodium chloride inhibited both ATP synthesis and O₂ uptake but stimulated the ATPase reaction. The SMP also catalyzed a slow ATP-phosphate exchange reaction.     

Glucose Deprivation Converts Poly(ADP-ribose) Polymerase-1 Hyperactivation into a Transient Energy-producing Process

Massive poly(ADP-ribose) formation by poly(ADP-ribose) polymerase-1 (PARP-1) triggers NAD depletion and cell death. These events have been invariantly related to cellular energy failure due to ATP shortage. The latter occurs because of both ATP consumption for NAD resynthesis and impairment of mitochondrial ATP formation caused by an increase of the AMP/ADP ratio. ATP depletion is therefore thought to be an inevitable consequence of NAD loss and a hallmark of PARP-1 activation. Here, we challenge this scenario by showing that PARP-1 hyperactivation in cells cultured in the absence of glucose (Glu⁻ cells) is followed by NAD depletion and an unexpected PARP-1 activity-dependent ATP increase. We found increased ADP content in resting Glu⁻ cells, a condition that counteracts the increase of the AMP/ADP ratio during hyperpoly(ADP-ribosyl)ation and preserves mitochondrial coupling. We also show that the increase of ATP in Glu⁻ cells is due to adenylate kinase activity, transforming AMP into ADP which, in turn, is converted into ATP by coupled mitochondria. Interestingly, PARP-1-dependent mitochondrial release of apoptosis-inducing factor (AIF) and cytochrome complex (Cyt c) is reduced in Glu⁻ cells, even though cell death eventually occurs. Overall, the present study identifies basal ADP content and adenylate kinase as key determinants of bioenergetics during PARP-1 hyperactivation and unequivocally demonstrates that ATP loss is not metabolically related to NAD depletion.     

Steady-state kinetics of formaldehyde dehydrogenase and formate dehydrogenase from a methanol-utilizing yeast, Candida boidinii.

Initial velocity studies and product inhibition studies were conducted for the forward and reverse reactions of formaldehyde dehydrogenase (formaldehyde: NAD oxidoreductase, EC 1.2.1.1) isolated from a methanol-utilizing yeast Candida boidinii. The data were consistent with an ordered Bi-Bi mechanism for this reaction in which NAD+ is bound first to the enzyme and NADH released last. Kinetic studies indicated that the nucleoside phosphates ATP, ADP and AMP are competitive inhibitors with respect to NAD and noncompetitive inhibitors with respect to S-hydroxymethylglutathione. The inhibitions of the enzyme activity by ATP and ADP are greater at pH 6.0 and 6.5 than at neutral or alkaline pH values. The kinetic studies of formate dehydrogenase (formate:NAD oxidoreductase, EC 1.2.1.2) from the methanol grown C. boidinii suggested also an ordered Bi-Bi mechanism with NAD being the first substrate and NADH the last product. Formate dehydrogenase the last enzyme of the dissimilatory pathway of the methanol metabolism is also inhibited by adenosine phosphates. Since the intracellular concentrations of NADH and ATP are in the range of the Ki values for formaldehyde dehydrogenase and formate dehydrogenase the activities of these main enzymes of the dissimilatory pathway of methanol metabolism in this yeast may be regulated by these compounds.     

The inhibition of isocitrate oxidation by palmitoyl-l-carnitine and palmitoyl-C0 A in rat liver mitochondria.

Palmitoyl-L carnitine decreases the oxidation of isocitrate in rat liver mitochondria in state 3 by 25-30%. Palmitoyl-L-carnitine acts as an additional substrate raising the rate of oxidative phosphorylation, NAD reduction and ATP/ADP ratio in mitochondria. Palmitoyl-CoA added to mitochondria oxidizing isocitrate in state 3 causes a strong inhibition of isocitrate oxidation and of oxidative phosphorylation and a considerable elevation of intramitochondrial NADH/NAD and ATP/ADP ratios. The effect of palmitoyl-CoA is dependent on its concentration and is competitive with ADP. Carnitine restores only oxidative phosphorylation, but the oxidation of isocitrate remains inhibited. Evidence is presented that the transport of isocitrate is not affected by palmitoyl-CoA is due to the inhibition of adenine nucleotide translocation. The kinetic studies of NAD-dependent isocitrate dehydrogenase in the soluble fraction of sonicated mitochondria revealed that the enzyme is very sensitive towards the inhibition by NADH and only very slightly affected by ATP (Ki for NADH and ATP are 0.017 and 3.6 mM respectively). On the basis of the kinetic data the relative contribution of NADH and ATP in the inhibition of isocitrate oxidation by fatty acids was calculated. It is concluded that the inhibition of isocitrate oxidation caused by palmitoyl-L-carnitine and palmitoyl-CoA is primarily due to the increased reduction of NAD, whereas the increase of ATP/ADP ratio is much less important.     

A thermodynamic analysis of the anaerobic oxidation of methane in marine sediments

Anaerobic oxidation of methane (AOM) in anoxic marine sediments is a significant process in the global methane cycle, yet little is known about the role of bulk composition, temperature and pressure on the overall energetics of this process. To better understand the biogeochemistry of AOM, we have calculated and compared the energetics of a number of candidate reactions that microorganisms catalyse during the anaerobic oxidation of methane in (i) a coastal lagoon (Cape Lookout Bight, USA), (ii) the deep Black Sea, and (iii) a deep-sea hydrothermal system (Guaymas basin, Gulf of California). Depending on the metabolic pathway and the environment considered, the amount of energy available to the microorganisms varies from 0 to 184 kJ mol(-1). At each site, the reactions in which methane is either oxidized to HCO3(-), acetate or formate are generally only favoured under a narrow range of pressure, temperature and solution composition--particularly under low (10(-10 )m) hydrogen concentrations. In contrast, the reactions involving sulfate reduction with H2, formate and acetate as electron donors are nearly always thermodynamically favoured. Furthermore, the energetics of ATP synthesis was quantified per mole of methane oxidized. Depending on depth, between 0.4 and 0.6 mol of ATP (mol CH4(-1) was produced in the Black Sea sediments. The largest potential productivity of 0.7 mol of ATP (mol CH4(-1) was calculated for Guaymas Basin, while the lowest values were predicted at Cape Lookout Bight. The approach used in this study leads to a better understanding of the environmental controls on the energetics of AOM.     

Regulation of the tyrosine oxidizing system in fetal rat liver

The formation of glucose 6-arsenate and glucose 6-phosphate shows similar thermodynamic constants: both reactions are endothermic, endergonic, and occur with a decrease of entropy. However, the kinetic coefficients of the spontaneous formation of the arsenate esters are ca. 10⁵ times greater than those of their homologous phosphate esters. The activation energy of the spontaneous formation of glucose 6-arsenate (E = + 12 kcal mol^?1) is even smaller than that of the formation of glucose 6-phosphate by alkaline phosphate (E = + 13 kcal mol^?1). Similar to the case of the monoalkylphosphates, the monoanion species of glucose 6-arsenate is much more reactive than the dianion species. This is an important difference with respect to glucose 6-phosphate. The calculated half-lives at 25 °C and pH 7.0 of glucose 6-arsenate and 6-arsenogluconate are only ca. 6 and 30 min, respectively; they increase at lower temperatures and alkaline pH. At 0 °C and pH 9.0 the half-life of glucose 6-arsenate is ca. 20 h. Therefore, arsenate esters could probably be isolated for use as a tool in biochemical studies. Arsenate esters are good analogs of the phosphate esters for a variety of enzymes. Glucose-6-phosphate dehydrogenase shows nearly similar values of K_m and V for either glucose 6-phosphate or glucose 6-arsenate, and hexokinase is similarly inhibited by both compounds. 6-Phosphogluconate dehydrogenase has the same V with respect to 6-phosphogluconate and 6-arsenogluconate although the enzyme shows a much lower affinity for the latter substrate.     

Cooperative binding of ATP and RNA substrates to the DEAD/H protein DbpA

Unlike most DEAD/H proteins, the purified Escherichia coli protein DbpA demonstrates high specificity for its 23S rRNA substrate in vitro. Here we describe several assays designed to characterize the interaction of DbpA with its RNA and ATP substrates. Electrophoretic mobility shift assays reveal a sub-nanomolar binding affinity for a 153 nucleotide RNA substrate (R153) derived from the 23S rRNA. High affinity RNA binding requires both hairpin 92 and helix 90, as substrates lacking these structures bind DbpA with lower affinity. AMPPNP inhibition assays and ATP/ADP binding assays provide binding constants for ATP and ADP to DbpA with and without RNA substrates. These data have been used to describe a minimal thermodynamic scheme for the binding of the RNA and ATP substrates to DbpA, which reveals cooperative binding between larger RNAs and ATP with cooperative energies of approximately 1.3 kcal mol(-1). This cooperativity is lost upon removal of helix 89 from R153, suggesting this helix is either the preferred target for DbpA's helicase activity or is a necessary structural element for organization of the target site within R153.