Temperature and the regulation of enzyme activity in poikilotherms. Properties of rainbow-trout fructose diphosphatase

1. The properties of fructose diphosphatase from the liver of rainbow trout (Salmo gairdnerii) were examined over the physiological temperature range of the organism. 2. Saturation curves for substrate (fructose 1,6-diphosphate) and a cofactor (Mg(2+)) are sigmoidal, and Hill plots of the results suggest a minimum of two interacting fructose 1,6-diphosphate sites and two interacting Mg(2+) sites per molecule of enzyme. 3. Mn(2+)-saturation curves are hyperbolic, and the K(a) for Mn(2+), which inhibits the enzyme at high concentrations, is 50-100-fold lower than the K(a) for Mg(2+). 4. Fructose diphosphatase is inhibited by low concentrations of AMP; this inhibition appears to be decreased and reversed by increasing the concentrations of Mg(2+) and Mn(2+). Higher concentrations of AMP are required to inhibit the trout fructose diphosphatase in the presence of Mn(2+). 5. The affinities of fructose diphosphatase for fructose diphosphate and Mn(2+) appear to be temperature-independent, whereas the affinities for Mg(2+) and AMP are highly temperature-dependent. 6. The pH optimum of the enzyme depends on the concentrations of Mg(2+) and Mn(2+). In addition, pH determines the K(a) for Mg(2+); at high pH, K(a) for Mg(2+) is lowered. 7. The enzyme is inhibited by Ca(2+) and Zn(2+), and the inhibition is competitive with respect to both cations. 8. The possible roles of these ions and AMP in the modulation of fructose diphosphatase and gluconeogenic activity are discussed in relation to temperature adaptation.     

Temperature and the regulation of enzyme activity in poikilotherms. Properties of lungfish fructose diphosphatase

1. The properties of fructose diphosphatase from liver of South American lungfish (Lepidosiren paradoxa) were examined. 2. Saturation curves for substrate (fructose diphosphate) and both cofactors (Mn(2+) and Mg(2+)) are sigmoidal and Hill plots of these results suggest about 2 interacting substrate and cofactor sites/molecule of enzyme. 3. Mn(2+) is an efficient positive modulator of the enzyme and K(a) for Mn(2+) is about 20-30-fold lower than the K(a) for Mg(2+). 4. Lungfish fructose diphosphatase is inhibited by low concentrations of AMP, and the affinity of the enzyme for AMP is insensitive to temperature. 5. The affinities of fructose diphosphatase for fructose diphosphate and Mn(2+) appear to be dependent on temperature, whereas affinity for Mg(2+) is temperature-independent. 6. The pH optimum of the enzyme depends on the presence of the particular cofactor. As pH increases, the K(a) values of both cations are lowered, maximum velocities are increased and the saturation curves for cofactor become hyperbolic. 7. The possible roles of these ions, pH and substrate in the modulation of fructose diphosphatase and gluconeogenic activity in the lungfish are discussed in relation to aestivation and temperature adaptation.     

Effect of Mn2+ on fructose 2,6-bisphosphate inhibition of mouse liver, intestinal, and muscle fructose-1,6-bisphosphatases

Fructose 2,6-bisphosphate inhibited all three fructose-1,6-bisphosphatases from the liver, intestine, and muscle of the mouse. The sensitivity of the liver enzyme to the inhibitor was significantly diminished when Mg2+ was replaced by Mn2+ as the activating cation. Inhibition of the liver enzyme by fructose 2,6-bisphosphate decreased as the concentration of the metal activator, Mn2+ or Mg2+, increased. The respective I50 values obtained by extrapolation of metal ion concentrations to zero were 40 microM with Mn2+ and 0.25 microM with Mg2+. The extent of desensitization to either fructose 2,6-bisphosphate or AMP inhibition by Mn2+ decreased in the order of the liver, intestine, and muscle enzyme. Only in the case of the liver enzyme was the substrate cooperativity induced by fructose 2,6-bisphosphate in the presence of Mg2+. In all three isoenzymes from the mouse, fructose 2,6-bisphosphate greatly potentiated the AMP inhibition of the enzyme in the presence of either Mg2+ or Mn2+. The liver enzyme with Mn2+ in addition to Mg2+ was still active in the presence of less than 1 microM fructose 2,6-bisphosphate, even though AMP was present at 100-200 microM.     

The functional significance of variants of fructose 1,6-diphosphatase in the gill and hypodermis of a marine crustacean. A kinetic study

1. In the hypodermis and gill of the Crustacea fructose 1,6-diphosphatase (EC 3.1.3.11) functions at a primary branch point between glycogen and chitin synthesis. In these tissues of the Arctic king-crab, Paralithodes camtchatica, fructose diphosphatase occurs in two electrophoretically distinguishable forms. 2. Fructose diphosphatase I (pI7.2-7.5) accounts for 70 and 10% of total fructose diphosphatase activity in the hypodermis and gill respectively, whereas fructose diphosphatase II (pI5.3) accounts for 30 and 90% of the total activity in the two tissues. Both forms display a neutral pH optimum, have an absolute requirement for a bivalent cation, and are potently inhibited by high concentrations of AMP and substrate. 3. Fructose 1,6-diphosphate saturation follows Michaelis-Menten kinetics for both fructose diphosphatases; the K(m) (fructose diphosphate) for fructose diphosphatase I is somewhat higher than for fructose diphosphatase II. In the presence of 50-200mm-K(+), the K(m) (fructose diphosphate) increases and at high concentrations of K(+) fructose diphosphate saturation follows sigmoidal kinetics. 4. UDP-N-acetylglucosamine and UDP-glucose at high concentrations specifically and potently inhibit fructose diphosphatase II, but do not significantly affect fructose diphosphatase I activity. 5. Low concentrations of UDP-N-acetylglucosamine activate fructose diphosphatase II by a decrease in the apparent K(m) (fructose diphosphate), but fructose diphosphatase I is again refractory to UDP-N-acetylglucosamine under these conditions. 6. In the presence of K(+) and UDP-N-acetylglucosamine, fructose diphosphatase II is able to compete for limiting fructose diphosphate about three times more effectively than is fructose diphosphatase I. 7. AMP inhibition of both forms of the enzyme is subject to three independent variables: (a) alkaline pH increases the K(i) (AMP), (b) K(+) decreases the K(i), increases the sigmoidicity of inhibition kinetics, increases the maximum inhibition attained, and abolishes the effect of pH on AMP inhibition, and (c) Mg(2+) strongly de-inhibits AMP-inhibited fructose diphosphatase. 8. It is postulated that the presence of two forms of fructose diphosphatase aids controlled channelling of carbon through the fructose diphosphatase ;bottleneck' either towards glycogen synthesis or chitin synthesis, but not towards both simultaneously.     

Some aspects of the kinetics of rat liver pyruvate carboxylase

1. The kinetics of rat liver pyruvate carboxylase were examined and the effect of various agents as activators or inhibitors determined. 2. Essentially similar results were obtained in comparisons of kinetics determined by a radioactivity method involving extracts of acetone-dried powders from whole livers and with a spectrophotometric assay using partially purified enzyme from the mitochondrial fraction. Activity per g of liver from fed or starved rats assayed under optimum substrate and activator conditions was 3 or 6 mumol of oxaloacetate formed/min at 30 degrees C, respectively. 3. The enzyme exhibited cold-lability and lost activity on standing, even in 1.5m-sucrose. 4. The K(m) towards pyruvate was about 0.33mm and towards bicarbonate 4.2mm. K(m) towards MgATP(2-) was 0.14mm. Mg(2+) ions activated the enzyme, in addition to their role in MgATP(2-) formation. From calculations of likely concentrations of free Mg(2+) in the assay medium a K(a) towards Mg(2+) of about 0.25mm was deduced. Mn(2+) also activated the enzyme as well as Mg(2+), but at much lower concentrations. It appeared to be inhibitory when concentrations of free Mn(2+) as low as 0.1mm were present. 5. Excess of ATP is inhibitory, and this appears at least in part independent of the trapping of Mg(2+). 6. Both Co(2+) and Zn(2+) were inhibitory; 2mol of the latter appeared to be bound even in the presence of excess of Mg(2+) and the inhibition was time-dependent. 7. Ca(2+) inhibited by competition with Mg(2+) (K(i) about 0.38mm). The inhibition due to Ca(2+) was less pronounced when activation was with Mn(2+). Inhibition by Ca(2+) and ATP appeared to be additive. 8. Hill plots suggested that no interactions occurred between ATP-binding sites. Although similar plots for total Mg(2+) gave n=3.6, no conclusions could be drawn due to the chelation of the cation with other components of the assay. Similar difficulties arose in assessing the values for Ca(2+). 9. The enzyme was inactive in the absence of acetyl-CoA and showed a sigmoidal response in its presence. K(a) was about 0.1mm with possibly up to four binding sites. Malonyl-CoA was a competitive inhibitor, with K(i) 0.01mm. 10. There was no apparent inhibition by glucose, glucose 6-phosphate, fructose 6-phosphate, fructose 1,6-diphosphate, acetoacetate, beta-hydroxybutyrate, malate, aspartate, pyruvate, palmitoylcarnitine, octanoate, glutathione, butacaine, triethyltin or potassium chloride under the conditions used. Inhibition was found with citrate (possibly by chelation) and adenosine, and also by phosphoenolpyruvate, AMP, ADP and cyclic AMP, K(i) towards the last four being 0.55, 0.76, 0.25 and 1.4mm respectively.     

The activities of fructose diphosphatase in flight muscles from the bumble-bee and role of this enzyme in heat generation

1. The maximum catalytic activities of fructose diphosphatase from flight muscles of bumble-bees (Bombus spp.) are at least 30-fold those reported for the enzyme from other tissues. The maximum activity of fructose diphosphatase in the flight muscle of any particular bee is similar to that of phosphofructokinase in the same muscle, and the activity of hexokinase is similar to or greater than the activity of phosphofructokinase. There is no detectable activity of glucose 6-phosphatase and only a very low activity of glucose 6-phosphate dehydrogenase in these muscles. The activities of both fructose diphosphatase and phosphofructokinase vary inversely with the body weight of the bee, whereas that of hexokinase is relatively constant. 2. There is no significant hydrolysis of fructose 1-phosphate, fructose 6-phosphate, glucose 1,6-diphosphate and glycerol 3-phosphate by extracts of bumble-bee flight muscle. 3. Fructose 1,6-diphosphatase from bumble-bee flight muscle and from other muscles is inhibited by Mn(2+) and univalent cations; the potency of inhibition by the latter varies in the order Li(+)>Na(+)>K(+). However, the fructose diphosphatase from bumble-bee flight muscle is different from the enzyme from other tissues in that it is not inhibited by AMP. 4. The contents of ATP, hexose monophosphates, fructose diphosphate and triose phosphates in bumble-bee flight muscle showed no significant changes between rest and flight. 5. It is proposed that both fructose diphosphatase and phosphofructokinase are simultaneously active and catalyse a cycle between fructose 6-phosphate and fructose diphosphate in resting bumble-bee flight muscle. Such a cycle would produce continuous hydrolysis of ATP, with the release of energy as heat, which would help to maintain the thoracic temperature during rest periods at a level adequate for flight.     

Temperature and the regulation of enzyme activity in poikilotherms. Regulatory properties of fructose diphosphatase from muscle of the Alaskan king-crab

1. The properties of fructose diphosphatase from skeletal muscle of the Alaskan king-crab (Paralithodes camtschatica) were examined over the physiological temperature range of the animal. 2. King-crab muscle fructose diphosphatase is first activated by Na(+) and NH(4) (+) and is then partially inhibited by these cations at concentrations higher than 10mm at 0 degrees , 8 degrees and 15 degrees C. Enzyme activity is stimulated by K(+) at 0 degrees C, but is curtailed at 8 degrees C and 15 degrees C, an effect that could render rate independent of temperature. 3. Affinity for substrate increases with decreasing temperature; below the temperature of acclimatization, K(m) for fructose 1,6-diphosphate increases, resulting in a complex U-shaped temperature-K(m) curve. 4. King-crab muscle fructose diphosphatase is inhibited by low concentrations of AMP. As with enzymes of other poikilotherms, inhibition by AMP is sensitive to temperature; the enzyme is least sensitive to inhibition by AMP near the temperature of acclimatization. 5. The affinity of fructose diphosphatase for fructose 1,6-diphosphate is enhanced by phosphoenolpyruvate, and this activation is temperature-sensitive; 0.5mm-phosphoenolpyruvate causes a sevenfold decrease in K(m) for fructose 1,6-diphosphate at 15 degrees C but a 25-fold decrease at 0 degrees C. 6. Phosphoenolpyruvate appears to decrease the affinity of king-crab muscle fructose diphosphatase for AMP at low temperature, whereas at the higher temperature it appears to enhance inhibition by AMP. Phosphoenolpyruvate was not observed to cause a reversal of inhibition of fructose diphosphatase activity by AMP. The identification of phosphoenolpyruvate as an activator of a rate-limiting step in gluconeogenesis permits the suggestion of a coupling of the controlling mechanisms of several steps in the glycolytic and gluconeogenic chains. 7. These findings suggest mechanisms for the maintenance and regulation of control of fructose diphosphatase activity in king-crab skeletal muscle at low temperature and under conditions that favour concomitant activity of phosphofructokinase.     

Comparative enzymatic properties of avian liver and skeletal muscle D-fructose-1,6-bisphosphate 1-phosphohydrolase.

The enzymatic properties of purified preparations of chicken liver and chicken skeletal muscle fructose bisphosphatases (D-fructose-1,6-bisphosphate 1-phosphohydrolase, EC 3.1.3.11) were compared. Both enzymes have an absolute requirement for Mg2+ or Mn2+. The apparent Km for MgCl2 at pH 7.5 was 0.5 mM for the muscle enzyme and 5 mM for the liver enzyme. Fructose bisphosphate inhibited both enzymes. At pH 7.5, the inhibitor constants (Ki) were 0.18 and 1.3 mM for muscle and liver fructose bisphosphatases, respectively. The muscle enzyme was considerably more sensitive to AMP inhibition than the liver enzyme. At pH 7.5 and in the presence of 1 mM MgCl2, 50% inhibition of muscle and liver fructose bisphosphatases occurred at AMP concentrations of 7 X 10(-9) and 1 X 10(-6) M, respectively. EDTA activated both enzymes. The degree of activation was time and concentration dependent. The degree of EDTA activation of both enzymes decreased with increasing MgCl2 concentration. Ca2+ was a potent inhibitor of both liver (Ki, 1 X 10(-4) M) and muscle (Ki, 1 X 10(-5) M) fructose bisphosphatase. This inhibition was reversed by the presence of EDTA. Ca2+ appears to be a competitive inhibitor with regard to Mg2+. There is, however, a positive homeotropic interaction among Mg2+ sites of both enzymes in the presence of Ca2+.     

Evolutionary conserved N-terminal region of human muscle fructose 1,6-bisphosphatase regulates its activity and the interaction with aldolase

N-terminal residues of muscle fructose 1,6-bisphosphatase (FBPase) are highly conserved among vertebrates. In this article, we present evidence that the conservation is responsible for the unique properties of the muscle FBPase isozyme: high sensitivity to AMP and Ca(2+) inhibition and the high affinity to muscle aldolase, which is a factor desensitizing muscle FBPase toward AMP and Ca(2+). The first N-terminal residue affecting the affinity of muscle FBPase to aldolase is arginine 3. On the other hand, the first residue significantly influencing the kinetics of muscle FBPase is proline 5. Truncation from 5-7 N-terminal residues of the enzyme not only decreases its affinity to aldolase but also reduces its k-(cat) and activation by Mg(2+), and desensitizes FBPase to inhibition by AMP and calcium ions. Deletion of the first 10 amino acids of muscle FBPase abolishes cooperativity of Mg(2+) activation and results in biphasic inhibition of the enzyme by AMP. Moreover, this truncation lowers affinity of muscle FBPase to aldolase about 14 times, making it resemble the liver isozyme. We suggest that the existence of highly AMP-sensitive muscle-like FBPase, activity of which is regulated by metabolite-dependent interaction with aldolase enables the precise regulation of muscle energy expenditures and might contributed to the evolutionary success of vertebrates.     

Experimental conditions affecting ribonucleic acid polymerase in isolated rat liver nuclei. Effect of nucleoside triphosphate concentration, temperature, ammonium sulphate and heparin

1. The conditions affecting the activity of RNA polymerase in isolated rat liver nuclei were studied with Mg(2+) or Mn(2+) as activating ions. 2. The enzyme assayed with Mg(2+) and at low ionic strength is saturated by a lower concentration of nucleotide substrates than if assayed with Mn(2+) at low ionic strength or with either ion at high ionic strength. 3. At low and at high ionic strength the incorporation of AMP is affected in a similar way by variations in the temperature of incubation. Preincubation at 37 degrees impairs the AMP incorporation. 4. Heparin stimulates the RNA polymerase activity in the presence of Mn(2+). 5. Both ammonium sulphate and heparin ;restart' the reaction if added after 15min., the effect being more marked with ammonium sulphate than with heparin, and also more marked in the presence of Mn(2+) than of Mg(2+). 6. alpha-Amanitin abolishes the effect of ammonium sulphate and of heparin.     

Effect of metal ions on the activity of green crab (Scylla serrata) alkaline phosphatase

Green crab (Scylla serrata) alkaline phosphatase (EC 3.1.3.1) is a metalloenzyme, which catalyzes the nonspecific hydrolysis of phosphate monoesters. The present paper deals with the study of the effect of some kinds of metal ions on the enzyme. The positive monovalent alkali metal ions (Li(+), Na(+) and K(+)) have no effect on the enzyme; positive bivalent alkaline-earth metal ions (Mg(2+), Ca(2+) and Ba(2+)) and transition metal ions (Mn(2+), Co(2+), Ni(2+) and Cd(2+)) activate the enzyme; heavy metal ions (Hg(2+), Ag(+), Bi(2+), Cu(2+) and Zn(2+)) inhibit the enzyme. The activation of magnesium ion on the enzyme appears to be a partial noncompetitive type. The kinetic model has been set up and a new plot to determine the activation constant of Mg(2+) was put forward. From the plot, we can easily determine the activation constant (K(a)) value and the activation ratio of Mg(2+) on the enzyme. The inhibition effects of Cu(2+) and Hg(2+) on the enzyme are of noncompetitive type. The inhibition constants have been determined. The inhibition effect of Hg(2+) is stronger than that of Cu(2+).     

Effects of added adenine nucleotides on renal carbohydrate metabolism

1. The regulatory effects that adenine nucleotides are known to exert on enzymes of glycolysis and gluconeogenesis were demonstrated to operate in kidney-cortex slices and in the isolated perfused rat kidney by the addition of exogenous ATP, ADP and AMP to the incubation or perfusion media. 2. Both preparations rapidly converted added ATP into ADP and AMP, and ADP into AMP; added AMP was rapidly dephosphorylated. AMP formed from ATP was dephosphorylated at a lower rate than was added AMP, especially when the initial ATP concentration was high (10mm). Deamination of added AMP occurred more slowly than dephosphorylation of AMP. 3. Gluconeogenesis from lactate or propionate by rat kidney-cortex slices, and from lactate by the isolated perfused rat kidney, was inhibited by the addition of adenine nucleotides to the incubation or perfusion media. In contrast, oxygen consumption and the utilization of propionate or lactate by slices were not significantly affected by added ATP or AMP. 4. The extent and rapidity of onset of the inhibition of renal gluconeogenesis were proportional to the AMP concentration in the medium and the tissue, and were not due to the production of acid or P(i) or the formation of complexes with Mg(2+) ions. 5. Glucose uptake by kidney-cortex slices was stimulated 30-50% by added ATP, but the extra glucose removed was not oxidized to carbon dioxide and did not all appear as lactate. Glucose uptake, but not lactate production, by the isolated perfused kidney was also stimulated by the addition of ATP or AMP. 6. In the presence of either glucose or lactate, ATP and AMP greatly increased the concentrations of C(3) phosphorylated intermediates and fructose 1,6-diphosphate in the kidney. There was a simultaneous rise in the concentration of malate and fall in the concentration of alpha-oxoglutarate. 7. The effects of added adenine nucleotides on renal carbohydrate metabolism seem to be mainly due to an increased concentration of intracellular AMP, which inhibits fructose diphosphatase and deinhibits phosphofructokinase. This conclusion is supported by the accumulation of intermediates of the glycolytic pathway between fructose diphosphate and pyruvate. 8. ATP or ADP (10mm) added to the medium perfusing an isolated rat kidney temporarily increased the renal vascular resistance, greatly diminishing the flow rate of perfusion medium for a period of several minutes.     

Magnesium dependence of the measured equilibrium constants of aminoacyl-tRNA synthetases

The apparent equilibrium constants (K') for six reactions catalyzed by aminoacyl-tRNA synthetases from Escherichia coli were measured, the equations for the magnesium dependence of the equilibrium constants were derived, and best-fit analyses between the measured and calculated values were used. The K' values at 1 mM Mg(2+) ranged from 0.49 to 1.13. The apparent equilibrium constants increased with increasing Mg(2+) concentrations. The values were 2-3 times higher at 20 mM Mg(2+) than at 1 mM Mg(2+), and the dependence was similar in the class I and class II synthetases. The main reason for the Mg(2+) dependence is the existence of PP(i) as two magnesium complexes, but only one of them is the real product. AMP exists either as free AMP or as MgAMP, and therefore also has some effect on the measured equilibrium constant. However, these dependences alone cannot explain the measured results. The measured dependence of the K' on the Mg(2+) concentration is weaker than that caused by PP(i) and AMP. Different bindings of the Mg(2+) ions to the substrate tRNA and product aminoacyl-tRNA can explain this observation. The best-fit analysis suggests that tRNA reacts as a magnesium complex in the forward aminoacylation direction but this given Mg(2+) ion is not bound to aminoacyl-tRNA at the start of the reverse reaction. Thus Mg(2+) ions seem to have an active catalytic role, not only in the activation of the amino acid, but in the posttransfer steps of the aminoacyl-tRNA synthetase reaction, too.     

The roles of magnesium ions in the reaction catalysed by phosphofructokinase from Trypanosoma brucei.

The involvement of Mg2+ ions in the reaction catalysed by phosphofructokinase from Trypanosoma brucei was studied. The true substrate for the enzyme was shown to be the MgATP2-complex, and free Mg2+ ions are also required for enzyme activity. At concentrations of MgATP2- of 2.92 mM and greater, and a fructose 6-phosphate concentration of 1 mM and in the presence of EDTA as a Mg2+ buffer, the Km value for Mg2+ was determined to be 294 +/- 18 microM. Neither MgATP nor free ATP is an inhibitor of the enzyme, although apparent inhibition by the latter can be observed as a consequence of the decrease in free Mg2+ by chelation.     

Interaction between muscle aldolase and muscle fructose 1,6-bisphosphatase results in the substrate channeling

Fructose 1,6-bisphosphatase (FBPase) is known to form a supramolecular complex with alpha-actinin and aldolase on both sides of the Z-line in skeletal muscle cells. It has been proposed that association of aldolase with FBPase not only desensitizes muscle FBPase toward AMP inhibition but it also might enable the channeling of intermediates between the enzymes [Rakus et al. (2003) FEBS Lett. 547, 11-14]. In the present paper, we tested the possibility of fructose 1,6-bisphosphate (F1,6-P(2)) channeling between aldolase and FBPase using the approach in which an inactive form of FBPase competed with active FBPase for binding to aldolase and thus decreased the rate of aldolase-FBPase reaction. The results showed that F1,6-P(2) is transferred directly from aldolase to FBPase without mixing with the bulk phase. Further evidence that F1,6-P(2) is channeled from aldolase to FBPase comes from the experiments investigating the inhibitory effect of a high concentration of magnesium ions on aldolase-FBPase activity. FBPase in a complex with aldolase, contrary to free muscle FBPase, was not inhibited by high Mg(2+) concentrations, which suggests that free F1,6-P(2) was not present in the assay mixture during the reaction. A real-time interaction analysis between aldolase and FBPase revealed a dual role of Mg(2+) in the regulation of the aldolase-FBPase complex stability. A physiological concentration of Mg(2+) increased the affinity of muscle FBPase to muscle aldolase, whereas higher concentrations of the cation decreased the concentration of the complex. We hypothesized that the presence of Mg(2+) stabilizes a positively charged cavity within FBPase and that it might enable an interaction with aldolase. Because magnesium decreased the binding constant (K(a)) between aldolase and FBPase in a manner similar to the decrease of K(a) caused by monovalent cations, it is postulated that electrostatic attraction might be a driving force for the complex formation. It is presumed that the biological relevance of F1,6-P(2) channeling between aldolase and FBPase is protection of this glyconeogenic, as well as glycolytic, intermediate against degradation by cytosolic aldolase, which is one of the most abundant enzyme of glycolysis.     

Regulation of rabbit liver fructose-1,6-bisphosphatase by metals, nucleotides, and fructose 2,6-bisphosphate as determined from fluorescence studies

The fluorescent nucleotide analogue formycin 5'-monophosphate (FMP) inhibits rabbit liver fructose-1,6-bisphosphatase (I50 = 17 microM, Hill coefficient = 1.2), as does the natural regulator AMP (I50 = 13 microM, Hill coefficient = 2.3), but exhibits little or no cooperativity of inhibition. Binding of FMP to fructose-1,6-bisphosphatase can be monitored by the increased fluorescence emission intensity (a 2.7-fold enhancement) or the increased fluorescence polarization of the probe. A single dissociation constant for FMP binding of 6.6 microM (4 sites per tetramer) was determined by monitoring fluorescence intensity. AMP displaces FMP from the enzyme as evidenced by a decrease in FMP fluorescence and polarization. The substrates, fructose 6-phosphate and fructose 1,6-bisphosphate, and inhibitors, methyl alpha-D-fructofuranoside 1,6-bisphosphate and fructose 2,6-bisphosphate, all increase the maximal fluorescence of enzyme-bound FMP but have little or no effect on FMP binding. Weak metal binding sites on rabbit liver fructose-1,6-bisphosphatase have been detected by the effect of Zn2+, Mn2+, and Mg2+ in displacing FMP from the enzyme. This is observed as a decrease in FMP fluorescence intensity and polarization in the presence of enzyme as a function of divalent cation concentration. The order of binding by divalent cations is Zn2+ = Mn2+ greater than Mg2+, and the Kd for Mn2+ displacement of FMP is 91 microM. Methyl alpha-D-fructofuranoside 1,6-bisphosphate, as well as fructose 6-phosphate and inorganic phosphate, enhances metal-mediated FMP displacement from rabbit liver fructose-1,6-bisphosphatase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Activation of rabbit kidney fructose diphosphatase by Mg-EDTA, Mn-EDTA and Co-EDTA complexes

Purified rabbit kidney fructose diphosphatase requires both a free cation and a metal-chelate when assayed at pH 8 or below. In the presence Mg²⁺ or Mn²⁺, effective metal chelates were Mn(II)-EDTA, Mg(II)-EDTA, and Co(III)-EDTA. With Mg²⁺ as the cation the affinity of the enzyme for Mn(II)-EDTA or Mg(II)-EDTA was approximately the same, and 300-fold greater than that for Co(III)-EDTA.Activation of the enzyme by the very stable Co(III)-EDTA complex, as well as failure of an ionophore antibiotic to replace EDTA as activator, exclude the possibility that the effects of EDTA are due to removal of metal inhibitors.Inhibition of fructose diphosphatase by Ca²⁺ was competitive with Mg²⁺, and noncompetitive with Mg(II)-EDTA, or Co(III)-EDTA. Conversely inhibition by Zn(II)-EDTA was competitive with Mg(II)-EDTA and noncompetitive with free Mg²⁺. The data suggest that the free metals bind to one site on the enzyme while the metal-EDTA chelates bind to a second site.     

Mg2+ is not catalytically required in the intrinsic and kirromycin-stimulated GTPase action of Thermus thermophilus EF-Tu

The influence of divalent metal ions on the intrinsic and kirromycin-stimulated GTPase activity in the absence of programmed ribosomes and on nucleotide binding affinity of elongation factor Tu (EF-Tu) from Thermus thermophilus prepared as the nucleotide- and Mg(2+)-free protein has been investigated. The intrinsic GTPase activity under single turnover conditions varied according to the series: Mn(2+) (0.069 min(-1)) > Mg(2+) (0.037 min(-1)) approximately no Me(2+) (0.034 min(-1)) > VO(2+) (0.014 min(-1)). The kirromycin-stimulated activity showed a parallel variation. Under multiple turnover conditions (GTP/EF-Tu ratio of 10:1), Mg(2+) retarded the rate of hydrolysis in comparison to that in the absence of divalent metal ions, an effect ascribed to kinetics of nucleotide exchange. In the absence of added divalent metal ions, GDP and GTP were bound with equal affinity (K(d) approximately 10(-7) m). In the presence of added divalent metal ions, GDP affinity increased by up to two orders of magnitude according to the series: no Me(2+) < VO(2+) < Mn(2+) approximately Mg(2+) whereas the binding affinity of GTP increased by one order of magnitude: no Me(2+) < Mg(2+) < VO(2+) < Mn(2+). Estimates of equilibrium (dissociation) binding constants for GDP and GTP by EF-Tu on the basis of Scatchard plot analysis, together with thermodynamic data for hydrolysis of triphosphate nucleotides (Phillips, R. C., George, P., and Rutman, R. J. (1969) J. Biol. Chem. 244, 3330-3342), showed that divalent metal ions stabilize the EF-Tu.Me(2+).GDP complex over the protein-free Me(2+).GDP complex in solution, with the effect greatest in the presence of Mg(2+) by approximately 10 kJ/mol. These combined results show that Mg(2+) is not a catalytically obligatory cofactor in intrinsic and kirromycin-stimulated GTPase action of EF-Tu in the absence of programmed ribosomes, which highlights the differential role of Mg(2+) in EF-Tu function.     

Role of vacuolar ion pool in Saccharomyces carlsbergensis: potassium efflux from vacuoles is coupled with manganese or magnesium influx.

Saccharomyces carlsbergensis cells accumulated Mn2+ (or Mg2+) ions in the presence of glucose, fructose, or mannose, but not of deoxyglucose, 3-O-methylglucose, and sorbose. Accumulation of one equivalent of Mn/2+ was coupled with the efflux of two equivalents of K+ from the cells. Mg/2+ did not exit during Mn2+ uptake. Preliminary treatment of cells with various proton conductors or glucose led to the loss of K+ and to the proportional inhibition of Mn2+ uptake. Polyene antibiotic candicidin together with glucose elicited rapid efflux of K+ and completely inhibited Mn2+ accumulation. Exogenous K+ (more than 1 mM), 100 microM N,N'-dicyclohexylcarbodiimide, and 30 mM sodium arsenate inhibited both K+ efflux and Mn2+ influx. K+ efflux from S. carlsbergensis cells affected the vacuolar pool of K+ both during the accumulation of Mn2+ or Mg2+ and during glucose uptake.     

The influence of metal ions on malic enzyme activity and lipid synthesis in Aspergillus niger

In the presence of copper significant induction of citric acid overflow was observed, while concomitantly lower levels of total lipids were detected in the cells. Its effect was more obvious in a medium with magnesium as sole divalent metal ions, while in a medium with magnesium and manganese the addition of copper had a less pronounced effect. Since the malic enzyme was recognised as a supplier of reducing power in the form of reduced nicotinamide adenine dinucleotide phosphate for lipid biosynthesis, its kinetic parameters with regard to different concentrations of metal ions were investigated. Some inhibition was found with Fe(2+) and Zn(2+), while Cu(2+) ions in a concentration of 0.1 mM completely abolished malic enzyme activity. The same metal ions proportionally reduced the levels of total lipids in Aspergillus niger cells. A strong competitive inhibition of the enzyme by Cu(2+) was observed. It seemed that copper competes with Mg(2+) and Mn(2+) for the same binding site on the protein.