Active subunits of rabbit liver fructose diphosphatase

Fructose diphosphatase, bound to a matrix of Sepharose, retains most of the catalytic activity but becomes half desensitized to AMP. The dimers, obtained by acid dissociation of the enzyme bound to the matrix, possess half of the specific activity of the tetramers and are almost completely desensitized to AMP. The monomers are inactive.     

Inactivation of fructose diphosphatase by sucrose in yeast.

In Saccharomyces carlsbergensis, the addition of sucrose to the medium led to the inactivation of fructose diphosphatase. Sucrose itself probably triggered this process.     

P-nitrophenyl phosphate as substrate for rabbit liver fructose diphosphatase

Purified rabbit liver fructose diphosphatase has been found to catalyze the hydrolysis of p-nitrophenyl phosphate, PNPP. It has been established that the hydrolysis of p-nitrophenyl phosphate is due to fructose diphosphatase through studies of the chromatographic properties of the enzyme, its temperature sensitivity, dependence on divalent cations and its inhibition by fructose diphosphate. The K_m for PNPP is 6 × 10⁻³M at pH 9.2, 5 × 10⁻⁴M at pH 7.5. This substrate should facilitate studies of the kinetics and mechanism of action of fructose diphosphatase and the comparison of this enzyme with other alkaline phosphatases.     

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.     

Regulatory sulfhydryl groups, conformational change, and allosteric inhibition in rabbit muscle fructose diphosphatase

The 16 sulfhydryl groups of native, homogeneous rabbit muscle fructose diphosphatase can all react with 5,5′-dithiobis-(2-nitrobenzoic acid). High concentrations of substrate (1–2 mm) decrease the reaction rate of the sulfhydryl groups, while concentrations up to 70 μm have no effect. After titration of the four most rapidly reacting sulfhydryl groups there is a marked desensitization toward the allosteric inhibitor AMP. In the presence of 30 μm AMP only 4–5 sulfhydryl groups/tetramer react with 5,5′-dithiobis-(2-nitrobenzoic acid), and the enzyme again becomes desensitized toward AMP inhibition. Together with a 3.5-fold increase in the I₅₀ for AMP inhibition, the K_m for Mg²⁺ or Mn²⁺ ions is also increased. In the presence of 7 mm MgCl₂ or 0.28 mm MnCl₂ only 6–8 sulfhydryl groups are modified. The rapid reaction of 4 sulfhydryl groups again results in desensitization. There is neither a protection by the substrate against inactivation, nor a protection by the allosteric inhibitor against desensitization. It is concluded that AMP and the divalent cations induce conformational changes in the protein molecule making 11–12 or 8–10 sulfhydryl groups inert for 5,5′-dithiobis-(2-nitrobenzoic acid), respectively. The K_m for fructose-1,6-diphosphate is not changed after the modification of 4–5 sulfhydryl groups.     

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.     

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.     

The activities of pyruvate carboxylase, phosphoenolpyruvate carboxylase and fructose diphosphatase in muscles from vertebrates and invertebrates

1. The activities of pyruvate carboxylase, phosphoenolpyruvate carboxylase and fructose diphosphatase in crude homogenates of vertebrate and invertebrate muscles are reported. 2. Pyruvate carboxylase activity was present in all insect flight muscles that were investigated: in homogenates of bumble-bee flight muscle the activity was inhibited by ADP and activated by acetyl-CoA, and it was distributed mainly in the mitochondrial fraction. This is the first demonstration of pyruvate carboxylase activity in muscle. However, the activity appears to be restricted to insect flight muscle, since it was not found in other invertebrate or vertebrate muscles. 3. Since the three enzymes were never found together in the same muscle, it is concluded that these enzymes cannot provide a pathway for the synthesis of glycogen from lactate or pyruvate in muscle. Other roles for these enzymes in muscle are suggested. In particular, pyruvate carboxylase may be present in insect flight muscle for the provision of oxaloacetate to support the large increase in activity of the tricarboxylic acid cycle which occurs when an insect takes flight.