The kinetic mechanism of yeast inorganic pyrophosphatase

The kinetic mechanism of yeast inorganic pyrophosphatase (PPase) was examined by carrying out initial velocity studies. Ca2+ and Rh(H2O)4(methylenediphosphonate) (Rh(H2O)4PCP) were used as dead-end inhibitors to study the order of binding of Cr(H2O)4PP to the substrate site and Mg2+ to the "low affinity" activator site on the enzyme. Competitive inhibition was observed for Ca2+ vs Mg2+ (Kis = 0.93 +/- 0.03 mM), for Rh(H2O)4PCP vs Cr(H2O)4PP (Kis = 0.25 +/- 0.07 mM), and for RH(H2O)4PCP vs Mg2+ (Kis = 0.38 +/- 0.03 mM). Uncompetitive inhibition was observed for Ca2+ vs Cr(H2O)4PP (Kii = 0.49 +/- 0.01). On the basis of these results a rapid equilibrium ordered mechanism in which Cr(H2O)4PP binding precedes Mg2+ ion binding is proposed. The inert substrate analog, Mg(imidodiphosphate) (MgPNP) was shown to induce Mg2+ inhibition of the PPase-catalyzed hydrolysis of MgPP. The Mg2+ inhibition observed was competitive vs MgPP and partial. These results suggest that Mg2+/MgPNP release from the enzyme occurs in preferred rather than strict order and that the Mg2+/MgPP-binding steps are at steady state. Zn2+, Co2+, and Mn2+ (but not Mg2+) displayed activator inhibition of the PPase-catalyzed hydrolysis of PPi (this study) and of Cr(H2O)4PP (W.B. Knight, S. Fitts, and D. Dunaway-Mariano, (1981) Biochemistry 20, 4079). These findings suggest that cofactor release from the low affinity cofactor site on the enzyme must precede product release and that Zn2+, Mn2+, and Co2+ (but not Mg2+) have high affinities for the cofactor sites on both the PPase.M.MPP and PPase.M.M(P)2 complexes. The role of the metal cofactor in determining PPase substrate specificity was briefly explored by testing the ability of the Mg2+ complex of tripolyphosphate (PPPi) (a substrate for the Zn2+-activated enzyme but not the Mg2+-activated enzyme) to induce Mg2+ inhibition of PPase-catalyzed hydrolysis of MgPP. MgPPP was shown to be as effective as MgPNP in inducing competitive Mg2+ inhibition (vs MgPP). This result suggests that the low affinity Mg2+ cofactor-binding site present in the enzyme-MgPP complex is maintained in the enzyme-MgPPP complex. Thus, failure of Mg2+ to bind to the enzyme-MgPPP complex was ruled out as a possible explanation for the failure of the Mg2+-activated enzyme to catalyze the hydrolysis of MgPPP.     

Kinetic model for the action of the inorganic pyrophosphatase from Streptococcus faecalis

Kinetic studies of the less active form of Streptococcus faecalis inorganic pyrophosphatase (EC 3.6.1.1), together with computational analysis, indicated that cooperativity in ligand binding contributes in a significant way to the behavior of this enzyme. The simplest model applicable to our data was a Monod-Wyman-Changeux-type, allosteric model, in which the enzyme is proposed to exist in two states, referred to as R and T states, respectively. In the absence of ligands, 94% of the enzyme was in the T state. MgPPi2- was the only substrate for the enzyme in the R form. This substrate was bound equally well by both enzyme forms, but it was hydrolyzed 5 times more efficiently by the R form than it was by the T form. Mg2PPi was bound exclusively to the T state of the enzyme, and it was hydrolyzed 25% as rapidly as MgPPi2- by the T form. Mg2PPi inhibited the hydrolysis of the more efficient substrate, MgPPi2-, by competing with MgPPi2- for the enzyme in the T form and by shifting the R----T equilibrium in favor of the T form. Mg2+ stabilized the R state, thus activating the hydrolysis of MgPPi2- and inhibiting that of Mg2PPi.     

Properties of cotton inorganic pyrophosphatase

The activity of inorganic pyrophosphatase and pyrophosphate content were studied in developing and germinating cotton seeds. It was shown that the content of pyrophosphate in germinating seeds reached its maximum value after two days of their development, and the activity of inorganic pyrophosphatase, one day after the beginning of seed bud formation. The low pyrophosphatase activity of dormant seeds increased during their germination under open-ground conditions, reaching its maximum on day 6–7. Properties of partly purified pyrophosphatase from three-day-old cotton seedlings grown under laboratory conditions were studied.     

Properties of cotton inorganic pyrophosphatase

The activity of inorganic pyrophosphatase and pyrophosphate content were studied in developing and germinating cotton seeds. It was shown that the content of pyrophosphate in germinating seeds reached its maximum value after two days of their development, and the activity of inorganic pyrophosphatase, one day after the beginning of seed bud formation. The low pyrophosphatase activity of dormant seeds increased during their germination under open-ground conditions, reaching its maximum on day 6-7. Properties of partly purified pyrophosphatase from three-day-old cotton seedlings grown under laboratory conditions were studied.     

Molecular cloning and characterization of an inorganic pyrophosphatase from barley

A cDNA clone with sequence homology to soluble inorganic pyrophosphatase (IPPase) was isolated from a library of developing barley grains. The protein encoded by this clone was produced in transgenic Escherichia coli, and showed IPPase activity. In nondormant barley grains, the gene appeared to be expressed in metabolically active tissue such as root, shoot, embryo and aleurone. During imbibition, a continuous increase of the steady state mRNA level of IPPase was observed in embryos of non-dormant grains. In the embryos of dormant grains its production declined, after an initial increase. With isolated dormant and nondormant embryos, addition of recombinant IPPase, produced by E. coli, enhanced the germination rate. On the other hand, addition of pyrophosphate (PPi), substrate for this enzyme, appeared to reduce the germination rate. A role for this IPPase in germination is discussed.     

A microcolorimetric assay of inorganic pyrophosphatase

A procedure is described for the assay of inorganic pyrophosphatase in tissues by a microcolorimetric procedure, taking advantage of the marked color intensification of phosphomolybdate by malachite green. Conditions are described for optimum enzyme activity, color stability, and sensitivity. With 1-cm cuvettes the AM660 is 100,000, allowing accurate measurement of Pi in the 1-nmol range. Reaction is conducted at 25 degrees C for 10 min in 0.5 ml of a 50 mM histidine buffer, pH 7.2, containing 0.2 mM inorganic pyrophosphate and 4 mM Mg2+, terminated by addition of 0.05 ml 2.4 M HClO4, cooled in ice, and 0.45 ml of color reagent is added. After standing 10 min at 0 degrees C, the contents are transferred to 1-cm cuvettes and the absorbance is read at 660 nm. Blanks are low, nonenzymatic hydrolysis of PPi is negligible, and color is stable without addition of detergents. The high sensitivity makes this procedure well-adapted to measurement of optimal activities in crude tissue preparations.     

Evolutionary aspects of inorganic pyrophosphatase.

Based on the primary structure, soluble inorganic pyrophosphatases can be divided into two families which exhibit no sequence similarity to each other. Family I, comprising most of the known pyrophosphatase sequences, can be further divided into prokaryotic, plant and animal/fungal pyrophosphatases. Interestingly, plant pyrophosphatases bear a closer similarity to prokaryotic than to animal/fungal pyrophosphatases. Only 17 residues are conserved in all 37 pyrophosphatases of family I and remarkably, 15 of these residues are located at the active site. Subunit interface residues are conserved in animal/fungal but not in prokaryotic pyrophosphatases.     

The essential activated carboxyl group of inorganic pyrophosphatase.

1. A carboxyl group of high reactivity has been found in inorganic pyrophosphatase (pyrophosphate phosphohydrolase, EC 3.6.1.1) from yeast. This group interacts with agents which react neither with carboxyl groups of low molecular weight compounds nor with other carboxyl groups of the protein. 2. The reaction of this activated carboxyl group with inorganic phosphate, hydroxylamine, N-methyl- and O-methylhydroxylamines, and glycine methyl ester has been studied. 3. Homoserine and homoserine lactone were found in the hydrolyzate of phosphorylated and NaBH4-reduced pyrophosphatase, indicating that an aspartyl residue is phosphorylated. 4. Hydroxylamine and other nucleophilic agents cause inactivation of pyrophosphatase as a result of interaction with a carboxyl group. Both diaminobutyric and diaminopropionic acids were seen in the acid hydrolyzate of the protein treated with hydroxylamine and subjected to rearrangement in the presence of carbodiimide. 5. The ways in which the activation of a carboxyl group in the enzyme is achieved and the presumed mechanism of action of inorganic pyrophosphatase are discussed.