T. I. Nazarova

X‐Ray crystallographic studies of recombinant inorganic pyrophosphatase from Escherichia coli

An E. coli inorganic pyrophosphatase overproducer and a method for a large‐scale production of the homogeneous enzyme are described. The inorganic pyrophosphatase was crystallized in the form containing one subunit of a homohexameric molecule per asymmetric unit: space group R32, a = 110.4 Å, c = 76.8 Å. The electron density map to 2.5 Å resolution phased with Eu‐ and Hg‐derivatives (figure of merit, = 0.51) was improved by the solvent flattening procedure ( = 0.77). The course of the polypeptide chain and the secondary structure elements, intersubunit contacts and positions of the active sites were characterized. Homology with S. cerevisiae inorganic pyrophosphatase structure was found.

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.

Effectory Site in Escherichia coli Inorganic Pyrophosphatase is Revealed Upon Mutation at the Intertrimeric Interface

Escherichia coli inorganic pyrophosphatase (E‐PPase) is a homohexamer formed from two trimers related by a two‐fold axis. The residue Asp26 participates in intertrimeric contacts. Kinetics of MgPPi hydrolysis by a mutant Asp26Ala E‐PPase is found to not obey Michaelis‐Menten equation but can be described within the scheme of activation of hydrolysis by a free PPi binding at an effectory subsite. Existence of such a subsite is confirmed by the finding that the free form of methylenediphosphonate activates MgPPi hydrolysis though its magnesium complex is a competitive inhibitor. The Asp26Ala variant is the first example of hexameric E‐PPase demonstrated to have an activatory subsite. IUBMB Life, 55: 37‐41, 2003

Phosphohistidine as the result of phosphate migration in phosphorylated inorganic pyrophosphatase from yeast

Whereas it has been well established that many enzymic reactions involve phosphorylation of the active center, it is much more difficult to pinpoint the amino residue taking on the phosphate group. In 1962 Boyer et al. found that such an amino acid could be histidine [ 1 ] . Later, phosphohistidine was isolated from the hydrolysates of several phosphorylated enzymes. The usual procedure for this purpose is alkaline hydrolysis. In the present paper it is shown that phosphohistidine can be isolated also from the alkaline hydrolysate of phosphorylated inorganic pyrophosphatase, but that it is the result of a migration of the phosphate group from the enzyme’s active site to the imidazole ring of the amino acid.

Metal-free PPi activates hydrolysis of MgPPi by an Escherichia coli inorganic pyrophosphatase

Soluble inorganic pyrophosphatase from Escherichia coli (E-PPase) is a hexamer forming under acidic conditions the active trimers. We have earlier found that the hydrolysis of a substrate (MgPPi) by the trimers as well as a mutant E-PPase Asp26Ala did not obey the Michaelis-Menten equation. To explain this fact, a model has been proposed implying the existence of, aside from an active site, an effector site that can bind PPi and thus accelerate MgPPi hydrolysis. In this paper, we demonstrate that the noncompetitive activation of MgPPi hydrolysis by metal-free PPi can also explain kinetic features of hexameric forms of both the native enzyme and the specially obtained mutant E-PPase with a substituted residue Glu145 in a flexible loop 144-149. Aside from PPi, its non-hydrolyzable analog methylene diphosphonate can also occupy the effector site resulting in the acceleration of the substrate hydrolysis. Our finding that two moles of [32P]PPi can bind with each enzyme subunit is direct evidence for the existence of the effector site in the native E-PPase.

Metal cofactors play a dual role in Mycobacterium tuberculosis inorganic pyrophosphatase.

Inorganic pyrophosphatase from Mycobacterium tuberculosis (Mt-PPase) is one of the possible targets for the rational design of anti-tuberculosis agents. In this paper, functional properties of this enzyme are characterized in the presence of the most effective activators—Mg2+ and Mn2+. Dissociation constants of Mt-PPase complexed with Mg2+ or Mn2+ are essentially similar to those of Escherichia coli PPase. Stability of a hexameric form of Mt-PPase has been characterized as a function of pH both for the metal-free enzyme and for Mg2+-or Mn2+-enzyme. Hexameric metal-free Mt-PPase has been shown to dissociate, forming monomers at pH below 4 or trimers at pH from 8 to 10. Mg2+ or Mn2+ shift the hexamer-trimer equilibrium found for the apo-Mt-PPase at pH 8–10 toward the hexameric form by stabilizing intertrimeric contacts. The pKa values have been determined for groups that control the observed hexamer-monomer (pKa 5.4), hexamer-trimer (pKa 7.5), and trimer-monomer (pKa 9.8) transitions. Our results demonstrate that due to the non-conservative amino acid residues His21 and His86 in the active site of Mt-PPase, substrate specificity of this enzyme, in contrast to other typical PPases, does not depend on the nature of the metal cofactor.

ATP as effector of inorganic pyrophosphatase of Escherichia coli. Identification of the binding site for ATP

The interaction of Escherichia coli inorganic pyrophosphatase (E-PPase) with effector ATP has been studied. The E-PPase has been chemically modified with the dialdehyde derivative of ATP. It has been established that in the experiment only one molecule of effector ATP is bound to each subunit of the hexameric enzyme. Tryptic digestion of the adenylated protein followed by isolation of a modified peptide by HPLC and its mass-spectrometric identification has showed that it is an amino group of Lys146 that undergoes modification. Molecular docking of ATP to E-PPase indicates that the binding site for effector ATP is located in a cluster of positively charged amino acid residues proposed earlier on the basis of site-directed mutagenesis to participate in binding of effector pyrophosphate. Molecular docking also reveals several other amino acid residues probably involved in the interaction with effectors.

ATP as effector of inorganic pyrophosphatase of Escherichia coli. The role of residue Lys112 in binding effectors.

It has been shown that PPi, methylenediphosphonate, and ATP act as effectors of Escherichia coli inorganic pyrophosphatase (E-PPase), and that they compete for binding at the allosteric regulatory site. On the basis of chemical modification and computer modeling of a structure of the enzyme-ATP complex, a number of amino acid residues presumably involved in binding effectors has been revealed. Mutant variants Lys112Gln, Lys112Gln/Lys148Gln, and Lys112Gln/Lys115Ala of E-PPase have been obtained, as well as a modified variant of wild type E-PPase (Adwt PPase) with a derivative of ATP chemically attached to the amino group of Lys146. Kinetic properties of these variants have been investigated and compared to the earlier described variants Lys115Ala, Arg43Gln, and Lys148Gln. Analysis of the data confirms the proposed location of an effector binding site in a cluster of positively charged amino acid residues including the side chains of Arg43, Lys146 (subunit A), Lys112, and Lys115 (subunit B). Lys112 is supposed to play a key role in forming contacts with the phosphate groups of the three studied effectors.

Substitutions of glycine residues Gly100 and Gly147 in conservative loops decrease rates of conformational rearrangements of Escherichia coli inorganic pyrophosphatase

Escherichia coli inorganic pyrophosphatase (PPase) is a one-domain globular enzyme characterized by its ability to easily undergo minor structure rearrangements involving flexible segments of the polypeptide chain. To elucidate a possible role of these segments in catalysis, catalytic properties of mutant variants of E. coli PPase Gly100Ala and Gly147Val with substitutions in the conservative loops II and III have been studied. The main result of the mutations was a sharp decrease in the rates of conformational changes required for binding of activating Mg2+ ions, whereas affinity of the enzyme for Mg2+ was not affected. The pH-independent parameters of MgPPi hydrolysis, kcat and kcat/Km, have been determined for the mutant PPases. The values of kcat for Gly100Ala and Gly147Val variants were 4 and 25%, respectively, of the value for the native enzyme. Parameter kcat/Km for both mutants was two orders of magnitude lower. Mutation Gly147Val increased pH-independent Km value about tenfold. The study of synthesis of pyrophosphate in the active sites of the mutant PPases has shown that the maximal level of synthesized pyrophosphate was in the case of Gly100Ala twofold, and in the case of Gly147Val fivefold, higher than for the native enzyme. The results reported in this paper demonstrate that the flexibility of the loops where the residues Gly100 and Gly147 are located is necessary at the stages of substrate binding and product release. In the case of Gly100Ala PPase, significant impairment of affinity of enzyme effector site for PPi was also found.

Some features of hydrolysis of organic and inorganic substrates by Escherichia coli inorganic pyrophosphatase in the presence of various activator cations

The kinetics of hydrolysis of the inorganic (PPi) and organic (ATP) substrates by Escherichia coli inorganic pyrophosphatase (PPase) and its mutant forms with Asp42 replaced by Ala, Asn, or Glu was studied. The Mn2+ or Zn2+ ions were used as activators of the enzymatic reaction. The kinetic parameters of hydrolysis were determined. The inhibitory effect of these cations on substrate hydrolysis was investigated. The dissociation constants were calculated for the Mn2+- and Zn2+-binding activator and inhibitor subsites of E. coli PPase. The observed hydrolysis rate of PPi increases in the series Zn2+ < Mn2+ < Mg2+, whereas the potential efficiency of these cations decreases in this series. Hydrolysis of ATP by E. coli PPase occurs only in the presence of Mn2+. The reasons for the observed differences in the substrate specificity of the enzyme are discussed.