Tightly bound pyrophosphate in Escherichia coli inorganic pyrophosphatase

Hexameric inorganic pyrophosphatase of Escherichia coli contains about 1 mol/mol of 'structural' pyrophosphate, which survives gel filtration and prolonged incubation with Mg2+, does not exchange with medium phosphate and pyrophosphate but is removed with 0.8 M perchloric acid. The site of pyrophosphate binding seems to be another than the active site. An additional 0.9 mol of enzyme-bound pyrophosphate is formed in the presence of phosphate and Mg2+ but this pyrophosphate is in fast equilibrium with medium phosphate and appears to be bound to the active site.     

Inhibition of inorganic pyrophosphatase from Escherichia coli with inorganic phosphate

The interaction of inorganic pyrophosphatase from E. coli with inorganic phosphate (Pi) was studied in a wide concentration range of phosphate. The apoenzyme gives two inactive compounds with Pi, a product of phosphorylation of the carboxylic group of the active site and a stable complex, which can be detected in the presence of the substrate. The phosphorylation occurs when Pi is added on a millimole concentration scale, and micromole concentrations are sufficient for the formation of the complex. The formation of the phosphorylated enzyme was confirmed by its sensitivity to hydroxylamine and a change in the properties of the inactive enzyme upon its incubation in alkaline medium. The phosphorylation of pyrophosphatase and the formation of the inactive complex occur upon interaction of inorganic phosphate with different subsites of the enzyme active sites, which are connected by cooperative interactions.     

Modification of tryptophan 149 of inorganic pyrophosphatase from Escherichia coli

• 1.1. The inorganic pyrophosphatase from Escherichia coli was almost completely inactivated on chemical modification of Trp-149 with N-bromosuccinimide (NBS).
• 2.2. The presence of a complex of Mg²⁺ and a substrate analogue, iminodiphosphate (PNP), provided considerable protection against the inactivation, whereas Mg²⁺ or PNP alone afforded only slight protection.

     

Interaction of Escherichia coli inorganic pyrophosphatase active sites

Escherichia coli inorganic pyrophosphatase (PPase) is a hexamer of identical subunits. This work shows that trimeric form of PPase exhibits the interaction of the active sites in catalysis. Some trimer subunits demonstrate high substrate binding affinity typical for hexamer whereas the rest of subunits reveal more than 300-fold substrate affinity decrease. This fact indicates the appearance of negative cooperativity of trimer subunits upon substrate binding. Association of the wild-type (WT) trimer with catalytically inactive, but still substrate binding mutant trimer into hexameric chimera restores the high activity of the first trimer, characteristic of trimer incorporated in the hexamer of WT PPase. Interaction of PPase active sites suggests that there are pathways for information transmission between the active sites, providing the perfect organization and concerted functioning of the hexameric active sites in catalysis.     

Comparative assessment of inorganic pyrophosphate and pyrophosphatase levels of Escherichia coli, Clostridium pasteurianum, and Clostridium thermoaceticum

Abstract Pyrophosphatase (PP_iase) specific activities were much higher in anaerobic cultures of Escherichia coli (0.54 units) than in Clostridium pasteurianum (0.067 units) and Clostridium thermoaceticum (0.017 units) (1 unit = 1 μ mole PP_i hydrolyzed/min per mg cell dry wt.), and were fairly constant throughout the growth of all three organisms. Conversely, intracellular levels of pyrophosphate (PP_i) were very low and constant in E. coli throughout growth (0.3 mM), while those of C. pasteurianum and C. thermoaceticum were higher (1.44 and 0.8 mM, respectively) and peaked sharply during mid log-phase of growth. PP_iase and intracellular PP_i remained relatively constant in E. coli when grown aerobically or anaerobically, and when growth was in medium containing PP_i as the sole source of supplemental phosphorus.     

Chemical modifications of histidyl and tyrosyl residues of inorganic pyrophosphatase from Escherichia coli

Chemical modifications by photooxidation in the presence of rose bengal (RB) and with tetranitromethane (TNM) were carried out to elucidate the amino acid residues involved in the active site of inorganic pyrophosphatase (pyrophosphate phosphohydrolase) [EC 3.6.1.1] from Escherichia coli Q13. The photooxidation caused almost complete inactivation, which followed pseudo-first-order kinetics depending on pH and concentration of RB. The presence of Mg2+ or complex between Mg2+ and substrate or substrate analogues, imidodiphosphate and sodium methylenediphosphate, gave partial protection against the photoinactivation, whereas the substrate alone showed no protective effect. The enzyme was almost completely inactivated by chemical modification with TNM, depending upon the concentration of TNM. The amino acid analyses and enzyme activity measurements revealed that 2 histidyl residues among 5 photooxidized residues and 2 tyrosyl residues per subunit were essential for the enzyme activity. The circular dichroism (CD) spectra in the far ultraviolet region showed no significant alteration during these two modifications, indicating that the polypeptide chain backbone of the enzyme remained unaltered. However, the modifications altered considerably the CD bands in the near ultraviolet region and the fluorescence spectra, indicating that subtle change in conformation had occurred in the vicinity of the active site in the enzyme molecule. These results strongly suggest that histidyl and tyrosyl residues may be involved in the active site or be located in the vicinity of the active site and seem to participate in the mechanism of stability against heat inactivation.     

The quaternary structure of Escherichia coli inorganic pyrophosphatase is essential for phosphorylation

The hexameric inorganic pyrophosphatase (PPase) is irreversibly inactivated by phosphoric acid monoesters. The inactivation kinetics are consistent with the formation of a dissociable complex of the phosphoric acid monoester with the enzyme, followed by phosphorylation of the dicarboxylic amino acid of its active site. PPi and its analogues, binding at the regulatory site, release the inhibitor from the active site and thus restore PPase activity. Chemically identical subunits in the hexameric PPase interact, promoting their cooperativity in a reaction with phosphoric acid monoesters. The trimeric and monomeric PPase, exhibiting full catalytic activity, form a dissociable complex with the phosphoric acid monoesters but, in contrast to the hexameric PPase, do not form a covalent bond with them. This indicates that the native hexameric structure is essential for the irreversible inactivation of Escherichia coli PPase by phosphoric acid monoesters. Possible nontraditional pathways for activity regulation of PPase are discussed.     

The role of Asp42 in Escherichia coli inorganic pyrophosphatase functioning.

Excess of Mg2+ ions is known to inhibit the soluble inorganic pyrophosphatases (PPases). In contrast, the mutant Escherichia coli inorganic pyrophosphatase Asp42-->Asn is three times more active than native and retains its activity at high Mg2+ concentration. In this paper, another two mutant variants with Asp42 replaced by Ala or Glu were investigated to characterize the role of Asp42 in catalysis. pH-independent kinetic parameters of MgPPi hydrolysis and the dissociation constants for the activating and inhibitory Mg2+ ions were calculated. It was shown that Mg2+ inhibition of MgPPi hydrolysis by native PPase exhibited uncompetitive kinetics under the saturating substrate concentration. All three substitutions of Asp42 lead to a sharp decrease of inhibitory Mg2+ affinity to the enzyme. These findings allow determination of the sites of inhibitory and substrate Mg2+ ions binding to PPase. Common features of these mutants allow the conclusion that the function of Asp42 is to accurately coordinate the residues implicated in the substrate and the inhibitory Mg2+ ion binding to PPase active site. Structural analysis of PPase complexed with Mg2+ compared with PPase complexed with Mn2+ and reaction products confirms this supposition.     

Effect of inorganic pyrophosphate on the pretransfer proofreading in the isoleucyl-tRNA synthetase from Escherichia coli.

A total rate equation was used to calculate the discrimination of valine by the isoleucyl-tRNA synthetase from Escherichia coli. The PPi present in the cell makes the backward reaction or the pyrophosphorolysis of the E.aa-AMP possible. If the E.Ile-AMP has been corrected for wrong aminoacyl adenylation by the pretransfer proofreading, the pyrophosphorolysis rapidly equilibrates the corrected E.Ile-AMP with E.Ile and thus spoils the effect of the proofreading. The loss of the corrected species is avoided if there is a barrier (perhaps conformational) formed by a slow reaction step between the noncorrected E.Ile-AMP and the corrected (*E)tRNA(Ile-AMP). If such a slow conformational change exists, the increase in accuracy from the pretransfer proofreading would be beneficial, and, in addition, the PPi increases the accuracy by optimizing the initial discrimination of the wrong amino acid.     

Functional characterization of Escherichia coli inorganic pyrophosphatase in zwitterionic buffers.

Catalysis by Escherichia coli inorganic pyrophosphatase (E-PPase) was found to be strongly modulated by Tris and similar aminoalcoholic buffers used in previous studies of this enzyme. By measuring ligand-binding and catalytic properties of E-PPase in zwitterionic buffers, we found that the previous data markedly underestimate Mg(2+)-binding affinity for two of the three sites present in E-PPase (3.5- to 16-fold) and the rate constant for substrate (dimagnesium pyrophosphate) binding to monomagnesium enzyme (20- to 40-fold). By contrast, Mg(2+)-binding and substrate conversion in the enzyme-substrate complex are unaffected by buffer. These data indicate that E-PPase requires in total only three Mg2+ ions per active site for best performance, rather than four, as previously believed. As measured by equilibrium dialysis, Mg2+ binds to 2.5 sites per monomer, supporting the notion that one of the tightly binding sites is located at the trimer-trimer interface. Mg2+ binding to the subunit interface site results in increased hexamer stability with only minor consequences for catalytic activity measured in the zwitterionic buffers, whereas Mg2+ binding to this site accelerates substrate binding up to 16-fold in the presence of Tris. Structural considerations favor the notion that the aminoalcohols bind to the E-PPase active site.     

The effect of CuCl2 on the efflux of inorganic phosphate from Escherichia coli

The influence of CuCl2 on inorganic phosphate efflux from resting E. coli and those treated with glucose has been studied. Maintaining of high phosphate gradient on the membrane is possibly only in case of continuous supply of external metabolic energy. Treatment with CuCl2 does not lead to the increase in permeability of the resting cell membrane for phosphates, but it causes the efflux of phosphates in glucose-treated cells. The above data suggest that the efflux is determined by inhibition of energy influx into cell by CuCl2, not by damaging the cytoplasmic membrane.     

Mechanism of Ca2+-induced inhibition of Escherichia coli inorganic pyrophosphatase

The causes of inhibition of Escherichia coli inorganic pyrophosphatase (PPase) by Ca2+ were investigated. The interactions of several mutant pyrophosphatases with Ca2+ in the absence of substrate were analyzed by equilibrium dialysis. The kinetics of Ca2+ inhibition of hydrolysis of the substrates MgPPi and LaPPi by the native PPase and three mutant enzymes (Asp-42-Asn, Ala, and Glu) were studied. X-Ray data on E. coli PPase complexed with Ca2+ or CaPPi solved at atomic resolution were analyzed. It was shown that, in the course of the catalytic reaction, Ca2+ replaces Mg2+ at the M2 site, which shows higher affinity for Ca2+ than for Mg2+. Different properties of these cations account for active site deformation. Our findings indicate that the filling of the M2 site with Ca2+ is sufficient for PPase inhibition. This fact proves that Ca2+ is incapable of properly activating the H2O molecule for nucleophilic attack on PPi. It was also demonstrated that Ca2+, as a constituent of the non-hydrolyzable substrate analog CaPPi, competes with MgPPi at the M3 binding site. As a result, Ca2+ is a powerful inhibitor of all known PPases. Other possible reasons for the inhibitory effect of Ca2+ on the enzyme activity are also considered.     

Hexameric,trimeric, dimeric,and monomeric forms of inorganic pyrophosphatase from Escherichia coli

The conditions were found for obtaining trimeric, dimeric, and monomeric forms of the Escherichia coli inorganic pyrophosphatase from its native hexameric form. Interconversions of the oligomers were studied, and rate constants for their dissociation and association were determined. All forms were found to be catalytically active, with the activity decreasing in the order: hexamer-trimer-dimer-monomer. The activity of trimeric and dimeric forms was high enough to study and to compare their catalytic properties. The monomeric form of the enzyme was unstable.     

The influence of diphosphonic analogues of inorganic pyrophosphate on activity of RNA-polymerases from the calf thymus

Diphosphonic analogues of inorganic pyrophosphate (PPi): methylene-, oxyethylidene-, aminomethylenediphosphonic acids as well as phosphonacetic, imidodiphosphoric bis- (phosphonomethyl)-phosphonic acids and methylenediphosphonic and phosphonic acid monoanhydrides were studied for their effect on the RNA-synthesizing activity of thymocytes. DNA-dependent RNA-polymerases I and II from the calf thymus nuclei were used for these studies. The analogues and PPi under study are shown to be inhibitors of both RNA-polymerases in nuclei from calf thymus and of purified RNA-polymerase II, which is more sensitive to the effect of diphosphonates. Methylenediphosphonic acid is the strongest inhibitor among the studied analogues, and imidodiphosphoric and phosphonacetic acids are the weakest inhibitors. Inhibition of purified RNA-polymerase II by diphosphonates has a complex character and includes both interaction of the PPi analogues with enzymes and chelating by them of Mn ions which are cofactors for RNA polymerase.     

Identification of new protein complexes of Escherichia coli inorganic pyrophosphatase using pull-down assay

Inorganic pyrophosphatase (PPase) is a conserved and essential enzyme catalyzing the hydrolysis of pyrophosphate PP_i. Its activity is required to promote a lot of thermodynamically unfavorable reactions including biosynthesis of activated precursors of sugars and amino acids. Several protein partners of PPase were found so far in Escherichia coli by large-scale approaches. Functional role of these interactions was not studied. In this paper we report the identification of three protein partners of E. coli PPase not found earlier. Pull-down assay on the Ni²⁺-chelating column using 6His-tagged PPase as bait was used to isolate PPase complexes from stationary-phase cells. Of several isolated protein components, five were identified by MALDI-TOF mass-spectrometry: two chaperones (DnaK and GroEL) and three enzymes of carbohydrate and amino acid metabolism (FbaB, fructose-1,6-bisphosphate aldolase, class I; GadA, l-glutamate decarboxylase; and KduI, 5-keto-4-deoxyuronate isomerase). These three proteins were cloned, expressed and purified in 6His-tagged and/or tag-free forms. Their binary interactions with PPase were verified by independent approaches. Initial characterization of the complexes indicates that PPase may stabilize its protein partners against unfolding or degradation. Comparative analysis of the PPase protein partners allowed an insight into its possible involvement in the cell metabolic regulation.