Ligand binding sites in Escherichia coli inorganic pyrophosphatase: effects of active site mutations.

Type I soluble inorganic pyrophosphatases (PPases) are well characterized both structurally and mechanistically. Earlier we measured the effects of active site substitutions on pH--rate profiles for the type I PPases from both Escherichia coli (E-PPase) and Saccharomyces cerevisae (Y-PPase). Here we extend these studies by measuring the effects of such substitutions on the more discrete steps of ligand binding to E-PPase, including (a) Mg(2+) and Mn(2+) binding in the absence of added ligand; (b) Mg(2+) binding in the presence of either P(i) or hydroxymethylbisphosphonate (HMBP), a competitive inhibitor of E-PPase; and (c) P(i) binding in the presence of Mn(2+). The active site of a type I PPase has well-defined subsites for the binding of four divalent metal ions (M1--M4) and two phosphates (P1, P2). Our results, considered in light of pertinent results from crystallographic studies on both E-PPase and Y-PPase and parallel functional studies on Y-PPase, allow us to conclude the following: (a) residues E20, D65, D70, and K142 play key roles in the functional organization of the active site; (b) the major structural differences between the product and substrate complexes of E-PPase are concentrated in the lower half of the active site; (c) the M1 subsite is functionally isolated from the rest of the active site; and (d) the M4 subsite is an especially unconstrained part of the active site.

Parameters influencing protein extraction for whole broths in detergent based aqueous two-phase systems.

The parameters important for an optimisation of cloud point extraction in technical scale were investigated using a genetically engineered fusion protein derived from endoglucanase I expressed in Trichoderma reesei and the nonionic polyoxyethylene Agrimul NRE 1205. The key parameters are temperature, detergent concentration, and additional salts. These parameters are interdependent, thus there is an optimum in the partition coefficient with respect to detergent concentration and a maximum for the partition coefficient and the yield with respect to temperature. These results were confirmed for the detergent C12E5 to demonstrate that these optima are due to the nature of polyoxyethylenes. Cloud point extraction was found to be only slightly affected by pH. In the case studied extraction of whole broth is favourable for a high yield and partition coefficient, since fusion protein adhering to the cells can be solubilized. However some loss of detergent which remains in the fungal biomass was observed.

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.

Trimeric inorganic pyrophosphatase of Escherichia coli obtained by directed mutagenesis.

Escherichia coli inorganic pyrophosphatase is a tight hexamer of identical subunits. Replacement of both His136 and His140 by Gln in the subunit interface results in an enzyme which is trimeric up to 26 mg/mL enzyme concentration in the presence of Mg2+, allowing direct measurements of Mg2+ binding to trimer by equilibrium dialysis. The results of such measurements, together with the results of activity measurements as a function of [Mg2+] and pH, indicate that Mg2+ binds more weakly to one of the three sites per monomer than it does to the equivalent site in the hexamer, suggesting this site to be located in the trimer:trimer interface. The otherwise unobtainable hexameric variant enzyme readily forms in the presence of magnesium phosphate, the product of the pyrophosphatase reaction, but rapidly dissociates on dilution into medium lacking magnesium phosphate or pyrophosphate. The kcat values are similar for the variant trimer and hexamer, but Km values are 3 orders of magnitude lower for the hexamer. Thus, while stabilizing hexamer, the two His residues, per se, are not absolutely required for active-site structure rearrangement upon hexamer formation. The reciprocal effect of hexamerization and product binding to the active site is explained by destabilization of alpha-helix A, contributing both to the active site and the subunit interface.

The R78K and D117E active-site variants of Saccharomyces cerevisiae soluble inorganic pyrophosphatase: structural studies and mechanistic implications.

We have solved the structure of two active-site variants of soluble inorganic pyrophosphatases (PPase), R78K and D117K, at resolutions of 1.85 and 2.15 A and R-factors of 19.5% and 18.3%, respectively. In the R78K variant structure, the high-affinity phosphate group (P1) is missing, consistent with the wild-type structure showing a bidentate interaction between P1 and Arg78, and solution data showing a decrease in P1 affinity in the variant. The structure explains why the mutation affects P1 and pyrophosphate binding much more than would be expected by the loss of one hydrogen bond: Lys78 forms an ion-pair with Asp71, precluding an interaction with P1. The R78K variant also provides the first direct evidence that the low-affinity phosphate group (P2) can adopt the structure that we believe is the immediate product of hydrolysis, with one of the P2 oxygen atoms co-ordinated to both activating metal ions (M1 and M2). If so, the water molecule (Wat1) between M1 and M2 in wild-type PPase is, indeed, the attacking nucleophile. The D117E variant structure likewise supports our model of catalysis, as the Glu117 variant carboxylate group is positioned where Wat1 is in the wild-type: the potent Wat1 nucleophile is replaced by a carboxylate co-ordinated to two metal ions. Alternative confirmations of Glu117 may allow Wat1 to be present but at much reduced occupancy, explaining why the pKa of the nucleophile increases by three pH units, even though there is relatively little distortion of the active site. These new structures, together with parallel functional studies measuring catalytic efficiency and ligand (metal ion, PPi and Pi) binding, provide strong evidence against a proposed mechanism in which Wat1 is considered unimportant for hydrolysis. They thus support the notion that PPase shares mechanistic similarity with the "two-metal ion" mechanism of polymerases.

Structural and functional consequences of substitutions at the tyrosine 55-lysine 104 hydrogen bond in Escherichia coli inorganic pyrophosphatase.

Tyrosine 55 and lysine 104 are evolutionarily conserved residues that form a hydrogen bond in the active site of Escherichia coli inorganic pyrophosphatase (E-PPase). Here we used site-directed mutagenesis to examine their roles in structure stabilization and catalysis. Though these residues are not part of the subunit interface, Y55F and K104R (but not K104I) substitutions markedly destabilize the hexameric structure, allowing dissociation into active trimers on dilution. A K104I variant is nearly inactive while Y55F and K104R variants exhibit appreciable activity and require greater concentrations of Mg2+ and higher pH for maximal activity. The effects on activity are explained by (a) increased pK(a)s for the catalytically essential base and acid at the active site, (b) decreases in the rate constant for substrate (dimagnesium pyrophosphate) binding to enzyme-Mg2 complex vs enzyme-Mg3 complex, and (c) parallel decreases in the catalytic constant for the resulting enzyme-Mg2-substrate and enzyme-Mg3-substrate complexes. The results are consistent with the major structural roles of Tyr55 and Lys104 in the active site. The microscopic rate constant for PPi hydrolysis on either the Y55F or K104R variants increases, by a factor of 3-4 in the pH range 7.2-8.0, supporting the hypothesis that this reaction step depends on an essential base within the enzyme active site.

Catalysis by Escherichia coli inorganic pyrophosphatase: pH and Mg2+ dependence.

Steady-state rates of PPi hydrolysis by Escherichia coli inorganic pyrophosphatase (E-PPase) were measured as a function of magnesium pyrophosphatase (substrate) and free Mg2+ ion (activator) in the pH range 6.0-10.0. Computer fitting of hydrolysis data in combination with direct measures of Mg2+ binding to enzyme has resulted in a model that quantitatively accounts for our results. The major features of this model are the following: (a) E-PPase catalysis proceeds both with three and with four (and possibly with five) Mg2+ ions per active site; (b) catalysis requires both an essential base and an essential acid, and the pKas of these groups are modulated by the stoichiometry of bound Mg2+; and (c) the four-metal route predominates for concentrations of free Mg2+>0.2mM. The model straightforwardly accounts for the apparent linkage between increased pKa of an essential base and activity requirements for higher Mg2+ concentration observed for several active site variants. Microscopic rate constants for overall catalysis of PPi-Pi equilibration were determined at pH 6.5-9.3 by combined analysis of enzyme-bound PPi formation and rates of PPi hydrolysis, PPi synthesis, and Pi-H2O oxygen exchange. The catalytic activity of E-PPase at saturating substrate increases toward PPi hydrolysis and decreases toward PPi synthesis and Pi-H2O oxygen exchange with increasing pH. These changes are mainly due to an increased rate of dissociation of the second released Pi and a decreased rate of enzyme-bound PPi synthesis from enzyme-bound Pi, respectively, as the pH is raised .

Dissociation of hexameric Escherichia coli inorganic pyrophosphatase into trimers on His-136-->Gln or His-140-->Gln substitution and its effect on enzyme catalytic properties.

Each of the five histidines in Escherichia coli inorganic pyrophosphatase (PPase) was replaced in turn by glutamine. Significant changes in protein structure and activity were observed in the H136Q and H140Q variants only. In contrast to wild-type PPase, which is hexameric, these variants can be dissociated into trimers by dilution, as shown by analytical ultracentrifugation and cross-linking. Mg2+ and substrate stabilize the hexameric forms of both variants. The hexameric H136Q- and H140Q-PPases have the same binding affinities for magnesium ion as wild-type, but their hydrolytic activities under optimal conditions are, respectively, 225 and 110% of wild-type PPase, and their synthetic activities, 340 and 140%. The increased activity of hexameric H136Q-PPase results from an increase in the rate constants governing most of the catalytic steps in both directions. Dissociation of the hexameric H136Q and H140Q variants into trimers does not affect the catalytic constants for PPi hydrolysis between pH 6 and 9 but drastically decreases their affinities for Mg2PPi and Mg2+. These results prove that His-136 and His-140 are key residues in the dimer interface and show that hexamer formation improves the substrate binding characteristics of the active site.

Effect of D97E substitution on the kinetic and thermodynamic properties of Escherichia coli inorganic pyrophosphatase.

Aspartic acid 97 in the inorganic pyrophosphatase of Escherichia coli (E-PPase) has been identified as an evolutionarily conserved residue forming part of the active site [Cooperman et al. (1992) Trends Biochem. Sci. 17, 262-266]. Here we determine the effect of D97E substitution on several kinetic and thermodynamic properties of E-PPase, including rate and equilibrium constants for enzyme-catalyzed PPi.Pi equilibration at pH 7.2 and 8.0, Mg2+ affinity in the presence and absence of substrate, and the Mg2+ and pH dependence of kcat and Km. We find the major effects of D97E substitution are to (a) decrease markedly the pH-independence rates of both PPi hydrolysis and, especially, PPi resynthesis on the enzyme, (b) selectively destabilize both the EMg4PPi complex and the transition state between this complex and the EMg2(MgPi)2 complex, (c) raise the pKa of the basic group "essential" for PPi hydrolysis and for productive PPi binding by 1.5 and > 2.2 log units, respectively, (d) distort a site to which Mg2+ binds in the absence of substrate such that occupancy of the site by Mg2+ no longer confers enzymatic activity, and (e) decrease the affinity of one of the two Mg2+ ions that binds to enzyme in the presence of substrate. That this multiplicity of effects arises from a single Asp to Glu substitution suggests, in the absence of any evidence for a generalized structural change, a tightly integrated active site in which the perturbation induced by conservative substitution at a single location can have widespread functional effects.