Crystal structure of Streptococcus mutans pyrophosphatase: a new fold for an old mechanism.

BACKGROUND: Streptococcus mutans pyrophosphatase (Sm-PPase) is a member of a relatively uncommon but widely dispersed sequence family (family II) of inorganic pyrophosphatases. A structure will answer two main questions: is it structurally similar to the family I PPases, and is the mechanism similar? RESULTS: The first family II PPase structure, that of homodimeric Sm-PPase complexed with metal and sulfate ions, has been solved by X-ray crystallography at 2.2 A resolution. The tertiary fold of Sm-PPase consists of a 189 residue alpha/beta N-terminal domain and a 114 residue mixed beta sheet C-terminal domain and bears no resemblance to family I PPase, even though the arrangement of active site ligands and the residues that bind them shows significant similarity. The preference for Mn2+ over Mg2+ in family II PPases is explained by the histidine ligands and bidentate carboxylate coordination. The active site is located at the domain interface. The C-terminal domain is hinged to the N-terminal domain and exists in both closed and open conformations. CONCLUSIONS: The active site similiarities, including a water coordinated to two metal ions, suggest that the family II PPase mechanism is "analogous" (not "homologous") to that of family I PPases. This is a remarkable example of convergent evolution. The large change in C-terminal conformation suggests that domain closure might be the mechanism by which Sm-PPase achieves specificity for pyrophosphate over other polyphosphates.

Probing essential water in yeast pyrophosphatase by directed mutagenesis and fluoride inhibition measurements.

The pattern of yeast pyrophosphatase (Y-PPase) inhibition by fluoride suggests that it replaces active site Mg(2+)-bound nucleophilic water, for which two different locations were proposed previously. To localize the bound fluoride, we investigate here the effects of mutating Tyr(93) and five dicarboxylic amino acid residues forming two metal binding sites in Y-PPase on its inhibition by fluoride and its five catalytic functions (steady-state PP(i) hydrolysis and synthesis, formation of enzyme-bound PP(i) at equilibrium, phosphate-water oxygen exchange, and Mg(2+) binding). D117E substitution had the largest effect on fluoride binding and made the P-O bond cleavage step rate-limiting in the catalytic cycle, consistent with the mechanism in which the nucleophile is coordinated by two metal ions and Asp(117). The effects of the mutations on PP(i) hydrolysis (as characterized by the catalytic constant and the net rate constant for P-O bond cleavage) were in general larger than on PP(i) synthesis (as characterized by the net rate constant for PP(i) release from active site). The effects of fluoride on the Y-PPase variants confirmed that PPase catalysis involves two enzyme.PP(i) intermediates, which bind fluoride with greatly different rates (Baykov, A. A., Fabrichniy, I. P., Pohjanjoki, P., Zyryanov, A. B., and Lahti, R. (2000) Biochemistry 39, 11939-11947). A mechanism for the structural changes underlying the interconversion of the enzyme.PP(i) intermediates is proposed.

Catalytically important ionizations along the reaction pathway of yeast pyrophosphatase.

Five catalytic functions of yeast inorganic pyrophosphatase were measured over wide pH ranges: steady-state PP(i) hydrolysis (pH 4. 8-10) and synthesis (6.3-9.3), phosphate-water oxygen exchange (pH 4. 8-9.3), equilibrium formation of enzyme-bound PP(i) (pH 4.8-9.3), and Mg(2+) binding (pH 5.5-9.3). These data confirmed that enzyme-PP(i) intermediate undergoes isomerization in the reaction cycle and allowed estimation of the microscopic rate constant for chemical bond breakage and the macroscopic rate constant for PP(i) release. The isomerization was found to decrease the pK(a) of the essential group in the enzyme-PP(i) intermediate, presumably nucleophilic water, from >7 to 5.85. Protonation of the isomerized enzyme-PP(i) intermediate decelerates PP(i) hydrolysis but accelerates PP(i) release by affecting the back isomerization. The binding of two Mg(2+) ions to free enzyme requires about five basic groups with a mean pK(a) of 6.3. An acidic group with a pK(a) approximately 9 is modulatory in PP(i) hydrolysis and metal ion binding, suggesting that this group maintains overall enzyme structure rather than being directly involved in catalysis.

Fluoride effects along the reaction pathway of pyrophosphatase: evidence for a second enzyme.pyrophosphate intermediate.

The fluoride ion is a potent and specific inhibitor of cytoplasmic pyrophosphatase (PPase). Fluoride action on yeast PPase during PP(i) hydrolysis involves rapid and slow phases, the latter being only slowly reversible [Smirnova, I. N., and Baykov, A. A. (1983) Biokhimiya 48, 1643-1653]. A similar behavior is observed during yeast PPase catalyzed PP(i) synthesis. The amount of enzyme.PP(i) complex formed from solution P(i) exhibits a rapid drop upon addition of fluoride, followed, at pH 7.2, by a slow increase to nearly 100% of the total enzyme. The slow reaction results in enzyme inactivation, which is not immediately reversed by dilution. These data show that fluoride binds to an enzyme.PP(i) intermediate during the slow phase and to an enzyme.P(i) intermediate during the rapid phase of the inhibition. In Escherichia coli PPase, the enzyme.PP(i) intermediate binds F(-) rapidly, explaining the lack of time dependence in the inhibition of this enzyme. The enzyme.PP(i) intermediate formed during PP(i) hydrolysis binds fluoride much faster (yeast PPase) or tighter (E. coli PPase) than the similar complex existing at equilibrium with P(i). It is concluded that PPase catalysis involves two enzyme.PP(i) intermediates, of which only one (immediately following PP(i) addition and predominating at acidic pH) can bind fluoride. Simulation experiments have indicated that interconversion of the enzyme.PP(i) intermediates is a partially rate-limiting step in the direction of hydrolysis and an exclusively rate-limiting step in the direction of synthesis.

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.

Effect of Asp-97-->Glu substitution on the pH dependence of catalysis by inorganic pyrophosphatase of Escherichia coli.

Substitution of Glu for the evolutionarily conserved Asp-97 in the active site of Escherichia coli inorganic pyrophosphatase increases the apparent pKa of the essential acidic group controlling the catalytic constant for pyrophosphate hydrolysis. In combination with previously reported data, this fact suggests that activity decreases in alkaline medium because of decreased rate of the release of the first molecule of the product phosphate from the active site.