Metal ion catalyzed hydrolysis of ethyl p-nitrophenyl phosphate.

15N isotope effects in the nitro group and 18O isotope effects in the phenolic oxygen have been measured for the hydrolysis of ethyl p-nitrophenyl phosphate catalyzed by several metal ions. Co(III)-cyclen at pH 7, 50 degrees C, gave an 15N isotope effect of 0.12% and an 18O one of 2.23%, showing that P-O cleavage is rate limiting and the bond is approximately 50% broken in the transition state. The active catalyst is a dimer and the substrate is presumably coordinated to the open site of one Co(III), and is attacked by hydroxide coordinated to the other Co(III). Co(III)-tacn under the same conditions shows a similar 15N isotope effect (0.13%), but a smaller 18O one (0.8%). Zn(II)-cyclen at pH 8.5, 80 degrees C, gave an 15N isotope effect of 0.05% and an 18O one of 0.95%, suggesting an earlier transition state. The catalyst in this case is monomeric, and thus the substrate is coordinated to one position and attacked by a cis-coordinated hydroxide. Eu(III) at pH 6.5, 50 degrees C, shows a very large 15N isotope effect of 0.34% and a 1.6% 18O isotope effect. The large 15N isotope effect argues for a late transition state or Eu(III) interaction with the nitro group, and was also seen in Eu(III)-catalyzed hydrolysis of p-nitrophenyl phosphate.

Isotope effects and medium effects on sulfuryl transfer reactions.

Kinetic isotope effects and medium effects have been measured for sulfuryl-transfer reactions of the sulfate ester p-nitrophenyl sulfate (pNPS). The results are compared to those from previous studies of phosphoryl transfer, a reaction with mechanistic similarities. The N-15 and the bridge O-18 isotope effects for the reaction of the pNPS anion are very similar to those of the p-nitrophenyl phosphate (pNPP) dianion. This indicates that in the transition states for both reactions the leaving group bears nearly a full negative charge resulting from a large degree of bond cleavage to the leaving group. The nonbridge O-18 isotope effects support the notion that the sulfuryl group resembles SO(3) in the transition state. The reaction of the neutral pNPS species in acid solution is mechanistically similar to the reaction of the pNPP monoanion. In both cases proton transfer from a nonbridge oxygen atom to the leaving group is largely complete in the transition state. Despite their mechanistic similarities, the phosphoryl- and sulfuryl-transfer reactions differ markedly in their response to medium effects. Increasing proportions of the aprotic solvent DMSO to aqueous solutions of pNPP cause dramatic rate accelerations of up to 6 orders of magnitude, but only a 50-fold rate increase is observed for pNPS. Similarly, phosphoryl transfer from the pNPP dianion to tert-amyl alcohol is 9000-fold faster than the aqueous reaction, while the sulfuryl transfer from the pNPS anion is some 40-fold slower. The enthalpic and entropic contributions to these differing medium effects have been measured and compared.

Isotope effects in the study of enzymatic phosphoryl transfer reactions.

Protein-tyrosine phosphatases and serine/threonine protein phosphatases utilize very different catalytic machinery to catalyze phosphoryl transfer reactions. Tyrosine is a better leaving group than serine or threonine, having a pK(a) more than three units lower. Has the difference in the catalytic machinery used by these enzyme families evolved as a result of the difference in the lability of their substrates? Are the transition states for phosphoryl transfer similar for the two classes of enzymes? This review summarizes what has been learned from kinetic isotope effects about the nature of enzymatic phosphoryl transfer, and how the enzymatic mechanisms compare to uncatalyzed phosphoryl transfer reactions.

The mechanism of the phosphoryl transfer catalyzed by Yersinia protein-tyrosine phosphatase: a computational and isotope effect study.

In order to evaluate various mechanistic proposals that have been made regarding the mechanism of the first step of the reaction catalyzed by protein-tyrosine phosphatases, new experimental data have been obtained, and some existing data have been carefully reevaluated. New kinetic isotope effect data for the uncatalyzed hydrolysis of p-nitrophenyl phosphate allow a better evaluation of previously reported data from enzymatic reactions with this substrate. The interpretation, and misinterpretation, of pH rate studies is considered. The pathway of this reaction has been modeled computationally and is found to be generally consistent with experimental studies, except for the extent of proton transfer to the leaving group.

Transition state analysis and requirement of Asp-262 general acid/base catalyst for full activation of dual-specificity phosphatase MKP3 by extracellular regulated kinase.

Dual-specificity phosphatase MKP3 down-regulates mitogenic signaling through dephosphorylation of extracellular regulated kinase (ERK). Unlike a simple substrate-enzyme interaction, the noncatalytic, amino-terminal domain of MKP3 can bind efficiently to ERK, leading to activation of the phosphatase catalytic domain by as much as 100-fold toward exogenous substrates. It has been suggested that ERK activates MKP3 through the stabilization of the active phosphatase conformation, enabling general acid catalysis. Here, we investigated whether Asp-262 of MKP3 is the bona fide general acid and evaluated its contribution to the catalytic steps activated by ERK. Using site-directed mutagenesis, pH rate and Brönsted analyses, kinetic isotope effects, and steady-state and rapid reaction kinetics, Asp-262 was identified as the authentic general acid catalyst, donating a proton to the leaving group oxygen during P-O bond cleavage. Kinetic isotope effects [(18)(V/K)(bridge), (18)(V/K)(nonbridge), and (15)(V/K)] were evaluated for the effect of ERK and of the D262N mutation on the transition state of the phosphoryl transfer reaction. The patterns of the three isotope effects for the reaction with native MKP3 in the presence of ERK are indicative of a reaction where the leaving group is protonated in the transition state, whereas in the D262N mutant, the leaving group departs as the anion. Even without general acid catalysis, the D262N mutant reaction is activated by ERK through increased phosphate affinity ( approximately 8-fold) and the partial stabilization of the transition state for phospho-enzyme intermediate formation ( approximately 4-fold). Based on these analyses, we estimate that dephosphorylation of phosphorylated ERK by the D262N mutant is >1000-fold lower than by native, activated MKP3. Also, the kinetic results suggest that Asp-262 functions as a general base during thiol-phosphate intermediate hydrolysis.

Mutation of Arg-166 of alkaline phosphatase alters the thio effect but not the transition state for phosphoryl transfer. Implications for the interpretation of thio effects in reactions of phosphatases.

It has been suggested that the mechanism of alkaline phosphatase (AP) is associative, or triester-like, because phosphorothioate monoesters are hydrolyzed by AP approximately 10(2)-fold slower than phosphate monoesters. This "thio effect" is similar to that observed for the nonenzymatic hydrolysis of phosphate triesters, and is the inverse of that observed for the nonenzymatic hydrolysis of phosphate monoesters. The latter reactions proceed by loose, dissociative transition states, in contrast to reactions of triesters, which have tight, associative transition states. Wild-type alkaline phosphatase catalyzes the hydrolysis of p-nitrophenyl phosphate approximately 70 times faster than p-nitrophenyl phosphorothioate. In contrast, the R166A mutant alkaline phosphatase enzyme, in which the active site arginine at position 166 is replaced with an alanine, hydrolyzes p-nitrophenyl phosphate only about 3 times faster than p-nitrophenyl phosphorothioate. Despite this approximately 23-fold change in the magnitude of the thio effects, the magnitudes of Bronsted beta(lg) for the native AP (-0.77 +/- 0.09) and the R166A mutant (-0.78 +/- 0. 06) are the same. The identical values for the beta(lg) indicate that the transition states are similar for the reactions catalyzed by the wild-type and the R166A mutant enzymes. The fact that a significant change in the thio effect is not accompanied by a change in the beta(lg) indicates that the thio effect is not a reliable reporter for the transition state of the enzymatic phosphoryl transfer reaction. This result has important implications for the interpretation of thio effects in enzymatic reactions.

Effects on general acid catalysis from mutations of the invariant tryptophan and arginine residues in the protein tyrosine phosphatase from Yersinia.

General acid catalysis in protein tyrosine phosphatases (PTPases) is accomplished by a conserved Asp residue, which is brought into position for catalysis by movement of a flexible loop that occurs upon binding of substrate. With the PTPase from Yersinia, we have examined the effect on general acid catalysis caused by mutations to two conserved residues that are integral to this conformation change. Residue Trp354 is at a hinge of the loop, and Arg409 forms hydrogen bonding and ionic interactions with the phosphoryl group of substrates. Trp354 was mutated to Phe and to Ala, and residue Arg409 was mutated to Lys and to Ala. The four mutant enzymes were studied using steady state kinetics and heavy-atom isotope effects with the substrate p-nitrophenyl phosphate. The data indicate that mutation of the hinge residue Trp354 to Ala completely disables general acid catalysis. In the Phe mutant, general acid catalysis is partially effective, but the proton is only partially transferred in the transition state, in contrast to the native enzyme where proton transfer to the leaving group is virtually complete. Mutation of Arg409 to Lys has a minimal effect on the K(m), while this parameter is increased 30-fold in the Ala mutant. The k(cat) values for R409K and for R409A are about 4 orders of magnitude lower than that for the native enzyme. General acid catalysis is rendered inoperative by the Lys mutation, but partial proton transfer during catalysis still occurs in the Ala mutant. Structural explanations for the differential effects of these mutations on movement of the flexible loop that enables general acid catalysis are presented.

Comparison of the reaction progress of calcineurin with Mn2+ and Mg2+.

Activation of calcineurin by Mn2+ and Mg2+ was compared using a heavy atom isotope analogue of the substrate p-nitrophenyl phosphate (pNPP). Heavy atom isotope effects were measured for Mg2+ activation and compared to published results of the isotope effects with Mn2+ as the activating metal. Isotope effects were measured for the kinetic parameter Vmax/Km at the nonbridging oxygen atoms [18(V/K)nonbridge]; at the position of bond cleavage in the bridging oxygen atom [18(V/K)bridge]; and at the nitrogen atom in the nitrophenol leaving group [15(V/K)]. The isotope effects increased in magnitude upon changing from an optimal pH to a nonoptimal pH; the 18(V/K)bridge effect increased from 1.0154 (+/-0.0007) to 1.0198 (+/-0.0002), and the 15(V/K) effect increased from 1.0018 (+/-0. 0002) to 1.0021 (+/-0.0003). The value for 18(V/K)nonbridge is 0. 9910 (+/-0.0003) at pH 7.0. As with Mn2+, the 18(V/K)nonbridge isotope effect indicated that the dianion was the substrate for catalysis, and that a dissociative transition state was operative for the phosphoryl transfer. Comparison to results for Mn2+ activation suggested that chemistry was more rate-limiting with Mg2+ than with Mn2+. Changing the activating metal concentration showed opposite trends with increasing Mg2+ increasing the commitment factor and seemingly making the chemistry less rate-limiting. The influence of viscosity was evaluated as well to gauge the role of chemistry. The activation of calcineurin-catalyzed hydrolysis of pNPP1 by Mg2+ or Mn2+ at pH 7.0 was compared in the presence of viscogens, glycerol and poly(ethylene glycol). Increasing glycerol caused different effects with the two activators. With Mn2+ as the activator, calcineurin activity showed a normal response with kcat and kcat/Km decreasing with viscosity. There was an inverse response with Mg2+ as the activator as values of kcat/Km increased with viscosity. From values of the normalized kcat/Km with Mn2+, the chemistry was found to be partially rate-limiting, consistent with previous heavy atom isotope studies (22). The effect observed for Mg2+ seems consistent with a change in the rate-limiting step for the two different metals at pH 7.0.

Isotope effect studies on the calcineurin phosphoryl-transfer reaction: transition state structure and effect of calmodulin and Mn2+.

The hydrolysis of p-nitrophenyl phosphate (pNPP) catalyzed by calcineurin has been studied by measurement of heavy-atom isotope effects in the substrate. The isotope effects were measured at the nonbridging oxygen atoms [18(V/K)nonbridge], at the position of bond cleavage in the bridging oxygen atom [18(V/K)bridge], and at the nitrogen atom in the nitrophenol leaving group [15(V/K)]. The isotope effects increased in magnitude upon moving from the pH optimum of 7.0 to 8.5; 18(V/K)bridge increased from 1.0072 to 1.0115, and 15(V/K) from 1.0006 to 1.0014. The value for 18(V/K)nonbridge is 0.9942 at pH 8.5. These data are consistent with P-O bond cleavage being partially rate-limiting at the pH optimum and more so at the higher pH. The 18(V/K)nonbridge isotope effect indicates that the dianion is the substrate for catalysis, and a dissociative transition state is operative for phosphoryl transfer. Increasing the concentration of the activating metal ion Mn2+ at pH 7.0 from 1 mM to 5 mM increases the magnitude of the isotope effects by an amount similar to that observed with the shift in pH from 7.0 to 8.5, indicative of a change in the commitment factor in the kinetic mechanism so as to make the chemical step more rate-limiting.

Examination of the transition state of the low-molecular mass small tyrosine phosphatase 1. Comparisons with other protein phosphatases.

The reactions of p-nitrophenyl phosphate (pNPP) with the low-molecular mass tyrosine phosphatase Stp1 and with the mutants D128N, D128A, D128E, and S18A have been studied by measurement of heavy-atom isotope effects in the substrate. The isotope effects were measured at the nonbridging oxygen atoms [18(V/K)nonbridge], at the bridging oxygen atom (the site of bond cleavage) [18(V/K)bridge], and at the nitrogen atom in the nitrophenol leaving group [15(V/K)]. The results with native Stp1 were 1.0160 +/- 0.0005 for 18(V/K)bridge, 1.0007 +/- 0.0001 for 15(V/K), and 1.0018 +/- 0.0003 for 18(V/K)nonbridge. The values for 18(V/K)nonbridge and 15(V/K) differ from those previously measured with other protein-tyrosine phosphatases and from those of the aqueous hydrolysis reaction of pNPP. The values indicate that in the transition state of the native Stp1 reaction the leaving group bears a partial negative charge, and there is nucleophilic interaction between the Cys nucleophile, and the phosphoryl group, causing some decrease in the nonbridge P-O bond order. The transition state remains highly dissociative with respect to the degree of bond cleavage to the leaving group. Mutation of the general acid from aspartic acid to glutamic acid slows catalysis but causes no change in the isotope effects and thus does not alter the degree of proton transfer to the leaving group in the transition state. Mutations of this residue to asparagine or alanine give values for 18(V/K)bridge of about 1.029, for 15(V/K) of about 1.003, and for 18(V/K)nonbridge of 1.0010 (D128A) to 1.0024 (D128N). These data indicate a dissociative transition state with the leaving group departing as the nitrophenolate anion and indicate more nucleophilic participation than in the aqueous hydrolysis of the pNPP dianion, just as in the native enzyme. The isotope effects with the S18A mutant, in which a hydrogen bonding stabilization of the anionic Cys nucleophile has been removed, were within experimental error of those with the native enzyme, indicating that this alteration has no effect on the transition state for phosphoryl transfer from pNPP.

Transition-state structures for the native dual-specific phosphatase VHR and D92N and S131A mutants. Contributions to the driving force for catalysis.

Isotope effects have been measured for the reaction of the human dual-specific phosphatase VHR with p-nitrophenyl phosphate (pNPP). Isotope effects in the nonbridge oxygen atoms, in the bridge oxygen atom, and in the nitrogen atom were measured by the competitive method using an isotope ratio mass spectrometer. These are isotope effects on V/K, and give information on the chemical step of phosphoryl transfer from substrate to the enzymatic nucleophile Cys-124. With native VHR, 18(V/K)nonbridge = 1.0003 +/- 0.0003, 18(V/K)bridge = 1.0118 +/- 0.0020, and 15(V/K) = 0.9999 +/- 0.0004. The values are similar to the intrinsic isotope effects for the uncatalyzed reaction, indicating that the chemical step is rate-limiting with the pNPP substrate. The transition-state structure resembles that for the uncatalyzed reaction and those previously found for the protein-tyrosine phosphatases YOP51 and PTP1, and is highly dissociative with P-O bond cleavage and protonation of the leaving group by the general acid Asp-92 both well advanced. The D92N mutant exhibits a transition state similar to that of the uncatalyzed reaction of the pNPP dianion, dissociative and with the leaving group departing as the nitrophenolate anion. The S131A mutation causes an increase in the pKa of the nucleophilic Cys, but the isotope effect data are unchanged from those for the native enzyme, indicating no effects of this increase in nucleophilicity on transition-state structure. The double mutant D92N/S131A manifests both the increase in pKa of the nucleophilic Cys and the loss of general acid assistance to the leaving group. In the absence of the general acid, the change in nucleophile pKa results in an increase in 18(V/K)nonbridge from 1.0019 (with D92N) to 1.0031 (with D92N/S131A), indicating loss of P-O nonbridge bond order in the transition state. It is concluded that this is more likely caused by electrostatic effects rather than resulting from increased nucleophile-phosphorus bonding in a less dissociative transition state, although the latter explanation cannot be excluded on the basis of the present data. Electrostatic effects between the thiolate anion nucleophile and the phosphoryl group may be an important part of the driving force for catalysis in this family of enzymes.

Mechanisms of phosphoryl and acyl transfer.

Acyl and phosphoryl transfer are important biochemical reactions. We have been using isotope effects caused by O-18, N-15, C-13, and deuterium substitution to examine the mechanisms and transition-state structures for enzymatic and nonenzymatic transfers of phosphoryl and acyl groups. Phosphoryl transfers from phosphate monoesters are highly dissociative, although not truly stepwise in protic solvents or in enzymatic reactions. Phosphodiesters show ANDN (SN2) reactions, whereas triester hydrolyses involve more associative transition states. Except under acidic conditions, true phosphorane intermediates likely form only when geometry requires (i.e., when the leaving group cannot be axial until pseudorotation of the phosphorane). Enzymatic phosphoryl transfers appear similar to nonenzymatic ones. The reactions of oxygen or sulfur nucleophiles with p-nitrophenyl acetate are concerted with a tetrahedral transition state, which is more dissociative with sulfur than with oxygen. Enzymatic hydrolyses of p-nitrophenyl acetate are also concerted reactions.

Nature of the transition state of the protein-tyrosine phosphatase-catalyzed reaction.

The dephosphorylation of p-nitrophenyl phosphate by Yersinia protein-tyrosine phosphatase (PTPase) and by the rat PTP1 has been examined by measurement of heavy-atom isotope effects at the nonbridge oxygen atoms [18(V/K)nonbridge], at the bridging oxygen atom [18(V/K)bridge], and the nitrogen atom in the leaving group 15(V/K). The effects were measured using an isotope ratio mass spectrometer by the competitive method and thus are effects on V/K. The results for the Yersinia PTPase and rat PTP1, respectively, are 1.0142 +/- 0.0004 and 1.0152 +/- 0.0006 for 18(V/K)bridge; 0.9981 +/- 0.0015 and 0.9998 +/- 0.0013 for 18(V/K)nonbridge; and 1.0001 +/- 0.0002 and 0.9999 +/- 0.0003 for 15(V/K). The magnitudes of the isotope effects are similar to the intrinsic values measured in solution, indicating that the chemical step is rate-limiting for V/K. The transition state for phosphorylation of the enzyme is dissociative in character, as is the case in solution. Binding of the substrate is rapid and reversible, as is the binding-induced conformational change which brings the catalytic general acid into the active site. Cleavage of the P-O bond and proton transfer from the general acid Asp to the leaving group are both far advanced in the transition state, and there is no development of negative charge on the departing leaving group. Experiments with several general acid mutants give values for 18(V/K)bridge of around 1.0280, 15(V/K) of about 1.002, and 18(V/K)nonbridge effects of from 1.0007 to 1.0022. These data indicate a dissociative transition state with the leaving group departing as the nitrophenolate anion but suggest more nucleophilic participation than in the solution reaction.