Alvan C. Hengge

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.—Cleland, W. W., Hengge, A. C. Mechanisms of phosphoryl and acyl transfer. FASEB J. 9, 1585‐1594 (1995)

Conformational Motions Regulate Phosphoryl Transfer in Related Protein Tyrosine Phosphatases

Closing the Loop Many studies have shown that protein dynamics are important to enzyme function. For example, enzyme protein movements have been shown to optimize the active site, enable binding of substrate and cofactor, and facilitate product release. Whittier et al. (p. 899) now show that in two tyrosine phosphatases, the rate of cleavage is coupled to motion of a loop. The two phosphatases have different catalytic rates; however, in both, a loop containing a catalytic residue switches between an inactive open and a catalytically competent closed state. The rates of closure are equivalent to the cleavage rates, suggesting that the leaving group tyrosine is protonated simultaneously with loop closure. Thus, tuning of the loop motion plays a regulatory role in the catalytic cycle. Differences in the rate of an internal protein loop closure are coupled to differences in enzyme reaction rates. Many studies have implicated a role for conformational motions during the catalytic cycle, acting to optimize the binding pocket or facilitate product release, but a more intimate role in the chemical reaction has not been described. We address this by monitoring active-site loop motion in two protein tyrosine phosphatases (PTPs) using nuclear magnetic resonance spectroscopy. The PTPs, YopH and PTP1B, have very different catalytic rates; however, we find in both that the active-site loop closes to its catalytically competent position at rates that mirror the phosphotyrosine cleavage kinetics. This loop contains the catalytic acid, suggesting that loop closure occurs concomitantly with the protonation of the leaving group tyrosine and explains the different kinetics of two otherwise chemically and mechanistically indistinguishable enzymes.

Insights into the reaction of protein-tyrosine phosphatase 1B: crystal structures for transition state analogs of both catalytic steps.

Catalysis by protein-tyrosine phosphatase 1B (PTP1B) occurs through a two-step mechanism involving a phosphocysteine intermediate. We have solved crystal structures for the transition state analogs for both steps. Together with previously reported crystal structures of apo-PTP1B, the Michaelis complex of an inactive mutant, the phosphoenzyme intermediate, and the product complex, a full picture of all catalytic steps can now be depicted. The transition state analog for the first catalytic step comprises a ternary complex between the catalytic cysteine of PTP1B, vanadate, and the peptide DADEYL, a fragment of a physiological substrate. The equatorial vanadate oxygen atoms bind to the P-loop, and the apical positions are occupied by the peptide tyrosine oxygen and by the PTP1B cysteine sulfur atom. The vanadate assumes a trigonal bipyramidal geometry in both transition state analog structures, with very similar apical O–O distances, denoting similar transition states for both phosphoryl transfer steps. Detailed interactions between the flanking peptide and the enzyme are discussed.

Physical Organic Perspectives on Phospho Group Transfer From Phosphates and Phosphinates

As phosphoryl transfer reactions are ubiquitous in biological chemistry, organic chemists have been very interested in the mechanisms of phosphate and phosphinate esters. Physical organic chemistry methods, including stereochemical studies, linear free energy relationships, and, most recently, heavy-atom kinetic isotope effects, have been used in the quest for mechanistic information about the chemistry of these compounds. This review summarizes what has been learned about the uncatalyzed phosphoryl transfer reactions of phosphate and phosphinate esters.

Mechanistic studies on enzyme-catalyzed phosphoryl transfer

Abstract Phosphoryl transfer reactions have essential roles throughout biochemistry. The enzymes that catalyze these reactions result in tremendous rate enhancements for their normally unreactive substrates. This fact has led to great interest in the enzymatic mechanisms, and debate as to whether the mechanisms for enzyme-catalyzed hydrolysis of phosphate esters differ from those of uncatalyzed reactions. This review summarizes the uncatalyzed reactions of monoesters, diesters and triesters. A selection of enzymatic phosphoryl transfer reactions that have been the most studied and are the best understood are discussed, with examples of phosphatases, diesterases, and triesterases.

Substrate-promoted formation of a catalytically competent binuclear center and regulation of reactivity in a glycerophosphodiesterase from Enterobacter aerogenes

The glycerophosphodiesterase (GpdQ) from Enterobacter aerogenes is a promiscuous binuclear metallohydrolase that catalyzes the hydrolysis of mono-, di-, and triester substrates, including some organophosphate pesticides and products of the degradation of nerve agents. GpdQ has attracted recent attention as a promising enzymatic bioremediator. Here, we have investigated the catalytic mechanism of this versatile enzyme using a range of techniques. An improved crystal structure (1.9 A resolution) illustrates the presence of (i) an extended hydrogen bond network in the active site, and (ii) two possible nucleophiles, i.e., water/hydroxide ligands, coordinated to one or both metal ions. While it is at present not possible to unambiguously distinguish between these two possibilities, a reaction mechanism is proposed whereby the terminally bound H2O/OH(-) acts as the nucleophile, activated via hydrogen bonding by the bridging water molecule. Furthermore, the presence of substrate promotes the formation of a catalytically competent binuclear center by significantly enhancing the binding affinity of one of the metal ions in the active site. Asn80 appears to display coordination flexibility that may modulate enzyme activity. Kinetic data suggest that the rate-limiting step occurs after hydrolysis, i.e., the release of the phosphate moiety and the concomitant dissociation of one of the metal ions and/or associated conformational changes. Thus, it is proposed that GpdQ employs an intricate regulatory mechanism for catalysis, where coordination flexibility in one of the two metal binding sites is essential for optimal activity.

Mechanistic Study of Protein Phosphatase-1 (PP1), A Catalytically Promiscuous Enzyme

The reaction catalyzed by the protein phosphatase-1 (PP1) has been examined by linear free energy relationships and kinetic isotope effects. With the substrate 4-nitrophenyl phosphate (4NPP), the reaction exhibits a bell-shaped pH-rate profile for kcat/KM indicative of catalysis by both acidic and basic residues, with kinetic pKa values of 6.0 and 7.2. The enzymatic hydrolysis of a series of aryl monoester substrates yields a Brønsted beta(lg) of -0.32, considerably less negative than that of the uncatalyzed hydrolysis of monoester dianions (-1.23). Kinetic isotope effects in the leaving group with the substrate 4NPP are (18)(V/K) bridge = 1.0170 and (15)(V/K) = 1.0010, which, compared against other enzymatic KIEs with and without general acid catalysis, are consistent with a loose transition state with partial neutralization of the leaving group. PP1 also efficiently catalyzes the hydrolysis of 4-nitrophenyl methylphosphonate (4NPMP). The enzymatic hydrolysis of a series of aryl methylphosphonate substrates yields a Brønsted beta(lg) of -0.30, smaller than the alkaline hydrolysis (-0.69) and similar to the beta(lg) measured for monoester substrates, indicative of similar transition states. The KIEs and the beta(lg) data point to a transition state for the alkaline hydrolysis of 4NPMP that is similar to that of diesters with the same leaving group. For the enzymatic reaction of 4NPMP, the KIEs are indicative of a transition state that is somewhat looser than the alkaline hydrolysis reaction and similar to the PP1-catalyzed monoester reaction. The data cumulatively point to enzymatic transition states for aryl phosphate monoester and aryl methylphosphonate hydrolysis reactions that are much more similar to one another than the nonenzymatic hydrolysis reactions of the two substrates.

The divalent metal ion in the active site of uteroferrin modulates substrate binding and catalysis

The purple acid phosphatases (PAP) are binuclear metallohydrolases that catalyze the hydrolysis of a broad range of phosphomonoester substrates. The mode of substrate binding during catalysis and the identity of the nucleophile is subject to debate. Here, we used native Fe(3+)-Fe(2+) pig PAP (uteroferrin; Uf) and its Fe(3+)-Mn(2+) derivative to investigate the effect of metal ion substitution on the mechanism of catalysis. Replacement of the Fe(2+) by Mn(2+) lowers the reactivity of Uf. However, using stopped-flow measurements it could be shown that this replacement facilitates approximately a ten-fold faster reaction between both substrate and inorganic phosphate with the chromophoric Fe(3+) site. These data also indicate that in both metal forms of Uf, phenyl phosphate hydrolysis occurs faster than formation of a mu-1,3 phosphate complex. The slower rate of interaction between substrate and the Fe(3+) site relative to catalysis suggests that the substrate is hydrolyzed while coordinated only to the divalent metal ion. The likely nucleophile is a water molecule in the second coordination sphere, activated by a hydroxide terminally coordinated to Fe(3+). The faster rates of interaction with the Fe(3+) site in the Fe(3+)-Mn(2+) derivative than the native Fe(3+)-Fe(2+) form are likely mediated via a hydrogen bond network connecting the first and second coordination spheres, and illustrate how the selection of metal ions may be important in fine-tuning the function of this enzyme.

The Catalytic Mechanism of Cdc25A Phosphatase

Cdc25 phosphatases are dual specificity phosphatases that dephosphorylate and activate cyclin-dependent kinases (CDKs), thereby effecting the progression from one phase of the cell cycle to the next. Despite its central role in the cell cycle, relatively little is known about the catalytic mechanism of Cdc25. In order to provide insights into the catalytic mechanism of Cdc25, we have performed a detailed mechanistic analysis of the catalytic domain of human Cdc25A. Our kinetic isotope effect results, Bronsted analysis, and pH dependence studies employing a range of aryl phosphates clearly indicate a dissociative transition state for the Cdc25A reaction that does not involve a general acid for the hydrolysis of substrates with low leaving group pK a values (5.45–8.05). Interestingly, our Bronsted analysis and pH dependence studies reveal that Cdc25A employs a different mechanism for the hydrolysis of substrates with high leaving group pK a values (8.68–9.99) that appears to require the protonation of glutamic acid 431. Mutation of glutamic acid 431 into glutamine leads to a dramatic drop in the hydrolysis rate for the high leaving group pK a substrates and the disappearance of the basic limb of the pH rate profile for the substrate with a leaving group pK a of 8.05, indicating that glutamic acid 431 is essential for the efficient hydrolysis of substrates with high leaving group pK a . We suggest that hydrolysis of the high leaving group pK a substrates proceeds through an unfavored but more catalytically active form of Cdc25A, and we propose several models illustrating this. Since the activity of Cdc25A toward small molecule substrates is several orders of magnitude lower than toward the physiological substrate, cyclin-CDK, we suggest that the cyclin-CDK is able to preferentially induce this more catalytically active form of Cdc25A for efficient phosphothreonine and phosphotyrosine dephosphorylation.

Impaired acid catalysis by mutation of a protein loop hinge residue in a YopH mutant revealed by crystal structures.

Catalysis by the Yersinia protein-tyrosine phosphatase YopH is significantly impaired by the mutation of the conserved Trp354 residue to Phe. Though not a catalytic residue, this Trp is a hinge residue in a conserved flexible loop (the WPD-loop) that must close during catalysis. To learn why this seemingly conservative mutation reduces catalysis by 2 orders of magnitude, we have solved high-resolution crystal structures for the W354F YopH in the absence and in the presence of tungstate and vanadate. Oxyanion binding to the P-loop in W354F is analogous to that observed in the native enzyme. However, the WPD-loop in the presence of oxyanions assumes a half-closed conformation, in contrast to the fully closed state observed in structures of the native enzyme. This observation provides an explanation for the impaired general acid catalysis observed in kinetic experiments with Trp mutants. A 1.4 A structure of the W354F mutant obtained in the presence of vanadate reveals an unusual divanadate species with a cyclic [VO](2) core, which has precedent in small molecules but has not been previously reported in a protein crystal structure.