Common-type acylphosphatase: steady-state kinetics and leaving-group dependence

Biological phosphoryl-transfer reactions: understanding mechanism and catalysis

Phosphoryl-transfer reactions are central to biology. These reactions also have some of the slowest nonenzymatic rates and thus require enormous rate accelerations from biological catalysts. Despite the central importance of phosphoryl transfer and the fascinating catalytic challenges it presents, substantial confusion persists about the properties of these reactions. This confusion exists despite decades of research on the chemical mechanisms underlying these reactions. Here we review phosphoryl-transfer reactions with the goal of providing the reader with the conceptual and experimental background to understand this body of work, to evaluate new results and proposals, and to apply this understanding to enzymes. We describe likely resolutions to some controversies, while emphasizing the limits of our current approaches and understanding. We apply this understanding to enzyme-catalyzed phosphoryl transfer and provide illustrative examples of how this mechanistic background can guide and deepen our understanding of enzymes and their mechanisms of action. Finally, we present important future challenges for this field.

A rigidifying salt-bridge favors the activity of thermophilic enzyme at high temperatures at the expense of low-temperature activity

BACKGROUND

Thermophilic enzymes are often less active than their mesophilic homologues at low temperatures. One hypothesis to explain this observation is that the extra stabilizing interactions increase the rigidity of thermophilic enzymes and hence reduce their activity. Here we employed a thermophilic acylphosphatase from Pyrococcus horikoshii and its homologous mesophilic acylphosphatase from human as a model to study how local rigidity of an active-site residue affects the enzymatic activity.

METHODS AND FINDINGS

Acylphosphatases have a unique structural feature that its conserved active-site arginine residue forms a salt-bridge with the C-terminal carboxyl group only in thermophilic acylphosphatases, but not in mesophilic acylphosphatases. We perturbed the local rigidity of this active-site residue by removing the salt-bridge in the thermophilic acylphosphatase and by introducing the salt-bridge in the mesophilic homologue. The mutagenesis design was confirmed by x-ray crystallography. Removing the salt-bridge in the thermophilic enzyme lowered the activation energy that decreased the activation enthalpy and entropy. Conversely, the introduction of the salt-bridge to the mesophilic homologue increased the activation energy and resulted in increases in both activation enthalpy and entropy. Revealed by molecular dynamics simulations, the unrestrained arginine residue can populate more rotamer conformations, and the loss of this conformational freedom upon the formation of transition state justified the observed reduction in activation entropy.

CONCLUSIONS

Our results support the conclusion that restricting the active-site flexibility entropically favors the enzymatic activity at high temperatures. However, the accompanying enthalpy-entropy compensation leads to a stronger temperature-dependency of the enzymatic activity, which explains the less active nature of the thermophilic enzymes at low temperatures.

PduL is an evolutionarily distinct phosphotransacylase involved in B12-dependent 1,2-propanediol degradation by Salmonella enterica serovar typhimurium LT2

Salmonella enterica degrades 1,2-propanediol (1,2-PD) in a coenzyme B(12)-dependent manner. Previous enzymatic assays of crude cell extracts indicated that a phosphotransacylase (PTAC) was needed for this process, but the enzyme involved was not identified. Here, we show that the pduL gene encodes an evolutionarily distinct PTAC used for 1,2-PD degradation. Growth tests showed that pduL mutants were unable to ferment 1,2-PD and were also impaired for aerobic growth on this compound. Enzyme assays showed that cell extracts from a pduL mutant lacked measurable PTAC activity in a background that also carried a pta mutation (the pta gene was previously shown to encode a PTAC enzyme). Ectopic expression of pduL corrected the growth defects of a pta mutant. PduL fused to eight C-terminal histidine residues (PduL-His(8)) was purified, and its kinetic constants were determined: the V(max) was 51.7 +/- 7.6 micromol min(-1) mg(-1), and the K(m) values for propionyl-PO(4)(2-) and acetyl-PO(4)(2-) were 0.61 and 0.97 mM, respectively. Sequence analyses showed that PduL is unrelated in amino acid sequence to known PTAC enzymes and that PduL homologues are distributed among at least 49 bacterial species but are absent from the Archaea and Eukarya.

Alkaline phosphatase mono- and diesterase reactions: comparative transition state analysis

Enzyme-catalyzed phosphoryl transfer reactions have frequently been suggested to proceed through transition states that are altered from their solution counterparts. Previous work with Escherichia coli alkaline phosphatase (AP), however, suggests that this enzyme catalyzes the hydrolysis of phosphate monoesters through a loose, dissociative transition state, similar to that in solution. AP also exhibits catalytic promiscuity, with a low level of phosphodiesterase activity, despite the tighter, more associative transition state for phosphate diester hydrolysis in solution. Because AP is evolutionarily optimized for phosphate monoester hydrolysis, it is possible that the active site environment alters the transition state for diester hydrolysis to be looser in its bonding to the incoming and outgoing groups. To test this possibility, we have measured the nonenzymatic and AP-catalyzed rate of reaction for a series of substituted methyl phenyl phosphate diesters. The values of beta(lg) and additional data suggest that the transition state for AP-catalyzed phosphate diester hydrolysis is indistinguishable from that in solution. Instead of altering transition state structure, AP catalyzes phosphoryl transfer reactions by recognizing and stabilizing transition states similar to those in aqueous solution. The AP active site therefore has the ability to recognize different transition states, a property that could assist in the evolutionary optimization of promiscuous activities.

Crystal structure of a hyperthermophilic archaeal acylphosphatase from Pyrococcus horikoshii--structural insights into enzymatic catalysis, thermostability, and dimerization

Acylphosphatases catalyze the hydrolysis of the carboxyl-phosphate bond in acyl phosphates. Although acylphosphatase-like sequences are found in all three domains of life, no structure of acylphosphatase has been reported for bacteria and archaea so far. Here, we report the characterization of enzymatic activities and crystal structure of an archaeal acylphosphatase. A putative acylphosphatase gene (PhAcP) was cloned from the genomic DNA of Pyrococcus horikoshii and was expressed in Escherichia coli. Enzymatic parameters of the recombinant PhAcP were measured using benzoyl phosphate as the substrate. Our data suggest that, while PhAcP is less efficient than other mammalian homologues at 25 degrees C, the thermophilic enzyme is fully active at the optimal growth temperature (98 degrees C) of P. horikoshii. PhAcP is extremely stable; its apparent melting temperature was 111.5 degrees C and free energy of unfolding at 25 degrees C was 54 kJ mol(-)(1). The 1.5 A crystal structure of PhAcP adopts an alpha/beta sandwich fold that is common to other acylphosphatases. PhAcP forms a dimer in the crystal structure via antiparallel association of strand 4. Structural comparison to mesophilic acylphosphatases reveals significant differences in the conformation of the L5 loop connecting strands 4 and 5. The extreme thermostability of PhAcP can be attributed to an extensive ion-pair network consisting of 13 charge residues on the beta sheet of the protein. The reduced catalytic efficiency of PhAcP at 25 degrees C may be due to a less flexible active-site residue, Arg20, which forms a salt bridge to the C-terminal carboxyl group. New insights into catalysis were gained by docking acetyl phosphate to the active site of PhAcP.

A nucleophilic catalysis step is involved in the hydrolysis of aryl phosphate monoesters by human CT acylphosphatase

Acylphosphatase, one of the smallest enzymes, is expressed in all organisms. It displays hydrolytic activity on acyl phosphates, nucleoside di- and triphosphates, aryl phosphate monoesters, and polynucleotides, with acyl phosphates being the most specific substrates in vitro. The mechanism of catalysis for human acylphosphatase (the organ-common type isoenzyme) was investigated using both aryl phosphate monoesters and acyl phosphates as substrates. The enzyme is able to catalyze phosphotransfer from p-nitrophenyl phosphate to glycerol (but not from benzoyl phosphate to glycerol), as well as the inorganic phosphate-H(2)18O oxygen exchange reaction in the absence of carboxylic acids or phenols. In short, our findings point to two different catalytic pathways for aryl phosphate monoesters and acyl phosphates. In particular, in the aryl phosphate monoester hydrolysis pathway, an enzyme-phosphate covalent intermediate is formed, whereas the hydrolysis of acyl phosphates seems a more simple process in which the Michaelis complex is attacked directly by a water molecule generating the reaction products. The formation of an enzyme-phosphate covalent complex is consistent with the experiments of isotope exchange and transphosphorylation from substrates to glycerol, as well as with the measurements of the Brønsted free energy relationships using a panel of aryl phosphates with different structures. His-25 involvement in the formation of the enzyme-phosphate covalent complex during the hydrolysis of aryl phosphate monoesters finds significant confirmation in experiments performed with the H25Q mutated enzyme.

Alkaline phosphatase revisited: hydrolysis of alkyl phosphates

Escherichia coli alkaline phosphatase (AP) is the prototypical two metal ion catalyst with two divalent zinc ions bound approximately 4 A apart in the active site. Studies spanning half a century have elucidated many structural and mechanistic features of this enzyme, rendering it an attractive model for investigating the potent catalytic power of bimetallic centers. Unfortunately, fundamental mechanistic features have been obscured by limitations with the standard assays. These assays generate concentrations of inorganic phosphate (P(i)) in excess of its inhibition constant (K(i) approximately 1 muM). This tight binding by P(i) has affected the majority of published kinetic constants. Furthermore, binding limits k(cat)/K(m) for reaction of p-nitrophenyl phosphate, the most commonly employed substrate. We describe a sensitive (32)P-based assay for hydrolysis of alkyl phosphates that avoids the complication of product inhibition. We have revisited basic mechanistic features of AP with these alkyl phosphate substrates. The results suggest that the chemical step for phosphorylation of the enzyme limits k(cat)/K(m). The pH-rate profile and additional results suggest that the serine nucleophile is active in its anionic form and has a pK(a) of < or = 5.5 in the free enzyme. An inactivating pK(a) of 8.0 is observed for binding of both substrates and inhibitors, and we suggest that this corresponds to ionization of a zinc-coordinated water molecule. Counter to previous suggestions, inorganic phosphate dianion appears to bind to the highly charged AP active site at least as strongly as the trianion. The dependence of k(cat)/K(m) on the pK(a) of the leaving group follows a Brønsted correlation with a slope of beta(lg) = -0.85 +/- 0.1, differing substantially from the previously reported value of -0.2 obtained from data with a less sensitive assay. This steep leaving group dependence is consistent with a largely dissociative transition state for AP-catalyzed hydrolysis of phosphate monoesters. The new (32)P-based assay employed herein will facilitate continued dissection of the AP reaction by providing a means to readily follow the chemical step for phosphorylation of the enzyme.

Acylphosphatase possesses nucleoside triphosphatase and nucleoside diphosphatase activities

We have demonstrated that acylphosphatase possesses ATP-diphosphohydrolase (apyrase-like) activity. In fact, acylphosphatase first catalyses the hydrolysis of the gamma-phosphate group of nucleoside triphosphates, and then attacks the beta-phosphate group of the initially produced nucleoside diphosphates, generating nucleoside monophosphates. In contrast, it binds nucleoside monophosphates but does not catalyse their hydrolyses. The calculated k(cat) values for the nucleoside triphosphatase activity of acylphosphatase are of the same order of magnitude as those displayed by certain G-proteins. An acidic environment enhances the apyrase-like activity of acylphosphatase. The true nucleotide substrates of acylphosphatase are free nucleoside di- and triphosphates, as indicated by the Mg(2+) ion inhibition of the activity. We have also demonstrated that, although nucleoside triphosphates are still hydrolysed at pH 7.2 and 37 degrees C, in the presence of millimolar Mg(2+) concentrations this occurs at a lower rate. Taken together with the previously observed strong increase of acylphosphatase levels during induced cell differentiation, our findings suggest that acylphosphatase plays an active role in the differentiation process (as well as in other processes, such as apoptosis) by modulating the ratio between the cellular levels of nucleoside diphosphates and nucleoside triphosphates.

The amino acid sequences of two acylphosphatase isoforms from fish muscle (Lamna nasus)

Two acylphosphatase isoenzymes have been purified from Lamna nasus muscle, and their complete amino acid sequences have been determined. The former (E1) consists of 99 amino acid residues, while the latter (E2) consists of 102 residues. Both are acetylated at their N termini. E1 has the FFRK active site motif characteristic of all common-type acylphosphatase isoenzymes, whereas E2 contains the CFRM active site motif characteristic of all muscle-type acylphosphatase isoenzymes. They have quite similar kinetic properties. The comparison of sequences of fish E1 and E2 isoenzymes with other known mammalian and bird acylphosphatases reveals that the E2 isoenzyme has an N terminus tail, four residues long, similar to those previously found in all known bird species muscle-type isoenzymes. Among organ-common-type acylphosphatases about 50% of residues are completely conserved, whereas about 60% of muscle-type acylphosphatase residues are completely conserved, indicating that the latter type of isoenzyme has a slower evolutionary rate than the former. The sequences of E1 and E2 acylphosphatases from L. nasus represent the first primary structures of this kind of enzyme determined among fish species.