Inactivation of Aeromonas hydrophila metallo-beta-lactamase by cephamycins and moxalactam.

Incubation of moxalactam and cefoxitin with the Aeromonas hydrophila metallo-beta-lactamase CphA leads to enzyme-catalyzed hydrolysis of both compounds and to irreversible inactivation of the enzyme by the reaction products. As shown by electrospray mass spectrometry, the inactivation of CphA by cefoxitin and moxalactam is accompanied by the formation of stable adducts with mass increases of 445 and 111 Da, respectively. The single thiol group of the inactivated enzyme is no longer titrable, and dithiothreitol treatment of the complexes partially restores the catalytic activity. The mechanism of inactivation by moxalactam was studied in detail. Hydrolysis of moxalactam is followed by elimination of the 3' leaving group (5-mercapto-1-methyltetrazole), which forms a disulfide bond with the cysteine residue of CphA located in the active site. Interestingly, this reaction is catalyzed by cacodylate.     

A theoretical study of torsional flexibility in the active site of aspartic proteinases: Implications for catalysis

We have performed ab initio Hartree-Fock self-consistent field calculations on the active site of endothiapepsin. The active site was modeled as a formic acid/formate anion moiety (representing the catalytic aspartates, Asp-32 and -215) and a bound water molecule. Residues Gly-34, Ser-35, Gly-217, and Thr-218, which all form hydrogen bonds to the active site, were modeled using formamide and methanol molecules. The water molecule, which is generally believed to function as the attacking nucleophile in catalysis, was allowed to bind to the active site in four distinct configurations. The geometry of each configuration was optimized using two basis sets (4-31G and 4-31G*). The results indicate that in the native enzyme the nucleophilic water is bound in a catalytically inert configuration. However, by rotating the carboxyl group of Asp-32 by about 90° the water molecule can be reorientated to attack the scissile bond of the substrate. A model of the bound enzyme-substrate complex was constructed from the crystal structure of a difluorostatone inhibitor complexed with endothiapepsin. This model suggests that the substrate itself initiates the reorientation of the nucleophilic water immediately prior to catalysis by forcing the carboxyl group of Asp-32 to rotate. The theoretical results predict that the active site of endothiapepsin undergoes a large distortion during substrate binding and this observation has been used to explain some of the kinetics results which have been reported for mutant aspartic proteinases.     

On the mechanism of the metallo-beta-lactamase from Bacteroides fragilis.

The catalytic mechanism of metallo-beta-lactamase from Bacteroides fragilis, a dinuclear Zn(II)-containing enzyme responsible for multiple antibiotic resistance, has been investigated by using nitrocefin as a substrate. Rapid-scanning and single-wavelength stopped-flow studies revealed the accumulation during turnover of an enzyme-bound intermediate with intense absorbance at 665 nm (epsilon = 30 000 M(-1) cm(-1)). The proposed minimum kinetic mechanism for the B. fragilis metallo-beta-lactamase-catalyzed nitrocefin hydrolysis [Wang, Z., and Benkovic, S. J. (1998) J. Biol. Chem. 273, 22402-22408] was confirmed, and more accurate kinetic parameters were obtained from computer simulations and fitting. The intermediate was shown to be a novel anionic species bound to the enzyme through a Zn-acyl linkage and contains a negatively charged nitrogen leaving group. This is the first time such an intermediate was observed in the catalytic cycle of a Zn(II)-containing hydrolase and is evidence for a unique beta-lactam hydrolysis mechanism in which the amine can leave as an anion; prior protonation is not required. The electrostatic interaction between the negatively charged intermediate and the positively charged dinuclear Zn(II) center of the enzyme is important for stabilization of the intermediate. The catalytic reaction was accelerated in the presence of exogenous nucleophiles or anions, and neither the product nor the enzyme was modified during turnover, indicating that a Zn-bound hydroxide (rather than Asp-103) is the active site nucleophile. On the basis of all the information on hand, a catalytic mechanism of the B. fragilis metallo-beta-lactamase is proposed.     

Divergence of chemical function in the alkaline phosphatase superfamily: structure and mechanism of the P-C bond cleaving enzyme phosphonoacetate hydrolase

Phosphonates constitute a class of natural products that mimic the properties of the more common organophosphate ester metabolite yet are not readily degraded owing to the direct linkage of the phosphorus atom to the carbon atom. Phosphonate hydrolases have evolved to allow bacteria to utilize environmental phosphonates as a source of carbon and phosphorus. The work reported in this paper examines one such enzyme, phosphonoacetate hydrolase. By using a bioinformatic approach, we circumscribed the biological range of phosphonoacetate hydrolase to a select group of bacterial species from different classes of Proteobacteria. In addition, using gene context, we identified a novel 2-aminoethylphosphonate degradation pathway in which phosphonoacetate hydrolase is a participant. The X-ray structure of phosphonoformate-bound phosphonoacetate hydrolase was determined to reveal that this enzyme is most closely related to nucleotide pyrophosphatase/diesterase, a promiscuous two-zinc ion metalloenzyme of the alkaline phosphatase enzyme superfamily. The X-ray structure and metal ion specificity tests showed that phosphonoacetate hydrolase is also a two-zinc ion metalloenzyme. By using site-directed mutagenesis and (32)P-labeling strategies, the catalytic nucleophile was shown to be Thr64. A structure-guided, site-directed mutation-based inquiry of the catalytic contributions of active site residues identified Lys126 and Lys128 as the most likely candidates for stabilization of the aci-carboxylate dianion leaving group. A catalytic mechanism is proposed which combines Lys12/Lys128 leaving group stabilization with zinc ion activation of the Thr64 nucleophile and the substrate phosphoryl group.     

Probing the function of conserved residues in the serine/threonine phosphatase PP2Calpha

Human PP2Calpha is a metal-dependent phosphoserine/phosphothreonine protein phosphatase and is the representative member of the large PPM family. The X-ray structure of human PP2Calpha has revealed an active site containing a dinuclear metal ion center that is coordinated by several invariant carboxylate residues. However, direct evidence for the catalytic function of these and other active-site residues has not been established. Using site-directed mutagenesis and enzyme kinetic analyses, we probed the roles of conserved active-site amino acids within PP2Calpha. Asp-60 bridges metals M1 and M2, and Asp-239 coordinates metal M2, both of which were replaced individually to asparagine residues. These point mutations resulted in >or=1000-fold decrease in k(cat) and >or=30-fold increase in K(m) value for Mn(2+). Mutation of Asp-282 to asparagine caused a 100-fold decrease in k(cat), but no significant effect on K(m) values for metal and substrate, consistent with Asp-282 activating a metal-bound water nucleophile. Mutants T128A, E37Q, D38N, and H40A displayed little or no alterations on k(cat) and K(m) values for substrate or metal ion (Mn(2+)). Analysis of H62Q and R33A yielded k(cat) values that were 20- and 2-fold lower than wild-type, respectively. The mutant R33A showed a 8-fold higher K(m) for substrate, while the K(m) observed with H62Q was unaffected. A pH-rate profile of the H62Q mutant showed loss of the ionization that must be protonated for activity. Br?nsted analysis of substrate leaving group pK(a) values for H62Q indicated a greater dependency (slope -0.84) on leaving group pK(a) in comparison to wild-type (slope -0.33). These data provide strong evidence that His-62 acts as a general acid during the cleavage of the P-O bond.     

Intermediate trapping on a mutant retaining alpha-galactosyltransferase identifies an unexpected aspartate residue

Lipopolysaccharyl-alpha-1,4-galactosyltransferase C (LgtC), a glycosyltransferase family 8 alpha-1,4-galactosyltransferase from Neisseria meningitidis, catalyzes the transfer of galactose from UDP galactose to terminal lactose-containing acceptor sugars with net retention of anomeric configuration. To investigate the potential role of discrete nucleophilic catalysis suggested by the double displacement mechanism generally proposed for retaining glycosyltransferases, the side chain amide of Gln-189, which is suitably positioned to act as the catalytic nucleophile of LgtC, was substituted with the more nucleophilic carboxylate-containing side chain of glutamate in the hope of accumulating a glycosyl-enzyme intermediate. The resulting mutant was subjected to kinetic, mass spectrometric, and x-ray crystallographic analysis. Although the K(m) for UDP-galactose is not significantly altered, the k(cat) was reduced to 3% that of the wild type enzyme. Electrospray mass spectrometric analysis revealed that a steady state population of the Q189E variant contains a covalently bound galactosyl moiety. Liquid chromatographic/mass spectrometric analysis of fragmented proteolytic digests identified the site of labeling not as Glu-189 but, surprisingly, as the sequentially adjacent Asp-190. However, the side chain carboxylate of Asp-190 is located 8.9 A away from the donor substrate in the available crystal structure. Kinetic analysis of a D190N mutant at this position revealed a k(cat) value 3000-fold lower than that of the wild type enzyme. A 2.6-A crystal structure of the Q189E mutant with bound uridine 5'-diphospho-2-deoxy-2-fluoro-alpha-d-galactopyranose revealed no significant perturbation of the mode of donor sugar binding nor of active site configuration. This is the first trapping of an intermediate in the active site of a retaining glycosyltransferase and, although not conclusive, implicates Asp-190 as an alternative candidate catalytic nucleophile, thereby rekindling a longstanding mechanistic debate.     

Mechanistic characterization of N-formimino-L-glutamate iminohydrolase from Pseudomonas aeruginosa

N-Formimino-l-glutamate iminohydrolase (HutF) from Pseudomonas aeruginosa catalyzes the deimination of N-formimino-l-glutamate in the histidine degradation pathway. An amino acid sequence alignment between HutF and members of the amidohydrolase superfamily containing mononuclear metal centers indicated that residues Glu-235, His-269, and Asp-320 are involved in substrate binding and activation of the nucleophilic water molecule. The purified enzyme contained up to one equivalent of zinc. The metal was removed by dialysis against the metal chelator dipicolinate with the complete loss of catalytic activity. Enzymatic activity was restored by incubation of the apoprotein with Zn2+, Cd2+, Ni2+, or Cu2+. The mutation of Glu-235, His-269, or Asp-320 resulted in the diminution of catalytic activity by two to six orders of magnitude. Bell-shaped profiles were observed for kcat and kcat/Km as a function of pH. The pKa of the group that must be unprotonated for catalytic activity was consistent with the ionization of His-269. This residue is proposed to function as a general base in the abstraction of a proton from the metal-bound water molecule. In the proposed catalytic mechanism, the reaction is initiated by the abstraction of a proton from the metal-bound water molecule by the side chain imidazole of His-269 to generate a tetrahedral intermediate of the substrate. The collapse of the tetrahedral intermediate commences with the abstraction of a second proton via the side chain carboxylate of Asp-320. The C-N bond of the substrate is subsequently cleaved with proton transfer from His-269 to form ammonia and the N-formyl product. The postulated role of the invariant Glu-235 is to ion pair with the positively charged formimino group of the substrate.     

Asp-196-->Ala mutant of Leuconostoc mesenteroides sucrose phosphorylase exhibits altered stereochemical course and kinetic mechanism of glucosyl transfer to and from phosphate

Mutagenesis of Asp-196 into Ala yielded an inactive variant of Leuconostoc mesenteroides sucrose phosphorylase (D196A). External azide partly complemented the catalytic defect in D196A with a second-order rate constant of 0.031 M-1 s-1 (pH 5, 30 degrees C) while formate, acetate and halides could not restore activity. The mutant utilized azide to convert alpha-D-glucose 1-phosphate into beta-D-glucose 1-azide, reflecting a change in stereochemical course of glucosyl transfer from alpha-retaining in wild-type to inverting in D196A. Phosphorolysis of beta-D-glucose 1-azide by D196A occurred through a ternary complex kinetic mechanism, in marked contrast to the wild-type whose reactions feature a common glucosyl enzyme intermediate and Ping-Pong kinetics. Therefore, Asp-196 is identified unambiguously as the catalytic nucleophile of sucrose phosphorylase, and its substitution by Ala forces the reaction to proceed via single nucleophilic displacement. D196A is not detectably active as alpha-glucosynthase.     

Probing the two-metal ion mechanism in the restriction endonuclease BamHI

The choreography of restriction endonuclease catalysis is a long-standing paradigm in molecular biology. Bivalent metal ions are required almost for all PD..D/ExK type enzymes, but the number of cofactors essential for the DNA backbone scission remained ambiguous. On the basis of crystal structures and biochemical data for various restriction enzymes, three models have been developed that assign critical roles for one, two, or three metal ions during the phosphodiester hydrolysis. To resolve this apparent controversy, we investigated the mechanism of BamHI catalysis using quantum mechanical/molecular mechanical simulation techniques and determined the activation barriers of three possible pathways that involve a Glu-113 or a neighboring water molecule as a general base or an external nucleophile that penetrated from bulk solution. The extrinsic mechanism was found to be the most favorable with an activation free energy of 23.4 kcal/mol, in reasonable agreement with the experimental data. On the basis of the effect of the individual metal ions on the activation barrier, metal ion A was concluded to be pivotal for the reaction, while the enzyme lacking metal ion B still has moderate efficiency. Thus, we propose that the catalytic scheme of BamHI does not involve a general base for nucleophile generation and requires one obligatory metal ion for catalysis that stabilizes the attacking nucleophile and coordinates it throughout the nucleophilic attack. Such a model may also explain the variation in the number of metal ions in the crystal structures and thus could serve as a framework for a unified catalytic scheme of type II restriction endonucleases.     

The role of Asp-295 in the catalytic mechanism of Leuconostoc mesenteroides sucrose phosphorylase probed with site-directed mutagenesis

Replacements of Asp-295 by Asn (D295N) and Glu (D295E) decreased the catalytic center activity of Leuconostoc mesenteroides sucrose phosphorylase to about 0.01% of the wild-type level (k(cat)=200s(-1)). Glucosylation and deglucosylation steps of D295N were affected uniformly, approximately 10(4.3)-fold, and independently of leaving group ability and nucleophilic reactivity of the substrate, respectively. pH dependences of the catalytic steps were similar for D295N and wild-type. The 10(5)-fold preference of the wild-type for glucosyl transfer compared with mannosyl transfer from phosphate to fructose was lost in D295N and D295E. Selective disruption of catalysis to glucosyl but not mannosyl transfer in the two mutants suggests that the side chain of Asp-295, through a strong hydrogen bond with the equatorial sugar 2-hydroxyl, stabilizes the transition states flanking the beta-glucosyl enzyme intermediate by > or = 23kJ/mol.     

Mechanism of the dihydroorotase reaction

Dihydroorotase (DHO) is a zinc metalloenzyme that functions in the pathway for the biosynthesis of pyrimidine nucleotides by catalyzing the reversible interconversion of carbamoyl aspartate and dihydroorotate. A chemical mechanism was proposed on the basis of an analysis of the effects of pH, metal substitution, solvent isotope effects, mutant proteins, and alternative substrates on the enzyme-catalyzed reaction. The pH-rate profiles for the hydrolysis of dihydroorotate or thiodihydroorotate demonstrated that a single group from the enzyme must be unprotonated for maximal catalytic activity. Conversely, the pH-rate profiles for the condensation of carbamoyl aspartate to dihydroorotate showed that a single group from the enzyme must be protonated for maximal catalytic activity. The native zinc ions within the active site of DHO were substituted with cobalt or cadmium by reconstitution of the apoenzyme with divalent cations in the presence of bicarbonate. The ionizations observed in the pH-rate profiles were dependent on the specific metal ion bound to the active site. Mutation of the residue (Asp-250) that hydrogen bonds to the bridging hydroxide (or water) resulted in the loss of catalytic activity. These results are consistent with the formation of a hydroxide bridge between the two divalent cations that functions as the nucleophile during the hydrolysis of dihydroorotate. In addition, Asp-250 is postulated to shuttle the proton from the bridging hydroxide to the leaving group amide during hydrolysis of dihydroorotate. The X-ray crystal structure of DHO showed that the exocyclic alpha-carboxylate of dihydroorotate is bound to the protein via electrostatic interactions with Arg-20, Asn-44, and His-254. Mutation of these residues resulted in the loss of catalytic activity, indicating that these residues are critical for substrate recognition. The thio analogue of dihydroorotate was found to be a good substrate of the enzyme. A comprehensive chemical mechanism for DHO was proposed on the basis of the experimental findings in this study and the X-ray crystal structure.     

Asp-120 locates Zn2 for optimal metallo-beta-lactamase activity

Metallo-beta-lactamases are zinc-dependent hydrolases that inactivate beta-lactam antibiotics, rendering bacteria resistant to them. Asp-120 is fully conserved in all metallo-beta-lactamases and is central to catalysis. Several roles have been proposed for Asp-120, but so far there is no agreed consensus. We generated four site-specifically substituted variants of the enzyme BcII from Bacillus cereus as follows: D120N, D120E, D120Q, and D120S. Replacement of Asp-120 by other residues with very different metal ligating capabilities severely impairs the lactamase activity without abolishing metal binding to the mutated site. A kinetic study of these mutants indicates that Asp-120 is not the proton donor, nor does it play an essential role in nucleophilic activation. Spectroscopic and crystallographic analysis of D120S BcII, the least active mutant bearing the weakest metal ligand in the series, reveals that this enzyme is able to accommodate a dinuclear center and that perturbations in the active site are limited to the Zn2 site. It is proposed that the role of Asp-120 is to act as a strong Zn2 ligand, locating this ion optimally for substrate binding, stabilization of the development of a partial negative charge in the beta-lactam nitrogen, and protonation of this atom by a zinc-bound water molecule.     

Specificity of the sarcoplasmic reticulum calcium ATPase at the hydrolysis step

The coupling of Ca2+ transport to ATP hydrolysis by the SR ATPase requires that the enzyme operate with considerable specificity, which is different at different steps. The limits of specificity of the calcium-free phosphorylated enzyme for transfer of its phosphoryl group to water have been examined. The rate of transfer of the phosphoryl group to the simple nucleophile methanol was compared to its transfer to water by following the formation of methyl phosphate from inorganic phosphate. The reverse reaction, hydrolysis of methyl phosphate, was compared to phosphate-water oxygen exchange. The reactions involving methanol as nucleophile or leaving group are at least 2-3 orders of magnitude slower than those involving water. This result indicates that the transition state for this reaction involves strong and specific interactions of the H2O molecule with the enzyme. These interactions may also involve the bound Mg2+ ion. The results also suggest that the difference in specificity between Ca2+ free and Ca2+ bound states of the enzyme involves significant differences in the structure of the catalytic site.     

A metallo-beta-lactamase enzyme in action: crystal structures of the monozinc carbapenemase CphA and its complex with biapenem

One strategy developed by bacteria to resist the action of beta-lactam antibiotics is the expression of metallo-beta-lactamases. CphA from Aeromonas hydrophila is a member of a clinically important subclass of metallo-beta-lactamases that have only one zinc ion in their active site and for which no structure is available. The crystal structures of wild-type CphA and its N220G mutant show the structural features of the active site of this enzyme, which is modeled specifically for carbapenem hydrolysis. The structure of CphA after reaction with a carbapenem substrate, biapenem, reveals that the enzyme traps a reaction intermediate in the active site. These three X-ray structures have allowed us to propose how the enzyme recognizes carbapenems and suggest a mechanistic pathway for hydrolysis of the beta-lactam. This will be relevant for the design of metallo-beta-lactamase inhibitors as well as of antibiotics that escape their hydrolytic activity.     

Experimental evidence for a metallohydrolase mechanism in which the nucleophile is not delivered by a metal ion: EPR spectrokinetic and structural studies of aminopeptidase from Vibrio proteolyticus

Metallohydrolases catalyse some of the most important reactions in biology and are targets for numerous chemotherapeutic agents designed to combat bacterial infectivity, antibiotic resistance, HIV infectivity, tumour growth, angiogenesis and immune disorders. Rational design of inhibitors of these enzymes with chemotherapeutic potential relies on detailed knowledge of the catalytic mechanism. The roles of the catalytic transition ions in these enzymes have long been assumed to include the activation and delivery of a nucleophilic hydroxy moiety. In the present study, catalytic intermediates in the hydrolysis of L-leucyl-L-leucyl-L-leucine by Vibrio proteolyticus aminopeptidase were characterized in spectrokinetic and structural studies. Rapid-freeze-quench EPR studies of reaction products of L-leucyl-L-leucyl-L-leucine and Co(II)-substituted aminopeptidase, and comparison of the EPR data with those from structurally characterized complexes of aminopeptidase with inhibitors, indicated the formation of a catalytically competent post-Michaelis pre-transition state intermediate with a structure analogous to that of the inhibited complex with bestatin. The X-ray crystal structure of an aminopeptidase-L-leucyl-L-leucyl-L-leucine complex was also analogous to that of the bestatin complex. In these structures, no water/hydroxy group was observed bound to the essential metal ion. However, a water/hydroxy group was clearly identified that was bound to the metal-ligating oxygen atom of Glu152. This water/hydroxy group is proposed as a candidate for the active nucleophile in a novel metallohydrolase mechanism that shares features of the catalytic mechanisms of aspartic proteases and of B2 metallo-beta-lactamases. Preliminary studies on site-directed variants are consistent with the proposal. Other features of the structure suggest roles for the dinuclear centre in geometrically and electrophilically activating the substrate.     

Crystal Structure of Serratia fonticola Sfh-I: Activation of the Nucleophile in Mono-Zinc Metallo-β-Lactamases

Metallo-β-lactamases (MBLs) or class B β-lactamases are zinc-dependent enzymes capable of inactivating almost all classes of β-lactam antibiotics. To date, no MBL inhibitors are available for clinical use. Of the three MBL subclasses, B2 enzymes, unlike those from subclasses B1 and B3, are fully active with one zinc ion bound and possess a narrow spectrum of activity, hydrolyzing carbapenem substrates almost exclusively. These remain the least studied MBLs. Sfh-I, originally identified from the aquatic bacterium Serratia fonticola UTAD54, is a divergent member of this group. Previous B2 MBL structures, available only for the CphA enzyme from Aeromonas hydrophila, all contain small molecules bound in their active sites. In consequence, the mechanism by which these enzymes activate the water nucleophile required for β-lactam hydrolysis remains to be unambiguously established. Here we report crystal structures of Sfh-I as a complex with glycerol and in the unliganded form, revealing for the first time the disposition of water molecules in the B2 MBL active site. Our data indicate that the hydrolytic water molecule is activated by His118 rather than by Asp120 and/or zinc. Consistent with this proposal, we show that the environment of His118 in B2 MBLs is distinct from that of the B1 and B3 enzymes, where this residue acts as a zinc ligand, and offer a structure-based mechanism for β-lactam hydrolysis by these enzymes.     

Structures and mechanisms of Nudix hydrolases

Nudix hydrolases catalyze the hydrolysis of nucleoside diphosphates linked to other moieties, X, and contain the sequence motif or Nudix box, GX(5)EX(7)REUXEEXGU. The mechanisms of Nudix hydrolases are highly diverse in the position on the substrate at which nucleophilic substitution occurs, and in the number of required divalent cations. While most proceed by associative nucleophilic substitutions by water at specific internal phosphorus atoms of a diphosphate or polyphosphate chain, members of the GDP-mannose hydrolase sub-family catalyze dissociative nucleophilic substitutions, by water, at carbon. The site of substitution is likely determined by the positions of the general base and the entering water. The rate accelerations or catalytic powers of Nudix hydrolases range from 10(9)- to 10(12)-fold. The reactions are accelerated 10(3)-10(5)-fold by general base catalysis by a glutamate residue within, or beyond the Nudix box, or by a histidine beyond the Nudix box. Lewis acid catalysis, which contributes 10(3)-10(5)-fold to the rate acceleration, is provided by one, two, or three divalent cations. One divalent cation is coordinated by two or three conserved residues of the Nudix box, the initial glycine and one or two glutamate residues, together with a remote glutamate or glutamine ligand from beyond the Nudix box. Some Nudix enzymes require one (MutT) or two additional divalent cations (Ap(4)AP), to neutralize the charge of the polyphosphate chain, to help orient the attacking hydroxide or oxide nucleophile, and/or to facilitate the departure of the anionic leaving group. Additional catalysis (10-10(3)-fold) is provided by the cationic side chains of lysine and arginine residues and by H-bond donation by tyrosine residues, to orient the general base, or to promote the departure of the leaving group. The overall rate accelerations can be explained by both independent and cooperative effects of these catalytic components.     

Coordination geometries of metal ions in d- or l-captopril-inhibited metallo-beta-lactamases

d- and l-captopril are competitive inhibitors of metallo-beta-lactamases. For the enzymes from Bacillus cereus (BcII) and Aeromonas hydrophila (CphA), we found that the mononuclear enzymes are the favored targets for inhibition. By combining results from extended x-ray absorption fine structure, perturbed angular correlation of gamma-rays spectroscopy, and a study of metal ion binding, we derived that for Cd(II)1-BcII, the thiolate sulfur of d-captopril binds to the metal ion located at the site defined by three histidine ligand residues. This is also the case for the inhibited Co(II)1 and Co(II)2 enzymes as observed by UV-visible spectroscopy. Although the single metal ion in Cd(II)1-BcII is distributed between both available binding sites in both the uninhibited and the inhibited enzyme, Cd(II)1-CphA shows only one defined ligand geometry with the thiolate sulfur coordinating to the metal ion in the site composed of 1 Cys, 1 His, and 1 Asp. CphA shows a strong preference for d-captopril, which is also reflected in a very rigid structure of the complex as determined by perturbed angular correlation spectroscopy. For BcII and CphA, which are representatives of the metallo-beta-lactamase subclasses B1 and B2, we find two different inhibitor binding modes.     

Assessment of metal-assisted nucleophile activation in the hepatitis delta virus ribozyme from molecular simulation and 3D-RISM

The hepatitis delta virus ribozyme is an efficient catalyst of RNA 2′-O-transphosphorylation and has emerged as a key experimental system for identifying and characterizing fundamental features of RNA catalysis. Recent structural and biochemical data have led to a proposed mechanistic model whereby an active site Mg²⁺ ion facilitates deprotonation of the O2′ nucleophile, and a protonated cytosine residue (C75) acts as an acid to donate a proton to the O5′ leaving group as noted in a previous study. This model assumes that the active site Mg²⁺ ion forms an inner-sphere coordination with the O2′ nucleophile and a nonbridging oxygen of the scissile phosphate. These contacts, however, are not fully resolved in the crystal structure, and biochemical data are not able to unambiguously exclude other mechanistic models. In order to explore the feasibility of this model, we exhaustively mapped the free energy surfaces with different active site ion occupancies via quantum mechanical/molecular mechanical (QM/MM) simulations. We further incorporate a three-dimensional reference interaction site model for the solvated ion atmosphere that allows these calculations to consider not only the rate associated with the chemical steps, but also the probability of observing the system in the presumed active state with the Mg²⁺ ion bound. The QM/MM results predict that a pathway involving metal-assisted nucleophile activation is feasible based on the rate-controlling transition state barrier departing from the presumed metal-bound active state. However, QM/MM results for a similar pathway in the absence of Mg²⁺ are not consistent with experimental data, suggesting that a structural model in which the crystallographically determined Mg²⁺ is simply replaced with Na⁺ is likely incorrect. It should be emphasized, however, that these results hinge upon the assumption of the validity of the presumed Mg²⁺-bound starting state, which has not yet been definitively verified experimentally, nor explored in depth computationally. Thus, further experimental and theoretical study is needed such that a consensus view of the catalytic mechanism emerges.     

Acetyl-CoA enolization in citrate synthase: A quantum mechanical/molecular mechanical (QM/MM) study

Citrate synthase forms citrate by deprotonation of acetyl-CoA followed by nucleophilic attack of this substrate on oxaloacetate, and subsequent hydrolysis. The rapid reaction rate is puzzling because of the instability of the postulated nucleophilic intermediate, the enolate of acetyl-CoA. As alternatives, the enol of acetyl-CoA, or an enolic intermediate sharing a proton with His-274 in a “low-barrier” hydrogen bond have been suggested. Similar problems of intermediate instability have been noted in other enzymic carbon acid deprotonation reactions. Quantum mechanical/molecular mechanical calculations of the pathway of acetyl-CoA enolization within citrate synthase support the identification of Asp-375 as the catalytic base. His-274, the proposed general acid, is found to be neutral. The acetyl-CoA enolate is more stable at the active site than the enol, and is stabilized by hydrogen bonds from His-274 and a water molecule. The conditions for formation of a low-barrier hydrogen bond do not appear to be met, and the calculated hydrogen bond stabilization in the reaction is less than the gas-phase energy, due to interactions with Asp-375 at the active site. The enolate character of the intermediate is apparently necessary for the condensation reaction to proceed efficiently. Proteins 27:9–25 © 1997 Wiley-Liss, Inc.