Benzopyranones with retro-amide side chains as (inhibitory) beta-lactamase substrates

3-(N-Benzylcarbamoyl)-7-carboxy-3, 4-dihydro-2H-1-benzo-pyran-2-one and its 8-carboxy analogue have been synthesized and evaluated as potential (inhibitory) substrates of beta-lactam-recognizing enzymes. These compounds are bicyclic delta-lactones with retro-amide (with respect to classical beta-lactams) side chains. They were found to be comparably effective as substrates of typical class A, C and D beta-lactamases as analogous benzopyranones bearing 'normal' amide side chains. The new 8-carboxy derivative, however, formed a much more (1000-fold) tightly-bound acyl-enzyme with a class C beta-lactamase than did its 'normal' analogue, and thus provides a structural lead to new inhibitors of this class of beta-lactamase.     

Substituted aryl malonamates as new serine β-lactamase substrates: Structure–activity studies

A series of substituted aryl malonamates have been prepared. These compounds are analogues of aryl phenaceturates where the amido side chain has been replaced by a retro-amide. Like the phenaceturates, these compounds are substrates of typical class A and class C β-lactamases, particularly of the latter, and of soluble DD-peptidases. The effect of substituents α to the ester carbonyl group on turnover by these enzymes is similar to that in the phenaceturates. On the other hand, N-alkylation of the side chain amide of malonamates, but not of phenaceturates, retains the susceptibility of the compounds to hydrolysis by β-lactamases. This reactivity is not enhanced, however, by bridging the amide nitrogen and Cα atoms. A phosphonate analogue of the malonamates was found to be an irreversible inhibitor of the β-lactamases. These results, therefore, provide further evidence for the covalent access of compounds bearing retro-amide side chains to the active sites of β-lactam-recognizing enzymes.     

Synthesis and reactivity with beta-lactamases of a monobactam bearing a retro-amide side chain

The monobactam sodium 3-benzylcarbamoyl-2-oxo-1-azetidinesulfonate, bearing a retro (vs classical beta-lactam)-amide side chain, has been synthesized and the kinetics of its reaction with typical beta-lactamases studied. The new compound is generally a poorer substrate than the analogous compound with a normal side chain but its formation of a transiently stable complex with a class C beta-lactamase sustains the retro-amide side-chain concept.     

The D-methyl group in beta-lactamase evolution: evidence from the Y221G and GC1 mutants of the class C beta-lactamase of Enterobacter cloacae P99

The beta-lactam antibiotics act through their inhibition of D-alanyl-D-alanine transpeptidases (DD-peptidases) that catalyze the last step of bacterial cell wall synthesis. Bacteria resist beta-lactams by a number of mechanisms, one of the more important of which is the production of beta-lactamases, enzymes that catalyze the hydrolysis of these antibiotics. The serine beta-lactamases are evolutionary descendants of DD-peptidases and retain much of their structure, particularly at the active site. Functionally, beta-lactamases differ from DD-peptidases in being able to catalyze hydrolysis of acyl-enzyme intermediates derived from beta-lactams and being unable to efficiently catalyze acyl transfer reactions of D-alanyl-D-alanine terminating peptides. The class C beta-lactamase of Enterobacter cloacae P99 is closely similar in structure to the DD-peptidase of Streptomyces R61. Previous studies have demonstrated that the evolution of the beta-lactamase, presumably from an ancestral DD-peptidase similar to the R61 enzyme, included structural changes leading to rejection of the D-methyl substituent of the penultimate D-alanine residue of the DD-peptidase substrate. This seems to have been achieved by suitable placement of the side chain of Tyr 221 in the beta-lactamase. We show in this paper that mutation of this residue to Gly 221 produces an enzyme that more readily hydrolyzes and aminolyzes acyclic D-alanyl substrates than glycyl analogues, in contrast to the wild-type beta-lactamase; the mutant is therefore a more efficient DD-peptidase. Molecular modeling showed that the D-alanyl methyl group fits snugly into the space originally occupied by the Tyr 221 side chain and, in doing so, allows the bound substrate to assume a conformation similar to that on the R61 DD-peptidase, which has a hydrophobic pocket for this substituent. Another mutant of the P99 beta-lactamase, the extended spectrum GC1 enzyme, also has space available for a D-alanyl methyl group because of an extended omega loop. In this case, however, no enhancement of activity against D-alanyl substrates with respect to glycyl was observed. Accommodation of the penultimate D-alanyl methyl group is therefore necessary for efficient DD-peptidase activity, but not sufficient.     

Crystal structure of the IMP-1 metallo beta-lactamase from Pseudomonas aeruginosa and its complex with a mercaptocarboxylate inhibitor: binding determinants of a potent, broad-spectrum inhibitor

Metallo beta-lactamase enzymes confer antibiotic resistance to bacteria by catalyzing the hydrolysis of beta-lactam antibiotics. This relatively new form of resistance is spreading unchallenged as there is a current lack of potent and selective inhibitors of metallo beta-lactamases. Reported here are the crystal structures of the native IMP-1 metallo beta-lactamase from Pseudomonas aeruginosa and its complex with a mercaptocarboxylate inhibitor, 2-[5-(1-tetrazolylmethyl)thien-3-yl]-N-[2-(mercaptomethyl)-4 -(phenylb utyrylglycine)]. The structures were determined by molecular replacement, and refined to 3.1 A (native) and 2.0 A (complex) resolution. Binding of the inhibitor in the active site induces a conformational change that results in closing of the flap and transforms the active site groove into a tunnel-shaped cavity enclosing 83% of the solvent accessible surface area of the inhibitor. The inhibitor binds in the active site through interactions with residues that are conserved among metallo beta-lactamases; the inhibitor's carboxylate group interacts with Lys161, and the main chain amide nitrogen of Asn167. In the "oxyanion hole", the amide carbonyl oxygen of the inhibitor interacts through a water molecule with the side chain of Asn167, the inhibitor's thiolate bridges the two Zn(II) ions in the active site displacing the bridging water, and the phenylbutyryl side chain binds in a hydrophobic pocket (S1) at the base of the flap. The flap is displaced 2.9 A compared to the unbound structure, allowing Trp28 to interact edge-to-face with the inhibitor's thiophene ring. The similarities between this inhibitor and the beta-lactam substrates suggest a mode of substrate binding and the role of the conserved residues in the active site. It appears that the metallo beta-lactamases bind their substrates by establishing a subset of binding interactions near the catalytic center with conserved characteristic chemical groups of the beta-lactam substrates. These interactions are complemented by additional nonspecific binding between the more variable groups in the substrates and the flexible flap. This unique mode of binding of the mercaptocarboxylate inhibitor in the enzyme active site provides a binding model for metallo beta-lactamase inhibition with utility for future drug design.     

Synthesis and beta-lactamase reactivity of alpha-substituted phenaceturates

Beta-lactams with 6alpha (penicillins) or 7alpha (cephalosporins) substituents are often beta-lactamase inhibitors. This paper assesses the effect of such substituents on acyclic beta-lactamase substrates. Thus, a series of m-carboxyphenyl phenaceturates, substituted at the glycyl alpha-carbon by -OMe, -CH(2)OH, -CO(2)(-), and -CH(2)NH(3)(+), have been prepared, and tested for their reactivity against serine beta-lactamases. The latter two are novel substituents in beta-lactamase substrates. The methoxy and hydroxymethyl compounds were found to be poor to moderately good substrates, depending on the enzyme. The aminomethyl compound gave rise to a transiently stable (t(1/2)=4.6s) complex on its reaction with a class C beta-lactamase. The reactivity of the compounds against three low molecular weight DD-peptidases was also tested. Again, the methoxy and hydroxymethyl compounds proved to be quite good substrates with no sign of inhibitory complexes. The DD-peptidases reacted with one enantiomer (the compounds were prepared as racemates), presumably the D compound. The class C beta-lactamase reacted with both D and L enantiomers although it preferred the latter. The structural bases of these stereo-preferences were explored by reference to the crystal structure of the enzyme by molecular modeling studies. The aminomethyl compound was unreactive with the DD-peptidases, whereas the carboxy compound did not react with any of the above-mentioned enzymes. The inhibitory effects of the -OMe and -CH(2)OH substituents in beta-lactams apparently require a combination of the substituent and the pendant leaving group of the beta-lactam at the acyl-enzyme stage.     

Kinetics of turnover of cefotaxime by the Enterobacter cloacae P99 and GCl beta-lactamases: two free enzyme forms of the P99 beta-lactamase detected by a combination of pre- and post-steady state kinetics

Third-generation cephalosporins bearing oximino side chains are resistant to hydrolysis by class C beta-lactamases such as that from Enterobacter cloacae P99. For example, steady state parameters for hydrolysis of cefotaxime by this enzyme are as follows: k(cat) = 0.41 s(-1), K(m) = 17.2 microM, and k(cat)/K(m) = 2.3 x 10(4) s(-1) M(-1). On the other hand, however, the K(i) value for cefotaxime as an inhibitor of cephalothin hydrolysis is 27 nM. The discrepancy between K(m) and K(i) indicated that a real steady state had not been achieved in at least one of these experiments. Analysis indicated that only two to three cefotaxime turnovers occurred during the K(i) determination. This suggested that the first few turnovers of cefotaxime by the P99 beta-lactamase may be different from those in the subsequent steady state. A direct pre-steady state experiment confirmed this hypothesis. The simplest reaction scheme that fitted the data involved replacement of the initial enzyme form, E, which bound cefotaxime tightly, with a second more weakly binding form, E', by partitioning of the acyl-enzyme intermediate during the first few turnovers. Steady state turnover of cefotaxime then largely involved E' as the free enzyme form. E' slowly reverted to E in the post-steady state regime. Further evidence for this scheme included quantitative analysis of the post-steady state and observation of a difference in the catalytic activity of E and E' in 2 M ammonium sulfate. The kinetics of P99 beta-lactamase-catalyzed hydrolysis of an acyclic depsipeptide substrate bearing a third-generation cephalosporin side chain showed that the side chain is necessary but not sufficient for production of resistance to beta-lactamase; a combination of the side chain and the dihydrothiazine ring of a cephalosporin is required. The beta-lactamase of E. cloacae GC1, an extended spectrum mutant of the P99 enzyme, rapidly hydrolyzes third-generation cephalosporins, without the structural transition described above. The flexibility of the extended Omega loop of the GC1 enzyme probably leads to this situation. Conformational restriction of the loop in the P99 enzyme is probably responsible for the long-lived acyl-enzyme intermediate and the transition to E' induced by cefotaxime.     

Kinetics and mechanism of inhibition of a serine beta-lactamase by O-aryloxycarbonyl hydroxamates

The class C serine beta-lactamase of Enterobacter cloacae P99 is irreversibly inhibited by O-aryloxycarbonyl hydroxamates. A series of these new inhibitors has been prepared to investigate the kinetics and mechanism of the inactivation reaction. A pH-rate profile for the reaction indicated that the reactive form of the inhibitor is neutral rather than anionic. The reaction rate is enhanced by electron-withdrawing aryloxy substituents and by hydrophobic substitution on both aryloxy and hydroxamate groups. Kinetics studies show that the rates of loss of the two possible leaving groups, aryloxide and hydroxamate, are essentially the same as the rate of enzyme inactivation. Nucleophilic trapping experiments prove, however, that the aryl oxide is the first to leave. It is likely, therefore, that the rate-determining step of inactivation is the initial acylation reaction, most likely of the active site serine, yielding a hydroxamoyl-enzyme intermediate. This then partitions between hydrolysis and aminolysis by Lys 315, the latter to form an inactive, cross-linked active site. A previously described crystal structure of the inactivated enzyme shows a carbamate cross-link of Ser 64 and Lys 315. Structure-activity studies of the reported compounds suggest that they do not react at the enzyme active site in the same way as normal substrates. In particular, it appears that the initial acylation by these compounds does not involve the oxyanion hole, an unprecedented departure from known and presumed reactivity. Molecular modeling suggests that an alternative oxyanion hole may have been recruited, consisting of the side chain functional groups of Tyr 150 and Lys 315. Such an alternative mode of reaction may lead to the design of novel inhibitors.     

Inhibition of beta-lactamases by monocyclic acyl phosph(on)ates

The cyclic acyl phosph(on)ates, 1-hydroxy-5-phenyl-2,6-dioxaphosphorinone(3)-1-oxide, its 4-phenyl isomer, and the phosphonate (2-oxo) analogue of the latter inhibited typical class A (TEM-2) and class C (Enterobacter cloacae P99) beta-lactamases in a time-dependent fashion. No enzyme-catalyzed turnover was detected in any case. The interactions occurring were interpreted in terms of the reaction scheme E + I left arrow over right arrow EI left arrow over right arrow EI', where EI is a reversibly formed noncovalent complex, and EI' is a covalent complex. Reactions of the cyclic phosphates with the P99 beta-lactamase were effectively irreversible, while that of the 4-phenyl cyclic phosphate with the TEM beta-lactamase was slowly reversible. The 4-phenyl cyclic phosphate was generally the most effective inhibitor, both kinetically and thermodynamically, with second-order rate constants of inactivation of both enzymes around 10(4) s(-1) M(-1). This compound also bound noncovalently to both enzymes, with dissociation constants of 25 microM from the P99 enzyme and 100 microM from the TEM. It is unusual to find an inhibitor equally effective against the TEM and P99 enzymes; the beta-lactamase inhibitors currently employed in medical practice (e.g., clavulanic acid) are significantly more effective against class A enzymes. The results of lysinoalanine analysis after hydroxide treatment of the inhibited enzymes and of a (31)P nuclear magnetic resonance spectrum of one such complex were interpreted as favoring a mechanism of inactivation by enzyme acylation rather than phosphylation. Molecular modeling of the enzyme complexes of the 4-phenyl phosphate revealed bound conformations where recyclization and thus reactivation of the enzyme would be difficult. The compounds studied were turned over slowly or not at all by acetylcholinesterase and phosphodiesterase I.     

Cryoenzymology of beta-lactamases

The cryoenzymology of several different beta-lactamases has been investigated. Particular attention has been paid to the experimental pitfalls of the technique. These include such factors as false bursts at the start of the reaction, instability of the enzymes during turnover, and Km values so high that little of the enzyme is present as a complex. Many of the difficulties in cryoenzymology stem from the use of organic cryosolvents. A novel "salt" cryosolvent has been tested: ammonium acetate solutions can be used down to about -60 degrees C. The enzymes examined are readily soluble, and stable, in this solvent. Nevertheless, out of 17 beta-lactamase beta-lactam systems, only 4 proved suitable for detailed investigation. In two of these, the hydrolysis of nitrocefin or 7-(thienyl-2-acetamido)-3-[[2-[[4- (dimethylamino)phenyl]azo]pyridinio]-methyl]cephem-4-carboxylic acid (PADAC), by beta-lactamase I from Bacillus cereus, substrate was converted into product at a slow enough rate (at -60 or -55 degrees C, respectively) for it to be possible to do successive scans during the course of the reaction. The spectra were those of substrate and product, and no intermediate was detected. The results argue against the accumulation of intermediate acyl-enzyme. The hydrolysis of PADAC by the P99 beta-lactamase from Enterobacter cloacae again showed spectra characteristic of substrate and product, and there was, moreover, a break in the Arrhenius plot; it is possible that a conformational change is (at least partially) rate-determining. The hydrolysis of dinitrophenylpenicillin by the P99 beta-lactamase did show features suggesting the accumulation of acyl-enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thermodynamic evaluation of a covalently bonded transition state analogue inhibitor: inhibition of beta-lactamases by phosphonates

Serine beta-lactamases are inhibited by phosphonate monoesters in a reaction that involves phosphonylation of the active site serine residue. This reaction is much more rapid than the hydrolysis of these inhibitors in solution under the same conditions. The beta-lactamase active site therefore must have the ability to stabilize not only the anionic tetrahedral transition states of the acyl transfer reactions of substrates but also the pentacoordinated transition state(s) of phosphyl transfer reactions. A series of p-nitrophenyl arylphosphonates have been synthesized and the rate constants for their inhibition of the class C beta-lactamase of Enterobacter cloacae P99 determined. There is no direct correlation between these rate constants and the dissociation constants of analogous aryl boronic acids, where the latter are believed to generate good tetrahedral transition state analogue structures. Thus, the mode of stabilization of pentacoordinated phosphorus transition states by the beta-lactamase active site is qualitatively different from that of tetrahedral transition states. Molecular modeling suggests that the difference arises from different positioning of the side chain and of one of the oxygen ligands. In principle, the quality of the stable tetrahedral phosphonate complex as a transition state analogue structure can be assessed from the effect of its formation on the stability of the protein. Phosphonylation of the P99 beta-lactamase, however, had little effect on the stability of the protein, as measured both by thermal and guanidine hydrochloride denaturation. Consideration of the results of similar experiments with the Staphylococcus aureus PC1 beta-lactamase, where considerable stabilization is observed in thermal melting and, to a lesser degree, in formation of the molten globule in guanidine hydrochloride, but not in the complete unfolding transition in guanidine, suggests that results from the method may be strongly influenced by the interactions of the ligand with its environment in the unfolded state of the protein. Thus, quantitative estimates of the quality of a covalently bonded transition state analogue cannot generally be achieved by this method.     

Hydrolysis of third-generation cephalosporins by class C beta-lactamases. Structures of a transition state analog of cefotoxamine in wild-type and extended spectrum enzymes

Bacterial resistance to the third-generation cephalosporins is an issue of great concern in current antibiotic therapeutics. An important source of this resistance is from production of extended-spectrum (ES) beta-lactamases by bacteria. The Enterobacter cloacae GC1 enzyme is an example of a class C ES beta-lactamase. Unlike wild-type (WT) forms, such as the E. cloacae P99 and Citrobacter freundii enzymes, the ES GC1 beta-lactamase is able to rapidly hydrolyze third-generation cephalosporins such as cefotaxime and ceftazidime. To understand the basis for this ES activity, m-nitrophenyl 2-(2-aminothiazol-4-yl)-2-[(Z)-methoxyimino]acetylaminomethyl phosphonate has been synthesized and characterized. This phosphonate was designed to generate a transition state analog for turnover of cefotaxime. The crystal structures of complexes of the phosphonate with both ES GC1 and WT C. freundii GN346 beta-lactamases have been determined to high resolution (1.4-1.5 Angstroms). The serine-bound analog of the tetrahedral transition state for deacylation exhibits a very different binding geometry in each enzyme. In the WT beta-lactamase the cefotaxime-like side chain is crowded against the Omega loop and must protrude from the binding site with its methyloxime branch exposed. In the ES enzyme, a mutated Omega loop adopts an alternate conformation allowing the side chain to be much more buried. During the binding and turnover of the cefotaxime substrate by this ES enzyme, it is proposed that ligand-protein contacts and intra-ligand contacts are considerably relieved relative to WT, facilitating positioning and activation of the hydrolytic water molecule. The ES beta-lactamase is thus able to efficiently inactivate third-generation cephalosporins.     

Purification of beta-lactamases by affinity chromatography on phenylboronic acid-agarose.

Several beta-lactamases, enzymes that play an important part in antibiotic resistance, have been purified by affinity chromatography on boronic acid gels. The procedure is rapid, appears to be selective for beta-lactamases, and allows a one-step purification of large amounts of enzyme from crude cell extracts. We have found the method useful for any beta-lactamase that is inhibited by boronic acids. Two kinds of boronic acid column have been prepared, the more hydrophobic one being reserved for those beta-lactamases that bind boronic acids relatively weakly. beta-Lactamase I from Bacillus cereus, P99 beta-lactamase and K 1 beta-lactamase from Gram-negative bacteria are among the better-known beta-lactamases that have been purified by this method. The procedure has also been used to purify a novel beta-lactamase from Pseudomonas maltophilia in high yield; the enzyme has an exceptionally broad substrate profile and hydrolyses monocyclic beta-lactams such as azthreonam and desthiobenzylpenicillin.     

Mechanism of reaction of acyl phosph(on)ates with the beta-lactamase of Enterobacter cloacae P99

A series of acyl phosph(on)ates has been prepared to more closely examine the details of the interactions of this class of molecule with beta-lactamases. In general, they were found to react with the class C beta-lactamase of Enterobacter cloacae P99 in two ways, by acylation and by phosphylation. The acyl-enzymes generated by the former reaction were transiently stable with half-lives of between 3 and 45 s, of comparable lifetime therefore to those generated by the inhibitory beta-lactams cefotaxime, cefuroxime, and cefoxitin. On the other hand, phosphylation led to a completely inactive enzyme. In general, the second-order rate constants for acylation (k(cat)/K(m)) were larger than for phosphylation (k(i)). As expected on chemical grounds, phosphylation was found to be relatively more effective for the phosphonates than the phosphates. The acyl phosphates were much more effective acylating agents however. The acylation reaction was found to be enhanced by hydrophobic substituents in both the acyl and leaving group moieties. Thus, the most reactive compound in this series was benzo[b]thiophene-2-carbonyl 2'-naphthyl phosphate with a K(m) value of 0.15 microM and a k(cat) of 0.2 s(-1); k(cat)/K(m) is therefore 1.3 x 10(6) s(-1) M(-1), making this compound the most specific acyclic acylation reagent for this beta-lactamase yet described. Significant substrate inhibition by this compound suggested that further binding regions may be available for exploitation in inhibitor design. A linear free energy analysis showed that the transition states for acylation of the beta-lactamase by aroyl phosphates are analogues of the corresponding aryl boronic acid adducts. Molecular modeling suggested that the aroyl phosphates react with the P99 beta-lactamase with the aroyl group in the side chain/acyl group site of normal substrates and the phosphate in the leaving group site. In this orientation, the phosphate leaving group interacts strongly with Lys 315.     

Engineering the substrate specificity of rhizopuspepsin: the role of Asp 77 of fungal aspartic proteinases in facilitating the cleavage of oligopeptide substrates with lysine in P1.

Rhizopuspepsin and other fungal aspartic proteinases are distinct from the mammalian enzymes in that they are able to cleave substrates with lysine in the P1 position. Sequence and structural comparisons suggest that two aspartic acid residues, Asp 30 and Asp 77 (pig pepsin numbering), may be responsible for generating this unique specificity. Asp 30 and Asp 77 were changed to the corresponding residues in porcine pepsin, Ile 30 and Thr 77, to create single and double mutants. The zymogen forms of the wild-type and mutant enzymes were overexpressed in Escherichia coli as inclusion bodies. Following solubilization, denaturation, refolding, activation, and purification to homogeneity, structural and kinetic comparisons were made. The mutant enzymes exhibited a high degree of structural similarity to the wild-type recombinant protein and a native isozyme. The catalytic activities of the recombinant proteins were analyzed with chromogenic substrates containing lysine in the P1, P2, or P3 positions. Mutation of Asp 77 resulted in a loss of 7 kcal mol-1 of transition-state stabilization energy in the hydrolysis of the substrate containing lysine in P1. An inhibitor containing the positively charged P1-lysine side chain inhibited only the enzymes containing Asp 77. Inhibition of the Asp 77 mutants of rhizopuspepsin and several mammalian enzymes was restored upon acetylation of the lysine side chain. These results suggest that an exploitation of the specific electrostatic interaction of Asp 77 in the active site of fungal enzymes may lead to the design of compounds that preferentially inhibit a variety of related Candida proteinases in immunocompromised patients.     

Kinetics and mechanism of the serine beta-lactamase catalyzed hydrolysis of depsipeptides

Steady-state kinetic parameters have been determined for the hydrolysis of a series of acyclic depsipeptides (ester analogues of acyl-D-alanyl-D-alanine peptides) catalyzed by representative class C (Enterobacter cloacae P99) and class A (Bacillus cereus I, TEM-2, and Staphylococcus aureus PC1) beta-lactamases. The best of these substrates, and the one most used in this work, was m-[[(phenylacetyl)-glycyl]oxy]benzoic acid, whose rates of cleavage could be followed spectrophotometrically. The P99 enzyme also catalyzed the methanolysis of these substrates in aqueous methanol solutions. Quantitative evaluation of the effects of methanol on the kinetics of the competing hydrolysis and methanolysis reactions, and on the product distribution, supports a reaction mechanism involving an acyl-enzyme intermediate whose formation is rate-determining under conditions of substrate saturation. Consideration of the variation of these kinetic parameters with the structure of the depsipeptides and comparison with the analogous parameters for bicyclic beta-lactam substrates suggest that a variety of substrate binding modes exist on this enzyme. The class A enzymes, B. cereus beta-lactamase I and the TEM-2 beta-lactamase, catalyze depsipeptide and benzylpenicillin hydrolyses but not methanolysis. The acyl-enzyme derived from both types of substrate is thus shielded from external nucleophiles; the shielding is therefore not an effect, direct or indirect, of the thiazolidinyl group in the penicilloyl-enzyme. The class A beta-lactamase of the PC1 plasmid of S. aureus is distinctly different from the above two representatives of that class, in that it does catalyze methanolysis of depsipeptides (but not of benzylpenicillin). The methanolysis kinetics suggest that deacylation is rate-determining at saturation, a conclusion supported by the demonstration of an intermediate during the hydrolysis of m-[[(phenylacetyl)glycyl]oxy]benzoate, subsequent to leaving-group departure. The beta-lactamases have thus been shown to catalyze the hydrolysis of specific depsipeptides with comparable facility to that demonstrated by D-alanyl-D-alanine carboxypeptidase/transpeptidases. The former enzymes, however, differ in being unable to cleave the analogous peptides.     

Substitution of lysine at position 104 or 240 of TEM-1pTZ18R beta-lactamase enhances the effect of serine-164 substitution on hydrolysis or affinity for cephalosporins and the monobactam aztreonam

By site-directed mutagenesis, TEM-1 beta-lactamase was altered to contain single amino acid changes of E104K, R164S, and E240K, in addition to double changes of E104K/R164S or R164S/E240K and the triple change of E104K/R164S/E240K. Hydrolysis rates for cephaloridine and benzylpenicillin were lowered at least 1 order of magnitude for all enzymes containing R164S substitutions. All mutant enzymes exhibited increased kcat values for beta-lactam antibiotics containing an aminothiazole oxime side chain. Hydrolysis of ceftazidime was most affected, with kcat values increased 3-4 orders of magnitude in all enzymes with the substituted R164S moiety. Km values decreased for all substrates except ceftazidime in the enzymes with multiple mutations. Aztreonam was most affected, with Km values lowered 23-56-fold in the enzymes bearing multiple mutations. When the crystal structures of aztreonam and related monobactams were studied and projected into an active-site model of the PC1 beta-lactamase, it became apparent that the two lysine residues might serve equivalent roles by interacting with the carboxylate of the aminothiazole oxime side chain. Hydrogen-bonding interactions involving the oxime and N7 of the lysine, particularly Lys-104, may also be important in some antibiotics. Ser-164 apparently serves an indirect role, since it is somewhat distant from the active-site cleft.     

EstB from Burkholderia gladioli: a novel esterase with a beta-lactamase fold reveals steric factors to discriminate between esterolytic and beta-lactam cleaving activity

Esterases form a diverse class of enzymes of largely unknown physiological role. Because many drugs and pesticides carry ester functions, the hydrolysis of such compounds forms at least one potential biological function. Carboxylesterases catalyze the hydrolysis of short chain aliphatic and aromatic carboxylic ester compounds. Esterases, D-alanyl-D-alanine-peptidases (DD-peptidases) and beta-lactamases can be grouped into two distinct classes of hydrolases with different folds and topologically unrelated catalytic residues, the one class comprising of esterases, the other one of beta-lactamases and DD-peptidases. The chemical reactivities of esters and beta-lactams towards hydrolysis are quite similar, which raises the question of which factors prevent esterases from displaying beta-lactamase activity and vice versa. Here we describe the crystal structure of EstB, an esterase isolated from Burkholderia gladioli. It shows the protein to belong to a novel class of esterases with homology to Penicillin binding proteins, notably DD-peptidase and class C beta-lactamases. Site-directed mutagenesis and the crystal structure of the complex with diisopropyl-fluorophosphate suggest Ser75 within the "beta-lactamase" Ser-x-x-Lys motif to act as catalytic nucleophile. Despite its structural homology to beta-lactamases, EstB shows no beta-lactamase activity. Although the nature and arrangement of active-site residues is very similar between EstB and homologous beta-lactamases, there are considerable differences in the shape of the active site tunnel. Modeling studies suggest steric factors to account for the enzyme's selectivity for ester hydrolysis versus beta-lactam cleavage.     

On the importance of a methyl group in beta-lactamase evolution: free energy profiles and molecular modeling.

beta-Lactam antibiotics are generally thought to inhibit their target enzymes, the bacterial cell wall-synthesizing DD-peptidases, because of their resemblance to D-alanyl-D-alanine peptides. Although a favorable conformation of the latter does structurally resemble the beta-lactams with respect to backbone conformation, a significant difference is the presence of a D-methyl substituent on the penultimate alanine residue of the cell wall peptide. A classical beta-lactam antibiotic has a hydrogen in the corresponding position. In the process of evolution of a beta-lactamase from a DD-peptidase, it seems likely that this D-methyl group would be selected against, to ensure that the former enzyme would hydrolyze beta-lactams rather than peptides. In this paper, the effect of the penultimate D-alanine residue (as opposed to a glycine residue) has been examined in peptide substrates of a present-day DD-peptidase and a beta-lactamase. The peptides N-(phenylacetyl)-D-alanyl-D-phenylalanine and N-(phenylacetyl)glycyl-D-phenylalanine were used as a test pair against the DD-peptidase of Streptomyces R61 and the structurally very similar class C beta-lactamase of Enterobacter cloacae P99. The kinetics of turnover of both of these substrates were determined for both enzymes. To quantify the partitioning of the acyl-enzyme intermediate, the aminolysis by D-phenylalanine of a cognate pair of depsipeptides was also studied. Thus, free energy-reaction coordinate diagrams were constructed for turnover of both peptides by both enzymes. Comparison of these profiles showed that the D-methyl group is preferred over hydrogen by the DD-peptidase at all stages of catalysis (acyl-enzyme and acylation and deacylation transition states), whereas the beta-lactamase selects against the D-methyl group only at the peptide acylation transition state. A process of evolution by uniform dissociation of the methyl group by the beta-lactamase has apparently occurred. These results were explored structurally by computational models of the acylation tetrahedral intermediates. A methyl group pocket on the DD-peptidase, less favorable on the beta-lactamase, was identified. The interaction of the leaving group, the terminal D-alanine residue, with the two enzymes was interesting, since it seemed that different positively charged active site residues were directly associated with the carboxylate, Lys 315 in the beta-lactamase and Arg 285 (rather than His 298) in the case of the DD-peptidase. The problems posed by larger substituents on the penultimate residue of the peptide, and in particular by the heterocyclic substituent present in a bicyclic beta-lactam, were analyzed. Qualitative and quantitative analysis of the models support the proposed importance of the penultimate D-alanine in beta-lactamase evolution.     

Chromogenic redox assay for beta-lactamases yielding water-insoluble products. I. Kinetic behavior and redox chemistry.

We describe a chromogenic detection system for beta-lactamase which yields water-insoluble colored products. The assay is based on kinetic measurement of the appearance of color due to the beta-lactamase-initiated redox reaction. The substrates are C3' thiolate-substituted cephalosporins, which, after enzyme-catalyzed hydrolysis of the beta-lactam ring, undergo elimination of the thiolate ion. This thiolate, in a postenzymatic step, reduces the tetrazolium salts, which are water-soluble colorless compounds, to a colored water-insoluble precipitate of formazan. Our model in this study was a beta-lactamase Enterobacter cloacae P-99-catalyzed reaction of thiolacetate cephalosporin with several tetrazolium salts. We found that the reaction rate is dependent on the concentration of the electron carrier 5-methyl phenazinium methyl sulfate, the pKa of the C3' thiolate substituent of the cephalosporin substrate, and the reduction potential of the tetrazolium salts. A kinetic study of this system yielded a rate law for the reaction. We present a mechanism of the reaction and determination of the kinetic parameters for the process. The sensitivity of this kinetic assay is very high; we detect 3 x 10(-10) M beta-lactamase P-99, which is approximately 30 mIU. The assay times are very short, lasting from 2 to 5 min. The new assay system is particularly suitable for a rapid detection of beta-lactamases in bacterial colonies and in enzyme immunoassays where beta-lactamase may be used as the label.