R. F. Pratt

CENTA as a Chromogenic Substrate for Studying β-Lactamases

ABSTRACT CENTA, a chromogenic cephalosporin, is readily hydrolyzed by β-lactamases of all classes except for the Aeromonas hydrophila metalloenzyme. Although it cannot practically be used for the detection of β-lactamase-producing strains on agar plates, it should be quite useful for kinetic studies and the detection of the enzymes in crude extracts and chromatographic fractions.

Structures of two kinetic intermediates reveal species specificity of penicillin-binding proteins.

Penicillin-binding proteins (PBPs), the target enzymes of beta-lactam antibiotics such as penicillins and cephalosporins, catalyze the final peptidoglycan cross-linking step of bacterial cell-wall biosynthesis. beta-Lactams inhibit this reaction because they mimic the D-alanyl-D-alanine peptide precursors of cell-wall structure. Prior crystallographic studies have described the site of beta-lactam binding and inhibition, but they have failed to show the binding of D-Ala-D-Ala substrates. We present here the first high-resolution crystallographic structures of a PBP, D-Ala-D-Ala-peptidase of Streptomyces sp. strain R61, non-covalently complexed with a highly specific fragment (glycyl-L-alpha-amino-epsilon-pimelyl-D-Ala-D-Ala) of the cell-wall precursor in both enzyme-substrate and enzyme-product forms. The 1.9A resolution structure of the enzyme-substrate Henri-Michaelis complex was achieved by using inactivated enzyme, which was formed by cross-linking two catalytically important residues Tyr159 and Lys65. The second structure at 1.25A resolution of the uncross-linked, active form of the DD-peptidase shows the non-covalent binding of the two products of the carboxypeptidase reaction. The well-defined substrate-binding site in the two crystallographic structures shows a subsite that is complementary to a portion of the natural cell-wall substrate that varies among bacterial species. In addition, the structures show the displacement of 11 water molecules from the active site, the location of residues responsible for substrate binding, and clearly demonstrate the necessity of Lys65 and or Tyr159 for the acylation step with the donor peptide. Comparison of the complexed structures described here with the structures of other known PBPs suggests the design of species-targeted antibiotics as a counter-strategy towards beta-lactamase-elicited bacterial resistance.

Substrate specificity of bacterial DD-peptidases (penicillin-binding proteins)

Abstract.The DD-peptidase enzymes (penicillin-binding proteins) catalyze the final transpeptidation reaction of bacterial cell wall (peptidoglycan) biosynthesis. Although there is now much structural information available about these enzymes, studies of their activity as enzymes lag. It is now established that representatives of two low-molecular-mass classes of DD-peptidases recognize elements of peptidoglycan structure and rapidly react with substrates and inhibitors incorporating these elements. No members of other DD-peptidase classes, including the high-molecular-mass enzymes, essential for bacterial growth, appear to interact strongly with any particular elements of peptidoglycan structure. Rational design of inhibitors for these enzymes is therefore challenging.

Crystal structures of complexes of bacterial DD-peptidases with peptidoglycan-mimetic ligands: the substrate specificity puzzle.

The X-ray crystal structures of covalent complexes of the Actinomadura R39 dd-peptidase and Escherichia coli penicillin-binding protein (PBP) 5 with beta-lactams bearing peptidoglycan-mimetic side chains have been determined. The structure of the hydrolysis product of an analogous peptide bound noncovalently to the former enzyme has also been obtained. The R39 DD-peptidase structures reveal the presence of a specific binding site for the D-alpha-aminopimelyl side chain, characteristic of the stem peptide of Actinomadura R39. This binding site features a hydrophobic cleft for the pimelyl methylene groups and strong hydrogen bonding to the polar terminus. Both of these active site elements are provided by amino acid side chains from two separate domains of the protein. In contrast, no clear electron density corresponding to the terminus of the peptidoglycan-mimetic side chains is present when these beta-lactams are covalently bound to PBP5. There is, therefore, no indication of a specific side-chain binding site in this enzyme. These results are in agreement with those from kinetics studies published earlier and support the general prediction made at the time of a direct correlation between kinetics and structural evidence. The essential high-molecular-mass PBPs have demonstrated, to date, no specific reactivity with peptidoglycan-mimetic peptide substrates and beta-lactam inhibitors and, thus, probably do not possess a specific substrate-binding site of the type demonstrated here with the R39 DD-peptidase. This striking deficiency may represent a sophisticated defense mechanism against low-molecular-mass substrate-analogue inhibitors/antibiotics; its discovery should focus new inhibitor design.

The irreversible cleavage of histidine residues by diethylpyrocarbonate (ethoxyformic anhydride)

In aqueous solution at neutral or slightly acidic pH values diethyl pyrocarbonate (ethoxyformic anhydride, DEP) has been shown to modify histidine residues in proteins with considerable specificity [l-3] . For this reason DEP has been widely used to test for the presence of functional histidine residues at the active sites of enzymes; for example, phosphofructokinase [4], thermolysin [5,6], lactate dehydrogenase [7], pyruvate kinase [8] , and liver alcohol dehydrogenase [9]. The reagent is convenient since it reacts with histidine to give an ultraviolet spectral change centered at 240 nm [2,3] from the intensity of which the number of modified histidine residues can be estimated and the modification reaction can be reversed by cleavage of the product, Ncarbethoxyhistidine, with suitable nucleophiles such as hydroxylamine. Diethyl pyrocarbonate has also been shown to modify nucleic acid components. Leonard et al. [ 1 O-l 21 however, have shown that in this case not only are ring nitrogen atoms and substituent ammo groups carbethoxylated but also the imidazole ring of purine bases can be cleaved in a Bamberger [ 131 reaction. Oligonucleotides and nucleic acids are also subject to this reaction [ 141. Despite this warning, many users of DEP as a protein modifying reagent appear unaware of the possibility of interference by the Bamberger reaction. In this work we demonstrate that under commonly used mild conditions for protein modification by DEP, Bamberger cleavage of imidazole rings in amino acids, peptides and proteins can and does occur.

β-Ketophosphonates as β-lactamase inhibitors: Intramolecular cooperativity between the hydrophobic subsites of a class D β-lactamase

A series of aryl and arylmethyl beta-aryl-beta-ketophosphonates have been prepared as potential beta-lactamase inhibitors. These compounds, as fast, reversible, competitive inhibitors, were most effective (micromolar K(i) values) against the class D OXA-1 beta-lactamase but had less activity against the OXA-10 enzyme. They were also quite effective against the class C beta-lactamase of Enterobacter cloacae P99 but less so against the class A TEM-2 enzyme. Reduction of the keto group to form the corresponding beta-hydroxyphosphonates led to reduced inhibitory activity. Molecular modeling, based on the OXA-1 crystal structure, suggested interaction of the aryl groups with the hydrophobic elements of the enzymes active site and polar interaction of the keto and phosphonate groups with the active site residues Ser 115, Lys 212 and Thr 213 and with the non-conserved Ser 258. Analysis of binding free energies showed that the beta-aryl and phosphonate ester aryl groups interacted cooperatively within the OXA-1 active site. Overall, the results suggest that quite effective inhibitors of class C and some class D beta-lactamases could be designed, based on the beta-ketophosphonate platform.

Design, synthesis, and evaluation of α-ketoheterocycles as class C β-lactamase inhibitors

A series of specific alpha-ketoheterocycles (benzoxazole, thiazole, imidazole, tetrazole, and thiazole-4-carboxylate) has been synthesized in order to assess their potential as beta-lactamase inhibitors. The syntheses were achieved either by construction of the heterocycle (benzoxazole) from an appropriate alpha-hydroxyimidate, followed by oxidation of the alcohol, or by direct reaction of methyl phenaceturate with a lithiated heterocycle. The properties of these compounds in aqueous solution are described and their inhibitory activity against beta-lactamases assessed. They did inhibit the class C beta-lactamase of Enterobacter cloacae P99 but not the TEM beta-lactamase. The most effective inhibitor of the former enzyme (K(i)=0.11 mM) was 5-(phenylacetylglycyl) tetrazole, probably because it is an anion at neutral pH. Interpretation of the results was aided by computational models of the tetrahedral adducts. Most of the compounds also inhibited alpha-chymotrypsin but not porcine pancreatic elastase.

Crystal Structure of a Complex between the Actinomadura R39 Dd-Peptidase and a Peptidoglycan- Mimetic Boronate Inhibitor: Interpretation of a Transition State Analogue in Terms of Catalytic Mechanism.

The Actinomadura R39 DD-peptidase is a bacterial low molecular weight class C penicillin-binding protein. It has previously been shown to catalyze hydrolysis and aminolysis of small D-alanyl-D-alanine terminating peptides, especially those with a side chain that mimics the amino terminus of the stem peptide precursor to the bacterial cell wall. This paper describes the synthesis of (D-alpha-aminopimelylamino)-D-1-ethylboronic acid, designed to be a peptidoglycan-mimetic transition state analogue inhibitor of the R39 DD-peptidase. The boronate was found to be a potent inhibitor of the peptidase with a K(i) value of 32 +/- 6 nM. Since it binds some 30 times more strongly than the analogous peptide substrate, the boronate may well be a transition state analogue. A crystal structure of the inhibitory complex shows the boronate covalently bound to the nucleophilic active site Ser 49. The aminopimelyl side chain is bound into the site previously identified as specific for this moiety. One boronate oxygen is held in the oxyanion hole; the other, occupying the leaving group site of acylation or the nucleophile site of deacylation, appears to be hydrogen-bonded to the hydroxyl group of Ser 298. The Ser 49 oxygen appears to be hydrogen bonded to Lys 52. If it is assumed that this structure does resemble a high-energy tetrahedral intermediate in catalysis, it seems likely that Ser 298 participates as part of a proton transfer chain initiated by Lys 52 or Lys 410 as the primary proton donor/acceptor. The structure, therefore, supports a particular class of mechanism that employs this proton transfer device.

The synthesis and evaluation of benzofuranones as β-lactamase substrates

Abstract 6- and 7-Carboxy-3-phenylacetamido-3 H -1-benzofuran-2-one have been synthesized as potential β-lactamase substrates and/or inhibitors. These compounds were prepared by lactonization of the corresponding, appropriately substituted phenylglycines. The latter compounds were prepared by either the Strecker or the Bucherer–Berg method. The benzofuran-2-ones were less stable in aqueous solution than the analogous acyclic phenaceturate esters but comparably stable to analogous benzopyran-2-ones. They differed from the latter compounds however in that the C-3 hydrogen of the furan-2-ones, adjacent to the lactone carbonyl group, was distinctly acidic; 7-carboxy-3-phenylacetamido-3 H -1-benzofuran-2-one exists largely as an enolate at pH 7.5. The furan-2-ones were β-lactamase substrates with reactivity very similar to the analogous acyclic phenaceturates. They were not, however, dd -peptidase inhibitors and are thus unlikely to have antibiotic activity. The structural basis for these observations is discussed.

Crystal structures of covalent complexes of β-lactam antibiotics with Escherichia coli penicillin-binding protein 5: toward an understanding of antibiotic specificity.

Penicillin-binding proteins (PBPs) are the molecular targets for the widely used β-lactam class of antibiotics, but how these compounds act at the molecular level is not fully understood. We have determined crystal structures of Escherichia coli PBP 5 as covalent complexes with imipenem, cloxacillin, and cefoxitin. These antibiotics exhibit very different second-order rates of acylation for the enzyme. In all three structures, there is excellent electron density for the central portion of the β-lactam, but weak or absent density for the R1 or R2 side chains. Areas of contact between the antibiotics and PBP 5 do not correlate with the rates of acylation. The same is true for conformational changes, because although a shift of a loop leading to an electrostatic interaction between Arg248 and the β-lactam carboxylate, which occurs completely with cefoxitin and partially with imipenem and is absent with cloxacillin, is consistent with the different rates of acylation, mutagenesis of Arg248 decreased the level of cefoxitin acylation only 2-fold. Together, these data suggest that structures of postcovalent complexes of PBP 5 are unlikely to be useful vehicles for the design of new covalent inhibitors of PBPs. Finally, superimposition of the imipenem-acylated complex with PBP 5 in complex with a boronic acid peptidomimetic shows that the position corresponding to the hydrolytic water molecule is occluded by the ring nitrogen of the β-lactam. Because the ring nitrogen occupies a similar position in all three complexes, this supports the hypothesis that deacylation is blocked by the continued presence of the leaving group after opening of the β-lactam ring.