Beta-lactamase of Bacillus licheniformis 749/C at 2 A resolution

Catalytic properties of class A beta-lactamases: efficiency and diversity

beta-Lactamases are the main cause of bacterial resistance to penicillins, cephalosporins and related beta-lactam compounds. These enzymes inactivate the antibiotics by hydrolysing the amide bond of the beta-lactam ring. Class A beta-lactamases are the most widespread enzymes and are responsible for numerous failures in the treatment of infectious diseases. The introduction of new beta-lactam compounds, which are meant to be 'beta-lactamase-stable' or beta-lactamase inhibitors, is thus continuously challenged either by point mutations in the ubiquitous TEM and SHV plasmid-borne beta-lactamase genes or by the acquisition of new genes coding for beta-lactamases with different catalytic properties. On the basis of the X-ray crystallography structures of several class A beta-lactamases, including that of the clinically relevant TEM-1 enzyme, it has become possible to analyse how particular structural changes in the enzyme structures might modify their catalytic properties. However, despite the many available kinetic, structural and mutagenesis data, the factors explaining the diversity of the specificity profiles of class A beta-lactamases and their amazing catalytic efficiency have not been thoroughly elucidated. The detailed understanding of these phenomena constitutes the cornerstone for the design of future generations of antibiotics.

Characterization of a new TEM-derived beta-lactamase produced in a Serratia marcescens strain

A natural TEM variant beta-lactamase was isolated from an epidemic strain of Serratia marcescens. Nucleotide gene sequencing revealed multiple point mutations located in the 42-to-44 tripeptide and positions 145 to 146, 178, and 238. In addition, a glutamic acid 212 deletion was also found. The purified enzyme was studied from a kinetic point of view, revealing the highest catalytic efficiency (k[cat]/Km) values for ceftazidime and aztreonam compared with the TEM-1 prototype enzyme. The in vitro resistance correlated with kinetic parameters, and the enzyme also mediated resistance to some penicillins and an ampicillin-clavulanic acid combination. The mutational and kinetic changes are discussed in relation to the three-dimensional crystallographic structure of the wild-type TEM-1 enzyme.

pKa calculations for class A beta-lactamases: methodological and mechanistic implications

Beta-lactamases are responsible for resistance to penicillins and related beta-lactam compounds. Despite numerous studies, the identity of the general base involved in the acylation step is still unclear. It has been proposed, on the basis of a previous pKa calculation and analysis of structural data, that the unprotonated Lys73 in the active site could act as the general base. Using a continuum electrostatic model with an improved treatment of the multiple titration site problem, we calculated the pKa values of all titratable residues in the substrate-free TEM-1 and Bacillus licheniformis class A beta-lactamases. The pKa of Lys73 in both enzymes was computed to be above 10, in good agreement with recent experimental data on the TEM-1 beta-lactamase, but inconsistent with the proposal that Lys73 acts as the general base. Even when the closest titratable residue, Glu166, is mutated to a neutral residue, the predicted downward shift of the pKa of Lys73 shows that it is unlikely to act as a proton abstractor in either enzyme. These results support a mechanism in which the proton of the active Ser70 is transferred to the carboxylate group of Glu166.

Characterization and amino acid sequence analysis of a new oxyimino cephalosporin-hydrolyzing class A beta-lactamase from Serratia fonticola CUV

Serratia fonticola CUV produces two isoenzymes (forms I and II) with beta-lactamase activity which were purified by a five-step procedure. The isoenzymes had identical kinetic parameters and isoelectric point (pI = 8.12). They were characterized by a specific activity towards benzylpenicillin of 1650 U/mg. The beta-lactamase hydrolyzed benzylpenicillin, amoxycillin, ureidopenicillins, first- and second-generation cephalosporins. Carboxypenicillins and isoxazolylpenicillins were hydrolyzed to a lesser extent. Towards cefotaxime and ceftriaxone (third-generation cephalosporins), the S. fonticola enzyme exhibited catalytic efficiencies much higher than those of MEN-1 and extended-spectrum TEM derivative beta-lactamases. The beta-lactamase from S. fonticola was markedly inhibited by beta-lactamase inhibitors such as clavulanic acid, sulbactam and tazobactam. The purified isoenzymes were digested by trypsin, endoproteinase Asp-N and chymotrypsin. Amino acid sequence determinations of the resulting peptides allowed the alignment of 267 amino acid residues (Swiss-Prot, accession number P 80545) for form I beta-lactamase. Form II is five residues shorter than form I at its N-terminus. From amino acid sequence comparisons, S. fonticola CUV beta-lactamase was found to share more than 69.3% identity with the chromosomally encoded beta-lactamases of Klebsiella oxytoca, Proteus vulgaris, Citrobacter diversus and the plasmid-mediated enzymes MEN-1 and Toho-1. Therefore, the oxyimino cephalosporin-hydrolyzing beta-lactamase of S. fonticola belongs to Ambler's class A. Contribution of the serine at ABL 237 in the broad-spectrum activity of these beta-lactamases is discussed.

Cloning and characterization of the ponA gene encoding penicillin-binding protein 1 from Neisseria gonorrhoeae and Neisseria meningitidis

The ponA gene encoding penicillin-binding protein 1 (PBP 1) from Neisseria gonorrhoeae was cloned by a reverse genetic approach. PBP 1 was purified from solubilized membranes of penicillin-susceptible strain FA19 by covalent ampicillin affinity chromatography and used to obtain an NH2-terminal amino acid sequence. A degenerate oligonucleotide based on this protein sequence and a highly degenerate oligonucleotide based on a conserved amino acid motif found in all class A high-molecular-mass PBPs were used to isolate the PBP 1 gene (ponA). The ponA gene encodes a protein containing all of the conserved sequence motifs found in class A PBPs, and expression of the gene in Escherichia coli resulted in the appearance of a new PBP that comigrated with PBP 1 purified from N. gonorrhoeae. A comparison of the gonococcal ponA gene to its homolog isolated from Neisseria meningitidis revealed a high degree of identity between the two gene products, with the greatest variability found at the carboxy terminus of the two deduced PBP 1 protein sequences.

Site-directed mutagenesis of glutamate 166 in two beta-lactamases. Kinetic and molecular modeling studies

The catalytic pathway of class A beta-lactamases involves an acyl-enzyme intermediate where the substrate is ester-linked to the Ser-70 residue. Glu-166 and Lys-73 have been proposed as candidates for the role of general base in the activation of the serine OH group. The replacement of Glu-166 by an asparagine in the TEM-1 and by a histidine in the Streptomyces albus G beta-lactamases yielded enzymes forming stable acyl-enzymes with beta-lactam antibiotics. Although acylation of the modified proteins by benzylpenicillin remained relatively fast, it was significantly impaired when compared to that observed with the wild-type enzyme. Moreover, the E166N substitution resulted in a spectacular modification of the substrate profile much larger than that described for other mutations of Omega-loop residues. Molecular modeling studies indicate that the displacement of the catalytic water molecule can be related to this observation. These results confirm the crucial roles of Glu-166 and of the "catalytic" water molecule in both the acylation and the deacylation processes.

A point mutation leads to altered product specificity in beta-lactamase catalysis

beta-Lactamases are the primary cause of beta-lactam antibiotic resistance in many pathogenic organisms. The beta-lactamase catalytic mechanism has been shown to involve a covalent acyl-enzyme. Examination of the structure of the class A beta-lactamase from Bacillus licheniformis suggested that replacement of Asn-170 by leucine would disrupt the deacylation reaction by displacing the hydrolytic water molecule. When N170L beta-lactamase was reacted with penicillins, a novel product was formed. We postulate that with leucine at position 170 the acyl-enzyme undergoes deacylation by an intramolecular rearrangement (rather than hydrolysis) to form a thiazolidine-oxazolinone as the initial product. The oxazolinone subsequently undergoes rapid breakdown leading to the formation of N-phenylacetylglycine and N-formylpenicillamine. This appears to be the first reported case where a point mutation leads to a change in enzyme mechanism resulting in a substantially altered product, effectively changing the product specificity of beta-lactamase into that of D-Ala-D-Ala-carboxypeptidase interacting with benzylpenicillin.

A disulfide bridge near the active site of carbapenem-hydrolyzing class A beta-lactamases might explain their unusual substrate profile

Bacterial resistance to beta-lactam antibiotics, a clinically worrying and recurrent problem, is often due to the production of beta-lactamases, enzymes that efficiently hydrolyze the amide bond of the beta-lactam nucleus. Imipenem and other carbapenems escape the activity of most active site serine beta-lactamases and have therefore become very popular drugs for antibacterial chemotherapy in the hospital environment. Their usefulness is, however, threatened by the appearance of new beta-lactamases that efficiently hydrolyze them. This study is focused on the structure and properties of two recently described class A carbapenemases, produced by Serratia marcescens and Enterobacter cloacae strains and leads to a better understanding of the specificity of beta-lactamases. In turn, this will contribute to the design of better antibacterial drugs. Three-dimensional models of the two class A carbapenemases were constructed by homology modeling. They suggested the presence, near the active site of the enzymes, of a disulfide bridge (C69-C238) whose existence was experimentally confirmed. Kinetic parameters were measured with the purified Sme-1 carbapenemase, and an attempt was made to explain its specific substrate profile by analyzing the structures of minimized Henri-Michaelis complexes and comparing them to those obtained for the "classical" TEM-1 beta-lactamase. The peculiar substrate profile of the carbapenemases appears to be strongly correlated with the presence of the disulfide bridge between C69 and C238.

Recovery of active beta-lactamases from Proteus vulgaris and RTEM-1 hybrid by random mutagenesis by using a dnaQ strain of Escherichia coli

Proteus vulgaris and RTEM-1 beta-lactamases that belong to molecular class A with 37% amino acid similarity were examined to find the relationship between amino acid residues and activity of enzymes. MICs of ampicillin were > 2,000 micrograms/ml for Escherichia coli cells producing these enzymes. We have made 18 hybrid genes by substituting the coding region of the P. vulgaris beta-lactamase gene with the equivalent portions from the RTEM-1 gene. Most of these hybrids produced inactive proteins, but a few hybrid enzymes had partial or trace activity. From one of the hybrid genes (MIC of ampicillin, 100 micrograms/ml), we recovered three kinds of active mutants which provided ampicillin MICs of 1,000 micrograms/ml by the selection of spontaneous mutations in a dnaQ strain of E. coli. In these mutants, Leu-148, Met-182, and Tyr-274 were replaced with Val, Thr, and His, respectively. These amino acids have not been identified as residues with functional roles in substrate hydrolysis. Furthermore, from these hybrid mutants, we obtained a second set of mutants which conferred ampicillin MICs of 1,500 micrograms/ml. Interestingly, the second mutations were limited to these three amino acid substitutions. These amino acid residues which do not directly interact with substrates have an effect on enzyme activity. These mutant enzymes exhibited lower K(m) values for cephaloridine than both parental enzymes.

Discovering protein secondary structures: classification and description of isolated alpha-turns

Irregular protein secondary structures are believed to be important structural domains involved in molecular recognition processes between proteins, in interactions between peptide substrates and receptors, and in protein folding. In these respects tight turns are being studied in detail. They also represent template structures for the design of new molecules such as drugs, pesticides, or antigens. Isolated alpha-turns, not participating in alpha-helical structures, have received little attention due to the overwhelming presence of other types of tight turns in peptide and protein structures. The growing number of protein X-ray structures allowed us to undertake a systematic search into the Protein Data Bank of this uncharacterized protein secondary structure. A classification of isolated alpha-turns into different types, based on conformational similarity, is reported here. A preliminary analysis on the occurrence of some particular amino acids in certain positions of the turned structure is also presented.

Primary structure of OXA-3 and phylogeny of oxacillin-hydrolyzing class D beta-lactamases

We determined the nucleotide sequence of the blaOXA-3(pMG25) gene from Pseudomonas aeruginosa. The bla structural gene encoded a protein of 275 amino acids representing one monomer of 31,879 Da for the OXA-3 enzyme. Comparisons between the OXA-3 nucleotide and amino acid sequences and those of class A, B, C, and D beta-lactamases were performed. An alignment of the eight known class D beta-lactamases including OXA-3 demonstrated the presence of conserved amino acids. In addition, conserved motifs composed of identical amino acids typical of penicillin-recognizing proteins and specific class D motifs were identified. These conserved motifs were considered for possible roles in the structure and function of oxacillinases. On the basis of the alignment and identity scores, a dendrogram was constructed. The phylogenetic data obtained revealed five groups of class D beta-lactamases with large evolutionary distances between each group.

beta-Lactamase mutations far from the active site influence inhibitor binding

Analysis of the three dimensional structure of the class A beta-lactamases shows that Arg-244, a spatially conserved residue important for inactivation by clavulanic acid, is held in place by a hydrogen (H) bond from the residue at 276. An Asn276-Gly mutant of OHIO-1, an SHV family class A enzyme, was constructed to investigate the importance of that interaction. Compared to a strain expressing the wild type enzyme, OHIO-1, the MIC of the Asn276-Gly mutant strain was more resistant to clavulanate (0.25 vs. 2.0 micrograms/ml) in the presence of ampicillin (16 micrograms/ml) but was as susceptible to sulbactam or tazobactam plus ampicillin as the OHIO-1 bearing strain. No difference in MICs was observed when other beta-lactams were tested. Consistent with the susceptibility test results, the apparent Ki of clavulanate for the Asn276-Gly enzyme (4.5 microM) was 10-fold greater than OHIO-1 (0.4 microM). For sulbactam and tazobactam the apparent Ki decreased for Asn276-Gly enzyme (1.0 and 0.1 micrograms/ml, respectively) compared to the wild-type parent (17 and 0.7 micrograms/ml, respectively). Comparing the Asn276-Gly heta-lactamase with OHIO-1, the Vmax for most substrates except cephaloridine did not change substantially. There was a 2-15 fold decreased affinity (Km) and catalytic efficiency (Vmax/Km) for beta-lactam substrates. These data support the observation and emphasize the role for this H bonding residue in orienting Arg-244 towards the active site.

Complementary roles of mutations at positions 69 and 242 in a class A beta-lactamase

Analysis of the three-dimensional structure of class A beta-lactamases suggests that deformation of the substrate binding site can be produced by changes in the hydrophobicity of residue 69 behind the beta-sheet and by outward movement of the B3 beta-strand by introduction of a non-glycine residue at position 242 on the B4 beta-strand. By site-directed mutagenesis Met69-IleGly242-Cys, a double mutant, of the OHIO-1 beta-lactamase, was constructed. The minimum inhibitory concentrations (MICs) of the double mutant compared with the wild type and each single mutant revealed an increased susceptibility to beta-lactams. Met69-IleGly242Cys hydrolyzed cephaloridine (Km = 213 microM) but had Km > 500 microM for other beta-lactams tested including cefotaxime, and demonstrated a higher apparent Ki for inhibitors (clavulanate Ki = 500 microM sulbactam = 434 microM, and tazobactam = 70 microM). In a competition experiment with cephaloridine, the apparent Ki values for penicillin and cefotaxime remained low, 21 microM and 0.7 microM, respectively. Since Ile is twice as hydrophobic as Met, the Met69-Ile mutation may result in partial collapse of the oxyanion hole. This would also increase the distance between Arg-244 and the carboxyl of clavulanic acid. The Gly242-Cys mutation opens the lower portion of the active site to bulky R groups of cephalosporins. Although these two mutations result in a catalytically impaired enzyme, they can be used to model the complementary role of two distinct residues, neither of which interacts directly with beta-lactam substrates or inhibitors.

Contribution of mutant analysis to the understanding of enzyme catalysis: the case of class A beta-lactamases

Class A beta-lactamases represent a family of well studied enzymes. They are responsible for many antibiotic resistance phenomena and thus for numerous failures in clinical chemotherapy. Despite the facts that five structures are known at high resolution and that detailed analyses of enzymes modified by site-directed mutagenesis have been performed, their exact catalytic mechanism remains controversial. This review attempts to summarize and to discuss the many available data.

Effects of site-specific mutagenesis of tyrosine 105 in a class A beta-lactamase

Tyr-105 is a conserved residue in the Class A beta-lactamases and is in close proximity to the active-site. Tyr-105 in beta-lactamase from Bacillus licheniformis was converted into Phe by site-directed mutagenesis. This mutation caused no significant effect on the structure of the enzyme and had only small effects on the catalytic properties. In particular, in comparison to the wild-type, kcat. for benzylpenicillin was increased slightly, whereas it was decreased slightly for several other substrates. For each substrate examined, Km increased 3-4-fold in the mutant compared with the wild-type enzyme. Examination of the effect of pH on the catalytic reaction revealed only small perturbations in the pK values for the acidic and basic limbs of the kcat./Km pH profiles due to the mutation. Overall effects of the Y105F substitution on the catalytic efficiency for different penicillin and cephalosporin substrates ranged from 14% to 56% compared with the wild-type activity. We conclude that Tyr-105 is not an essential residue for beta-lactamase catalysis, but does contribute to substrate binding.

Relative specificities of a series of beta-lactam-recognizing enzymes towards the side-chains of penicillins and of acyclic thioldepsipeptides

In an attempt to understand more of the subtle differences between bacterial beta-lactamases and DD-peptidases, comparisons have been made between the specificities of these enzymes towards the phenylacetyl side chain, generally thought to be favoured by beta-lactamases, and the NN'-diacetyl-L-lysyl side chain, widely employed in low-molecular-mass substrates of DD-peptidases. These comparisons were carried out with both a penicillin and an acyclic thioldepsipeptide reaction nucleus and employing a range of both beta-lactamases and DD-peptidases. Rather contrary to general expectations, a general preference for reaction of both groups of enzymes with penicillins rather than thioldepsipeptides was observed and for the phenylacetyl rather than the NN'-diacetyl-L-lysyl side chain. Quantitative comparisons suggested that the side chains of penicillins may be bound in relatively similar sites in all of the enzymes whereas the side chains of thioldepsipeptides are more heterogeneously bound, both with respect to each other and to the comparable side chains of penicillins.

Replacement of serine 237 in class A beta-lactamase of Proteus vulgaris modifies its unique substrate specificity

The chromosomal beta-lactamase gene of Proteus vulgaris K1 was cloned and sequenced. The gene comprises 813 nucleotides and codes for the mature enzyme of 29,655 Da, comprising 271 amino acids. The K1 beta-lactamase showed 30-70% similarity, in the overall amino acid sequence, to class A beta-lactamases of Gram-negative bacteria. However, the K1 beta-lactamase differs from most class A enzymes in having a unique substrate specificity as a cephalosporinase, its spectrum extending to even oxyiminocephalosporins. To clarify the relationship between its unique substrate specificity and specific amino acid residues, alignment of the amino acid sequence of the K1 beta-lactamase with those of class A beta-lactamases was performed, and Ala104 and Ser237 were found to be candidates. Ala104 and Ser237 were replaced with glutamic acid and alanine, respectively, which are commonly found in other class A beta-lactamases. The substitution at position 104 had no effect on the enzyme activity or the substrate specificity. The amino acid replacement at position 237, however, reduced the kcat/Km value for an oxyiminocephalosporin (cefuroxime) to 17% of that in the case of the wild-type enzyme, whereas the mutant enzyme showed a higher kcat/Km value for benzylpenicillin, 3 times, than that of the wild-type enzyme. These results indicated that Ser237 is one of the residues responsible for the unique substrate specificity of the P. vulgaris beta-lactamase.

Chromosomally encoded cephalosporin-hydrolyzing beta-lactamase of Proteus vulgaris RO104 belongs to Ambler's class A

Proteus vulgaris RO104 strain produces a chromosomally encoded beta-lactamase that confers resistance to various beta-lactam antibiotics including methoxyimino third-generation cephalosporins. The beta-lactamase hydrolyzes first- and second-generation cephalosporins efficiently and cefotaxime to a lesser extent. Catalytic activity is inhibited by low concentrations of clavulanic acid and sulbactam. By its broad-spectrum substrate profile, beta-lactamase of Proteus vulgaris RO104 belongs to the group 2e defined by Bush. The protein purified to homogeneity by a four-step procedure was characterized by a pI of 8.31 and a specific activity of 1200 U/mg. The beta-lactamase was digested by trypsin, endoproteinase Asp-N and chymotrypsin. Amino-acid sequence determinations of the resulting peptides allowed the alignment of the 271 amino-acid residues of the protein which did not contain any cysteine residue. From amino-acid sequence comparisons, Proteus vulgaris RO104 beta-lactamase was found to share about 68% identity with the chromosomally mediated beta-lactamases of Klebsiella oxytoca D488 and E23004. Therefore, the cephalosporin-hydrolyzing beta-lactamase of Proteus vulgaris RO104 belongs to Ambler's class A.

The mechanism of action of DD-peptidases: the role of Threonine-299 and -301 in the Streptomyces R61 DD-peptidase

The side chains of residues Thr299 and Thr301 in the Streptomyces R61 DD-peptidase have been modified by site-directed mutagenesis. These amino acids are part of a beta-strand which forms a wall of the active-site cavity. Thr299 corresponds to the second residue of the Lys-Thr(Ser)-Gly triad, highly conserved in active-site beta-lactamases and penicillin-binding proteins (PBPs). Modification of Thr301 resulted only in minor alterations of the catalytic and penicillin-binding properties of the enzyme. No selective decrease of the rate of acylation was observed for any particular class of compounds. By contrast, the loss of the hydroxy group of the residue in position 299 yielded a seriously impaired enzyme. The rates of inactivation by penicillins were decreased 30-50-fold, whereas the reactions with cephalosporins were even more affected. The efficiency of hydrolysis against the peptide substrate was also seriously decreased. More surprisingly, the mutant was completely unable to catalyse transpeptidation reactions. The conservation of an hydroxylated residue in this position in PBPs is thus easily explained by these results.

Site-directed mutagenesis of glutamate-166 in beta-lactamase leads to a branched path mechanism

Glutamate-166 of the Bacillus licheniformis beta-lactamase was specifically mutated to aspartate and cysteine in order to probe the function of this residue in catalysis. In both cases, a large decrease in activity (kcat/Km was 3.5 x 10(-5) smaller for E166C and 1 x 10(-3) smaller for E166D than for the wild-type) was observed, although the kinetics for the two mutants were very different. The pH-rate profiles for E166D and E166C reflected the ionization characteristics of the new residue at site 166. This result indicates that the ionization of Glu-166 is responsible for the acidic limb of the kcat/Km-pH profiles, and suggests that the function of Glu-166 is that of a general base catalyst. The kinetics of the E166C mutant were investigated in detail. An initial burst was observed, whose amplitude was stoichiometric with the enzyme concentration, suggesting rate-limiting deacylation of the acyl-enzyme intermediate. However, further study revealed that in the presence of 0.5 M sodium sulfate, which stabilizes the native conformational state, the magnitude of the burst corresponded to 2 equiv of enzyme. This observation, in conjunction with the limited effect of the mutation on Km, indicated that the mutation resulted in a change in the kinetic mechanism from the linear, acyl-enzyme pathway to one with a branch leading to an inactive form of the acyl-enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)

Crystallographic structure of a phosphonate derivative of the Enterobacter cloacae P99 cephalosporinase: mechanistic interpretation of a beta-lactamase transition-state analog

The crystal structure of a complex formed on reaction of the Enterobacter cloacae P99 cephalosporinase (beta-lactamase) with a phosphonate monoester inhibitor, m-carboxyphenyl [[N-[(p-iodophenyl)acetyl]amino]methyl]phosphonate, has been obtained at 2.3-A resolution. The structure shows that the inhibitor has phosphonylated the active site serine (Ser64) with loss of the m-carboxyphenol leaving group. The inhibitor is positioned in the active site in a way that can be interpreted in terms of a transition-state analog. The arylacetamido side chain is placed as anticipated from analogous beta-lactamoyl complexes of penicillin-recognizing enzymes, with the amino group hydrogen-bonded to the backbone carbonyl of Ser318 (of the B3 beta-strand) and to the amides of Gln120 and Asn152. There is support in the asymmetry of the hydrogen bonding of this side chain to the protein and in the 2-fold disorder of the benzyl group for the considerable breadth in substrate specificity exhibited by class C beta-lactamases. One phosphonyl oxygen atom is in the oxyanion hole, hydrogen-bonded to main-chain NH groups of Ser318 and Ser64, while the other oxygen is solvated, not within hydrogen-bonding distance of any amino acid side chain. The closest active site functional group to the solvated oxygen atom is the Tyr150 hydroxyl group (3.4A); Lys67 and Lys315 are quite distant (4.3 and 5.7 A, respectively). Rather, Tyr150 and Lys67 are more closely associated with Ser64O gamma (2.9 and 3.3 A). This arrangement is interpreted in terms of the transition state for breakdown of the tetrahedral intermediate in the deacylation step of catalysis, where the Tyr150 phenol seems the most likely general acid. Thus, Tyr150, as the phenoxide anion, would be the general base catalyst in acylation, as proposed by Oefner et al. [Nature (1990) 343, 284-288]. The structure is compared with that of a similar phosphonate derivative of a class A beta-lactamase [Chen et al. (1993) J. Mol. Biol. 234, 165-178], and mechanistic comparisons are made. The sensitivity of serine beta-lactamases, as opposed to serine proteinases, toward inhibition by phosphonate monoanions is supported by electrostatic calculations showing a net positive potential only in the catalytic sites of the beta-lactamases.

A structure-based analysis of the inhibition of class A beta-lactamases by sulbactam

From the crystal structure of the Bacillus licheniformis 749/C beta-lactamase, energy-minimized structures for the precatalytic, the acyl-enzyme intermediate, and the acylated linear inactivating species for sulbactam--a clinically useful mechanism-based inactivator for class A beta-lactamases--were generated. The effect of individual Ser-235-Ala and Arg244-Ser point mutations on the inactivation and turnover processes was consistent with the existence of hydrogen bonds between the side chains of these residues and the sulbactam species. The departure of the sulfinate leaving group from the acyl-enzyme intermediate of sulbactam is believed to be a prerequisite for the inactivation process. In order to explore the influence of the leaving group, penicillanic acid (2), penicillanic acid alpha-S-oxide (3), and penicillanic acid beta-S-oxide (4) were synthesized and studied in kinetic experiments with the TEM-1 beta-lactamase. Penicillanic acid is only a substrate, but penicillanic acid S-oxides were both substrates and inactivators for the enzyme. An argument is presented to rationalize these observations on the basis of the leaving ability of thiolate, sulfenate, and sulfinate from the acyl-enzyme intermediates of penicillanic acid (2), the penicillanic acid S-oxides (3 and 4), and sulbactam, respectively. The departure of the leaving group does not appear to be rate limiting in the inactivator process, but is an indispensable component of the irreversible inactivation of the enzyme. Molecular dynamics calculations of the putative inactivating species suggest that Lys-73, Lys-234, and Ser-130 are three likely residues that may be modified in the course of the inactivation chemistry. A discussion is presented of the mechanism of formation of the transiently inhibited enzyme species, which comes about as a consequence of the tautomerization of the double bond of the inactivating iminium moiety. In addition, the mechanistic details presented for sulbactam are compared and contrasted with those of clavulanic acid, another clinically used inactivator for class A beta-lactamases.

Reversal of clavulanate resistance conferred by a Ser-244 mutant of TEM-1 beta-lactamase as a result of a second mutation (Arg to Ser at position 164) that enhances activity against ceftazidime

The mutation of Arg-244 to Ser (Arg-244-->Ser mutation) in the TEM-1 beta-lactamase has been shown to produce resistance to inactivation by clavulanate in the mutant enzyme and resistance to ampicillin plus clavulanate in a strain of Escherichia coli producing this enzyme. The Arg-164-->Ser mutation in the TEM-1 beta-lactamase (TEM-12 enzyme) is known to enhance the activity of the enzyme against ceftazidime, resulting in resistance to the drug in a strain producing the mutant enzyme (D. A. Weber, C. C. Sanders, J. S. Bakken, and J. P. Quinn, J. Infect. Dis. 162:460-465, 1990). The doubly mutated derivative of the TEM-1 enzyme (Ser-164/Ser-244) retains the characteristics of the Ser-164 mutant enzyme, i.e., enhanced activity against ceftazidime and sensitivity to inactivation by clavulanate. It also confers the same phenotype as the Ser-164 mutant enzyme, i.e., resistance to ceftazidime and ampicillin, with reversal of this resistance in the presence of clavulanate. Thus, the Arg-164-->Ser mutation in the TEM-1 beta-lactamase suppresses the effect of the Arg-244-->Ser mutation which, by itself, reduces the sensitivity of the enzyme to inactivation by clavulanate.

Sequence analysis of PER-1 extended-spectrum beta-lactamase from Pseudomonas aeruginosa and comparison with class A beta-lactamases

We have determined the nucleotide sequence (EMBL accession number, Z 21957) of the cloned chromosomal PER-1 extended-spectrum beta-lactamase gene from a Pseudomonas aeruginosa RNL-1 clinical isolate, blaPER-1 corresponds to a 924-bp open reading frame which encodes a polypeptide of 308 amino acids. This open reading frame is preceded by a -10 and a -35 region consistent with a putative P. aeruginosa promoter. Primer extension analysis of the PER-1 mRNA start revealed that this promoter was active in P. aeruginosa but not in Escherichia coli, in which PER-1 expression was driven by vector promoter sequences. N-terminal sequencing identified the PER-1 26-amino-acid leader peptide and enabled us to calculate the molecular mass (30.8 kDa) of the PER-1 mature form. Analysis of the percent GC content of blaPER-1 and of its 5' upstream sequences, as well as the codon usage for blaPER-1, indicated that blaPER-1 may have been inserted into P. aeruginosa genomic DNA from a nonpseudomonad bacterium. The PER-1 gene showed very low homology with other beta-lactamase genes at the DNA level. By using computer methods, assessment of the extent of identity between PER-1 and 10 beta-lactamase amino acid sequences indicated that PER-1 is a class A beta-lactamase. PER-1 shares around 27% amino acid identity with the sequenced extended-spectrum beta-lactamases of the TEM-SHV series and MEN-1 from Enterobacteriaceae species. The use of parsimony methods showed that PER-1 is not more closely related to gram-negative than to gram-positive bacterial class A beta-lactamases. Surprisingly, among class A beta-lactamases, PER-1 was most closely related to the recently reported CFXA from Bacteroides vulgatus, with which it shared 40% amino acid identity. This work indicates that non-Enterobacteriaceae species such as P. aeruginosa may possess class A extended-spectrum beta-lactamase genes possibly resulting from intergeneric DNA transfer.

Microbial systems and directed evolution of protein activities

Recent advances in recombinant DNA methodology have had an important impact on the capacity to manipulate protein-coding sequences. The appearance of new, powerful screening systems completes a scenario for conducting directed evolution experiments. We review here some of the latest developments in experimental approaches to directed evolution, utilizing microbial systems. These include phage display, surface display, operator-repressor systems, and novel mutagenesis approaches. We also highlight the achievements and limitations of current methodologies. We present strategies used by our own group that permitted isolation of specificity mutants of beta-lactamase. Possible improvements for the future of the variation-selection approach to the study and manipulation of proteins are presented.

Evidence for myosin motors on organelles in squid axoplasm

Squid axoplasm has proved a rich source for the identification of motors involved in organelle transport. Recently, squid axoplasmic organelles have been shown to move on invisible tracks that are sensitive to cytochalasin, suggesting that these tracks are actin filaments. Here, an assay is described that permits observation of organelles moving on unipolar actin bundles. This assay is used to demonstrate that axoplasmic organelles move on actin filaments in the barbed-end direction, suggesting the presence of a myosin motor on axoplasmic organelles. Indeed, axoplasm contains actin-dependent ATPase activity, and a pan-myosin antibody recognized at least four bands in Western blots of axoplasm. An approximately 235-kDa band copurified in sucrose gradients with KI-extracted axoplasmic organelles, and the myosin antibody stained the organelle surfaces by immunogold electron microscopy. The myosin is present on the surface of at least some axoplasmic organelles and thus may be involved in their transport through the axoplasm, their movement through the cortical actin in the synapse, or some other aspect of axonal function.

Evolution of an enzyme activity: crystallographic structure at 2-A resolution of cephalosporinase from the ampC gene of Enterobacter cloacae P99 and comparison with a class A penicillinase

The structure of the class C ampC beta-lactamase (cephalosporinase) from Enterobacter cloacae strain P99 has been established by x-ray crystallography to 2-A resolution and compared to a class A beta-lactamase (penicillinase) structure. The binding site for beta-lactam (penicillinase) structure. The binding site for beta-lactam antibiotics is generally more open than that in penicillinases, in agreement with the ability of the class C beta-lactamases to better bind third-generation cephalosporins. Four corresponding catalytic residues (Ser-64/70, Lys-67/73, Lys-315/234, and Tyr-150/Ser-130 in class C/A) lie in equivalent positions within 0.4 A. Significant differences in positions and accessibilities of Arg-349/244 may explain the inability of clavulanate-type inhibitors to effectively inactivate the class C beta-lactamases. Glu-166, required for deacylation of the beta-lactamoyl intermediate in class A penicillinases, has no counterpart in this cephalosporinase; the nearest candidate, Asp-217, is 10 A from the reactive Ser-64. A comparison of overall tertiary folding shows that the cephalosporinase, more than the penicillinase, is broadly similar to the ancestral beta-lactam-inhibited enzymes of bacterial cell wall synthesis. On this basis, it is proposed that the cephalosporinase is the older of the two beta-lactamases, and, therefore, that a local refolding in the active site, rather than a simple point mutation, was required for the primordial class C beta-lactamase to evolve to the class A beta-lactamase having an improved ability to catalyze the deacylation step of beta-lactam hydrolysis.

Critical hydrogen bonding by serine 235 for cephalosporinase activity of TEM-1 beta-lactamase

The role of Ser-235 in the catalytic mechanism of the TEM-1 beta-lactamase has been explored by the study of a mutant enzyme in which Ser-235 has been substituted by alanine (Ala-235 mutant enzyme). A comparative kinetic analysis of both the wild-type and the Ala-235 TEM-1 enzymes revealed little effect of this substitution of residue 235 on the turnover of penicillins but a greater effect on the turnover of cephalosporins. Susceptibility testing of Escherichia coli strains harboring the wild-type TEM-1 beta-lactamase and the Ala-235 mutant enzyme revealed an effect of the mutation similar to that observed in the enzymological studies. The MICs of two representative cephalosporins for the strain containing the mutant enzyme were much lower than those for the isogenic strain bearing the wild-type TEM-1 beta-lactamase. On the other hand, the strain with the mutant enzyme was still highly resistant to penicillins.

Site-directed mutagenesis of beta-lactamase TEM-1. Investigating the potential role of specific residues on the activity of Pseudomonas-specific enzymes

From sequence alignments, two groups can be defined for the carbenicillin-hydrolysing beta-lactamases (CARB enzymes). One group includes the Pseudomonas-specific enzymes PSE-1, PSE-4, CARB-3, CARB-4 and also the Proteus mirabilis GN79, for which the well-conserved residue Lys 234 in all class-A beta-lactamases is changed to an arginine residue. The second group includes the enzymes PSE-3 and AER-1 which have an arginine or a lysine residue at position 165. All these enzymes also have leucine at position 68, threonine at position 104 and glycine at position 240. We engineered these mutations into the TEM-1 beta-lactamase to study their potential role in defining the substrate profile of the CARB enzymes. The mutations K234R and E240G in TEM-1 noticeably increased the hydrolysis of carboxypenicillins relative to other penicillins by approximately sixfold and twofold, respectively. The variant E240G also demonstrated an improved rate of second-generation cephalosporin and cefotaxime hydrolysis. In contrast, the substitution of Trp165 by arginine does not extend the substrate profile to alpha-carboxypenicillins nor does it noticeably modify the kinetic behavior of the enzyme. The mutations M68L and E104T do not have a large effect on the hydrolysis rate but the mutation E104T enhances the affinity of the enzyme for third-generation cephalosporins. As the mutation K234R resulted in a severe decrease in the affinity for carboxypenicillins, the double mutant E240G/K234R was constructed in an attempt to enhance the CARB character of the enzyme. Contrary to what could be expected, the additional mutation E240G for the TEM-1 K234R enzyme increases neither the catalytic constant for the carboxypenicillins nor the affinity towards these substrates. Consequently, this study strongly suggests that the three-dimensional structures of the active site of the TEM-1 enzyme and PSE-3, PSE-4 or other related enzymes are significantly different. This probably explains the discrepancy of the substrate profile between the CARB enzymes and the TEM-1 protein variants.

A survey of a functional amino acid of class C beta-lactamase corresponding to Glu166 of class A beta-lactamases

The class C beta-lactamase of Citrobacter freundii GN346 is a typical cephalosporinase comprising 361 amino acids. The aspartic acid at position 217 and glutamic acid at position 219 in this beta-lactamase were, respectively, previously shown not to be the counterpart of Glu166 (ABL166) in class A beta-lactamases, even though sequence alignment of class A and C enzymes strongly suggested this possibility [(1990) FEBS Lett. 264, 211-214; (1990) J. Bacteriol. 172, 4348-4351]. We tried again to assign candidates for the counterpart of Glu166 through sequence alignment based on other criteria, the glutamic acids at positions 195 and 205 in the class C beta-lactamase being selected. To investigate this possibility, these two glutamic acids were changed to glutamine, lysine or alanine, respectively. All the mutant enzymes showed more than 50% of the activity of the wild-type enzyme, indicating that the possibility was ruled out. These results strongly suggested the possibility that the class C beta-lactamase lacks a functional acidic residue corresponding to Glu166 in class A enzymes.

The dacA gene of Bacillus stearothermophilus coding for D-alanine carboxypeptidase: cloning, structure and expression in Escherichia coli and Pichia pastoris

The bacterial D-alanine carboxypeptidases (CPases) remove C-terminal D-alanyl residues from sugar-peptide cell wall precursors. The CPases have many characteristics in common with the high-M(r) penicillin-binding proteins (PBPs) whose inhibition by beta-lactam antibiotics is lethal. The CPases are attractive as model PBPs, because of their relatively lower M(r) and higher activity in vitro. We have cloned and sequenced the Bacillus stearothermophilus gene (dacA) coding for a membrane-bound CPase. The nucleotide (nt) sequence of the gene is homologous to that of the Escherichia coli and Bacillus subtilis dacA loci, which also code for membrane-bound CPases. E. coli host cells lysed when expression of B. stearothermophilus dacA was induced. The same coding sequence was expressed in the methylotrophic yeast, Pichia pastoris, using the alcohol oxidase-1 (AOX1) promoter. Over 100 micrograms/ml of CPase was efficiently secreted into the medium after induction by methanol, without adversely affecting this host. The yeast product is indistinguishable from the native enzyme in structure and activity. The ability to secrete large amounts of heterologous protein and the lack of endogenous peptidoglycan metabolism makes P. pastoris an attractive candidate for the production of PBPs.

Crystal structure of Escherichia coli TEM1 beta-lactamase at 1.8 A resolution

The X-ray structure of Escherichia coli TEM1 beta-lactamase has been refined to a crystallographic R-factor of 16.4% for 22,510 reflections between 5.0 and 1.8 A resolution; 199 water molecules and 1 sulphate ion were included in refinement. Except for the tips of a few solvent-exposed side chains, all protein atoms have clear electron density and refined to an average atomic temperature factor of 11 A2. The estimated coordinates error is 0.17 A. The substrate binding site is located at the interface of the two domains of the protein and contains 4 water molecules and the sulphate anion. One of these solvent molecules is found at hydrogen bond distance from S70 and E166. S70 and S130 are hydrogen bonded to K73 and K234, respectively. It was found that the E. coli TEM1 and Staphylococcus aureus PC1 beta-lactamases crystal structures differ in the relative orientations of the two domains composing the enzymes, which result in a narrowed substrate binding cavity in the TEM1 enzyme. Local but significant differences in the vicinity of this site may explain the occurrence of TEM1 natural mutants with extended substrate specificities.

Interactions between active-site-serine beta-lactamases and compounds bearing a methoxy side chain on the alpha-face of the beta-lactam ring: kinetic and molecular modelling studies

The interactions between three class A beta-lactamases and compounds bearing a methoxy side chain on the alpha-face of the beta-lactam ring (cefoxitin, moxalactam and temocillin) have been studied. When compared with the situation prevailing with good substrates, both acylation and deacylation steps appeared to be severely impaired. Molecular modelling studies of the structures of the Henri-Michaelis complexes and of the acyl-enzymes indicate a major displacement of the crystallographically observed water molecule which connects the glutamate-166 and serine-70 side chains and underline the role of this water molecule in both reaction steps.

Mechanism of action of DD-peptidases: role of asparagine-161 in the Streptomyces R61 DD-peptidase

The role of residue Asn-161 in the interaction between the Streptomyces R61 DD-peptidase and various substrates or beta-lactam inactivators was probed by site-directed mutagenesis. The residue was successively replaced by serine and alanine. In the first case, acylation rates were mainly affected with the peptide and ester substrates but not with the thiol-ester substrates and beta-lactams. However, the deacylation rates were decreased 10-30-fold with the substrates yielding benzoylglycyl and benzoylalanyl adducts. The Asn161Ala mutant was more generally affected, although the acylation rates with cefuroxime and cefotaxime remained similar to those observed with the wild-type enzyme. Surprisingly, the deacylation rates of the benzoylglycyl and benzoylalanyl adducts were very close to those observed with the wild-type enzyme. The results also indicate that the interaction with the peptide substrate and the transpeptidation reaction were more sensitive to the mutations than the other reactions studied. The results are discussed and compared with those obtained with the Asn-132 mutants of a class A beta-lactamase.

Molecular structure of the acyl-enzyme intermediate in beta-lactam hydrolysis at 1.7 A resolution

The X-ray crystal structure of the molecular complex of penicillin G with a deacylation-defective mutant of the RTEM-1 beta-lactamase from Escherichia coli shows how these antibiotics are recognized and destroyed. Penicillin G is covalently bound to Ser 70 0 gamma as an acyl-enzyme intermediate. The deduced catalytic mechanism uses Ser 70 0 gamma as the attacking nucleophile during acylation. Lys 73 N zeta acts as a general base in abstracting a proton from Ser 70 and transferring it to the thiazolidine ring nitrogen atom via Ser 130 0 gamma. Deacylation is accomplished by nucleophilic attack on the penicilloyl carbonyl carbon by a water molecule assisted by the general base, Glu 166.