Structure-Activity Relationships of Different {beta}-Lactam Antibiotics against a Soluble Form of Enterococcus faecium PBP5, a Type II Bacterial Transpeptidase

Penicillin-binding proteins (PBPs) catalyze the essential reactionsin the biosynthesis of cell wall peptidoglycan from glycopeptideprecursors. ß-Lactam antibiotics normally interferewith this process by reacting covalently with the active siteserine to form a stable acyl-enzyme. The design of novel ß-lactamsactive against penicillin-susceptible and penicillin-resistantorganisms will require a better understanding of the moleculardetails of this reaction. To that end, we compared the affinitiesof different ß-lactam antibiotics to a modified solubleform of a resistant Enterococcus faecium PBP5 ( ${Delta}$ 1-36 rPBP5).The soluble protein, ${Delta}$ 1-36 rPBP5, was expressed in Escherichiacoli and purified, and the NH₂-terminal protein sequence wasverified by amino acid sequencing. Using ß-lactamswith different R1 side chains, we show that azlocillin has greateraffinity for ${Delta}$ 1-36 rPBP5 than piperacillin and ampicillin (apparentK_i = 7 ± 0.3 µM, compared to 36 ± 3 and51 ± 10 µM, respectively). Azlocillin also exhibitsthe most rapid acylation rate (apparent k₂ = 15 ± 4 M^–1s^–1). Meropenem demonstrates an affinity for ${Delta}$ 1-36 rPBP5comparable to that of ampicillin (apparent K_i = 51 ±15 µM) but is slower at acylating (apparent k₂ = 0.14± 0.02 M^–1 s^–1). This characterization definesimportant structure-activity relationships for this clinicallyrelevant type II transpeptidase, shows that the rate of formationof the acyl-enzyme is an essential factor determining the efficacyof a ß-lactam, and suggests that the specific sidechain interactions of ß-lactams could be modifiedto improve inactivation of resistant PBPs.

INTRODUCTION

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Introduction

Bacterial penicillin-binding proteins (PBPs) are members ofthe penicilloyl serine transferase family of enzymes (2, 3,8, 11). PBPs catalyze the essential reactions in the biosynthesisof cell wall peptidoglycan from the glycolipid precursor, lipidII (2). These reactions are composed of two parts: transglycosylationand transpeptidation. Transglycosylation joins the disaccharidesof lipid II monomers to the peptidoglycan, creating the N-acetylmuramicacid and N-acetylglucosamine backbone of the murein sacculus.Transpeptidation cross-links the glycosidic backbone into anetwork of interlocking units that confers exceptional tensilestrength. There are three broad types of PBPs (types I to III).Type I PBPs are multifunctional, multidomain proteins catalyzingboth peptidoglycan polymerization and cross-linking. Type IIPBPs are monofunctional multidomain proteins catalyzing thepeptidoglycan linkage (D,D-transpeptidases). Type III PBPs aremonofunctional D,D-carboxypeptidases; these enzymes remove theterminal D-Ala to prevent further cross-linking (4).

ß-Lactam antibiotics normally inactivate PBPs andinterfere with the process of transpeptidation by forming anester bond between the active site serine and the carbonyl carbonof the ß-lactam. Hence, ß-lactams mimicthe acyl-D-Ala-D-Ala of the bacterial cell wall in their interactionswith transpeptidases (13). This process is represented in equation1, where L represents a ß-lactam:

(1)
Unfortunately,penicillin resistance mediated by PBPs that are, or have become,insensitive to the inhibition by ß-lactams is foundin many clinically important pathogens. Some of the more problematicpathogens are Staphylococcus aureus (methicillin-resistant S.aureus [MRSA]), coagulase-negative staphylococci (CNS), Neisseriagonorrhoeae, Streptococcus pneumoniae, Enterococcus faecium,and Enterococcus faecalis (6). The increasing prevalence andresistance of these pathogens are overcoming our best therapeuticefforts, since few antibiotics are available to treat thesepenicillin-resistant organisms.

One of the most pressing clinical problems in the chemotherapyof gram-positive infections is the treatment of high-level ampicillin-resistantE. faecium. Ampicillin-resistant E. faecium expresses variantsof PBP5 that are very insensitive to attack by penicillin (hereindesignated rPBP5 for resistant PBP5) (14). Similar to PBP2aof MRSA, PBP5 of E. faecium acts as the principle cell wall-synthesizingenzyme when all the other PBPs have been inactivated by ampicillinor penicillin (9). The individual contribution of each aminoacid mutation to penicillin resistance has been inferred froma direct comparison between penicillin-susceptible and penicillin-resistantenterococcal PBP5s (14). The recent crystal structure of E.faecium PBP5 has highlighted the relationships in the activesite residues that impact upon the penicillin-resistant phenotype(12). Most notably, the increased rigidity of the penicillin-bindingsite due to the formation of a salt bridge between residuesR464 and D481 and lower accessibility for the active site cleftas a result of a unique amino acid substitution (e.g., V465)defines the low affinity of benzylpenicillin for the activesite.

Herein, we initiated investigations with a soluble form of rPBP5of E. faecium to systematically characterize the affinitiesof different ß-lactam antibiotics against this penicillin-resistantcell wall-synthesizing enzyme. Unlike other PBP5s, the PBP5protein of E. faecium is not a D,D-peptidase (11). This is thefirst comparative study addressing structure-activity relationshipsof different ß-lactams against enterococcal rPBP5.Comparing the effects of different R1 side chains, we demonstratethat the acylureido-penicillin, azlocillin, possesses the highestapparent affinity for the active site of ${Delta}$ 1-36 rPBP5. Using carbapenemsas a means to explore the effects of the R2 side chains, wealso show that meropenem possesses the same affinity as ampicillinfor ${Delta}$ 1-36 rPBP5, but it is significantly slower at acylation.Taken together, these data explain why rPBP5 in E. faecium isresistant to many ß-lactams and that the inactivationprocess exceeds the dividing time of enterococci.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains and plasmids. The clinical strain E. faecium vanB E45-7 was employed for isolationof chromosomal DNA used to construct ${Delta}$ 1-36 rPBP5 (Mensch et al.,unpublished data). E. faecium DNA was digested with XbaI, anda 4.5-kb insert was identified containing the pbp5 gene, itspromoter, and the napA gene. PCR primers were next designedbased upon the DNA sequence of Enterococcus hirae PBP3r (EMBLaccession number X69092) and used to generate a pbp5 amplificationproduct. The amplicon was then cloned into the plasmid vectorpUC19 (New England Biolabs). This was used in Southern hybridizationexperiments to screen a library of E. faecium DNA identifyingthe complete gene for rPBP5. The 2,037-bp open reading frameencoding a 679-amino-acid protein with an M_r of 73,780 was nextidentified. Plasmids pREP4, pDS56/RBS11, and pMC56 were usedfor cloning and overexpression of the rPBP5. The truncated protein( ${Delta}$ 1-36 rPBP5) was expressed in pMC56 and lacked the membrane-anchoringdomain. A representation of ${Delta}$ 1-36 rPBP5 is shown in Fig. 1.

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FIG. 1. Ribbon representation of the structure of E. faecium ${Delta}$ 1-36 rPBP5.

Protein purification. Purification of ${Delta}$ 1-36 rPBP5 was performed by using size exclusionchromatography, anion exchange with DEAE cellulose, and hydroxyapatitecolumns as described elsewhere (B. Mensch et al., unpublished).Protein concentrations were determined using a commerciallyavailable Bio-Rad protein assay reagent (Hercules, Calif.) andbovine serum albumin as a standard. Purity was assessed by resolutionof ${Delta}$ 1-36 rPBP5 on sodium dodecyl sulfate-8% polyacrylamide gelelectrophoresis (SDS-PAGE) gels.

N-Terminal amino acid sequencing. Pulsed liquid-phase Edman degradation amino acid sequencingwas performed on an Applied Biosystems Procise 494 protein sequencer(Applied Biosystems, Foster City, Calif.) to confirm truncationof ${Delta}$ 1-36 rPBP5 (Case School of Medicine Core Facility).

ß-Lactam antibiotics. BOCILLIN FL was obtained from Molecular Probes (Eugene, Oreg.).Benzylpenicillin was purchased from Fluka (Milwaukee, Wis.).Ampicillin, carbenicillin, azlocillin, and piperacillin wereobtained from Sigma Chemical Co. (St. Louis, Mo.). Aztreonamand cefepime were purchased from Bristol-Myers Squibb (Princeton,N.J.). Ticarcillin was obtained from GlaxoSmithKline (ResearchTriangle Park, N.C.). Meropenem was purchased from Astra Zeneca(Wilmington, Del.), and imipenem-cilistatin and ertapenem wereobtained from Merck Research Laboratories (Whitehouse Station,N.J.). The structure of each antibiotic is shown in Fig. 2.All antibiotics were dissolved in phosphate-buffered saline(PBS; 2 mM monobasic sodium phosphate, 8 mM dibasic sodium phosphate,154 mM sodium chloride) at pH 7.4, at room temperature.

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FIG. 2. Chemical structures of ß-lactams used in these studies.

Kinetics of ß-lactam- ${Delta}$ 1-36 rPBP5 interaction. All kinetic studies were performed in PBS at 37°C. A UVtrans-illuminator with ${lambda}$ = 302 nm was used and fluorescence intensity(F_I; binding of BOCILLIN FL to ${Delta}$ 1-36 rPBP5) was visualized witha Gel DOC 2000 imaging system (Quantity One software; Bio-Rad).Densitometry was performed using Scion Image, a Windows-compatibleversion of NIH Image (www.scioncorp.com), as previously described(12). In each assay, background fluorescence was subtracted.The maximum value of F_I (F_{I max}) defined complete saturationof 9.5 µM ${Delta}$ 1-36 rPBP5.

${Delta}$ 1-36 rPBP5, like other PBPs, is acylated by ß-lactamantibiotics and deacylated according to the following scheme:

(2)
where E represents the enzyme ( ${Delta}$ 1-36 rPBP5), Lis the ß-lactam, E:L is the Michaelis complex, E-Lis the acylated enzyme, and P is the hydrolyzed ß-lactamproduct. In the analysis that follows, the ratio of k_-1/k₁ willbe represented by the term K. In all experiments using BOCILLINFL, the rate of formation of the hydrolyzed product P was veryslow, which allowed us to neglect k₃.

First, the apparent affinity of BOCILLIN FL for ${Delta}$ 1-36 rPBP5 (K_m)was determined by reacting increasing concentrations (0 to 300µM BOCILLIN FL) with 9.5 µM ${Delta}$ 1-36 rPBP5 for 4 h.F_I was measured, graphed against the concentration of BOCILLINFL, and fit to the working expression:

(3)
Adaptingthe method of Golemi-Kotra et al. (5), the first-order rateconstant for acylation (k₂) of BOCILLIN FL to ${Delta}$ 1-36 rPBP5 wasderived by measuring F_I and k_obs for increasing concentrations.BOCILLIN FL (0 to 500 µM) was mixed with 9.5 µM ${Delta}$ 1-36 rPBP5 for 0 to 360 min. Beginning with time zero (and att = 10, 30, 60, 120, 180, 240, 300, and 360 min), a sample ofthe reaction mix was rapidly frozen to –80°C. Sampleswere thawed and resolved on SDS-8% PAGE gels. F_I was measured,and the amount of enzyme acylated was determined by densitometryand graphed as a function of time. The data were fit to a first-orderexponential rate equation:

(4)
and wederived values for k_obs for each concentration. The measuredk_obs values were plotted against BOCILLIN FL concentration,and the slope of the line defined the apparent first-order rateconstant (k₂) for BOCILLIN FL, based on equation 5:

(5)
Using BOCILLIN FL as the reporter substrate,we next derived the apparent first-order rate constant for acylation(k₂) for unlabeled ß-lactams in a competition reactionalso adapted from the methods described by Golemi-Kotra et al.(5) and Frere et al. (1). This apparent first-order rate constantfor acylation of the reaction with unlabeled ß-lactamswas determined using a fixed concentration (500 µM) ofBOCILLIN FL. Here, BOCILLIN FL and concentrations of the unlabeledß-lactams that inhibited binding by approximately50% were incubated with ${Delta}$ 1-36 rPBP5 at 37°C for 60 min, andthe amount of BOCILLIN FL bound to ${Delta}$ 1-36 rPBP5 (amount acylated)was measured as described above. We derived the apparent k₂of the unlabeled ß-lactam using equation 6:

(6)
Here, [U] represents the concentration of unlabeledß-lactam, and F₀ and F_U are the F_Is of BOCILLIN FLand unlabeled ß-lactam reacting with 9.5 µM ${Delta}$ 1-36 rPBP5, respectively.

To determine 50% inhibitory concentration (IC₅₀) values, weperformed direct competition assays. In brief, increasing concentrationsof the unlabeled test ß-lactam antibiotic were addedto a solution of PBS containing 200 µM BOCILLIN FL. Tothese mixtures, 9.5 µM ${Delta}$ 1-36 rPBP5 was added. Samples wereincubated for 4 h at 37°C and then rapidly frozen to –80°C.Aliquots were resolved on SDS-8% PAGE gels as described above.F_I was measured, and the amount of acylation was estimated basedupon the F_I value obtained from a control sample run withoutcompeting test antibiotic.

To estimate the apparent inhibition constant (K_i) of each unlabeledß-lactam for ${Delta}$ 1-36 rPBP5, we reacted 9.5 µM ${Delta}$ 1-36rPBP5, 200 µM BOCILLIN FL, and increasing concentrationsof unlabeled ß-lactam and then measured F_I. The reciprocalsof the densitometry values obtained were graphed versus concentrationof unlabeled ß-lactam, and the apparent K_i of eachunlabeled ß-lactam for ${Delta}$ 1-36 rPBP5 was determined fromthe slope and intercept of the reciprocal plot. We correctedeach value for the affinity of BOCILLIN FL by using equation7 (see also reference 7):

(7)

Molecular representation. Molecular modeling was performed using the program MOLOC (http://www.moloc.ch)and compared to the X-ray crystal structure of the PBP2a ofMRSA complexed with benzylpenicillin and ${Delta}$ 1-36 rPBP5 (unpublisheddata). Azlocillin was docked manually in the active site of ${Delta}$ 1-36 rPBP5. Two-step energy minimizations were performed.

RESULTS AND DISCUSSION

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Results and Discussion

Our investigations with ${Delta}$ 1-36 rPBP5 of E. faecium attempted toelucidate the structure-activity relationships of a series ofß-lactam antibiotics against this highly resistantcell wall-synthesizing enzyme. This approach explored the effectsof different R1 and R2 side chains in ß-lactam binding.

Expression, purification, and characterization of E. faecium ${Delta}$ 1-36 rPBP5. The truncated protein ${Delta}$ 1-36 rPBP5 was expressed in E. coli insoluble form and purified to homogeneity. To verify that theprotein expressed did not possess the membrane-anchoring domain( ${Delta}$ 1-36), we performed N-terminal amino acid sequencing. Sequencingof the amino terminus NH₂-MYQETQAVEAG demonstrated that ourconstruct contained the correct N-terminal sequence. This formof the protein ensured solubility and facilitated purification,while preserving enzymatic activity (binding of ß-lactams).

Kinetics of ß-lactam- ${Delta}$ 1-36 rPBP5 interactions. To study the affinity of the various ß-lactams for ${Delta}$ 1-36 rPBP5, we first determined the binding of BOCILLIN FL to14.5 µg (9.5 µM) of this protein with an excessof the fluorescent ß-lactam. Our initial experimentsdemonstrated ${Delta}$ 1-36 rPBP5 reached a stable level of labeling within4 h (F_{I max}) (Fig. 3).

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FIG. 3. Determination of maximum F_I (F_{I max}) by reacting 200 µM BOCILLIN FL with ${Delta}$ 1-36 rPBP5 for 4 h.

We next determined the affinity of BOCILLIN FL for ${Delta}$ 1-36 rPBP5.As expected, a monophasic saturation curve resulted from thebinding of BOCILLIN FL to ${Delta}$ 1-36 rPBP5. From this analysis, wecalculated the affinity of BOCILLIN FL for ${Delta}$ 1-36 PBP5 to be 70± 27 µM.

Table 1 summarizes the IC₅₀ and apparent inhibition constant(K_i) of unlabeled ß-lactams when using 200 µMBOCILLIN FL as the competing ß-lactam. These competitionexperiments were used as indicators of the sensitivity of the ${Delta}$ 1-36 PBP5 to inactivation by ß-lactams. We tested11 representative ß-lactams (penams, penems, and cephems)under identical conditions. These included benzylpenicillin,one aminopenicillin (ampicillin), two carboxypenicillins (carbenicillinand ticarcillin), two ureidopenicillins (piperacillin and azlocillin),three carbapenems (meropenem, ertapenem, and imipenem), onemonobactam (aztreonam), and one advanced-generation cephalosporin(cefepime). The penicillins chosen differed primarily in thecomposition of the R1 side chain and the length of the substituentsfrom the N-8 position. The carbapenems differed primarily inthe structure of the R2 side chains: the R1 side chain is uniformin each carbapenem (6- ${alpha}$ -hydroxyethyl moiety).

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TABLE 1. Kinetics of different ß-lactam substrates for ${Delta}$ 1-36 rPBP5^a

Azlocillin possessed the greatest apparent affinity for theactive site of ${Delta}$ 1-36 rPBP5 (lowest K_i) (Fig. 4; Table 1). Thisresult was unanticipated, since azlocillin was initially usedas an antipseudomonal ß-lactam and has not been exploredas an agent effective against the enterococci. As expected,benzylpenicillin was less active than ampicillin or piperacillin.In contrast, the carboxypenicillins (carbenicillin and ticarcillin),cefepime, and aztreonam were the least-active ß-lactamsin competition with BOCILLIN FL.

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FIG. 4. Comparative binding studies (IC₅₀ determinations) performed with 200 µM BOCILLIN. Azlocillin demonstrated the greatest affinity for ${Delta}$ 1-36 rPBP5 of E. faecium.

Among the penems, meropenem demonstrated a greater affinity(lower IC₅₀) for ${Delta}$ 1-36 rPBP5 compared to imipenem or ertapenem(Table 1; Fig. 4). In fact, meropenem and ampicillin appearto have equal apparent affinity for ${Delta}$ 1-36 rPBP5. In contrastto ampicillin, benzylpenicillin, and piperacillin, the relativesizes and active site binding interactions of the carbapenemsexamined in this study suggest a role of the R2 side chainsin ß-lactam binding. Hence, this analysis led us toconclude that both R1 and R2 side chains influence substrateaffinity for ${Delta}$ 1-36 rPBP5.

In order to understand the dynamic consequence of differingaffinities of ß-lactams in binding to ${Delta}$ 1-36 rPBP5,we determined the time dependence of the accumulation of BOCILLINFL to ${Delta}$ 1-36 rPBP5 in the absence of a competing ß-lactam.Based upon the reaction time courses of 50, 100, 150, 200, and250 µM BOCILLIN binding, we calculated k_obs for each concentration(0.11, 0.15, 0.21, 0.25, and 0.33 s^–1, respectively).Graphing k_obs versus BOCILLIN FL concentration, we derived ak₂ of 1.1 ± 0.1 M^–1 s^–1 (r² = 0.98). Usingequation 6, we determined an apparent acylation rate for a seriesof other ß-lactams by a competition method. The rankorder corresponded in large part to the IC₅₀ values (Table 1;Fig. 4 and 5). Again, we noted that the fastest acylation ratewas observed with the acylureidopenicillin, azlocillin. Piperacillinand ampicillin acylated ${Delta}$ 1-36 rPBP5 at similar rates. Meropenem,a ß-lactam with the same affinity as ampicillin, wassignificantly slower at acylating ${Delta}$ 1-36 rPBP5 than was ampicillin.

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FIG. 5. Determination of second-order rate constants for competing ß-lactams. Each ß-lactam was competed with 500 µM BOCILLIN for 1 h at 37°C.

This experimental approach shows that the properties of theside chains R1 and R2 are essential determinants in the bindingof ß-lactams to ${Delta}$ 1-36 rPBP5. It has not escaped ournotice that R1 modifications of the penicillin structure canbe used in drug synthesis strategies to find potent inhibitorsof this bacterial type II transpeptidase. The modeling performedherein suggests that the additional ureido side chain of azlocillinpenetrates deeper into the active site of ${Delta}$ 1-36 PBP5 than anyof the other ß-lactam side chains (Fig. 6). The importanceof the additional noncovalent interactions remains to be proven.

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FIG. 6. (Left) Experimentally observed conformation of the benzylpenicillinoyl moiety of the acyl-enzyme complex formed with ${Delta}$ 1-36 rPBP5. (Right) Modeled conformation of the penicillinoyl moiety of the acyl-enzyme complex formed between ${Delta}$ 1-36 rPBP5 and azlocillin, based on the benzylpenicillin complex. The carbonyl oxygen of the ureido side chain offers H-bonding interactions not present with other ß-lactams.

Preliminary attempts to use azlocillin in combination with anotherß-lactam, as a double ß-lactam synergisticcombination, in susceptibility tests were not very successful(data not shown). Screening a heterogeneous collection of ampicillin-resistantE. faecium isolates, we were not able to demonstrate, in a consistentmanner, bacterial synergy using azlocillin (50 and 100 µg/ml)added to increasing concentrations of piperacillin. However,it is suspected from the data that despite its high affinity,the absolute rate of inactivation at clinically relevant concentrationswas so low that there was no effective inhibition.

In conclusion, these experiments are a necessary first stepin the study of the dynamic interactions of various ß-lactamswith a highly resistant target, ${Delta}$ 1-36 rPBP5. Studies such asthis complement the existing investigations that have used asimilar approach to analyze the S. pneumoniae PBP2x and themethicillin-resistant PBP2a of S. aureus (10). Like investigationswith ß-lactamase inhibitors and the inactivation ofinhibitor-resistant SHV enzymes, these data shows that boththe affinity and rate at which ${Delta}$ 1-36 rPBP is inactivated aresignificant factors in the evaluation of potent inhibitors oftranspeptidation (7). A series of variants of ${Delta}$ 1-36 rPBP5 havebeen already constructed that are aimed at further exploringthe role of individual amino acid substitutions on ${Delta}$ 1-36 rPBP5binding of penicillin.

ACKNOWLEDGMENTS

This work was supported by grants from the Veterans AffairsMedical Center Merit Review, Career Development, and VISN 10programs (R.A.B., M.S.H., and L.B.R.). L.B.R. is also supportedby the NIH (R01 AI 45626). J.D.B. acknowledges the continuedsupport of the Robert A. Welch foundation.

FOOTNOTES

* Corresponding author. Mailing address: Louis Stokes Cleveland Veterans Affairs Medical Center, 10701 East Blvd., Cleveland, OH 44106. Phone: (216) 791-3800, ext. 4399. Fax: (216) 231-3482. E-mail: Robert.Bonomo{at}med.va.gov.

REFERENCES

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