INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The important opportunistic pathogen Pseudomonas aeruginosa contains a type II or dissociated fatty acid synthetase system, in which the individual reactions are catalyzed by separate proteins (22, 24). Although the overall organization of the P. aeruginosa fab genes is similar to that in Escherichia coli (for reviews see references 9 and 28), some potentially significant differences exist. First, the P. aeruginosa fabA and fabB genes, encoding -hydroxyacyl-acyl carrier protein (ACP) dehydratase and -ketoacyl-ACP synthase I, form an operon (22), whereas in E. coli these genes map to separate genetic loci. Second, unlike in E. coli and several other gram-negative bacteria, the fabH gene, encoding -ketoacyl-synthase III, is absent from the fabD-fabG-acpP-fabF gene cluster, encoding malonyl-coenzyme A (CoA):ACP transacylase, -ketoacyl-ACP reductase, ACP, and -ketoacyl-ACP synthase II (25). Searches of the P. aeruginosa genome database revealed several potential fabH homologs located elsewhere on the genome.

Our current model for fatty acid biosynthesis in P. aeruginosa is shown in Fig. 1. Three -ketoacyl-ACP synthases, KAS I (FabB), KAS II (FabF), and KAS III (FabH), play pivotal roles in fatty acid synthesis. Initiation requires malonyl-CoA and malonyl-ACP. Malonyl-CoA is synthesized from acetyl-CoA via the acetyl carboxylase reaction (5). Malonyl-ACP is derived from malonyl-CoA and ACP by malonyl-CoA:ACP transacylase (FabD) (24, 25). Although a P. aeruginosa fabH homolog has only tentatively been identified, the first cycle of elongation is probably initiated by KAS III (FabH), which condenses malonyl-ACP with acetyl-CoA. Subsequent cycles are then initiated by condensation of malonyl-ACP with acyl-ACP, catalyzed by KAS I (FabB) for saturated fatty acid substrates and KAS II (FabF) for unsaturated fatty acid substrates. In the second step, the resulting -ketoester is reduced to a -hydroxyacyl-ACP by a NADPH-dependent -ketoacyl-ACP reductase (FabG). It has recently been shown that P. aeruginosa contains a FabG homolog, RhlG, which presumably functions as a NADPH-dependent -ketoacyl-ACP reductase specific for rhamnolipid synthesis (6). The third step in the cycle is catalyzed by either the fabA- or fabZ-encoded -hydroxyacyl-ACP dehydratase. The final step in each cycle involves conversion of trans-2-enoyl-ACP to acyl-ACP, a reaction catalyzed by NADH-dependent enoyl-ACP reductase (FabI). Physiologically, FabI is an important enzyme because (i) reduction of enoyl-ACP derivatives is thought to regulate the ratio of saturated to unsaturated fatty acids and to coordinate fatty acid and phospholipid syntheses (16, 23); and (ii) FabI plays a determinant role in completing cycles of fatty acid elongation (15). FabI belongs to the short-chain alcohol dehydrogenase family and in E. coli is the target of a group of antibacterial compounds, the diazoborines (44) and triclosan (19, 33). In Mycobacterium tuberculosis, the FabI homolog InhA is one of the targets for the clinically used antimycobacterial isoniazid (2), and genetic evidence was obtained that M. smegmatis InhA is a triclosan target (32). More recently, it has been shown that E. coli mutants resistant to the antiseptic triclosan contain fabI mutations (33), and a subsequent study confirmed that triclosan and other related compounds indeed target FabI (19). Although P. aeruginosa PAO1 is resistant to triclosan due to constitutive expression of the mexAB-oprM-encoded efflux pump, (mexAB-oprM) mutants are susceptible to triclosan (41). The E. coli FabI protein has been cocrystallized with NADH and thienodiazoborine (18), or NAD⁺ (26), and these studies allowed definition of the enzyme active site and amino acid residues important in substrate and drug interactions.

View larger version (29K): [in this window] [in a new window]   FIG. 1.   Current model for fatty acid biosynthesis in P. aeruginosa and proposed role of butyryl-ACP as acyl donor in N-butyryl-L-homoserine lactone synthesis. The genes for all enzymes except one (fabH) have been identified and characterized; for fabH, only a tentative identification has been made among several paralogs. Abbreviations: ACP, acyl carrier protein; ACP-SH, ACP with 4'-phosphopantetheine co-factor; CoA-SH; coenzyme A; FabA (and FabZ), -hydroxyacyl-ACP dehydratase; FabB, -ketoacyl synthase I; FabD; malonyl-CoA:ACP transacylase; FabF, -ketoacyl synthase II; FabG, -ketoacyl-ACP reductase; FabH, -ketoacyl synthase III; FabI; enoyl-ACP reductase; 5-MTA, 5-methylthioadenosine; SAM, S-adenosylmethionine; LasI, N-(3-oxo)-dodecanoyl homoserine lactone synthase; RhlI, N-butyryl homoserine lactone synthase.

Besides providing fatty acid intermediates for a multitude of cellular constituents (phospholipids [9], lipid A [37], etc.), the Fab pathway has been implicated in providing the acyl groups for the acylated homoserine lactones (HSLs) that are the signalling molecules in quorum sensing (14, 35, 39, 45). In P. aeruginosa, quorum sensing is a mechanism that regulates virulence factor gene expression (46), biofilm formation in vitro (10) and in natural settings (31), twitching motility (13), and other important cellular processes. According to the current model, quorum sensing in P. aeruginosa involves two separate systems, LasR-LasI and RhlR-RhlI. These proteins are encoded by two separate, tandemly arranged transcriptional units. In these two systems, the LasI and RhlI proteins are HSL synthases that direct the synthesis of N-(3-oxo)-dodecanoyl-L-homoserine lactone (3-oxo-C₁₂-HSL) and N-butyryl-L-homoserine lactone (C₄-HSL), respectively. According to the current model, the synthases react with acyl-ACPs and S-adenosylmethionine (SAM) to form the cognate HSLs, with concomitant release of 5-methylthioadenosine (35, 39). For C₄-HSL synthesis, the rhlI-encoded P. aeruginosa HSL synthase RhlI catalyzes the formation of C₄-HSL in a reaction utilizing butyryl-ACP as the acyl donor and SAM as the nucleophile in a lactonization reaction (35, 39).

In this report, we describe the characterization of the P. aeruginosa fabI gene and its product, show evidence for the presence of at least one other enoyl-ACP reductase in this bacterium, provide biochemical evidence that FabI is a triclosan target, and demonstrate its role in C₄-HSL synthesis.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacterial strains, plasmids, primers, and media. The relevant strains, plasmids, and primers are described in Table 1. LB (Luria-Bertani) medium (34) was routinely used as the rich medium for all bacterial strains. For growth of the fabI(Ts) mutant JP1111, the NaCl concentration of LB medium was reduced to 0.05%. For some experiments, RB medium (20) was used instead of LB. The minimal medium used for growth of P. aeruginosa was VBMM (40). The antibiotics used in selection media were as follows: for E. coli, ampicillin (100 µg/ml) and gentamicin (15 µg/ml); for P. aeruginosa, carbenicillin (500 µg/ml) and gentamicin (200 µg/ml).

General DNA procedures. Routine DNA were performed as previously described (21). The details underlying construction of pPS921 were as follows. For PCR amplification of a fragment from chromosomal DNA, two mutagenic oligonucleotides were synthesized. The FabIU and FabID primers were designed to introduce a HindIII site upstream of fabI and a BamHI site downstream of fabI, respectively (Table 1). These oligonucleotides were used to prime synthesis from PAO1 chromosomal DNA. PCRs were performed on a PTC-100 PCR system thermocycler (MJ Research, Watertown, Mass.) as previously described (21, 22). The ca. 870-bp PCR fragment was ligated to BamHI-HindIII-digested pWSK30 (47) DNA to form pPS921. Nucleotide sequences were determined and analyzed as previously described (22). Motif searches were performed by using the on-line E-Motif program provided by Stanford University, Palo Alto, Calif.

Disruption of the fabI gene. The fabI strain PAO235 was isolated in several steps. A plasmid-borne fabI mutation was constructed by insertion of a blunt-ended 1,053-bp gentamicin resistance (Gm^r)-FRT cassette from pPS856 (21) into the SmaI site located within the fabI coding sequence. The resulting mutation was returned to the P. aeruginosa chromosome after subcloning into the sacB-based suicide vector pEX18Tc (21) to derive the fabI::Gm^r-FRT mutant PAO234. From PAO234, the unmarked fabI::FRT mutant PAO235 was then derived by in vivo excision of the Gm^r-FRT cassette with Flp recombinase (21). The mutants were confirmed by performing colony PCR (21) utilizing the FabIU and FabID primers.

Purification of an polyhistidine-tagged FabI fusion protein. A hexahistidine-FabI (H₆-FabI) expression vector was constructed by PCR amplifying the fabI coding sequence from PAO1 genomic DNA with primers FabI-Nde, creating a NdeI site at the fabI ATG initiation codon, and FabID, which creates a BamHI site immediately downstream of fabI. The PCR fragment was digested with NdeI and BamHI, and the resulting 840-bp BamHI-NdeI fragment was ligated between the same restriction sites of pET-15b to form pPS935, which was then transformed into E. coli BL21(DE3). Expression of H₆-FabI, cell lysis, and purification of the soluble fusion protein on a Ni²⁺-agarose column (Qiagen) were performed as previously described (17) except that the cells were grown in LB medium containing ampicillin (LB-Ap medium). The same procedure was used for purification of a mutant FabI protein.

Enoyl-ACP reductase assays. P. aeruginosa cell extracts were prepared from exponentially growing cells (A₅₄₀ of ~0.8 to 1.0). Cells grown in LB medium at 37°C were harvested by centrifugation and then suspended and washed in 0.1 M sodium phosphate buffer (pH 6.5). Cell lysates were prepared by passing the cell suspensions three times through a French pressure cell (19,000 lb/in²). Cell debris was removed by ultracentrifugation for 1 h at 260,000 × g, and the supernatants were saved as cell extracts.

Determination of acyl HSL concentrations in culture fluid. Acyl HSLs were detected in culture fluids of LB-grown P. aeruginosa strains as previously described (36), using E. coli XL-1 Blue/pECP61.5 for detection of C₄-HSL and E. coli MG4/pKDT17 for detection of 3-oxo-C₁₂-HSL. Standard curves were prepared by using synthetic HSLs to ensure that bioassays were always performed in the linear range.

C₄-HSL assays. The in vitro C₄-HSL synthesis reactions contained (in 500 µl) Moré buffer (10 mM Tris-HCl [pH 7.4], 330 mM NaCl, 15% glycerol, 0.7 mM dithiothreitol, 2 mM EDTA, 25 mM MgSO₄, 0.1 mM FeSO₄) (35), 0.1 mM SAM, 0.2 mM NADH, 1 µg of purified H₆-RhlI (details to be published elsewhere), and various amounts of H₆-FabI. The reaction mixtures were incubated at 37°C for 1 h and then extracted three times with 250 µl of ethyl acetate. The ethyl acetate extracts were vacuum dried, and the residue was suspended in 20 µl of high-pressure liquid chromatography-grade acetonitrile (Fisher Scientific, Fair Lawn, N.J.). For detection of C₄-HSL, the Chromobacterium violaceum bioassay was used (30). Aliquots (5 µl) of the extracted reactions were spotted onto a Whatman (Clifton, N.J.) C₁₈ reverse-phase thin-layer chromatography (TLC) plate and allowed to air dry. The solvent used for chromatography was 60% methanol-40% water (vol/vol). For detection, 2.5 ml of an overnight culture of strain CV026 grown at room temperature in LB medium was diluted into 25 ml of 0.3% LB agar kept at 45°C, and the agar mixture was used to overlay the dried TLC plate. After solidification of the overlay, the TLC plate was incubated overnight at room temperature in a wet box. The presence of C₄-HSL in the extracted reactions was scored by appearance of a violet spot on the TLC plates.

Nucleotide sequence accession number. The DNA sequence of the fabI region has been deposited in GenBank under accession no. AF104262.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Cloning of the fabI gene of P. aeruginosa. At the onset of this project, an examination of the incomplete Pseudomonas genome database release revealed two contigs which contained sequences that in BLAST searches showed extensive similarities to E. coli fabI. The amino and carboxy termini were located on two different contigs. The putative fabI coding sequence was successfully amplified from P. aeruginosa chromosomal DNA by using two oligonucleotide primers, FabIU and FabID (Table 1). These two primers were designed to introduce a unique HindIII site upstream of fabI and its putative ribosome binding site and to introduce a unique BamHI site downstream of fabI. PCR amplification was very specific and yielded a 880-bp product that was digested with BamHI plus HindIII and ligated to similarly digested pWSK30 DNA to form pPS922. This procedure placed fabI under transcriptional control of the lac promoter (P_lac) since the cloned fabI gene presumably lacks its own promoter. The low-copy-number (five to eight copies per cell) cloning vector pWSK30 (47) was used to avoid potential toxicity problems that we had observed during the cloning of other fab genes (25). The fabI(Ts) E. coli strain JP1111 does not grow at 42°C and has a low-salt tolerance at the nonpermissive temperature; e.g., it does not grow on regular LB medium containing 0.5% NaCl. This strain was transformed with pPS922 DNA, and Ap^r transformants were selected at 30°C on LB-Ap medium. The transformants were then transferred to LB-Ap medium with and without 1 mM isopropyl--D-thiogalactopyranoside (IPTG) and incubated at 42°C. Within 24 h, only the colonies plated on LB-Ap medium with IPTG grew under these conditions, indicating that the cloned fabI (i) complemented the temperature-sensitive (Ts) and low-salt-tolerance phenotype of the E. coli fabI(Ts) mutant and (ii) does not contain its own promoter since transcription from P_lac requires IPTG induction in the lac repressor producing strain JP1111. When JP1111 was transformed with pPS967, a multicopy plasmid expressing fabI from P_lac (Table 1), complementation was observed in the absence of IPTG since the amounts of chromosomally encoded lac repressor were insufficient to fully repress fabI transcription.

Sequence analysis of the fabI gene. Since the fabI gene sequence in the incomplete genome database was contained on two separate contigs, we sequenced the cloned 874-bp HindIII-BamHI fragment which contained a single open reading frame (ORF), and BLAST searches revealed significant identity of the protein to other FabI proteins. Alignments showed the greatest similarities with FabI proteins from E. coli and Salmonella typhimurium (69% identity; 81% similarity) and Haemophilus influenzae (63% identity; 76% similarity). This similarity also extended to FabIs from gram-positive bacteria, including Bacillus subtilis (49% identity; 66% similarity).

Disruption of the chromosomal fabI gene. A defined pPS933-borne fabI::Gm^r insertion was constructed as described in Table 1, and the deletion was returned to the P. aeruginosa chromosome as illustrated in Fig. 2A. After conjugal transfer of the nonreplicative pPS933 from E. coli SM10 into PAO1, merodiploids were obtained by selecting for Gm^r. From these, colonies having undergone 1 were selected as sucrose resistant, Gm^r, and carbenicillin resistant. The unmarked fabI::FRT mutant PAO235 was then derived from PAO234 by Flp-catalyzed excision of the Gm^r marker. During its expression in the recipient, Flp recombinase acted at the FRT sites to catalyze excision of the Gm^r element (labeled 2 in Fig. 2A), leaving behind a short FRT-containing sequence.

View larger version (28K): [in this window] [in a new window]   FIG. 2.   (A) Strategy for isolation of an unmarked chromosomal fabI mutation via sacB-counterselected gene replacement (1) and Flp-mediated excision of the Gmr marker (2). (B) Genetic organization of the fabI region in wild-type PAO1 (1.), the fabI::Gmr-FRT insertion mutant (2.), and the unmarked fabI mutant after Flp-mediated excision of the Gmr marker (3. and 4.). (C) PCR analysis of genomic DNA from the strains depicted in panel B. The PCRs were primed with the primers FabIU and FabID (B). Abbreviations: bla, -lactamase-encoding gene; FRT, Flp recombinase target sites; Gm, Gmr marker; ori, pMB1 origin of replication; oriT, origin of transfer; sacB, levansucrase-encoding gene.

fabI mutants contain reduced levels of enoyl-ACP reductase activity. The growth rates of wild-type PAO1 and the fabI mutant PAO235 were superimposable when grown in RB medium and other media (data not shown). Since PAO235 contains only a 86-bp nonpolar insertion at a SmaI site that is located late in the fabI gene, we considered the possibility that this strain could still express a functional FabI protein. To rule out this possibility, we PCR amplified the fabI region from PAO235 by using the primers FabIU and FabID and subcloned the resulting BamHI-HindIII fragment into pWSK30. Under inducing conditions, this DNA segment no longer complemented the Ts and low-salt-tolerance phenotypes of E. coli fabI(Ts) strain JP1111.

View larger version (23K): [in this window] [in a new window]   FIG. 3.   Enoyl-ACP reductase activities in cell extracts of wild-type PAO1 and the fabI mutant PAO235. The 500-µl reactions contained in phosphate buffer with the indicated pH, 0.1 mM NADH or NADPH, and 50 to 100 µg of PAO1 extract or 300 µg of PAO235 extract for determination of NADH- or NADPH-dependent enoyl-ACP reductase activities, respectively. The reactions were initiated by addition of 13 µM crotonyl-ACP, and the decrease in absorbance at 340 nm was recorded. The results shown represent the means plus standard deviations of three experiments.

Purification and properties of purified FabI. An expression vector was constructed, and FabI was purified as an H₆-FabI protein. When transformed into E. coli JP1111, the expression vector could complement the fabI(Ts) mutation of this strain, indicating expression of a functional H₆-FabI protein. The purified FabI protein (Fig. 4A) could utilize crotonyl-CoA and crotonyl-ACP as substrates (Fig. 4B), although it was 5.9-fold more active with crotonyl-ACP as the substrate. The enzyme was unable to utilize NADPH as cofactor (not shown), which may be a consequence of its purification at alkaline pH, conditions that may inactivate its NADPH-dependent activity, as has been observed with the E. coli enzyme (3).

View larger version (42K): [in this window] [in a new window]   FIG. 4.   (A) SDS-PAGE of purified wild-type (WT) FabI and FabI G95V mutant proteins; (B) substrate preference and specific activities of wild-type and mutant FabI proteins. (A) The proteins were expressed as H6-tagged proteins and purified by Ni2+ affinity chromatography. One microgram of each protein was analyzed by SDS-PAGE, and proteins were detected by Coomassie blue staining. The protein standards (Bio-Rad Laboratories) in the rightmost lane were (top to bottom) myosin, -galactosidase, bovine serum albumin, ovalbumin, carbonic anhydrase, trypsin inhibitor, and lysozyme; molecular masses are shown on the right. (B) Enoyl-ACP reductase activities were measured with 20 µM crotonyl-CoA or 13 µM crotonyl-ACP as substrate and 0.1 mM NADH as cofactor. The reaction mixture contained either 1 µg of wild-type FabI or 1 µg of mutant FabI protein. The results shown represent the means plus standard deviations of three experiments.

View larger version (19K): [in this window] [in a new window]   FIG. 5.   Inhibition of FabI activity by triclosan. The reaction mixtures (500 µl) in phosphate buffer (pH 7.5) contained either 1 µg of purified wild-type (WT) FabI or 1 µg of mutant FabI protein, 0.1 mM NADH, 13 µM crotonyl-ACP, and increasing concentrations of triclosan. The insert shows the inhibition curve for the mutant FabI protein over a wider triclosan range; the first four values are identical to the ones plotted in the larger graph. Each value shown represents the mean plus standard deviation of three independent enzymatic reactions.

Role of FabI in HSL synthesis in vitro and in vivo. Reduction of crotonyl-ACP by FabI to form butyryl-ACP is the last step in the first cycle of fatty acid elongation following condensation of malonyl-ACP with acetyl-CoA (Fig. 1). Theoretically, butyryl-ACP generated by FabI could serve as a substrate for transacylation of RhlI, followed by a lactonization reaction utilizing SAM as the substrate to form C₄-HSL, and inhibition of FabI or mutational inactivation should therefore lead to reduced levels of HSL production.

View larger version (23K): [in this window] [in a new window]   FIG. 6.   In vitro synthesis of C4-HSL and inhibition by triclosan. In vitro synthesis reaction mixtures containing the indicated components plus 20 µM crotonyl-ACP, 0.1 mM SAM, and 0.2 mM NADH were extracted with ethyl acetate, and portions of the concentrated residues were separated by TLC. C4-HSL in the samples was detected by overlaying the TLC plate with the C. violaceum indicator strain CV026. Lane a contained 50 pmol of synthetic C4-HSL.

View larger version (19K): [in this window] [in a new window]   FIG. 7.   HSL levels in wild-type and a fabI P. aeruginosa mutant. HSLs were extracted from overnight culture supernatants, and relative levels were determined by using E. coli-based C4-HSL and 3-oxo-C12-HSL bioassays. Values were determined in triplicate, and the values shown represent the means plus standard deviations.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The fabI gene encodes an enoyl-ACP reductase. We have cloned and characterized a gene from P. aeruginosa, encoding an enoyl-ACP reductase, by PCR amplification from genomic DNA and complementation of a defined E. coli fabI(Ts) mutant. Sequence analysis revealed that this gene may be transcriptionally linked to an upstream ORF encoding an ATP-binding protein of an ABC transporter of unknown function, and the presence of strong downstream Rho-independent transcriptional terminator indicated that it is probably the last gene in a transcriptional unit.

FabI is a triclosan target. It has recently been shown that in E. coli triclosan targets lipid synthesis, and since triclosan-resistant mutants harbor mutations in fabI, it was concluded that the most likely target is enoyl-ACP reductase (33); this was subsequently confirmed in assays using purified FabI (19). To examine whether P. aeruginosa FabI is a triclosan target, we used the purified H₆-FabI in triclosan inhibition studies (Fig. 5). The purified protein was efficiently inhibited by very low concentrations of triclosan, showing 50% inhibition (50% inhibitory concentration [IC₅₀]) with 0.2 µM triclosan. McMurry et al. (33) and Heath et al. (18, 19) showed that their most triclosan-resistant mutants contained Gly⁹³-to-Val substitutions. To assess whether changing a glycine residue at the equivalent position 95 in P. aeruginosa FabI would lead to synthesis of a triclosan-resistant FabI enzyme, we introduced a Gly⁹⁵-to-Val change by site-directed mutagenesis and then expressed and purified the mutant H₆-FabI protein. Although the mutant protein exhibited a slightly increased enoyl-ACP reductase activity (Fig. 4B), it showed an IC₅₀ of 7 µM for triclosan and was not yet completely inhibited by the highest concentration (62 µM) tested in our experiments (Fig. 5, insert). While our studies neared completion, Heath et al. (18, 19) arrived at similar results after comparing the purified E. coli FabI with Gly⁹³-to-Ser and Gly⁹³-to-Val mutant enzymes; the triclosan IC₅₀s were 2 µM for FabI, 8 µM for the Gly⁹³-to-Ser mutant enzyme (19), and 10 µM for the Gly⁹³-to-Val mutant enzyme (18). Although both proteins were purified by using the same expression vector and same NH₂-terminal H₆ extension, P. aeruginosa FabI was ~10-fold more sensitive than the E. coli enzyme to triclosan. Although we do not know the reason(s) for this observation, the differences may be partially due to the different enoyl-ACP reductase assays used for the inhibition studies. We used the natural substrate crotonyl-ACP, whereas Heath et al. (18, 19) used the synthetic substrate trans-2-octadecenoyl-N-cysteamine, and the latter assay required substantially more FabI (12 µg, versus 1 µg in our assays). The recent determination of the X-ray structure of the E. coli FabI-NAD⁺-triclosan complex confirmed that triclosan interacts with both the NAD⁺ and the protein via hydrogen and hydrophobic bonds, forming a stable ternary complex (18, 26). Mutations in the FabI active site interfere with the formation of a stable FabI-NAD⁺-triclosan ternary complex and thus confer resistance to the drug.

FabI participates in homoserine lactone synthesis. According to the current model, butyryl-ACP serves as the most likely acyl donor in C₄-HSL synthesis. To confirm that FabI can indeed provide butyryl-ACP for C₄-HSL synthesis by RhlI, we set up an in vitro synthesis system containing purified FabI, RhlI, the cofactor NADH, and the substrates crotonyl-ACP and SAM. This reconstituted system allowed synthesis of biologically active C₄-HSL that comigrated with synthetic C₄-HSL (Fig. 6). Synthesis of C₄-HSL was efficiently inhibited by triclosan. This inhibition was relieved by increasing concentrations of FabI but not RhlI, indicating that FabI and not RhlI is the triclosan target. Corroborating evidence that FabI plays a central role in HSL synthesis in vivo was provided by the observation that a fabI mutant produced only 50% of the HSLs found in wild-type cells. This is the first documented evidence that an enzyme of the fatty acid biosynthetic pathway plays a crucial role in HSL synthesis, and the establishment of an in vitro HSL synthesis system will facilitate the search for novel antimicrobials aimed at interfering with the pathways involved in HSL biosynthesis. The design and development of new FabI inhibitors will form an integral part of such strategies.