Vibrio cholerae FabV defines a new class of enoyl-acyl carrier protein reductase

Enoyl-acyl carrier protein (ACP) reductase catalyzes the last step of the fatty acid elongation cycle. The paradigm enoyl-ACP reductase is the FabI protein of Escherichia coli that is the target of the antibacterial compound, triclosan. However, some Gram-positive bacteria are naturally resistant to triclosan due to the presence of the triclosan-resistant enoyl-ACP reductase isoforms, FabK and FabL. The genome of the Gram-negative bacterium, Vibrio cholerae lacks a gene encoding a homologue of any of the three known enoyl-ACP reductase isozymes suggesting that this organism encodes a novel fourth enoyl-ACP reductase isoform. We report that this is the case. The gene encoding the new isoform, called FabV, was isolated by complementation of a conditionally lethal E. coli fabI mutant strain and was shown to restore fatty acid synthesis to the mutant strain both in vivo and in vitro. Like FabI and FabL, FabV is a member of the short chain dehydrogenase reductase superfamily, although it is considerably larger (402 residues) than either FabI (262 residues) or FabL (250 residues). The FabV, FabI and FabL sequences can be aligned, but only poorly. Alignment requires many gaps and yields only 15% identical residues. Thus, FabV defines a new class of enoyl-ACP reductase. The native FabV protein has been purified to homogeneity and is active with both crotonyl-ACP and the model substrate, crotonyl-CoA. In contrast to FabI and FabL, FabV shows a very strong preference for NADH over NADPH. Expression of FabV in E. coli results in markedly increased resistance to triclosan and the purified enzyme is much more resistant to triclosan than is E. coli FabI.     

Inhibition of the Staphylococcus aureus NADPH-dependent enoyl-acyl carrier protein reductase by triclosan and hexachlorophene

Enoyl-acyl carrier protein reductase (FabI) plays a determinant role in completing cycles of elongation in type II fatty acid synthase systems and is an important target for antibacterial drugs. The FabI component of Staphylococcus aureus (saFabI) was identified, and its properties were compared with Escherichia coli FabI (ecFabI). ecFabI and saFabI had similar specific activities, and saFabI expression complemented the E. coli fabI(Ts) mutant, illustrating that the Gram-positive FabI was interchangeable with the Gram-negative FabI enzyme. However, ecFabI was specific for NADH, whereas saFabI exhibited specific and positive cooperative binding of NADPH. Triclosan and hexachlorophene inhibited both ecFabI and saFabI. The triclosan-resistant ecFabI(G93V) protein was also refractory to hexachlorophene inhibition, illustrating that both drugs bind at the FabI active site. Both the introduction of a plasmid expressing the safabI gene or a missense mutation in the chromosomal safabI gene led to triclosan resistance in S. aureus; however, these strains did not exhibit cross-resistance to hexachlorophene. The replacement of the ether linkage in triclosan by a carbon bridge in hexachlorophene prevented the formation of a stable FabI-NAD(P)(+)-drug ternary complex. Thus, the formation of this ternary complex is a key determinant of the antibacterial activity of FabI inhibitors.     

Mechanism of triclosan inhibition of bacterial fatty acid synthesis

Triclosan is a broad-spectrum antibacterial agent that inhibits bacterial fatty acid synthesis at the enoyl-acyl carrier protein reductase (FabI) step. Resistance to triclosan in Escherichia coli is acquired through a missense mutation in the fabI gene that leads to the expression of FabI[G93V]. The specific activity and substrate affinities of FabI[G93V] are similar to FabI. Two different binding assays establish that triclosan dramatically increases the affinity of FabI for NAD+. In contrast, triclosan does not increase the binding of NAD+ to FabI[G93V]. The x-ray crystal structure of the FabI-NAD+-triclosan complex confirms that hydrogen bonds and hydrophobic interactions between triclosan and both the protein and the NAD+ cofactor contribute to the formation of a stable ternary complex, with the drug binding at the enoyl substrate site. These data show that the formation of a noncovalent "bi-substrate" complex accounts for the effectiveness of triclosan as a FabI inhibitor and illustrates that mutations in the FabI active site that interfere with the formation of a stable FabI-NAD+-triclosan ternary complex acquire resistance to the drug.     

Characterization of a novel enoyl-acyl carrier protein reductase of diazaborine-resistant Rhodobacter sphaeroides mutant

Rhodobacter sphaeroides contains two enoyl-acyl carrier protein (ACP) reductases, FabI(1) and FabI(2). However, FabI(1) displays most of the cellular enzyme activity. The spontaneous diazaborine-resistant mutation was mapped as substitution of glutamine for proline 155 (P155Q) of FabI(1). The mutation of FabI(1)[P155Q] increased the specificity constants (k(cat)/K(m)) for crotonyl-ACP and NADH by more than 2-fold, while the site-directed mutation G95S (FabI(1)[G95S]), corresponding to the well-known G93 mutation of Escherichia coli FabI, rather decreased the values. Inhibition kinetics of the enzymes revealed that triclosan binds to the enzyme in the presence of NAD(+), while the diazaborine appears to interact with NADH and NAD(+) in the enzyme active site. The apparent inhibition constant K(i)(') of triclosan for FabI(1)[P155Q] and FabI(1)[G95S] at saturating NAD(+) were approximately 80- and 3-fold higher than that for the wild-type enzyme, respectively, implying that the inhibition was remarkably impaired by the P155Q mutation. The similar levels of K(i)(') of diazaborine for the mutant enzymes were also observed with respect to NAD(+). Thus, the novel mutation P155Q appears to disturb the binding of inhibitors to the enzyme without affecting the catalytic efficiency.     

4-Pyridone derivatives as new inhibitors of bacterial enoyl-ACP reductase FabI

Bacterial FAS provides essential fatty acids for use in the assembly of key cellular components. Among them, FabI is an enoyl-ACP reductase which catalyzes the final and rate-limiting step of bacterial FAS. It is a potential target for selective antibacterial action, because it shows low overall sequence homology with mammalian enzymes. Until today, various compounds have been reported as inhibitors of bacterial FabI-inhibitory compounds. To discover novel small-molecular FabI inhibitors, we initially screened our compound library for inhibitory activity toward FabI of Escherichia coli. And discovered 4-pyridone derivatives as a lead compound. Structure optimization studies yielded 4-pyridone derivatives 7n having strong FabI-inhibitory and antibacterial activities against Staphylococcus aureus. There have been no reports concerning 4-pyridone derivatives as FabI inhibitor.     

The enoyl-[acyl-carrier-protein] reductases FabI and FabL from Bacillus subtilis

Enoyl-[acyl-carrier-protein] (ACP) reductase is a key enzyme in type II fatty-acid synthases that catalyzes the last step in each elongation cycle. The FabI component of Bacillus subtilis (bsFabI) was identified in the genomic data base by homology to the Escherichia coli protein. bsFabI was cloned and purified and exhibited properties similar to those of E. coli FabI, including a marked preference for NADH over NADPH as a cofactor. Overexpression of the B. subtilis fabI gene complemented the temperature-sensitive growth phenotype of an E. coli fabI mutant. Triclosan was a slow-binding inhibitor of bsFabI and formed a stable bsFabI.NAD(+). triclosan ternary complex. Analysis of the B. subtilis genomic data base revealed a second open reading frame (ygaA) that was predicted to encode a protein with a relatively low overall similarity to FabI, but contained the Tyr-Xaa(6)-Lys enoyl-ACP reductase catalytic architecture. The purified YgaA protein catalyzed the NADPH-dependent reduction of trans-2-enoyl thioesters of both N-acetylcysteamine and ACP. YgaA was reversibly inhibited by triclosan, but did not form the stable ternary complex characteristic of the FabI proteins. Expression of YgaA complemented the fabI(ts) defect in E. coli and conferred complete triclosan resistance. Single knockouts of the ygaA or fabI gene in B. subtilis were viable, but double knockouts were not obtained. The fabI knockout was as sensitive as the wild-type strain to triclosan, whereas the ygaA knockout was 250-fold more sensitive to the drug. YgaA was renamed FabL to denote the discovery of a new family of proteins that carry out the enoyl-ACP reductase step in type II fatty-acid synthases.     

Role of inhibitor aliphatic chain in the thermodynamics of inhibitor binding to Escherichia coli enoyl-ACP reductase and the Phe203Leu mutant: a proposed mechanism for drug resistance

The antibacterial target enoyl-acyl carrier protein (ACP) reductase is a homotetrameric enzyme that catalyzes the last reductive step of fatty acid biosynthesis. In the present paper, four 2-(2-hydroxyphenoxy)phenol inhibitors, wherein the 4-position substituent varied from H to n-propyl, were studied to determine the contribution of the aliphatic chain to the binding to the wild-type (wt) enoyl-ACP reductase from Escherichia coli (FabI) and a drug-resistant mutant, (F203L)FabI, in which phenylalanine 203 is mutated to leucine. Thermodynamic parameters of ternary complex formation (enzyme-NAD(+)-inhibitor) were determined by isothermal titration calorimetry. The inhibitor affinity to wt FabI and (F203L)FabI increases with increasing aliphatic chain length, although the corresponding affinity for (F203L)FabI is lower, and also, it shows no detectable binding to the 4-H inhibitor. A distinguishing feature of inhibitor binding to either binary enzyme-NAD(+) complex is the apparent negative cooperativity for binding to the tetramer with half-site occupancy. For both enzymes, binding is enthalpy, DeltaH, driven. However, binding DeltaH becomes less favorable with increasing aliphatic chain length. Increases in affinity are found to be exclusively due to favorable changes in solvation entropy. Incremental changes in thermodynamic parameters within the series of inhibitors binding to wt FabI and (F203L)FabI are approximately the same. However, absolute differences between the two enzymes for binding to a given inhibitor are significant, suggesting different binding modes. This finding, coupled with a binding site conformation that is likely to be more rigid in the mutant, appears to result in the drug resistance of (F203L)FabI.     

Resistance to AFN-1252 Arises from Missense Mutations in Staphylococcus aureus Enoyl-acyl Carrier Protein Reductase (FabI)

AFN-1252 is a potent antibiotic against Staphylococcus aureus that targets the enoyl-acyl carrier protein reductase (FabI). A thorough screen for AFN-1252-resistant strains was undertaken to identify the spectrum of mechanisms for acquired resistance. A missense mutation in fabI predicted to encode FabI(M99T) was isolated 49 times, and a single isolate was predicted to encode FabI(Y147H). AFN-1252 only bound to the NADPH form of FabI, and the close interactions between the drug and Met-99 and Tyr-147 explained how the mutations would result in resistant enzymes. The clone expressing FabI(Y147H) had a pronounced growth defect that was rescued by exogenous fatty acid supplementation, and the purified protein had less than 5% of the enzymatic activity of FabI. FabI(Y147F) was also catalytically defective but retained its sensitivity to AFN-1252, illustrating the importance of the conserved Tyr-147 hydroxyl group in FabI function. The strains expressing FabI(M99T) exhibited normal growth, and the biochemical properties of the purified protein were indistinguishable from those of FabI. The AFN-1252 K_i^app increased from 4 nm in FabI to 69 nm in FabI(M99T), accounting for the increased resistance of the corresponding mutant strain. The low activity of FabI(Y147H) precluded an accurate K_i measurement. The strain expressing FabI(Y147H) was also resistant to triclosan; however, the strain expressing FabI(M99T) was more susceptible. Strains with higher levels of AFN-1252 resistance were not obtained. The AFN-1252-resistant strains remained sensitive to submicromolar concentrations of AFN-1252, which blocked growth through inhibition of fatty acid biosynthesis at the FabI step.     

Type II Fatty Acid Synthesis Is Essential for the Replication of Chlamydia trachomatis

The major phospholipid classes of the obligate intracellular bacterial parasite Chlamydia trachomatis are the same as its eukaryotic host except that they also contain chlamydia-made branched-chain fatty acids in the 2-position. Genomic analysis predicts that C. trachomatis is capable of type II fatty acid synthesis (FASII). AFN-1252 was deployed as a chemical tool to specifically inhibit the enoyl-acyl carrier protein reductase (FabI) of C. trachomatis to determine whether chlamydial FASII is essential for replication within the host. The C. trachomatis FabI (CtFabI) is a homotetramer and exhibited typical FabI kinetics, and its expression complemented an Escherichia coli fabI(Ts) strain. AFN-1252 inhibited CtFabI by binding to the FabI·NADH complex with an IC₅₀ of 0.9 μm at saturating substrate concentration. The x-ray crystal structure of the CtFabI·NADH·AFN-1252 ternary complex revealed the specific interactions between the drug, protein, and cofactor within the substrate binding site. AFN-1252 treatment of C. trachomatis-infected HeLa cells at any point in the infectious cycle caused a decrease in infectious titers that correlated with a decrease in branched-chain fatty acid biosynthesis. AFN-1252 treatment at the time of infection prevented the first cell division of C. trachomatis, although the cell morphology suggested differentiation into a metabolically active reticulate body. These results demonstrate that FASII activity is essential for C. trachomatis proliferation within its eukaryotic host and validate CtFabI as a therapeutic target against C. trachomatis.     

Kinetic determinants of the interaction of enoyl-ACP reductase from Plasmodium falciparum with its substrates and inhibitors.

We have recently demonstrated that Plasmodium falciparum, unlike its human host, has the type II fatty acid synthase, in which steps of fatty acid biosynthesis are catalyzed by independent enzymes. This difference could be successfully exploited in the design of drugs specifically targeted at the different enzymes of this pathway in P. falciparum, without affecting the corresponding enzymes in humans. The importance of enoyl-ACP reductase (FabI) in the fatty acid biosynthesis pathway makes it an important target in antimalarial therapy. We report here the initial characterization of Plasmodium FabI expressed in Escherichia coli. The K(m) values of the enzyme for crotonyl-CoA and NADH were derived as 165 and 33 microM, respectively. Triclosan shows competitive kinetics with respect to NADH but is uncompetitive with respect to NAD(+), which shows that the binding of triclosan to the enzyme is facilitated in the presence of NAD(+).     

Spiro-naphthyridinone piperidines as inhibitors of S. aureus and E. coli enoyl-ACP reductase (FabI)

Spiropiperidine naphthyridinone inhibitors of Staphylococcus aureus and Escherichia coli FabI have been prepared. Compounds 14a and 14c were identified as having sub-nanomolar E. coli FabI activity and are among the most potent FabI inhibitors yet described. The structural model of 14a bound to E. coli FabI is shown.     

Structure-activity studies of the inhibition of FabI,the enoyl reductase from Escherichia coli,by triclosan: kinetic analysis of mutant FabIs

Triclosan, a common antibacterial additive used in consumer products, is an inhibitor of FabI, the enoyl reductase enzyme from type II bacterial fatty acid biosynthesis. In agreement with previous studies [Ward, W. H., Holdgate, G. A., Rowsell, S., McLean, E. G., Pauptit, R. A., Clayton, E., Nichols, W. W., Colls, J. G., Minshull, C. A., Jude, D. A., Mistry, A., Timms, D., Camble, R., Hales, N. J., Britton, C. J., and Taylor, I. W. (1999) Biochemistry 38, 12514-12525], we report here that triclosan is a slow, reversible, tight binding inhibitor of the FabI from Escherichia coli. Triclosan binds preferentially to the E.NAD(+) form of the wild-type enzyme with a K(1) value of 23 pM. In agreement with genetic selection experiments [McMurry, L. M., Oethinger, M., and Levy, S. B. (1998) Nature 394, 531-532], the affinity of triclosan for the FabI mutants G93V, M159T, and F203L is substantially reduced, binding preferentially to the E.NAD(+) forms of G93V, M159T, and F203L with K(1) values of 0.2 microM, 4 nM, and 0.9 nM, respectively. Triclosan binding to the E.NADH form of F203L can also be detected and is defined by a K(2) value of 51 nM. We have also characterized the Y156F and A197M mutants to compare and contrast the binding of triclosan to InhA, the homologous enoyl reductase from Mycobacterium tuberculosis. As observed for InhA, Y156F FabI has a decreased affinity for triclosan and the inhibitor binds to both E.NAD(+) and E.NADH forms of the enzyme with K(1) and K(2) values of 3 and 30 nM, respectively. The replacement of A197 with Met has no impact on triclosan affinity, indicating that differences in the sequence of the conserved active site loop cannot explain the 10000-fold difference in affinities of FabI and InhA for triclosan.     

Structure of acyl carrier protein bound to FabI, the FASII enoyl reductase from Escherichia coli

Acyl carrier proteins play a central role in metabolism by transporting substrates in a wide variety of pathways including the biosynthesis of fatty acids and polyketides. However, despite their importance, there is a paucity of direct structural information concerning the interaction of ACPs with enzymes in these pathways. Here we report the structure of an acyl-ACP substrate bound to the Escherichia coli fatty acid biosynthesis enoyl reductase enzyme (FabI), based on a combination of x-ray crystallography and molecular dynamics simulation. The structural data are in agreement with kinetic studies on wild-type and mutant FabIs, and reveal that the complex is primarily stabilized by interactions between acidic residues in the ACP helix alpha2 and a patch of basic residues adjacent to the FabI substrate-binding loop. Unexpectedly, the acyl-pantetheine thioester carbonyl is not hydrogen-bonded to Tyr(156), a conserved component of the short chain alcohol dehydrogenase/reductase superfamily active site triad. FabI is a proven target for drug discovery and the present structure provides insight into the molecular determinants that regulate the interaction of ACPs with target proteins.     

Candida tropicalis Etr1p and Saccharomyces cerevisiae Ybr026p (Mrf1'p), 2-enoyl thioester reductases essential for mitochondrial respiratory competence

We report here on the identification and characterization of novel 2-enoyl thioester reductases of fatty acid metabolism, Etr1p from Candida tropicalis and its homolog Ybr026p (Mrf1'p) from Saccharomyces cerevisiae. Overexpression of these proteins in S. cerevisiae led to the development of significantly enlarged mitochondria, whereas deletion of the S. cerevisiae YBR026c gene resulted in rudimentary mitochondria with decreased contents of cytochromes and a respiration-deficient phenotype. Immunolocalization and in vivo targeting experiments showed these proteins to be predominantly mitochondrial. Mitochondrial targeting was essential for complementation of the mutant phenotype, since targeting of the reductases to other subcellular locations failed to reestablish respiratory growth. The mutant phenotype was also complemented by a mitochondrially targeted FabI protein from Escherichia coli. FabI represents a nonhomologous 2-enoyl-acyl carrier protein reductase that participates in the last step of the type II fatty acid synthesis. This indicated that 2-enoyl thioester reductase activity was critical for the mitochondrial function. We conclude that Etr1p and Ybr026p are novel 2-enoyl thioester reductases required for respiration and the maintenance of the mitochondrial compartment, putatively acting in mitochondrial synthesis of fatty acids.     

Meleagrin,a New FabI Inhibitor from Penicillium chryosogenum with at Least One Additional Mode of Action

Bacterial enoyl-acyl carrier protein reductase (FabI) is a promising novel antibacterial target. We isolated a new class of FabI inhibitor from Penicillium chrysogenum, which produces various antibiotics, the mechanisms of some of them are unknown. The isolated FabI inhibitor was determined to be meleagrin by mass spectroscopy and nuclear magnetic resonance spectral analyses, and its more active and inactive derivatives were chemically prepared. Consistent with their selective inhibition of Staphylococcus aureus FabI, meleagrin and its more active derivatives directly bound to S. aureus FabI in a fluorescence quenching assay, inhibited intracellular fatty acid biosynthesis and growth of S. aureus, and increased the minimum inhibitory concentration for fabI-overexpressing S. aureus. The compounds that were not effective against the FabK isoform, however, inhibited the growth of Streptococcus pneumoniae that contained only the FabK isoform. Additionally no resistant mutant to the compounds was obtained. Importantly, fabK-overexpressing Escherichia coli was not resistant to these compounds, but was resistant to triclosan. These results demonstrate that the compounds inhibited another target in addition to FabI. Thus, meleagrin is a new class of FabI inhibitor with at least one additional mode of action that could have potential for treating multidrug-resistant bacteria.     

A novel series of enoyl reductase inhibitors targeting the ESKAPE pathogens, Staphylococcus aureus and Acinetobacter baumannii

S. aureus and A. baumannii are among the ESKAPE pathogens that are increasingly difficult to treat due to the rise in the number of drug resistant strains. Novel therapeutics targeting these pathogens are much needed. The bacterial enoyl reductase (FabI) is as potentially significant drug target for developing pathogen-specific antibiotics due to the presence of alternate FabI isoforms in many other bacterial species. We report the identification and development of a novel N-carboxy pyrrolidine scaffold targeting FabI in S. aureus and A. baumannii, two pathogens for which FabI essentiality has been established. This scaffold is unrelated to other known antibiotic families, and FabI is not targeted by any currently approved antibiotic. Our data shows that this scaffold displays promising enzyme inhibitory activity against FabI from both S. aureus and A. baumannii, as well as encouraging antibacterial activity in S. aureus. Compounds also display excellent synergy when combined with colistin and tested against A. baumannii. In this combination the MIC of colistin is reduced by 10-fold. Our first generation compound displays promising enzyme inhibition, targets FabI in S. aureus with a favorable selectivity index (ratio of cytotoxicity to MIC), and has excellent synergy with colistin against A. baumannii, including a multidrug resistant strain.     

Overexpression of marA, soxS, or acrAB produces resistance to triclosan in laboratory and clinical strains of Escherichia coli

Triclosan (Irgasan) is a broad spectrum antimicrobial agent used in handsoaps, toothpastes, fabrics, and plastics. It inhibits lipid biosynthesis in Escherichia coli , probably by action upon enoyl reductase (FabI) (McMurry L.M., Oethinger M. and Levy S.B. (1988) Nature 394, 531–532). We report here that overexpression of the multidrug efflux pump locus acrAB , or of marA or soxS , both encoding positive regulators of acrAB , decreased susceptibility to triclosan 2-fold. Deletion of the acrAB locus increased the susceptibility to triclosan approximately 10-fold. Four of five clinical E. coli strains which overexpressed marA or soxS also showed enhanced triclosan resistance. The acrAB locus was involved in the effects of triclosan upon both cell growth rate and cell lysis.     

Novel enoyl-ACP reductase (FabI) potential inhibitors of Escherichia coli from Chinese medicine monomers

By structure-based virtual screening and experimental verification, two Chinese medicine monomers, luteolin and curcumin, had been proved to be uncompetitive inhibitors of enoyl-ACP reductase from Escherichia coli (EcFabI) with the inhibition constant (K_i) of 7.1 μM and 15.0 μM, respectively. In particular, curcumin had apparent antibacterial activity against E. coli, and the minimum inhibition concentration (MIC₉₀) was 73.7 μg/mL. Importantly, fabI-overexpressing E. coli showed reduced susceptibility to the inhibitor compared with the wild-type strains, demonstrating that its antibacterial action is mediated by the inhibition of EcFabI.     

Enrichment of Escherichia coli proteins by column chromatography on reactive dye columns

The reliable identification and analysis of the low abundance proteins expressed by a cell remains a key challenge in the study of cellular proteomes. The analysis of low abundance proteins is a particular problem when using two-dimensional gel electrophoresis (2-DE) to resolve the cellular proteins since the technology is unable to display the wide dynamic range of protein levels typically synthesized by cells. We have investigated the use of reactive dye compounds for the enrichment of low abundance cellular proteins prior to analysis by 2-DE. The capacity of reactive dye compounds to bind specific protein species was used as the basis for a general chromatographic tool for protein enrichment. Six reactive dye compounds were investigated in detail for the analysis of Escherichia coli proteins. Whole bacterial cell lysates were passed down columns prepared with the reactive dye compounds. The bound proteins were eluted with 1.5 M NaCl and analyzed by 2-DE. Distinctive protein profiles were observed for the bound proteins recovered from the different reactive dye compounds. Selected proteins enriched by these methods were identified by peptide mass mapping. The enrichment procedure developed using reactive dye compounds were used to investigate acid-induced changes in the proteome of E. coli grown at either pH 7.0 or pH 5.8. Increased levels of expression were observed for a number of proteins (for example, GdhA, PanC, ProC, TkrA, EF-TS and YodA) were observed for E. coli grown at pH 5.8. Five identified proteins (AroG, FabI, GlyA, PurA and EF-Tu) showed reduced levels of synthesis for bacteria grown at pH 5.8 compared to pH 7.0. In the case of PanC and FabI the altered expression profiles were only reliably demonstrated using the enrichment protocols. One theme emerging from these data was that the expression of proteins concerned with one-carbon metabolism was perturbed at pH 5.8, which may point to a previously unrecognized affect of low pH stress on the physiology of E. coli cells. We conclude that the prefractionation of cell lysates on reactive dye columns will serve as a valuable generic tool for the analysis of low abundance proteins expressed by both prokaryotic and eukaryotic cells.