Acyl carrier protein synthases from gram-negative, gram-positive, and atypical bacterial species: Biochemical and structural properties and physiological implications

Acyl carrier protein (ACP) synthase (AcpS) catalyzes the transfer of the 4'-phosphopantetheine moiety from coenzyme A (CoA) onto a serine residue of apo-ACP, resulting in the conversion of apo-ACP to the functional holo-ACP. The holo form of bacterial ACP plays an essential role in mediating the transfer of acyl fatty acid intermediates during the biosynthesis of fatty acids and phospholipids. AcpS is therefore an attractive target for therapeutic intervention. In this study, we have purified and characterized the AcpS enzymes from Escherichia coli, Streptococcus pneumoniae, and Mycoplasma pneumoniae, which exemplify gram-negative, gram-positive, and atypical bacteria, respectively. Our gel filtration column chromatography and cross-linking studies demonstrate that the AcpS enzyme from M. pneumoniae, like E. coli enzyme, exhibits a homodimeric structure, but the enzyme from S. pneumoniae exhibits a trimeric structure. Our biochemical studies show that the AcpS enzymes from M. pneumoniae and S. pneumoniae can utilize both short- and long-chain acyl CoA derivatives but prefer long-chain CoA derivatives as substrates. On the other hand, the AcpS enzyme from E. coli can utilize short-chain CoA derivatives but not the long-chain CoA derivatives tested. Finally, our biochemical studies show that M. pneumoniae AcpS is kinetically a very sluggish enzyme compared with those from E. coli and S. pneumoniae. Together, the results of these studies show that the AcpS enzymes from different bacterial species exhibit different native structures and substrate specificities with regard to the utilization of CoA and its derivatives. These findings suggest that AcpS from different microorganisms plays a different role in cellular physiology.     

Holo-(acyl carrier protein) synthase and phosphopantetheinyl transfer in Escherichia coli

Holo-(acyl carrier protein) synthase (AcpS) post-translationally modifies apoacyl carrier protein (apoACP) via transfer of 4'-phosphopantetheine from coenzyme A (CoA) to the conserved serine 36 gamma-OH of apoACP. The resulting holo-acyl carrier protein (holo-ACP) is then active as the central coenzyme of fatty acid biosynthesis. The acpS gene has previously been identified and shown to be essential for Escherichia coli growth. Earlier mutagenic studies isolated the E. coli MP4 strain, whose elevated growth requirement for CoA was ascribed to a deficiency in holoACP synthesis. Sequencing of the acpS gene from the E. coli MP4 strain (denoted acpS1) showed that the AcpS1 protein contains a G4D mutation. AcpS1 exhibited a approximately 5-fold reduction in its catalytic efficiency when compared with wild type AcpS, accounting for the E. coli MP4 strain phenotype. It is shown that a conditional acpS mutant accumulates apoACP in vivo under nonpermissive conditions in a manner similar to the E. coli MP4 strain. In addition, it is demonstrated that the gene product, YhhU, of a previously identified E. coli open reading frame can completely suppress the acpS conditional, lethal phenotype upon overexpression of the protein, suggesting that YhhU may be involved in an alternative pathway for phosphopantetheinyl transfer and holoACP synthesis in E. coli.     

The apparent coupling between synthesis and posttranslational modification of Escherichia coli acyl carrier protein is due to inhibition of amino acid biosynthesis.

Acyl carrier protein (ACP) is modified on serine 36 by the covalent posttranslational attachment of 4'-phosphopantetheine from coenzyme A (CoA), and this modification is required for lipid biosynthesis. Jackowski and Rock (J. Biol. Chem 258:15186-15191, 1983) reported that upon depletion of the CoA pool by starvation for a CoA precursor, no accumulation of the unmodified form of ACP (apo-ACP) was detected. We report that this lack of apo-ACP accumulation results from decreased translation of the acpP mRNAs because of the limitation of the synthesis of glutamate and other amino acids made directly from tricarboxylic acid cycle intermediates.     

A genome rearrangement has orphaned the Escherichia coli K-12 AcpT phosphopantetheinyl transferase from its cognate Escherichia coli O157:H7 substrates

Phosphopantetheinyl transferases (PPTases) are enzymes that catalyse the transfer of a 4'-phosphopantetheine moiety from CoA to a conserved serine residue of a carrier protein. These carrier proteins use the 4'-phosphopantetheine thiol to shuttle intermediates between the active sites of biosynthetic enzymes involved in fatty acid, non-ribosomal peptide and polyketide synthesis. Three PPTases have been previously been identified in Escherichia coli K-12 and other E. coli strains by homology searches and are encoded by the genes acpS, entD and acpT. Both AcpS and EntD have been well studied whereas the function of AcpT has been an enigma because no carrier protein substrate could be found. We report genetic and biochemical evidence that AcpT modifies two carrier proteins encoded in O-island 138, a cluster of fatty acid biosynthesis-like genes located adjacent to acpT in the genome of the pathogenic E. coli strain O157:H7 (E. coli K-12 and several other sequenced E. coli and Shigella strains lack O-island 138). The two carrier proteins of O-island 138 of strain O157:H7 are not modified (or only very poorly modified) by AcpS, the PPTase responsible for 4'-phosphopantetheine attachment to the acyl carrier protein (AcpP) of fatty acid synthesis. We demonstrate that AcpT cannot functionally replace AcpS in E. coli K-12 either in its native chromosomal location or upon insertion of acpT into the acpS chromosomal location. However, in the absence of AcpS activity AcpT does allow very slow growth thus providing a rationale for its retention in the absence of its cognate substrates. These results together with phylogenetic analyses and comparisons of the E. coli and Shigella strains of known genome sequence strongly argue that AcpT has been orphaned from its cognate substrates by a deletion event that occurred in a common ancestor of these organisms. This seems one of the few cases where a chromosomal rearrangement has been functionally demonstrated to be a deletion event rather than an insertion event in the reference organism. We also show that the previously reported suppression of an acpS mutation by the deletion of Lon protease is an artifact of the increased capsular polysaccharide production of lon strains.     

Crystal structures of substrate binding to Bacillus subtilis holo-(acyl carrier protein) synthase reveal a novel trimeric arrangement of molecules resulting in three active sites

BACKGROUND: Holo-(acyl carrier protein) synthase (AcpS), a member of the phosphopantetheinyl transferase superfamily, plays a crucial role in the functional activation of acyl carrier protein (ACP) in the fatty acid biosynthesis pathway. AcpS catalyzes the attachment of the 4'-phosphopantetheinyl moiety of coenzyme A (CoA) to the sidechain of a conserved serine residue on apo-ACP. RESULTS: We describe here the first crystal structure of a type II ACP from Bacillus subtilis in complex with its activator AcpS at 2.3 A. We also have determined the structures of AcpS alone (at 1.8 A) and AcpS in complex with CoA (at 1.5 A). These structures reveal that AcpS exists as a trimer. A catalytic center is located at each of the solvent-exposed interfaces between AcpS molecules. Site-directed mutagenesis studies confirm the importance of trimer formation in AcpS activity. CONCLUSIONS: The active site in AcpS is only formed when two AcpS molecules dimerize. The addition of a third molecule allows for the formation of two additional active sites and also permits a large hydrophobic surface from each molecule of AcpS to be buried in the trimer. The mutations Ile5-->Arg, Gln113-->Glu and Gln113-->Arg show that AcpS is inactive when unable to form a trimer. The co-crystal structures of AcpS-CoA and AcpS-ACP allow us to propose a catalytic mechanism for this class of 4'-phosphopantetheinyl transferases.     

Crystal structure of Streptococcus pneumoniae acyl carrier protein synthase: an essential enzyme in bacterial fatty acid biosynthesis

Acyl carrier protein synthase (AcpS) catalyzes the formation of holo-ACP, which mediates the essential transfer of acyl fatty acid intermediates during the biosynthesis of fatty acids and lipids in the cell. Thus, AcpS plays an important role in bacterial fatty acid and lipid biosynthesis, making it an attractive target for therapeutic intervention. We have determined, for the first time, the crystal structure of the Streptococcus pneumoniae AcpS and AcpS complexed with 3'5'-ADP, a product of AcpS, at 2.0 and 1.9 A resolution, respectively. The crystal structure reveals an alpha/beta fold and shows that AcpS assembles as a tightly packed functional trimer, with a non-crystallographic pseudo-symmetric 3-fold axis, which contains three active sites at the interface between protomers. Only two active sites are occupied by the ligand molecules. Although there is virtually no sequence similarity between the S.pneumoniae AcpS and the Bacillus subtilis Sfp transferase, a striking structural similarity between both enzymes was observed. These data provide a starting point for structure-based drug design efforts towards the identification of AcpS inhibitors with potent antibacterial activity.     

大肠杆菌holo-ACP的过表达、分离纯化及长链脂酰ACP的合成

[目的]获得高纯度大肠杆菌holo-ACP和多种长链脂酰ACP,为研究细菌脂肪酸、类脂A和N-酯酰高丝氨酸内脂等物质的合成提供底物.[方法和结果]采用PCR方法扩增得到大肠杆菌酰基载体蛋白基因(acpP)和holo-ACP合成酶基因(acpS).使用载体pBAD24、pBAD34和pET28b分别克隆了acpP和acpS,得到pBAD-ACP、pET-ACP和pET-ACP-ACPS 3个ACP表达质粒和一个AcpS表达质粒pBAD-ACPS.分别用3个ACP表达质粒转化大肠杆菌DH5a和BL21(DE3),构建了DH5αpBAD-ACP、BL21(DE3)/pET-ACP和BL21(DE3)/pET-ACP-ACPS 3种ACP生产菌株.与holo-ACP纯化常用菌株DK574相比,虽然三菌株在诱导时均能过量表达ACP,但是holo-ACP所占比例偏低.为了提高ACP生产菌株holo-ACP的产量,用质粒pBAD-ACPS分别转化上述3种ACP生产菌株,获得了3种携带双质粒的ACP生产菌株.表达结果显示携带pBAD-ACP和pBAD-ACPS双质粒的DH5a菌株比DK574菌株能产生更多的holo-ACP,且纯度也得到提高(纯度达99%).同时使用UNOsphere Q阴离子交换层析从这一菌株培养物中分离纯化到了高纯度的holo-ACP,并以纯化到的holo-ACP和多种长链脂肪酸为底物在哈氏弧菌脂酰ACP合成酶的催化下,合成了多种长链脂酰ACP.[结论]通过研究获得一株holo-ACP高产菌株,并证明在大肠杆菌菌株中,同时表达acpP基因和acpS基因,有利于holo-ACP的产生.     

Mutational analysis of peptidyl carrier protein and acyl carrier protein synthase unveils residues involved in protein-protein recognition

4'-Phosphopantetheinyl transferases (PPTases) are essential for the production of fatty acids by fatty acid synthases (primary metabolism) and natural products by nonribosomal peptide synthetases and polyketide synthases (secondary metabolism). These systems contain carrier proteins (CPs) for the covalent binding of reaction intermediates during synthesis. PPTases transfer the 4'-phosphopantetheine moiety from coenzyme A (CoA) onto conserved serine residues of the apo-CPs to convert them to their functionally active holo form. In bacteria, two types of PPTases exist that are evolutionary related but differ in their substrate spectrum. Acyl carrier protein synthases (AcpSs) recognize CPs from primary metabolism, whereas Sfp- (surfactin production-) type PPTases have a preference for CPs of secondary metabolism. Previous investigations showed that a peptidyl carrier protein (PCP) of secondary metabolism can be altered to serve as substrate for AcpS. We demonstrate here that a single mutation in PCP suffices for the modification of this CP by AcpS, and we have identified by mutational analysis several other PCP residues and two AcpS residues involved in substrate discrimination by this PPTase. These altered PCPs were still capable of serving their designated function in NRPS modules, and selective use of AcpS or Sfp leads to production of two different products by a trimodular NRPS.     

Solution structure of B. subtilis acyl carrier protein

BACKGROUND: Acyl carrier protein (ACP) is a fundamental component of fatty acid biosynthesis in which the fatty acid chain is elongated by the fatty acid synthetase system while attached to the 4'-phosphopantetheine prosthetic group (4'-PP) of ACP. Activation of ACP is mediated by holo-acyl carrier protein synthase (ACPS) when ACPS transfers the 4'-PP moiety from coenzyme A (CoA) to Ser36 of apo-ACP. Both ACP and ACPS have been identified as essential for E. coli viability and potential targets for development of antibiotics. RESULTS: The solution structure of B. subtilis ACP (9 kDa) has been determined using two-dimensional and three-dimensional heteronuclear NMR spectroscopy. A total of 22 structures were calculated by means of hybrid distance geometry-simulated annealing using a total of 1,050 experimental NMR restraints. The atomic rmsd about the mean coordinate positions for the 22 structures is 0.45 +/- 0.08 A for the backbone atoms and 0.93 +/- 0.07 A for all atoms. The overall ACP structure consists of a four alpha-helical bundle in which 4'-PP is attached to the conserved Ser36 that is located in alpha helix II. CONCLUSIONS: Structural data were collected for both the apo and holo forms of ACP that suggest that the two forms of ACP are essentially identical. Comparison of the published structures for E. coli ACP and actinorhodin polyketide synthase acyl carrier protein (act apo-ACP) from Streptomyces coelicolor A3(2) with B. subtilis ACP indicates similar secondary structure elements but an extremely large rmsd between the three ACP structures (>4.3 A). The structural difference between B. subtilis ACP and both E. coli and act apo-ACP is not attributed to an inherent difference in the proteins, but is probably a result of a limitation in the methodology available for the analysis for E. coli and act apo-ACP. Comparison of the structure of free ACP with the bound form of ACP in the ACP-ACPS complex reveals a displacement of helix II in the vicinity of Ser36. The induced perturbation of ACP by ACPS positions Ser36 proximal to coenzyme A and aligns the dipole of helix II to initiate transfer of 4'-PP to ACP.     

Structure-based mutational analysis of the 4'-phosphopantetheinyl transferases Sfp from Bacillus subtilis: carrier protein recognition and reaction mechanism

The activation of apo-peptidyl carrier proteins (PCPs) of nonribosomal peptide synthetases (NRPSs), apo-acyl carrier proteins (ACPs) of polyketide synthases (PKSs), and fatty acid synthases (FASs) to their active holo form is accomplished with dedicated 4'-phosphopantetheinyl transferases (PPTases). They catalyze the transfer of the essential prosthetic group 4'-phosphopantetheine (4'-Ppant) from coenzyme A (CoA) to a highly conserved serine residue in all PCPs and ACPs. PPTases, based on sequence and substrate specifity, have been classified into three types: bacterial holo-acyl carrier protein synthase (AcpS), fatty acid synthase of eukaryotes (FAS2) and Sfp, a PPTase of secondary metabolism. The recently solved crystal structures of AcpS and Sfp-type PPTases with CoA revealed a common alpha + beta-fold with a beta(1)alpha(3)beta(2) motif and similarities in CoA binding and polymerization mode. However, it was not possible to discern neither the PCP binding region of Sfp nor the priming reaction mechanism from the Sfp-CoA cocrystal. In this work, we provide a model for the reaction mechanism based on mutational analysis of Sfp that suggests a reaction mechanism in which the highly conserved E151 deprotonates the hydroxyl group of the invariant serine of PCP. That, in turn, acts as a nucleophile to attack the beta-phosphate of CoA. The Sfp mutants K112, E117, and K120 further revealed that the loop region between beta4 and alpha5 (residues T111-S124) in Sfp is the PCP binding region. Also, residues T44, K75, S89, H90, D107, E109, E151, and K155 that have been shown in the Sfp-CoA cocrystal structure to coordinate CoA are now all confirmed by mutational and biochemical analysis.     

Analysis of Streptomyces coelicolor phosphopantetheinyl transferase, AcpS, reveals the basis for relaxed substrate specificity

The transfer of the phosphopantetheine chain from coenzyme A (CoA) to the acyl carrier protein (ACP), a key protein in both fatty acid and polyketide synthesis, is catalyzed by ACP synthase (AcpS). Streptomyces coelicolor AcpS is a doubly promiscuous enzyme capable of activation of ACPs from both fatty acid and polyketide synthesis and catalyzes the transfer of modified CoA substrates. Five crystal structures have been determined, including those of ligand-free AcpS, complexes with CoA and acetyl-CoA, and two of the active site mutants, His110Ala and Asp111Ala. All five structures are trimeric and provide further insight into the mechanism of catalysis, revealing the first detailed structure of a group I active site with the essential magnesium in place. Modeling of ACP binding supported by mutational analysis suggests an explanation for the promiscuity in terms of both ACP partner and modified CoA substrates.     

Fatty acid synthetase. A steady state kinetic analysis of the reaction catalyzed by the enzyme from pigeon liver.

The kinetic mechanism of pigeon liver fatty acid synthetase action has been studied using steady state kinetic analysis. Initial velocity studies are consistent with an earlier suggestion that the enzyme catalyzes this reaction by a seven-site ping-pong mechanism. Although the range of substrate concentrations that could be used was limited by several factors, the initial velocity patterns showing the relationship between the substrates acetyl coenzyme CoA, malonyl-CoA, and NADPH appear to be a series of parallel lines, regardless of which substrate is varied at fixed levels of a second substrate. However, two of the substrates, acetyl-CoA and malonly-CoA, apparently exhibit a competitive substrate inhibition with respect to each other, but NADPH shows no inhibition of any kind. Product inhibition patterns suggest that free CoA is competitive versus acetyl-CoA and malonyl-CoA and is uncompetitive versus NADPH, and that NADP+ is competitive versus NADPH and uncompetitive versus acetyl-CoA or malonyl-CoA. These results are consistent with a seven-site ping-pong mechanism with intermediates covalently bound to 4'-phosphopantetheine (part of acyl carrier protein). Double competitive substrate inhibition by acetyl-CoA and malonyl-CoA is consistent with the rate equation derived for the over-all mechanism. The kinetic mechanism developed from these results is capable of explaining the formation of fatty acids from malonyl-CoA and NADPH alone (Katiyar, S. S., Briedis, A. V., and Porter, J. W. (1974) Arch. Biochem. Biophys. 162, 412-420) and also the formation of triacetic acid lactone from either malonyl-CoA alone or acetyl-CoA plus malonyl-CoA.     

A high yield optimized method for the production of acylated ACPs enabling the analysis of enzymes involved in P. falciparum fatty acid biosynthesis

The natural substrates of the enzymes involved in type-II fatty acid biosynthesis (FAS-II) are acylated acyl carrier proteins (acyl-ACPs). The state of the art method to produce acyl-ACPs involves the transfer of a phosphopantetheine moiety from CoA to apo-ACP by E. coli holo-ACP synthase (EcACPS), yielding holo-ACP which subsequently becomes thioesterified with free fatty acids by the E. coli acyl-ACP synthase (EcAAS). Alternatively, acyl-ACPs can be synthesized by direct transfer of acylated phosphopantetheine moieties from acyl-CoA to apo-ACP by means of EcACPS. The need for native substrates to characterize the FAS-II enzymes of P. falciparum prompted us to investigate the potential and limit of the two methods to efficiently acylate P. falciparum ACP (PfACP) with respect to chain length and β-modification and in preparative amounts. The EcAAS activity is found to be independent from the oxidation state at the β-position and accepts fatty acids as substrates with chain lengths starting from C8 to C20, whereas EcACPS accepts very efficiently acyl-CoAs with chain lengths up to C16, and with decreasing activity also longer chains (C18 to C20). Methods were developed to synthesize and purify preparative amounts of high quality natural substrates that are fully functional for the enzymes of the P. falciparum FAS-II system.     

The role of 4'-phosphopantetheine in t' biosynthesis of fatty acids, polyketides and peptides

The peptide part of CoA, 4'-phosphopantetheine, has been identified as an essential cofactor in in the biosynthesis of fatty acids, polyketides, depsipeptides, peptides, and compounds derived from both carboxylic and amino acid precursors, like rapamycin. The cofactor is attached to a unique protein moiety, referred to as acyl carrier protein, aminoacyl carrier protein, or peptidyl carrier protein. These carrier proteins are either associated to enzyme complexes (type II) or integrated within multifunctional polypeptide chains (type I). The cofactor is added in a post-translational modification reaction by highly specific transferases, acting on CoA. The functions of carrier proteins in directed condensation reactions are: (1) the selection of substrates to be attached as thioesters, (2) the stabilization of intermediates, (3) the presentation of intermediates for modification by associated enzyme activities, (4) facilitation of the directed condensation reactions of two adjacent intermediates, and (5) assistance in the termination reaction(s) leading to product release.     

4'-phosphopantetheine transfer in primary and secondary metabolism of Bacillus subtilis

4'-Phosphopantetheine transferases (PPTases) transfer the 4'-phosphopantetheine moiety of coenzyme A onto a conserved serine residue of acyl carrier proteins (ACPs) of fatty acid and polyketide synthases as well as peptidyl carrier proteins (PCPs) of nonribosomal peptide synthetases. This posttranslational modification converts ACPs and PCPs from their inactive apo into the active holo form. We have investigated the 4'-phosphopantetheinylation reaction in Bacillus subtilis, an organism containing in total 43 ACPs and PCPs but only two PPTases, the acyl carrier protein synthase AcpS of primary metabolism and Sfp, a PPTase of secondary metabolism associated with the nonribosomal peptide synthetase for the peptide antibiotic surfactin. We identified and cloned ydcB encoding AcpS from B. subtilis, which complemented an Escherichia coli acps disruption mutant. B. subtilis AcpS and its substrate ACP were biochemically characterized. AcpS also modified the d-alanyl carrier protein but failed to recognize PCP and an acyl carrier protein of secondary metabolism discovered in this study, designated AcpK, that was not identified by the Bacillus genome project. On the other hand, Sfp was able to modify in vitro all acyl carrier proteins tested. We thereby extend the reported broad specificity of this enzyme to the homologous ACP. This in vitro cross-interaction between primary and secondary metabolism was confirmed under physiological in vivo conditions by the construction of a ydcB deletion in a B. subtilis sfp(+) strain. The genes coding for Sfp and its homolog Gsp from Bacillus brevis could also complement the E. coli acps disruption. These results call into question the essential role of AcpS in strains that contain a Sfp-like PPTase and consequently the suitability of AcpS as a microbial target in such strains.     

Posttranslational Maturation of the Invasion Acyl Carrier Protein of Salmonella enterica Serovar Typhimurium Requires an Essential Phosphopantetheinyl Transferase of the Fatty Acid Biosynthesis Pathway

Salmonella pathogenicity island 1 (SPI-1) carries genes required for the formation of a type 3 secretion system, which is necessary for the invasion process of Salmonella. Among the proteins encoded by SPI-1 is IacP, a homolog of acyl carrier proteins. Acyl carrier proteins are mainly involved in fatty acid biosynthesis, and they require posttranslational maturation by addition of a 4′-phosphopantetheine prosthetic group to be functional. In this study, we analyzed IacP maturation in vivo. By performing matrix-assisted laser desorption ionization–time-of-flight (MALDI-TOF) mass spectrometry analysis of intact purified proteins, we showed that IacP from Salmonella enterica serovar Typhimurium was matured by addition of 4′-phosphopantetheine to the conserved serine 38 residue. Therefore, we searched for the phosphopantetheinyl transferases in charge of IacP maturation. A bacterial two-hybrid approach revealed that IacP interacted with AcpS, an enzyme normally required for the maturation of the canonical acyl carrier protein (ACP), which is involved in fatty acid biosynthesis. The creation of a conditional acpS mutant then demonstrated that AcpS was necessary for the maturation of IacP. However, although IacP was similar to ACP and matured by using the same enzyme, IacP could not replace the essential function of ACP in fatty acid synthesis. Hence, the demonstration that IacP is matured by AcpS establishes a cross-connection between virulence and fatty acid biosynthesis pathways.     

Regulation of coenzyme A biosynthesis.

Coenzyme A (CoA) and acyl carrier protein are two cofactors in fatty acid metabolism, and both possess a 4'-phosphopantetheine moiety that is metabolically derived from the vitamin pantothenate. We studied the regulation of the metabolic pathway that gives rise to these two cofactors in an Escherichia coli beta-alanine auxotroph, strain SJ16. Identification and quantitation of the intracellular and extracellular beta-alanine-derived metabolites from cells grown on increasing beta-alanine concentrations were performed. The intracellular content of acyl carrier protein was relatively insensitive to beta-alanine input, whereas the CoA content increased as a function of external beta-alanine concentration, reaching a maximum at 8 microM beta-alanine. Further increase in the beta-alanine concentration led to the excretion of pantothenate into the medium. Comparing the amount of pantothenate found outside the cell to the level of intracellular metabolites demonstrates that E. coli is capable of producing 15-fold more pantoic acid than is required to maintain the intracellular CoA content. Therefore, the supply of pantoic acid is not a limiting factor in CoA biosynthesis. Wild-type cells also excreted pantothenate into the medium, showing that the beta-alanine supply is also not rate limiting in CoA biogenesis. Taken together, the results point to pantothenate kinase as the primary enzymatic step that regulates the CoA content of E. coli.     

Identification, substrate specificity, and inhibition of the Streptococcus pneumoniae beta-ketoacyl-acyl carrier protein synthase III (FabH)

In the bacterial type II fatty acid synthase system, beta-ketoacyl-acyl carrier protein (ACP) synthase III (FabH) catalyzes the condensation of acetyl-CoA with malonyl-ACP. We have identified, expressed, and characterized the Streptococcus pneumoniae homologue of Escherichia coli FabH. S. pneumoniae FabH is approximately 41, 39, and 38% identical in amino acid sequence to Bacillus subtilis, E. coli, and Hemophilus influenzae FabH, respectively. The His-Asn-Cys catalytic triad present in other FabH molecules is conserved in S. pneumoniae FabH. The apparent K(m) values for acetyl-CoA and malonyl-ACP were determined to be 40.3 and 18.6 microm, respectively. Purified S. pneumoniae FabH preferentially utilized straight short-chain CoA primers. Similar to E. coli FabH, S. pneumoniae FabH was weakly inhibited by thiolactomycin. In contrast, inhibition of S. pneumoniae FabH by the newly developed compound SB418011 was very potent, with an IC(50) value of 0.016 microm. SB418011 also inhibited E. coli and H. influenzae FabH with IC(50) values of 1.2 and 0.59 microm, respectively. The availability of purified and characterized S. pneumoniae FabH will greatly aid in structural studies of this class of essential bacterial enzymes and facilitate the identification of small molecule inhibitors of type II fatty acid synthase with the potential to be novel and potent antibacterial agents active against pathogenic bacteria.     

Characterization of HmqF, a protein involved in the biosynthesis of unsaturated quinolones produced by Burkholderia thailandensis

The opportunistic pathogen Burkholderia thailandensis produces a number of structurally similar unsaturated quinolones involved in quorum sensing. However, little is known about the biosynthesis of these unsaturated quinolones. In this study, we have characterized the starting point of the biosynthesis of unsaturated quinolone molecules produced in B. thailandensis. We have shown by using in vitro enzymology, liquid chromatography, and mass spectrometry that protein HmqF is involved in the biosynthesis of unsaturated quinolones produced by B. thailandensis. HmqF consists of three domains: an adenylation domain (A domain), a dehydrogenase domain (DH domain), and an acyl carrier domain (ACP). The three domains (A, DH, and ACP) were cloned and expressed individually in Escherichia coli, and their reactivity was studied using high-performance liquid chromatography (HPLC) and mass spectrometry (MS) based assays. Our in vitro studies show that the A domain catalyzes ATP-dependent activation of medium chain (C6-C14) fatty acids without activation by coenzyme A (CoA). Results from competition assays are consistent with decanoic acid being the preferred substrate. Incubation of the ACP domain with 4'-phosphopantetheine transferase and CoA led to the formation of phosphopantetheinylated ACP (Ppant-ACP). In a Ppant ejection assay using tandem MS (MS/MS), a mass consistent with the mass of a cyclic variant of dephosphorylated Ppant was detected. We further demonstrated that Ppant-ACP could be loaded with medium chain fatty acids in the presence of ATP and the A domain. MS analysis was consistent with the formation of Ppant-ACP thiol esters of the fatty acids. MS/MS Ppant ejection experiments confirmed the loss of 2H in samples of fatty acid-loaded Ppant-ACP in the presence of the DH domain. HPLC analysis of benzyl amide ligation products allowed us to conclude that dehydrogenation produced trans-β,γ-unsaturation in the fatty acid chains. Our results are in good agreement with naturally observed quinolone molecules produced by B. thailandensis, which predominately produce nine-carbon trans-β,γ-unsaturated alkyl chain quinolone molecules.     

An ordered reaction mechanism for bacterial toxin acylation by the specialized acyltransferase HlyC: formation of a ternary complex with acylACP and protoxin substrates

The 110 kDa haemolysin protoxin (proHlyA) is activated in the Escherichia coli cytosol by acyl carrier protein-dependent fatty acylation of two internal lysine residues, directed by the co-synthesized protein HlyC. Using an in vitro maturation reaction containing purified protoxin peptides and acylACP, we show unambiguously that HlyC possesses an apparently unique acyltransferase activity fully described by Michaelis-Menten analysis. The Vmax of HlyC at saturating levels of both substrates was approximately 115 nmol acyl group min-1 mg-1 with KMacylACP of 260 nM and KMproHlyA of 27 nM, kinetic parameters sufficient to explain why in vivo HlyC is required at a concentration equimolar to proHlyA. HlyC bound the fatty acyl group from acylACP to generate an acylated HlyC intermediate that was depleted in the presence of proHlyA, but enriched in the presence of proHlyA derivatives lacking acylation target sites. HlyC was also able to bind in vivo 4'-phosphopantetheine. Substitution of conserved amino acids that could act as putative covalent attachment sites did not prevent binding of the fatty acyl or 4'-phosphopantetheine groups. These data and substrate variation analyses suggest that the unique acylation reaction does not involve covalent attachment of fatty acid to the acyltransferase, but rather that it proceeds via a sequential ordered Bi-Bi reaction mechanism, requiring the formation of a non-covalent ternary acylACP-HlyC-proHlyA complex.