A Francisella virulence factor catalyses an essential reaction of biotin synthesis

We recently identified a gene (FTN_0818) required for Francisella virulence that seemed likely involved in biotin metabolism. However, the molecular function of this virulence determinant was unclear. Here we show that this protein named BioJ is the enzyme of the biotin biosynthesis pathway that determines the chain length of the biotin valeryl side‐chain. Expression of bioJ allows growth of an Escherichia coli bioH strain on biotin‐free medium, indicating functional equivalence of BioJ to the paradigm pimeloyl‐ACP methyl ester carboxyl‐esterase, BioH. BioJ was purified to homogeneity, shown to be monomeric and capable of hydrolysis of its physiological substrate methyl pimeloyl‐ACP to pimeloyl‐ACP, the precursor required to begin formation of the fused heterocyclic rings of biotin. Phylogenetic analyses confirmed that distinct from BioH, BioJ represents a novel subclade of the α/β‐hydrolase family. Structure‐guided mapping combined with site‐directed mutagenesis revealed that the BioJ catalytic triad consists of Ser151, Asp248 and His278, all of which are essential for activity and virulence. The biotin synthesis pathway was reconstituted reaction in vitro and the physiological role of BioJ directly assayed. To the best of our knowledge, these data represent further evidence linking biotin synthesis to bacterial virulence.     

Three enigmatic BioH isoenzymes are programmed in the early stage of mycobacterial biotin synthesis,an attractive anti-TB drug target

Tuberculosis (TB) is one of the leading infectious diseases of global concern, and one quarter of the world’s population are TB carriers. Biotin metabolism appears to be an attractive anti-TB drug target. However, the first-stage of mycobacterial biotin synthesis is fragmentarily understood. Here we report that three evolutionarily-distinct BioH isoenzymes (BioH1 to BioH3) are programmed in biotin synthesis of Mycobacterium smegmatis. Expression of an individual bioH isoform is sufficient to allow the growth of an Escherichia coli ΔbioH mutant on the non-permissive condition lacking biotin. The enzymatic activity in vitro combined with biotin bioassay in vivo reveals that BioH2 and BioH3 are capable of removing methyl moiety from pimeloyl-ACP methyl ester to give pimeloyl-ACP, a cognate precursor for biotin synthesis. In particular, we determine the crystal structure of dimeric BioH3 at 2.27Å, featuring a unique lid domain. Apart from its catalytic triad, we also dissect the substrate recognition of BioH3 by pimeloyl-ACP methyl ester. The removal of triple bioH isoforms (ΔbioH1/2/3) renders M. smegmatis biotin auxotrophic. Along with the newly-identified Tam/BioC, the discovery of three unusual BioH isoforms defines an atypical ‘BioC-BioH(3)’ paradigm for the first-stage of mycobacterial biotin synthesis. This study solves a long-standing puzzle in mycobacterial nutritional immunity, providing an alternative anti-TB drug target.     

Remarkable Diversity in the Enzymes Catalyzing the Last Step in Synthesis of the Pimelate Moiety of Biotin

Biotin synthesis in Escherichia coli requires the functions of the bioH and bioC genes to synthesize the precursor pimelate moiety by use of a modified fatty acid biosynthesis pathway. However, it was previously noted that bioH has been replaced with bioG or bioK within the biotin synthetic gene clusters of other bacteria. We report that each of four BioG proteins from diverse bacteria and two cyanobacterial BioK proteins functionally replace E. coli BioH in vivo. Moreover, purified BioG proteins have esterase activity against pimeloyl-ACP methyl ester, the physiological substrate of BioH. Two of the BioG proteins block biotin synthesis when highly expressed and these toxic proteins were shown to have more promiscuous substrate specificities than the non-toxic BioG proteins. A postulated BioG-BioC fusion protein was shown to functionally replace both the BioH and BioC functions of E. coli. Although the BioH, BioG and BioK esterases catalyze a common reaction, the proteins are evolutionarily distinct.     

The Serratia marcescens bioH gene encodes an esterase

The 3.9 kb chromosomal DNA was cloned from Serratia marcescens Sr41, which confers on Escherichia coli cells a phenotype of clear halo formation on tributyrin agar plates. Three complete open reading frames (ORFs) were identified in the inserted DNA, and one ORF was demonstrated to encode a 28 kDa protein of 255 amino acids related to esterase activity. Interestingly, the ORF was 70% identical to a product of the E. coli bioH gene, which lies at a locus separated from the bioABFCD operon and acts in the early steps of the biotin synthetic pathway before pimeloyl-CoA synthesis. This gene complemented a bioH-deficient mutation of E. coli. From the sequence analysis, BioH is presumed to be a serine hydrolase, which belongs to the alpha/beta hydrolase-fold family comprising a wide variety of hydrolases including esterases. A catalytic triad composed of a nucleophilic residue (Ser80), an acidic residue (Asp206), and histidine (His234) was conserved in BioH, and the nucleophilic residue Ser, a catalytic center, was situated in the consensus sequence of G-X-S-X-G-G, a nucleophile elbow. Although the enzymatic function of BioH is not yet elucidated, the bioH gene products from S. marcescens and E. coli show esterase activity, which may imply the hydrolysis of a precursor leading to pimeloyl-CoA ester. The esterase activity of BioH and its CoA binding activity recently reported agree with a current hypothesis of pimeloyl-CoA ester synthesis from CoA and acylester derivatives including an acyl-carrier protein.     

Substrate specificity of an α-amino acid ester hydrolase produced by Acetobacter turbidans A.T.C.C. 9325

A partially purified preparation of an alpha-amino acid ester hydrolase was obtained from Acetobacter turbidans A.T.C.C. 9325, which catalyses synthesis of 7-(d-alpha-amino-alpha-phenylacetamido)-3-cephem-3-methyl-4- carboxylic acid (cephalexin) from methyl d-alpha-aminophenylacetate and 7-amino-3-deacetoxycephalosporanic acid. The enzyme preparation catalysed both cephalosprin synthesis from 7-amino-3-deacetoxycephalosporanic acid and suitable amino acid esters (e.g. methyl d-alpha-aminophenylacetate, l-cysteine methyl ester, glycine ethyl ester, d-alanine methyl ester, methyl dl-alpha-aminoiso-butyrate, l-serine methyl ester, d-leucine methyl ester, l-methionine methyl ester) and the hydrolysis of such esters. The substrate specificity of the enzyme preparation for the hydrolysis closely paralleled the acyl-donor specificity for cephalosporin synthesis, even to the reaction rates. Only alpha-amino acid derivatives could act as acyl donors. The hydrogen atom on the alpha-carbon atom was not always required by acyl donors. The hydrolysis rate was markedly diminished by adding 7-amino-3-deacetoxycephalosporanic acid to reaction mixtures, but no effect on the total reaction rate (the hydrolysis rate plus synthesis rate) was observed with various concentrations of 7-amino-3-deacetoxycephalosporanic acid. Both the hydrolytic and the synthetic activities of the enzyme preparation were inhibited by high concentrations of some acyl donors (e.g. methyl d-alpha-aminophenylacetate, ethyl d-alpha-aminophenylacetate). The enzyme preparation hydrolysed alpha-amino acid esters much more easily than alpha-amino acid derivatives with an acid-amide bond.     

Engineering Escherichia coli for biodiesel production utilizing a bacterial fatty acid methyltransferase

The production of low-cost biofuels in engineered microorganisms is of great interest due to the continual increase in the world's energy demands. Biodiesel is a renewable fuel that can potentially be produced in microbes cost-effectively. Fatty acid methyl esters (FAMEs) are a common component of biodiesel and can be synthesized from either triacylglycerol or free fatty acids (FFAs). Here we report the identification of a novel bacterial fatty acid methyltransferase (FAMT) that catalyzes the formation of FAMEs and 3-hydroxyl fatty acid methyl esters (3-OH-FAMEs) from the respective free acids and S-adenosylmethionine (AdoMet). FAMT exhibits a higher specificity toward 3-hydroxy free fatty acids (3-OH-FFAs) than FFAs, synthesizing 3-hydroxy fatty acid methyl esters (3-OH-FAMEs) in vivo. We have also identified bacterial members of the fatty acyl-acyl carrier protein (ACP) thioesterase (FAT) enzyme family with distinct acyl chain specificities. These bacterial FATs exhibit increased specificity toward 3-hydroxyacyl-ACP, generating 3-OH-FFAs, which can subsequently be utilized by FAMTs to produce 3-OH-FAMEs. PhaG (3-hydroxyacyl ACP:coenzyme A [CoA] transacylase) constitutes an alternative route to 3-OH-FFA synthesis; the coexpression of PhaG with FAMT led to the highest level of accumulation of 3-OH-FAMEs and FAMEs. The availability of AdoMet, the second substrate for FAMT, is an important factor regulating the amount of methyl esters produced by bacterial cells. Our results indicate that the deletion of the global methionine regulator metJ and the overexpression of methionine adenosyltransferase result in increased methyl ester synthesis.     

Structural studies of fatty acyl-(acyl carrier protein) thioesters reveal a hydrophobic binding cavity that can expand to fit longer substrates

A knowledge of the structures of acyl chain loaded species of the acyl carrier protein (ACP) as used in fatty acid biosynthesis and a range of other metabolic events, is essential for a full understanding of the molecular recognition at the heart of these processes. To date the only crystal structure of an acylated species of ACP is that of a butyryl derivative of Escherichia coli ACP. We have now determined the structures of a family of acylated E. coli ACPs of varying acyl chain length. The acyl moiety is attached via a thioester bond to a phosphopantetheine linker that is in turn bound to a serine residue in ACP. The growing acyl chain can be accommodated within a central cavity in the ACP for transport during the elongation stages of lipid synthesis through changes in the conformation of a four alpha-helix bundle. The results not only clarify the means by which a substrate of varying size and complexity is transported in the cell but also suggest a mechanism by which interacting enzymes can recognize the loaded ACP through recognition of surface features including the conformation of the phosphopantetheine linker.     

Reconstituting modular activity from separated domains of 6-deoxyerythronolide B synthase

The hallmark of a type I polyketide synthase (PKS), such as the 6-deoxyerythronolide B synthase (DEBS), is the presence of catalytic modules comprised of covalently fused domains acting together to catalyze one round of chain elongation. In addition to an obligate ketosynthase (KS), acyl transferase (AT), and acyl carrier protein (ACP), a module may also include a ketoreductase (KR), dehydratase (DH), and/or enoyl reductase (ER) domain. The size, flexibility, and fixed domain-domain stoichiometry of these PKS modules present challenges for structural, mechanistic, and protein-engineering studies. Here, we have harnessed the power of limited proteolysis and heterologous protein expression to isolate and characterize individual domains of module 3 of DEBS, a 150-kD protein consisting of a KS, an AT, an ACP, and an inactive KR domain. Two interdomain boundaries were identified via limited proteolysis, which led to the production of a 90-kD KS-AT, a 142-kD KS-AT-KR(0), and a 10-kD ACP as structurally stable stand-alone proteins. Each protein was shown to possess the requisite catalytic properties. In the presence of the ACP, both the KS-AT and the KS-AT-KR(0) proteins were able to catalyze chain elongation as well as the intact parent module. Separation of the KS from the ACP enabled direct interrogation of the KS specificity for both the nucleophilic substrate and the partner ACP. Malonyl and methylmalonyl extender units were found to be equivalent substrates for chain elongation. Whereas ACP2 and ACP4 of DEBS could be exchanged for ACP3, ACP6 was a substantially poorer partner for the KS. Remarkably, the newly identified proteolytic sites were conserved in many PKS modules, raising the prospect of developing improved methods for the construction of hybrid PKS modules by engineering domain fusions at these interdomain junctions.     

Chicken avidin exhibits pseudo-catalytic properties. Biochemical, structural, and electrostatic consequences

Avidin and its bacterial analogue streptavidin exhibit similarly high affinities toward the vitamin biotin. The extremely high affinity of these two proteins has been utilized as a powerful tool in many biotechnological applications. Although avidin and streptavidin have similar tertiary and quaternary structures, they differ in many of their properties. Here we show that avidin enhances the alkaline hydrolysis of biotinyl p-nitrophenyl ester, whereas streptavidin protects this reaction even under extreme alkaline conditions (pH > 12). Unlike normal enzymatic catalysis, the hydrolysis reaction proceeds as a single cycle with no turnover because of the extremely high affinity of the protein for one of the reaction products (i.e. free biotin). The three-dimensional crystal structures of avidin (2 A) and streptavidin (2.4 A) complexed with the amide analogue, biotinyl p-nitroanilide, as a model for the p-nitrophenyl ester, revealed structural insights into the factors that enhance or protect the hydrolysis reaction. The data demonstrate that several molecular features of avidin are responsible for the enhanced hydrolysis of biotinyl p-nitrophenyl ester. These include the nature of a decisive flexible loop, the presence of an obtrusive arginine 114, and a newly formed critical interaction between lysine 111 and the nitro group of the substrate. The open conformation of the loop serves to expose the substrate to the solvent, and the arginine shifts the p-nitroanilide moiety toward the interacting lysine, which increases the electron withdrawing characteristics and consequent electrophilicity of the carbonyl group of the substrate. Streptavidin lacked such molecular properties, and analogous interactions with the substrate were consequently absent. The information derived from these structures may provide insight into the action of artificial protein catalysts and the evolution of catalytic sites in general.     

Characterization of substrate specificity of plant FatA and FatB acyl-ACP thioesterases

The specificity of plant acyl-acyl carrier protein (ACP) thioesterases is the major determinant of the chain length and level of saturated fatty acids found in most plant tissues. Although these enzymes have been previously characterized from a number of sources, information on kinetic parameters for a wide range of substrates with cloned enzymes is lacking. In the present study the substrate specificity of recombinant FatA thioesterase isoforms from Arabidopsis (AtFatA) and coriander (CsFatA) and FatB from Arabidopsis (AtFatB) have been re-examined with a comprehensive range of substrates including 14:1-ACP and 16:1-ACP. AtFatA displayed the highest catalytic efficiencies (kcat/Km) towards oleoyl-ACP with activities at least 20-fold lower for all other tested substrates and 75-fold lower with palmitoyl-ACP. Both chain length and double bond presence strongly influenced kcat of FatA with minor influence on Km. Arabidopsis FatB substrate specificity was found to differ from previous reports and this difference could be attributed to the influence of ACP structure. FatB activity with palmitoyl-ACP was 2.5-fold higher and the ratio of 16:0-ACP/14:0-ACP hydrolysis was 6.4-fold higher with spinach ACP compared to E. coli ACP. Additionally, the influence of amino acid domains from both AtFatA and AtFatB on their substrate specificity was studied by utilizing a domain-swapping approach. The characterization of the resulting chimeric enzymes pointed to the N-terminus as a determinant of the substrate specificity for both FatA and FatB acyl-ACP thioesterases.     

Integrating structure,bioinformatics, and enzymology to discover function: BioH,a new carboxylesterase from Escherichia coli

Structural proteomics projects are generating three-dimensional structures of novel, uncharacterized proteins at an increasing rate. However, structure alone is often insufficient to deduce the specific biochemical function of a protein. Here we determined the function for a protein using a strategy that integrates structural and bioinformatics data with parallel experimental screening for enzymatic activity. BioH is involved in biotin biosynthesis in Escherichia coli and had no previously known biochemical function. The crystal structure of BioH was determined at 1.7 A resolution. An automated procedure was used to compare the structure of BioH with structural templates from a variety of different enzyme active sites. This screen identified a catalytic triad (Ser82, His235, and Asp207) with a configuration similar to that of the catalytic triad of hydrolases. Analysis of BioH with a panel of hydrolase assays revealed a carboxylesterase activity with a preference for short acyl chain substrates. The combined use of structural bioinformatics with experimental screens for detecting enzyme activity could greatly enhance the rate at which function is determined from structure.     

Ketosynthases in the initiation and elongation modules of aromatic polyketide synthases have orthogonal acyl carrier protein specificity

Many bacterial aromatic polyketides are synthesized by type II polyketide synthases (PKSs) which minimally consist of a ketosynthase-chain length factor (KS-CLF) heterodimer, an acyl carrier protein (ACP), and a malonyl-CoA:ACP transacylase (MAT). This minimal PKS initiates polyketide biosynthesis by decarboxylation of malonyl-ACP, which is catalyzed by the KS-CLF complex and leads to incorporation of an acetate starter unit. In non-acetate-primed PKSs, such as the frenolicin (fren) PKS and the R1128 PKS, decarboxylative priming is suppressed in favor of chain initiation with alternative acyl groups. Elucidation of these unusual priming pathways could lead to the engineered biosynthesis of polyketides containing novel starter units. Unique to some non-acetate-primed PKSs is a second catalytic module comprised of a dedicated homodimeric KS, an additional ACP, and a MAT. This initiation module is responsible for starter-unit selection and catalysis of the first chain elongation step. To elucidate the protein-protein recognition features of this dissociated multimodular PKS system, we expressed and purified two priming and two elongation KSs, a set of six ACPs from diverse sources, and a MAT. In the presence of the MAT, each ACP was labeled with malonyl-CoA rapidly. In the presence of a KS-CLF and MAT, all ACPs from minimal PKSs supported polyketide synthesis at comparable rates (k(cat) between 0.17 and 0.37 min(-1)), whereas PKS activity was attenuated by at least 50-fold in the presence of an ACP from an initiation module. In contrast, the opposite specificity pattern was observed with priming KSs: while ACPs from initiation modules were good substrates, ACPs from minimal PKSs were significantly poorer substrates. Our results show that KS-CLF and KSIII recognize orthogonal sets of ACPs, and the additional ACP is indispensable for the incorporation of non-acetate primer units. Sequence alignments of the two classes of ACPs identified a tyrosine residue that is unique to priming ACPs. Site-directed mutagenesis of this amino acid in the initiation and elongation module ACPs of the R1128 PKS confirmed the importance of this residue in modulating interactions between KSs and ACPs. Our study provides new biochemical insights into unusual chain initiation mechanisms of bacterial aromatic PKSs.     

Separation and characterization of 61- and 57-kDa lipases from Geotrichum candidum ATCC 66592.

Two lipolytic proteins (61 and 57 kDa) present in a Sephadex G-100 fraction of extracellular lipase from Geotrichum candidum ATCC 66592 were separated using high-performance liquid chromatography. Crossed electrofocusing immunoelectrophoresis was used to demonstrate that the 61-kDa lipase fraction contained two forms of lipase with pI 4.5 and 4.7. However, when deglycosylated with endoglycosidase H, the two forms gained an identical pI, 4.6. The 57-kDa lipase fraction contained one form of lipase with pI close to 4.5. Although the 61- and 57-kDa lipases were immunologically identical, the substrate specificity differed. Thus, the 61-kDa lipase hydrolysed palmitic acid methyl ester at an initial velocity of hydrolysis that was 60% of the initial velocity of hydrolysis of oleic acid methyl ester, whereas the 57-kDa lipase hydrolysed palmitic acid methyl ester at an initial velocity of hydrolysis that was only 7% of the initial velocity of hydrolysis of oleic acid methyl ester.     

Insights from molecular dynamics simulations into pH-dependent enantioselective hydrolysis of ibuprofen esters by Candida rugosa lipase

An interesting observation was found during our continued studies on the hydrolysis of ibuprofen esters by Candida rugosa lipase (CRL). An important role is played by pH in the stereospecific hydrolysis of these esters. The flap region of CRL plays a significant role in the access of the substrate to the active site of the enzyme. At pH 5.6, 48% of the methyl ester and 5% of the butyl ester of ibuprofen were hydrolysed in 5.5 h, whereas at pH 7.2, 9% of methyl ester and 45% of the butyl ester of ibuprofen was hydrolysed in a identical reaction time using CRL. This lead us to assume that CRL prefers the methyl ester of ibuprofen as a substrate at an acidic pH and the butyl ester of ibuprofen at a neutral pH. Therefore, in order to understand the role of pH in the substrate selection by CRL for the esters of ibuprofen we used the crystallographic coordinates of the open form of the CRL (1CRL) for molecular dynamics (MD) simulations under acidic and neutral conditions for 2 ns using GROMACS. The final structures obtained after simulation in acidic and neutral conditions were compared with the energy-minimized structure, and the root-mean-square deviations (r.m.s.ds) were calculated. The r.m.s.d. of the CRL flap at neutral pH was found to be greater than that of the CRL flap at acidic pH. The extent to which the flap opens at neutral pH allowed the bulkier substrate, the butyl ester of ibuprofen, to diffuse into the active site and provides the best enzyme-substrate fit for this specific substrate. At acidic pH there is a decreased opening of the flap thereby accommodating a more compact substrate, namely the methyl ester of ibuprofen. Thus, simulation experiments using MD provide reasonable insight for the pH-dependent substrate selectivity of CRL in aqueous environments.     

Stereoselective esterase from Pseudomonas putida IFO12996 reveals alpha/beta hydrolase folds for D-beta-acetylthioisobutyric acid synthesis

Esterase (EST) from Pseudomonas putida IFO12996 catalyzes the stereoselective hydrolysis of methyl dl-beta-acetylthioisobutyrate (dl-MATI) to produce d-beta-acetylthioisobutyric acid (DAT), serving as a key intermediate for the synthesis of angiotensin-converting enzyme inhibitors. The EST gene was cloned and expressed in Escherichia coli; the recombinant protein is a non-disulfide-linked homotrimer with a monomer molecular weight of 33,000 in both solution and crystalline states, indicating that these ESTs function as trimers. EST hydrolyzed dl-MATI to produce DAT with a degree of conversion of 49.5% and an enantiomeric excess value of 97.2% at an optimum pH of about 8 to 10 and an optimum temperature of about 57 to 67 degrees C. The crystal structure of EST has been determined by X-ray diffraction to a resolution of 1.6 A, confirming that EST is a member of the alpha/beta hydrolase fold superfamily of enzymes and includes a catalytic triad of Ser97, Asp227, and His256. The active site is located approximately in the middle of the molecule at the end of a pocket approximately 12 A deep. EST can hydrolyze the methyl ester group without affecting the acetylthiol ester moiety in dl-MATI. The examination of substrate specificity of EST toward other linear esters revealed that the enzyme showed specific activity toward methyl esters and that it recognized the configuration at C-2.     

Improving simvastatin bioconversion in Escherichia coli by deletion of bioH

Simvastatin is an important cholesterol lowering compound and is currently synthesized from the natural product lovastatin via multistep chemical synthesis. We have previously reported the use of an Escherichia coli strain BL21(DE3)/pAW31 as the host for whole-cell biocatalytic conversion of monacolin J acid to simvastatin acid. During fermentation and bioconversion, unknown E. coli enzyme(s) hydrolyzed the membrane permeable thioester substrate dimethylbutyryl-S-methyl mercaptopropionate (DMB-S-MMP) to the free acid, significantly decreased the efficiencies of the whole-cell bioconversion and the downstream purification steps. Using the Keio K-12 Singe-Gene Knockout collection, we identified BioH as the sole enzyme responsible for the observed substrate hydrolysis. Purification and reconstitution of E. coli BioH activity in vitro confirmed its function. BioH catalyzed the rapid hydrolysis of DMB-S-MMP with kcat and Km values of 260+/-45 s(-1) and 229+/-26 microM, respectively. This is in agreement with previous reports that BioH can function as a carboxylesterase towards fatty acid esters. YT2, which is a delta bioH mutant of BL21(DE3), did not hydrolyze DMB-S-MMP during prolonged fermentation and was used as an alternative host for whole-cell biocatalysis. The rate of simvastatin acid synthesis in YT2 was significantly faster than in BL21(DE3) and 99% conversion of 15 mM simvastatin acid in less than 12 h was achieved. Furthermore, the engineered host required significantly less DMB-S-MMP to be added to accomplish complete conversion. Finally, simvastatin acid synthesized using YT2 can be readily purified from fermentation broth and no additional steps to remove the hydrolyzed dimethylbutyryl-S-mercaptopropionic acid is required. Together, the proteomic and metabolic engineering approaches render the whole-cell biocatalytic process more robust and economically attractive.     

Enzyme cleavable and biotinylated photoaffinity ligand with diazirine

The efficient synthesis of an enzyme cleavable biotinylated diazirinyl photoaffinity ligand is described to allow the effective manipulation of the photolabeled biocomponents. The compound contains a glutamic acid gamma-methyl ester, which is a precursor of the substrate for V8 protease, between the diazirinyl photophor and biotin moiety. After alkaline hydrolysis of the ester, the compound can be proteolyzed at the Glu moiety by V8 protease. The photophore was introduced to L-Phe p-nitroanilide and the ligand was applied to photolabel of chymotrypsin to manipulate the application of the concept.     

Hydrolysis of 13-sophorosyloxydocosanoic acid esters by acetyl- and carboxylesterases isolated from Candida bororiensis.

Two enzymes have been isolated from Candida bogoriensis which catalyze the hydrolysis of 13-sophorosyloxydocosanoic acid (Glc2HDA) esters obtained from this organism. The 6',6"-diacetyl derivative of Glc2HDA (Ac2Glc2HDA) is hydrolyzed by an acetylesterase (EC 3.1.1.6) which has been purified 1300-fold. The acetylesterase has a molecular weight of 35,000 estimated from gel filtration, and is much more active with p-nitrophenyl acetate than with the acetylated glycolipid. The rate of hydrolysis increases with Ac2Glc2HDA concentration until a plateau is reached at a concentration of about 40 muM, near the critical micelle concentration of this glycolipid. These kinetic data are interpreted as an enzyme specificity for the monomeric, but not the micellar form of the glycolipid. The acetylesterase is inhibited by 0.1 to 10 mM diisopropyl fluorophosphate, 5 mM p-hydroxymercuribenzoate, and 5 mM N-ethylmaleimide, but only slightly by 5 mM iodoacetamide. The methyl ester of Ac2Glc2HDA is hydrolyzed by at least two carboxylesterases (EC 3.1.1) which differ in size according to gel filtration. Their molecular weights are estimated as 140,000 for carboxyesterase A and 40,000 for carboxyesterase B. Both carboxylesterases were purified over 20-fold, and carboxylesterase A was characterized further. Carboxylesterase A activity was inhibited completely by 0.1 to 10 mM diisopropyl fluorophosphate and by 10 mM p-hydroxymercuribenzoate, but only slightly by lower concentrations of p-hydroxymercuribenzoate or by N-ethylmaleimide or iodoacetamide. The carboxylesterase A preparation also acted as a thioesterase with palmityl-CoA (palmityl-CoA hydrolase, EC 3.1.2.2), showing the following approximate relative activities: palmityl-CoA, 100; octanoyl-CoA, 90; methyl Glc2HD, 22; butyryl-CoA, 18; methyl AcGlc2HD, 15; methyl Ac2Glc2HD, 10; and acetyl-CoA, O. Methyl Ac2Glc2HD showed some substrate inhibition at higher concentrations, but neither methyl Ac2Glc2HD nor palmityl-CoA approached enzyme saturation until well above their critical micelle concentrations, indicating hydrolysis of the micellar substrate was occurring. The carboxylesterase and palmityl-CoA hydrolase activities were destroyed in a parallel fashion by heat denaturation, and each substrate inhibited the action of the preparation on the other substrate, but the preparation has not been purified sufficiently to establish with certainty that both activities reside in the same protein.     

Enhanced acylation activity of esterase BioH from Escherichia coli by directed evolution towards improved hydrolysis activity

Esterase BioH is a critical enzyme for Biotin synthesis in Escherichia coli, which has been previously found to be active in the acylation of secondary alcohols and amines. Directed evolution towards improved acylation activity requires a high-throughput screening method. The aim of this study is to explore whether the acylation activity of BioH can be improved by directed evolution of its hydrolysis activity. A colorimetric method based on p-nitrophenyl butyrate hydrolysis was adopted in the high-throughput determination of hydrolysis activity. The wild-type BioH showed a hydrolysis activity of 18 U/mg, and the specific activities for α-phenylethanol and α-phenylethylamine acylation were 12.8 U/mg and 3.5 U/mg, respectively. After two rounds of directed evolution, seven mutants with improved hydrolysis activity were obtained, among which, K213E, Q70L/M170T and M197L/K213E also showed improvement in acylation activity. To further improve the acylation activity, site mutations were generated in different combinations at the four hot spots Q70L, M170T, M197L and K213E. Among the resulting mutants, Q70L/M197L/K213E showed the highest activity in α-phenylethylamine acylation with a 120% improvement, while Q70L/K213E had the highest α-phenylethanol acylation activity, which was improved by 70%. The results demonstrated that directed evolution of the hydrolysis activity might be a possible approach to improve the acylation activity of the esterase BioH.     

In vitro reconstitution and analysis of the chain initiating enzymes of the R1128 polyketide synthase.

Biosynthesis of the carbon chain backbone of the R1128 substances is believed to involve the activity of a ketosynthase/chain length factor (ZhuB/ZhuA), an additional ketosynthase (ZhuH), an acyl transferase (ZhuC), and two acyl carrier proteins (ACPs; ZhuG and ZhuN). A subset of these proteins initiate chain synthesis via decarboxylative condensation between an acetyl-, propionyl-, isobutyryl-, or butyryl-CoA derived primer unit and a malonyl-CoA derived extender unit to yield an acetoacetyl-, beta-ketopentanoyl-, 3-oxo-4-methylpentanoyl-, or beta-ketohexanoyl-ACP product, respectively. To investigate the precise roles of ZhuH, ZhuC, ZhuG, and ZhuN, each protein was expressed in Escherichia coli and purified to homogeneity. Although earlier reports had proposed that ZhuC and its homologues played a role in primer unit selection, direct in vitro analysis of ZhuC showed that it was in fact a malonyl-CoA:ACP malonyltransferase (MAT). The enzyme could catalyze malonyl transfer but not acetyl- or propionyl-transfer onto R1128 ACPs or onto ACPs from other biosynthetic pathways, suggesting that ZhuC has broad substrate specificity with respect to the holo-ACP substrate but is specific for malonyl-CoA. Thus, ZhuC supplies extender units to both the initiating and elongating ketosynthases from this pathway. To interrogate the primer unit specificity of ZhuH, the kinetics of beta-ketoacyl-ACP formation in the presence of various acyl-CoAs and malonyl-ZhuG were measured. Propionyl-CoA and isobutyryl-CoA were the two most preferred substrates of ZhuH, although acetyl-CoA and butyryl-CoA could also be accepted and elongated. This specificity is not only consistent with earlier reports demonstrating that R1128B and R1128C are the major products of the R1128 pathway in vivo, but is also in good agreement with the properties of the ZhuH substrate binding pocket, as deduced from a recently solved crystal structure of the enzyme. Finally, to investigate the molecular logic for the occurrence of not one but two ACP genes within the R1128 gene cluster, the inhibition of ZhuH-catalyzed formation of beta-ketopentanoyl-ACP was quantified in the presence of apo-ZhuG or apo-ZhuN. Both apo-proteins were comparable inhibitors of the ZhuH catalyzed reaction, suggesting that the corresponding apo-proteins can be used interchangeably during chain initiation. Together, these results provide direct biochemical insights into the mechanism of chain initiation of an unusual bacterial aromatic PKS.