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.     

Cloning and characterization of biotin biosynthetic genes of Kurthia sp

The biotin biosynthesis genes of Kurthia sp., which is an aerobic gram-positive bacterium, were cloned from Kurthia sp. 538-KA26 and characterized. Eleven biotin biosynthetic genes have been identified in Kurthia sp. Kurthia sp. has two genes coding for KAPA synthase, bioF and bioFII, and also has two genes coding for BioH protein, bioH and bioHII. In addition, three genes, orf1, orf2, and orf3, whose functions are unknown, were found in the biotin gene clusters of Kurthia sp. The bioA, bioD, and orf1 genes are arranged in a gene cluster in the order orf1bioDA, and the bioB, bioF, and orf2 genes are arranged in a gene cluster in the order orf2bioFB. These gene clusters proceed to both directions; the face to face promoters and two 40-bp of palindrome sequences exist upstream of the orf1 and orf2 genes. The bioC, bioFII, and bioHII genes are arranged in a gene cluster in the order bioFIIHIIC; a 40-bp of palindrome sequence exists upstream of the bioFII gene. The bioH and orf3 genes are arranged in a gene cluster in the order bioHorf3; a palindrome sequence was not found upstream of the bioH gene. These palindrome sequences are extremely similar to each other, suggesting that the orf1bioDA, orf2bioFB, and bioFIIHIIC gene clusters are regulated by biotin. Kurthia sp. does not have the bioW gene coding pimeloyl-CoA synthase, suggesting that pimeloyl-CoA may be produced by a different pathway than that of gram-positive bacterium B. subtilis or B. sphaericus, further suggesting a modified fatty acid synthesis pathway via acetyl-CoA instead as E. coli has.     

The first thermophilic alpha-oxoamine synthase family enzyme that has activities of 2-amino-3-ketobutyrate CoA ligase and 7-keto-8-aminopelargonic acid synthase: cloning and overexpression of the gene from an extreme thermophile, Thermus thermophilus, and characterization of its gene product

The first thermophilic alpha-oxoamine synthase family enzyme was identified. The gene (ORF TTHA1582), which is annotated to code putative alpha-oxoamine synthase family enzymes, 7-keto-8-aminopelargonic acid (KAPA) synthase (BioF, 8-amino-7-oxononanoate synthase, EC 2.3.1.47) and 2-amino-3-ketobutyrate CoA ligase (KBL, EC 2.3.1.29), in a genomic database, was cloned from an extreme thermophile, Thermus thermophilus, and overexpressed in Escherichia coli. The recombinant TTHA1582 protein was purified and characterized. It exhibited activity of BioF, which catalyzes the condensation of pimeloyl-CoA and L-alanine to produce a biotin intermediate KAPA, CoASH, and CO(2) with pyridoxal 5'-phosphate as a cofactor. The protein is a dimer with a subunit of 43 kDa that shows an amino acid sequence identity of 35% with E. coli BioF. The optimum temperature and pH were about 70 degrees C and about 6.0. The enzyme showed high thermostability at temperatures of up to 70 degrees C for 1 h, and a half-life of 1 h at 80 degrees C. Thus the TTHA1582 protein was found to have the highest optimum temperature and thermostablility of the alpha-oxoamine synthase family enzymes so far reported. Substrate specificity experiments revealed that it was also able to catalyze the KBL reaction, which used acetyl-CoA and glycine as substrates, and that enzyme activity was seen with the following combinations of substrates: acetyl-CoA and glycine, L-alanine, or L-serine; pimeloyl-CoA and L-alanine, glycine, or L-serine; palmitoyl-CoA and L-alanine. This suggests that the recombinant TTHA1582 protein has broad substrate specificity, unlike the reported mesophilic enzymes of the alpha-oxoamine synthase family.     

Purification and characterization of phosphopantetheine adenylyltransferase from Escherichia coli.

Phosphopantetheine adenylyltransferase (PPAT) catalyzes the penultimate step in coenzyme A (CoA) biosynthesis: the reversible adenylation of 4'-phosphopantetheine yielding 3'-dephospho-CoA and pyrophosphate. Wild-type PPAT from Escherichia coli was purified to homogeneity. N-terminal sequence analysis revealed that the enzyme is encoded by a gene designated kdtB, purported to encode a protein involved in lipopolysaccharide core biosynthesis. The gene, here renamed coaD, is found in a wide range of microorganisms, indicating that it plays a key role in the synthesis of 3'-dephospho-CoA. Overexpression of coaD yielded highly purified recombinant PPAT, which is a homohexamer of 108 kDa. Not less than 50% of the purified enzyme was found to be associated with CoA, and a method was developed for its removal. A steady state kinetic analysis of the reverse reaction revealed that the mechanism of PPAT involves a ternary complex of enzyme and substrates. Since purified PPAT lacks dephospho-CoA kinase activity, the two final steps of CoA biosynthesis in E. coli must be catalyzed by separate enzymes.     

Nucleotide sequence and expression in Escherichia coli of the 3-hydroxy-3-methylglutaryl coenzyme A lyase gene of Pseudomonas mevalonii.

The mva operon of Pseudomonas mevalonii encodes two enzymes that can convert internalized mevalonate into acetoacetate and acetyl-coenzyme A (CoA). The promoter-proximal gene of this operon is mvaA, the structural gene for 3-hydroxy-3-methylglutaryl (HMG)-CoA reductase (EC 1.1.1.88). The cloning, characterization, and expression of mvaA has been reported (M. J. Beach and V. W. Rodwell, J. Bacteriol. 171:2994-3001, 1989). We report here the nucleotide sequence of another gene of this operon, mvaB, its expression in Escherichia coli, and its identification as the structural gene for HMG-CoA lyase (EC 4.1.3.4). P. mevalonii HMG-CoA lyase is a cytosolic protein with 301 amino acid residues and a molecular weight of 31,600. This represents the first reported sequence of an HMG-CoA lyase from any source.     

Role of betaine:CoA ligase (CaiC) in the activation of betaines and the transfer of coenzyme A in Escherichia coli

Aims:  Characterization of the role of CaiC in the biotransformation of trimethylammonium compounds into l (−)-carnitine in Escherichia coli .
Methods and Results:  The caiC gene was cloned and overexpressed in E. coli and its effect on the production of l (−)-carnitine was analysed. Betaine:CoA ligase and CoA transferase activities were analysed in cell free extracts and products were studied by electrospray mass spectrometry (ESI-MS). Substrate specificity of the caiC gene product was high, reflecting the high specialization of the carnitine pathway. Although CoA-transferase activity was also detected in vitro , the main in vivo role of CaiC was found to be the synthesis of betainyl-CoAs. Overexpression of CaiC allowed the biotransformation of crotonobetaine to l (−)-carnitine to be enhanced nearly 20-fold, the yield reaching up to 30% (with growing cells). Higher yields were obtained using resting cells (up to 60%), even when d (+)-carnitine was used as substrate.
Conclusions:  The expression of CaiC is a control step in the biotransformation of trimethylammonium compounds in E. coli .
Significance and Impact of the Study:  A bacterial betaine:CoA ligase has been characterized for the first time, underlining its important role for the production of l -carnitine with Escherichia coli .     

Complete reconstitution of the human coenzyme A biosynthetic pathway via comparative genomics

The biosynthesis of CoA from pantothenic acid (vitamin B5) is an essential universal pathway in prokaryotes and eukaryotes. The CoA biosynthetic genes in bacteria have all recently been identified, but their counterparts in humans and other eukaryotes remained mostly unknown. Using comparative genomics, we have identified human genes encoding the last four enzymatic steps in CoA biosynthesis: phosphopantothenoylcysteine synthetase (EC ), phosphopantothenoylcysteine decarboxylase (EC ), phosphopantetheine adenylyltransferase (EC ), and dephospho-CoA kinase (EC ). Biological functions of these human genes were verified using a complementation system in Escherichia coli based on transposon mutagenesis. The individual human enzymes were overexpressed in E. coli and purified, and the corresponding activities were experimentally verified. In addition, the entire pathway from phosphopantothenate to CoA was successfully reconstituted in vitro using a mixture of purified recombinant enzymes. Human recombinant bifunctional phosphopantetheine adenylyltransferase/dephospho-CoA kinase was kinetically characterized. This enzyme was previously suggested as a point of CoA biosynthesis regulation, and we have observed significant differences in mRNA levels of the corresponding human gene in normal and tumor cells by Northern blot analysis.     

Transfer of the high-GC cyclohexane carboxylate degradation pathway from Rhodopseudomonas palustris to Escherichia coli for production of biotin

This work demonstrates the transfer of the five-gene cyclohexane carboxylate (CHC) degradation pathway from the high-GC alphaproteobacterium Rhodopseudomonas palustris to Escherichia coli, a gammaproteobacterium. The degradation product of this pathway is pimeloyl-CoA, a key metabolite in E. coli's biotin biosynthetic pathway. This pathway is useful for biotin overproduction in E. coli; however, the expression of GC-rich genes is troublesome in this host. When the native R. palustris CHC degradation pathway is transferred to a DeltabioH pimeloyl-CoA auxotroph of E. coli, it is unable to complement growth in the presence of CHC. To overcome this expression problem we redesigned the operon with decreased GC content and removed stretches of high-GC intergenic DNA which comprise the 5' untranslated region of each gene, replacing these features with shorter low-GC sequences. We show this synthetic construct enables growth of the DeltabioH strain in the presence of CHC. When the synthetic degradation pathway is overexpressed in conjunction with the downstream genes for biotin biosynthesis, we measured significant accumulation of biotin in the growth medium, showing that the pathway transfer is successfully integrated with the host metabolism.     

Isolation, identification, and synthesis of gamma-butyrobetainyl-CoA and crotonobetainyl-CoA, compounds involved in carnitine metabolism of E. coli

A still unknown low-molecular-mass cofactor essential for the activity of carnitine-metabolizing enzymes (e.g., L-carnitine dehydratase, crotonobetaine reductase) from E. coli has been purified to homogeneity from a cell-free extract of E. coli O44K74. The purity of the cofactor was confirmed by HPLC analysis. Biosynthesis of the unknown compound was only observed when bacteria were cultivated anaerobically in the presence of L-carnitine or crotonobetaine. The determined properties, together with results obtained from UV-visible, (1)H NMR, and mass spectrometry, indicate that the compound in question is a new CoA derivative. The esterified compound was suggested to be gamma-butyrobetaine-a metabolite of carnitine metabolism of E. coli. Proof of structure was performed by chemical synthesis. Besides gamma-butyrobetainyl-CoA, a second new CoA derivative, crotonobetainyl-CoA, was also chemically synthesized. Both CoA derivatives were purified and their structures confirmed using NMR and mass spectrometry. Comparisons of structural data and of the chemical properties of gamma-butyrobetainyl-CoA, crotonobetainyl-CoA, and the isolated cofactor verified that the unknown compound is gamma-butyrobetainyl-CoA. The physical and chemical properties of gamma-butyrobetainyl-CoA and crotonobetainyl-CoA are similar to known CoA derivatives.     

Cloning, sequencing, and characterization of the Bacillus subtilis biotin biosynthetic operon.

A 10-kb region of the Bacillus subtilis genome that contains genes involved in biotin-biosynthesis was cloned and sequenced. DNA sequence analysis indicated that B. subtilis contains homologs of the Escherichia coli and Bacillus sphaericus bioA, bioB, bioD, and bioF genes. These four genes and a homolog of the B. sphaericus bioW gene are arranged in a single operon in the order bioWAFDR and are followed by two additional genes, bioI and orf2. bioI and orf2 show no similarity to any other known biotin biosynthetic genes. The bioI gene encodes a protein with similarity to cytochrome P-450s and was able to complement mutations in either bioC or bioH of E. coli. Mutations in bioI caused B. subtilis to grow poorly in the absence of biotin. The bradytroph phenotype of bioI mutants was overcome by pimelic acid, suggesting that the product of bioI functions at a step prior to pimelic acid synthesis. The B. subtilis bio operon is preceded by a putative vegetative promoter sequence and contains just downstream a region of dyad symmetry with homology to the bio regulatory region of B. sphaericus. Analysis of a bioW-lacZ translational fusion indicated that expression of the biotin operon is regulated by biotin and the B. subtilis birA gene.     

Identification and characterization of two bile acid coenzyme A transferases from Clostridium scindens, a bile acid 7α-dehydroxylating intestinal bacterium

The human bile acid pool composition is composed of both primary bile acids (cholic acid and chenodeoxycholic acid) and secondary bile acids (deoxycholic acid and lithocholic acid). Secondary bile acids are formed by the 7α-dehydroxylation of primary bile acids carried out by intestinal anaerobic bacteria. We have previously described a multistep biochemical pathway in Clostridium scindens that is responsible for bile acid 7α-dehydroxylation. We have identified a large (12 kb) bile acid inducible (bai) operon in this bacterium that encodes eight genes involved in bile acid 7α-dehydroxylation. However, the function of the baiF gene product in this operon has not been elucidated. In the current study, we cloned and expressed the baiF gene in E. coli and discovered it has bile acid CoA transferase activity. In addition, we discovered a second bai operon encoding three genes. The baiK gene in this operon was expressed in E. coli and found to encode a second bile acid CoA transferase. Both bile acid CoA transferases were determined to be members of the type III family by amino acid sequence comparisons. Both bile acid CoA transferases had broad substrate specificity, except the baiK gene product, which failed to use lithocholyl-CoA as a CoA donor. Primary bile acids are ligated to CoA via an ATP-dependent mechanism during the initial steps of 7α-dehydroxylation. The bile acid CoA transferases conserve the thioester bond energy, saving the cell ATP molecules during bile acid 7α-dehydroxylation. ATP-dependent CoA ligation is likely quickly supplanted by ATP-independent CoA transfer.     

Cloning, overexpression, purification, and characterization of O-acetylserine sulfhydrylase-B from Escherichia coli

O-Acetylserine sulfhydrylase-B (OASS-B, EC 2.5.1.47) is one of the two isozymes produced by Escherichia coli that catalyze the synthesis of L-cysteine from O-acetyl-L-serine and sulfide. The cysM gene encoding OASS-B was cloned and the enzyme was overexpressed in E. coli using pUC19 with a lacUV5 promoter. The enzyme was purified to homogeneity, as evidenced by SDS-PAGE. Approximately 300 mg of purified OASS-B was obtained from 1600 mL of culture broth with a purification yield of 60% or higher. The purified OASS-B was characterized and its properties compared with OASS-A. OASS-B did not form a complex with E. coli serine acetyltransferase (SAT, EC 2.3.1.30) and showed a wide range of substrate specificity in nonproteinaceous amino acid synthesis.     

Genetic Fine Structure of the Leucine Operon of Escherichia coli K-12

The order of mutational sites in 10 independently isolated leucine auxotrophys of Escherichia coli K-12 was determined by three-point reciprocal transductions. The sites of mutation mapped in linear sequence in a cluster; all leucine auxotrophic mutations were cotransducible with mutations in the arabinose operon. The mutations were assigned to four complementation groups by abortive transduction tests, designated D, C, B, and A, reading in a clockwise direction from the arabinose operon. Enzyme analyses showed that strains with a mutation in gene A lacked alpha-isopropylmalate synthetase activity (EC 4.1.3), and those with a mutation in gene B lacked beta-isopropylmalate dehydrogenase activity (EC 1.1.1). It is concluded that the gross structure of the leucine operon in E. coli is closely similar to, if not identical with, the gross structure of the leucine operon in Salmonella typhimurium.     

Characterization of the genes encoding beta-ketoadipate: succinyl-coenzyme A transferase in Pseudomonas putida.

beta-Ketoadipate:succinyl-coenzyme A transferase (beta-ketoadipate:succinyl-CoA transferase) (EC 2.8.3.6) carries out the penultimate step in the conversion of benzoate and 4-hydroxybenzoate to tricarboxylic acid cycle intermediates in bacteria utilizing the beta-ketoadipate pathway. This report describes the characterization of a DNA fragment from Pseudomonas putida that encodes this enzyme. The fragment complemented mutants defective in the synthesis of the CoA transferase, and two proteins of sizes appropriate to encode the two nonidentical subunits of the enzyme were produced in Escherichia coli when the fragment was placed under the control of a phage T7 promoter. DNA sequence analysis revealed two open reading frames, designated pcaI and pcaJ, that were separated by 8 bp, suggesting that they may comprise an operon. A comparison of the deduced amino acid sequence of the P. putida CoA transferase genes with the sequences of two other bacterial CoA transferases and that of succinyl-CoA:3-ketoacid CoA transferase from pig heart suggests that the homodimeric structure of the mammalian enzyme may have resulted from a gene fusion of the bacterial alpha and beta subunit genes during evolution. Conserved functional groups important to the catalytic activity of CoA transferases were also identified.     

Detection and characterization of a thermophilic biotin biosynthetic enzyme, 7-keto-8-aminopelargonic acid synthase, from various thermophiles

By detailed BLAST searches of the genome database of various thermophiles, five ORFs with similarity to the bioF gene, which encodes 7-keto-8-aminopelargonic acid synthase (BioF) involved in biotin biosynthesis, of Escherichia coli were found: AqbioF, CltbioF, GkbioF, SytbioF, and TsebioF, from Aquifex aeolicus VF5, Clostridium thermocellum ATCC27405, Geobacillus kaustophilus JCM12893, Symbiobacterium thermophilum IAM14863, and Thermosynechococcus elongatus BP-1 respectively. The five purified recombinant bioF gene products, which were overexpressed in E. coli, had the enzyme activity of BioF. The optimum temperature range and thermostability of five BioFs, AqBioF, CltBioF, GkBioF, SytBioF, and TseBioF, were higher than those of E. coli BioF. In particular, AqBioF was found to show the highest thermostability of the α-oxoamine synthase family enzymes reported to date. Substrate specificity experiments revealed that SytBioF was also able to catalyze the reaction of 2-amino-3-ketobutyrate CoA ligase, a member of the α-oxoamine synthase family, and that it used acetyl-CoA and glycine as substrates, like the TTHA1582 protein of Thermus thermophilus. The other purified BioFs, AqBioF and GkBioF, did not show any activity with acyl-CoAs and amino acids other than pimeloyl-CoA and L-alanine as substrates.     

Identification of GutQ from Escherichia coli as a D-arabinose 5-phosphate isomerase

The glucitol operon (gutAEBDMRQ) of Escherichia coli encodes a phosphoenolpyruvate:sugar phosphotransferase system that metabolizes the hexitol D-glucitol (sorbitol). The functions for all but the last gene, gutQ, have been previously assigned. The high sequence similarity between GutQ and KdsD, a D-arabinose 5-phosphate isomerase (API) from the 3-deoxy-D-manno-octulosonate (KDO)-lipopolysaccharide (LPS) biosynthetic pathway, suggested a putative activity, but its role within the context of the gut operon remained unclear. Accordingly, the enzyme was cloned, overexpressed, and characterized. Recombinant GutQ was shown to indeed be a second copy of API from the E. coli K-12 genome with biochemical properties similar to those of KdsD, catalyzing the reversible aldol-ketol isomerization between D-ribulose 5-phosphate (Ru5P) and D-arabinose 5-phosphate (A5P). Genomic disruptions of each API gene were constructed in E. coli K-12. TCM11[(deltakdsD)] was capable of sustaining essential LPS synthesis at wild-type levels, indicating that GutQ functions as an API inside the cell. The gut operon remained inducible in TCM7[(deltagutQ)], suggesting that GutQ is not directly involved in d-glucitol catabolism. The conditional mutant TCM15[(deltagutQdeltakdsD)] was dependent on exogenous A5P both for LPS synthesis/growth and for upregulation of the gut operon. The phenotype was suppressed by complementation in trans with a plasmid encoding a functional copy of GutQ or by increasing the amount of A5P in the medium. As there is no obvious obligatory role for GutQ in the metabolism of d-glucitol and there is no readily apparent link between D-glucitol metabolism and LPS biosynthesis, it is suggested that A5P is not only a building block for KDO biosynthesis but also may be a regulatory molecule involved in expression of the gut operon.     

Structure of the lac operon galactoside acetyltransferase

The galactoside acetyltransferase (thiogalactoside transacetylase) of Escherichia coli (GAT, LacA, EC 2.3.1.18) is a gene product of the classical lac operon. GAT may assist cellular detoxification by acetylating nonmetabolizable pyranosides, thereby preventing their reentry into the cell. The structure of GAT has been solved in binary complexes with acetyl-CoA or CoA and in ternary complexes with CoA and the nonphysiological acceptor substrates isopropyl beta-D-thiogalactoside (IPTG) or p-nitrophenyl beta-D-galactopyranoside (PNPbetaGal). A hydrophobic cleft that binds the thioisopropyl and p-nitrophenyl aglycones of IPTG and PNPbetaGal may discriminate against substrates with hydrophilic substituents at this position, such as lactose, or inducers of the lac operon. An extended loop projecting from the left-handed parallel beta helix domain contributes His115, which is in position to facilitate attack of the C6-hydroxyl group of the substrate on the thioester.     

Discovering new enzymes and metabolic pathways: conversion of succinate to propionate by Escherichia coli

The Escherichia coli genome encodes seven paralogues of the crotonase (enoyl CoA hydratase) superfamily. Four of these have unknown or uncertain functions; their existence was unknown prior to the completion of the E. coli genome sequencing project. The gene encoding one of these, YgfG, is located in a four-gene operon that encodes homologues of methylmalonyl CoA mutases (Sbm) and acyl CoA transferases (YgfH) as well as a putative protein kinase (YgfD/ArgK). We have determined that YgfG is methylmalonyl CoA decarboxylase, YgfH is propionyl CoA:succinate CoA transferase, and Sbm is methylmalonyl CoA mutase. These reactions are sufficient to form a metabolic cycle by which E. coli can catalyze the decarboxylation of succinate to propionate, although the metabolic context of this cycle is unknown. The identification of YgfG as methylmalonyl CoA decarboxylase expands the range of reactions catalyzed by members of the crotonase superfamily.     

Molecular cloning of polyhydroxyalkanoate synthesis operon from Aeromonas hydrophila and its expression in Escherichia coli

The polyhydroxyalkanoate synthesis operon was cloned from Aeromonas hydrophila CGMCC 0911. Heterogeneous expression of the cloned polyhydroxyalkanoate synthesis operon in Escherichia coli resulted in accumulation of poly(3-hydroxybutyrate-co-3-hydroxyhexanoate) consisting of 13.9 mol % 3-hydroxyhexanoate up to 29.2 wt % of cell dry weight when grown in lauric acid. The cell dry weight of recombinant E. coli harboring the polyhydroxyalkanoate synthesis operon was improved to 1.7 g L (-1), which was much higher than that of 0.3 g L (-1) of the wild type E. coli. Coexpression of acyl-CoA dehydrogenase gene (yafH) from E. coli and Vitreoscilla hemoglobin gene (vgb) from Vitreoscilla together with the whole A. hydrophila CGMCC 0911 polyhydroxyalkanoate synthesis operon facilitated cell growth and polyhydroxyalkanoate accumulation in E. coli. When yafH was coexpressed together with the polyhydroxyalkanoate synthesis operon, the poly(3-hydroxybutyrate-co-3-hydroxyhexanoate) content was increased from 29.2 to 52.1 wt %, and the cell dry weight was also increased slightly from 1.70 to 1.86 g L (-1). Coexpression of vgb gene could further enhance the cell dry weight to 2.0 g L(-1) and the polyhydroxyalkanoate content to 60.7 wt %.     

Cloning and expression of Clostridium acetobutylicum ATCC 824 acetoacetyl-coenzyme A:acetate/butyrate:coenzyme A-transferase in Escherichia coli

Coenzyme A (CoA)-transferase (acetoacetyl-CoA:acetate/butyrate:CoA-transferase [butyrate-acetoacetate CoA-transferase] [EC 2.8.3.9]) of Clostridium acetobutylicum ATCC 824 is an important enzyme in the metabolic shift between the acid-producing and solvent-forming states of this organism. The purification and properties of the enzyme have recently been described (D. P. Weisenborn, F. B. Rudolph, and E. T. Papoutsakis, Appl. Environ. Microbiol. 55:323-329, 1989). The genes encoding the two subunits of this enzyme have been cloned by using synthetic oligodeoxynucleotide probes designed from amino-terminal sequencing data from each subunit of the CoA-transferase. A bacteriophage lambda EMBL3 library of C. acetobutylicum DNA was prepared and screened by using these probes. Subsequent subcloning experiments established the position of the structural genes for CoA-transferase. Complementation of Escherichia coli ato mutants with the recombinant plasmid pCoAT4 (pUC19 carrying a 1.8-kilobase insert of C. acetobutylicum DNA encoding CoA-transferase activity) enabled the transformants to grow on butyrate as a sole carbon source. Despite the ability of CoA-transferase to complement the ato defect in E. coli mutants, Southern blot and Western blot (immunoblot) analyses showed that neither the C. acetobutylicum genes encoding CoA-transferase nor the enzyme itself shared any apparent homology with its E. coli counterpart. Polypeptides of Mr of the purified CoA-transferase subunits were observed by Western blot and maxicell analysis of whole-cell extracts of E. coli harboring pCoAT4. The proximity and orientation of the genes suggest that the genes encoding the two subunits of CoA-transferase may form an operon similar to that found in E. coli.(ABSTRACT TRUNCATED AT 250 WORDS)