The Catalytic Mechanism of the Hotdog-fold Enzyme Superfamily 4-Hydroxybenzoyl-CoA Thioesterase from Arthrobacter sp. Strain SU

The hotdog-fold enzyme 4-hydroxybenzoyl-coenzyme A (4-HB-CoA) thioesterase from Arthrobacter sp. strain AU catalyzes the hydrolysis of 4-HB-CoA to form 4-hydroxybenzoate (4-HB) and coenzyme A (CoA) in the final step of the 4-chlorobenzoate dehalogenation pathway. Guided by the published X-ray structures of the liganded enzyme (Thoden, J. B., Zhuang, Z., Dunaway-Mariano, D., and Holden H. M. (2003) J.Biol. Chem. 278, 43709-43716), a series of site-directed mutants were prepared for testing the roles of active site residues in substrate binding and catalysis. The mutant thioesterases were subjected to X-ray structure determination to confirm retention of the native fold, and in some cases, to reveal changes in the active site configuration. In parallel, the wild-type and mutant thioesterases were subjected to transient and steady-state kinetic analysis, and to (18)O-solvent labeling experiments. Evidence is provided that suggests that Glu73 functions in nucleophilic catalysis, that Gly65 and Gln58 contribute to transition-state stabilization via hydrogen bond formation with the thioester moiety and that Thr77 orients the water nucleophile for attack at the 4-hydroxybenzoyl carbon of the enzyme-anhydride intermediate. The replacement of Glu73 with Asp was shown to switch the function of the carboxylate residue from nucleophilic catalysis to base catalysis and thus, the reaction from a two-step process involving a covalent enzyme intermediate to a single-step hydrolysis reaction. The E73D/T77A double mutant regained most of the catalytic efficiency lost in the E73D single mutant. The results from (31)P NMR experiments indicate that the substrate nucleotide unit is bound to the enzyme surface. Kinetic analysis of site-directed mutants was carried out to determine the contributions made by Arg102, Arg150, Ser120, and Thr121 in binding the nucleotide unit. Lastly, we show by kinetic and X-ray analyses of Asp31, His64, and Glu78 site-directed mutants that these three active site residues are important for productive binding of the substrate 4-hydroxybenzoyl ring.     

The BH1999 protein of Bacillus halodurans C-125 is gentisyl-coenzyme A thioesterase

In this study, we have shown that recombinant BH1999 from Bacillus halodurans catalyzes the hydrolysis of gentisyl coenzyme A (CoA) (2,5-dihydroxybenzoyl-coenzyme A) at physiological pH with a k(cat)/K(m) of 1.6 x 10(6) M(-1) s(-1) and the hydrolysis of 3-hydroxybenzoyl-CoA with a k(cat)/K(m) of 3.0 x 10(5) M(-1) s(-1). All other acyl-CoA thioesters tested had low or no substrate activity. The BH1999 gene is juxtaposed with a gene cluster that contains genes believed to function in gentisate oxidative degradation. It is hypothesized that BH1999 functions as a gentisyl-CoA thioesterase. Gentisyl-CoA thioesterase shares the backbone fold and the use of an active site aspartate residue to mediate catalysis with the 4-hydroxybenzoyl-CoA thioesterase of the hotdog fold enzyme superfamily. A comparative study of these two enzymes showed that they differ greatly in the rate contribution made by the catalytic aspartate, in the pH dependence of catalysis, and in substrate specificity.     

Mechanism of 4-chlorobenzoate:coenzyme a ligase catalysis

Within the accompanying paper in this issue (Reger et al. (2008) Biochemistry, 47, 8016-8025) we reported the X-ray structure of 4-chlorobenzoate:CoA ligase (CBL) bound with 4-chlorobenzoyl-adenylate (4-CB-AMP) and the X-ray structure of CBL bound with 4-chlorophenacyl-CoA (4-CP-CoA) (an inert analogue of the product 4-chlorobenzoyl-coenzyme A (4-CB-CoA)) and AMP. These structures defined two CBL conformational states. In conformation 1, CBL is poised to catalyze the adenylation of 4-chlorobenzoate (4-CB) with ATP (partial reaction 1), and in conformation 2, CBL is poised to catalyze the formation of 4-CB-CoA from 4-CB-AMP and CoA (partial reaction 2). These two structures showed that, by switching from conformation 1 to conformation 2, the cap domain rotates about the domain linker and thereby changes its interface with the N-terminal domain. The present work was carried out to determine the contributions made by each of the active site residues in substrate/cofactor binding and catalysis, and also to test the role of domain alternation in catalysis. In this paper, we report the results of steady-state kinetic and transient state kinetic analysis of wild-type CBL and of a series of site-directed CBL active site mutants. The major findings are as follows. First, wild-type CBL is activated by Mg (2+) (a 12-75-fold increase in activity is observed depending on assay conditions) and its kinetic mechanism (ping-pong) supports the structure-derived prediction that PP i dissociation must precede the switch from conformation 1 to conformation 2 and therefore CoA binding. Also, transient kinetic analysis of wild-type CBL identified the rate-limiting step of the catalyzed reaction as one that follows the formation of 4-CB-CoA (viz. CBL conformational change and/or product dissociation). The single turnover rate of 4-CB and ATP to form 4-CB-AMP and PP i ( k = 300 s (-1)) is not affected by the presence of CoA, and it is approximately 3-fold faster than the turnover rate of 4-CB-AMP and CoA to form 4-CB-CoA and AMP ( k = 120 s (-1)). Second, the active site mutants screened via steady-state kinetic analysis were ranked based on the degree of reduction observed in any one of the substrate k cat/ K m values, and those scoring higher than a 50-fold reduction in k cat/ K m value were selected for further evaluation via transient state kinetic analysis. The single-turnover time courses, measured for the first partial reaction, and then for the full reaction, were analyzed to define the microscopic rate constants for the adenylation reaction and the thioesterification reaction. On the basis of our findings we propose a catalytic mechanism that centers on a small group of key residues (some of which serve in more than one role) and that includes several residues that function in domain alternation.     

Enzymic Dehalogenation of 4-Chlorobenzoyl Coenzyme A in Acinetobacter sp. Strain 4-CB1

4-Chlorobenzoate degradation in cell extracts of Acinetobacter sp. strain 4-CB1 occurs by initial synthesis of 4-chlorobenzoyl coenzyme A (4-chlorobenzoyl CoA) from 4-chlorobenzoate, CoA, and ATP. 4-Chlorobenzoyl CoA is dehalogenated to 4-hydroxybenzoyl CoA. Following the dehalogenation reaction, 4-hydroxybenzoyl CoA is hydrolyzed to 4-hydroxybenzoate and CoA. Possible roles for the CoA moiety in the dehalogenation reaction are discussed.     

Benzoyl-coenzyme A thioesterase of Azoarcus evansii: properties and function

The aerobic benzoate metabolism in Azoarcus evansii follows an unusual route. The intermediates of the pathway are processed as coenzyme A (CoA) thioesters and the cleavage of the aromatic ring is non-oxygenolytic. The enzymes of this pathway are encoded by the box gene cluster which harbors a gene, orf1, coding for a putative thioesterase. Benzoyl-CoA thioesterase activity (20 nmol min⁻¹ mg⁻¹ protein) was present in cells grown aerobically on benzoate, but was lacking in cells grown on other aromatic or aliphatic substrates under oxic or anoxic conditions. The gene was cloned and overexpressed in Escherichia coli to produce a C-terminal His-tag fusion protein. The recombinant enzyme was a homotetramer of 16 kDa subunits. It catalyzed not only the hydrolysis of benzoyl-CoA, but also of 2,3-dihydro-2,3-dihydroxybenzoyl-CoA, the second intermediate in the pathway. The enzyme exhibited higher activity with mono-substituted derivatives of benzoyl-CoA, showing highest activity with 4-hydroxybenzoyl-CoA. Di-substituted derivatives of benzoyl-CoA, phenylacetyl-CoA, and aliphatic CoA thioesters were not hydrolyzed but some acted as inhibitors. The thioesterase appears to protect the cell from CoA pool depletion. It may constitute the prototype of a new subfamily within the hotdog fold enzyme superfamily.     

NADPH-dependent reductive ortho dehalogenation of 2,4-dichlorobenzoic acid in Corynebacterium sepedonicum KZ-4 and Coryneform bacterium strainNTB-1 via 2,4-dichlorobenzoyl coenzyme A.

Corynebacterium sepedonicum KZ-4, described earlier as a strain capable of growth on 2,4-dichlorobenzoate (G.M. Zaitsev and Y.N. Karasevich, Mikrobiologiya 54:356-369, 1985), is known to metabolize this substrate via 4-hydroxybenzoate and protocatechuate, and evidence consistent with an initial reductive dechlorination step to form 4-chlorobenzoate was found in another coryneform bacterium, strain NTB-1 (W.J.J. van den Tweel, J.B. Kok, and J.A.M. de Bont, Appl. Environ. Microbiol. 53:810-815, 1987). 2-Chloro-4-fluorobenzoate was found to be converted stoichiometrically to 4-fluorobenzoate by resting cells of strain KZ-4, compatible with a reductive process. Experiments with cell extracts demonstrated that Mg - ATP and coenzyme A (CoA) were required to stimulate reductive dehalogenation, consistent with the intermediacy of 2-chloro-4-fluoro-benzoyl-CoA and 2,4-dichlorobenzoyl-CoA thioesters. 2,4-Dichlorobenzoyl-CoA was shown to be converted to 4-chlorobenzoyl-CoA in a novel NADPH-dependent reaction in extracts of both KZ-4 and NTB-1. In addition to the ligase and reductive dehalogenase activities, hydrolytic 4-chlorobenzoyl-CoA dehalogenase and thioesterase activities, 4-hydroxybenzoate 3-monooxygenase, and protocatechuate 3,4-dioxygenase activities were demonstrated to be present in the soluble fraction of KZ-4 extracts following ultracentrifugation. We propose that the pathway for 2,4-dichlorobenzoate catabolism in strains KZ-4 and NTB-1 involves formation of 2,4-dichlorobenzoyl-CoA, NADPH-dependent ortho dehalogenation yielding 4-chlorobenzoyl-CoA, hydrolytic removal of chlorine from the para position to generate 4-hydroxybenzoyl-CoA, hydrolysis to form 4-hydroxybenzoate, oxidation to yield protocatechuate, and oxidative ring cleavage.     

Identification of genes coding for hydrolytic dehalogenation in the metagenome derived from a denitrifying 4-chlorobenzoate degrading consortium.

A metagenomic approach was taken to investigate the genetic basis for the ability of an anaerobic consortium to grow on either 4-chlorobenzoate or 4-bromobenzoate under denitrifying conditions. Degenerate PCR primers were designed for the family of 4-chlorobenzoyl-CoA dehalogenase genes. The primers were utilized to screen a metagenome library and two overlapping clones were identified which yield a PCR product. The complete sequence of one metagenome clone was determined and genes encoding 4-chlorobenzoyl-CoA ligase (FcbA) and 4-chlorobenzoyl-CoA dehalogenase (FcbB) were identified. Analysis of the ORFs present in the nucleotide sequence suggests that the metagenome clone originated from an uncultured denitrifying microorganism belonging to the Betaproteobacteria. Interestingly, unlike similar gene clusters reported in aerobes, a gene encoding 4-hydroxybenzoyl-CoA thioesterase was not present in the gene cluster. This suggests that 4-hydroxybenzoyl-CoA is further degraded via the anaerobic reduction pathway in the corresponding microorganism instead of through thioester hydrolysis to yield 4-hydroxybenzoate.     

Mechanism of flavin reduction in the alkanesulfonate monooxygenase system

The alkanesulfonate monooxygenase system from Escherichia coli is involved in scavenging sulfur from alkanesulfonates under sulfur starvation. An FMN reductase (SsuE) catalyzes the reduction of FMN by NADPH, and the reduced flavin is transferred to the monooxygenase (SsuD). Rapid reaction kinetic analyses were performed to define the microscopic steps involved in SsuE catalyzed flavin reduction. Results from single-wavelength analyses at 450 and 550 nm showed that reduction of FMN occurs in three distinct phases. Following a possible rapid equilibrium binding of FMN and NADPH to SsuE (MC-1) that occurs before the first detectable step, an initial fast phase (241 s(-1)) corresponds to the interaction of NADPH with FMN (CT-1). The second phase is a slow conversion (11 s(-1)) to form a charge-transfer complex of reduced FMNH(2) with NADP(+) (CT-2), and represents electron transfer from the pyridine nucleotide to the flavin. The third step (19 s(-1)) is the decay of the charge-transfer complex to SsuE with bound products (MC-2) or product release from the CT-2 complex. Results from isotope studies with [(4R)-(2)H]NADPH demonstrates a rate-limiting step in electron transfer from NADPH to FMN, and may imply a partial rate-limiting step from CT-2 to MC-2 or the direct release of products from CT-2. While the utilization of flavin as a substrate by the alkanesulfonate monooxygenase system is novel, the mechanism for flavin reduction follows an analogous reaction path as standard flavoproteins.     

Reductive dehydroxylation of 4-hydroxybenzoyl-CoA to benzoyl-CoA in a denitrifying, phenol-degrading Pseudomonas species

The initial reactions in anaerobic degradation of phenol to CO2 have been studied in vitro with a denitrifying Pseudomonas strain grown with phenol and nitrate in the absence of molecular oxygen. Phenol has been proposed to be carboxylated to 4-hydroxybenzoate [(1987) Arch. Microbiol. 148, 213-217]. 4-Hydroxybenzoate was activated to 4-hydroxybenzoyl-CoA by a coenzyme A ligase. Cell extracts also catalyzed the reductive dehydroxylation of 4-hydroxybenzoyl-CoA to benzoyl-CoA with reduced benzyl viologen as electron donor. This enzyme, benzoyl-CoA:(acceptor) 4-oxidoreductase (hydroxylating) (EC 1.3.99.-), has not been reported before. The data suggest that phenol and 4-hydroxybenzoate are anaerobically metabolized by this strain via benzoyl-CoA.     

Involvement of coenzyme A thioesters in anaerobic metabolism of 4-hydroxybenzoate by Rhodopseudomonas palustris.

The initial steps of anaerobic 4-hydroxybenzoate degradation were studied in whole cells and cell extracts of the photosynthetic bacterium Rhodopseudomonas palustris. Illuminated suspensions of cells that had been grown anaerobically on 4-hydroxybenzoate and were assayed under anaerobic conditions took up [U-14C]4-hydroxybenzoate at a rate of 0.6 nmol min-1 mg of protein-1. Uptake occurred with high affinity (apparent Km = 0.3 microM), was energy dependent, and was insensitive to external pH in the range of 6.5 to 8.2 Very little free 4-hydroxybenzoate was found associated with cells, but a range of intracellular products was formed after 20-s incubations of whole cells with labeled substrate. When anaerobic pulse-chase experiments were carried out with cells incubated on ice or in darkness, 4-hydroxybenzoyl coenzyme A (4-hydroxybenzoyl-CoA) was formed early and disappeared immediately after addition of excess unlabeled substrate, as would be expected of an early intermediate in 4-hydroxybenzoate metabolism. A 4-hydroxybenzoate-CoA ligase activity with an average specific activity of 0.7 nmol min-1 mg of protein-1 was measured in the soluble protein fraction of cells grown anaerobically on 4-hydroxybenzoate. 4-Hydroxybenzoyl-CoA was the sole product formed from labeled 4-hydroxybenzoate in the ligase reaction mixture. 4-Hydroxybenzoate uptake and ligase activities were present in cells grown anaerobically with benzoate, 4-hydroxybenzoate, and 4-aminobenzoate and were not detected in succinate-grown cells. These results indicate that the high-affinity uptake of 4-hydroxybenzoate by R. palustris is due to rapid conversion of the free acid to its CoA derivative by a CoA ligase and that this is also the initial step of anaerobic 4-hydroxybenzoate degradation.     

Human immunodeficiency virus-1 protease. 2. Use of pH rate studies and solvent kinetic isotope effects to elucidate details of chemical mechanism

The pH dependence of the peptidolytic reaction of recombinant human immunodeficiency virus type 1 protease has been examined over a pH range of 3-7 for four oligopeptide substrates and two competitive inhibitors. The pK values obtained from the pKis vs pH profiles for the unprotonated and protonated active-site aspartyl groups, Asp-25 and Asp-25', in the monoprotonated enzyme form were 3.1 and 5.2, respectively. Profiles of log V/K vs pH for all four substrates were "bell-shaped" in which the pK values for the unprotonated and protonated aspartyl residues were 3.4-3.7 and 5.5-6.5, respectively. Profiles of log V vs pH for these substrates were "wave-shaped" in which V was shifted to a constant lower value upon protonation of a residue of pK = 4.2-5.2. These results indicate that substrates bind only to a form of HIV-1 protease in which one of the two catalytic aspartyl residues is protonated. Solvent kinetic isotope effects were measured over a pH (D) range of 3-7 for two oligopeptide substrates, Ac-Arg-Ala-Ser-Gln-Asn-Tyr-Pro-Val-Val-NH2 and Ac-Ser-Gln-Asn-Tyr-Pro-Val-Val-NH2. The pH-independent value for DV/K was 1.0 for both substrates, and DV = 1.5-1.7 and 2.2-3.2 at low and high pH (D), respectively. The attentuation of both V and DV at low pH (D) is consistent with a change in rate-limiting step from a chemical one at high pH (D) to one in which a product release step or an enzyme isomerization step becomes partly rate-limiting at low pH (D). Proton inventory data is in accord with the concerted transfer of two protons in the transition state of a rate-limiting chemical step in which the enzyme-bound amide hydrate adduct collapses to form the carboxylic acid and amine products.     

The structure of 4-hydroxybenzoyl-CoA thioesterase from arthrobacter sp. strain SU

The 4-chlorobenzoyl-CoA dehalogenation pathway in certain Arthrobacter and Pseudomonas bacterial species contains three enzymes: a ligase, a dehalogenase, and a thioesterase. Here we describe the high resolution x-ray crystallographic structure of the 4-hydroxybenzoyl-CoA thioesterase from Arthrobacter sp. strain SU. The tetrameric enzyme is a dimer of dimers with each subunit adopting the so-called "hot dog fold" composed of six strands of anti-parallel beta-sheet flanked on one side by a rather long alpha-helix. The dimers come together to form the tetramer with their alpha-helices facing outwards. This quaternary structure is in sharp contrast to that previously observed for the 4-hydroxybenzoyl-CoA thioesterase from Pseudomonas species strain CBS-3, whereby the dimers forming the tetramer pack with their alpha-helices projecting toward the interfacial region. In the Arthrobacter thioesterase, each of the four active sites is formed by three of the subunits of the tetramer. On the basis of both structural and kinetic data, it appears that Glu73 is the active site base in the Arthrobacter thioesterase. Remarkably, this residue is located on the opposite side of the substrate-binding pocket compared with that observed for the Pseudomonas enzyme. Although these two bacterial thioesterases demonstrate equivalent catalytic efficiencies, substrate specificities, and metabolic functions, their quaternary structures, CoA-binding sites, and catalytic platforms are decidedly different.     

Properties of the thioesterase component obtained by limited trypsinization of the fatty acid synthetase multienzyme complex.

The fatty acid synthetase from lactating rat mammary gland is shown to consist of two polyfunctional polypeptides of similar molecular weight (about 220,000); a 4'-phosphopantetheine residue is covalently bound to one, or both subunits. Limited trypsinization of the fatty acid synthetase releases on enzymatically active thioesterase component which has been purified and its properties studied. The thioesterase sediments in the ultracentrifuge as a single component of molecular weight 32,000; its sedimentation coefficient is 2.9 x 10-(13) s its diffusion coefficient 5.0 x 10-(7) cm2 s-(1). The thioesterase also elutes from a column of Sephadex G-75 as a single, symmetrical peak of constant specific activity. However, electrophoresis of the denatured thioesterase in the presence of sodium dodecyl sulfate reveals that the enzyme has been partially nicked during isolation. The kinetic data of the enzyme reaction were studied using palmityl-CoA as a model substrate. Solvent pH was found to affect both Vmax and Km (Km = 0.5 micron at pH 6.6, 2.5 micron at pH 8.0) wereas solvent ionic strength affected Vmax but no Km. The thioesterases from the fatty acid synthetases of rat liver and lactating mammary gland have identical physical properties, identical amino acid compositions, and are immunologically indistinguishable. Both thioesterases hydrolyze long chain, in preference to short chain, thioesters of CoA, an observation consistent with their role in regulation of the chain-terminating step in fatty acid synthesis by the parent multienzyme complexes.     

Metabolism of cyclohexane carboxylic acid by the photosynthetic bacteriumRhodopseudomonas palustris

Cyclohexane carboxylate supported relatively rapid growth (doubling times 7–8 h) of Rhodopseudomonas palustris under oxic or photosynthetic conditions, but did not serve as a substrate for either of the known aromatic CoA ligases. A CoA ligase that thioesterifies cyclohexane carboxylate was partially purified and did not cross react immunologically with the two CoA ligases purified previously from this bacterium. Crude extracts of R. palustris cells grown with a range of aromatic or alicyclic acids contained a dehydrogenase that reacted with cyclohexane carboxyl-CoA or cyclohex-1-ene carboxyl-CoA, using 2,6-dichlorophenolindophenol or ferricenium ion as electron carrier. This activity was not detected in extracts of adipate-, glutamate-, or succinate-grown cells. No oxidation or reduction of nonesterified cyclohexane carboxylate or cyclohexene carbocylate was detected in extracts of cells grown with aromatic or aliphatic substrates, neither aerobically nor anaerobically. A constitutively expressed thioesterase that hydrolyzed cyclohexane carboxyl-CoA and also some alicyclic and aliphatic CoA derivatives was purified and characterized. The enzyme had little or no activity on benzoyl-CoA or 4-hydroxybenzoyl-CoA. The presence of a thioesterase that effectively hydrolyzes cyclohexane carboxyl-CoA suggests that transient production of cyclohexane carboxylate is a physiological response to temporary excess of reductant during metabolism of aromatic compounds. Received: 22 May 1995 / Accepted: 13 September 1995     

Kinetic and mechanistic analysis of the malonyl CoA:ACP transacylase from Streptomyces coelicolor indicates a single catalytically competent serine nucleophile at the active site

The source of malonyl groups for polyketide and fatty acid biosynthesis is malonyl CoA. During fatty acid and polyketide biosynthesis, malonyl groups are normally transferred to the acyl carrier protein (ACP) component of the synthase by a malonyl CoA:holo-ACP transacylase (MCAT) enzyme. The fatty acid synthase (FAS) malonyl CoA:ACP transacylase from Streptomyces coelicolor was expressed in Escherichia coli as a hexahistidine-tagged (His(6)) fusion protein in high yield. The His(6)-MCAT was purified to homogeneity using standard techniques, and kinetic analysis of the malonylation of S. coelicolorFAS holo-ACP, catalyzed by His(6)-MCAT, gave K(infinity) (M) values of 73 (ACP) and 60 microM (malonyl CoA). A catalytic constant k (infinity) (M) of 450 s(-1) and specificity constants k (infinity) (M)/K (infinity) (M) of 6.2 (ACP) and 7.5 microM(-1) s(-1) (malonyl CoA) were measured. Malonyl transfer to the E. coli FAS holo-ACP, catalyzed by His(6)-MCAT, was less efficient (k (infinity) (M)/K (infinity) (M) was 10% of that of the S. coelicolor ACP). Incubation of MCAT with the serine specific agent PMSF caused inhibition of malonyl transfer to FAS ACPs, and an S97A MCAT mutant was incapable of catalyzing malonyl transfer. Our results show that in the reaction with FAS holo-ACPs the S. coelicolor MCAT is very similar to the E. coli MCAT paradigm in terms of its kinetic mechanism and active site residues. These results indicate that no other active site nucleophile is involved in catalysis as has been suggested to explain recently reported observations.     

Dehalogenation of 4-chlorobenzoate

Pseudomonas sp. CBS3 is capable of growing with 4-chlorobenzoate as sole source of carbon and energy. The removal of the chlorine of 4-chlorobenzoate is performed in the first degradation step by an enzyme system consisting of three proteins. A 4-halobenzoate-coenzyme A ligase activates 4-chlorobenzoate in a coenzyme A, ATP and Mg²⁺ dependent reaction to 4-chlorobenzoyl-coenzyme A. This thioester intermediate is dehalogenated by the 4-chlorobenzoyl-coenzyme A dehalogenase. Finally coenzyme A is split off by a 4-hydroxybenzoyl-CoA thioesterase to form 4-hydroxybenzoate. The involved 4-chlorobenzoyl-coenzyme A dehalogenase was purified to apparent homogeneity by a five-step purification procedure. The native enzyme had an apparent molecular mass of 120,000 and was composed of four identical polypeptide subunits of 31 kDa. The enzyme displayed an isoelectric point of 6.7. The maximal initial rate of catalysis was achieved at pH 10 at 60 °C. The apparent K _m value for 4-chlorobenzoyl-coenzyme A was 2.4–2.7 µM. V _max was 1.1 × 10^–7 M sec^–1 (2.2 µmol min^–1 mg^–1 of protein). The NH₂-terminal amino acid sequence was determined. All 4-halobenzoyl-coenzyme A thioesters, except 4-fluorobenzoyl-coenzyme A, were dehalogenated by the 4-chlorobenzoyl-CoA dehalogenase.Abbreviations CBA chlorobenzoate - CoA coenzyme A - HBA hydroxybenzoate - DTT dithiothreitol - HPLC high performance liquid chromatography - PAGE polyacrylamide gel electrophoresis     

Anaerobic degradation of phenol via carboxylation to 4-hydroxybenzoate: in vitro study of isotope exchange between 14CO2 and 4-hydroxybenzoate

Extracts of denitrifying bacteria grown anaerobically with phenol and nitrate catalyzed an isotope exchange between ¹⁴CO₂ and the carboxyl group of 4-hydroxybenzoate. This exchange reaction is ascribed to a novel enzyme, phenol carboxylase, initiating the anaerobic degradation of phenol by para-carboxylation to 4-hydroxybenzoate. Some properties of this enzyme were determined by studying the isotope exchange reaction. Phenol carboxylase was rapidly inactivated by oxygen; strictly anoxic conditions were essential for preserving enzyme activity. The exchange reaction specifically was catalyzed with 4-hydroxybenzoate but not with other aromatic acids. Only the carboxyl group was exchanged; [U-¹⁴C]phenol was not exchanged with the aromatic ring of 4-hydroxybenzoate. Exchange activity depended on Mn²⁺ and inorganic phosphate and was not inhibited by avidin. Ortho-phosphate could not be substituted by organic phosphates nor by inorganic anions; arsenate had no effect. The pH optimum was between pH 6.5–7.0. The specific activity was 100 nmol ¹⁴CO₂ exchange · min^-1 · mg^-1 protein. Phenol grown cells contained 4-hydroxybenzoyl CoA synthetase activity (40 nmol · min^-1 · mg^-1 protein). The possible role of phenol carboxylase and 4-hydroxybenzoyl CoA synthetase in anaerobic phenol metabolism is discussed.     

The serine acetyltransferase reaction: acetyl transfer from an acylpantothenyl donor to an alcohol

Serine acetyltransferase is a member of the left-handed parallel beta-helix family of enzymes that catalyzes the committed step in the de novo synthesis of l-cysteine in bacteria and plants. The enzyme has an ordered kinetic mechanism with acetyl CoA bound prior to l-serine and O-acetyl-l-serine released prior to CoA. The rate-limiting step along the reaction pathway is the nucleophilic attack of the serine hydroxyl on the thioester of acetyl CoA. Product release contributes to rate-limitation at saturating concentrations of reactants. The reaction is catalyzed by an active site general base with a pK of 7, which accepts a proton from the serine hydroxyl as a tetrahedral intermediate is formed between the reactants, and donates it to the thiol of CoA as the intermediate collapses to give products. This mechanism is likely the same for all O-acyltransferases that catalyze their reaction by direct attack of the alcohol on the acyl donor, using an active-site histidine as the general base. Serine acetyltransferase is regulated by feedback inhibition by the end product l-cysteine, which acts by binding to the serine site in the active site and inducing a conformational change that prevents reactant binding. The enzyme also associates with O-acetylserine sulfhydrylase, the final enzyme in the biosynthetic pathway, which contributes to stabilizing the acetyltransferase.     

Transient-state kinetic analysis of Saccharomyces cerevisiae myristoylCoA:protein N-myristoyltransferase reveals that a step after chemical transformation is rate limiting

MyristoylCoA:protein N-myristoyltransferase is a member of the superfamily of GCN5-related N-acetyltransferases and catalyzes the covalent attachment of myristate to the N-terminal Gly residue of proteins with diverse functions. Saccharomyces cerevisiae Nmt1p is a monomeric protein with an ordered bi-bi reaction mechanism: myristoylCoA is bound prior to peptide substrate; after catalysis, CoA is released followed by myristoylpeptide. Analysis of the X-ray structure of Nmt1p with bound substrate analogues indicates that the active site contains an oxyanion hole and a catalytic base and that catalysis proceeds through the nucleophilic addition-elimination mechanism. To determine the rate-limiting step in the enzyme reaction, pre-steady-state kinetic analyses were performed using a new, sensitive nonradioactive assay that detects CoA. Multiple turnover quenched flow studies disclosed that a step after the chemical transformation limits the overall rate of the reaction. Multiple and single turnover analyses revealed that the rate for the chemical transformation step is 13.8+/-0.6 s(-1) while the slower steady-state phase is 0.10+/-0.01 s(-1). Stopped flow kinetic studies of substrate acquisition indicated that binding of myristoylCoA to the apo-enzyme occurs through at least a two-step process, with a fast phase rate of 3.2 x 10(8) M(-1) s(-1) and a slow phase rate of 23+/-2 s(-1) (defined at 5 degrees C). Binding of an octapeptide substrate, representing the N-terminal sequence of a known yeast N-myristoylprotein (Cnb1p), to a binary complex composed of Nmt1p and a nonhydrolyzable myristoylCoA analogue (S-(2-oxo)pentadecylCoA) has a second-order rate constant of 2.1+/-0.3 x 10(6) M(-1) s(-1) and a dissociation rate of 26+/-15 s(-1) (defined at 10 degrees C). These results are interpreted in light of the X-ray structures of this enzyme.     

Mechanistic studies with 2-C-methyl-D-erythritol 4-phosphate synthase from Escherichia coli

The mechanism of the reaction catalyzed by 2-C-methyl-d-erythritol 4-phosphate (MEP) synthase from Escherichia coli has been studied by steady-state and single-turnover kinetic experiments for the 1-deoxy-d-xylulose 5-phosphoric acid (DXP) analogues, 1,1,1-trifluoro-1-deoxy-d-xylulose 5-phosphoric acid (CF(3)-DXP), 1,1-difluoro-1-deoxy-d-xylulose 5-phosphoric acid (CF(2)-DXP), 1-fluoro-1-deoxy-d-xylulose 5-phosphoric acid (CF-DXP), and 1,2-dideoxy-d-hexulose 6-phosphate (Et-DXP). CF(3)-DXP, CF(2)-DXP, and Et-DXP were poor inhibitors, most likely because of the increase in steric bulk at C1 of DXP. The three analogues were also poor substrates for the enzyme. In contrast, CF-DXP was a good substrate (k(cat)(CF)(-)(DXP) = 37 +/- 2 s(-)(1), K(m)(CF)(-)(DXP) = 227 +/- 25 microM) for MEP synthase when compared to DXP (k(cat)(DXP) = 29 +/- 1 s(-)(1), K(m)(DXP) = 45 +/- 4 microM). A primary deuterium isotope effect was observed under single-turnover conditions when CF-DXP was incubated with 4S-[(2)H]NADPH ((H)k/(D)k = 1.34 +/-0.01), whereas no isotope effect was observed upon incubation with DXP and 4S-[(2)H]NADPH ((H)k/(D)k = 1.02 +/- 0.02). The reaction did not exhibit burst kinetics for either substrate, indicating that product release is not rate-limiting. These studies suggest that positive charge does not develop at C2 of DXP during catalysis. In addition, the isotope effect with CF-DXP and 4S-[(2)H]NADPH but not DXP indicates that the rearrangement step, which precedes hydride transfer, is rate-limiting for DXP but becomes partially rate-limiting for CF-DXP. Thus, rearrangement appears to be enhanced by substitution of a hydrogen atom in the methyl group of DXP by fluorine. These observations are consistent with a retro-aldol/aldol mechanism for the rearrangement during conversion of DXP to MEP.