Bacterial L-serine dehydratases: a new family of enzymes containing iron-sulfur clusters.

Two families of enzymes are described which catalyse identical chemical reactions but differ in their prosthetic groups and hence in their mechanism of action. One family, the pyridoxal-5'-phosphate (PLP)-dependent L-threonine dehydratases, also use L-serine as substrate. The other, hitherto unrecognized family is the iron-dependent, highly specific bacterial L-serine dehydratases. It has been shown that L-serine dehydratase from the anaerobic bacterium Peptostreptococcus asaccharolyticus contains an iron-sulfur cluster but no PLP. A mechanism for the dehydration of L-serine which is similar, but not identical, to that of the dehydration of citrate catalysed by aconitase is proposed.

Glutaconate CoA-transferase from Acidaminococcus fermentans: the crystal structure reveals homology with other CoA-transferases.

BACKGROUND: Coenzyme A-transferases are a family of enzymes with a diverse substrate specificity and subunit composition. Members of this group of enzymes are found in anaerobic fermenting bacteria, aerobic bacteria and in the mitochondria of humans and other mammals, but so far none have been crystallized. A defect in the human gene encoding succinyl-CoA: 3-oxoacid CoA-transferase causes a metabolic disease which leads to severe ketoacidosis, thus reflecting the importance of this family of enzymes. All CoA-transferases share a common mechanism in which the CoA moiety is transferred from a donor (e.g. acetyl CoA) to an acceptor, (R)-2-hydroxyglutarate, whereby acetate is formed. The transfer has been described by a ping-pong mechanism in which CoA is bound to the active-site residue of the enzyme as a covalent thiol ester intermediate. We describe here the crystal structure of glutaconate CoA-transferase (GCT) from the strictly anaerobic bacterium Acidaminococcus fermentans. This enzyme activates (R)-2-hydroxyglutarate to (R)-2-hydroxyglutaryl-CoA in the pathway of glutamate fermentation. We initiated this project to gain further insight into the function of this enzyme and the structural basis for the characteristics of CoA-transferases. RESULTS: The crystal structure of GCT was solved by multiple isomorphous replacement to 2.55 A resolution. The enzyme is a heterooctamer and its overall arrangement of subunits can be regarded as an (AB)4tetramer obeying 222 symmetry. Both subunits A and B belong to the open alpha/beta-protein class and can be described as a four-layered alpha/alpha/beta/alpha type with a novel composition and connectivity of the secondary structure elements. The core of subunit A consists of seven alpha/beta repeats resulting in an all parallel central beta sheet, against which helices pack from both sides. In contrast, the centre of subunit B is formed by a ninefold mixed beta sheet. In both subunits the helical C terminus is folded back onto the N-terminal domain to form the third layer of helices. CONCLUSIONS: The active site of GCT is located at the interface of subunits A and B and is formed by loops of both subunits. The funnel-shaped opening to the active site has a depth and diameter of about 20 A with the catalytic residue, Glu54 of subunit B, at the bottom. The active-site glutamate residue is stabilized by hydrogen bonds. Despite very low amino acid sequence similarity, subunits A and B reveal a similar overall fold. Large parts of their structures can be spatially superimposed, suggesting that both subunits have evolved from a common ancestor.

Glutamate mutase from Clostridium cochlearium: the structure of a coenzyme B12-dependent enzyme provides new mechanistic insights.

BACKGROUND: Glutamate mutase (Glm) equilibrates (S)-glutamate with (2S,3S)-3-methylaspartate. Catalysis proceeds with the homolytic cleavage of the organometallic bond of the cofactor to yield a 5'-desoxyadenosyl radical. This radical then abstracts a hydrogen atom from the protein-bound substrate to initiate the rearrangement reaction. Glm from Clostridium cochlearium is a heterotetrameric molecule consisting of two sigma and two epsilon polypeptide chains. RESULTS: We have determined the crystal structures of inactive recombinant Glm reconstituted with either cyanocobalamin or methylcobalamin. The molecule shows close similarity to the structure of methylmalonyl CoA mutase (MCM), despite poor sequence similarity between its catalytic epsilon subunit and the corresponding TIM-barrel domain of MCM. Each of the two independent B12 cofactor molecules is associated with a substrate-binding site, which was found to be occupied by a (2S,3S)-tartrate ion. A 1:1 mixture of cofactors with cobalt in oxidation states II and III was observed in both crystal structures of inactive Glm. CONCLUSIONS: The long axial cobalt-nitrogen bond first observed in the structure of MCM appears to result from a contribution of the species without upper ligand. The tight binding of the tartrate ion conforms to the requirements of tight control of the reactive intermediates and suggests how the enzyme might use the substrate-binding energy to initiate cleavage of the cobalt-carbon bond. The cofactor does not appear to have a participating role during the radical rearrangement reaction.

Sodium ion-translocating decarboxylases.

The review is concerned with three Na(+)-dependent biotin-containing decarboxylases, which catalyse the substitution of CO(2) by H(+) with retention of configuration (DeltaG degrees '=-30 kJ/mol): oxaloacetate decarboxylase from enterobacteria, methylmalonyl-CoA decarboxylase from Veillonella parvula and Propiogenium modestum, and glutaconyl-CoA decarboxylase from Acidaminococcus fermentans. The enzymes represent complexes of four functional domains or subunits, a carboxytransferase, a mobile alanine- and proline-rich biotin carrier, a 9-11 membrane-spanning helix-containing Na(+)-dependent carboxybiotin decarboxylase and a membrane anchor. In the first catalytic step the carboxyl group of the substrate is converted to a kinetically activated carboxylate in N-carboxybiotin. After swing-over to the decarboxylase, an electrochemical Na(+) gradient is generated; the free energy of the decarboxylation is used to translocate 1-2 Na(+) from the inside to the outside, whereas the proton comes from the outside. At high [Na(+)], however, the decarboxylases appear to catalyse a mere Na(+)/Na(+) exchange. This finding has implications for the life of P. modestum in sea water, which relies on the synthesis of ATP via Delta(mu)Na(+) generated by decarboxylation. In many sequenced genomes from Bacteria and Archaea homologues of the carboxybiotin decarboxylase from A. fermentans with up to 80% sequence identity have been detected.

Crystal structure of the Acidaminococcus fermentans 2-hydroxyglutaryl-CoA dehydratase component A.

Acidaminococcus fermentans degrades glutamate via the hydroxyglutarate pathway, which involves the syn-elimination of water from (R)-2-hydroxyglutaryl-CoA in a key reaction of the pathway. This anaerobic process is catalyzed by 2-hydroxyglutaryl-CoA dehydratase, an enzyme with two components (A and D) that reversibly associate during reaction cycles. Component A (CompA), a homodimeric protein of 2x27 kDa, contains a single, bridging [4Fe-4S] cluster and uses the hydrolysis of ATP to deliver an electron to the dehydratase component (CompD), where the electron is used catalytically. The structure of the extremely oxygen-sensitive CompA protein was solved by X-ray crystallography to 3 A resolution. The protein was found to be a member of the actin fold family, revealing a similar architecture and nucleotide-binding site. The key differences between CompA and other members of the actin fold family are: (i) the presence of a cluster binding segment, the "cluster helix"; (ii) the [4Fe-4S] cluster; and (iii) the location of the homodimer interface, which involves the bridging cluster. Possible reaction mechanisms are discussed in light of the close structural similarity to members of the actin-fold family and the functional similarity to the nitrogenase Fe- protein.

Use of computer decision support in an antimicrobial stewardship program (ASP).

OBJECTIVE: Document information needs, gaps within the current electronic applications and reports, and workflow interruptions requiring manual information searches that decreased the ability of our antimicrobial stewardship program (ASP) at Intermountain Healthcare (IH) to prospectively audit and provide feedback to clinicians to improve antimicrobial use. METHODS: A framework was used to provide access to patient information contained in the electronic medical record, the enterprise-wide data warehouse, the data-driven alert file and the enterprise-wide encounter file to generate alerts and reports via pagers, emails and through the Centers for Diseases and Control's National Healthcare Surveillance Network. RESULTS: Four new applications were developed and used by ASPs at Intermountain Medical Center (IMC) and Primary Children's Hospital (PCH) based on the design and input from the pharmacists and infectious diseases physicians and the new Center for Diseases Control and Prevention/National Healthcare Safety Network (NHSN) antibiotic utilization specifications. Data from IMC and PCH now show a general decrease in the use of drugs initially targeted by the ASP at both facilities. CONCLUSIONS: To be effective, ASPs need an enormous amount of "timely" information. Members of the ASP at IH report these new applications help them improve antibiotic use by allowing efficient, timely review and effective prioritization of patients receiving antimicrobials in order to optimize patient care.

Unusual dehydrations in anaerobic bacteria: considering ketyls (radical anions) as reactive intermediates in enzymatic reactions.

Dehydratases have been detected in anaerobic bacteria which use 2-, 4- or 5-hydroxyacyl-CoA as substrates and are involved in the removal of hydrogen atoms from the unactivated beta- or gamma-positions. In addition there are bacterial dehydratases acting on 1,2-diols which are substrates lacking any activating group. These enzymes contain either FAD, or flavins + iron-sulfur clusters or coenzyme B12. It has been proposed that the overall dehydrations are actually reductions followed by oxidations or vice versa mediated by these prosthetic groups. Whereas the gamma-hydrogen of 5-hydroxyvaleryl-CoA is activated by a transient two-election alpha, beta-oxidation, the other substrates are proposed to require either a transient one-electron reduction or an oxidation to a ketyl (radical anion).

Coenzyme B12-dependent 2-methyleneglutarate mutase from Clostridium barkeri. Protection by the substrate from inactivation by light.

Partially purified 2-methyleneglutarate mutase from Clostridium barkeri was separated from 3-methylitaconate delta-isomerase by treatment with 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS) followed by FPLC on the anion exchange column Mono Q in the presence of the detergent. When purified in the dark, the active mutase contained a corrinoid, most probably coenzyme B12. The enzyme was inactivated by light at the same wavelength (lambda less than 620 nm) and rate as free coenzyme B12. The rate was not influenced by oxygen or by temperature (0-37 degrees C). Reactivation of up to 50% of the original activity was achieved by incubation with coenzyme B12 and dithiothreitol. The substrates 2-methyleneglutarate (up to 40 mM) or (R)-3-methylitaconate specifically protected the enzyme from inactivation by visible light. This effect was enhanced 3-fold by raising the temperature from 0 degrees C to 37 degrees C. The data indicate that during catalysis, the Co-C bond of the coenzyme is cleaved and cannot be affected any more by light.

Identification of glutamate beta 54 as the covalent-catalytic residue in the active site of glutaconate CoA-transferase from Acidaminococcus fermentans.

In the course of glutamate fermentation by Acidaminococcus fermentans glutaconate coenzyme A-transferase catalyzes the transfer of CoAS- from acetyl-CoA to (R)-2-hydroxyglutarate, forming (R)-2-hydroxyglutaryl-CoA. Glutamate (E) 54 of the beta-subunit was postulated to be directly involved in catalysis by formation of a CoASH ester intermediate [(1994) Eur. J. Biochem., in press]. In order to prove this preliminary result, the following mutations, beta E54A, beta E64A, beta E54Q and beta E54D, were introduced by mismatch oligonucleotide priming. As expected, beta E54A was inactive (0.02% of the wild-type), whereas beta E64A and beta E54D were active, 30% and > 7%, respectively. However, no CoASH intermediate was detected in the latter mutant, indicating a change in the catalytic mechanism. The activity of the beta E54Q mutant increased from 1% to almost 100% upon incubation with acetyl-CoA and glutaconate at 37 degrees C within 40 h. Hence, the substrates induced the conversion of the mutant glutamine residue into the glutamate residue of the wild-type enzyme.

Conversion of glutaconate CoA-transferase from Acidaminococcus fermentans into an acyl-CoA hydrolase by site-directed mutagenesis.

The heterooctameric (alphabeta)4 glutaconate CoA-transferase (EC 2.8.3.12) from the anaerobic bacterium Acidaminococcus fermentans catalyses the transfer of CoASH from acetyl-CoA to the 1-carboxylate of glutaconate. During this reaction the glutamate residue 54 of the beta-subunit (betaE54) forms a CoA-ester. The single amino acid replacement betaE54D resulted in a drastic change of enzymatic function. The CoA-transferase activity decreased from 140 to less than 0.01 s(-1), whereas the acyl-CoA hydrolase activity increased from less than 0.01 to 16 s(-1). The new enzyme was able to catalyse the hydrolysis of glutaryl-CoA, acetyl-CoA and 3-butenoyl-CoA. Since the mutants betaE54A and betaE54N showed neither acyl-CoA hydrolase nor CoA-transferase activity, it was concluded that the aspartate carboxylate of the mutant betaE54D acted as a general base which facilitated the attack of water at the thiolester carbonyl. Surprisingly, Km for glutaryl-CoA hydrolysis by the mutant (0.7 microM) as compared to CoA-transfer by the wild-type (28 microM) was 40 times lower. A 65 kDa protein, obtained by fusing the genes, gctA-gctB, coding for glutaconate CoA-transferase, retained 30% of the wild-type activity. Comparison of the amino acid sequences of 13 related enzymes demonstrated that Nature already has applied gene fusion in the case of pig heart CoA-transferase and has been using the E --> D mutation for catalysis by a yeast acetyl-CoA hydrolase.

Identification of acrylate, the product of the dehydration of (R)-lactate catalysed by cell-free extracts from Clostridium propionicum.

Cell extracts from Clostridium propionicum harvested in the late log-phase catalysed the dehydration of (R)-lactate to acrylate at a maximum rate of 0.06 U/mg protein. The unsaturated acid was identified by high-performance liquid chromatography and as p-bromophenacyl ester by gas chromatography combined with mass spectroscopy. The amount of acrylate formed was dependent on protein and (R)-lactate concentrations. However, due to product inhibition the yield of acrylate did not exceed 0.5%. Like the dehydration of (R)-2-hydroxyglutarate to glutaconate the dehydration of (R)-lactate to acrylate was inhibited by 1 mM hydroxylamine, 1mM azide, 0.1 mM dinitrophenol, 10 mM EDTA or by exposure to air. A radical mechanism is postulated.

A biotin-dependent sodium pump: glutaconyl-CoA decarboxylase from Acidaminococcus fermentans.

The decarboxylation of glutaconyl-CoA to crotonyl-CoA in the anaerobic bacterium Acidaminococcus fermentans is catalysed by a membrane-bound, biotin-dependent enzyme which requires Na+ for activity. Inverted vesicles from A. fermentans accumulated Na+ only if glutaconyl-CoA was decarboxylated. The Na+ uptake was inhibited by avidin but not by the avidin biotin complex. Detergents and ionophores such as monensin also prevented the Na+ transport. The results indicate that the enzyme is able to convert the free energy of decarboxylation (delta Go' approximately equal to -30 kJ/mol) into a Na+ gradient.

On the dehydration of (R)-lactate in the fermentation of alanine to propionate by Clostridium propionicum.

All the enzymes of the pathway of (S)-alanine fermentation to acetate and propionate were detected in cell-free extracts of Clostridium propionicum . Among these (S)-glutamate dehydrogenase (NAD), (R)-lactate dehydrogenase (NAD) and propionate CoA-transferase were purified to apparent homogeneity. Their structures were presumably alpha 6, alpha 2 and alpha 4, respectively. The latter enzyme was specific for short-chain monocarboxylic acids with a pronounced preference for (R)-lactate over the (S)-enantiomer. The key step of the pathway, the dehydration of (R)-lactate required acetyl phosphate and CoASH under anaerobic conditions. It was inhibited by hydroxylamine, arsenate, azide (1 mM each) or by 0.1 mM 2,4-dinitrophenol. Thus it closely resembled the dehydration of (R)-2-hydroxyglutarate in Acidaminococcus fermentans , although an activation was not necessary.

The stereochemistry of the formation of the methyl group in the glutamate mutase-catalysed reaction in Clostridium tetanomorphum.

The adenosylcobalamin-dependent enzyme glutamate mutase from Clostridium tetanomorphum catalyses the reversible rearrangement of (2S)-glutamate to (2S,3S)-3- methylaspartate . In this conversion 6 carbon centers are involved. The stereochemistry of 4 has been elucidated whereas the formation of the methyl group from the methylene group remains to be established. To solve this problem, (2S,3R)- and (2S,3S)-[3,3-2H1,3H]glutamates were prepared via the 2-oxo[3,3-2H2 or 3H] glutarates by incubation with isocitrate dehydrogenase in deuterium oxide or tritiated water. The labelled glutamates were fermented with growing cells of C. tetanomorphum to butyrate and acetate. Butyrate was further degraded to acetate in which methyl group over 90% of the tritium of the starting glutamate was retained. The chirality of the acetates was determined with malate synthase and fumarase. In both samples complete racemisation was found. This result confirms the rule that racemisation occurs in all adenosylcobalamin-dependent rearrangements in which methyl groups are formed. A methylene radical as intermediate could explain these observations. In a control experiment inversion of configuration in the formation of the methine group of (2S,3S)-3-methylaspartate from the methylene group of (2S)-glutamate was confirmed. Glutamates stereospecifically labelled at C-4 were synthesized from chiral acetates via citrate.

Coordination of a histidine residue of the protein-component S to the cobalt atom in coenzyme B12-dependent glutamate mutase from Clostridium cochlearium.

Electron paramagnetic resonance (EPR) spectroscopy of glutamate mutase from Clostridium cochlearium was performed in order to test the idea, that a histidine residue of component S replaces the dimethylbenzimidazole ligand of the Co-atom during binding of coenzyme B12 to the enzyme. The shapes and the superhyperfine splitting of the gz-lines of the Co(II) EPR spectra were used as indicators of the interaction of the axial base nitrogen with the Co-atom. A mixture of completely 15N-labelled component S, unlabelled component E, coenzyme B12 and glutamate gave slightly sharper gz-lines than that with unlabelled component S. A more dramatic change was observed in the Co(II) spectrum of the inactivated enzyme containing tightly bound cob(II)alamin, in which unlabelled component S caused a threefold superhyperfine-splitting of the gz-line, whereas the 15N-labelled protein only caused a twofold splitting, as expected for a direct interaction of a nitrogen of the enzyme with the Co-atom. By using a sample of 15N-labelled component S, in which only the histidines were 14N-labelled, the EPR spectra showed no difference to those with unlabelled component S. The experiments indeed demonstrate a replacement of the dimethylbenzimidazole ligand in coenzyme B12 by a histidine when bound to glutamate mutase. The most likely candidate is H16, which is conserved among the carbon skeleton rearranging mutases and methionine synthase.

Iron-sulfur cluster-containing L-serine dehydratase from Peptostreptococcus asaccharolyticus: correlation of the cluster type with enzymatic activity.

Investigations were performed with regard to the function of the iron-sulfur cluster of L-serine dehydratase from Peptostreptococcus asaccharolyticus, an enzyme which is novel in the class of deaminating hydro-lyases in that it lacks pyridoxal-5'-phosphate. Anaerobically purified L-serine dehydratase from P. asaccharolyticus revealed EPR spectra characteristic of a [3Fe-4S]+ cluster constituting 1% of the total enzyme concentration. Upon incubation of the enzyme under air the intensity of the [3Fe-4S]+ signal increased correlating with the loss of enzymatic activity. Addition of L-serine prevented this. Hence, active L-serine dehydratase probably contains a diamagnetic [4Fe-4S]2+ cluster which is converted by oxidation and loss of one iron ion to a paramagnetic [3Fe-4S]+ cluster, resulting in inactivation of the enzyme. In analogy to the mechanism elucidated for aconitase, it is proposed that L-serine is coordinated via its hydroxyl and carboxyl groups to the labile iron atom of the [4Fe-4S]2+ cluster.

Identification of a paramagnetic species as an early intermediate in the coenzyme B12-dependent glutamate mutase reaction. A cob(II)amide?

Highly active and cobamide-free glutamate mutase was obtained from Clostridium cochlearium by a modification of the original purification procedure. After incubation of the enzyme with dithiothreitol, adenosylcobalamin (coenzyme B12) and the substrate (S)-glutamate, a paramagnetic species was observed by EPR-spectroscopy. The signal was maximal within 15 ms after mixing with glutamate. Different signals were detected after incubating the system with the competitive inhibitors (2S,4S)-4-fluoroglutamate or 2-methyleneglutarate instead of the substrate. The former developed with an at least 100-fold lower rate then the signal with glutamate. All three signals are probably due to low-spin cob(II)amide species with an extraordinary low gxy value as compared with cob(II)alamin.

Identification of the gene encoding the activator of (R)-2-hydroxyglutaryl-CoA dehydratase from Acidaminococcus fermentans by gene expression in Escherichia coli.

(R)-2-Hydroxyglutaryl-CoA dehydratase (HGDA/B) from Acidaminococcus fermentans requires an activator protein for activity. This activator (HGDC) has not yet been purified from its natural source due to its low concentration combined with an extreme sensitivity towards oxygen. Gene expression in Escherichia coli identified an open reading frame (780 bp) as the gene encoding HGDC. Dehydratase activity was stimulated at least tenfold by cell-free extracts of E. coli cells transformed with a plasmid carrying hgdC. On the chromosome the hgdC gene is located just before hgdA and hgdB.

Re-face stereospecificity at C4 of NAD(P) for alcohol dehydrogenase from Methanogenium organophilum and for (R)-2-hydroxyglutarate dehydrogenase from Acidaminococcus fermentans as determined by 1H-NMR spectroscopy.

The two diastereotopic protons at C4 of NAD(P)H are seen separately in 1H-NMR spectra. This fact was used to determine the stereospecificity at C4 of NAD(P) for the NADP-dependent alcohol dehydrogenase from Methanogenium organophilum and for the NAD-dependent (R)-2-hydroxyglutarate dehydrogenase from Acidaminococcus fermentans. The reduction of NADP+ with [2H6]ethanol was found to yield (4R)-[4-2H1]NADPH and the oxidation of (4R)-[4-2H1]NADH with 2-oxoglutarate to yield unlabelled [4-1H]NAD+. These results indicate that both enzymes are Re-face stereospecific at C4 of the pyridine nucleotides.

Carbon-13 labelled biotin--a new probe for the study of enzyme catalyzed carboxylation and decarboxylation reactions.

[2'-13C]Biotin was incorporated into avidin (egg white), glutaconyl-CoA decarboxylase (EC 4.1.1.70) from Acidaminococcus fermentans and the biotin carrier of transcarboxylase from Propionibacterium freudenreichii (EC 2.1.3.1). 13C-NMR measurements showed an upfield shift of the carbonyl carbon of 3.1 and 2.0 ppm for both enzymes, whereas binding to avidin induced no significant change of the chemical shift as compared to free biotin. The data indicate that the enzymes provide an electronic environment for the covalently bound biotin which favours carboxylation. In addition it was demonstrated by NMR-measurements that glutaconyl-CoA decarboxylase, from which the hydrophobic carboxy-lyase subunit (beta) was removed, could carboxylate free biotin.