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.

2-Methylisocitrate lyases from the bacterium Escherichia coli and the filamentous fungus Aspergillus nidulans: characterization and comparison of both enzymes.

In Escherichia coli and Aspergillus nidulans, propionate is oxidized to pyruvate via the methylcitrate cycle. The last step of this cycle, the cleavage of 2-methylisocitrate to succinate and pyruvate is catalysed by 2-methylisocitrate lyase. The enzymes from both organisms were assayed with chemically synthesized threo-2-methylisocitrate; the erythro-diastereomer was not active. 2-Methylisocitrate lyase from E. coli corresponds to the PrpB protein of the prp operon involved in propionate oxidation. The purified enzyme has a molecular mass of approximately 32 kDa per subunit, which is lower than those of isocitrate lyases from bacterial sources ( approximately 48 kDa). 2-Methylisocitrate lyase from A. nidulans shows an apparent molecular mass of 66 kDa per subunit, almost equal to that of isocitrate lyase of the same organism. Both 2-methylisocitrate lyases have a native homotetrameric structure as identified by size-exclusion chromatography. The enzymes show no measurable activity with isocitrate. Starting from 250 mM pyruvate, 150 mM succinate and 10 microM PrpB, the enzymatically active stereoisomer could be synthesized in 1% yield. As revealed by chiral HPLC, the product consisted of a single enantiomer. This isomer is cleaved by 2-methylisocitrate lyases from A. nidulans and E. coli. The PrpB protein reacted with stoichiometric amounts of 3-bromopyruvate whereby the activity was lost and one amino-acid residue per subunit became modified, most likely a cysteine as shown for isocitrate lyase of E. coli. PrpB exhibits 34% sequence identity with carboxyphosphoenolpyruvate phosphonomutase from Streptomyces hygroscopicus, in which the essential cysteine residue is conserved.

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.

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.

Unusual enzymes involved in five pathways of glutamate fermentation.

Anaerobic bacteria from the orders Clostridiales and Fusobacteriales are able to ferment glutamate by at least five different pathways, most of which contain enzymes with radicals in their catalytic pathways. The first two pathways proceed to ammonia, acetate and pyruvate via the coenzyme B12-dependent glutamate mutase, which catalyses the re-arrangement of the linear carbon skeleton to that of the branched-chain amino acid (2S,3S)-3-methylaspartate. Pyruvate then disproportionates either to CO2 and butyrate or to CO2, acetate and propionate. In the third pathway, glutamate again is converted to ammonia, CO2, acetate and butyrate. The key intermediate is (R)-2-hydroxyglutaryl-CoA, which is dehydrated to glutaconyl-CoA, followed by decarboxylation to crotonyl-CoA. The unusual dehydratase, containing an iron-sulfur cluster, is activated by an ATP-dependent one-electron reduction. The remaining two pathways require more then one organism for the complete catabolism of glutamate to short chain fatty acids. Decarboxylation of glutamate leads to 4-aminobutyrate, which is fermented by a second organism via the fourth pathway to acetate and butyrate, again mediated by an unusual dehydratase which catalyses the reversible dehydration of 4-hydroxybutyryl-CoA to crotonyl-CoA. The fifth pathway is the only one without decarboxylation, since the gamma-carboxylate of glutamate is reduced to the amino group of delta-aminovalerate, which then is fermented to acetate, propionate and valerate. The pathway involves the oxidative dehydration of 5-hydroxyvaleryl-CoA to 2,4-pentadienoyl-CoA followed by reduction to 3-pentenoyl-CoA and isomerisation to 2-pentenoyl-CoA.

The iron-sulfur clusters in 2-hydroxyglutaryl-CoA dehydratase from Acidaminococcus fermentans. Biochemical and spectroscopic investigations.

The reversible dehydration of (R)-2-hydroxyglutaryl-CoA to (E)-glutaconyl-CoA is catalysed by the combined action of two oxygen-sensitive enzymes from Acidaminococcus fermentans, the homodimeric component A (2 x 27 kDa) and the heterodimeric component D (45 and 50 kDa). Component A was purified to homogeneity (specific activity 25-30 s-1) using streptavidin-tag affinity chromatography. In the presence of 5 mM MgCl2 and 1 mM ADP or ATP, component A could be stabilized and stored for 4-5 days at 4 degrees C without loss of activity. The purification of component D from A. fermentans was also improved as indicated by the 1.5-fold higher specific activity (15 s-1). The content of 1.0 riboflavin 5'-phosphate (FMN) per heterodimer could be confirmed, whereas in contrast to an earlier report only trace amounts of riboflavin (< 0.1) could be detected. Each active component contains an oxygen sensitive diamagnetic [4Fe-4S]2+ cluster as revealed by UV-visible, EPR and Mössbauer spectroscopy. Reduction of the [4Fe-4S]2+ cluster in component A with dithionite yields a paramagnetic [4Fe-4S]1+ cluster with the unusual electron spin ground state S = 3/2 as indicated by strong absorption type EPR signals at high g values, g = 4-6. Spin-Hamiltonian simulations of the EPR spectra and of magnetic Mössbauer spectra were performed to determine the zero field splitting (ZFS) parameters of the cluster and the 57Fe hyperfine interaction parameters. The electronic properties of the [4Fe-4S]2+, 1+ clusters of component A are similar to those of the nitrogenase iron protein in which a [4Fe-4S]2+ cluster bridges the two subunits of the homodimeric protein. Under air component A looses its activity within seconds due to irreversible degradation of its [4Fe-4S]2+ cluster to a [2Fe-2S]2+ cluster. The [4Fe-4S]2+ cluster of component D could not be reduced to a [4Fe-4S]1+ cluster, even with excess of Ti(III)citrate or dithionite. Exposure to oxic conditions slowly converts the diamagnetic [4Fe-4S]2+ cluster of component D to a paramagnetic [3Fe-4S]+ cluster concomitant with loss of activity (30% within 24 h at 4 degrees C).

Fermentation of 4-aminobutyrate by Clostridium aminobutyricum: cloning of two genes involved in the formation and dehydration of 4-hydroxybutyryl-CoA.

Clostridium aminobutyricum ferments 4-aminobutyrate via succinic semialdehyde, 4-hydroxybutyrate, 4-hydroxybutyryl-CoA and crotonyl-CoA to acetate and butyrate. The genes coding for the enzymes that catalyse the interconversion of these intermediates are arranged in the order abfD (4-hydroxybutyryl-CoA dehydratase), abfT (4-hydroxybutyrate CoA-transferase), and abfH (NAD-dependent 4-hydroxybutyrate dehydrogenase). The genes abfD and abfT were cloned, sequenced and expressed as active enzymes in Escherichia coli. Hence the insertion of the [4Fe-4S]clusters and FAD into the dehydratase required no additional specific protein from C. aminobutyricum. The amino acid sequences of the dehydratase and the CoA-transferase revealed close relationships to proteins deduced from the genomes of Clostridium difficile, Porphyromonas gingivalis and Archaeoglobus fulgidus. In addition the N-terminal part of the dehydratase is related to those of a family of FAD-containing mono-oxygenases from bacteria. The putative assignment in the databank of Cat2 (OrfZ) from Clostridium kluyveri as 4-hydroxybutyrate CoA-transferase, which is thought to be involved in the reductive pathway from succinate to butyrate, was confirmed by sequence comparison with AbfT (57% identity). Furthermore, an acetyl-CoA:4-hydroxybutyrate CoA-transferase activity could be detected in cell-free extracts of C. kluyveri. In contrast to glutaconate CoA-transferase from Acidaminococcus fermentans, mutation studies suggested that the glutamate residue of the motive EXG, which is conserved in many homologues of AbfT, does not form a CoA-ester during catalysis.

Native corrinoids from Clostridium cochlearium are adeninylcobamides: spectroscopic analysis and identification of pseudovitamin B(12) and factor A.

The corrinoids from the obligate anaerobe Clostridium cochlearium were extracted as a mixture of Co(beta)-cyano derivatives. From 50 g of frozen cells, approximately 2 mg (1.5 micromol) of B(12) derivatives was obtained as a crystalline sample. Analysis of the corrinoid sample of C. cochlearium by a combination of high-pressure liquid chromatography and UV-Vis absorbance spectroscopy revealed the presence of three cyano corrinoids in a ratio of about 3:1:1. The spectroscopic data acquired for the sample indicated the main components to be pseudovitamin B(12) (Co(beta)-cyano-7"-adeninylcobamide) (60%) and factor A (Co(beta)-cyano-7"-[2-methyl]adeninylcobamide) (20%). Authentic pseudovitamin B(12) was prepared by guided biosynthesis from cobinamide and adenine. Both pseudovitamin B(12) and its homologue, factor A, were subjected to complete spectroscopic analysis by UV-Vis, circular dichroism, mass spectrometry, and by one- and two-dimensional (1)H, (13)C-, and (15)N nuclear magnetic resonance (NMR) spectroscopy. The third component was indicated by the mass spectra to be an isomer of factor A and is likely (according to NMR) to be 7"-[N(6)-methyl]-adeninylcobamide, a previously unknown corrinoid. C. cochlearium thus biosynthesizes as its native "complete" B(12) cofactors the 7"-adeninylcobamides and two homologous corrinoids, in which the nucleotide base is a methylated adenine.

The involvement of coenzyme A esters in the dehydration of (R)-phenyllactate to (E)-cinnamate by Clostridium sporogenes.

Phenyllactate dehydratase from Clostridium sporogenes grown anaerobically on L-phenylalanine catalyses the reversible syn-dehydration of (R)-phenyllactate to (E)-cinnamate. Purification yielded a heterotrimeric enzyme complex (130 +/- 15 kDa) composed of FldA (46 kDa), FldB (43 kDa) and FldC (40 kDa). By re-chromatography on Q-Sepharose, the major part of FldA could be separated and identified as oxygen insensitive cinnamoyl-CoA:phenyllactate CoA-transferase, whereas the transferase depleted trimeric complex retained oxygen sensitive phenyllactate dehydratase activity and contained about one [4Fe-4S] cluster. The dehydratase activity required 10 microM FAD, 0.4 mM ATP, 2.5 mM MgCl2, 0.1 mM NADH, 5 microM cinnamoyl-CoA and small amounts of cell-free extract (10 microg protein per mL) similar to that known for 2-hydroxyglutaryl-CoA dehydratase from Acidaminococcus fermentans. The N-terminus of the homogenous FldA (39 amino acids) is homologous to that of CaiB (39% sequence identity) involved in carnitine metabolism in Escherichia coli. Both enzymes are members of an emerging group of CoA-transferases which exhibit high substrate specificity but apparently do not form enzyme CoA-ester intermediates. It is concluded that dehydration of (R)-phenyllactate to (E)-cinnamate proceeds in two steps, a CoA-transfer from cinnamoyl-CoA to phenyllactate, catalysed by FldA, followed by the dehydration of phenyllactyl-CoA, catalysed by FldB and FldC, whereby the noncovalently bound prosthetic group cinnamoyl-CoA is regenerated. This demonstrates the necessity of a 2-hydroxyacyl-CoA intermediate in the dehydration of 2-hydroxyacids. The transient CoA-ester formation during the dehydration of phenyllactate resembles that during citrate cleavage catalysed by bacterial citrate lyase, which contain a derivative of acetyl-CoA covalently bound to an acyl-carrier-protein (ACP).

Methylcitrate synthase from Aspergillus nidulans: implications for propionate as an antifungal agent.

Aspergillus nidulans was used as a model organism to investigate the fungal propionate metabolism and the mechanism of growth inhibition by propionate. The fungus is able to grow slowly on propionate as sole carbon and energy source. Propionate is oxidized to pyruvate via the methylcitrate cycle. The key enzyme methylcitrate synthase was purified and the corresponding gene mcsA, which contains two introns, was cloned, sequenced and overexpressed in A. nidulans. The derived amino acid sequence of the enzyme shows more than 50% identity to those of most eukaryotic citrate synthases, but only 14% identity to the sequence of the recently detected bacterial methylcitrate synthase from Escherichia coli. A mcsA deletion strain was unable to grow on propionate. The inhibitory growth effect of propionate on glucose medium was enhanced in this strain, which led to the assumption that trapping of the available CoA as propionyl-CoA and/or the accumulating propionyl-CoA itself interferes with other biosynthetic pathways such as fatty acid and polyketide syntheses. In the wild-type strain, however, the predominant inhibitor may be methylcitrate. Propionate (100 mM) not only impaired hyphal growth of A. nidulans but also synthesis of the green polyketide-derived pigment of the conidia, whereas in the mutant pigmentation was abolished with 20 mM propionate.

Sensitivity and specificity of free and total glutaric acid and 3-hydroxyglutaric acid measurements by stable-isotope dilution assays for the diagnosis of glutaric aciduria type I.

Glutaric aciduria type I (GA I) is a recessive disorder caused by a deficiency of glutaryl-CoA dehydrogenase (GCDH). The biochemical hallmark of the disease is the accumulation of glutaric acid and, to a lesser degree, of 3-hydroxyglutaric acid and glutaconic acid in body fluids and tissues. A substantial number of patients show only slightly, intermittently elevated or even normal urinary excretion of glutaric acid, which makes early diagnosis and treatment to prevent the severe neurological sequelae difficult. Furthermore, elevated urinary excretion of glutaric acid can also be found in a number of other disease states, mostly related to mitochondrial dysfunction. Stable-isotope dilution assays were designed for both glutaric acid and 3-hydroxyglutaric acid and their diagnostic sensitivity and specificity were evaluated. Control ranges of glutaric acid in urine were 1.1-9.7 mmol/mol creatinine before and 4.1-32 after hydrolysis. The respective values of 3-hydroxyglutaric acid were 1.4-8.0 and 2.6-11.7 mmol/mol creatnine. For other body fluids, control ranges in mumol/l/L were: for glutaric acid 0.55-2.9 (plasma), 0.18-0.63 (cerebrospinal fluid) and 0.19-0.7 (amniotic fluid); and for 3-hydroxyglutaric acid, 0.2-1.36 (plasma), < 0.2 (cerebrospinal fluid) and 0.22-0.41 (amniotic fluid). Twenty-five patients with GCDH deficiency were studied. Low excretors (12 patients) were defined by a urinary glutaric acid below 100 mmol/mol creatinine down into the normal range, while high excretors (13 patients) had glutaric acid excretions well above this value. With and without hydrolysis there was an overlap of glutaric acid values between patients and controls. Diagnostic sensitivity and specificity of 100% could only be achieved by the quantitative determination of 3-hydroxyglutaric acid with the newly developed stable-isotope dilution assay, allowing an accurate diagnosis of all patients, regardless of the amount of glutaric acid excreted in urine.

2-hydroxyglutaryl-CoA dehydratase from Clostridium symbiosum.

Component D (HgdAB) of 2-hydroxyglutaryl-CoA dehydratase from Clostridium symbiosum was purified to homogeneity. It is able to use component A from Acidaminococcus fermentans (HgdC) to initiate catalysis together with ATP, Mg2+ and a strong reducing agent such as Ti(III)citrate. Component D from C. symbiosum has a 6 x higher specific activity compared with that from A. fermentans and contains a second [4Fe-4S] cluster but the same amount of riboflavin 5'-phosphate (1.0 per heterodimeric enzyme, m = 100 kDa). Mössbauer spectroscopy revealed symmetric cube-type structures of the two [4Fe-4S]2+ clusters. EPR spectroscopy showed the resistance of the clusters to reducing agents, but detected a sharp signal at g = 2. 004 probably due to a stabilized flavin semiquinone. Three genes from C. symbiosum coding for components D (hgdA and hgdB) and A (hgdC) were cloned and sequenced. Primer extension experiments indicated that the genes are transcribed in the order hgdCAB from an operon only half the size of that from A. fermentans. Sequence comparisons detected a close relationship to the dehydratase system from A. fermentans and HgdA from Fusobacterium nucleatum, as well as to putative proteins of unknown function from Archaeoglobus fulgidus. Lower, but significant, identities were found with putative enzymes from several methanogenic Archaea and Escherichia coli, as well as with the mechanistically related benzoyl-CoA reductases from the Proteobacteria Rhodopseudomonas palustris and Thauera aromatica.

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.

Structure and dynamics of the B12-binding subunit of glutamate mutase from Clostridium cochlearium.

Glutamate mutase (Glm) is an adenosylcobamide-dependent enzyme that catalyzes the reversible rearrangement of (2S)-glutamate to (2S, 3S)-3-methylaspartate. The active enzyme from Clostridium cochlearium consists of two subunits (of 53.6 and 14.8 kDa) as an alpha2beta2 tetramer, whose assembly is mediated by coenzyme B12. The smaller of the protein components, GlmS, has been suggested to be the B12-binding subunit. Here we report the solution structure of GlmS, determined from a heteronuclear NMR-study, and the analysis of important dynamical aspects of this apoenzyme subunit. The global fold and dynamic behavior of GlmS in solution are similar to those of the corresponding subunit MutS from C. tetanomorphum, which has previously been investigated using NMR-spectroscopy. Both solution structures of the two Glm B12-binding subunits share striking similarities with that determined by crystallography for the B12-binding domain of methylmalonyl CoA mutase (Mcm) from Propionibacterium shermanii, which is B12 bound. In the crystal structure a conserved histidine residue was found to be coordinated to cobalt, displacing the endogenous axial ligand of the cobamide. However, in GlmS and MutS the sequence motif, Asp-x-His-x-x-Gly, which includes the cobalt-coordinating histidine residue, and a predicted alpha-helical region following the motif, are present as an unstructured and highly mobile loop. In the absence of coenzyme, the B12-binding site apparently is only partially formed. By comparing the crystal structure of Mcm with the solution structures of B12-free GlmS and MutS, a consistent picture on the mechanism of B12 binding has been obtained. Important elements of the binding site only become structured upon binding B12; these include the cobalt-coordinating histidine residue, and an alpha helix that forms one side of the cleft accommodating the nucleotide 'tail' of the coenzyme.

Oxygen exchange between acetate and the catalytic glutamate residue in glutaconate CoA-transferase from Acidaminococcus fermentans. Implications for the mechanism of CoA-ester hydrolysis.

The exchange of oxygen atoms between acetate, glutaryl-CoA, and the catalytic glutamate residue in glutaconate CoA-transferase from Acidaminococcus fermentans was analyzed using [(18)O(2)]acetate together with matrix-assisted laser desorption/ionization time of flight mass spectrometry of an appropriate undecapeptide. The exchange reaction was shown to be site-specific, reversible, and required both glutaryl-CoA and [(18)O(2)]acetate. The observed exchange is in agreement with the formation of a mixed anhydride intermediate between the enzyme and acetate. In contrast, with a mutant enzyme, which was converted to a thiol ester hydrolyase by replacement of the catalytic glutamate residue by aspartate, no (18)O uptake from H(2)(18)O into the carboxylate was detectable. This result is in accord with a mechanism in which the carboxylate of aspartate acts as a general base in activating a water molecule for hydrolysis of the thiol ester intermediate. This mechanism is further supported by the finding of a significant hydrolyase activity of the wild-type enzyme using acetyl-CoA as substrate, whereas glutaryl-CoA is not hydrolyzed. The small acetate molecule in the substrate binding pocket may activate a water molecule for hydrolysis of the nearby enzyme-CoA thiol ester.

The sodium ion translocating glutaconyl-CoA decarboxylase from Acidaminococcus fermentans: cloning and function of the genes forming a second operon.

Glutaconyl-CoA decarboxylase from Acidaminococcus fermentans (clostridal cluster IX), a strict anaerobic inhabitant of animal intestines, uses the free energy of decarboxylation (delta G(o) approximately -30 kJ mol-1) in order to translocate Na+ from the inside through the cytoplasmic membrane. The proton, which is required for decarboxylation, most probably comes from the outside. The enzyme consists of four different subunits. The largest subunit, alpha or GcdA (65 kDa), catalyses the transfer of CO2 from glutaconyl-CoA to biotin covalently attached to the gamma-subunit, GcdC. The beta-subunit, GcdB, is responsible for the decarboxylation of carboxybiotin, which drives the Na+ translocation (approximate K(m) for Na+ 1 mM), whereas the function of the smallest subunit, delta or GcdD, is unclear. The gene gcdA is part of the 'hydroxyglutarate operon', which does not contain genes coding for the other three subunits. This paper describes that the genes, gcdDCB, are transcribed in this order from a distinct operon. The delta-subunit (GcdD, 12 kDa), with one potential transmembrane helix, probably serves as an anchor for GcdA. The biotin carrier (GcdC, 14 kDa) contains a flexible stretch of 50 amino acid residues (A26-A75), which consists of 34 alanines, 14 prolines, one valine and one lysine. The beta-subunit (GcdB, 39 kDa) comprising 11 putative transmembrane helices shares high amino acid sequence identities with corresponding deduced gene products from Veillonella parvula (80%, clostridial cluster IX), Archaeoglobus fulgidus (61%, Euryarchaeota), Propionigenium modestum (60%, clostridial cluster XIX), Salmonella typhimurium (51%, enterobacteria) and Klebsiella pneumoniae (50%, enterobacteria). Directly upstream of the promoter region of the gcdDCB operon, the 3' end of gctM was detected. It encodes a protein fragment with 73% sequence identity to the C-terminus of the alpha-subunit of methylmalonyl-CoA decarboxylase from V. parvula (MmdA). Hence, it appears that A. fermentans should be able to synthesize this enzyme by expression of gctM together with gdcDCB, but methylmalonyl-CoA decarboxylase activity could not be detected in cell-free extracts. Earlier observations of a second, lower affinity binding site for Na+ of glutaconyl-CoA decarboxylase (apparent K(m) 30 mM) were confirmed by identification of the cysteine residue 243 of GcdB between the putative hellces VII and VIII, which could be specifically protected from alkylation by Na+. The alpha-subunit was purified from an overproducing Escherichia coli strain and was characterized as a putative homotrimer able to catalyse the carboxylation of free biotin.

Crystallization and preliminary X-ray analysis of recombinant glutamate mutase and of the isolated component S from Clostridium cochlearium.

Glutamate mutase [varepsilon2sigma2(B12)1] was reconstituted by incubating purified components E (varepsilon2) and S (sigma2) from Clostridium cochlearium, both produced in Escherichia coli, with either aquo- or cyanocobalamin. The inactive glutamate mutase obtained was crystallized with polyethyleneglycol 4000 as precipitant. Crystals are monoclinic with space group P21 and have cell dimensions a = 64.6, b = 113.2, c = 108.4 A and beta = 96.0 degrees for the glutamate mutase reconstituted with aquocobalamin. They diffract to a resolution of at least 2.7 A. Isolated component S was crystallized in the presence of an excess of cyanocobalamin, yielding red crystals of space group I422 with unit-cell dimensions of a = b = 69.9 and c = 107.1 A. The crystals diffract to about 3.2 A resolution. Native data sets were collected for both crystal forms.

Identification of the 4-glutamyl radical as an intermediate in the carbon skeleton rearrangement catalyzed by coenzyme B12-dependent glutamate mutase from Clostridium cochlearium.

A series of 2H- and 13C-labeled glutamates were used as substrates for coenzyme B12-dependent glutamate mutase, which equilibrates (S)-glutamate with (2S,3S)-3-methylaspartate. These compounds contained the isotopes at C-2, C-3, or C-4 of the carbon chain: [2-2H], [3,3-2H2], [4,4-2H2], [2,3,3,4,4-2H5], [2-13C], [3-13C], and [4-13C]glutamate. Each reaction was monitored by electron paramagnetic resonance (EPR) spectroscopy and revealed a similar signal characterized by g'xy = 2.1, g'z = 1.985, and A' = 5.0 mT. The interpretation of the spectral data was aided by simulations which gave close agreement with experiment. This approach underpinned the idea of the formation of a radical pair, consisting of cob(II)alamin interacting with an organic radical at a distance of 6.6 +/- 0.9 A. Comparison of the hyperfine couplings observed with unlabeled glutamate with those from the labeled glutamates enabled a principal contributor to the radical pair to be identified as the 4-glutamyl radical. These findings support the currently accepted mechanism for the glutamate mutase reaction, i.e., the process is initiated through hydrogen atom abstraction from C-4 of glutamate by the 5'-deoxyadenosyl radical, which is derived by homolysis of the Co-C sigma-bond of coenzyme B12.

Propionate oxidation in Escherichia coli: evidence for operation of a methylcitrate cycle in bacteria.

Escherichia coli grew in a minimal medium on propionate as the sole carbon and energy source. Initially a lag phase of 4-7 days was observed. Cells adapted to propionate still required 1-2 days before growth commenced. Incorporation of (2-13C), (3-13C) or (2H3)propionate into alanine revealed by NMR that propionate was oxidized to pyruvate without randomisation of the carbon skeleton and excluded pathways in which the methyl group was transiently converted to a methylene group. Extracts of propionate-grown cells contained a specific enzyme that catalyses the condensation of propionyl-CoA with oxaloacetate, most probably to methylcitrate. The enzyme was purified and identified as the already-known citrate synthase II. By 2-D gel electrophoresis, the formation of a second propionate-specific enzyme with sequence similarities to isocitrate lyases was detected. The genes of both enzymes were located in a putative operon with high identities (at least 76% on the protein level) with the very recently discovered prp operon from Salmonella typhimurium. The results indicate that E. coli oxidises propionate to pyruvate via the methylcitrate cycle known from yeast. The 13C patterns of aspartate and glutamate are consistent with the further oxidation of pyruvate to acetyl-CoA. Oxaloacetate is predominantly generated via the glyoxylate cycle rather than by carboxylation of phosphoenolpyruvate.