Sequence of the sodium ion pump methylmalonyl-CoA decarboxylase from Veillonella parvula

Mechanisms of Energy Transduction by Charge Translocating Membrane Proteins

Life relies on the constant exchange of different forms of energy, i.e., on energy transduction. Therefore, organisms have evolved in a way to be able to harvest the energy made available by external sources (such as light or chemical compounds) and convert these into biological useable energy forms, such as the transmembrane difference of electrochemical potential (Δμ̃). Membrane proteins contribute to the establishment of Δμ̃ by coupling exergonic catalytic reactions to the translocation of charges (electrons/ions) across the membrane. Irrespectively of the energy source and consequent type of reaction, all charge-translocating proteins follow two molecular coupling mechanisms: direct- or indirect-coupling, depending on whether the translocated charge is involved in the driving reaction. In this review, we explore these two coupling mechanisms by thoroughly examining the different types of charge-translocating membrane proteins. For each protein, we analyze the respective reaction thermodynamics, electron transfer/catalytic processes, charge-translocating pathways, and ion/substrate stoichiometries.

Molecular and Low-Resolution Structural Characterization of the Na+-Translocating Glutaconyl-CoA Decarboxylase From Clostridium symbiosum

Some anaerobic bacteria use biotin-dependent Na⁺-translocating decarboxylases (Bdc) of β-keto acids or their thioester analogs as key enzymes in their energy metabolism. Glutaconyl-CoA decarboxylase (Gcd), a member of this protein family, drives the endergonic translocation of Na⁺ across the membrane with the exergonic decarboxylation of glutaconyl-CoA (ΔG⁰’ ≈−30 kJ/mol) to crotonyl-CoA. Here, we report on the molecular characterization of Gcd from Clostridium symbiosum based on native PAGE, size exclusion chromatography (SEC) and laser-induced liquid bead ion desorption mass spectrometry (LILBID-MS). The obtained molecular mass of ca. 400 kDa fits to the DNA sequence-derived mass of 379 kDa with a subunit composition of 4 GcdA (65 kDa), 2 GcdB (35 kDa), GcdC1 (15 kDa), GcdC2 (14 kDa), and 2 GcdD (10 kDa). Low-resolution structural information was achieved from preliminary electron microscopic (EM) measurements, which resulted in a 3D reconstruction model based on negative-stained particles. The Gcd structure is built up of a membrane-spanning base primarily composed of the GcdB dimer and a solvent-exposed head with the GcdA tetramer as major component. Both globular parts are bridged by a linker presumably built up of segments of GcdC1, GcdC2 and the 2 GcdDs. The structure of the highly mobile Gcd complex represents a template for the global architecture of the Bdc family.

Phylogenetic distribution of three pathways for propionate production within the human gut microbiota

Propionate is produced in the human large intestine by microbial fermentation and may help maintain human health. We have examined the distribution of three different pathways used by bacteria for propionate formation using genomic and metagenomic analysis of the human gut microbiota and by designing degenerate primer sets for the detection of diagnostic genes for these pathways. Degenerate primers for the acrylate pathway (detecting the lcdA gene, encoding lactoyl-CoA dehydratase) together with metagenomic mining revealed that this pathway is restricted to only a few human colonic species within the Lachnospiraceae and Negativicutes. The operation of this pathway for lactate utilisation in Coprococcus catus (Lachnospiraceae) was confirmed using stable isotope labelling. The propanediol pathway that processes deoxy sugars such as fucose and rhamnose was more abundant within the Lachnospiraceae (based on the pduP gene, which encodes propionaldehyde dehydrogenase), occurring in relatives of Ruminococcus obeum and in Roseburia inulinivorans. The dominant source of propionate from hexose sugars, however, was concluded to be the succinate pathway, as indicated by the widespread distribution of the mmdA gene that encodes methylmalonyl-CoA decarboxylase in the Bacteroidetes and in many Negativicutes. In general, the capacity to produce propionate or butyrate from hexose sugars resided in different species, although two species of Lachnospiraceae (C. catus and R. inulinivorans) are now known to be able to switch from butyrate to propionate production on different substrates. A better understanding of the microbial ecology of short-chain fatty acid formation may allow modulation of propionate formation by the human gut microbiota.

Ex situ formation of metal selenide quantum dots using bacterially derived selenide precursors

Luminescent quantum dots were synthesized using bacterially derived selenide (Se(II-)) as the precursor. Biogenic Se(II-) was produced by the reduction of Se(IV) by Veillonella atypica and compared directly against borohydride-reduced Se(IV) for the production of glutathione-stabilized CdSe and β-mercaptoethanol-stabilized ZnSe nanoparticles by aqueous synthesis. Biological Se(II-) formed smaller, narrower size distributed QDs under the same conditions. The growth kinetics of biologically sourced CdSe phases were slower. The proteins isolated from filter sterilized biogenic Se(II-) included a methylmalonyl-CoA decarboxylase previously characterized in the closely related Veillonella parvula. XAS analysis of the glutathione-capped CdSe at the S K-edge suggested that sulfur from the glutathione was structurally incorporated within the CdSe. A novel synchrotron based XAS technique was also developed to follow the nucleation of biological and inorganic selenide phases, and showed that biogenic Se(II-) is more stable and more resistant to beam-induced oxidative damage than its inorganic counterpart. The bacterial production of quantum dot precursors offers an alternative, 'green' synthesis technique that negates the requirement of expensive, toxic chemicals and suggests a possible link to the exploitation of selenium contaminated waste streams.

Decarboxylation mechanisms in biological system

This review examines the mechanisms propelling cofactor-independent, organic cofactor-dependent and metal-dependent decarboxylase chemistry. Decarboxylation, the removal of carbon dioxide from organic acids, is a fundamentally important reaction in biology. Numerous decarboxylase enzymes serve as key components of aerobic and anaerobic carbohydrate metabolism and amino acid conversion. In the past decade, our knowledge of the mechanisms enabling these crucial decarboxylase reactions has continued to expand and inspire. This review focuses on the organic cofactors biotin, flavin, NAD, pyridoxal 5'-phosphate, pyruvoyl, and thiamin pyrophosphate as catalytic centers. Significant attention is also placed on the metal-dependent decarboxylase mechanisms.

ATP synthesis by decarboxylation phosphorylation

Adenosine triphosphate (ATP) is used as a general energy source by all living cells. The free energy released by hydrolyzing its terminal phosphoric acid anhydride bond to yield ADP and phosphate is utilized to drive various energy-consuming reactions. The ubiquitous F(1)F(0) ATP synthase produces the majority of ATP by converting the energy stored in a transmembrane electrochemical gradient of H(+) or Na(+) into mechanical rotation. While the mechanism of ATP synthesis by the ATP synthase itself is universal, diverse biological reactions are used by different cells to energize the membrane. Oxidative phosphorylation in mitochondria or aerobic bacteria and photophosphorylation in plants are well-known processes. Less familiar are fermentation reactions performed by anaerobic bacteria, wherein the free energy of the decarboxylation of certain metabolites is converted into an electrochemical gradient of Na(+) ions across the membrane (decarboxylation phosphorylation). This chapter will focus on the latter mechanism, presenting an updated survey on the Na(+)-translocating decarboxylases from various organisms. In the second part, we provide a detailed description of the F(1)F(0) ATP synthases with special emphasis on the Na(+)-translocating variant of these enzymes.

Oxaloacetate decarboxylase of Archaeoglobus fulgidus: cloning of genes and expression in Escherichia coli

Archaeoglobus fulgidus harbors three consecutive and one distantly located gene with similarity to the oxaloacetate decarboxylase Na+ pump of Klebsiella pneumoniae (KpOadGAB). The water-soluble carboxyl transferase (AfOadA) and the biotin protein (AfOadC) were readily synthesized in Escherichia coli, but the membrane-bound subunits AfOadB and AfOadG were not. AfOadA was affinity purified from inclusion bodies after refolding and AfOadC was affinity purified from the cytosol. Isolated AfOadA catalyzed the carboxyl transfer from [4-14C]-oxaloacetate to the prosthetic biotin group of AfOadC or the corresponding biotin domain of KpOadA. Conversely, the carboxyl transferase domain of KpOadA exhibited catalytic activity not only with its pertinent biotin domain but also withAfOadC.

Characterization of a bifunctional archaeal acyl coenzyme A carboxylase

Acyl coenzyme A carboxylase (acyl-CoA carboxylase) was purified from Acidianus brierleyi. The purified enzyme showed a unique subunit structure (three subunits with apparent molecular masses of 62, 59, and 20 kDa) and a molecular mass of approximately 540 kDa, indicating an alpha(4)beta(4)gamma(4) subunit structure. The optimum temperature for the enzyme was 60 to 70 degrees C, and the optimum pH was around 6.4 to 6.9. Interestingly, the purified enzyme also had propionyl-CoA carboxylase activity. The apparent K(m) for acetyl-CoA was 0.17 +/- 0.03 mM, with a V(max) of 43.3 +/- 2.8 U mg(-1), and the K(m) for propionyl-CoA was 0.10 +/- 0.008 mM, with a V(max) of 40.8 +/- 1.0 U mg(-1). This result showed that A. brierleyi acyl-CoA carboxylase is a bifunctional enzyme in the modified 3-hydroxypropionate cycle. Both enzymatic activities were inhibited by malonyl-CoA, methymalonyl-CoA, succinyl-CoA, or CoA but not by palmitoyl-CoA. The gene encoding acyl-CoA carboxylase was cloned and characterized. Homology searches of the deduced amino acid sequences of the 62-, 59-, and 20-kDa subunits indicated the presence of functional domains for carboxyltransferase, biotin carboxylase, and biotin carboxyl carrier protein, respectively. Amino acid sequence alignment of acetyl-CoA carboxylases revealed that archaeal acyl-CoA carboxylases are closer to those of Bacteria than to those of Eucarya. The substrate-binding motifs of the enzymes are highly conserved among the three domains. The ATP-binding residues were found in the biotin carboxylase subunit, whereas the conserved biotin-binding site was located on the biotin carboxyl carrier protein. The acyl-CoA-binding site and the carboxybiotin-binding site were found in the carboxyltransferase subunit.

Sodium ion cycle in bacterial pathogens: evidence from cross-genome comparisons

Analysis of the bacterial genome sequences shows that many human and animal pathogens encode primary membrane Na+ pumps, Na+-transporting dicarboxylate decarboxylases or Na+ translocating NADH:ubiquinone oxidoreductase, and a number of Na+ -dependent permeases. This indicates that these bacteria can utilize Na+ as a coupling ion instead of or in addition to the H+ cycle. This capability to use a Na+ cycle might be an important virulence factor for such pathogens as Vibrio cholerae, Neisseria meningitidis, Salmonella enterica serovar Typhi, and Yersinia pestis. In Treponema pallidum, Chlamydia trachomatis, and Chlamydia pneumoniae, the Na+ gradient may well be the only energy source for secondary transport. A survey of preliminary genome sequences of Porphyromonas gingivalis, Actinobacillus actinomycetemcomitans, and Treponema denticola indicates that these oral pathogens also rely on the Na+ cycle for at least part of their energy metabolism. The possible roles of the Na+ cycling in the energy metabolism and pathogenicity of these organisms are reviewed. The recent discovery of an effective natural antibiotic, korormicin, targeted against the Na+ -translocating NADH:ubiquinone oxidoreductase, suggests a potential use of Na+ pumps as drug targets and/or vaccine candidates. The antimicrobial potential of other inhibitors of the Na+ cycle, such as monensin, Li+ and Ag+ ions, and amiloride derivatives, is discussed.

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.

Coupling mechanism of the oxaloacetate decarboxylase Na(+) pump

The oxaloacetate decarboxylase Na(+) pump consists of subunits alpha, beta and gamma, and contains biotin as the prosthetic group. The peripheral alpha subunit catalyzes the carboxyltransfer from oxaloacetate to the prosthetic biotin group to yield the carboxybiotin enzyme. Subsequently, this is decarboxylated in a Na(+)-dependent reaction by the membrane-bound beta subunit. The decarboxylation is coupled to Na(+) translocation from the cytoplasm into the periplasm, and consumes a periplasmically derived proton. The gamma subunit contains a Zn(2+) metal ion which may be involved in the carboxyltransfer reaction. It is proposed to insert with its N-terminal alpha-helix into the membrane and to form a complex with the alpha subunit with its water-soluble C-terminal domain. The beta subunit consists of nine transmembrane alpha-helices, a segment (IIIa) which inserts from the periplasm into the membrane but does not penetrate it, and connecting hydrophilic loops. The most highly conserved regions of the molecule are segment IIIa and transmembrane helix VIII. Functionally important residues are D203 (segment IIIa), Y229 (helix IV) and N373, G377, S382 and R389 (helix VIII). The polar of these amino acids may constitute a network of ionizable groups which promotes the translocation of Na(+) and the oppositely oriented translocation of H(+) across the membrane. Evidence indicates that two Na(+) ions are bound simultaneously to subunit beta with D203 and S382 acting as binding sites. Sodium ion binding from the cytoplasm to both sites elicits decarboxylation of carboxybiotin possibly with the consumption of the proton extracted from S382 and delivered via Y229 to the carboxylated prosthetic group. A conformational change exposes the bound Na(+) ions toward the periplasm. With H(+) entering from the periplasm, the hydroxyl group of S382 is regenerated, and as a consequence, the Na(+) ions are released into this compartment. After switching back to the original conformation, Na(+) pumping continues.

Identification of tuftelin- and amelogenin-interacting proteins using the yeast two-hybrid system

Biomineralization of enamel is a complex process that involves the eventual replacement of an extracellular protein matrix by hydroxyapatite crystallites. To date four different enamel matrix proteins have been identified; the amelogenins, tuftelin, enamelin and ameloblastin. Assembly of the enamel extracellular matrix from these component proteins is believed to be critical in producing a matrix competent to undergo mineral replacement. Enamel formation is a complex process and additional proteins are likely to have a role in the assembly of the extracellular matrix. In order to identify additional proteins involved in the assembly process, the yeast two-hybrid system developed by Fields and Song (1989) has been implemented. This system allows for the identification of unknown proteins that interact with proteins of interest. Typically a known protein is used as "bait" to screen a cDNA expression library of interest. In our studies, tuftelin or amelogenin have been used to screen a mouse tooth library produced from one day old pups. A library screening of six million clones with amelogenin as bait resulted in eleven positive clones all of which show high homology to the human leukocyte antigen-B (HLA-B) associated transcript (BAT) family of genes. A library screening of one million clones using tuftelin as the bait identified twenty-one tuftelin-interacting proteins. Ten of these proteins are either keratin K5 or keratin K6, four are constitutively expressed and the remaining seven are novel. Further characterization of the proteins shown to interact with amelogenin or tuftelin may shed additional light on this complex process of enamel matrix assembly.

Molecular cloning and characterization of two genes for the biotin carboxylase and carboxyltransferase subunits of acetyl coenzyme A carboxylase in Myxococcus xanthus

We have cloned a DNA fragment from a genomic library of Myxococcus xanthus using an oligonucleotide probe representing conserved regions of biotin carboxylase subunits of acetyl coenzyme A (acetyl-CoA) carboxylases. The fragment contained two open reading frames (ORF1 and ORF2), designated the accB and accA genes, capable of encoding a 538-amino-acid protein of 58.1 kDa and a 573-amino-acid protein of 61.5 kDa, respectively. The protein (AccA) encoded by the accA gene was strikingly similar to biotin carboxylase subunits of acetyl-CoA and propionyl-CoA carboxylases and of pyruvate carboxylase. The putative motifs for ATP binding, CO(2) fixation, and biotin binding were found in AccA. The accB gene was located upstream of the accA gene, and they formed a two-gene operon. The protein (AccB) encoded by the accB gene showed high degrees of sequence similarity with carboxyltransferase subunits of acetyl-CoA and propionyl-CoA carboxylases and of methylmalonyl-CoA decarboxylase. Carboxybiotin-binding and acyl-CoA-binding domains, which are conserved in several carboxyltransferase subunits of acyl-CoA carboxylases, were found in AccB. An accA disruption mutant showed a reduced growth rate and reduced acetyl-CoA carboxylase activity compared with the wild-type strain. Western blot analysis indicated that the product of the accA gene was a biotinylated protein that was expressed during the exponential growth phase. Based on these results, we propose that this M. xanthus acetyl-CoA carboxylase consists of two subunits, which are encoded by the accB and accA genes, and occupies a position between prokaryotic and eukaryotic acetyl-CoA carboxylases in terms of evolution.

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 characterization of the non-biotin-containing subunit of 3-methylcrotonyl-CoA carboxylase

The biotin enzyme, 3-methylcrotonyl-CoA carboxylase (MCCase) (3-methylcrotonyl-CoA:carbon-dioxide ligase (ADP-forming), EC 6.4.1. 4), catalyzes a pivotal reaction required for both leucine catabolism and isoprenoid metabolism. MCCase is a heteromeric enzyme composed of biotin-containing (MCC-A) and non-biotin-containing (MCC-B) subunits. Although the sequence of the MCC-A subunit was previously determined, the primary structure of the MCC-B subunit is unknown. Based upon sequences of biotin enzymes that use substrates structurally related to 3-methylcrotonyl-CoA, we isolated the MCC-B cDNA and gene of Arabidopsis. Antibodies directed against the bacterially produced recombinant protein encoded by the MCC-B cDNA react solely with the MCC-B subunit of the purified MCCase and inhibit MCCase activity. The primary structure of the MCC-B subunit shows the highest similarity to carboxyltransferase domains of biotin enzymes that use methyl-branched thiol esters as substrate or products. The single copy MCC-B gene of Arabidopsis is interrupted by nine introns. MCC-A and MCC-B mRNAs accumulate in all cell types and organs, with the highest accumulation occurring in rapidly growing and metabolically active tissues. In addition, these two mRNAs accumulate coordinately in an approximately equal molar ratio, and they each account for between 0.01 and 0.1 mol % of cellular mRNA. The sequence of the Arabidopsis MCC-B gene has enabled the identification of animal paralogous MCC-B cDNAs and genes, which may have an impact on the molecular understanding of the lethal inherited metabolic disorder methylcrotonylglyciuria.

Cloning and characterization of a gene, mpsA, encoding a protein associated with intracellular magnetic particles from Magnetospirillum sp. strain AMB-1

Proteins located within the lipid bilayer, surrounding the intracellular bacterial magnetic particles (BMP) from Magnetospirillum sp. AMB-1, were separated using SDS-PAGE. Several major proteins of approximate molecular weight 66.2, 35.6, and 24.8 kDa were identified. The N-terminal amino acid sequence of one of these proteins, designated MpsA, was determined and used to design a pair of PCR primers which amplified a 105 bp DNA fragment from AMB-1 genomic DNA. Gene-walking, using anchored PCR, was used to determine the complete nucleotide sequence (954 bp) of the mpsA gene. The mpsA encodes a 317 amino acid protein which does not have an N-terminal cytoplasmic transport signal sequence. Intracellular localization studies were carried out using an mpsA-luc gene fusion expressed in AMB-1 following gene transfer by conjugation. The gene fusion was constructed by cloning a 1.6 kb mpsA fragment upstream of luc in the conjugal plasmid pKLC. The MpsA-Luc fusion protein was preferentially located on the magnetic particle membrane. Although the function of MpsA remains unknown, homology searches suggest similarity with the alpha subunit of acetyl-CoA carboxylase and the CoA-binding motif.

Molecular mechanism of magnet formation in bacteria

Magnetic bacteria have an ability to synthesize intracellular ferromagnetic crystalline particles consisting of magnetite (Fe3O4) or greigite (Fe3S4) which occur within a specific size range (50-100 nm). Bacterial magnetic particles (BMPs) can be distinguished by the regular morphology and the presence of an thin organic membrane enveloping crystals from abiologically formed magnetite. The particle is the smallest magnetic crystal that has a regular morphology within the single domain size. Therefore, BMPs have an unfathomable amount of potential value for various technological applications not only scientific interests. However, the molecular and genetic mechanism of magnetite biomineralization is hardly understood although iron oxide formation occurs widely in many higher animals as well as microorganisms. In order to elucidate the molecular and genetic mechanisms of magnetite biomineralization, a magnetic bacterium Magnetospirillum sp. AMB-1, for which gene transfer and transposon mutagenesis techniques had been recently developed, has been used as a model organism. Several findings and information on the BMPs formation process have been obtained within this decade by means of studies with this model organism and its related one. Biomineralization mechanism and potential availability in biotechnology of bacterial magnets have been elucidated through molecular and genetic approach.

Bioremediation of Heavy Metal Pollution Exploiting Constituents, Metabolites and Metabolic Pathways of Livings. A Review

Removal of heavy metals from the soil and water or their remediation from the waste streams "at source" has been a long-term challenge. During the recent era of environmental protection, the use of microorganisms for the recovery of metals from waste streams as well as employment of plants for landfill applications has generated growing attention. Many studies have demonstrated that both prokaryotes and eukaryotes have the ability to remove metals from contaminated water or waste streams. They sequester metals from soils and sediments or solubilize them to aid their extraction. The proposed microbial processes for bioremediation of toxic metals and radionuclides from waste streams employ living cells and non-living biomass or biopolymers as biosorbents. Microbial biotransformation of metals or metalloids results in an alteration of their oxidation state or in their alkylation and subsequent precipitation or volatilization. Specific metabolic pathways leading to precipitation of heavy metals as metal sulfides, phosphates or carbonates possess significance for possible biotechnology application. Moreover, the possibility of altering the properties of living species used in heavy metal remediation or constructing chimeric organisms possessing desirable features using genetic engineering is now under study in many laboratories. The encouraging evidence as to the usefulness of living organisms and their constituents as well as metabolic pathways for the remediation of metal contamination is reviewed here. A review with 243 references.

The KdpF subunit is part of the K(+)-translocating Kdp complex of Escherichia coli and is responsible for stabilization of the complex in vitro

The kdpABC operon codes for the high affinity K(+)-translocating Kdp complex (P-type ATPase) of Escherichia coli. Upon expression of this operon in minicells, a so far unrecognized small hydrophobic polypeptide, KdpF, could be identified on high resolution SDS-polyacrylamide gels in addition to the subunits KdpA, KdpB, and KdpC. Furthermore, it could be demonstrated that KdpF remains associated with the purified complex. As determined by mass spectrometry, this peptide is present in its formylated form and has a molecular mass of 3100 Da. KdpF is not essential for growth on low K(+) (0.1 mM) medium, as shown by deletion analysis of kdpF, but proved to be indispensable for a functional enzyme complex in vitro. In the absence of KdpF, the ATPase activity of the membrane-bound Kdp complex was almost indistinguishable from that of the wild type. In contrast, the purified detergent-solubilized enzyme complex showed a dramatic decrease in enzymatic activity. However, addition of purified KdpF to the KdpABC complex restored the activity up to wild type level. It is interesting to note that the addition of high amounts of E. coli lipids had a similar effect. Although KdpF is not essential for the function of the Kdp complex in vivo, it is part of the complex and functions as a stabilizing element in vitro. The corresponding operon should now be referred to as kdpFABC.

Membrane topology of the beta-subunit of the oxaloacetate decarboxylase Na+ pump from Klebsiella pneumoniae

The topology of the beta-subunit of the oxaloacetate Na+ pump (OadB) was probed with the alkaline phosphatase (PhoA) and beta-galactosidase (lacZ) fusion technique. Additional evidence for the topology was derived from amino acid alignments and comparative hydropathy profiles of OadB with related proteins. Consistent results were obtained for the three N-terminal and the six C-terminal membrane-spanning alpha-helices. However, the two additional helices that were predicted by hydropathy analyses between the N-terminal and C-terminal blocks did not conform with the fusion results. The analyses were therefore extended by probing the sideness of various engineered cysteine residues with the membrane-impermeant reagent 4-acetamido-4'-maleimidylstilbene-2, 2'-disulfonate. The results were in accord with those of the fusion analyses, suggesting that the protein folds within the membrane by a block of three N-terminal transmembrane segments and another one with six C-terminal transmembrane segments. The mainly hydrophobic connecting segment is predicted not to traverse the membrane fully, but to insert in an undefined manner from the periplasmic face. According to our model, the N-terminus is at the cytoplasmic face and the C-terminus is at the periplasmic face of the membrane.

Cloning and characterization of a gene cluster from Streptomyces cyanogenus S136 probably involved in landomycin biosynthesis

From a cosmid library of Streptomyces cyanogenus S136, DNA fragments encompassing approximately 35 kb of the presumed landomycin biosynthetic gene cluster were identified and sequenced, revealing 32 open reading frames most of which could be assigned through data base comparison.

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.

Methylmalonyl-CoA decarboxylase from Propionigenium modestum--cloning and sequencing of the structural genes and purification of the enzyme complex

Methylmalonyl-CoA decarboxylase catalyses the only energy-conserving step during succinate fermentation by Propionigenium modestum: the decarboxylation of (S)-methylmalonyl-CoA to propionyl-CoA is coupled to the vectorial transport of Na+ across the cytoplasmic membrane, thereby creating a sodium ion motive force that is used for ATP synthesis. By taking advantage of the sequence similarity between the beta-subunits of other Na+-transport decarboxylases, a portion of the P. modestum beta-subunit gene was amplified by PCR with degenerated primers. The cloned PCR product then served as homologous probe for cloning suitable fragments from genomic DNA. Sequence analysis of a 3.7-kb region identified four genes which probably form a transcriptional unit, mmdADCB. Remarkably, a mmdE gene which is present in the homologous mmdADECB cluster from Veillonella parvula and encodes the 6-kDa epsilon-subunit, is missing in P. modestum. By sequence comparisons, the following functions could be assigned to the P. modestum proteins: MmdA (56.1 kDa; alpha-subunit), carboxyltransferase; MmdB (41.2 kDa; beta-subunit), carboxybiotin-carrier-protein decarboxylase; MmdC (13.1 kDa; gamma-subunit), biotin carrier protein. MmdD (14.2 kDa; delta-subunit) presumably is essential for the assembly of the complex, as shown for the corresponding V. parvula protein. Methylmalonyl-CoA decarboxylase was solubilized from membranes of P. modestum with n-dodecylmaltoside and enriched 15-fold by affinity chromatography on monomeric avidin resin. The purified protein was composed of four subunits, three of which were identified by N-terminal sequence analysis as MmdA, MmdD, and MmdC. The purified enzyme exhibited a specific activity of up to 25 U/mg protein and an apparent Km value for (S)-methylmalonyl-CoA of approximately 12 microM. Compared to the five-subunit complex of V. parvula, the four-subunit enzyme of P. modestum appeared to be more labile, presumably a consequence of the lack of the epsilon-subunit.

Propionyl coenzyme A carboxylase is required for development of Myxococcus xanthus

A dcm-1 mutant, obtained by transposon mutagenesis of Myxococcus xanthus, could aggregate and form mounds but was unable to sporulate under nutrient starvation. A sequence analysis of the site of insertion of the transposon showed that the insertion lies within the 3' end of a 1,572-bp open reading frame (ORF) designated the M. xanthus pccB ORF. The wild-type form of the M. xanthus pccB gene, obtained from a lambdaEMBL library of M. xanthus, shows extensive similarity to a beta subunit of propionyl coenzyme A (CoA) carboxylase, an alpha subunit of methylmalonyl-CoA decarboxylase, and a 12S subunit of transcarboxylase. In enzyme assays, extracts of the dcm-1 mutant were deficient in propionyl-CoA carboxylase activity. This enzyme catalyzes the ATP-dependent carboxylation of propionyl-CoA to yield methylmalonyl-CoA. The methylmalonyl-CoA rescued the dcm-1 mutant fruiting body and spore development. During development, the dcm-1 mutant cells also had reduced levels of long-chain fatty acids (C16 to C18) compared to wild-type cells.

Cloning and sequencing of genes encoding malonate decarboxylase in Acinetobacter calcoaceticus

Malonate decarboxylase from Acinetobacter calcoaceticus was isolated and characterized (Kim, Y.S., Byun, H.S., J. Biol. Chem. 269 (1994) 29636-29641), and its subunits were reanalyzed recently to be alpha, beta, gamma, and delta. The genes for the subunits, MdcA (548 a.a.), B (295 a.a.), C (238 a.a.), and D (102 a.a.), of the enzyme have been cloned by using oligonucleotide primers deduced from amino acid sequences of peptides isolated from the purified enzyme, and sequenced to be clustered in an operon in the order of A-D-B-C. The operon was found to encode more genes than mdcABCD. The Escherichia coli, transformed with the vector containing the insert mdcADBC and about 1.7 kb of an upstream region, expressed the four subunits of the enzyme but the proteins did not show enzyme activity. It indicates that, like the enzymes from Malonomonas rubra and Klebsiella pneumoniae, more genes are needed for the formation of the functional malonate decarboxylase.

Sequence of a gene cluster from Malonomonas rubra encoding components of the malonate decarboxylase Na+ pump and evidence for their function

Malonate decarboxylation in Malonomonas rubra involves the formation of malonyl-S-[acyl-carrier protein] from acetyl-S-[acyl-carrier protein] and malonate, carboxyltransfer to a biotin protein and its decarboxylation that is coupled to delta mu Na+ generation. The genes encoding components of the malonate decarboxylase enzyme system have been cloned and sequenced. These are located within a gene cluster of approximately 11 kb comprising 14 genes that have been termed madYZGBAECDHKFLMN in the given order. Upstream of madY an open reading frame pointing into the opposite direction of the mad genes was found with structural similarities to insertion-sequence elements. The upstream region also contains DNA regions which are typical for an Escherichia coli sigma 70 promoter. Within 950 bp downstream of madN no other open reading frame was found. This region contains a putative terminator sequence. The intergenic regions within the mad gene cluster are short (usually < 70 bp, maximum 302 bp) and ribosome binding sites were defined before all 14 genes. Thus, this DNA region could form a transcriptional unit and all 14 genes could be translated into proteins. The genes madABCDEF encode the structural proteins of the malonate decarboxylase as yet identified. By comparing protein and DNA sequences and by data bank searches for related proteins with known function the following assignments could be made: MadA represents the acyl-carrier-protein-transferase component. MadB is the integral membrane-bound carboxybiotin protein decarboxylase, MadC and MadD are the two subunits of the carboxyltransferase, MadE is the acyl carrier protein and MadF is the biotin protein. Sequence comparison further indicates that MadH could be involved in the acetylation of the phosphoribosyl-dephospho-CoA prosthetic group and MadG could be involved in its biosynthesis. MadL and MadM are membrane proteins that could function as malonate carrier. The function of the madY,Z,K and N gene products is as yet unknown.

Synthesis of the oxaloacetate decarboxylase Na+ pump and its individual subunits in Escherichia coli and analysis of their function

The oadGAB genes encoding the gamma, alpha and beta-subunits of the oxaloacetate decarboxylase Na+ pump in Klebsiella pneumoniae have been cloned on plasmid pSK-GAB and expressed in Escherichia coli. The membranes of the recombinant E. coli clone contained about three times as much catalytically active oxaloacetate decarboxylase (3 mg protein/2 g wet cells) as those of the K. pneumoniae strain from which the genes were derived. The enzyme was solubilised from the membranes with Triton X-100 and purified. Its Na+ transport function was demonstrated after reconstitution into proteoliposomes. Proteoliposomes containing only the membrane-bound subunits beta and gamma (not the peripheral alpha-subunit) were unable to catalyse Na+ translocation in response to a transmembrane Na+ (delta pNa+) or electrical gradient (delta psi). Individual subunits of oxaloacetate decarboxylase and combinations of two subunits were expressed from appropriate derivatives of plasmid pSK-GAB. The hydrophobic subunits beta and beta gamma were membrane-bound as expected. Interestingly, the alpha-subunit was located in the cytoplasm if expressed separately or together with beta, but became membrane-bound if expressed together with gamma. A gamma alpha complex was isolated from such membranes by avidin-Sepharose affinity chromatography. Interactions of the gamma-subunit with the water-soluble alpha-subunit and with the membrane-bound beta-subunit are therefore required to form the oxaloacetate decarboxylase complex. The combinations of separately expressed subunits gamma alpha + beta and beta gamma+alpha were shown to yield the catalytically active enzyme. The alpha or the beta-subunit and the combinations of these subunits with the gamma-subunit were therefore expressed in E. coli in a catalytically competent state. Functional expression of the separate gamma-subunit, however, could not be demonstrated. The alpha-subunit was strongly overexpressed from a pT7-7 derived plasmid, but was only partially biotinylated under these conditions. On coexpression of the birA gene encoding biotin ligase the major part (80-100%) of the overexpressed alpha-subunit was biotinylated. Highly purified alpha-subunit was obtained by fractionated precipitation of the soluble cell fraction with ammonium sulfate. Incubation of the alpha-subunit with oxaloacetate led to a CO2 transfer to its prosthetic biotin group with the formation of stoichiometric amounts of pyruvate. The velocity of the CO2 transfer to the biotin on the alpha-subunit was about three orders of magnitude too low to account for the rate of the overall reaction. The carboxyltransfer reaction was significantly accelerated if the gamma-subunit was additionally present.(ABSTRACT TRUNCATED AT 400 WORDS)

Expression of the sodium ion pump methylmalonyl-coenzyme A-decarboxylase from Veillonella parvula and of mutated enzyme specimens in Escherichia coli

The structural genes of the sodium ion pump methylmalonyl-coenzyme A (CoA)-decarboxylase from Veillonella parvula have recently been cloned on three overlapping plasmids (pJH1, pJH20, and pJH40) and sequenced. To synthesize the complete decarboxylase in Escherichia coli, the genes were fused in the correct order (mmdADECB) on a single plasmid (pJH70). A DNA region upstream of mmdA apparently served as promoter in E. coli because expression of the mmd genes was not dependent on the correct orientation of the lac promoter present on the pBluescript KS(+)-derived expression plasmid. To allow controlled induction of the mmd genes, the upstream region was deleted and the mmd genes were cloned behind a T7 promoter. The derived plasmid, pT7mmd, was transformed into E. coli BL21(DE3) expressing T7 RNA polymerase under the control of the lac promoter. The synthesized proteins showed the typical properties of methylmalonyl-CoA-decarboxylase, i.e., the same migration behavior during sodium dodecyl sulfate-polyacrylamide gel electrophoresis, stimulation of the decarboxylation activity by sodium ions, and inhibition with avidin. In methylmalonyl-CoA-decarboxylase expressed in E. coli from pT7mmd, the gamma subunit was only partially biotinylated and the alpha subunit was present in substoichiometric amounts, resulting in a low catalytic activity. This activity could be considerably increased by coexpression of biotin ligase and by incubation with separately expressed alpha subunit. After these treatments methylmalonyl-CoA-decarboxylase with a specific activity of about 5 U/mg of protein was isolated by adsorption and elution from monomeric avidin-Sepharose. To analyze the function of the delta and epsilon subunits, the corresponding genes were deleted from plasmid pT7mmd. E. coli cells transformed with pJHdelta2, which lacks mmdE and the 3' -terminal part of mmdD, showed no methylmalonyl-CoA-decarboxylase activity. In addition, a contrast, catalytically active methylmalonyl-CoA-decarboxylase was expressed in E. coli from plasmid pJHdelta1, which contained a deletion of the mmdE gene only. The mutant enzyme could be isolated, reconstituted into proteolipsomes, and shown to function in the transport of Na+ ions coupled to methylmalonyl-CoA decarboxylation. The small epsilon subunit therefore has no catalytic function within the methylmalonyl-CoA-decarboxylase complex but appears to increase the stability of this complex.

The energy conserving N5-methyltetrahydromethanopterin:coenzyme M methyltransferase complex from Methanobacterium thermoautotrophicum is composed of eight different subunits

N5-Methyltetrahydromethanopterin:coenzyme M methyltransferase (Mtr) from Methanobacterium thermoautotrophicum strain Marburg is a membrane-associated enzyme complex which catalyzes an energy-conserving, sodium-ion-translocating step in methanogenesis from H2 and CO2. We report here that the complex is composed of eight different subunits for which evidence was obtained at the protein, DNA and RNA levels: (a) SDS/PAGE of the purified complex revealed the presence of eight different polypeptides of apparent molecular masses of 34 (MtrH), 28 (MtrE), 24 (MtrC), 23 (MtrA), 21 (MtrD), 13 (MtrG), 12.5 (MtrB) and 12 kDa (MtrF). The N-terminal amino acid sequences of the 12-, 12.5- and 13-kDa polypeptides, which had previously not been accessible, were determined; (b) cloning and sequencing of the corresponding genes revealed the presence of the eight mtr genes organized in a 4.9-kbp gene cluster in the order mtrEDCBAFGH; (c) Northern-blot analysis revealed the presence of a 5-kbp transcript. DNA probes derived from the mtrE and mtrH genes hybridized to the transcript, indicating that the eight mtr genes are organized in a transcription unit. By primer extension, the 5' end of the mtrEDC-BAFGH mRNA was analyzed. The mtr operon was found to be located between the methyl-coenzyme M reductase I operon (mcr) and a downstream open reading frame predicted to encode a Na+/Ca2+, K+ exchanger.

Location of the two genes encoding glutaconate coenzyme A-transferase at the beginning of the hydroxyglutarate operon in Acidaminococcus fermentans

Glutaconate coenzyme A-transferase (Gct) from Acidaminococcus fermentans consists of two subunits (GctA, 35725 Da and GctB, 29168 Da). The N-termini sequences of both subunits were determined. DNA sequencing of a subgenomic fragment of A. fermentans revealed that the genes encoding glutaconate CoA-transferase (gctAB) are located upstream of a gene cluster formed by gcdA, hgdC, hgdA and hgdB in this order. Further upstream of gctA, a DNA sequence was detected showing significant similarities to sigma 70-type promoters from Escherichia coli. Primer-extension analysis revealed that this specific DNA sequence was indeed the location of transcription initiation in A. fermentans. The entire gene cluster, 7.3 kb in length, comprising gctAB, gcdA and hgdCAB, has tentatively been named the hydroxyglutarate operon, since the enzymes encoded by these genes are involved in the conversion of (R)-2-hydroxyglutarate to crotonyl-CoA in the pathway of glutamate fermentation by A. fermentans. The genes gctAB were expressed together in E. coli. Cell-free extracts of a transformant E. coli strain contained glutaconate CoA-transferase at a specific activity of up to 30 U/mg protein. The recombinant enzyme was purified to homogeneity with a specific activity of 130 U/mg protein by ammonium sulfate fractionation and crystallisation. The amino acid residue directly involved in catalysis was tentatively identified as E54 of the small subunit of the enzyme (GctB).

Anaerobic growth of Salmonella typhimurium on L(+)- and D(-)-tartrate involves an oxaloacetate decarboxylase Na+ pump

We show here that the Enterobacterium Salmonella typhimurium LT2 has the capacity to grow anaerobically on L(+)- or D(-)-tartrate as sole carbon and energy source. Growth on these substrates was Na(+)-dependent and involved the L(+)- or D(-)-tartrate-inducible expression of oxaloacetate decarboxylase. The induced decarboxylase was closely related to the oxaloacetate decarboxylase Na+ pump of Klebsiella pneumoniae as shown by the sensitivity towards avidin, the location in the cytoplasmic membrane, activation by Na+ ions, and Western blot analysis with antiserum raised against the K. pneumoniae oxaloacetate decarboxylase. Participation of an oxaloacetate decarboxylase Na+ pump in L(+)-tartrate degradation by S. typhimurium is in accord with results from DNA analyses. The deduced protein sequence of the open reading frame identified upstream of the recently sequenced oxaloacetate decarboxylase genes is clearly homologous with the beta-subunit of L-tartrate dehydratase from Escherichia coli. Southern blot analysis with S. typhimurium chromosomal DNA indicated the presence of probably more than one gene for oxaloacetate decarboxylase.

Bacterial sodium ion-coupled energetics

For many bacteria Na+ bioenergetics is important as a link between exergonic and endergonic reactions in the membrane. This article focusses on two primary Na+ pumps in bacteria, the Na(+)-translocating oxaloacetate decarboxylase of Klebsiella pneumoniae and the Na(+)-translocating F1Fo ATPase of Propionigenium modestum. Oxaloacetate decarboxylase is an essential enzyme of the citrate fermentation pathway and has the additional function to conserve the free energy of decarboxylation by conversion into a Na+ gradient. Oxaloacetate decarboxylase is composed of three different subunits and the related methylmalonyl-CoA decarboxylase consists of five different subunits. The genes encoding these enzymes have been cloned and sequenced. Remarkable are large areas of complete sequence identity in the integral membrane-bound beta-subunits including two conserved aspartates that may be important for Na+ translocation. The coupling ratio of the decarboxylase Na+ pumps depended on delta muNa+ and decreased from two to zero Na+ uptake per decarboxylation event as delta mu Na+ increased from zero to the steady state level. In P. modestum, delta mu Na+ is generated in the course of succinate fermentation to propionate and CO2. This delta mu Na+ is used by a unique Na(+)-translocating F1Fo ATPase for ATP synthesis. The enzyme is related to H(+)-translocating F1Fo ATPases. The Fo part is entirely responsible for the coupling of ion specificity. A hybrid ATPase formed by in vivo complementation of an Escherichia coli deletion mutant was completely functional as a Na(+)-ATP synthase conferring the E. coli strain the ability of Na(+)-dependent growth on succinate. The hybrid consisted of subunits a, c, b, delta and part of alpha from P. modestum and of the remaining subunits from E. coli. Studies on Na+ translocation through the Fo part of the P. modestum ATPase revealed typical transporter-like properties. Sodium ions specifically protected the ATPase from the modification of glutamate-65 in subunit c by dicyclohexylcarbodiimide in a pH-dependent manner indicating that the Na+ binding site is at this highly conserved acidic amino acid residue of subunit c within the middle of the membrane.