Purification and characterization of a methanol-induced cobamide-containing protein from Sporomusa ovata

The major cobamide-containing protein from methanol-utilizing Sporomusa ovata was 8-fold enriched to apparent homogeneity. The protein exhibited a molecular mass of 40 kDa and of 38 kDa determined by gel filtration and by SDS-polyacrylamide gel electrophoresis, respectively. This finding indicates a monomeric protein structure. Monospecific polyclonal antisera raised against the protein did not cross react with another cobamide-containing protein from Sporomusa cells. Only the 40 kDa cobamide-containing protein was induced by methanol, since proteins from cells grown on 3,4-dimethoxybenzoate, betaine H₂/CO₂, or fructose showed faint or no cross reaction. Hence, the 40 kDa cobamide-containing protein is presumably involved in the methyltransfer reaction of the methanol metabolism. The purified enzyme revealed 1.1 mol of p-cresolyl cobamide per mol of protein, but it lacked of iron-sulfur centers. Remarkably, the cofactor was firmly bound to its protein.     

Identification of phenolyl cobamide from the homoacetogenic bacterium Sporomusa ovata

Phenolyl cobamide was isolated from cyanide extractions of the anaerobic eubacterium Sporomusa ovata. The proposed corrinoid structure [Co alpha,Co beta-(monocyano,monoaquo)-phenolyl cobamide] has been deduced from 1H NMR, fast-atom-bombardment mass spectroscopy and ultraviolet/visible spectroscopy data. The complete corrinoid resembled p-cresolyl cobamide [Co alpha,Co beta-(monocyano,monoaquo)-p-cresolyl cobamide], which recently has been obtained from cyanide extractions of the same bacterium. The structures and chemical properties of both cobamides with uncoordinated nucleotides differed significantly from those of vitamin B12 [Co alpha-[alpha-(5,6-dimethylbenzimidazolyl)]-Co beta-cyanocobamide]. Sporomusa synthesized coenzymes of phenolyl cobamide and p-cresolyl cobamide in considerable amounts of 400 nmol/g and 1700 nmol/g dry cells, respectively. More than 90% of the complete corrinoid pool of the homoacetogenic bacterium consisted of these two corrinoids, indicating that they are physiologically important coenzymes of the bacterial metabolism.     

Biosynthesis of para-cresolyl cobamide in Sporomusa ovata

Para-cresolyl-cobamide is a unique corrinoid from Sporomusa ovata because a cresol-riboside is present in place of a benzimidazole-nucleotide. The biosynthesis of the complete corrinoid was studied by growing cells with the possible [¹⁴C]-labeled precursors tyrosine, para-cresol, threonine, glutamate and glycine, respectively. The specific radioactivities of these precursors in their cellular pools were evaluated by determining the specific radioactivities of various amino acids isolated from cellular proteins. Those measurements were compared to the specific radioactivities of the complete corrinoid and its degradation product cobinamide. Hence, the incorporation of a particular precursor either in the cobinamide or in the cresol-riboside was verified. Tyrosine and p-cresol were incorporated into the cresol-riboside moiety of the complete corrinoid, and tyrosine rather than p-cresol was incorporated also into the cell protein. This finding suggested that the cellular tyrosine was degraded irreversibly to p-cresol. The p-cresol thereafter required an -O-transglycosidase-like activation reaction to yield the cresol-riboside with an O-glycosidic bond. Both, glutamate and threonine were incorporated into the protein fraction and into the cobinamide fraction, but not into the cresolriboside moiety. Glycine, however, was excluded as a direct precursor of the p-cresolyl-cobamide, suggesting the C-5 pathway of -aminolevulinic acid synthesis in Sporomusa.     

Sporomusa,a new genus of gram-negative anaerobic bacteria including Sporomusa sphaeroides spec. nov. and Sporomusa ovata spec. nov.

A new genus of strictly anaerobic, gram-negative, banana-shaped bacteria is described. Cells formed spores and were motile by means of up to 15 laterally inserted flagella. Nitrate or sulfate were not used as electron acceptor. Organic substrates that were fermented included N-methyl compounds, such as betaine, N,N-dimethylglycine and sarcosine, primary alcohols, hydroxy fatty acids, and 2,3-butanediol. In addition, molecular hydrogen and carbon dioxide were fermented to acetate. The latter was the characteristic fermentation product in general. During growth on betaine, trimethylamine was formed in addition. The degradation of N,N-dimethylglycine yielded acetate, monomethylamine, and trimethylamine. The presence of cytochrome b and of ubiquinone in the cells was shown. The deoxyribonuleic acid base composition of the strains was between 41.3 and 47.4 mol% guanine plus cytosine. The name Sporomusa is proposed for this new genus. On the basis of the DNA-DNA homology values obtained, the shape of the spores and some other properties, the isolated strains were assigned to two species. Names proposed: Sporomusa sphaeroides and Sporomusa ovata. The type species is S. sphaeroides and the type strains are strain E, DSM 2875 (S. sphaeroides) and strain H1, DSM 2662 (S. ovata).Dedicated to Prof. H. G. Schlegel on the occasion of his 60th birthday     

ArsAB, a novel enzyme from Sporomusa ovata activates phenolic bases for adenosylcobamide biosynthesis

In the homoacetogenic bacterium Sporomusa ovata, phenol and p‐cresol are converted into α‐ribotides, which are incorporated into biologically active cobamides (Cbas) whose lower ligand bases do not form axial co‐ordination bonds with the cobalt ion of the corrin ring. Here we report the identity of two S. ovata genes that encode an enzyme that transfers the phosphoribosyl group of nicotinate mononucleotide (NaMN) to phenol or p‐cresol, yielding α‐O‐glycosidic ribotides. The alluded genes were named arsA and arsB (for alpha‐ribotide synthesis), arsA and arsB were isolated from a genomic DNA library of S. ovata. A positive selection strategy using an Escherichia coli strain devoid of NaMN:5,6‐dimethylbenzimidazole (DMB) phosphoribosyltransferase (CobT) activity was used to isolate a fragment of S. ovata DNA that contained arsA and arsB, whose nucleotide sequences overlapped by 8 bp. SoArsAB was isolated to homogeneity, shown to be functional as a heterodimer, and to have highest activity at pH 9. SoArsAB also activated DMB to its α‐N‐glycosidic ribotide. Previously characterized CobT‐like enzymes activate DMB but do not activate phenolics. NMR spectroscopy was used to confirm the incorporation of phenol into the cobamide, and mass spectrometry was used to identify SoArsAB reaction products.     

The molybdate binding protein Mop from Haemophilus influenzae--biochemical and thermodynamic characterisation

The protein Mop from Haemophilus influenzae is a member of the molbindin family of proteins. Using isothermal titration calorimetry (ITC), Mop was observed to bind molybdate at two distinct sites with a stoichiometry of 8 mol molybdate per Mop hexamer. Six moles of molybdate bound endothermically at high affinity sites (K(a)=8.5 x 10(7)M(-1)), while 2 mol of molybdate bound exothermically at lower affinity sites (K(a)=3.7 x 10(7)M(-1)). Sulphate was also found to bind weakly at the higher affinity sites. ITC revealed that the affinity of molybdate binding to the endothermic site decreased with increasing pH and was accompanied by the transfer from the buffer to the protein of one proton per Mop monomer. These kinetic and thermodynamic results are interpreted with reference to molbindin crystal structures and data concerning molbindin binding affinities. Mop binds molybdate with high specificity, capacity, and affinity which indicates that Mop has a role as an intracellular molybdate binding protein involved in oxyanion homeostasis.     

Inhibition of cultured cell growth by tungstate and molybdate

The growth of suspension cultured cells of Nicotiana tabacum (tobacco) was inhibited completely by 100 M tungstate. Even though molybdate reversed the tungstate inactivation of nitrate reductase activity, the growth inhibition was not reversed. The growth inhibition of N. tabacum, Daucus carota, Glycine max and Solanum tuberosum suspension cultured cells by tungstate was similar in media with or without amino acids as a source of reduced nitrogen. Only in the case of G. max was a slight reversal caused by the amino acids. Tungstate was slightly less inhibitory to the growth of a nitrate reductase-lacking mutant N. tabacum line (nia-63) than to the line with nitrate reductase. These results indicate that tungstate must inhibit the cell growth of the four species used, predominantly, in some way other than by inhibiting nitrate reductase activity. Similar studies with molybdate, a sulfate analog which apparently competes with sulfate at the ATP sulfury-lase enzyme, showed that 1 mM concentrations were completely inhibitory to cell growth. The addition of sulfate or cysteine, as a source of reduced sulfur, and amino acids, as a source of reduced nitrogen, in most cases did not reverse the molybdate inhibition appreciably. Some reversal was seen only by sulfate with D. carota cells and by cysteine plus amino acids with D. carota and G. max. These results indicate that selection for tungstate or molybdate resistance will in general not select for higher levels or other alterations in the activity of nitrate reductase or ATP sulfurylase, respectively, since these ions do not inhibit growth by primarily affecting these enzymatic steps in cultured cells of the four species studied.     

Vanadate, tungstate and molybdate activate rod outer segment phosphodiesterase in the dark

Anionic activation of rod outer segment phosphodiesterase by vanadate, molybdate and tungstate is demonstrated. Comparisons are made to adenylate cyclase, which is known to be activated by vanadate and molybdate but not by tungstate. In view of the differences in anionic activation between these two important enzymatic regulators of intracellular cyclic nucleotide metabolism, it is possible that tungstate can be used as a selective probe for the effects of phosphodiesterase activity in photoreceptors and other cells. The known electrophysiological stimulation of Limulus photoreceptors by these anions is also interpreted in light of our results. If anionic production of quantum bumps in Limulus photoreceptors is mediated by changes in cyclic nucleotides, then the electrophysiological response of Limulus photoreceptors to tungstate may indicate a role for phosphodiesterase rather than adenylate cyclase in mediating light-induced cyclic nucleotide alterations in this cell.     

Cloning, expression and sequencing the molybdenum-pterin binding protein (mop) gene of Clostridium pasteurianum in Escherichia coli

mop is the structural gene for the molybdenum-pterin binding protein, which is the major molybdenum binding protein in Clostridium pastuerianum. The mop gene was detected by immunoscreening genomic libraries of C. pastuerianum and identified by determining the nucleotide sequence of the cloned insert of clostridial DNA. The deduced amino acid sequence of an open reading frame proved to be identical to the first twelve residues of purified Mop. The DNA sequence flanking the mop gene contains promoter-like consensus sequences which are probably responsible for the expression of Mop in Escherichia coli. The deduced amino acid composition shows that the protein is hydrophobic, lacks aromatic and cysteine residues and has a calculated molecular weight of 7,038. The N-terminal amino acid sequence of Mop has sequence homology with DNA binding proteins. The pattern and type of residues in the N-terminal region suggest it forms the helix-turn-helix structure observed in DNA binding proteins. We propose that Mop may be a regulatory protein binding the anabolic source of molybdenum.     

Influence of molybdate and tungstate ions on activity of cis-epoxysuccinate hydrolase in Nocardia tartaricans

L-Tartaric acid was produced by transformation of cis-epoxysuccinic acid using Nocardia tartaricans ATCC 31191 in a molar yield of 100%. cis-Epoxysuccinic acid was prepared by epoxidation of maleic acid in the presence of molybdate or tungstate ions. The effect of these ions on the subsequent activity of the cis-epoxysuccinate hydrolase was determined in both intact cells and cell-free extracts of Nocardia tartaricans. Based on kinetic studies, the tungstate ions behaved as a strong inhibitor while the molybdate ions as a stimulator of the enzyme. © Rapid Science Ltd. 1998     

Tungsten transport protein A (WtpA) in Pyrococcus furiosus: the first member of a new class of tungstate and molybdate transporters

A novel tungstate and molybdate binding protein has been discovered from the hyperthermophilic archaeon Pyrococcus furiosus. This tungstate transport protein A (WtpA) is part of a new ABC transporter system selective for tungstate and molybdate. WtpA has very low sequence similarity with the earlier-characterized transport proteins ModA for molybdate and TupA for tungstate. Its structural gene is present in the genome of numerous archaea and some bacteria. The identification of this new tungstate and molybdate binding protein clarifies the mechanism of tungstate and molybdate transport in organisms that lack the known uptake systems associated with the ModA and TupA proteins, like many archaea. The periplasmic protein of this ABC transporter, WtpA (PF0080), was cloned and expressed in Escherichia coli. Using isothermal titration calorimetry, WtpA was observed to bind tungstate (dissociation constant [K(D)] of 17 +/- 7 pM) and molybdate (K(D) of 11 +/- 5 nM) with a stoichiometry of 1.0 mol oxoanion per mole of protein. These low K(D) values indicate that WtpA has a higher affinity for tungstate than do ModA and TupA and an affinity for molybdate similar to that of ModA. A displacement titration of molybdate-saturated WtpA with tungstate showed that the tungstate effectively replaced the molybdate in the binding site of the protein.     

Structure of the dna binding cleft of the gene 5 protein from bacteriophage fd

The structure of the gene 5 DNA unwinding protein from bacteriophage fd has been solved to 2.3-Å resolution by X-ray diffraction techniques. The molecule contains an extensive cleft region that we have identified as the DNA binding site on the basis of the residues that comprise its surface. The interior of the groove has a rather large number of basic amino acid residues that serve to draw the polynucleotide backbone into the cleft. Arrayed along the external edges of the groove are a number of aromatic amino acid side groups that are in position to stack upon the bases of the DNA and fix it in place. The structure and binding mechanism as we visualize it appear to be fully consistent with evidence provided by physical-chemical studies of the protein in solution.     

Classification of a Haemophilus influenzae ABC transporter HI1470/71 through its cognate molybdate periplasmic binding protein, MolA

molA (HI1472) from H. influenzae encodes a periplasmic binding protein (PBP) that delivers substrate to the ABC transporter MolB(2)C(2) (formerly HI1470/71). The structures of MolA with molybdate and tungstate in the binding pocket were solved to 1.6 and 1.7 ? resolution, respectively. The MolA-binding protein binds molybdate and tungstate, but not other oxyanions such as sulfate and phosphate, making it the first class III molybdate-binding protein structurally solved. The ～100 μM binding affinity for tungstate and molybdate is significantly lower than observed for the class II ModA molybdate-binding proteins that have nanomolar to low micromolar affinity for molybdate. The presence of two molybdate loci in H. influenzae suggests multiple transport systems for one substrate, with molABC constituting a low-affinity molybdate locus.     

An analysis of the binding of repressor protein ModE to modABCD (molybdate transport) operator/promoter DNA of Escherichia coli.

Expression of the modABCD operon in Escherichia coli, which codes for a molybdate-specific transporter, is repressed by ModE in vivo in a molybdate-dependent fashion. In vitro DNase I-footprinting experiments identified three distinct regions of protection by ModE-molybdate on the modA operator/promoter DNA, GTTATATT (-15 to -8; region 1), GCCTACAT (-4 to +4; region 2), and GTTACAT (+8 to +14; region 3). Within the three regions of the protected DNA, a pentamer sequence, TAYAT (Y = C or T), can be identified. DNA-electrophoretic mobility experiments showed that the protected regions 1 and 2 are essential for binding of ModE-molybdate to DNA, whereas the protected region 3 increases the affinity of the DNA to the repressor. The stoichiometry of this interaction was found to be two ModE-molybdate per modA operator DNA. ModE-molybdate at 5 nM completely protected the modABCD operator/promoter DNA from DNase I-catalyzed hydrolysis, whereas ModE alone failed to protect the DNA even at 100 nM. The apparent K(d) for the interaction between the modA operator DNA and ModE-molybdate was 0.3 nM, and the K(d) increased to 8 nM in the absence of molybdate. Among the various oxyanions tested, only tungstate replaced molybdate in the repression of modA by ModE, but the affinity of ModE-tungstate for modABCD operator DNA was 6 times lower than with ModE-molybdate. A mutant ModE(T125I) protein, which repressed modA-lac even in the absence of molybdate, protected the same region of modA operator DNA in the absence of molybdate. The apparent K(d) for the interaction between modA operator DNA and ModE(T125I) was 3 nM in the presence of molybdate and 4 nM without molybdate. The binding of molybdate to ModE resulted in a decrease in fluorescence emission, indicating a conformational change of the protein upon molybdate binding. The fluorescence emission spectra of mutant ModE proteins, ModE(T125I) and ModE(Q216*), were unaffected by molybdate. The molybdate-independent mutant ModE proteins apparently mimic in its conformation the native ModE-molybdate complex, which binds to a DNA sequence motif of TATAT-7bp-TAYAT.     

Structure of the spectrin-actin binding site of erythrocyte protein 4.1

The complete primary structure of the functional site of erythrocyte protein 4.1 involved in spectrin-actin associations has been determined. The sequence of this domain, which contains 67 amino acids and has a molecular mass of 8045 daltons, has been obtained by NH2-terminal sequence analysis of an 8-kDa chymotryptic peptide, three endoproteinase lysine C-cleaved peptides and two peptides obtained by Staphylococcus aureus protease V8 cleavage. All peptides including the 8-kDa domain peptide were purified by reverse-phase high performance liquid chromatography. Antibodies against two different synthetic peptides of the 8-kDa domain are able to inhibit the association between protein 4.1, spectrin, and F-actin, corroborating that the 8-kDa domain is responsible for the formation of a ternary complex. A computer search of the 8-kDa sequence with the National Biomedical Research Foundation database did not detect any significant homologies to known sequences. Protein 4.1 is not related to any known proteins and may represent a new protein superfamily.