Kinetic and spectroscopic studies of the ATP:corrinoid adenosyltransferase PduO from Lactobacillus reuteri: substrate specificity and insights into the mechanism of Co(II)corrinoid reduction

The PduO-type ATP:corrinoid adenosyltransferase from Lactobacillus reuteri ( LrPduO) catalyzes the formation of the essential Co-C bond of adenosylcobalamin (coenzyme B 12) by transferring the adenosyl group from cosubstrate ATP to a transient Co (1+)corrinoid species generated in the enzyme active site. While PduO-type enzymes have previously been believed to be capable of adenosylating only Co (1+)cobalamin (Co (1+)Cbl (-)), our kinetic data obtained in this study provide in vitro evidence that LrPduO can in fact also utilize the incomplete corrinoid Co (1+)cobinamide (Co (1+)Cbi) as an alternative substrate. To explore the mechanism by which LrPduO overcomes the thermodynamically challenging reduction of its Co (2+)corrinoid substrates, we have examined how the enzyme active site alters the geometric and electronic properties of Co (2+)Cbl and Co (2+)Cbi (+) by using electronic absorption, magnetic circular dichroism, and electron paramagnetic resonance spectroscopic techniques. Our data reveal that upon binding to LrPduO that was preincubated with ATP, both Co (2+)corrinoids undergo a partial ( approximately 40-50%) conversion to distinct paramagnetic Co (2+) species. The spectroscopic signatures of these species are consistent with essentially four-coordinate, square-planar Co (2+) complexes, based on a comparison with the results obtained in our previous studies of related enzymes. Consequently, it appears that the general strategy employed by adenosyltransferases for effecting Co (2+) --> Co (1+) reduction involves the formation of an "activated" Co (2+)corrinoid intermediate that lacks any significant axial bonding interactions, to stabilize the redox-active, Co 3d z (2) -based molecular orbital.     

Effect of the cobalt-N coordination on the cobamide recognition by the human vitamin B12 binding proteins intrinsic factor, transcobalamin and haptocorrin

The binding of several corrinoids to the binding site of human intrinsic factor, transcobalamin or haptocorrin was investigated, p-Cresolyl cobamide and 2-amino-vitamin B12 are complete corrinoids, whose nucleotide at the lower face of the corrin ring is not coordinated to the cobalt. These corrinoids were greater than or equal to 10(3) times less efficiently recognized by intrinsic factor or transcobalamin than vitamin B12, which contains a Co-coordinated nucleotide. Pseudovitamin B12, with a weak Co-N coordination bond, revealed only moderate affinity to intrinsic factor. From these findings it is concluded that the cobamide binding to intrinsic factor and transcobalamin is strongly affected by the Co-N coordination bonds of their lower cobalt nucleotide ligands. We suggest that the Co-N coordination bond positions the nucleotide at a critical distance to the corrin ring, which is recognized by the binding proteins. Human haptocorrin, however, disclosed to distinctive selectivity regarding the different corrinoid structures. The protein bound all corrinoids with similar efficiency, independent of the strength of their Co-N coordinations, or the structures of their lower Co alpha ligands. Hence, the corrin ring, rather than a structural feature induced by the Co-N coordination, has to be considered responsible for the corrinoid binding to haptocorrin.     

The corrinoid from Methanobacterium thermoautotrophicum (Marburg strain). Spectroscopic structure analysis and identification as Co beta-cyano-5'-hydroxybenzimidazolyl-cobamide (factor III)

The corrinoids from Methanobacterium thermoautotrophicum were extracted as the Co-cyano derivative, which was isolated in crystalline form. A consistent set of spectroscopic data was acquired (ultraviolet/visible, circular dichroic, infrared, fast-atom-bombardment mass, 1H-NMR and 13C-NMR spectra), which allowed the structural analysis of this complete corrinoid. It was assigned the structure of the Co beta-cyano-5'-hydroxybenzimidazolyl-cobamide and was identified with Friedrich and Bernhauer's 'factor III' by comparison with an authentic sample.     

Cobinamides as structural probes in B12-biosynthesis: synthesis and spectroscopic analysis of isomers of Co alpha,Co beta-dicyanocobinamide

Vitamin B(12) and its coenzyme forms are cobalamins (i.e., cobamides, 'complete' with a 5,6-dimethylbenzimidazole nucleotide base), in which the particular corrinoid moiety of the cobinamides is conjugated to alpha-ribazole-3'-phosphate via a phosphate-diester group. Aside of being provided with their particular reactivity, required for their functions as organometallic cofactors in B(12)-dependent enzymes, the cobalamins also depend upon their specific three-dimensional buildup, to be able to adapt the unique constitution of 'base-on' corrinoids by intramolecular Co-coordination of the nucleotide base. We report rational partial syntheses and detailed spectral analyses of three close cobinamide isomers in their Co(alpha),Co(beta)-dicyano forms: of 13-epicobinamide (also called neocobinamide), of 176(S)-epicobinamide, and of 176-isocobinamide. Neocobinamide was obtained under acidic conditions as a degradation product of vitamin B(12). 176(S)-Epicobinamide and 176-isocobinamide were prepared by condensation of cobyric acid with (2S)-1-aminopropan-2-ol and with 3-aminopropan-1-ol, respectively. Natural cobinamide represents the corrinoid nucleus produced by proper microbial biosynthesis (as intermediate for the further assembly of the 'complete' corrinoid cofactors) or is required in some microorganisms, such as Escherichia coli, as an exogenously supplied unit for further biosynthetic buildup. The three compounds may thus be of use as structural probes for the biosynthetic capacity and tolerance in microorganisms, and (some of them) may serve as substrates as well, for further biosynthetic 'completion' of corrinoid cofactors or their analogues.     

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.     

5'-Methylbenzimidazolyl-cobamides are the corrinoids from some sulfate-reducing and sulfur-metabolizing bacteria

The sulfate-reducing bacteria Desulfobacterium autotrophicum, Desulfobulbus propionicus and Archaeoglobus fulgidus (VC-16) and the sulfur-metabolizing archaebacteria Desulfurolobus ambivalens and Thermoplasma acidophilum were found to contain considerable amounts of corrinoids, that were isolated and crystallized in their Co beta-cyano form. In three other sulfur-metabolizing archaebacteria, Thermoproteus neutrophilus, Pyrodictium occultum and Staphylothermus marinus significant amounts of corrinoids were not detected under the isolation methods used. The samples from the three sulfate-reducers were identified with Co alpha-[alpha-(5'-methylbenzimidazolyl)]-Co beta-cyanocobamide. This corrinoid was also obtained from a 5-methylbenzimidazole-supplemented Propionibacterium fermentation and was structurally characterized by ultraviolet/visible, CD, fast-atom-bombardment MS, 1H-and 13C-NMR spectroscopy. Also the major corrinoid from T. acidophilum was (tentatively) analyzed as a 5'-methylbenzimidazolyl-cobamide, whereas the main corrinoid from D. ambivalens was indicated to be vitamin B12 (a 5',6'-dimethylbenzimidazolyl-cobamide). The 5'-methylbenzimidazolylcobamides are found here as the common corrins of some sulfate-reducing and sulfur-metabolizing bacteria. The structural diversity due to the differing nucleotide bases of the corrins examined here and in methanogenic and acetogenic bacteria appears not to correlate to the biological function(s) of the corrins, but rather to be determined by biosynthetic properties of these organisms under natural growth conditions.     

Evidence for a super-reduced cobamide as the major corrinoid fraction in vivo and a histidine residue as a cobalt ligand of the p-cresolyl cobamide in the acetogenic bacterium Sporomusa ovata

The redox state of cobalt in p-cresolyl cobamide and one of its axial ligands were determined by EPR spectroscopy of Sporomusa ovata as harvested. The analyses revealed that less than 2% (less than 30 nmol/g dry cells) of the total corrinoids (greater than 2400 nmol/g dry cells) were in a low-spin Co(II) complex. The amount increased to about 15% (190-450 nmol/g dry cells) upon partial oxidation by air, indicating that the original valence state of cobalt was a Co(I) prior to this treatment. The cob(I)amide was quantified as Co(III)-CH3 after methylation by iodomethane. More than 45% (1100 nmol/g dry cells) of the extractable corrinoids were in the methylated form, whereas non-treated cells revealed less than 1% (less than 15 nmol g dry cells) of light-sensitive corrinoids. EPR spectra of the Co(II) complex exhibited a threefold N-hyperfine splitting in the gz region, which was similar to vitamin B12. Cells grown with [1.3-15N2]histidine showed a twofold N-hyperfine splitting, demonstrating that the axial N ligand of the corrinoid was derived from the imidazole group of histidine. It is concluded that the super-nucleophilic p-cresolyl cob(I)amide is the major corrinoid complex in vivo and that it is stabilized by its protein(s). The Co(II) ion of the prosthetic group was coordinated by one histidine residue of the apoprotein(s).     

Characterization of a corrinoid compound in the edible (blue-green) alga, Suizenji-nori

The edible blue-green alga (cyanobacterium), Suizenji-nori, contained 143.8+/-22.4 microg of vitamin B(12) per 100 g dry weight of the alga (mean+/-SE, n=4). A corrinoid compound was purified from the dried Suizenji-nori, and partially characterized. The silica gel 60 TLC and reversed-phase HPLC patterns of the purified corrinoid compound were not identical to those of true vitamin B(12), but to those of pseudovitamin B(12) which is inactive for humans.     

Guanylcobamide and hypoxanthylcobamide-Corrinoids formed by Desulfovibrio vulgaris

The corrinoids synthesized by the sulfate-reducing bacterium Desulfovibrio vulgaris were analyzed. The compounds found were guanylcobamide and hypoxanthylcobamide; structures were determined by mass spectrometry, ¹H-NMR, and ultraviolet/visible spectroscopy. D. vulgaris used externally added guanine to form guanylcobamide, as demonstrated with 8-¹⁴C-guanine. Addition of adenine did not lead to the formation of adenylcobamide (pseudovitamin B₁₂), whereas 5,6-dimethylbenzimidazole was transformed into vitamin B₁₂.     

A blue corrinoid from partial degradation of vitamin B12 in aqueous bicarbonate: spectra, structure, and interaction with proteins of B12 transport

Cobalamin (Cbl) is a complex cofactor produced only by bacteria but used by all animals and humans. Cyanocobalamin (vitamin B(12), CNCbl) is one commonly isolated form of cobalamin. B(12) belongs to a large group of corrinoids, which are characterized by a distinct red color conferred by the system of conjugated double bonds of the corrin ring retaining a Co(III) ion. A unique blue Cbl derivative was produced by hydrolysis of CNCbl in a weakly alkaline aqueous solution of bicarbonate. This corrinoid was purified and isolated as dark blue crystals. Its spectroscopic analysis and X-ray crystallography revealed B-ring opening with formation of 7,8-seco-cyanocobalamin (7,8-sCNCbl). The unprecedented structural change was caused by cleavage of the peripheral C-C bond between saturated carbons 7 and 8 of the corrin macrocycle accompanied by formation of a C═C bond at C7 and a carbonyl group at C8. Additionally, the C-amide was hydrolyzed to a carboxylic acid. The extended conjugation of the π-system caused a considerable red shift of the absorbance spectrum. Formation and degradation of 7,8-sCNCbl were analyzed qualitatively. Its interaction with the proteins of mammalian Cbl transport revealed both a slow binding kinetics and a low overall affinity. The binding data were compared to those of other monocarboxylic derivatives and agreed with the earlier proposed scheme for two-step ligand recognition. The obtained results are consistent with the structural models of 7,8-sCNCbl and the transport proteins intrinsic factor and transcobalamin. Potential applications of the novel derivative for drug conjugation are discussed.     

Production of corrinoids including vitamin B-12 byMethanosarcina barkeri growing on methanol

Summary A preliminary attempt was made for producing vitamin B-12 byMethanosarcina barkeri strain Fusaro in a fed-batch culture with a methanol minimum medium. After 11 days, total methanol consumption, cell density and corrinoid concentration were 145 g/l, 8.5 g(dry cell weight)/l, and 135 mg/l (73% in supernatant) respectively. Electrophoretic separation revealed that 33% of the total corrinoids was B-12 Factor III (5-hydroxybenzimidazolylcobamide) and the remaining corrinoids were cobinamide (Factor B) and its derivatives.     

Biosynthesis of corrinoids and other tetrapyrrole compounds by an acetogenic Clostridium

Biosynthesis of corrinoids and other tetrapyrrole pigments by the pure culture of the acetogenic Clostridium 99 was studied. When growing on media containing glucose or methanol, the physiological and biochemical characteristics of Clostridium 99 are very close to those of C. thermoautotrophicum. Methanol was shown to stimulate the corrinoid accumulation with the yield increasing from 154 micrograms/g dry biomass (glucose medium) up to 2250 micrograms/g dry biomass (methanol medium). According to the paper chromatography the corrinoid accumulated in Clostridium 99 cells differed both from vitamin B12 and Factor III. A study on the composition of extracellular tetrapyrroles, accumulated when the culture grows on the medium containing glucose and delta-aminolevulinic acid, revealed that they are represented both by uroporphyrin III and sirohydrochlorine-like pigments. The latters differ by a number of properties from sirohydrochlorine (corrifirine-2) of propione acidic bacteria. These pigments appear to be involved as intermediants in biosynthesis of corrinoids and other tetrapyrroles.     

Molecular recognition in the binding of vitamin B12 by the cobalamin-specific Intrinsic Factor

Equilibrium constants (given as log K/M-1) have been determined at pH 7.4 and 4 degrees C for binding by porcine Intrinsic Factor (B12-binding protein from the gut, specific for the 'cobalamin' series of Co corrinoids) of vitamin B12 or cyanocobalamin (10.5), cyanocobinamide, alpha-ribazole and alpha-ribazole-phosphate (main fragments produced by cleaving off the 'cobalamin' side-chain, all less than or equal to 3), and cyanocobinamide in the presence of greater than or equal to 10(-9) M ribazole (5.6 and independent of ribazole concentration), i.e. ribazole catalyses the binding of the cobinamide. It is proposed that the specificity of Intrinsic Factor for the cobalamins depends on the presence of the ribazole fragment in the cobalamin side-chain to promote an essential change in conformation before the corrinoid fragment can be bound.     

Identification of specific corrinoids reveals corrinoid modification in dechlorinating microbial communities

Cobalamin and other corrinoids are essential cofactors for many organisms. The majority of microbes with corrinoid‐dependent enzymes do not produce corrinoids de novo, and instead must acquire corrinoids produced by other organisms in their environment. However, the profile of corrinoids produced in corrinoid‐dependent microbial communities, as well as the exchange and modification of corrinoids among community members have not been well studied. In this study, we applied a newly developed liquid chromatography tandem mass spectrometry‐based corrinoid detection method to examine relationships among corrinoids, their lower ligand bases and specific microbial groups in microbial communities containing Dehalococcoides mccartyi that has an obligate requirement for benzimidazole‐containing corrinoids for trichloroethene respiration. We found that p‐cresolylcobamide ([p‐Cre]Cba) and cobalamin were the most abundant corrinoids in the communities. It suggests that members of the family Veillonellaceae are associated with the production of [p‐Cre]Cba. The decrease of supernatant‐associated [p‐Cre]Cba and the increase of biomass‐associated cobalamin were correlated with the growth of D. mccartyi by dechlorination. This supports the hypothesis that D. mccartyi is capable of fulfilling its corrinoid requirements in a community through corrinoid remodelling, in this case, by importing extracellular [p‐Cre]Cba and 5,6‐dimethylbenzimidazole (DMB) (the lower ligand of cobalamin), to produce cobalamin as a cofactor for dechlorination. This study also highlights the role of DMB, the lower ligand produced in all of the studied communities, in corrinoid remodelling. These findings provide novel insights on roles played by different phylogenetic groups in corrinoid production and corrinoid exchange within microbial communities. This study may also have implications for optimizing chlorinated solvent bioremediation.     

Microbial Degradation of Corrinoids VI. Reduction of Hydroxocobalamin by Cell-free Particles from Pseudomonas rubescens

Cell-free particles from Pseudomonas rubescens have been shown to reduce hydroxocobalamin to vitamin B(12r). The particles are unable to reduce the B(12r) to B(12s). The reduction of hydroxocobalamin is dependent upon reduced nicotinamide adenine dinucleotide and is stimulated by flavin adenine dinucleotide. Cobinamide and diaquocobinamide were reduced at 25 and 10%, respectively, of the rate of hydroxocobalamin. Cyanocobalamin, coenzyme B(12), pseudovitamin B(12), and diaquopseudocobalamin were not reduced. Reduced nicotinamide adenine dinucleotide phosphate and flavin mononucleotide were not active. Diaphorase and xanthine oxidase activity were not present in the particulate fraction.     

Corrinoids in anaerobic bacteria

Abstract C₁-metabolizing bacteria were analyzed for their corrinoids. The autotrophic phototrophe Chloroflexus aurantiacus contains predominantly the light-sensitive coenzyme B₁₂. The corrinoid could be teh prostethic group of a methylmalonyl-CoA mutase, which is involved in the CO₂ fixing reaction sequence from proplonyl-CoA to succinyl CoA. Methanobacterium thermoautotrophicum and Sporomusa ovata contain only traces of light-sensitive corrinoids, indicating that the demethylation reaction is favored, if these corrinoids are involved in methyl transfer reactions. The chemical structure of the unique p -cresolyl cobamide is specific for the acetogenic bacterium S. ovata , rather than the corrinoid 'factor III' for methanogenic bacteria.     

Versatility in Corrinoid Salvaging and Remodeling Pathways Supports Corrinoid-Dependent Metabolism in Dehalococcoides mccartyi

Corrinoids are cobalt-containing molecules that function as enzyme cofactors in a wide variety of organisms but are produced solely by a subset of prokaryotes. Specific corrinoids are identified by the structure of their axial ligands. The lower axial ligand of a corrinoid can be a benzimidazole, purine, or phenolic compound. Though it is known that many organisms obtain corrinoids from the environment, the variety of corrinoids that can serve as cofactors for any one organism is largely unstudied. Here, we examine the range of corrinoids that function as cofactors for corrinoid-dependent metabolism in Dehalococcoides mccartyi strain 195. Dehalococcoides bacteria play an important role in the bioremediation of chlorinated solvents in the environment because of their unique ability to convert the common groundwater contaminants perchloroethene and trichloroethene to the innocuous end product ethene. All isolated D. mccartyi strains require exogenous corrinoids such as vitamin B₁₂ for growth. However, like many other corrinoid-dependent bacteria, none of the well-characterized D. mccartyi strains has been shown to be capable of synthesizing corrinoids de novo. In this study, we investigate the ability of D. mccartyi strain 195 to use specific corrinoids, as well as its ability to modify imported corrinoids to a functional form. We show that strain 195 can use only specific corrinoids containing benzimidazole lower ligands but is capable of remodeling other corrinoids by lower ligand replacement when provided a functional benzimidazole base. This study of corrinoid utilization and modification by D. mccartyi provides insight into the array of strategies that microorganisms employ in acquiring essential nutrients from the environment.     

Purification and some properties of the corrinoid-containing membrane protein from Methanobacterium thermoautotrophicum

The cytoplasmic membrane of the methanogenic archaebacterium Methanobacterium thermoautotrophicum does not contain cytochromes, but did contain a corrinoid protein of molecular mass about 33 kDa which, after treatment with 10 mg Triton X-100/mg protein, was contained in a protein complex of about 500 kDa. Washed membranes from 1 g dry cells contained about 70 nmol of the cobamide factor III (5-hydroxybenzimidazolyl cobamide) as the sole corrinoid. The corrinoid-containing protein complex was purified and some of its properties were studied. According to several criteria it is an integral membrane protein complex. The corrinoid-protein complex, after about 100-fold purification, gave a single band on native PAGE and still had molecular mass of about 500 kDa. In SDS-PAGE several subunits were observed: in addition to the corrinoid-carrying subunit of about 33 kDa, other polypeptides of approximately 28 kDa, 26 kDa, and possibly 23 kDa were present. One mole of the purified 500-kDa protein complex contained greater than or equal to eight moles of the cobamide factor III. It was estimated that the corrinoid-protein complex accounts for 8% of the membrane protein of M. thermoautotrophicum. The visible spectrum of the oxidized protein exhibited absorbance maxima at 547 nm, 511 nm, and a shoulder at 468 nm, which disappeared upon reduction with dithionite. The midpoint potential of this transition was around -145 mV (pH 7). With EPR a Co2+ signal was observed within -50 mV and -350 mV with a maximum around -200 mV. Possible reasons for the disappearance of the Co2+ signal at low redox potentials are discussed. The line shape of the Co2+ signal was similar to that of Co2+ in free corrinoids. The signal of Co2+ could also be evoked by reduction with 5 mM dithiothreitol. From the redox properties of the corrinoid membrane protein it may be expected that in vivo the cobalt may become reduced and reoxidized. Its possible function as an electron-mediating membrane protein in the metabolism of methanogenic bacteria is discussed.     

Characterization of a Corrinoid Compound in the Edible (Blue-Green) Alga,Suizenji-nori

The edible blue-green alga (cyanobacterium), Suizenji-nori, contained 143.8±22.4 μg of vitamin B₁₂ per 100 g dry weight of the alga (mean±SE, n=4). A corrinoid compound was purified from the dried Suizenji-nori, and partially characterized. The silica gel 60 TLC and reversed-phase HPLC patterns of the purified corrinoid compound were not identical to those of true vitamin B₁₂, but to those of pseudovitamin B₁₂ which is inactive for humans.