High-pressure liquid chromatography of cobalamins and cobalamin analogs

High-pressure liquid chromatography has been used to separate, identify, and quantitate 37 different cyanocobalamin analogs, including the most commonly occurring analogs that result from bacterial synthesis. This technique has also been used to simultaneously separate, identify, and quantitate five naturally occurring cobalamins that differ in their upper axial ligands: methylcobalamin, adenosylcobalamin, hydroxocobalamin, cyanocobalamin, and sulfitocobalamin. This method permits rapid quantitative detection and identification of cobalamins and naturally occurring and synthetic cobalamin analogs in complex mixtures.     

Tissue distribution of endogenous cobalamins and other corrins in the rat, cat and guinea pig.

1. Methylcobalamin, adenosylcobalamin, hydroxocobalamin and cyanocobalamin have been estimated by a chromato-bioautographic techniques in 16 tissues from healthy rats and in five guinea pig tissues. 2. Plasma and erythrocyte cobalamins have been estimated in rats, cats and guinea pigs and the results compared with those in man. 3. Unidentified corrins were detected in 8 of the 16 rat tissues and in 3 of the 5 guinea pig tissues analysed, but were not present in tissues from specific pathogen-free rats nor in the standard laboratory diet. 4. Adenosylcobalamin was the major corrin in 8 of the 16 rat tissues. In the remainder hydroxocobalamin predominated or was present in equal proportions with adenosylcobalamin. Methylcobalamin was detected in the majority of rat tissues but at levels much lower than those in human tissues. Small amounts of cyanocobalamin were detected also and levels were higher than those of methylcobalamin in 8 of the 16 tissues. 5. In the rat, cat and guinea pig, levels of methylcobalamin and hydroxobalamin were higher in erythrocytes than in plasma, a pattern almost the complete reverse of that in man.     

Heteronuclear NMR studies of cobalamins. 31P NMR observations of cobalamins bound to a haptocorrin from chicken serum

A vitamin B12-binding protein (haptocorrin) from chicken serum has been purified to homogeneity by photodissociative affinity chromatography and characterized by gel electrophoresis and UV-visible spectrophotometry of its aquocobalamin, hydroxocobalamin, and cyanocobalamin complexes. The haptocorrin is a glycoprotein with a molecular mass of about 70 kDa and a protein moiety of about 40 kDa. 31P NMR resonances of the haptocorrin-cobalamin complexes are relatively broad singlets (with or without proton decoupling) shifted downfield by 0.7-1.0 ppm from the position of the free cobalamin resonances. From the line width data, the relaxation of the phosphorus nucleus is found to be dominated by chemical shift anisotropy with a very minor (13%) component from dipolar interaction with the two nearest neighbor protons. The rotational correlation time of the haptocorrin at 25 degrees C is estimated to be 85 ns and the activation energy for rotational correlation 3.9 +/- 0.3 kcal mol-1. The downfield shift of the 31P resonances of cobalamins upon binding to the haptocorrin cannot be due to hydrogen bonding phosphodiester moiety or displacement of the axial base by a group on the protein. Calculations also show that the downfield shift is very unlikely to be due to dipolar deshielding of the phosphorus nucleus by the ring current of an aromatic residue of the protein. It is concluded that the downfield shift of the 31P resonance must be due to sterically induced changes in phosphodiester conformation which may, or may not, involve steric compression of the axial Co-N bond.     

A simple, convenient and direct method for assessing the purity of cobalamins.

A straightforward and simple, but powerful and direct, method is presented for both the detection and quantitation of cobalamin impurities in either commercial cobalamins or in metastable cobalamins (Cbls), such as RSCbls. The method is, quite simply, the use of the aromatic region of the 1H NMR of cobalamins; it is a method developed as an outgrowth of our work preparing metastable thiolatocobalamins (RSCbls) and is a method that proved necessary for characterizing those (and by inference other) cobalamins unstable to HPLC separation conditions (i.e., and, therefore, where the normally powerful HPLC method so commonly used in cobalamin chemistry fails). Despite considerable, prior, modern multidimensional NMR literature on cobalamins, the present method has not yet been indicated explicitly, nor has anyone reported previously the NMR data required to prove that the method works (i.e., the data for a series of cobalamins and their common impurities proving that they have different chemical shifts in the aromatic region of their 1H NMR when examined under identical NMR solvent, pH and other conditions). The direct NMR method is easy to perform, readily quantitated and applicable to species unstable to the HPLC conditions required to separate cobalamin impurities. The results have allowed quantitation of the 5-11% impurities in, for example, commercial HOCb1.HX, results which document that some commercially available cobalamins are not as pure as the manufacturers' claims.     

The structures of some cobalamins in solution.

Nuclear magnetic resonance spectroscopy has been used to examine the conformations of cobalamins in solution. The perturbation of the resonances in the n.m.r. spectra by lanthanide probes provided particularly valuable information. Except for minor details the conformations are the same as those in the crystalline state. The temperature dependence of the conformation has been reassessed.     

Polarographic method of studying natural cobalamins in mixtures

By means of polarography and tree-angle scan voltammetry, AdoCbl, MeCbl and OH-Cbl were studied in mixtures and separately. The possibility to obtain a polarographic scope of quality for each of the natural cobalamins studied was shown. The ability of cobalamins to be adsorbed on a mercury electrode enables to increase the sensitivity of the method by conducting the accumulative adsorption from solutions with the concentration up to 1 microgram/ml.     

Naturally occurring cobalamins have antimalarial activity

The acquisition of resistance by malaria parasites towards existing antimalarials has necessitated the development of new chemotherapeutic agents. The effect of vitamin B(12) derivatives on the formation of beta-haematin (synthetic haemozoin) was determined under conditions similar to those in the parasitic food vacuole (using chloroquine, a known inhibitor of haemozoin formation for comparison). Adenosylcobalamin (Ado-cbl), methylcobalamin (CH(3)-cbl) and aquocobalamin (H(2)O-cbl) were approximately forty times more effective inhibitors of beta-haematin formation than chloroquine, cyanocobalamin (CN-cbl) was slightly more inhibitory than chloroquine, while dicyanocobinamide had no effect. It is proposed that the cobalamins exert their inhibitory effect on beta-haematin formation by pi-interactions of their corrin ring with the Fe(III)-protoporphyrin ring and by hydrogen-bonding using their 5,6-dimethylbenzimidazole/ribose/sugar side-chain. The antimalarial activity for the cobalamins (Ado-cbl>CH(3)-cbl>H(2)O-cbl>CN-cbl) was found to be less than that for chloroquine or quinine. Ado-cbl, CH(3)-cbl and CN-cbl do not accumulate in the parasite food vacuole by pH trapping, but H(2)O-cbl does. Unlike humans, the malaria parasite has only one enzyme that uses cobalamin as a cofactor, namely methionine synthase, which is important for growth and metabolism. Thus cobalamins in very small amounts are necessary for Plasmodium falciparum growth but in larger amounts they display antimalarial properties.     

Some Metabolic Effects of Sodium Nitroprusside in Man

The infusion of sodium nitroprusside during surgical operations produced plasma levels of cyanide of up to four times the control value. Plasma thiocyanate showed little change except during prolonged infusion of the drug, but total plasma B₁₂ tended to fall, as did methylcobalamin. Other cobalamins showed little change after nitroprusside infusion for short periods. During longer infusions the ratio of methylcobalamin to adenosyl + hydroxocobalamin fell and cyanocobalamin concentrations were high.     

Preparation of Radioactive Labelled (57Co) Sulfitocobalamin

Abstract

Farquharson and Adams (Br. J. Nutr. 36, 127-135 (1976)) have identified sulfitocobalamin (S0₃?Cbl) as one of the naturally occurring cobalamins (Cbls) in foods. We have devised a method of making radioactive labelled S0₃?Cbl for invivo and in vitro studies of this form of Cbl. ⁵⁷Co labelled cyanocobalamin (⁵⁷Co CN-Cbl) was acid photolyzed to ⁵⁷Co hydroxocobalamin (⁵⁷Co OH-Cbl) followed by ligand substitution with S0₃ ^?2 ion from aqueous sodium (meta) bisulfite in the dark. The resulting ⁵⁷Co SO₃?Cbl was purified by organic extraction and cation ex-change chromatography. The final preparation was >99% Co⁵⁷ S0₃?Cbl with an overall yield of >70%, stable for up to four weeks at 20°C in the dark, and capable of binding to the human Cbl binding proteins Transcobalamin II (TC II), Intrinsic factor (IF) and Salivary R. This method allows a simple 1 day preparation of high specific activity labelled ⁵⁷Co S0₃?Cbl for biological studies.     

Active transport of cobalamins in leukemic cells of L-1210 mice

The Tc-II receptors of cell surface membrane and the cobalamins entering into the L-1210 mouse leukemia cells were investigated. We used the blood serum Tc-II saturated with 57CoCNCbl for radioactivity determination separately in solubilized receptors and inside of the cells. The data on ligand regulation of the leukemic cell membrane receptors number were received. The internalization of radioactive complex of Tc-II and cobalamin was revealed during intensive 3H-thymidine incorporation into DNA of the cultivated cells.     

Rapid analysis of cobalamin coenzymes and related corrinoid analogs by high-performance liquid chromatography

Cobalamin coenzymes and a series of related corrinoid analogs have been analyzed by high-performance liquid chromatography on reverse-phase C₈ and C₁₈ columns using both isocratic and gradient elution systems and 254-nm absorbance detection. In the isocratic mode, retention times for sulfitocobalamin, cyanocobalamin, methylcobalamin, adenosylcobalamin, and aquacobalamin on a LiChrosorb C₈ column were 1.1, 1.6, 2.2, 2.9, and 4.7 min, respectively. In the gradient mode, corresponding retention times were 9.7, 10.2, 12.8, 11.4, and 9.0 min. Closely related structural analogs of adenosylcobalamin such as 1,N⁶-ethenoadenosylcobalamin, formycinylcobalamin, and 2,6-diaminonebularinylcobalamin were clearly resolved from naturally occurring cobalamins by isocratic elution. In the gradient system, the order of elution of cobalamins was related to the hydrophobicity of the upper-axial ligand. This was demonstrated by determining the retention times of aminoalkylcobalamin homologs (C₂, 9.8; C₃, 10.5; C₅, 11.2; C₈, 12.8; and C₁₁, 14.9 min). The usefulness of this method was demonstrated by analyzing ⁵⁷Co-labeled cobalamins present in extracts of Lactobacillus leichmannii and murine leukemia L1210 cells.     

Acceleration of cleavage of the carbon-cobalt bond of sterically hindered alkylcobalamins by binding to apoprotein of diol dehydrase

Cleavage of the C-Co bond of sterically hindered alkylcobalamins bearing neither an adenine moiety nor functional groups, such as isobutylcobalamin, neopentylcobalamin, and cyclohexylcobalamin, was markedly accelerated by their interaction with apoprotein of diol dehydrase, although these cobalamins do not function as coenzyme. Acceleration of the conversion of alkylcobalamins to enzyme-bound hydroxocobalamin was stoichiometric and obeyed first-order reaction kinetics. These results, together with strong competitive inhibition by these alkylcobalamins with respect to adenosylcobalamin, indicate that acceleration of the C-Co bond cleavage by the apoenzyme is due to labilization of their C-Co bond by binding to the active site of the enzyme. This labilization is considered to be caused by a steric distortion of the corrin ring which is induced by specific tight interaction of the cobalamin moiety with apoprotein. The importance of such a labilizing effect for activation of the C-Co bond of adenosylcobalamin in enzymatic reactions is discussed.     

On the reversibility of the B1 2r−B1 2s couple in cobalamins

The cobalt(II)—cobalt(I) interconversion in a number of vitamin B_{1 2} derivatives was investigated by cyclic voltammetry. Particular attention was focused on the factors determining whether the interconversion is reversible. When the lower axial coordination position is occupied by a strong ligand, such as the benzimidazole nucleotide in “base on” cobalamins, the cobalt(II)—cobalt(I) interconversion is irreversible due to a slow reduction of the cobalt(II). However, when the lower axial coordination position is free of a strong ligand, as in most cobinamides or in “base off” cobalamins, the cobalt(II)—cobalt(I) interconversion is nearly perfectly reversible. Possible implications of the observations to B_{1 2}-dependent enzymes are briefly discussed.     

Inhibition of nitric oxide synthase by cobalamins and cobinamides

Cobalamins are important cofactors for methionine synthase and methylmalonyl-CoA mutase. Certain corrins also bind nitric oxide (NO), quenching its bioactivity. To determine if corrins would inhibit NO synthase (NOS), we measured their effects on -l-[¹⁴C]arginine-to-l-[¹⁴C]citrulline conversion by NOS1, NOS2, and NOS3. Hydroxocobalamin (OH-Cbl), cobinamide, and dicyanocobinamide (CN₂-Cbi) potently inhibited all isoforms, whereas cyanocobalamin, methylcobalamin, and adenosylcobalamin had much less effect. OH-Cbl and CN₂-Cbi prevented binding of the oxygen analog carbon monoxide (CO) to the reduced NOS1 and NOS2 heme active site. CN₂-Cbi did not react directly with NO or CO. Spectral perturbation analysis showed that CN₂-Cbi interacted directly with the purified NOS1 oxygenase domain. NOS inhibition by corrins was rapid and not reversed by dialysis with l-arginine or tetrahydrobiopterin. Molecular modeling indicated that corrins could access the unusually large heme- and substrate-binding pocket of NOS. Best fits were obtained in the “base-off” conformation of the lower axial dimethylbenzimidazole ligand. CN₂-Cbi inhibited interferon-γ-activated Raw264.7 mouse macrophage NO production. We show for the first time that certain corrins directly inhibit NOS, suggesting that these agents (or their derivatives) may have pharmacological utility. Endogenous cobalamins and cobinamides might play important roles in regulating NOS activity under normal and pathological conditions.     

An improved enzymatic cycle for nicotinamide-adenine dinucleotide phosphate.

We describe the use of column chromatography on the nonpolar adsorbent. Amberlite XAD-2, and on silanized silica gel in the desalting and partial purification of cobalamins. These techniques are both simpler and more versatile than phenol extraction, without sacrificing efficiency. In addition, a solvent system for thin-layer chromatography on silanized silica gel is described which rapidly separates naturally occurring cobalamins.     

Protection of aquo/hydroxocobalamin from reduced glutathione by a B12 trafficking chaperone

We identified a bovine B(12) trafficking chaperone bCblC in Bos taurus that showed 88% amino acid sequence identity with a human homologue. The protein bCblC was purified from E. coli by over-expression of the encoding gene. bCblC bound cyanocobalamin (CNCbl), methylcobalamin (MeCbl) and adenosylcobalamin (AdoCbl) in the base-off states and eliminated the upper axial ligands forming aquo/hydroxocobalamin (OH(2)/OHCbl) under aerobic conditions. A transition of OH(2)/OHCbl was induced upon binding to bCblC. Interestingly, bCblC-bound OH(2)/OHCbl did not react with reduced glutathione (GSH), while the reaction of free OH(2)/OHCbl with GSH resulted in the formation of glutathionylcobalamin (GSCbl) and glutathione disulfide (GSSG). Furthermore we found that bCblC eliminates the GSH ligand of GSCbl forming OH(2)/ OHCbl. The results demonstrated that bCblC is a B(12) trafficking chaperone that binds cobalamins and protects OH(2)/OHCbl from GSH, which could be oxidized to GSSG by free OH(2)/OHCbl.     

Mitochondrial metabolism of hydroxocobalamin: synthesis of adenosylcobalamin by intact rat liver mitochondria.

When free hydroxocobalamin (vitamin B₁₂) is added in vitro to a suspension of intact rat liver mitochondria in the presence of a source of both reducing equivalents and ATP, adenosylcobalamin synthesis is observed. This synthetic process is not dependent on electron transport or oxidative phosphorylation and is not detected when cyanocobalamin is substituted for hydroxocobalamin. Adenosylcobalamin synthesis is linear with time for at least 10 min and with hydroxocobalamin concentration up to 37 nm. At the latter concentration of hydroxocobalamin, the rate of synthesis at 37 °C is 0.26 pmol/min/mg of protein. Only part (<30%) of the newly synthesized adenosylcobalamin is bound to the mitochondrial cobalamin binding protein, whereas most (90%) of the concurrently accumulated hydroxocobalamin is bound. On the other hand, when adenosylcobalamin is added to a suspension of intact mitochondria, it is accumulated at a rate similar to that for hydroxocobalamin, and is bound to the mitochondrial binding protein to a similar extent. These findings indicate that rat liver mitochondria contain all of the enzymatic components necessary to convert hydroxocobalamin to adenosylcobalamin, the coenzyme for the mitochondrial enzyme methylmalonyl CoA mutase.     

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.     

Mechanisms of discrimination between cobalamins and their natural analogues during their binding to the specific B12-transporting proteins

Three proteins, intrinsic factor (IF), transcobalamin (TC), and haptocorrin (HC), all have an extremely high affinity for the cobalamins (Cbls, Kd approximately 5 fM) but discriminate these physiological ligands from Cbl analogues with different efficiencies decreasing in the following order: IF > TC > HC. We investigated interactions of these proteins with a number of ligands: Cbl, fluorescent conjugate CBC, two base-off analogues [pseudo-coenzyme B12 (pB) and adenosyl factor A (fA)], and a baseless corrinoid cobinamide. Protein-ligand encounter and the following internal rearrangements in both molecules were registered as a change in the fluorescence of CBC (alone or mixed with other ligands), a transition in absorbance of pB and fA (base-off --> on-base conversion), and alterations in the molecular mass of two split IF domains. The greater complexity of the binding kinetics followed better Cbl specificity (HC < TC < IF). On the basis of the experimental results, we propose a general binding model with three major steps: (1) initial attachment of the ligand to the high-affinity C-domain, (2) primary assembly of N- and C-domains, and (3) slow adjustments and fixation of the ligand at the domain-domain interface. Since step 3 was characteristic of highly specific TC and especially IF, we suggest its particular importance for ligand recognition. The designed models revealed the absolute Kd values for a group of analogues. Calculations show that most of them could potentially bind to the specific transporters IF and TC under physiological conditions. Implications of this finding and the protective role of HC are discussed.     

Mechanism of reactivation of coenzyme B12-dependent diol dehydratase by a molecular chaperone-like reactivating factor.

The mechanism of reactivation of diol dehydratase by its reactivating factor was investigated in vitro by using enzyme. cyanocobalamin complex as a model for inactivated holoenzyme. The factor mediated the exchange of the enzyme-bound, adenine-lacking cobalamins for free, adenine-containing cobalamins through intermediate formation of apoenzyme. The factor showed extremely low but distinct ATP-hydrolyzing activity. It formed a tight complex with apoenzyme in the presence of ADP but not at all in the presence of ATP. Incubation of the enzyme.cyanocobalamin complex with the reactivating factor in the presence of ADP brought about release of the enzyme-bound cobalamin, leaving the tight apoenzyme-reactivating factor complex. Although the resulting complex was inactive even in the presence of added adenosylcobalamin, it dissociated by incubation with ATP, forming the apoenzyme, which was reconstitutable into active holoenzyme with added coenzyme. Thus, it was established that the reactivation of the inactivated holoenzyme by the factor in the presence of ATP and Mg2+ takes place in two steps: ADP-dependent cobalamin release and ATP-dependent dissociation of the apoenzyme.factor complex. ATP plays dual roles as a precursor of ADP in the first step and as an effector to change the factor into the low-affinity form for diol dehydratase. The enzyme-bound adenosylcobalamin was also susceptible to exchange with free adeninylpentylcobalamin, although to a much lesser degree. The mechanism for discrimination of adenine-containing cobalamins from adenine-lacking cobalamins was explained in terms of formation equilibrium constants of the cobalamin.enzyme.reactivating factor ternary complexes. We propose that the reactivating factor is a new type of molecular chaperone that participates in reactivation of the inactivated enzymes.