Orally tolerant CD4 T cells respond poorly to antigenic stimulation but strongly to direct stimulation of intracellular signaling pathways

The response of splenic CD4 T cells from ovalbumin (OVA)-specific T cell receptor (TCR) transgenic mice after long-term feeding of a diet containing this antigen was examined. These CD4 T cells exhibited a decreased response to OVA peptide stimulation, in terms of proliferation, interleukin-2 secretion, and CD40 ligand expression, compared to those from mice fed a control diet lacking OVA, demonstrating that oral tolerance of T cells had been induced through oral intake of the antigen. We investigated the intracellular signaling pathways, which were Ca/CN cascade and Ras/MAPK cascade, of these tolerant CD4 T cells using phorbol-12-myristate-13-acetate (PMA) and ionomycin, which are known to directly stimulate these pathways. In contrast to the decreased response to TCR stimulation by OVA peptide, it was shown that the response of splenic CD4 T cells to these reagents in the state of oral tolerance was stronger. These results suggest that splenic CD4 T cells in the state of oral tolerance have an impairment in signaling, in which signals are not transmitted from the TCR to downstream signaling pathways, and have impairments in the vicinity of TCR.

Energetic feasibility of hydrogen abstraction and recombination in coenzyme B(12)-dependent diol dehydratase reaction

Coenzyme B(12) serves as a cofactor for enzymatic radical reactions. The essential steps in all the coenzyme B(12)-dependent rearrangements are two hydrogen abstraction steps: hydrogen abstraction of the adenosyl radical from substrates, and hydrogen back-abstraction (recombination) of a product-derived radical from 5'-deoxyadenosine. The energetic feasibility of these hydrogen abstraction steps in the diol dehyratase reaction was examined by theoretical calculations with a protein-free, simplified model at the B3LYP/6-311G* level of density functional theory. Activation energies for the hydrogen abstraction and recombination with 1,2-propanediol as substrate are 9.0 and 15.1 kcal/mol, respectively, and essentially not affected by coordination of the substrate and the radical intermediate to K+. Since these energies can be considered to be supplied by the substrate-binding energy, the computational results with this simplified model indicate that the hydrogen abstraction and recombination in the coenzyme B(12)-dependent diol dehydratase reaction are energetically feasible.

Radical production simulated by photoirradiation of the diol dehydratase-adeninylpentylcobalamin complex

In the course of structural studies of diol dehydratase-cobalamin complexes, it was found that the electron density corresponding to the cyano group of the enzyme-bound cyanocobalamin is almost not observable at room temperature and very low even at cryogenic temperatures, suggesting its dissociation from the Co atom upon X-ray irradiation. On the contrary, the adenine moiety of the enzyme-bound adeninylpentylcobalamin was clearly located in the electron density map. When the enzyme-adeninylpentylcobalamin complex was illuminated with visible light, the electron density between the C5' and Co atoms disappeared, and the temperature factors of the atoms comprising the pentamethylene group became much larger than those in the dark. This indicates a Co-C bond cleavage and that the adenine moiety remains held by hydrogen bonds with some residues in the enzyme. Thus, the formation of an adenine-anchored radical upon illumination was demonstrated crystallographically with this complex. These observations clearly indicate that homolysis of the Co-C bond of alkylcobalamin takes place upon illumination with visible light but is not readily cleaved during X-ray irradiation.

Characterization and mechanism of action of a reactivating factor for adenosylcobalamin-dependent glycerol dehydratase

Adenosylcobalamin-dependent glycerol dehydratase undergoes mechanism-based inactivation by its physiological substrate glycerol. We identified two genes (gdrAB) of Klebsiella pneumoniae for a glycerol dehydratase-reactivating factor (Tobimatsu, T., Kajiura, H., Yunoki, M., Azuma, M., and Toraya, T. (1999) J. Bacteriol. 181, 4110-4113). Recombinant GdrA and GdrB proteins formed a tight complex of (GdrA)(2)(GdrB)(2), which is a putative reactivating factor. The purified factor reactivated the glycerol-inactivated and O(2)-inactivated glycerol dehydratases as well as activated the enzyme-cyanocobalamin complex in vitro in the presence of ATP, Mg(2+), and adenosylcobalamin. The factor mediated the exchange of the enzyme-bound, adenine-lacking cobalamins for free, adenine-containing cobalamins in the presence of ATP and Mg(2+) through intermediate formation of apoenzyme. The factor showed extremely low ATP-hydrolyzing activity and formed a tight complex with apoenzyme in the presence of ADP. Incubation of the enzyme-cyanocobalamin complex with the reactivating factor in the presence of ADP brought about release of the enzyme-bound cobalamin. The resulting tight inactive complex of apoenzyme with the factor dissociated upon incubation with ATP, forming functional apoenzyme and a low affinity form of factor. Thus, it was established that the reactivation of the inactivated holoenzymes takes place in two steps: ADP-dependent cobalamin release and ATP-dependent dissociation of the apoenzyme-factor complex. We propose that the glycerol dehydratase-reactivating factor is a molecular chaperone that participates in reactivation of the inactivated enzymes.

Revised sequence and expression of cyclin B cDNA from the starfish Asterina pectinifera

Cyclin B cDNA was cloned from the ovary of the starfish Asterina pectinifera and analyzed by RT-PCR and 3'- and 5'-RACE techniques. The cDNA consists of a 0.13-kb upstream untranslated region, a 1.22-kb coding region, and a 0.86-kb downstream untranslated region. The open reading frame encoded a polypeptide of 404 amino acid residues with a calculated molecular weight of 45,692. All the characteristic sequences, such as destruction and cyclin boxes, cyclin B motif, and cytoplasmic retention and nuclear export signals, were found in the newly cloned cyclin B cDNA. The deduced amino acid sequence of the cyclin B cDNA was highly homologous in the middle and carboxy terminal regions to that from mature eggs of the same organism, but quite different in the amino terminal region. Evidence was obtained which suggested that this cyclin B is expressed in immature and maturing oocytes and is the same as that cloned from mature eggs.

Extremely low activity of methionine synthase in vitamin B-12-deficient rats may be related to effects on coenzyme stabilization rather than to changes in coenzyme induction

Severely vitamin B-12 (B-12)-deficient rats were produced by feeding a B-12-deficient diet. The status of B-12 deficiency was confirmed by an increase in urinary methylmalonate excretion and decreases in liver B-12 concentrations and cobalamin-dependent methionine synthase activity. Rat liver methionine synthase existed almost exclusively as the holoenzyme. In B-12-deficient rats, the level of methionine synthase protein was lower, although the mRNA level was not significantly different from that of control rats. When methylcobalamin, the coenzyme for methionine synthase, was administered to the B-12-deficient rats, growth, liver B-12 concentrations and urinary excretion of methylmalonate were reversed although not always to control (B-12-sufficient) levels in a short period. During this recovery process, methionine synthase activity and its protein level increased, whereas the mRNA level was unaffected. We reported previously that rat apomethionine synthase is very unstable and is stabilized by forming a complex with methylcobalamin. Thus, the extremely low activity of methionine synthase in B-12-deficient rats may be related to effects on "coenzyme stabilization" (stabilization of the enzyme by cobalamin binding) rather than to changes in "coenzyme induction."

How a protein generates a catalytic radical from coenzyme B(12): X-ray structure of a diol-dehydratase-adeninylpentylcobalamin complex

BACKGROUND

Adenosylcobalamin (coenzyme B(12)) serves as a cofactor for enzymatic radical reactions. The adenosyl radical, a catalytic radical in these reactions, is formed by homolysis of the cobalt-carbon bond of the coenzyme, although the mechanism of cleavage of its organometallic bond remains unsolved.

RESULTS

We determined the three-dimensional structures of diol dehydratase complexed with adeninylpentylcobalamin and with cyanocobalamin at 1.7 A and 1.9 A resolution, respectively, at cryogenic temperatures. In the adeninylpentylcobalamin complex, the adenine ring is bound parallel to the corrin ring as in the free form and methylmalonyl-CoA-mutase-bound coenzyme, but with the other side facing pyrrole ring C. All of its nitrogen atoms except for N(9) are hydrogen-bonded to mainchain amide oxygen and amide nitrogen atoms, a sidechain hydroxyl group, and a water molecule. As compared with the cyanocobalamin complex, the sidechain of Seralpha224 rotates by 120 degrees to hydrogen bond with N(3) of the adenine ring.

CONCLUSIONS

The structure of the adenine-ring-binding site provides a molecular basis for the strict specificity of diol dehydratase for the coenzyme adenosyl group. The superimposition of the structure of the free coenzyme on that of enzyme-bound adeninylpentylcobalamin demonstrated that the tight enzyme-coenzyme interactions at both the cobalamin moiety and adenine ring of the adenosyl group would inevitably lead to cleavage of the cobalt-carbon bond. Rotation of the ribose moiety around the glycosidic linkage makes the 5'-carbon radical accessible to the hydrogen atom of the substrate to be abstracted.

Specificities of reactivating factors for adenosylcobalamin-dependent diol dehydratase and glycerol dehydratase

Adenosylcobalamin-dependent glycerol and diol dehydratases undergo inactivation by the physiological substrate glycerol during catalysis. In the permeabilized cells of Klebsiella pneumoniae, Klebsiella oxytoca, and recombinant Escherichia coli, glycerol-inactivated glycerol dehydratase and diol dehydratase are reactivated by their respective reactivating factors in the presence of ATP, Mg2+, and adenosylcobalamin. Both of the reactivating factors consist of two subunits. To examine the specificities of the reactivating factors, their genes or their hybrid genes were co-expressed with dehydratase genes in E. coli cells in various combinations. The reactivating factor of K. oxytoca for diol dehydratase efficiently cross-reactivated the inactivated glycerol dehydratase, whereas the reactivating factor of K. pneumoniae for glycerol dehydratase hardly cross-reactivated the inactivated diol dehydratase. Both of the two hybrid reactivating factors rapidly reactivated the inactivated glycerol dehydratase. In contrast, the hybrid reactivating factor containing the large subunit of the glycerol dehydratase reactivating factor hardly reactivated the inactivated diol dehydratase. These results indicate that the glycerol dehydratase reactivating factor is much more specific for the dehydratase partner than the diol dehydratase reactivating factor and that a large subunit of the reactivating factors principally determines the specificity for a dehydratase.

Radical catalysis of B12 enzymes: structure, mechanism, inactivation, and reactivation of diol and glycerol dehydratases

Enzymatic radical catalysis is defined as a mechanism of catalysis by which enzymes catalyze chemically difficult reactions by utilizing the high reactivity of free radicals. Adenosylcobalamin (coenzyme B12) serves as a cofactor for enzymatic radical reactions. The recent structural analysis of adenosylcobalamin-dependent diol dehydratase revealed that the substrate 1,2-propanediol and an essential potassium ion are located inside a (beta/alpha)8 barrel. Two hydroxyl groups of the substrate coordinate directly to the potassium ion which binds to the negatively charged inner part of the cavity. Cobalamin bound in the base-on mode covers the cavity to isolate the active site from solvent. Based on the three-dimensional structure and theoretical calculations, a new mechanism for diol dehydratase is proposed in which the potassium ion plays a direct role in the catalysis. The mechanisms for generation of a catalytic radical by homolysis of the coenzyme Co-C bond and for protection of radical intermediates from undesired side reactions during catalysis are discussed based on the structure. The reactivating factors for diol and glycerol dehydratases have been identified. These factors are a new type of molecular chaperone which participate in reactivation of the inactivated holoenzymes by mediating ATP-dependent exchange of the modified coenzyme for free intact coenzyme.

Heterologous high level expression, purification, and enzymological properties of recombinant rat cobalamin-dependent methionine synthase

Rat methionine synthase was expressed chiefly as apoenzyme in recombinant baculovirus-infected insect cells (Yamada, K., Tobimatsu, T., and Toraya, T. (1998) Biosci. Biotech. Biochem. 62, 2155-2160). The apoenzyme produced was very unstable, and therefore, after complexation with methylcobalamin, the functional holoenzyme was purified to homogeneity. The specific activity and apparent K(m) values for substrates were in good agreement with those obtained with purified rat liver enzyme. The electronic spectrum of the purified recombinant enzyme resembled that of cob(II)alamin and changed to a methylcobalamin-like one upon incubation of the enzyme with titanium(III) and S-adenosylmethionine. The rate of oxidative inactivation of the enzyme in the absence of S-adenosylmethionine was slower with a stronger reducing agent like titanium(III). The nucleotide moiety, especially the phosphodiester group, was shown to play an important role in the binding of the coenzyme to apoprotein and thus for catalysis. Upon incubation with the apoenzyme in the absence of a reducing agent, cyano- and aquacobalamin were not effective or were effective only slightly in reconstituting holoenzyme. Ethyl- and propylcobalamin formed inactive complexes with apoenzyme, which were converted to holoenzyme by photolytic activation. Adenosylcobalamin was not able to form a complex with apoenzyme, which was convertible to holoenzyme by photoirradiation.

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.

Direct participation of potassium ion in the catalysis of coenzyme B(12)-dependent diol dehydratase

The direct ion-dipolar interactions between potassium ion (K(+)) and the two hydroxyl groups of the substrate are the most striking feature of the crystal structure of coenzyme B(12)-dependent diol dehydratase. We carried out density-functional-theory computations to determine whether K(+) can assist the 1,2-shift of the hydroxyl group in the substrate-derived radical. Between a stepwise abstraction/recombination reaction proceeding via a direct hydroxide abstraction by K(+) and a concerted hydroxyl group migration assisted by K(+), only a transition state for the latter concerted mechanism was found from our computations. The barrier height for the transition state from the complexed radical decreases by only 2.3 kcal/mol upon coordination of the migrating hydroxyl group to K(+), which corresponds to a 42-fold rate acceleration at 37 degrees C. The net binding energy upon replacement of the K(+)-bound water for substrate was calculated to be 10.7 kcal/mol. It can be considered that such a large binding energy is at least partly used for the substrate-induced conformational changes in the enzyme that trigger the homolytic cleavage of the Co-C bond of the coenzyme and the subsequent catalysis by a radical mechanism. We propose here a new mechanism for diol dehydratase in which K(+) plays a direct role in the catalysis.

A new mode of B12 binding and the direct participation of a potassium ion in enzyme catalysis: X-ray structure of diol dehydratase

BACKGROUND

Diol dehydratase is an enzyme that catalyzes the adenosylcobalamin (coenzyme B12) dependent conversion of 1,2-diols to the corresponding aldehydes. The reaction initiated by homolytic cleavage of the cobalt-carbon bond of the coenzyme proceeds by a radical mechanism. The enzyme is an alpha2beta2gamma2 heterooligomer and has an absolute requirement for a potassium ion for catalytic activity. The crystal structure analysis of a diol dehydratase-cyanocobalamin complex was carried out in order to help understand the mechanism of action of this enzyme.

RESULTS

The three-dimensional structure of diol dehydratase in complex with cyanocobalamin was determined at 2.2 A resolution. The enzyme exists as a dimer of heterotrimers (alphabetagamma)2. The cobalamin molecule is bound between the alpha and beta subunits in the 'base-on' mode, that is, 5,6-dimethylbenzimidazole of the nucleotide moiety coordinates to the cobalt atom in the lower axial position. The alpha subunit includes a (beta/alpha)8 barrel. The substrate, 1,2-propanediol, and an essential potassium ion are deeply buried inside the barrel. The two hydroxyl groups of the substrate coordinate directly to the potassium ion.

CONCLUSIONS

This is the first crystallographic indication of the 'base-on' mode of cobalamin binding. An unusually long cobalt-base bond seems to favor homolytic cleavage of the cobalt-carbon bond and therefore to favor radical enzyme catalysis. Reactive radical intermediates can be protected from side reactions by spatial isolation inside the barrel. On the basis of unique direct interactions between the potassium ion and the two hydroxyl groups of the substrate, direct participation of a potassium ion in enzyme catalysis is strongly suggested.

Identification and expression of the genes encoding a reactivating factor for adenosylcobalamin-dependent glycerol dehydratase

Adenosylcobalamin-dependent glycerol dehydratase undergoes inactivation by glycerol, the physiological substrate, during catalysis. In permeabilized cells of Klebsiella pneumoniae, the inactivated enzyme is reactivated in the presence of ATP, Mg2+, and adenosylcobalamin. We identified the two open reading frames as the genes for a reactivating factor for glycerol dehydratase and designated them gdrA and gdrB. The reactivation of the inactivated glycerol dehydratase by the gene products was confirmed in permeabilized recombinant Escherichia coli cells coexpressing GdrA and GdrB proteins with glycerol dehydratase.

Crystallization and preliminary x-ray study of two crystal forms of Klebsiella oxytoca diol dehydratase-cyanocobalamin complex

Two crystal forms of Klebsiella oxytoca diol dehydratase complexed with cyanocobalamin have been obtained and preliminary crystallographic experiments have been performed. The crystals belong to two different space groups, depending on the crystallization conditions. One crystal (form I) belongs to space group P212121 with unit-cell parameters a = 76.2, b = 122.3, c = 209. 6 A, and diffracts to 2.2 A resolution using an X-ray beam from a synchrotron radiation source. The other crystal (form II) belongs to space group P21 with unit-cell parameters a = 75.4, b = 132.7, c = 298.8 A, beta = 91.9 degrees, and diffracts to 3.0 A resolution. For the purpose of structure determination, a heavy-atom derivative search was carried out and some mercuric derivatives were found to be promising. Structure analysis by the multiple isomorphous replacement method is now under way.

A reactivating factor for coenzyme B12-dependent diol dehydratase

Adenosylcobalamin-dependent diol dehydratase of Klebsiella oxytoca undergoes suicide inactivation by glycerol, a physiological substrate. The coenzyme is modified through irreversible cleavage of its cobalt-carbon bond, resulting in inactivation of the enzyme by tight binding of the modified coenzyme to the active site. Recombinant DdrA and DdrB proteins of K. oxytoca were co-purified to homogeneity from cell-free extracts of Escherichia coli overexpressing the ddrAB genes. They existed as a tight complex, i.e. a putative reactivating factor, with an apparent molecular weight of 150,000. The factor consists of equimolar amounts of the two subunits with Mr of 64,000 (A) and 14,000 (B), encoded by the ddrA and ddrB genes, respectively. Therefore, its subunit structure is most likely A2B2. The factor not only reactivated glycerol-inactivated and O2-inactivated holoenzymes but also activated enzyme-cyanocobalamin complex in the presence of free adenosylcobalamin, ATP, and Mg2+. The reactivating factor mediated ATP-dependent exchange of the enzyme-bound cyanocobalamin for free 5-adeninylpentylcobalamin in the presence of ATP and Mg2+, but the reverse was not the case. Thus, it can be concluded that the inactivated holoenzyme becomes reactivated by exchange of the enzyme-bound, adenine-lacking cobalamins for free adenosylcobalamin, an adenine-containing cobalamin.

Cloning, sequencing, and heterologous expression of rat methionine synthase cDNA

Methionine synthase catalyzes cobalamin-dependent methyl transfer reaction from 5-methyltetrahydrofolate to homocysteine, forming methionine. Rat methonine synthase cDNA was cloned and analyzed by RT-PCR, 3'- and 5'-RACE techniques. The cDNA consists of a 0.3-kb upstream untranslated region, a 3.8-kb coding region, and a 0.4-kb downstream untranslated region. The open reading frame encoded a polypeptide of 1,253 amino acid residues with a calculated molecular weight of 139,162. This molecular weight was in good agreement with the observed one (143,000) of the purified rat liver enzyme. The deduced amino acid sequence was 53, 92, and 64% identical with those of the Escherichia coli, human, and presumptive Caenorhabditis elegans enzymes, respectively. All the fingerprint sequences, forming parts of the cobalamin- and S-adenosylmethionine-binding sites, were completely conserved in the rat methionine synthase. A high-level expression of catalytically active enzyme in insect cells was done by infection with a baculovirus containing the rat methionine synthase cDNA.

EPR spectroscopic evidence for the mechanism-based inactivation of adenosylcobalamin-dependent diol dehydratase by coenzyme analogs

EPR spectra were measured upon incubation of the complex of diol dehydratase with coenzyme analogs in the presence of 1,2-propanediol, a physiological substrate. When the analog in which the D-ribose moiety of the nucleotide loop was replaced by a trimethylene group was used as coenzyme, essentially the same EPR spectrum as that with adenosylcobalamin was obtained. The higher-field doublet and the lower-field broad signals derived from an organic radical and low-spin Co(II) of cob(II)alamin, respectively, were observed. With the imidazolyl counterpart, base-on cob(II)alamin-like species accumulated, but signals due to an organic radical quickly disappeared. When a coenzyme analog lacking the nucleotide moiety was incubated with apoenzyme in the presence of substrate, the EPR spectrum resembling cob(II)inamide was obtained, but no signals due to an organic radical were observed. From these results, it was concluded that the extinction of organic radical intermediates results in inactivation of the enzyme by these coenzyme analogs. Upon suicide inactivation with a [15N2]imidazolyl analog, the octet signals due to Co(II) showed superhyperfine splitting into doublets, indicating axial coordination of 5,6-dimethylbenzimidazole to the cobalamin bound to diol dehydratase.

Molecular cloning, sequencing and characterization of the genes for adenosylcobalamin-dependent diol dehydratase of Klebsiella pneumoniae

Klebsiella pneumoniae and some of the other Enterobacteriaceae form both diol dehydratase and glycerol dehydratase in response to growth substrates. To compare these enzymes produced by the same bacterium, the pdd genes of K. pneumoniae encoding adenosylcobalamin-dependent diol dehydratase were cloned and sequenced. The sequential three open reading frames (pddA, pddB, and pddC genes) encoded polypeptides of 554, 228, and 174 amino acid residues with predicted molecular weights of 60,379(alpha), 24,401(beta), and 19,489(gamma), respectively. The deduced amino acid sequences of the subunits were 84-100% and 54-71% identical with those reported for diol dehydratases and glycerol dehydratases, respectively.

Evidence for axial coordination of 5,6-dimethylbenzimidazole to the cobalt atom of adenosylcobalamin bound to diol dehydratase

It was demonstrated by electron paramagnetic resonance (EPR) spectroscopy that organic radical intermediates disappeared and cob(II)alamin accumulated upon suicide inactivation of diol dehydratase by 2-methyl-1,2-propanediol. The resulting EPR spectra showed that the eight hyperfine lines due to the divalent cobalt atom of cob(II)alamin further split into triplets by the superhyperfine coupling to the 14N nucleus. Essentially the same superhyperfine splitting of the octet into triplets was observed with [14N]- and [15N]apoenzyme. When the adenosyl form of [14N2]- and [15N2]imidazolyl analogues of the coenzyme [Toraya, T., and Ishida, A. (1991) J. Biol. Chem. 266, 5430-5437] was used with unlabeled apoenzyme, the octet showed superhyperfine splitting into triplets and doublets, respectively. Therefore, it was concluded that cobalamin is bound to this enzyme with 5,6-dimethylbenzimidazole coordinating to the cobalt atom. This conclusion is consistent with the fact that the consensus sequence forming part of a cobalamin-binding motif, conserved in methionine synthase and some of the other cobalamin enzymes, was not found in the deduced amino acid sequences of the subunits of diol dehydratase. Adenosylcobinamide methyl phosphate, a coenzyme analogue lacking the nucleotide moiety, underwent cleavage of the cobalt-carbon bond upon binding to the enzyme in the presence of substrate, forming a cob(II)inamide derivative without nitrogenous base coordination, as judged by EPR and optical spectroscopy. Therefore, this analogue may be a useful probe for determining whether the replacement of the 5, 6-dimethylbenzimidazole ligand by a histidine residue takes place upon binding of cobalamin to proteins.

Characterization, sequencing, and expression of the genes encoding a reactivating factor for glycerol-inactivated adenosylcobalamin-dependent diol dehydratase

Diol dehydratase undergoes suicide inactivation by glycerol during catalysis involving irreversible cleavage of the Co-C bond of adenosylcobalamin. In permeabilized Klebsiella oxytoca and Klebsiella pneumoniae cells, the glycerol-inactivated holoenzyme or the enzyme-cyanocobalamin complex is rapidly activated by the exchange of the inactivated coenzyme or cyanocobalamin for free adenosylcobalamin in the presence of ATP and Mg2+ (Honda, S., Toraya, T., and Fukui, S. (1980) J. Bacteriol. 143, 1458-1465; Ushio, K., Honda, S., Toraya, T., and Fukui, S. (1982) J. Nutr. Sci. Vitaminol. 28, 225-236). Permeabilized Escherichia coli cells co-expressing the diol dehydratase genes with two open reading frames in the 3'-flanking region were capable of reactivating glycerol-inactivated diol dehydratase as well as activating the enzyme-cyanocobalamin complex in situ in the presence of free adenosylcobalamin, ATP, and Mg2+. These open reading frames, designated as ddrA and ddrB genes, were identified as the genes of a putative reactivating factor for inactivated diol dehydratase. The genes encoded polypeptides consisting of 610 and 125 amino acid residues with predicted molecular weights of 64,266 and 13,620, respectively. Co-expression of the open reading frame in the 5'-flanking region was stimulatory but not obligatory for conferring the reactivating activity upon E. coli. Thus, the product of this gene was considered not an essential component of the reactivating factor.

Heterologous expression, purification, and properties of diol dehydratase, an adenosylcobalamin-dependent enzyme of Klebsiella oxytoca

Recombinant adenosylcobalamin-dependent diol dehydratase of Klebsiella oxytoca overexpressed in Escherichia coli was purified to homogeneity. The enzyme has a low solubility and was extracted from the crude membrane fraction with 1% Brij 35 in a high recovery. Subsequent chromatography on DEAE-cellulose resulted in 4.9-fold purification of the enzyme in an overall yield of 65%. The enzyme thus obtained showed specific activity comparable to that of the wild-type enzyme of K. oxytoca. The apparent molecular weight determined by nondenaturing gel electrophoresis on a gradient gel was 220,000. The enzyme consists of equimolar amounts of the three subunits with apparent Mr of 60,000 (alpha), 30,000 (beta), and 19,000 (gamma). Therefore, the subunit structure of the enzyme is most likely alpha2beta2gamma2. The recombinant enzyme was also separated into components F and S upon DEAE-cellulose chromatography in the absence of substrate. Components F and S were identified as the beta subunit and alpha2gamma2 complex, respectively. Apparent Km for adenosylcobalamin, 1,2-propanediol, glycerol, and 1,2-ethanediol were 0.83 microM, 0.08 mM, 0.73 mM, and 0.56 mM, respectively. The three genes encoding the subunits of diol dehydratase were overexpressed individually or in various combinations in Escherichia coli. The alpha and gamma subunits mutually required each other for correct folding forming the soluble, active alpha2gamma2 complex (component S). Expression of the beta subunit in a soluble, active form (component F) was promoted by coexpression with both the alpha and gamma subunits, probably by coexistence with component S. These lines of evidence indicate that each subunit mutually affects the folding of the others in this heterooligomer enzyme.

A protein factor is essential for in situ reactivation of glycerol-inactivated adenosylcobalamin-dependent diol dehydratase

The adenosylcobalamin-dependent diol dehydratase of Klebsiella oxytoca undergoes suicidal inactivation by glycerol during catalysis involving irreversible dissociation of the Co-C bond of the coenzyme. The glycerol-inactivated holoenzyme in permeabilized cells (in situ) of E. coli harboring a plasmid containing the diol dehydratase genes and their flanking regions was rapidly reactivated in the presence of free AdoCbl, ATP, and Mg2+. beta,gamma-Methylene ATP was not able to replace ATP. Inactive complexes of the enzyme with aqCbl, CN-Cbl, and PeCbl were activated in situ in the presence of AdoCbl, ATP, and Mg2+, but the complex with AdePeCbl was not. These results suggest that the inactivated holoenzyme is reactivated in situ in the presence of ATP and Mg2+ by exchange of the inactivated coenzyme lacking the adenine moiety for free intact AdoCbl. The in situ reactivation was also observed when an analog lacking the alpha-ribose moiety of the nucleotide loop was used as coenzyme. The results with a recombinant E. coli strains carrying a deletion mutant plasmid demonstrate that certain protein(s) encoded by the 3'-flanking region of the diol dehydratase genes are essential for the in situ reactivation of inactivated diol dehydratase.

Purification and some properties of cobalamin-dependent methionine synthase from rat liver

Cobalamin-dependent methionine synthase was purified from rat liver. The enzyme activity was separated into two peaks upon Mono-Q column chromatography. Peaks I and II of the enzyme, eluted in this order, were purified 18,000- and 44,000-fold in overall yields of 0.7 and 1.8%, respectively. Peak II methionine synthase, the major fraction, was homogeneous as judged by SDS-polyacrylamide gel electrophoresis. The enzyme was a large monomeric protein with an apparent molecular weight of 143,000 Da. Interconversion of the enzyme between the two peaks was not observed during purification procedures. The enzyme required S-adenosylmethionine and a reducing system for activity. Apparent K(m) values of the peak II enzyme for 5-methyltetrahydrofolate and homocysteine were 75 and 1.7 microM, respectively.

An electron paramagnetic resonance study on the mechanism-based inactivation of adenosylcobalamin-dependent diol dehydrase by glycerol and other substrates

Adenosylcobalamin-dependent diol dehydrase undergoes mechanism-based inactivation by glycerol or other substrates during catalysis. X-band electron paramagnetic resonance spectra of holoenzyme were measured at -130 degrees C after reaction with such substrates. After short time of incubation, broad signals assigned to low-spin Co(II) of cob(II)alamin and doublet signals assigned to an organic radical intermediate derived from each substrate were observed with 1,2-propanediol, 1,2-ethanediol, glycerol and meso-2,3-butanediol with the magnitude of their exchange interaction (J-value) decreasing in this order. A substrate with the smaller magnitude of exchange interaction between low-spin Co(II) and an organic radical intermediate seems to be an efficient mechanism-based inactivator. Since the magnitude of exchange interaction decreases with the distance between radical species in a radical pair, these results suggest that a stabilizing effect of holoenzyme on radical intermediates during reactions decreases with the distance between Co(II) and a radical.

Cloning, sequencing, and high level expression of the genes encoding adenosylcobalamin-dependent glycerol dehydrase of Klebsiella pneumoniae

The gld genes encoding adenosylcobalamin-dependent glycerol dehydrase of Klebsiella pneumoniae were cloned by cross-hybridization with a DNA fragment of Klebsiella oxytoca diol dehydrase genes. Since the Escherichia coli clones isolated did not show appreciable enzyme activity, plasmids for high level expression of cloned genes were constructed. The enzyme expressed in E. coli was indistinguishable from the wild-type glycerol dehydrase of K. pneumoniae by the criteria of polyacrylamide gel electrophoretic, immunochemical, and catalytic properties. It was also shown that the recombinant functional enzyme consists of Mr 61,000, 22,000, and 16, 000 subunits. Sequence analysis of the genes revealed four open reading frames separated by 2-12 bases. The sequential three open reading frames from the first to the third (gldA, gldB, and gldC genes) encoded polypeptides of 555, 194, and 141 amino acid residues with predicted molecular weights of 60,659(alpha), 21,355(beta), and 16,104(gamma), respectively. High level expression of these three genes in E. coli produced more than 14-fold higher level of fully active apoenzyme than that in K. pneumoniae. It was thus concluded that these are the genes encoding the subunits of glycerol dehydrase. The deduced amino acid sequences of the three subunits were 71, 58, and 54% identical with those of the alpha, beta, and gamma subunits of diol dehydrase, respectively, but failed to show any apparent homology with other proteins.

Synthesis, properties and microbiological activity of hydrophobic derivatives of vitamin B12

Long chain alkylcobalamins and long chain acyl-cyanocobalamins, two types of hydrophobic derivatives of vitamin B12, were synthesized. It was shown by TLC and determination of the partition coefficient between organic and aqueous phases that the hydrophobicity of alkylcobalamins and acyl-cyanocobalamins increased with the chain length of the alkyl or acyl group introduced into cobalamin. Long chain alkylcobalamins were easily converted to aquacobalamin by photoirradiation, but the first-order rate constant of photolysis decreased with the length of an alkyl group. Long chain acyl-cyanocobalamins were gradually hydrolyzed to cyanocobalamin in neutral or alkaline solution with the pseudo-first order rate constant increasing with the pH of the solution. Stabilization of acyl-cyanocobalamins toward hydrolysis was achieved by introducing a methyl group into the alpha-position of an acyl group. All the long chain alkylcobalamins tested supported the growth of Escherichia coli 215, a cobalamin- or L-methionine-auxotroph, and Lactobacillus leichmannii, although their activity as cobalamin was at most 28% and 15% that of cyanocobalamin for E. coli 215 and L. leichmannii, respectively.

Purification and structural determination of an inhibitor of starfish oocyte maturation from a Bacillus species

Inhibitors of bacterial origins of starfish oocyte maturation were sought to obtain biologically active substances which act on either hormonal signal transduction or cell cycle regulation. An oocyte maturation-inhibiting substance found in culture fluid of a Bacillus species was purified to homogeneity. This substance possessed the nature of a detergent and specifically inhibited 1-methyladenine-induced oocyte maturation (50% inhibitory concentration, 3.3 microM) but not dithiothreitol-induced maturation. Its total structure was established to be the lactone of 3-hydroxy-13-methyltetradecanoyl-Glu-Leu-Leu-Val-Asp-Leu -Leu through COOH of the carboxy-terminal Leu. This structure is identical to surfactin, although although the configuration of the substance's amino acid residues has not yet been determined. Surfactin was shown to be identical with this substance in its inhibitory effect on starfish oocyte maturation as well as its chromatographic and electrophoretic properties. Therefore, it was concluded that the oocyte maturation-inhibiting substance produced by a Bacillus species is surfactin.

Molecular cloning, sequencing, and expression of the genes encoding adenosylcobalamin-dependent diol dehydrase of Klebsiella oxytoca

The pdd genes encoding adenosylcobalamin-dependent diol dehydrase of Klebsiella oxytoca were cloned by using a synthetic oligodeoxyribonucleotide as a hybridization probe followed by measuring the enzyme activity of each clone. Five clones of Escherichia coli exhibited diol dehydrase activity. At least one of them was shown to express diol dehydrase genes under control of their own promoter. Sequence analysis of the DNA fragments found in common in the inserts of these five clones and the flanking regions revealed four open reading frames separated by 10-18 base pairs. The sequential three open reading frames from the second to the fourth (pddA, pddB, and pddC genes) encoded polypeptides of 554, 224, and 173 amino acid residues with predicted molecular weights of 60,348 (alpha), 24,113 (beta), and 19,173 (gamma), respectively. Overexpression of these three genes in E. coli produced more than 50-fold higher level of functional apodiol dehydrase than that in K. oxytoca. The recombinant enzyme was indistinguishable from the wild-type one of K. oxytoca by the criteria of polyacrylamide gel electrophoretic and immunochemical properties. It was thus concluded that these three gene products are the subunits of functional diol dehydrase. Comparisons of the deduced amino acid sequences of the three subunits with other proteins failed to reveal any apparent homology.

Microbiological activities of nucleotide loop-modified analogues of vitamin B12

Novel vitamin B12 analogues in which the D-ribose moiety of the nucleotide loop was replaced by an oligomethylene group and a trimethylene analogue containing imidazole instead of 5,6-dimethylbenzimidazole as well as cobinamide methyl phosphate were tested for biological activities with Escherichia coli 215, a B12- or methionine-auxotroph, and Lactobacillus leichmannii ATCC 7830 as test organisms. A cyano form of 5,6-dimethylbenzimidazolyl tetramethylene, trimethylene and hexamethylene analogues supported the growth of L. leichmannii in this order. 5,6-Dimethylbenzimidazolyl dimethylene and imidazolyl trimethylene analogues did not show B12 activity and behaved as weak B12 antagonists when added together with cyanocobalamin. An adenosyl form of the biologically active analogues served as coenzymes for ribonucleotide reductase of this bacterium, whereas that of the inactive analogues did not. The latter acted as weak competitive inhibitors against adenosylcobalamin. On the contrary, all the analogues did not support the growth of E. coli 215 at all by themselves and inhibited the growth when added with a suboptimum level of cyanocobalamin. A methyl form of the analogues also did not support the growth of E. coli 215, although they served as active coenzymes for methionine synthase of the bacterium. Since unlabeled analogues strongly inhibited the uptake of [3H]cyanocobalamin by this bacterium, it seems likely that the analogues exert their anti-B12 activity toward E. coli 215 by blocking the B12-transport system.

The synthesis of a pyridyl analog of adenosylcobalamin and its coenzymic function in the diol dehydratase reaction

A novel analog of adenosylcobalamin in which 5,6-dimethylbenzimidazole and D-ribose moieties of the nucleotide loop are replaced by pyridine and the trimethylene group, respectively, was synthesized and examined for coenzymic function. The coordination of pyridine to the cobalt atom in this analog was stronger than that of 5,6-dimethylbenzimidazole in the corresponding homolog. The adenosyl form of pyridyl analog served as partially active coenzyme for diol dehydratase. The kcat/Km values calculated from the initial velocity indicate that this analog is a better coenzyme than the 5,6-dimethylbenzimidazolyl or imidazolyl counterpart. However, the reaction with the pyridyl analog as coenzyme was accompanied with a concomitant inactivation during catalysis, with a kcat/Kinact value 50-100 times lower than that for adenosylcobalamin or the 5,6-dimethylbenzimidazolyl analog. Therefore, it can be concluded that the 5,6-dimethylbenzimidazole moiety of adenosylcobalamin is important for continuous progress of a catalytic cycle by protecting the reactive intermediates from side reactions.

Importance of the nucleotide loop moiety coordinated to the cobalt atom of adenosylcobalamin for coenzymic function in the diol dehydrase reaction

Three analogs of adenosylcobalamin were synthesized and their coenzymic properties in the diol dehydrase reaction were studied. Neither adenosylcobinamide nor adenosylcobinamide phosphate was active as coenzyme and showed very low affinity for apoenzyme, irrespective of the presence of nucleotide loop fragments, such as 5,6-dimethylbenzimidazole, alpha-D-ribazole, or alpha-D-ribazole-3'-phosphate. The coordination of pyridine to the cobalt atom neither confers the coenzymic function upon adenosylcobinamide nor strengthens the inhibitory effect of cyanoaquacobinamide and methylcobinamide significantly. The analog of adenosylcobalamin in which the N-3 position of 5,6-dimethylbenz-imidazole is methylated was also not active as coenzyme and showed very low affinity for apoenzyme. Since 3,5,6-trimethylbenzimidazole in this analog is no longer coordinated to the cobalt atom, these results show that at least a part of the nucleotide loop moiety coordinated to the cobalt atom of adenosylcobalamin is essential for tight binding to the apoenzyme and therefore for manifestation of coenzymic function.

Adenosylcobinamide methyl phosphate as a pseudocoenzyme for diol dehydrase

Adenosylcobinamide methyl phosphate, a novel analog of adenosylcobalamin lacking the nucleotide loop moiety, was synthesized. It did not show detectable coenzymic activity but behaved as a strong competitive inhibitor against AdoCbl with relatively high affinity (Ki = 2.5 microM). When apoenzyme was incubated at 37 degrees C with this analog in the presence of substrate, the Co-C bond of the analog was almost completely and irreversibly cleaved within 10 min, forming an enzyme-bound Co(II)-containing species. The cleavage was not observed in the absence of substrate. The Co-C bond cleavage in the presence of substrate was not catalytic but stoichiometric, implying that the Co-C bond of the analog undergoes activation when the analog binds to the active site of the enzyme. 5'-Deoxyadenosine was the only product derived from the adenosyl group of the analog upon the Co-C bond cleavage. Apoenzyme did not undergo modification during this process. Therefore, it seems likely that adenosylcobinamide methyl phosphate acts as a pseudocoenzyme or a potent suicide coenzyme. Since adenosylcobinamide neither functions as coenzyme nor binds tightly to apoenzyme, it can be concluded that the phosphodiester moiety of the nucleotide loop of adenosylcobalamin is essential for tight binding to apoenzyme and therefore for subsequent activation of the Co-C bond and catalysis. It is also evident that the nucleotide loop is obligatory for the normal progress of catalytic cycle.

Roles of the D-ribose and 5,6-dimethylbenzimidazole moieties of the nucleotide loop of adenosylcobalamin in manifestation of coenzymic function in the diol dehydrase reaction

Coenzyme analogs in which the D-ribose moiety of the nucleotide loop was replaced by an oligomethylene group and a trimethylene analog containing imidazole instead of 5,6-dimethylbenzimidazole were synthesized. Coordination of the 5,6-dimethylbenzimidazole to the cobalt atom in these analogs was much weaker than that in cobalamins. The replacement of this base with imidazole did not significantly alter the strength of the coordination to the cobalt atom. 5,6-Dimethylbenzimidazolyl trimethylene and tetramethylene and imidazolyl trimethylene analogs were partially active as coenzymes in the diol dehydrase reaction in this order as judged by kcat, but the others were not active as coenzymes and were weak competitive inhibitors. This indicates that neither the alpha-D-ribofuranose ring nor the functional groups of the ribose moiety are essential for coenzymic function. There was an optimum loop size of the analogs for catalysis and for tight binding to the apoenzyme, which corresponds to the loop size of cobalamins. Therefore, the D-ribose moiety seems important as a spacer to keep the base in the proper position. The reaction with the imidazolyl trimethylene analog as coenzyme was accompanied with concomitant rapid inactivation during catalysis. The inactivation occurred only in the presence of substrate. Upon inactivation with this analog, 5'-deoxyadenosine and a B12r-like species were formed from the adenosyl group and the rest of the analog molecule, respectively, without modification of the apoenzyme. Therefore, it can be concluded that this is a kind of suicide inactivation which occurred from one of the intermediates in the normal catalytic process. The dimethylbenzo moiety of the regular coenzyme thus seems to play an important role in preventing the intermediate complexes from inactivation during catalysis.

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.

Roles of the beta-D-ribofuranose ring and the functional groups of the D-ribose moiety of adenosylcobalamin in the diol dehydratase reaction

Four analogs of adenosylcobalamin (AdoCbl) modified in the D-ribose moiety of the Co beta ligand were synthesized, and their coenzymic properties were studied with diol dehydratase of Klebsiella pneumoniae ATCC 8724. 2'-Deoxyadenosylcobalamin (2'-dAdoCbl) and 3'-deoxyadenosylcobalamin (3'-dAdoCbl) were active as coenzyme. 2',3'-Secoadenosylcobalamin (2',3'-secoAdoCbl), an analog bearing the same functional groups as AdoCbl but nicked between the 2' and 3' positions in the ribose moiety, and its 2',3'-dialdehyde derivative (2',3'-secoAdoCbl dialdehyde) were totally inactive analogs of the coenzyme. It is therefore evident that the beta-D-ribofuranose ring itself, possibly its rigid structure, is essential and much more important than the functional groups of the ribose moiety for coenzymic function (relative importance: beta-D-ribofuranose ring much greater than 3'-OH greater than 2'-OH greater than ether group). With 2'-dAdoCbl and 3'-dAdoCbl as coenzymes, an absorption peak at 478 nm appeared during enzymatic reaction, suggesting homolysis of the C-Co bond to form cob(II)alamin as intermediate. In the absence of substrate, the complexes of the enzyme with these active analogs underwent rapid inactivation by oxygen. This suggests that their C-Co bond is activated even in the absence of substrate by binding to the apoprotein. No significant spectral changes were observed with 2',3'-secoAdoCbl upon binding to the apoenzyme. In contrast, spectroscopic observation indicates that 2'3'-secoAdoCbl dialdehyde, another inactive analog, underwent gradual and irreversible cleavage of the C-Co bond by interaction with the apodiol dehydratase, forming the enzyme-bound cob(II)alamin without intermediates.

A factor potentiating serotonin in the induction of germinal vesicle breakdown in surf clam oocytes

Simultaneous addition of an aliquot of body fluid obtained from the surf clam, Spisula solidissima, enhanced oocyte germinal vesicle breakdown induced with serotonin but not with KCl. When the body fluid and serotonin were added sequentially to the oocytes, potentiation did not occur. Body fluids of both males and females were effective at a 200-fold dilution. The factor is stable when treated with heat, acid, base, trypsin and pronase. It is hydrophobic and not dialyzable through tubing with a molecular weight cutoff of 1000 daltons. The factor is probably not a protein.

Activation and cleavage of the carbon-cobalt bond of adeninylethylcobalamin by diol dehydrase

Adeninylethylcobalamin (AdeEtCbl) underwent cleavage of the C-Co bond by interaction with apoprotein of diol dehydrase from Klebsiella pneumoniae ATCC 8724, although this analog was quite inactive as coenzyme. Spectroscopic observation indicates that AdeEtCbl was converted to the enzyme-bound hydroxocobalamin without intermediates. The conversion was stoichiometric (1:1) and obeyed the second-order reaction kinetics (k = 0.027 min-1 microM-1 at 37 degrees C) depending upon concentrations of apoprotein and AdeEtCbl. This suggests that the complex formation is the rate-determining step and that AdeEtCbl undergoes rapid C-Co bond cleavage once it binds to the apoenzyme. Substrates and oxygen did apparently not affect the rate of the C-Co bond cleavage. The experiments using [adenine-U-14C]AdeEtCbl and [1(3)-3H]glycerol demonstrated that 9-ethyladenine was the only product formed from the adeninylethyl group of AdeEtCbl during the conversion and that an additional hydrogen atom in the 9-ethyladenine is not derived from the substrate. 1H NMR measurement of the 9-ethyladenine formed enzymatically from AdeEtCbl and DL-1,2-[1,1,2-2H3]propanediol also led to the same conclusion. All of these results indicate that the C-Co bond of AdeEtCbl is activated by diol dehydrase and undergoes heterolysis forming Co(III) and a carbanion or a carbanion-like species, in clear contrast to the homolysis of the C-Co bond of adenosylcobalamin in the normal catalytic process. 9-Ethyladenine formed remained tightly associated with the enzyme. Longer chain homologs, i.e. adeninylpropylcobalamin, adeninylbutylcobalamin, and adeninylpentylcobalamin did not undergo such cleavage of the C-Co bond by diol dehydrase.

Re-investigation of the protein structure of coenzyme B12-dependent diol dehydrase

We have purified diol dehydrase, an adenosylcobalamin-dependent enzyme, from Klebsiella pneumoniae by two different procedures to re-investigate its protein structure; one including its extraction with detergent from the membrane fraction, and the other consisting of only chromatographic separations of the soluble fraction. The enzyme preparations obtained by these two methods were different in the subunit structure, but both are identical in molecular weight, and in-enzymological and immunochemical properties. In addition, the enzyme preparation obtained from the membrane fraction dissociated reversibly into two dissimilar protein components (F and S) in the absence of substrate, as did the preparation from the soluble fraction. Although the subunit multiplicity of component S might be partly due to proteolytic cleavage during the enzyme purification as revealed by limited digestion with trypsin, component F is not a product of proteolytic cleavage of component S, but a primordial and essential constituent of the enzyme.

The synthesis of adenine-modified analogs of adenosylcobalamin and their coenzymic function in the reaction catalyzed by diol dehydrase

Five analogs of adenosylcobalamin modified in the adenine moiety of the Co beta ligand were synthesized and tested for coenzymic function with diol dehydrase of Klebsiella pneumoniae ATCC 8724. 1-Deaza and 3-deaza analogs of adenosylcobalamin were active as coenzyme, whereas 7-deaza and N6,N6-dimethyl derivatives and guanosylcobalamin did not show detectable coenzymic activity. 7-Deaza and N6,N6-dimethyl analogs acted as strong competitive inhibitors with respect to adenosylcobalamin. The formation of cob(II)alamin as intermediate in the catalytic reaction was spectroscopically observed with catalytically active complexes of the enzyme with 1-deaza and 3-deaza analogs in the presence of 1,2-propanediol, but not with complexes with the inactive analogs. Oxygen sensitivity of the enzyme-analog complexes suggests that the carbon-cobalt bond of 1-deaza and 3-deaza analogs becomes activated by the enzyme even in the absence of substrate. These results indicate that the importance of the nitrogen atoms in the adenine moiety of the coenzyme for manifestation of catalytic function and for activation of the carbon-cobalt bond decreases in the following order: N-7 greater than 6-NH2 greater than N-3 greater than N-1. The dissociation constant for 5'-deoxyadenosine determined by equilibrium dialysis at 37 degrees C was about 23 microM.

Identification of a dephosphorylated oxidation product of the molybdenum cofactor as 2-(1,2-dihydroxyethyl)thieno[3,2-g]pterin

A new method was developed for the synthesis of 2-(1,2-dihydroxyethyl)thieno[3,2-g]pterin and related 2-substituted thienopterins. A dephosphorylated fluorescent oxidation product of the molybdenum cofactor isolated from xanthine oxidase (EC 1.2.3.2) was identified as 2-(1,2-dihydroxyethyl)thieno[3,2-g]pterin by comparison of electronic and fluorescence spectra and TLC behaviors with those of the synthetic compound.

The binding site for the adenosyl group of coenzyme B12 in diol dehydrase

The binding of cob(II)alamin (CblII) and 5'-deoxyadenosine to diol dehydrase was studied spectroscopically and with [U-14C]5'-deoxyadenosine. CblII was bound to this enzyme forming a tight 1:1 complex which was resistant to oxidation by O2 even in the presence of CN-. An irreversible 1:1:1 ternary complex was formed between enzyme, CblII, and 5'-deoxyadenosine, when the enzyme was incubated first with the nucleoside and then with CblII. When this order of addition of the constituents was reversed, no 5'-deoxyadenosine was bound to the enzyme-CblII complex. Hydroxocobalamin could also bind to the enzyme together with the nucleoside, while other cob(III)alamins bearing a bulkier Co beta ligand displaced the nucleoside upon binding to the enzyme. The binding of [U-14C]5'-deoxyadenosine was strongly inhibited by unlabeled 5'-deoxy-ara-adenosine, 4',5'-anhydroadenosine, adenosine, adenine, and 5',8-cyclic adenosine, in this order, but not by 5'-deoxyuridine. These results constitute direct evidence for the presence of the binding site for the adenosyl group of adenosylcobalamin, which is spatially limited to and highly specific for adenine nucleosides. The binding of 5'-deoxyadenosine to the apoenzyme was reversible.

Functional role of cysteinyl residues in tryptophanase

Holotryptophanase inactivated by oxidation of cysteinyl residues showed a different absorption spectrum from the native enzyme. At pH 8.0, the native enzyme preferentially existed as a 337-nm species (active form), whereas in the inactive enzyme a 420-nm species (inactive form) was dominant. During the reactivation of the enzyme by reduction with dithiothreitol, an increase at 337 nm and a decrease at 420 nm were observed with concomitant increase in enzymatic activity, which was accompanied by the appearance of two cysteinyl residues per monomer. Specific S-cyanylation of cysteinyl residues by nitrothiocyanobenzoic-acid-inactivated apotryptophanase with the modification of one cysteinyl residue per monomer, whereas holotryptophanase was highly resistant to inactivation with nitrothiocyanobenzoic acid. The essential role of the active-site-bound pyridoxal 5'-phosphate in protection against inactivation was confirmed by the agreement of the K1/2 (protection) of 5.0 microM for pyridoxal 5'-phosphate with Km of 2.0 microM in enzyme catalysis. The inactivation by nitrothiocyanobenzoic acid caused a similar shift in the equilibrium between the 337-nm species and 420-nm species, i.e. decrease of the 337-nm species and increase of the 420-nm species. From the pH dependence of the equilibrium between these two species, pKa of 7.9 and 7.4 was obtained for the inactive and the dithiothreitol-activated enzyme, respectively, indicating that cysteinyl residue(s) participated in lowering the pKa of the interconversion between the 337-nm species (active form) and 420-nm species (inactive form). The possible role of cysteinyl residues in the function of tryptophanase is discussed.

Ligand exchange reactions of diol dehydrase-bound cobalamins and the effect of the nucleoside binding

The inactive complex of diol dehydrase with hydroxocobalamin was resolved by treatment with SO2-3, followed by dialysis to remove SO2-3, giving the apoenzyme which was reconstitutable into catalytically active holoenzyme upon addition of adenosylcobalamin ("re-activation"). Spectral evidence showed that the enzyme-bound hydroxocobalamin undergoes a Co beta-ligand exchange reaction forming sulfitocobalamin. Sulfitocobalamin was bound to diol dehydrase only loosely, and therefore dissociated from the enzyme. In contrast, neither the enzyme-hydroxocobalamin-5'-deoxyadenosine nor the enzyme-hydroxocobalamin-adenosine complex was resolved and thus re-activated by this procedure. It was shown spectroscopically that the hydroxocobalamin in these complexes does not react with SO2-3, or even with CN-, indicating that the OH group in the Co beta-position was blocked spatially by these enzyme-bound nucleosides. Neither O2-inactivated holoenzyme nor the holoenzyme inactivated suicidally by glycerol or 1,2-ethanediol during dehydration reaction was also re-activated by the same procedure. The complex of the enzyme with cyanocobalamin or methylcobalamin was not resolvable by the SO2-3 treatment. This was because these cobalamins bound to the enzyme were not subject to a ligand exchange reaction with SO2-3.