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

Coenzyme B12-dependent eliminases: Diol and glycerol dehydratases and ethanolamine ammonia-lyase

Adenosylcobalamin (AdoCbl) or coenzyme B₁₂-dependent enzymes catalyze intramolecular group-transfer reactions and ribonucleotide reduction in a wide variety of organisms from bacteria to animals. They use a super-reactive primary-carbon radical formed by the homolysis of the coenzyme's Co-C bond for catalysis and thus belong to the larger class of "radical enzymes." For understanding the general mechanisms of radical enzymes, it is of great importance to establish the general mechanism of AdoCbl-dependent catalysis using enzymes that catalyze the simplest reactions-such as diol dehydratase, glycerol dehydratase and ethanolamine ammonia-lyase. These enzymes are often called "eliminases." We have studied AdoCbl and eliminases for more than a half century. Progress has always been driven by the development of new experimental methodologies. In this chapter, we describe our investigations on these enzymes, including their metabolic roles, gene cloning, preparation, characterization, activity assays, and mechanistic studies, that have been conducted using a wide range of biochemical and structural methodologies we have developed.

Experimental study of hydrogen bonding potentially stabilizing the 5'-deoxyadenosyl radical from coenzyme B12

Coenzyme B(12) can assist radical enzymes that accomplish the vicinal interchange of a hydrogen atom with a functional group. It has been proposed that the Co-C bond homolysis of coenzyme B(12) to cob(II)alamin and the 5'-deoxyadenosyl radical is aided by hydrogen bonding of the corrin C19-H to the 3'-O of the ribose moiety of the incipient 5'-deoxyadenosyl radical, which is stabilized by 30 kJ mol(-1) (B. Durbeej et al., Chem. Eur. J. 2009, 15, 8578-8585). The diastereoisomers (R)- and (S)-2,3-dihydroxypropylcobalamin were used as models for coenzyme B(12). A downfield shift of the NMR signal for the C19-H proton was observed for the (R)-isomer (δ=4.45 versus 4.01 ppm for the (S)-isomer) and can be ascribed to an intramolecular hydrogen bond between the C19-H and the oxygen of CHOH. Crystal structures of (R)- and (S)-2,3-dihydroxypropylcobalamin showed C19-H⋅⋅⋅O distances of 3.214(7) Å (R-isomer) and 3.281(11) Å (S-isomer), which suggest weak hydrogen-bond interactions (-ΔG<6 kJ mol(-1)) between the CHOH of the dihydroxypropyl ligand and the C19-H. Exchange of the C19-H, which is dependent on the cobalt redox state, was investigated with cob(I)alamin, cob(II)alamin, and cob(III)alamin by using NMR spectroscopy to monitor the uptake of deuterium from deuterated water in the pH range 3-11. No exchange was found for any of the cobalt oxidation states. 3',5'-Dideoxyadenosylcobalamin, but not the 2',5'-isomer, was found to act as a coenzyme for glutamate mutase, with a 15-fold lower k(cat)/K(M) than 5'-deoxyadenosylcobalamin. This indicates that stabilization of the 5'-deoxyadenosyl radical by a hydrogen bond that involves the C19-H and the 3'-OH group of the cofactor is, at most, 7 kJ mol(-1) (-ΔG). Examination of the crystal structure of glutamate mutase revealed additional stabilizing factors: hydrogen bonds between both the 2'-OH and 3'-OH groups and glutamate 330. The actual strength of a hydrogen bond between the C19-H and the 3'-O of the ribose moiety of the 5'-deoxyadenosyl group is concluded not to exceed 6 kJ mol(-1) (-ΔG).

Homoadenosylcobalamins as probes for exploring the active sites of coenzyme B12-dependent diol dehydratase and ethanolamine ammonia-lyase

[Omega-(Adenosyl)alkyl]cobalamins (homoadenosylcobalamins) are useful analogues of adenosylcobalamin to get information about the distance between Co and C5', which is critical for Co-C bond activation. In order to use them as probes for exploring the active sites of enzymes, the coenzymic properties of homoadenosylcobalamins for diol dehydratase and ethanolamine ammonia-lyase were investigated. The kcat and kcat/Km values for adenosylmethylcobalamin were about 0.27% and 0.15% that for the regular coenzyme with diol dehydratase, respectively. The kcat/kinact value showed that the holoenzyme with this analogue becomes inactivated on average after about 3000 catalytic turnovers, indicating that the probability of inactivation during catalysis is almost 500 times higher than that for the regular holoenzyme. The kcat value for adenosylmethylcobalamin was about 0.13% that of the regular coenzyme for ethanolamine ammonia-lyase, as judged from the initial velocity, but the holoenzyme with this analogue underwent inactivation after on average about 50 catalytic turnovers. This probability of inactivation is 3800 times higher than that for the regular holoenzyme. When estimated from the spectra of reacting holoenzymes, the steady state concentration of cob(II)alamin intermediate from adenosylmethylcobalamin was very low with either diol dehydratase or ethanolamine ammonia-lyase, which is consistent with its extremely low coenzymic activity. In contrast, neither adenosylethylcobalamin nor adeninylpentylcobalamin served as active coenzyme for either enzyme and did not undergo Co-C bond cleavage upon binding to apoenzymes.

Enzymatic radical catalysis: coenzyme B12-dependent diol dehydratase

A peculiar function resides in a peculiar structure. Coenzyme B(12) or adenosylcobalamin, a naturally occurring organometallic compound, serves as a cofactor for enzymatic radical reactions. How do the enzymes form catalytic radicals at the active sites? How do the enzymes utilize and control the high reactivity of the radicals for catalysis? Recently, three-dimensional structures of several radical-containing or radical-forming enzymes including B(12) enzymes have been reported, enabling the analysis of the fine mechanisms of the action of these interesting enzymes. Our biochemical, mutational, and crystallographic studies as well as theoretical calculations on diol dehydratase, an adenosylcobalamin-dependent enzyme, revealed that its structure is adapted for its function-that is, activation of the Cobond;C bond toward homolysis, abstraction of a specific hydrogen atom from the substrate and its recombination to a particular product, and transition state stabilization in the hydroxyl group migration of a substrate-derived radical. The functions of K(+) and the active-site amino acid residues in enzyme catalysis are also investigated. Based on the results, the fine mechanism of the enzyme and the energetic feasibility of enzymatic radical catalysis are described here.

Internal degrees of freedom, structural motifs, and conformational energetics of the 5'-deoxyadenosyl radical: implications for function in adenosylcobalamin-dependent enzymes. A computational study

The potential energy surface of the free 5'-deoxyadenosyl radical in the gas phase is explored using density functional and second-order Møller-Plesset perturbation theories with 6-31G(d) and 6-31++G(d,p) basis sets and interpreted in terms of attractive and repulsive interactions. The 5',8-cyclization is found to be exothermic by approximately 20 kcal/mol but kinetically unfavorable; the lowest cyclization transition state (TS) lies about 7 kcal/mol higher than the highest TS for conversion between most of the open isomers. In open isomers, the two energetically most important attractive interactions are the hydrogen bonds (a) between the 2'-OH group and the N3 adenine center and (b) between the 2'-OH and 3'-OH groups. The relative ribose-adenine rotation about the C1'-N9 glycosyl bond in a certain range changes the energy by as much as 10-15 kcal/mol, the origin being (i) the repulsive 2'-H.H-C8 and O1'.N3 and (ii) the attractive 2'-OH.N3 ribose-adenine interactions. The hypothetical synergy between the glycosyl rotation and the Co-C bond scission may contribute to the experimentally established labilization of the Co-C bond in enzyme-bound adenosylcobalamin. The computational results are not inconsistent with the rotation about the C1'-N9 glycosyl bond being the principal coordinate for long-range radical migration in coenzyme B(12)-dependent enzymes. The effect of the protein environment on the model system results reported here remains an open question.

Substrate-induced conformational change of a coenzyme B12-dependent enzyme: crystal structure of the substrate-free form of diol dehydratase

Substrate binding triggers catalytic radical formation through the cobalt-carbon bond homolysis in coenzyme B12-dependent enzymes. We have determined the crystal structure of the substrate-free form of Klebsiella oxytoca diol dehydratase*cyanocobalamin complex at 1.85 A resolution. The structure contains two units of the heterotrimer consisting of alpha, beta, and gamma subunits. As compared with the structure of its substrate-bound form, the beta subunits are tilted by approximately 3 degrees and cobalamin is also tilted so that pyrrole rings A and D are significantly lifted up toward the substrate-binding site, whereas pyrrole rings B and C are only slightly lifted up. The structure revealed that the potassium ion in the substrate-binding site of the substrate-free enzyme is also heptacoordinated; that is, two oxygen atoms of two water molecules coordinate to it instead of the substrate hydroxyls. A modeling study in which the structures of both the cobalamin moiety and the adenine ring of the coenzyme were superimposed onto those of the enzyme-bound cyanocobalamin and the adenine ring-binding pocket, respectively, demonstrated that the distortions of the Co-C bond in the substrate-free form are already marked but slightly smaller than those in the substrate-bound form. It was thus strongly suggested that the Co-C bond becomes largely activated (labilized) when the coenzyme binds to the apoenzyme even in the absence of substrate and undergoes homolysis through the substrate-induced conformational changes of the enzyme. Kinetic coupling of Co-C bond homolysis with hydrogen abstraction from the substrate shifts the equilibrium to dissociation.

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.