Molecular basis for specificities of reactivating factors for adenosylcobalamin-dependent diol and glycerol dehydratases

Reactivating chaperones for coenzyme B12-dependent diol and glycerol dehydratases and ethanolamine ammonia-lyase

Adenosylcobalamin (AdoCbl) or coenzyme B₁₂-dependent enzymes tend to undergo mechanism-based inactivation during catalysis or inactivation in the absence of substrate. Such inactivation may be inevitable because they use a highly reactive radical for catalysis, and side reactions of radical intermediates result in the damage of the coenzyme. How do living organisms address such inactivation when enzymes are inactivated by undesirable side reactions? We discovered reactivating factors for radical B₁₂ eliminases. They function as releasing factors for damaged cofactor(s) from enzymes and thus mediate their exchange for intact AdoCbl. Since multiple turnovers and chaperone functions were demonstrated, they were renamed "reactivases" or "reactivating chaperones." They play an essential role in coenzyme recycling as part of the activity-maintaining systems for B₁₂ enzymes. In this chapter, we describe our investigations on reactivating chaperones, including their discovery, gene cloning, preparation, characterization, activity assays, and mechanistic studies, that have been conducted using a wide range of biochemical and structural methods that we have developed.

Statistical Optimization of 1,3-Propanediol (1,3-PD) Production from Crude Glycerol by Considering Four Objectives: 1,3-PD Concentration, Yield, Selectivity, and Productivity

This study investigated the biological conversion of crude glycerol generated from a commercial biodiesel production plant as a by-product to 1,3-propanediol (1,3-PD). Statistical analysis was employed to derive a statistical model for the individual and interactive effects of glycerol, (NH₄)₂SO₄, trace elements, pH, and cultivation time on the four objectives: 1,3-PD concentration, yield, selectivity, and productivity. Optimum conditions for each objective with its maximum value were predicted by statistical optimization, and experiments under the optimum conditions verified the predictions. In addition, by systematic analysis of the values of four objectives, optimum conditions for 1,3-PD concentration (49.8 g/L initial glycerol, 4.0 g/L of (NH₄)₂SO₄, 2.0 mL/L of trace element, pH 7.5, and 11.2 h of cultivation time) were determined to be the global optimum culture conditions for 1,3-PD production. Under these conditions, we could achieve high 1,3-PD yield (47.4%), 1,3-PD selectivity (88.8%), and 1,3-PD productivity (2.1/g/L/h) as well as high 1,3-PD concentration (23.6 g/L).

Diol Dehydratase-Reactivase Is Essential for Recycling of Coenzyme B12 in Diol Dehydratase

Holoenzymes of adenosylcobalamin-dependent diol and glycerol dehydratases undergo mechanism-based inactivation by glycerol and O2 inactivation in the absence of substrate, which accompanies irreversible cleavage of the coenzyme Co-C bond. The inactivated holodiol dehydratase and the inactive enzyme·cyanocobalamin complex were (re)activated by incubation with NADH, ATP, and Mg(2+) (or Mn(2+)) in crude extracts of Klebsiella oxytoca, suggesting the presence of a reactivating system in the extract. The reducing system with NADH could be replaced by FMNH2. When inactivated holoenzyme or the enzyme·cyanocobalamin complex, a model of inactivated holoenzyme, was incubated with purified recombinant diol dehydratase-reactivase (DD-R) and an ATP:cob(I)alamin adenosyltransferase in the presence of FMNH2, ATP, and Mg(2+), diol dehydratase activity was restored. Among the three adenosyltransferases (PduO, EutT, and CobA) of this bacterium, PduO and CobA were much more efficient for the reactivation than EutT, although PduO showed the lowest adenosyltransfease activity toward free cob(I)alamin. These results suggest that (1) diol dehydratase activity is maintained through coenzyme recycling by a reactivating system for diol dehydratase composed of DD-R, PduO adenosyltransferase, and a reducing system, (2) the releasing factor DD-R is essential for the recycling of adenosycobalamin, a tightly bound, prosthetic group-type coenzyme, and (3) PduO is a specific adenosylating enzyme for the DD reactivation, whereas CobA and EutT exert their effects through free synthesized coenzyme. Although FMNH2 was mainly used as a reductant in this study, a natural reducing system might consist of PduS cobalamin reductase and NADH.

Essential roles of nucleotide-switch and metal-coordinating residues for chaperone function of diol dehydratase-reactivase

Diol dehydratase-reactivase (DD-R) is a molecular chaperone that reactivates inactivated holodiol dehydratase (DD) by cofactor exchange. Its ADP-bound and ATP-bound forms are high-affinity and low-affinity forms for DD, respectively. Among DD-Rs mutated at the nucleotide-binding site, neither the Dα8N nor Dα413N mutant was effective as a reactivase. Although Dα413N showed ATPase activity, it did not mediate cyanocobalamin (CN-Cbl) release from the DD·CN-Cbl complex in the presence of ATP or ADP and formed a tight complex with apoDD even in the presence of ATP, suggesting the involvement of Aspα413 in the nucleotide switch. In contrast, Dα8N showed very low ATPase activity and did not mediate CN-Cbl release from the complex in the presence of ATP, but it did cause about 50% release in the presence of ADP. The complex formation of this mutant with DD was partially reversed by ATP, suggesting that Aspα8 is involved in the ATPase activity but only partially in the nucleotide switch. Among DD-Rs mutated at the Mg(2+)-binding site, only Eβ31Q was about 30% as active as wild-type DD-R and formed a tight complex with apoDD, indicating that the DD-R β subunit is not absolutely required for reactivation. If subunit swapping occurs between the DD-R β and DD β subunits, Gluβ97 of DD would coordinate to Mg(2+). The complex of Eβ97Q DD with CN-Cbl was not activated by wild-type DD-R. No complex was formed between this mutant and wild-type DD-R, indicating that the coordination of Gluβ97 to Mg(2+) is essential for subunit swapping and therefore for (re)activation.

Novel coenzyme B12-dependent interconversion of isovaleryl-CoA and pivalyl-CoA

5'-Deoxyadenosylcobalamin (AdoCbl)-dependent isomerases catalyze carbon skeleton rearrangements using radical chemistry. We have recently characterized a fusion protein that comprises the two subunits of the AdoCbl-dependent isobutyryl-CoA mutase flanking a G-protein chaperone and named it isobutyryl-CoA mutase fused (IcmF). IcmF catalyzes the interconversion of isobutyryl-CoA and n-butyryl-CoA, whereas GTPase activity is associated with its G-protein domain. In this study, we report a novel activity associated with IcmF, i.e. the interconversion of isovaleryl-CoA and pivalyl-CoA. Kinetic characterization of IcmF yielded the following values: a K(m) for isovaleryl-CoA of 62 ± 8 μM and V(max) of 0.021 ± 0.004 μmol min(-1) mg(-1) at 37 °C. Biochemical experiments show that an IcmF in which the base specificity loop motif NKXD is modified to NKXE catalyzes the hydrolysis of both GTP and ATP. IcmF is susceptible to rapid inactivation during turnover, and GTP conferred modest protection during utilization of isovaleryl-CoA as substrate. Interestingly, there was no protection from inactivation when either isobutyryl-CoA or n-butyryl-CoA was used as substrate. Detailed kinetic analysis indicated that inactivation is associated with loss of the 5'-deoxyadenosine moiety from the active site, precluding reformation of AdoCbl at the end of the turnover cycle. Under aerobic conditions, oxidation of the cob(II)alamin radical in the inactive enzyme results in accumulation of aquacobalamin. Because pivalic acid found in sludge can be used as a carbon source by some bacteria and isovaleryl-CoA is an intermediate in leucine catabolism, our discovery of a new isomerase activity associated with IcmF expands its metabolic potential.

Class I ribonucleotide reductases: metallocofactor assembly and repair in vitro and in vivo

Incorporation of metallocofactors essential for the activity of many enyzmes is a major mechanism of posttranslational modification. The cellular machinery required for these processes in the case of mono- and dinuclear nonheme iron and manganese cofactors has remained largely elusive. In addition, many metallocofactors can be converted to inactive forms, and pathways for their repair have recently come to light. The class I ribonucleotide reductases (RNRs) catalyze the conversion of nucleotides to deoxynucleotides and require dinuclear metal clusters for activity: an Fe(III)Fe(III)-tyrosyl radical (Y•) cofactor (class Ia), a Mn(III)Mn(III)-Y• cofactor (class Ib), and a Mn(IV)Fe(III) cofactor (class Ic). The class Ia, Ib, and Ic RNRs are structurally homologous and contain almost identical metal coordination sites. Recent progress in our understanding of the mechanisms by which the cofactor of each of these RNRs is generated in vitro and in vivo and by which the damaged cofactors are repaired is providing insight into how nature prevents mismetallation and orchestrates active cluster formation in high yields.

Diol dehydratase-reactivating factor is a reactivase--evidence for multiple turnovers and subunit swapping with diol dehydratase

Adenosylcobalamin-dependent diol dehydratase (DD) undergoes suicide inactivation by glycerol, one of its physiological substrates, resulting in the irreversible cleavage of the coenzyme Co-C bond. The damaged cofactor remains tightly bound to the active site. The DD-reactivating factor reactivates the inactivated holoenzyme in the presence of ATP and Mg(2+) by mediating the exchange of the tightly bound damaged cofactor for free intact coenzyme. In this study, we demonstrated that this reactivating factor mediates the cobalamin exchange not stoichiometrically but catalytically in the presence of ATP and Mg(2+). Therefore, we concluded that the reactivating factor is a sort of enzyme. It can be designated DD reactivase. The reactivase showed broad specificity for nucleoside triphosphates in the activation of the enzyme·cyanocobalamin complex. This result is consistent with the lack of specific interaction with the adenine ring of ADP in the crystal structure of the reactivase. The specificities of the reactivase for divalent metal ions were also not strict. DD formed 1:1 and 1:2 complexes with the reactivase in the presence of ADP and Mg(2+). Upon complex formation, one β subunit was released from the (αβ)₂ tetramer of the reactivase. This result, together with the similarity in amino acid sequences and folds between the DD β subunit and the reactivase β subunit, suggests that subunit displacement or swapping takes place upon formation of the enzyme·reactivase complex. This would result in the dissociation of the damaged cofactor from the inactivated holoenzyme, as suggested by the crystal structures of the reactivase and DD.