Your search keyword '"Propanediol Dehydratase chemistry"' showing total 67 results

1. The action of coenzyme B12-dependent diol dehydratase on 3,3,3-trifluoro-1,2-propanediol results in elimination of all the fluorides with formation of acetaldehyde.

Author

Mori K, Golding BT, and Toraya T

Subjects

Fluorides metabolism, Fluorides chemistry, Propylene Glycols metabolism, Propylene Glycols chemistry, Acetaldehyde metabolism, Acetaldehyde chemistry, Propanediol Dehydratase metabolism, Propanediol Dehydratase chemistry, Cobamides metabolism, Cobamides chemistry

Abstract

3,3,3-Trifluoro-1,2-propanediol undergoes complete defluorination in two distinct steps: first, the conversion into 3,3,3-trifluoropropionaldehyde catalyzed by adenosylcobalamin (coenzyme B12)-dependent diol dehydratase; second, non-enzymatic elimination of all three fluorides from this aldehyde to afford malonic semialdehyde (3-oxopropanoic acid), which is decarboxylated to acetaldehyde. Diol dehydratase accepts 3,3,3-trifluoro-1,2-propanediol as a relatively poor substrate, albeit without significant mechanism-based inactivation of the enzyme during catalysis. Optical and electron paramagnetic resonance (EPR) spectra revealed the steady-state formation of cob(II)alamin and a substrate-derived intermediate organic radical (3,3,3-trifluoro-1,2-dihydroxyprop-1-yl). The coenzyme undergoes Co-C bond homolysis initiating a sequence of reaction by the generally accepted pathway via intermediate radicals. However, the greater steric size of trifluoromethyl and especially its negative impact on the stability of an adjacent radical centre compared to a methyl group has implications for the mechanism of the diol dehydratase reaction. Nevertheless, 3,3,3-trifluoropropionaldehyde is formed by the normal diol dehydratase pathway, but then undergoes non-enzymatic conversion into acetaldehyde, probably via 3,3-difluoropropenal and malonic semialdehyde., (© The Author(s) 2024. Published by Oxford University Press on behalf of the Japanese Biochemical Society. All rights reserved.)

Published

2024

2. Unveiling Therapeutic Avenues for Crohn's Disease Management: Exploring Inhibitors for Adherent-Invasive Escherichia coli Propanediol Dehydratase.

Author

Bourhia M, Hosen ME, Faruqe MO, Tasnim F, Taibi M, Elbouzidi A, Bin Jardan YA, Ibenmoussa S, and Asehraou A

Subjects

Anti-Bacterial Agents pharmacology, Anti-Bacterial Agents chemistry, Humans, Molecular Dynamics Simulation, Molecular Structure, Escherichia coli enzymology, Escherichia coli drug effects, Crohn Disease drug therapy, Molecular Docking Simulation, Enzyme Inhibitors chemistry, Enzyme Inhibitors pharmacology, Propanediol Dehydratase metabolism, Propanediol Dehydratase antagonists & inhibitors, Propanediol Dehydratase chemistry

Abstract

Introduction: Inflammatory Bowel Disease (IBD) encompasses a group of chronic disorders distinguished by inflammation of the gastrointestinal tract. Among these, Crohn's Disease (CD) stands out as a complex and impactful condition due to challenges for both diagnosis and management, making it a cynosure of research., Methods: In CD, there is the predominance of proinflammatory bacteria, including the Adherentinvasive Escherichia coli (AIEC) with virulence-associated metabolic enzyme Propanediol Dehydratase (pduC), which has been identified as a therapeutic target for the management of CD. Herein, molecular modeling techniques, including molecular docking, Molecular Mechanics with Generalized Born and Surface Area (MMGBSA), drug-likeness, and pharmacokinetics profiling, were utilized to probe the potentials of eighty antibacterial compounds to serve as inhibitors of pduC., Results: The results of this study led to the identification of five compounds with promising potentials; the results of the molecular docking simulation revealed the compounds as possessing better binding affinities for the target compared to the standard drug (sulfasalazine), while Lipinski's rule of five-based assessment of their drug-likeness properties revealed them as potential oral drugs. MMGBSA free energy calculation and Molecular Dynamics (MD) simulation of the complexes formed a sequel to molecular docking, revealing the compounds as stable binders in the active site of the protein., Conclusion: Ultimately, the results of this study have revealed five compounds to possess the potential to serve as inhibitors of pduC of AIEC. However, experimental studies are still needed to validate the findings of this study., (Copyright© Bentham Science Publishers; For any queries, please email at epub@benthamscience.net.)

Published

2024

3. Structural Insights into the Very Low Activity of the Homocoenzyme B 12 Adenosylmethylcobalamin in Coenzyme B 12 -Dependent Diol Dehydratase and Ethanolamine Ammonia-Lyase.

Author

Shibata N, Higuchi Y, Kräutler B, and Toraya T

Subjects

Cobamides chemistry, Cobamides metabolism, Kinetics, Ethanolamine Ammonia-Lyase chemistry, Ethanolamine Ammonia-Lyase metabolism, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism

Abstract

The X-ray structures of coenzyme B 12 (AdoCbl)-dependent eliminating isomerases complexed with adenosylmethylcobalamin (AdoMeCbl) have been determined. As judged from geometries, the Co-C bond in diol dehydratase (DD) is not activated even in the presence of substrate. In ethanolamine ammonia-lyase (EAL), the bond is elongated in the absence of substrate; in the presence of substrate, the complex likely exists in both pre- and post-homolysis states. The impacts of incorporating an extra CH 2 group are different in the two enzymes: the DD active site is flexible, and AdoMeCbl binding causes large conformational changes that make DD unable to adopt the catalytic state, whereas the EAL active site is rigid, and AdoMeCbl binding does not induce significant conformational changes. Such flexibility and rigidity of the active sites might reflect the tightness of adenine binding. The structures provide good insights into the basis of the very low activity of AdoMeCbl in these enzymes., (© 2022 Wiley-VCH GmbH.)

Published

2022

4. Reactivating chaperones for coenzyme B 12 -dependent diol and glycerol dehydratases and ethanolamine ammonia-lyase.

Author

Toraya T, Tobimatsu T, Shibata N, and Mori K

Subjects

Cobamides chemistry, Coenzymes, Glycerol, Hydro-Lyases, Molecular Chaperones, Phosphothreonine analogs & derivatives, Ethanolamine Ammonia-Lyase chemistry, Propanediol Dehydratase chemistry, Propanediol Dehydratase genetics

Abstract

Adenosylcobalamin (AdoCbl) or coenzyme B 12 -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 B 12 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 B 12 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., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

5. Computational Study of Glycerol Binding within the Active Site of Coenzyme B 12 -Dependent Diol Dehydratase.

Author

Bilić L, Barić D, Banhatti RD, Smith DM, and Kovačević B

Subjects

Crystallography, X-Ray, Protein Binding, Catalytic Domain, Cobamides metabolism, Glycerol metabolism, Molecular Dynamics Simulation, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism

Abstract

Molecular dynamics (MD) simulations have been employed for the first time to gain insight into the geometry of glycerol (GOL) bound within the active site of B 12 -dependent diol dehydratase (B 12 -dDDH). A peculiar feature of the B 12 -dDDH enzyme is that it undergoes suicidal inactivation by the substrate glycerol. To fully understand the inactivation mechanism, it is crucial to identify all possible interactions between GOL and the surrounding amino acid residues in the enzyme-substrate complex. Particularly important is the orientation of the C3-OH group in GOL since the presence of this OH group is the only difference between GOL and propanediol (PDO), a substrate for B 12 -dDDH that does not induce suicidal inactivation. The MD simulations indicate that glycerol can adopt two conformations that differ with respect to the orientation of the C3-OH group; in one conformer, the C3-OH group is oriented toward Ser301 (C3-OH···Ser301), and in the other toward Asp335 (C3-OH···Asp335). Although the former configuration is consistent with the crystal structure of B 12 -dDDH crystallized with cyanocobalamin (CNCbl) as the cofactor, MD simulations of this system suggest a substantial predominance of the latter conformer. A similar result with an even higher preference for the latter conformer is obtained for B 12 -dDDH with 5'-deoxyadenosylcobalamin (AdoCbl) as a cofactor. Employing QM/MM calculations it is found that the energy difference between the two conformers of GOL is very small in CNCbl B 12 -dDDH, where the slightly preferred conformer is C3-OH···Ser301. However, in AdoCbl B 12 -dDDH, this energy difference is higher, implying that GOL exists predominantly as the C3-OH···Asp335 conformer. These findings offer a new perspective for investigations of substrate-induced inactivation of the B 12 -dDDH enzyme.

Published

2019

6. In Vitro Characterization and Concerted Function of Three Core Enzymes of a Glycyl Radical Enzyme - Associated Bacterial Microcompartment.

Author

Zarzycki J, Sutter M, Cortina NS, Erb TJ, and Kerfeld CA

Subjects

Aldehyde Dehydrogenase metabolism, Bacterial Proteins metabolism, Cell Compartmentation, Propanediol Dehydratase metabolism, Propylene Glycol metabolism, Protein Binding, Rhodopseudomonas enzymology, Aldehyde Dehydrogenase chemistry, Bacterial Proteins chemistry, Propanediol Dehydratase chemistry

Abstract

Many bacteria encode proteinaceous bacterial microcompartments (BMCs) that encapsulate sequential enzymatic reactions of diverse metabolic pathways. Well-characterized BMCs include carboxysomes for CO 2 -fixation, and propanediol- and ethanolamine-utilizing microcompartments that contain B 12 -dependent enzymes. Genes required to form BMCs are typically organized in gene clusters, which promoted their distribution across phyla by horizontal gene transfer. Recently, BMCs associated with glycyl radical enzymes (GREs) were discovered; these are widespread and comprise at least three functionally distinct types. Previously, we predicted one type of these GRE-associated microcompartments (GRMs) represents a B 12 -independent propanediol-utilizing BMC. Here we functionally and structurally characterize enzymes of the GRM of Rhodopseudomonas palustris BisB18 and demonstrate their concerted function in vitro. The GRM signature enzyme, the GRE, is a dedicated 1,2-propanediol dehydratase with a new type of intramolecular encapsulation peptide. It forms a complex with its activating enzyme and, in conjunction with an aldehyde dehydrogenase, converts 1,2-propanediol to propionyl-CoA. Notably, homologous GRMs are also encoded in pathogenic Escherichia coli strains. Our high-resolution crystal structures of the aldehyde dehydrogenase lead to a revised reaction mechanism. The successful in vitro reconstitution of a part of the GRM metabolism provides insights into the metabolic function and steps in the assembly of this BMC.

Published

2017

7. A prominent glycyl radical enzyme in human gut microbiomes metabolizes trans -4-hydroxy-l-proline.

Author

Levin BJ, Huang YY, Peck SC, Wei Y, Martínez-Del Campo A, Marks JA, Franzosa EA, Huttenhower C, and Balskus EP

Subjects

Amino Acid Motifs, Anaerobiosis, Humans, Metagenome, Proline Oxidase metabolism, Propanediol Dehydratase chemistry, Propanediol Dehydratase genetics, Protein Processing, Post-Translational, Sequence Alignment, Gastrointestinal Microbiome genetics, Gastrointestinal Tract microbiology, Hydroxyproline metabolism, Proline Oxidase chemistry, Proline Oxidase genetics

Abstract

The human microbiome encodes vast numbers of uncharacterized enzymes, limiting our functional understanding of this community and its effects on host health and disease. By incorporating information about enzymatic chemistry into quantitative metagenomics, we determined the abundance and distribution of individual members of the glycyl radical enzyme superfamily among the microbiomes of healthy humans. We identified many uncharacterized family members, including a universally distributed enzyme that enables commensal gut microbes and human pathogens to dehydrate trans -4-hydroxy-l-proline, the product of the most abundant human posttranslational modification. This "chemically guided functional profiling" workflow can therefore use ecological context to facilitate the discovery of enzymes in microbial communities., (Copyright © 2017, American Association for the Advancement of Science.)

Published

2017

8. 1,2-Propanediol Dehydration in Roseburia inulinivorans: STRUCTURAL BASIS FOR SUBSTRATE AND ENANTIOMER SELECTIVITY.

Author

LaMattina JW, Keul ND, Reitzer P, Kapoor S, Galzerani F, Koch DJ, Gouvea IE, and Lanzilotta WN

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Clostridiales genetics, Propanediol Dehydratase genetics, Propanediol Dehydratase metabolism, Propylene Glycol metabolism, Substrate Specificity physiology, Bacterial Proteins chemistry, Clostridiales enzymology, Propanediol Dehydratase chemistry, Propylene Glycol chemistry

Abstract

Glycyl radical enzymes (GREs) represent a diverse superfamily of enzymes that utilize a radical mechanism to catalyze difficult, but often essential, chemical reactions. In this work we present the first biochemical and structural data for a GRE-type diol dehydratase from the organism Roseburia inulinivorans (RiDD). Despite high sequence (48% identity) and structural similarity to the GRE-type glycerol dehydratase from Clostridium butyricum, we demonstrate that the RiDD is in fact a diol dehydratase. In addition, the RiDD will utilize both (S)-1,2-propanediol and (R)-1,2-propanediol as a substrate, with an observed preference for the S enantiomer. Based on the new structural information we developed and successfully tested a hypothesis that explains the functional differences we observe., (© 2016 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2016

9. Cloning, expression, and characterization of coenzyme-B12-dependent diol dehydratase from Lactobacillus diolivorans.

Author

Wei X, Meng X, Chen Y, Wei Y, Du L, and Huang R

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Cloning, Molecular, Cobamides, Glycerol metabolism, Lactobacillus genetics, Oxygen metabolism, Propanediol Dehydratase chemistry, Propanediol Dehydratase genetics, Recombinant Proteins chemistry, Recombinant Proteins genetics, Bacterial Proteins metabolism, Lactobacillus enzymology, Propanediol Dehydratase metabolism, Recombinant Proteins metabolism

Abstract

The three gldCDE genes from Lactobacillus diolivorans, that encode the three subunits of the glycerol dehydratase, were cloned and the proteins were co-expressed in soluble form in Escherichia coli with added sorbitol and betaine hydrochloride. The purified enzyme exists as a heterohexamer (α2β2γ2) structure with a native molecular mass of 210 kDa. It requires coenzyme B12 for catalytic activity and is subject to suicide inactivation by glycerol during catalysis. The enzyme had maximum activity at pH 8.6 and 37 °C. The apparent K m values for coenzyme B12, 1,2-ethanediol, 1,2-propanediol, and glycerol were 1.5 μM, 10.5 mM, 1.3 mM, and 5.8 mM, respectively. Together, these results indicated that the three genes gldCDE encoding the proteins make up a coenzyme B12-dependent diol dehydratase and not a glycerol dehydratase.

Published

2014

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

Author

Mori K, Obayashi K, Hosokawa Y, Yamamoto A, Yano M, Yoshinaga T, and Toraya T

Subjects

Amino Acid Sequence, Bacterial Proteins chemistry, Bacterial Proteins physiology, Binding Sites, Enzyme Reactivators chemistry, Humans, Kinetics, Klebsiella oxytoca enzymology, Metals chemistry, Models, Molecular, Molecular Sequence Data, Protein Binding, Protein Interaction Domains and Motifs physiology, Molecular Chaperones chemistry, Nucleotides metabolism, Propanediol Dehydratase chemistry

Abstract

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.

Published

2013

11. Inactivation mechanism of glycerol dehydration by diol dehydratase from combined quantum mechanical/molecular mechanical calculations.

Author

Doitomi K, Kamachi T, Toraya T, and Yoshizawa K

Subjects

Models, Molecular, Propanediol Dehydratase antagonists & inhibitors, Protein Conformation, Quantum Theory, Glycerol metabolism, Hydrogen chemistry, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism

Abstract

Inactivation of diol dehydratase during the glycerol dehydration reaction is studied on the basis of quantum mechanical/molecular mechanical calculations. Glycerol is not a chiral compound but contains a prochiral carbon atom. Once it is bound to the active site, the enzyme adopts two binding conformations. One is predominantly responsible for the product-forming reaction (G(R) conformation), and the other primarily contributes to inactivation (G(S) conformation). Reactant radical is converted into a product and byproduct in the product-forming reaction and inactivation, respectively. The OH group migrates from C2 to C1 in the product-forming reaction, whereas the transfer of a hydrogen from the 3-OH group of glycerol to C1 takes place during the inactivation. The activation barrier of the hydrogen transfer does not depend on the substrate-binding conformation. On the other hand, the activation barrier of OH group migration is sensitive to conformation and is 4.5 kcal/mol lower in the G(R) conformation than in the G(S) conformation. In the OH group migration, Glu170 plays a critical role in stabilizing the reactant radical in the G(S) conformation. Moreover, the hydrogen bonding interaction between Ser301 and the 3-OH group of glycerol lowers the activation barrier in G(R)-TS2. As a result, the difference in energy between the hydrogen transfer and the OH group migration is reduced in the G(S) conformation, which shows that the inactivation is favored in the G(S) conformation.

Published

2012

12. Redesign of coenzyme B(12) dependent diol dehydratase to be resistant to the mechanism-based inactivation by glycerol and act on longer chain 1,2-diols.

Author

Yamanishi M, Kinoshita K, Fukuoka M, Saito T, Tanokuchi A, Ikeda Y, Obayashi H, Mori K, Shibata N, Tobimatsu T, and Toraya T

Subjects

Catalysis, Catalytic Domain, Crystallization, Crystallography, X-Ray, Kinetics, Models, Molecular, Mutagenesis, Site-Directed, Mutation genetics, Propanediol Dehydratase genetics, Propylene Glycol chemistry, Protein Conformation, Stereoisomerism, Vitamin B 12 metabolism, Cobamides metabolism, Drug Resistance, Glycerol metabolism, Klebsiella oxytoca enzymology, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism, Propylene Glycol metabolism

Abstract

Coenzyme B(12) dependent diol dehydratase undergoes mechanism-based inactivation by glycerol, accompanying the irreversible cleavage of the coenzyme Co-C bond. Bachovchin et al. [Biochemistry16, 1082-1092 (1977)] reported that glycerol bound in the G(S) conformation, in which the pro-S-CH(2) OH group is oriented to the hydrogen-abstracting site, primarily contributes to the inactivation reaction. To understand the mechanism of inactivation by glycerol, we analyzed the X-ray structure of diol dehydratase complexed with cyanocobalamin and glycerol. Glycerol is bound to the active site preferentially in the same conformation as that of (S)-1,2-propanediol, i.e. in the G(S) conformation, with its 3-OH group hydrogen bonded to Serα301, but not to nearby Glnα336. k(inact) of the Sα301A, Qα336A and Sα301A/Qα336A mutants with glycerol was much smaller than that of the wild-type enzyme. k(cat) /k(inact) showed that the Sα301A and Qα336A mutants are substantially more resistant to glycerol inactivation than the wild-type enzyme, suggesting that Serα301 and Glnα336 are directly or indirectly involved in the inactivation. The degree of preference for (S)-1,2-propanediol decreased on these mutations. The substrate activities towards longer chain 1,2-diols significantly increased on the Sα301A/Qα336A double mutation, probably because these amino acid substitutions yield more space for accommodating a longer alkyl group on C3 of 1,2-diols. Database Structural data are available in the Protein Data Bank under the accession number 3AUJ. Structured digital abstract • Diol dehydrase gamma subunit, Diol dehydrase beta subunit and Diol dehydrase alpha subunit physically interact by X-ray crystallography (View interaction)., (© 2012 The Authors Journal compilation © 2012 FEBS.)

Published

2012

13. [Computational mutation analysis of enzymatic reaction].

Author

Doitomi K, Kamachi T, and Yoshizawa K

Subjects

Amino Acids chemistry, Amino Acids genetics, Binding Sites genetics, Biocatalysis, Molecular Structure, Organometallic Compounds chemistry, Computational Biology methods, Mutation, Propanediol Dehydratase chemistry, Propanediol Dehydratase genetics, Quantum Theory, Vitamin B 12

Abstract

Density functional theory (DFT) calculations are established as a useful research tool to investigate the structures and reactivity of biological systems; however, their high computational costs still restrict their applicability to systems of several tens up to a few hundred atoms. Recently, a combined quantum mechanical/molecular mechanical (QM/MM) approach has become an important method to study enzymatic reactions. In the past several years, we have investigated B12-dependent diol dehydratase using QM/MM calculations. The enzyme catalyzes chemically difficult reactions by utilizing the high reactivity of free radicals. In this paper, we explain our QM/MM calculations for the structure and reactivity of diol dehydratase and report key findings with respect to the catalytic roles of the active-site amino acid residues, computational mutational analysis of the active-site amino acid residues, assignment of the central metal ion, and function of the central metal ion. Our QM/MM calculations can correctly describe the structures and activation barriers of intermediate and transition states in the protein environment. Moreover, predicted relative activities of mutants are consistent with experimentally observed reactivity. These results will encourage the application of QM/MM research to the mechanistic study of enzymatic reactions, functional analysis of active-site residues, and rational design of enzymes with new catalytic functions.

Published

2012

14. The N-terminal region of the medium subunit (PduD) packages adenosylcobalamin-dependent diol dehydratase (PduCDE) into the Pdu microcompartment.

Author

Fan C and Bobik TA

Subjects

Bacterial Proteins genetics, Cytoplasmic Granules chemistry, Cytoplasmic Granules genetics, Molecular Sequence Data, Propanediol Dehydratase genetics, Propylene Glycol metabolism, Protein Structure, Tertiary, Protein Subunits chemistry, Protein Subunits genetics, Protein Subunits metabolism, Salmonella enterica chemistry, Salmonella enterica genetics, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Cobamides metabolism, Cytoplasmic Granules enzymology, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism, Salmonella enterica enzymology

Abstract

Salmonella enterica produces a proteinaceous microcompartment for B(12)-dependent 1,2-propanediol utilization (Pdu MCP). The Pdu MCP consists of catabolic enzymes encased within a protein shell, and its function is to sequester propionaldehyde, a toxic intermediate of 1,2-propanediol degradation. We report here that a short N-terminal region of the medium subunit (PduD) is required for packaging the coenzyme B(12)-dependent diol dehydratase (PduCDE) into the lumen of the Pdu MCP. Analysis of soluble cell extracts and purified MCPs by Western blotting showed that the PduD subunit mediated packaging of itself and other subunits of diol dehydratase (PduC and PduE) into the Pdu MCP. Deletion of 35 amino acids from the N terminus of PduD significantly impaired the packaging of PduCDE with minimal effects on its enzyme activity. Western blotting showed that fusing the 18 N-terminal amino acids of PduD to green fluorescent protein or glutathione S-transferase resulted in the association of these fusion proteins with the MCP. Immunoprecipitation tests indicated that the fusion proteins were encapsulated inside the MCP shell.

Published

2011

15. Catalytic roles of the metal ion in the substrate-binding site of coenzyme B12-dependent diol dehydratase.

Author

Kamachi T, Doitomi K, Takahata M, Toraya T, and Yoshizawa K

Subjects

Binding Sites, Biocatalysis, Calcium chemistry, Crystallography, X-Ray, Ions chemistry, Ions metabolism, Models, Molecular, Molecular Structure, Organometallic Compounds chemistry, Propanediol Dehydratase chemistry, Vitamin B 12 chemistry, Calcium metabolism, Organometallic Compounds metabolism, Propanediol Dehydratase metabolism, Quantum Theory, Vitamin B 12 metabolism

Abstract

Functions of the metal ion in the substrate-binding site of diol dehydratase are studied on the basis of quantum mechanical/molecular mechanical (QM/MM) calculations. The metal ion directly coordinates to substrate and is essential for structural retention and substrate binding. The metal ion has been originally assigned to the K(+) ion; however, QM/MM computations indicate that Ca(2+) ion is more reasonable as the metal ion because calculated Ca-O distances better fit to the coordination distances in X-ray crystal structures rather than calculated K-O distances. The activation energy for the OH group migration, which is essential in the conversion of diols to corresponding aldehydes, is sensitive to the identity of the metal ion. For example, the spectator OH group of substrate is fully deprotonated by Glu170 in the transition state for the OH group migration in the Ca-contained QM/MM model, and therefore the barrier height is significantly decreased in the model having Ca(2+) ion. On the other hand, the deprotonation of the spectator OH group cannot effectively be triggered by the K(+) ion. Moreover, in the hydrogen recombination, the most energy-demanding step is more favorable in the Ca-contained model. The proposal that the Ca(2+) ion should be involved in the substrate-binding site is consistent with an observed large deuterium kinetic isotope effect of 10, which indicates that C-H bond activation is involved in the rate-determining step. Asp335 is found to have a strong anticatalytic effect on the OH group migration despite its important role in substrate binding. The synergistic interplay of the O-C bond cleavage by Ca(2+) ion and the deprotonation of the spectator OH group by Glu170 is required to overcome the anticatalytic effect of Asp335.

Published

2011

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

Author

Mori K, Hosokawa Y, Yoshinaga T, and Toraya T

Subjects

Adenosine Triphosphate metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Cobamides, Coenzymes metabolism, Holoenzymes metabolism, Kinetics, Klebsiella metabolism, Klebsiella pneumoniae metabolism, Magnesium metabolism, Models, Biological, Models, Molecular, Multiprotein Complexes chemistry, Multiprotein Complexes metabolism, Protein Subunits, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Vitamin B 12 metabolism, Enzyme Reactivators chemistry, Enzyme Reactivators metabolism, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism

Abstract

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., (© 2010 The Authors Journal compilation © 2010 FEBS.)

Published

2010

17. Coenzyme B12-dependent diol dehydratase is a potassium ion-requiring calcium metalloenzyme: evidence that the substrate-coordinated metal ion is calcium.

Author

Toraya T, Honda S, and Mori K

Subjects

Calcium chemistry, Catalytic Domain, Crystallography, X-Ray, Edetic Acid metabolism, Egtazic Acid metabolism, Enzyme Stability, Metalloproteins metabolism, Metals chemistry, Metals metabolism, Models, Molecular, Propanediol Dehydratase antagonists & inhibitors, Propanediol Dehydratase metabolism, Protein Binding, Substrate Specificity, Vitamin B 12 metabolism, Calcium metabolism, Klebsiella oxytoca enzymology, Metalloproteins chemistry, Propanediol Dehydratase chemistry

Abstract

The X-ray analyses of coenzyme B(12)-dependent diol dehydratase revealed two kinds of electron densities that correspond to metal ions in the active site. One is directly coordinated by substrate [Shibata, N., et al. (1999) Structure 7, 997-1008] and the other located near the adenine ring of the coenzyme adenosyl group [Masuda, J., et al. (2000) Structure 8, 775-788]. Both have been assigned as potassium ions, although the coordination distances of the former are slightly shorter than expected. We examined the possibility that the enzyme is a metalloenzyme. Apodiol dehydratase was strongly inhibited by incubation with EDTA and EGTA in the absence of substrate. The metal analysis revealed that the enzyme contains approximately 2 mol of tightly bound calcium per mole of enzyme. The calcium-deprived, EDTA-free apoenzyme was obtained by the EDTA treatment, followed by ultrafiltration. The activity of the calcium-deprived apoenzyme was dependent on Ca(2+) when assayed with 1 mM substrate. The K(m) for Ca(2+) evaluated in reconstitution experiments was 0.88 muM. These results indicate that the calcium is essential for catalysis. Ca(2+) showed a significant stabilizing effect on the calcium-deprived apoenzyme as well. It was thus concluded that the substrate-coordinated metal ion is not potassium but calcium. The potassium ion bound near the adenine ring would be the essential one for the diol dehydratase catalysis. Therefore, this enzyme can be considered to be a metal-activated metalloenzyme.

Published

2010

18. What is the identity of the metal ions in the active sites of coenzyme B12-dependent diol dehydratase? A computational mutation analysis.

Author

Kamachi T, Takahata M, Toraya T, and Yoshizawa K

Subjects

Computer Simulation, Propanediol Dehydratase metabolism, Quantum Theory, Catalytic Domain, Cobamides metabolism, Metals analysis, Models, Molecular, Mutation, Propanediol Dehydratase chemistry, Propanediol Dehydratase genetics

Abstract

What is the identity of the metal ion in the active sites of diol dehydratase? To address this question, we calculated the M-O bond lengths in the active sites using QM/MM calculations (M=K, Na, Mg, Ca). Our results show that the previous assignment of the metal ion in the substrate-binding site is wrong and that the identity of the metal ion is likely to be Ca2+. This is consistent with accumulated experimental evidence.

Published

2009

19. Low-solubility glycerol dehydratase, a chimeric enzyme of coenzyme B12 -dependent glycerol and diol dehydratases.

Author

Tobimatsu T, Nishiki T, Morimoto M, Miyata R, and Toraya T

Subjects

Amino Acid Sequence, Escherichia coli enzymology, Molecular Sequence Data, Recombinant Proteins chemistry, Solubility, Cobamides chemistry, Hydro-Lyases chemistry, Propanediol Dehydratase chemistry

Abstract

Coenzyme B(12)-dependent diol and glycerol dehydratases are isofunctional enzymes, which catalyze dehydration of 1, 2-diols to produce corresponding aldehydes. Although the two types of dehydratases have high sequence homology, glycerol dehydratase is a soluble cytosolic enzyme, whereas diol dehydratase is a low-solubility enzyme associated with carboxysome-like polyhedral organelles. Since both the N-terminal 20 and 16 amino acid residues of the beta and gamma subunits, respectively, are indispensable for the low solubility of diol dehydratase, we constructed glycerol dehydratase-based chimeric enzymes which carried N-terminal portions of the beta and gamma subunits of diol dehydratase in the corresponding subunits of glycerol dehydratase. Addition of the diol dehydratase-specific N-terminal 34 and 33 amino acid residues of the beta and gamma subunits, respectively, was not enough to lower the solubility of glycerol dehydratase. A chimeric enzyme which carries the low homology region (residues 35-60) of the diol dehydratase beta subunit in addition to the diol dehydratase-specific extra-regions of beta and gamma subunits showed low solubility comparable to diol dehydratase, although its hydropathy plot does not show any prominent hydrophobic peaks in these regions. It was thus concluded that short N-terminal sequences are sufficient to change the solubility of the enzyme.

Published

2009

20. Roles of adenine anchoring and ion pairing at the coenzyme B12-binding site in diol dehydratase catalysis.

Author

Ogura K, Kunita S, Mori K, Tobimatsu T, and Toraya T

Subjects

Amino Acid Substitution, Binding Sites, Catalysis, Cobamides genetics, Hydrogen Bonding, Kinetics, Lysine chemistry, Models, Molecular, Propanediol Dehydratase chemistry, Propanediol Dehydratase genetics, Protein Conformation, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Serine chemistry, Substrate Specificity, Vitamin B 12 metabolism, Adenine metabolism, Cobamides metabolism, Propanediol Dehydratase metabolism

Abstract

The X-ray structure of the diol dehydratase-adeninylpentylcobalamin complex revealed that the adenine moiety of adenosylcobalamin is anchored in the adenine-binding pocket of the enzyme by hydrogen bonding of N3 with the side chain OH group of Seralpha224, and of 6-NH(2), N1 and N7 with main chain amide groups of other residues. A salt bridge is formed between the epsilon-NH(2) group of Lysbeta135 and the phosphate group of cobalamin. To assess the importance of adenine anchoring and ion pairing, Seralpha224 and Lysbeta135 mutants of diol dehydratase were prepared, and their catalytic properties investigated. The Salpha224A, Salpha224N and Kbeta135E mutants were 19-2% as active as the wild-type enzyme, whereas the Kbeta135A, Kbeta135Q and Kbeta135R mutants retained 58-76% of the wild-type activity. The presence of a positive charge at the beta135 residue increased the affinity for cobalamins but was not essential for catalysis, and the introduction of a negative charge there prevented the enzyme-cobalamin interaction. The Salpha224A and Salpha224N mutants showed a k(cat)/k(inact) value that was less than 2% that of the wild-type, whereas for Lysbeta135 mutants this value was in the range 25-75%, except for the Kbeta135E mutant (7%). Unlike the wild-type holoenzyme, the Salpha224N and Salpha224A holoenzymes showed very low susceptibility to oxygen in the absence of substrate. These findings suggest that Seralpha224 is important for cobalt-carbon bond activation and for preventing the enzyme from being inactivated. Upon inactivation of the Salpha224A holoenzyme during catalysis, cob(II)alamin accumulated, and a trace of doublet signal due to an organic radical disappeared in EPR. 5'-Deoxyadenosine was formed from the adenosyl group, and the apoenzyme itself was not damaged. This inactivation was thus considered to be a mechanism-based one.

Published

2008

21. Mechanism-based inactivation of coenzyme B12-dependent diol dehydratase by 3-unsaturated 1,2-diols and thioglycerol.

Author

Toraya T, Tamura N, Watanabe T, Yamanishi M, Hieda N, and Mori K

Subjects

Cobamides chemistry, Electron Spin Resonance Spectroscopy, Enzyme Inhibitors pharmacology, Escherichia coli enzymology, Glycerol pharmacology, Glycols pharmacology, Kinetics, Models, Molecular, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism, Butylene Glycols pharmacology, Cobamides metabolism, Glycerol analogs & derivatives, Propanediol Dehydratase antagonists & inhibitors

Abstract

The reactions of diol dehydratase with 3-unsaturated 1,2-diols and thioglycerol were investigated. Holodiol dehydratase underwent rapid and irreversible inactivation by either 3-butene-1,2-diol, 3-butyne-1,2-diol or thioglycerol without catalytic turnovers. In the inactivation, the Co-C bond of adenosylcobalamin underwent irreversible cleavage forming unidentified radicals and cob(II)alamin that resisted oxidation even in the presence of oxygen. Two moles of 5'-deoxyadenosine per mol of enzyme was formed as an inactivation product from the coenzyme adenosyl group. Inactivated holoenzymes underwent reactivation by diol dehydratase-reactivating factor in the presence of ATP, Mg(2+) and adenosylcobalamin. It was thus concluded that these substrate analogues served as mechanism-based inactivators or pseudosubstrates, and that the coenzyme was damaged in the inactivation, whereas apoenzyme was not damaged. In the inactivation by 3-unsaturated 1,2-diols, product radicals stabilized by neighbouring unsaturated bonds might be unable to back-abstract the hydrogen atom from 5'-deoxyadenosine and then converted to unidentified products. In the inactivation by thioglycerol, a product radical may be lost by the elimination of sulphydryl group producing acrolein and unidentified sulphur compound(s). H(2)S or sulphide ion was not formed. The loss or stabilization of product radicals would result in the inactivation of holoenzyme, because the regeneration of the coenzyme becomes impossible.

Published

2008

22. Histidine-alpha143 assists 1,2-hydroxyl group migration and protects radical intermediates in coenzyme B12-dependent diol dehydratase.

Author

Kinoshita K, Kawata M, Ogura K, Yamasaki A, Watanabe T, Komoto N, Hieda N, Yamanishi M, Tobimatsu T, and Toraya T

Subjects

Crystallography, X-Ray, Electron Spin Resonance Spectroscopy, Histidine chemistry, Histidine genetics, Hydrogen Bonding, Hydrogen-Ion Concentration, Kinetics, Klebsiella oxytoca enzymology, Klebsiella oxytoca genetics, Klebsiella oxytoca metabolism, Models, Biological, Molecular Structure, Mutagenesis, Site-Directed, Mutation, Propanediol Dehydratase chemistry, Propanediol Dehydratase genetics, Structure-Activity Relationship, Substrate Specificity, Cobamides metabolism, Histidine metabolism, Propanediol Dehydratase metabolism

Abstract

Diol dehydratase of Klebsiella oxytoca contains an essential histidine residue. Its X-ray structure revealed that the migrating hydroxyl group on C2 of substrate is hydrogen-bonded to Hisalpha143. Mutant enzymes in which Hisalpha143 was mutated to another amino acid residue were expressed in Escherichia coli, purified, and examined for enzymatic activity. The Halpha143Q mutant was 34% as active as the wild-type enzyme. Halpha143A and Halpha143L showed only a trace of activity. Kinetic analyses indicated that the hydrogen bonding interaction between the hydroxyl group on C2 of substrate and the side chain of residue alpha143 is important not only for catalysis but also for protecting radical intermediates. Halpha143E and Halpha143K that did not exist as (alphabetagamma) 2 complexes were inactive. The deuterium kinetic isotope effect on the overall reaction suggested that a hydrogen abstraction step is fully rate-determining for the wild type and Halpha143Q and partially rate-determining for Halpha143A. The preference for substrate enantiomers was reversed by the Halpha143Q mutation in both substrate binding and catalysis. Upon the inactivation of the Halpha143A holoenzyme by 1,2-propanediol, cob(II)alamin without an organic radical coupling partner accumulated, 5'-deoxyadenosine was quantitatively formed from the coenzyme adenosyl group, and the apoenzyme itself was not damaged. This inactivation was thus concluded to be a mechanism-based inactivation. The holoenzyme of Halpha143Q underwent irreversible inactivation by O 2 in the absence of substrate at a much lower rate than the wild type.

Published

2008

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

Author

Kajiura H, Mori K, Shibata N, and Toraya T

Subjects

Adenosine Triphosphate pharmacology, Apoenzymes antagonists & inhibitors, Bacterial Proteins metabolism, Cobamides metabolism, Crystallography, X-Ray, Enzyme Reactivators metabolism, Hydro-Lyases metabolism, Klebsiella pneumoniae enzymology, Propanediol Dehydratase metabolism, Time Factors, Vitamin B 12 chemistry, Vitamin B 12 metabolism, Bacterial Proteins chemistry, Cobamides chemistry, Enzyme Reactivators chemistry, Hydro-Lyases chemistry, Propanediol Dehydratase chemistry

Abstract

Adenosylcobalamin-dependent diol and glycerol dehydratases are isofunctional enzymes and undergo mechanism-based inactivation by a physiological substrate glycerol during catalysis. Inactivated holoenzymes are reactivated by their own reactivating factors that mediate the ATP-dependent exchange of an enzyme-bound, damaged cofactor for free adenosylcobalamin through intermediary formation of apoenzyme. The reactivation takes place in two steps: (a) ADP-dependent cobalamin release and (b) ATP-dependent dissociation of the resulting apoenzyme-reactivating factor complexes. The in vitro experiments with purified proteins indicated that diol dehydratase-reactivating factor (DDR) cross-reactivates the inactivated glycerol dehydratase, whereas glycerol dehydratase-reactivating factor (GDR) did not cross-reactivate the inactivated diol dehydratase. We investigated the molecular basis of their specificities in vitro by using purified preparations of cognate and noncognate enzymes and reactivating factors. DDR mediated the exchange of glycerol dehydratase-bound cyanocobalamin for free adeninylpentylcobalamin, whereas GDR cannot mediate the exchange of diol dehydratase-bound cyanocobalamin for free adeninylpentylcobalamin. As judged by denaturing PAGE, the glycerol dehydratase-DDR complex was cross-formed, although the diol dehydratase-GDR complex was not formed. There were no specificities of reactivating factors in the ATP-dependent dissociation of enzyme-reactivating factor complexes. Thus, it is very likely that the specificities of reactivating factors are determined by the capability of reactivating factors to form complexes with apoenzymes. A modeling study based on the crystal structures of enzymes and reactivating factors also suggested why DDR cross-forms a complex with glycerol dehydratase, and why GDR does not cross-form a complex with diol dehydratase.

Published

2007

24. Dioldehydrase: an essential role for potassium ion in the homolytic cleavage of the cobalt-carbon bond in adenosylcobalamin.

Author

Schwartz PA and Frey PA

Subjects

Carbon chemistry, Cobalt chemistry, Kinetics, Models, Molecular, Oxidation-Reduction, Oxygen metabolism, Propanediol Dehydratase antagonists & inhibitors, Spectrophotometry, Cobamides chemistry, Cobamides metabolism, Potassium metabolism, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism

Abstract

The complex of dioldehydrase with adenosylcobalamin (coenzyme B12) and potassium ion reacts with molecular oxygen in the absence of a substrate to oxidize coenzyme and inactivate the complex. In this article, high performance liquid chromatography and mass spectral analysis are used to identify the nucleoside products resulting from oxygen inactivation. The product profile indicates that oxygen inactivation proceeds by direct reaction of molecular oxygen with the 5'-deoxyadenosyl radical and cob(II)alamin. Formation of 5'-peroxyadenosine as the initial nucleoside product chemically correlates this reaction with aerobic, aqueous photoinduced homolytic cleavage of adenosylcobalamin (Schwartz, P. A., and Frey, P. A., (2007) Biochemistry, in press), indicating that both reactions proceed through similar chemical intermediates. The oxygen inactivation of the enzyme-coenzyme complex shows an absolute requirement for the same monocations required in catalysis by dioldehydrase. Measurements of the dissociation constants for adenosylcobalamin from potassium-free (Kd = 16 +/- 2 microM) or potassium-bound dioldehydrase (Kd = 0.8 +/- 0.2 microM) reveal that the effect of the monocation in stimulating oxygen sensitivity cannot be explained by an effect on the binding of coenzyme to the enzyme. Cross-linking experiments suggest that the full quaternary structure is assembled in the absence of potassium ion under the experimental conditions. The results indicate that dioldehydrase likely harvests the binding energy of the activating monocation to stimulate the homolytic cleavage of the Co-C5' bond in adenosylcobalamin.

Published

2007

25. Probing interactions from solvent-exchangeable protons and monovalent cations with the 1,2-propanediol-1-yl radical intermediate in the reaction of dioldehydrase.

Author

Schwartz PA, Lobrutto R, Reed GH, and Frey PA

Subjects

Binding Sites, Cations, Monovalent metabolism, Cobamides chemistry, Electron Spin Resonance Spectroscopy methods, Models, Chemical, Molecular Structure, Potassium chemistry, Potassium metabolism, Propanediol Dehydratase metabolism, Protons, Thallium chemistry, Thallium metabolism, Cations, Monovalent chemistry, Propanediol Dehydratase chemistry, Solvents chemistry

Abstract

The reaction of adenosylcobalamin-dependent dioldehydrase with 1,2-propanediol gives rise to a radical intermediate observable by EPR spectroscopy. This reaction requires a monovalent cation such as potassium ion. The radical signal arises from the formation of a radical pair comprised of the Co(II) of cob(II)alamin and a substrate-related radical generated upon hydrogen abstraction by the 5'-deoxyadenosyl radical. The high-field asymmetric doublet arising from the organic radical has allowed investigation of its composition and environment through the use of EPR spectroscopic techniques. To characterize the protonation state of the oxygen substituents in the radical intermediate, X-band EPR spectroscopy was performed in the presence of D(2)O and compared to the spectrum in H(2)O. Results indicate that the unpaired electron of the steady-state radical couples to a proton on the C(1) hydroxyl group. Other spectroscopic experiments were performed, using either potassium or thallous ion as the activating monovalent cation, in an attempt to exploit the magnetic nature of the (205,203)Tl nucleus to identify any intimate interaction of the radical intermediate with the activating cation. The radical intermediate in complex with dioldehydrase, cob(II)alamin and one of the activating monovalent cations was observed using EPR, ENDOR, and ESEEM spectroscopy. The spectroscopic evidence did not implicate a direct coordination of the activating cation and the substrate derived radical intermediate.

Published

2007

26. Computational mutation analysis of hydrogen abstraction and radical rearrangement steps in the catalysis of coenzyme B12-dependent diol dehydratase.

Author

Kamachi T, Toraya T, and Yoshizawa K

Subjects

Binding Sites, Catalysis, Computational Biology methods, DNA Mutational Analysis methods, Enzyme Activation, Hydrogen chemistry, Mutation, Propylene Glycol chemistry, Propylene Glycols metabolism, Protein Conformation, Cobamides chemistry, Propanediol Dehydratase chemistry, Propanediol Dehydratase genetics, Vitamin B 12 biosynthesis

Abstract

A mutation analysis of the catalytic functions of active-site residues of coenzyme B(12)-dependent diol dehydratase in the conversion of 1,2-propanediol to 1,1-propanediol has been carried out by using QM/MM computations. Mutants His143Ala, Glu170Gln, Glu170Ala, and Glu170Ala/Glu221Ala were considered to estimate the impact of the mutations of His143 and Glu170. In the His143Ala mutant the activation energy for OH migration increased to 16.4 from 11.5 kcal mol(-1) in the wild-type enzyme. The highest activation energy, 19.6 kcal mol(-1), was measured for hydrogen back-abstraction in this reaction. The transition state for OH migration is not sufficiently stabilized by the hydrogen-bonding interaction formed between the spectator OH group and Gln170 in the Glu170Gln mutant, which demonstrates that a strong proton acceptor is required to promote OH migration. In the Glu170Ala mutant, a new strong hydrogen bond is formed between the spectator OH group and Glu221. A computed activation energy of 13.6 kcal mol(-1) for OH migration in the Glu170Ala mutant is only 2.1 kcal mol(-1) higher than the corresponding barrier in the wild-type enzyme. Despite the low activation barrier, the Glu170Ala mutant is inactive because the subsequent hydrogen back-abstraction is energetically demanding in this mutant. OH migration is not feasible in the Glu170Ala/Glu221Ala mutant because the activation barrier for OH migration is greatly increased by the loss of COO(-) groups near the spectator OH group. This result indicates that the effect of partial deprotonation of the spectator OH group is the most important factor in reducing the activation barrier for OH migration in the conversion of 1,2-propanediol to 1,1-propanediol catalyzed by diol dehydratase.

Published

2007

27. Analysis of the Cob(II)alamin-5'-deoxy-3',4'-anhydroadenosyl radical triplet spin system in the active site of diol dehydrase.

Author

Mansoorabadi SO, Magnusson OT, Poyner RR, Frey PA, and Reed GH

Subjects

Binding Sites, Coenzymes chemistry, Coenzymes metabolism, Electron Spin Resonance Spectroscopy, Free Radicals chemistry, Models, Molecular, Molecular Structure, Salmonella typhimurium enzymology, Vitamin B 12 chemistry, Vitamin B 12 metabolism, Cobamides chemistry, Oxygen chemistry, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism, Vitamin B 12 analogs & derivatives

Abstract

A triplet spin system (S=1) is detected by low-temperature electron paramagnetic resonance (EPR) spectroscopy in samples of diol dehydrase and the functional adenosylcobalamin (AdoCbl) analogue 5'-deoxy-3',4'-anhydroadenosylcobalamin (anAdoCbl). Different spectra are observed in the presence and absence of the substrate (R,S)-1,2-propanediol. In both cases, the spectra include a prominent half-field transition (DeltaM(S) = 2) that is a hallmark of strongly coupled triplet spin systems. The appearance of 59Co hyperfine splitting in the EPR signals and the positions (g values) of the signals in the spectra show that half of the triplet spin is contributed by the low-spin Co2+ of cob(II)alamin. Line width effects from isotopic labeling (13C and 2H) in the 5'-deoxy-3',4'-anhydroribosyl ring demonstrate that the other half of the spin triplet is from an allylic 5'-deoxy-3',4'-anhydroadenosyl (anhydroadenosyl) radical. The zero-field splitting (ZFS) tensors describing the magnetic dipole-dipole interactions of the component spins of the triplets have rhombic symmetry because of electron spin delocalization within the organic radical component and the proximity of the radical to the low-spin Co2+. The dipole-dipole interaction was modeled as a summation of point-dipole interactions involving the spin-bearing orbitals of the anhydroadenosyl radical and cob(II)alamin. Geometries which are consistent with the ZFS tensors in the presence and absence of the substrate position the 5'-carbon of the anhydroadenosyl radical 3.5 and 4.1 A from Co2+, respectively. Homolytic cleavage of the cobalt-carbon bond of the analogue in the absence of the substrate indicates that, in diol dehydrase, binding of the coenzyme to the protein weakens the bond prior to binding of the substrate.

Published

2006

28. Survey of catalytic residues and essential roles of glutamate-alpha170 and aspartate-alpha335 in coenzyme B12-dependent diol dehydratase.

Author

Kawata M, Kinoshita K, Takahashi S, Ogura K, Komoto N, Yamanishi M, Tobimatsu T, and Toraya T

Subjects

Aspartic Acid, Bacterial Proteins genetics, Catalytic Domain genetics, Cobamides metabolism, Glutamic Acid, Kinetics, Mutagenesis, Site-Directed, Propanediol Dehydratase genetics, Structure-Activity Relationship, Substrate Specificity, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Klebsiella oxytoca enzymology, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism

Abstract

The importance of each active-site residue in adenosylcobalamin-dependent diol dehydratase of Klebsiella oxytoca was estimated using mutant enzymes in which one of the residues interacting with substrate and/or K(+) was mutated to Ala or another amino acid residue. The Ealpha170A and Dalpha335A mutants were totally inactive, and the Halpha143A mutant showed only a trace of activity, indicating that Glu-alpha170, Asp-alpha335, and His-alpha143 are catalytic residues. The Qalpha141A, Qalpha296A, and Salpha362A mutants showed partial activity. It was suggested from kinetic parameters that Gln-alpha296 is important for substrate binding and Gln-alpha296 and Gln-alpha141 for preventing the enzyme from mechanism-based inactivation. The Ealpha221A, Ealpha170H, and Dalpha335A did not form the (alphabetagamma)(2) complex, suggesting that these mutations indirectly disrupt subunit contacts. Among other Glu-alpha170 and Asp-alpha335 mutants, Ealpha170D and Ealpha170Q were 2.2 +/- 0.3% and 0.02% as active as the wild-type enzyme, respectively, whereas Dalpha335N was totally inactive. Kinetic analysis indicated that the presence and the position of a carboxyl group in the residue alpha170 are essential for catalysis as well as for the continuous progress of catalytic cycles. It was suggested that the roles of Glu-alpha170 and Asp-alpha335 are to participate in the binding of substrate and intermediates and keep them appropriately oriented and to function as a base in the dehydration of the 1,1-diol intermediate. In addition, Glu-alpha170 seems to stabilize the transition state for the hydroxyl group migration from C2 to C1 by accepting the proton of the spectator hydroxyl group on C1.

Published

2006

29. Insights into the hydrogen-abstraction reactions of diol dehydratase: relevance to the catalytic mechanism and suicide inactivation.

Author

Sandala GM, Smith DM, Coote ML, Golding BT, and Radom L

Subjects

Acetaldehyde analogs & derivatives, Acetaldehyde chemistry, Acetaldehyde metabolism, Catalysis, Electron Spin Resonance Spectroscopy, Enzyme Activation, Ethylene Glycol chemistry, Ethylene Glycol metabolism, Free Radicals chemistry, Free Radicals metabolism, Glyoxal chemistry, Glyoxal metabolism, Hydrogen chemistry, Hydrogen metabolism, Kinetics, Propylene Glycol chemistry, Propylene Glycol metabolism, Quantum Theory, Thermodynamics, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism

Abstract

High-level quantum chemistry calculations have been used to examine the hydrogen-abstraction reactions of diol dehydratase (DDH) in the context of both the catalytic mechanism and the enzyme dysfunction phenomenon termed suicide inactivation. The barriers for the catalytic hydrogen-abstraction reactions of ethane-1,2-diol and propane-1,2-diol are examined in isolation, as well as in the presence of various Brønsted acids and bases. Modest changes in the magnitudes of the initial and final abstraction barriers are seen, depending on the strength of the acid or base, and on whether these effects are considered individually or together. The most significant changes (ca. 20 kJ mol(-1)) are found for the initial abstraction barrier when the spectator OH group is partially deprotonated. Kinetic isotope effects including Eckart tunneling corrections (KIEs) have also been calculated for these model systems. We find that contributions from tunneling are of a magnitude similar to that of the contributions from semiclassical theory alone, meaning that quantum effects serve to significantly accelerate the rate of hydrogen transfer. The calculated KIEs for the partially deprotonated system are in qualitative agreement with experimentally determined values. In complementary investigations, the ability of DDH to become deactivated by certain substrate analogues is examined. In all cases, the formation of a stable radical intermediate causes the hydrogen re-abstraction step to become an extremely endothermic process. The consequent inability of 5'-deoxyadenosyl radical to be regenerated breaks the catalytic cycle, resulting in the suicide inactivation of DDH.

Published

2006

30. Acid-, base-, and lewis-acid-catalyzed heterolysis of methoxide from an alpha-hydroxy-beta-methoxy radical: models for reactions catalyzed by coenzyme B12-dependent diol dehydratase.

Author

Xu L and Newcomb M

Subjects

Catalysis, Kinetics, Lasers, Photolysis, Acids pharmacology, Cobamides pharmacology, Free Radicals, Models, Chemical, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism

Abstract

[Reaction: see text].A model for glycol radicals was employed in laser flash photolysis kinetic studies of catalysis of the fragmentation of a methoxy group adjacent to an alpha-hydroxy radical center. Photolysis of a phenylselenylmethylcyclopropane precursor gave a cyclopropylcarbinyl radical that rapidly ring opened to the target alpha-hydroxy-beta-methoxy radical (3). Heterolysis of the methoxy group in 3 gave an enolyl radical (4a) or an enol ether radical cation (4b), depending upon pH. Radicals 4 contain a 2,2-diphenylcyclopropane reporter group, and they rapidly opened to give UV-observable diphenylalkyl radicals as the final products. No heterolysis was observed for radical 3 under neutral conditions. In basic aqueous acetonitrile solutions, specific base catalysis of the heterolysis was observed; the pK(a) of radical 3 was determined to be 12.5 from kinetic titration plots, and the ketyl radical formed by deprotonation of 3 eliminated methoxide with a rate constant of 5 x 10(7) s(-1). In the presence of carboxylic acids in acetonitrile solutions, radical 3 eliminated methanol in a general acid-catalyzed reaction, and rate constants for protonation of the methoxy group in 3 by several acids were measured. Radical 3 also reacted by fragmentation of methoxide in Lewis-acid-catalyzed heterolysis reactions; ZnBr2, Sc(OTf)3, and BF3 were found to be efficient catalysts. Catalytic rate constants for the heterolysis reactions were in the range of 3 x 10(4) to 2 x 10(6) s(-1). The Lewis-acid-catalyzed heterolysis reactions are fast enough for kinetic competence in coenzyme B12 dependent enzyme-catalyzed reactions of glycols, and Lewis-acid-catalyzed cleavages of beta-ethers in radicals might be applied in synthetic reactions.

Published

2005

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

Author

Fukuoka M, Nakanishi Y, Hannak RB, Kräutler B, and Toraya T

Subjects

Binding Sites, Catalysis, Enzyme Activation, Escherichia coli enzymology, Kinetics, Klebsiella oxytoca enzymology, Models, Molecular, Vitamin B 12 analogs & derivatives, Cobamides chemistry, Ethanolamine Ammonia-Lyase chemistry, Molecular Probes chemistry, Propanediol Dehydratase chemistry

Abstract

[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.

Published

2005

32. Crystallization and preliminary X-ray analysis of molecular chaperone-like diol dehydratase-reactivating factor in ADP-bound and nucleotide-free forms.

Author

Mori K, Hieda N, Yamanishi M, Shibata N, and Toraya T

Subjects

Adenosine Triphosphate, Bacterial Proteins genetics, Bacterial Proteins isolation & purification, Cloning, Molecular, Cobamides, Crystallization methods, Magnesium, Molecular Chaperones, X-Ray Diffraction, Adenosine Diphosphate chemistry, Bacterial Proteins chemistry, Klebsiella oxytoca enzymology, Propanediol Dehydratase chemistry

Abstract

Adenosylcobalamin (coenzyme B12) dependent diol dehydratase (EC 4.2.1.28) catalyzes the conversion of 1,2-diols and glycerol to the corresponding aldehydes. It undergoes mechanism-based inactivation by glycerol. The diol dehydratase-reactivating factor (DDR) reactivates the inactivated holoenzymes in the presence of adenosylcobalamin, ATP and Mg2+ by mediating the release of a damaged cofactor. This molecular chaperone-like factor was overexpressed in Escherichia coli, purified and crystallized in the ADP-bound and nucleotide-free forms by the sandwich-drop vapour-diffusion method. The crystals of the ADP-bound form belong to the orthorhombic system, with space group P2(1)2(1)2(1) and unit-cell parameters a = 83.26, b = 84.60, c = 280.09 A, and diffract to 2.0 A. In the absence of nucleotide, DDR crystals were orthorhombic, with space group P2(1)2(1)2(1) and unit-cell parameters a = 81.92, b = 85.37, c = 296.99 A and diffract to 3.0 A. Crystals of both forms were suitable for structural analysis.

Published

2005

33. The N-terminal regions of beta and gamma subunits lower the solubility of adenosylcobalamin-dependent diol dehydratase.

Author

Tobimatsu T, Kawata M, and Toraya T

Subjects

Amino Acid Sequence, Base Sequence, DNA Primers, Escherichia coli genetics, Klebsiella oxytoca genetics, Molecular Sequence Data, Propanediol Dehydratase chemistry, Propanediol Dehydratase genetics, Solubility, Cobamides metabolism, Propanediol Dehydratase metabolism

Abstract

Adenosylcobalamin-dependent diol dehydratase is one of essential components of carboxysome-like polyhedral bodies. It exists as a heterohexamer (alphabetagamma)(2), and its activity is recovered in a precipitant fraction of Klebsiella oxytoca and overexpressing Escherichia coli cells. Limited proteolysis of the enzyme with trypsin converted the enzyme into a highly soluble form without loss of enzyme activity. The N-terminal amino acid sequencing of the enzyme thus solubilized indicated that the N-terminal 20 and 16 amino acid residues had been removed from the beta and gamma subunits, respectively. Mutant enzymes with the same N-terminal truncations of either or both of the beta and gamma subunits were expressed on a high level in E. coli cells. All the mutant enzymes obtained were expressed in a soluble, active form. These results indicate that the N-terminal regions of the beta and gamma subunits lower the solubility of diol dehydratase. The mutant enzyme with the N-terminal truncations of both beta and gamma subunits was essentially indistinguishable in catalytic properties from recombinant wild-type enzyme or the enzyme purified from K. oxytoca in a soluble form.

Published

2005

34. Identification of the 1,2-propanediol-1-yl radical as an intermediate in adenosylcobalamin-dependent diol dehydratase reaction.

Author

Yamanishi M, Ide H, Murakami Y, and Toraya T

Subjects

Binding Sites, Carbon Isotopes metabolism, Cobamides metabolism, Deuterium Exchange Measurement, Electron Spin Resonance Spectroscopy, Energy Metabolism, Free Radicals, Hydrogen Bonding, Klebsiella oxytoca enzymology, Models, Molecular, Propanediol Dehydratase metabolism, Propylene Glycols metabolism, Substrate Specificity, Cobamides chemistry, Propanediol Dehydratase chemistry, Propylene Glycols chemistry

Abstract

The reaction catalyzed by adenosylcobalamin-dependent diol dehydratase proceeds by a radical mechanism. A radical pair consisting of the Co(II) of cob(II)alamin and an organic radical intermediate formed during catalysis gives EPR spectra. The high-field doublet and the low-field broad signals arise from the weak interaction of an organic radical with the low-spin Co(II) of cob(II)alamin. To characterize the organic radical intermediate in the diol dehydratase reaction, several deuterated and (13)C-labeled 1,2-propanediols were synthesized, and the EPR spectra observed in the catalysis were measured using them as substrate. The EPR spectra with the substrates deuterated on C1 showed significant line width narrowing of the doublet signal. A distinct change in the hyperfine coupling was seen with [1-(13)C]-1,2-propanediol, but not with the [2-(13)C]-counterpart. Thus, the organic radical intermediate observed by EPR spectroscopy was identified as the 1,2-propanediol-1-yl radical, a C1-centered substrate-derived radical.

Published

2005

35. Catalytic roles of active-site amino acid residues of coenzyme B12-dependent diol dehydratase: protonation state of histidine and pull effect of glutamate.

Author

Kamachi T, Toraya T, and Yoshizawa K

Subjects

Binding Sites, Catalysis, Cobamides chemistry, Glutamic Acid chemistry, Histidine chemistry, Hydrogen chemistry, Hydrogen metabolism, Kinetics, Models, Molecular, Potassium chemistry, Potassium metabolism, Propanediol Dehydratase chemistry, Protein Conformation, Quantum Theory, Thermodynamics, Cobamides metabolism, Glutamic Acid metabolism, Histidine metabolism, Propanediol Dehydratase metabolism

Abstract

The hydrogen abstraction and the OH migration processes catalyzed by diol dehydratase are discussed by means of a quantum mechanical/molecular mechanical method. To evaluate the push effect of His143 and the pull effect of Glu170, we considered three kinds of whole-enzyme model, the protonated and two unprotonated His143 models. A calculated activation energy for the hydrogen abstraction by the adenosyl radical is 15.6 (13.6) kcal/mol in the protonated (unprotonated) His143 model. QM/MM calculational results show that the mechanism of the OH migration is significantly changed by the protonation of His143. In the protonated His143 model, the OH group migration triggered by the full proton donation from the imidazolium to the migrating OH group occurs by a stepwise OH abstraction/re-addition process in which the water production reduces the barrier for the C-O bond cleavage. On the other hand, the OH migration in the unprotonated His143 model proceeds in a concerted manner, as we previously proposed using a simple model including only K+ ion and substrate. The latter mechanism seems to be kinetically more favorable from the calculated energy profiles and is consistent with experimental results. The activation barrier of the OH group migration step is only 1.6 kcal/mol reduced by the hydrogen-bonding interaction between the O2 of the substrate and unprotonated His143. Thus, it is predicted that His143 is not protonated, and therefore the main active-site amino acid residue that lowers the energy of the transition state for the OH group migration is determined to be Glu170.

Published

2004

36. Lewis acid catalysis in heterolysis reactions of glycol ether radicals mimicking diol dehydratase-catalyzed reactions.

Author

Miranda N, Xu L, and Newcomb M

Subjects

Catalysis, Ethers chemistry, Free Radicals chemistry, Molecular Mimicry, Propanediol Dehydratase chemistry

Abstract

Zinc bromide-catalyzed heterolysis reactions of glycol ether radicals were studied by laser flash photolysis methods, which gave the binding constants and catalytic rate constants for fragmentation. The Lewis acid-catalyzed heterolysis reactions mimic a putative reaction pathway in diol dehydratase-catalyzed reactions and are potentially useful polar processes for incorporation into conventional radical chain reaction sequences. [reaction: see text]

Published

2004

37. Suicide inactivation of dioldehydratase by glycolaldehyde and chloroacetaldehyde: an examination of the reaction mechanism.

Author

Sandala GM, Smith DM, Coote ML, and Radom L

Subjects

Acetaldehyde chemistry, Binding Sites, Electron Spin Resonance Spectroscopy, Enzyme Activation drug effects, Propanediol Dehydratase chemistry, Thermodynamics, Acetaldehyde analogs & derivatives, Acetaldehyde pharmacology, Propanediol Dehydratase antagonists & inhibitors, Propanediol Dehydratase metabolism

Abstract

High-level ab initio calculations have been used to study the mechanism for the inactivation of diol dehydratase (DDH) by glycolaldehyde or 2-chloroacetaldehyde. As in the case of the catalytic substrates of DDH, e.g., ethane-1,2-diol, the 5'-deoxyadenosyl radical (Ado*) is able to abstract a hydrogen atom from both substrate analogues in the initial step on the reaction pathway, as evidenced by comparable energy barriers. However, in subsequent step(s), each substrate analogue produces the highly stable glycolaldehyde radical. The barrier for hydrogen atom reabstraction by the glycolaldehyde radical is calculated to be too high ( approximately 110 kJ mol-1) to allow Ado* to be regenerated and recombine with the cob(II)alamin radical, the latter therefore remaining tightly bound to DDH. As a consequence, the catalytic pathway is disrupted, and DDH becomes an impotent enzyme. Interconversion of equivalent structures of the glycolaldehyde radical via the symmetrical cis-ethanesemidione radical is calculated to require 38 kJ mol-1. EPR indications of a symmetrical cis-ethanesemidione structure are likely to be the result of formation of an equilibrium mixture of glycolaldehyde radical structures, this equilibration being facilitated by partial deprotonation of the glycolaldehyde radical by the carboxylate of an amino acid residue within the active site of DDH.

Published

2004

38. Insight into the mechanism of the B12-independent glycerol dehydratase from Clostridium butyricum: preliminary biochemical and structural characterization.

Author

O'Brien JR, Raynaud C, Croux C, Girbal L, Soucaille P, and Lanzilotta WN

Subjects

Acetyltransferases chemistry, Amino Acid Sequence, Binding Sites, Clostridium growth & development, Crystallization, Crystallography, X-Ray, Culture Media, Enzyme Activation, Enzyme Reactivators chemistry, Enzyme Reactivators metabolism, Glycerol metabolism, Hydro-Lyases isolation & purification, Molecular Sequence Data, Propanediol Dehydratase chemistry, Propylene Glycol metabolism, Structure-Activity Relationship, Substrate Specificity, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Clostridium enzymology, Hydro-Lyases chemistry, Hydro-Lyases metabolism, Vitamin B 12 chemistry

Abstract

The molecular characterization of a B12-independent glycerol dehydratase from Clostridium butyricum has recently been reported [Raynaud, C., et al. (2003) Proc. Natl. Acad. Sci. U.S.A. 100, 5010-5015]. In this work, we have further characterized this system by biochemical and crystallographic methods. Both the glycerol dehydratase (GD) and the GD-activating enzyme (GD-AE) could be purified to homogeneity under aerobic conditions. In this form, both the GD and GD-AE were inactive. A reconstitution procedure, similar to what has been reported for pyruvate formate lyase activating enzyme (PFL-AE), was employed to reconstitute the activity of the GD-AE. Subsequently, the reconstituted GD-AE could be used to reactivate the GD under strictly anaerobic conditions. We also report here the crystal structure of the inactive GD in the native (2.5 A resolution, Rcryst = 17%, Rfree = 20%), glycerol-bound (1.8 A resolution, Rcryst = 21%, Rfree = 24%), and 1,2-propanediol-bound (2.4 A resolution, Rcryst = 20%, Rfree = 24%) forms. The overall fold of the GD monomer was similar to what has been observed for pyruvate formate lyase (PFL) and anaerobic ribonucleotide reductase (ARNR), consisting of a 10-stranded beta/alpha barrel motif. Clear density was observed for both substrates, and a mechanism for the dehydration reaction is presented. This mechanism clearly supports a concerted pathway for migration of the OH group through a cyclic transition state that is stabilized by partial protonation of the migrating OH group. Finally, despite poor alignment (rmsd approximately 6.8 A) of the 10 core strands that comprise the barrel structure of the GD and PFL, the C-terminal domains of both proteins align well (rmsd approximately 0.7 A) and have structural properties consistent with this being the docking site for the activating enzyme. A single point mutation within this domain, at a strictly conserved arginine residue (R782K) in the GD, resulted in formation of a tight protein-protein complex between the GD and the GD-AE in vivo, thereby supporting this hypothesis.

Published

2004

39. The first experimental test of the hypothesis that enzymes have evolved to enhance hydrogen tunneling.

Author

Doll KM, Bender BR, and Finke RG

Subjects

Cobamides metabolism, Free Radicals chemistry, Free Radicals metabolism, Hydrogen metabolism, Kinetics, Propanediol Dehydratase metabolism, Thermodynamics, Cobamides chemistry, Hydrogen chemistry, Propanediol Dehydratase chemistry

Abstract

The literature hypothesis that "the optimization of enzyme catalysis may entail the evolutionary implementation of chemical strategies that increase the probability of quantum-mechanical tunneling" is experimentally tested herein for the first time. The system employed is the key to being able to provide this first experimental test of the "enhanced hydrogen tunneling" hypothesis, one that requires a comparison of the three criteria diagnostic of tunneling (vide infra) for the same, or nearly the same, reaction with and without the enzyme. Specifically, studied herein are the adenosylcobalamin (AdoCbl, also known as coenzyme B(12))-dependent diol dehydratase model reactions of (i). H(D)(*) atom abstraction from ethylene glycol-d(0) and ethylene glycol-d(4) solvent by 5'-deoxyadenosyl radical (Ado(*)) and (ii.) the same H(*) abstraction reactions by the 8-methoxy-5'-deoxyadenosyl radical (8-MeOAdo(*)). The Ado(*) and 8-MeOAdo(*) radicals are generated by Co-C thermolysis of their respective precursors, AdoCbl and 8-MeOAdoCbl. Deuterium kinetic isotope effects (KIEs) of the H(*)(D(*)) abstraction reactions from ethylene glycol have been measured over a temperature range of 80-120 degrees C: KIE = 12.4 +/- 1.1 at 80 degrees C for Ado(*) and KIE = 12.5 +/- 0.9 at 80 degrees C for 8-MeOAdo(*) (values ca. 2-fold that of the predicted maximum primary times secondary ground-state zero-point energy (GS-ZPE) KIE of 6.4 at 80 degrees C). From the temperature dependence of the KIEs, zero-point activation energy differences ([E(D) - E(H)]) of 3.0 +/- 0.3 kcal mol(-)(1) for Ado(*) and 2.1 +/- 0.6 kcal mol(-)(1) for 8-MeOAdo(*) have been obtained, both of which are significantly larger than the nontunneling, zero-point energy only maximum of 1.2 kcal mol(-)(1). Pre-exponential factor ratios (A(H)/A(D)) of 0.16 +/- 0.07 for Ado(*) and 0.5 +/- 0.4 for 8-MeOAdo(*) are observed, both of which are significantly less than the 0.7 minimum for nontunneling behavior. The data provide strong evidence for the expected quantum mechanical tunneling in the Ado(*) and 8-MeOAdo(*)-mediated H(*) abstraction reactions from ethylene glycol. More importantly, a comparison of these enzyme-free tunneling data to the same KIE, (E(D) - E(H)) and A(H)/A(D) data for a closely related, Ado(*)-mediated H(*) abstraction reaction from a primary CH(3)- group in AdoCbl-dependent methylmalonyl-CoA mutase shows the enzymic and enzyme-free data sets are identical within experimental error. The Occam's Razor conclusion is that at least this adenosylcobalamin-dependent enzyme has not evolved to enhance quantum mechanical tunneling, at least within the present error bars. Instead, this B(12)-dependent enzyme simply exploits the identical level of quantum mechanical tunneling that is available in the enzyme-free, solution-based H(*) abstraction reaction. The results also require a similar, if not identical, barrier width and height within experimental error for the H(*) abstraction both within, and outside of, the enzyme.

Published

2003

40. Structural rationalization for the lack of stereospecificity in coenzyme B12-dependent diol dehydratase.

Author

Shibata N, Nakanishi Y, Fukuoka M, Yamanishi M, Yasuoka N, and Toraya T

Subjects

Cloning, Molecular, Escherichia coli genetics, Models, Molecular, Propanediol Dehydratase isolation & purification, Protein Conformation, Recombinant Proteins chemistry, Recombinant Proteins isolation & purification, Recombinant Proteins metabolism, Stereoisomerism, Substrate Specificity, Klebsiella oxytoca enzymology, Malondialdehyde chemistry, Malondialdehyde metabolism, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism, Vitamin B 12 pharmacology

Abstract

Adenosylcobalamin-dependent diol dehydratase of Klebsiella oxytoca is apparently not stereospecific and catalyzes the conversion of both (R)- and (S)-1,2-propanediol to propionaldehyde. To explain this unusual property of the enzyme, we analyzed the crystal structures of diol dehydratase in complexes with cyanocobalamin and (R)- or (S)-1,2-propanediol. (R)- and (S)-isomers are bound in a symmetrical manner, although the hydrogen-bonding interactions between the substrate and the active-site residues are the same. From the position of the adenosyl radical in the modeled "distal" conformation, it is reasonable for the radical to abstract the pro-R and pro-S hydrogens from (R)- and (S)-isomers, respectively. The hydroxyl groups in the substrate radicals would migrates from C(2) to C(1) by a suprafacial shift, resulting in the stereochemical inversion at C(1). This causes 60 degrees clockwise and 70 degrees counterclockwise rotations of the C(1)-C(2) bond of the (R)- and (S)-isomers, respectively, if viewed from K+. A modeling study of 1,1-gem-diol intermediates indicated that new radical center C(2) becomes close to the methyl group of 5'-deoxyadenosine. Thus, the hydrogen back-abstraction (recombination) from 5'-deoxyadenosine by the product radical is structurally feasible. It was also predictable that the substitution of the migrating hydroxyl group by a hydrogen atom from 5'-deoxyadenosine takes place with the inversion of the configuration at C(2) of the substrate. Stereospecific dehydration of the 1,1-gem-diol intermediates can also be rationalized by assuming that Asp-alpha335 and Glu-alpha170 function as base catalysts in the dehydration of the (R)- and (S)-isomers, respectively. The structure-based mechanism and stereochemical courses of the reaction are proposed.

Published

2003

41. Crystal structure of substrate free form of glycerol dehydratase.

Author

Liao DI, Dotson G, Turner I Jr, Reiss L, and Emptage M

Subjects

Binding Sites, Crystallization, Crystallography, X-Ray, Hydro-Lyases isolation & purification, Hydro-Lyases metabolism, Klebsiella pneumoniae enzymology, Models, Molecular, Molecular Structure, Propanediol Dehydratase chemistry, Propanediol Dehydratase isolation & purification, Propanediol Dehydratase metabolism, Protein Binding, Protein Structure, Secondary, Protein Structure, Tertiary, Recombinant Proteins chemistry, Recombinant Proteins isolation & purification, Recombinant Proteins metabolism, Substrate Specificity, Vitamin B 12 metabolism, Hydro-Lyases chemistry

Abstract

Glycerol dehydratase (GDH) and diol dehydratase (DDH) are highly homologous isofunctional enzymes that catalyze the elimination of water from glycerol and 1,2-propanediol (1,2-PD) to the corresponding aldehyde via a coenzyme B(12)-dependent radical mechanism. The crystal structure of substrate free form of GDH in complex with cobalamin and K(+) has been determined at 2.5 A resolution. Its overall fold and the subunit assembly closely resemble those of DDH. Comparison of this structure and the DDH structure, available only in substrate bound form, shows the expected change of the coordination of the essential K(+) from hexacoordinate to heptacoordinate with the displacement of a single coordinated water by the substrate diol. In addition, there appears to be an increase in the rigidity of the K(+) coordination (as measured by lower B values) upon the binding of the substrate. Structural analysis of the locations of conserved residues among various GDH and DDH sequences has aided in identification of residues potentially important for substrate preference or specificity of protein-protein interactions.

Published

2003

42. Functions of the D-ribosyl moiety and the lower axial ligand of the nucleotide loop of coenzyme B(12) in diol dehydratase and ethanolamine ammonia-lyase reactions.

Author

Fukuoka M, Yamada S, Miyoshi S, Yamashita K, Yamanishi M, Zou X, Brown KL, and Toraya T

Subjects

Apoenzymes chemistry, Apoenzymes metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Cobamides metabolism, Ethanolamine Ammonia-Lyase chemistry, Molecular Structure, Propanediol Dehydratase chemistry, Spectrum Analysis, Cobamides chemistry, Ethanolamine Ammonia-Lyase metabolism, Ligands, Nucleic Acid Conformation, Propanediol Dehydratase metabolism

Abstract

The roles of the D-ribosyl moiety and the bulky axial ligand of the nucleotide loop of adenosylcobalamin in coenzymic function have been investigated using two series of coenzyme analogs bearing various artificial bases. The 2-methylbenzimidazolyl trimethylene analog that exists exclusively in the base-off form was a totally inactive coenzyme for diol dehydratase and served as a competitive inhibitor. The benzimidazolyl trimethylene analog and the benzimidazolylcobamide coenzyme were highly active for diol dehydratase and ethanolamine ammonia-lyase. The imidazolylcobamide coenzyme was 59 and 9% as active as the normal coenzyme for diol dehydratase and ethanolamine ammonia-lyase, respectively. The latter analog served as an effective suicide coenzyme for both enzymes, although the partition ratio (k(cat)/k(inact)) of 630 for ethanolamine ammonia-lyase is much lower than that for diol dehydratase. Suicide inactivation was accompanied by the accumulation of a cob(II)amide species, indicating irreversible cleavage of the coenzyme Co-C bond during the inactivation. It was thus concluded that the bulkiness of a Co-coordinating base of the nucleotide loop is essential for both the initial activity and continuous catalytic turnovers. Since the k(cat)/k(inact) value for the imidazolylcobamide in diol dehydratase was 27-times higher than that for the imidazolyl trimethylene analog, it is clear that the ribosyl moiety protects the reaction intermediates from suicide inactivation. Stopped-flow measurements indicated that the rate of Co-C bond homolysis is essentially unaffected by the bulkiness of the Co-coordinating base for diol dehydratase. Thus, it seems unlikely that the Co-C bond is labilized through a ground state mechanochemical triggering mechanism in diol dehydratase.

Published

2002

43. Purification, characterization and subunits identification of the diol dehydratase of Lactobacillus collinoides.

Author

Sauvageot N, Pichereau V, Louarme L, Hartke A, Auffray Y, and Laplace JM

Subjects

Chromatography, Gel, Cloning, Molecular, Electrophoresis, Gel, Two-Dimensional, Electrophoresis, Polyacrylamide Gel, Glycerol pharmacology, Hydrogen-Ion Concentration, Kinetics, Propylene Glycol pharmacology, Temperature, Time Factors, Lactobacillus enzymology, Propanediol Dehydratase chemistry, Propanediol Dehydratase isolation & purification

Abstract

The three genes pduCDE encoding the diol dehydratase of Lactobacillus collinoides, have been cloned for overexpression in the pQE30 vector. Although the three subunits of the protein were highly induced, no activity was detected in cell extracts. The enzyme was therefore purified to near homogeneity by ammonium sulfate precipitation and gel filtration chromatography. In fractions showing diol dehydratase activity, three main bands were present after SDS/PAGE with molecular masses of 63, 28 and 22 kDa, respectively. They were identified by mass spectrometry to correspond to the large, medium and small subunits of the dehydratase encoded by the pduC, pduD and pduE genes, respectively. The molecular mass of the native complex was estimated to 207 kDa in accordance with the calculated molecular masses deduced from the pduC, D, E genes (61, 24.7 and 19,1 kDa, respectively) and a alpha2beta2gamma2 composition. The Km for the three main substrates were 1.6 mm for 1,2-propanediol, 5.5 mm for 1,2-ethanediol and 8.3 mm for glycerol. The enzyme required the adenosylcobalamin coenzyme for catalytic activity and the Km for the cofactor was 8 micro m. Inactivation of the enzyme was observed by both glycerol and cyanocobalamin. The optimal reaction conditions of the enzyme were pH 8.75 and 37 degrees C. Activity was inhibited by sodium and calcium ions and to a lesser extent by magnesium. A fourth band at 59 kDa copurified with the diol dehydratase and was identified as the propionaldehyde dehydrogenase enzyme, another protein involved in the 1,2-propanediol metabolism pathway.

Published

2002

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

Author

Shibata N, Masuda J, Morimoto Y, Yasuoka N, and Toraya T

Subjects

Binding Sites, Carbon chemistry, Cations, Monovalent, Cobalt chemistry, Crystallization, Crystallography, X-Ray, Klebsiella enzymology, Models, Molecular, Potassium chemistry, Protein Conformation, Substrate Specificity, Cobamides chemistry, Propanediol Dehydratase chemistry, Vitamin B 12 chemistry

Abstract

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.

Published

2002

45. The crystal structure of coenzyme B12-dependent glycerol dehydratase in complex with cobalamin and propane-1,2-diol.

Author

Yamanishi M, Yunoki M, Tobimatsu T, Sato H, Matsui J, Dokiya A, Iuchi Y, Oe K, Suto K, Shibata N, Morimoto Y, Yasuoka N, and Toraya T

Subjects

Binding Sites, Cobamides metabolism, Crystallography, X-Ray, Escherichia coli, Hydro-Lyases genetics, Hydro-Lyases isolation & purification, Hydro-Lyases metabolism, Kinetics, Models, Molecular, Potassium metabolism, Propanediol Dehydratase chemistry, Propylene Glycol metabolism, Protein Conformation, Recombinant Proteins chemistry, Recombinant Proteins genetics, Spectrum Analysis, Substrate Specificity, Vitamin B 12 metabolism, Cobamides chemistry, Hydro-Lyases chemistry, Propylene Glycol chemistry, Vitamin B 12 chemistry

Abstract

Recombinant glycerol dehydratase of Klebsiella pneumoniae was purified to homogeneity. The subunit composition of the enzyme was most probably alpha 2 beta 2 gamma 2. When (R)- and (S)-propane-1,2-diols were used independently as substrates, the rate with the (R)-enantiomer was 2.5 times faster than that with the (S)-isomer. In contrast to diol dehydratase, an isofunctional enzyme, the affinity of the enzyme for the (S)-isomer was essentially the same or only slightly higher than that for the (R)-isomer (Km(R)/Km(S) = 1.5). The crystal structure of glycerol dehydratase in complex with cyanocobalamin and propane-1,2-diol was determined at 2.1 A resolution. The enzyme exists as a dimer of the alpha beta gamma heterotrimer. Cobalamin is bound at the interface between the alpha and beta subunits in the so-called 'base-on' mode with 5,6-dimethylbenzimidazole of the nucleotide moiety coordinating to the cobalt atom. The electron density of the cyano group was almost unobservable, suggesting that the cyanocobalamin was reduced to cob(II)alamin by X-ray irradiation. The active site is in a (beta/alpha)8 barrel that was formed by a central region of the alpha subunit. The substrate propane-1,2-diol and essential cofactor K+ are bound inside the (beta/alpha)8 barrel above the corrin ring of cobalamin. K+ is hepta-coordinated by the two hydroxyls of the substrate and five oxygen atoms from the active-site residues. These structural features are quite similar to those of diol dehydratase. A closer contact between the alpha and beta subunits in glycerol dehydratase may be reminiscent of the higher affinity of the enzyme for adenosylcobalamin than that of diol dehydratase. Although racemic propane-1,2-diol was used for crystallization, the substrate bound to glycerol dehydratase was assigned to the (R)-isomer. This is in clear contrast to diol dehydratase and accounts for the difference between the two enzymes in the susceptibility of suicide inactivation by glycerol.

Published

2002

46. Interactions of diol dehydrase and 3',4'-anhydroadenosylcobalamin: suicide inactivation by electron transfer.

Author

Magnusson OT and Frey PA

Subjects

Carbon chemistry, Chromatography, High Pressure Liquid, Chromatography, Liquid, Cobalt chemistry, Deuterium, Dideoxyadenosine chemistry, Electron Transport, Enzyme Activation, Hydrolysis, Kinetics, Nuclear Magnetic Resonance, Biomolecular, Oxidation-Reduction, Propanediol Dehydratase isolation & purification, Propanediol Dehydratase metabolism, Salmonella typhimurium enzymology, Spectrometry, Mass, Electrospray Ionization, Spectrophotometry, Ultraviolet, Vitamin B 12 chemistry, Cobamides chemistry, Enzyme Inhibitors chemistry, Propanediol Dehydratase antagonists & inhibitors, Propanediol Dehydratase chemistry

Abstract

3',4'-Anhydroadenosylcobalamin (anAdoCbl) is an analogue of the adenosylcobalamin (AdoCbl) coenzyme (Magnusson, O.Th., and Frey, P. A. (2000) J. Am. Chem. Soc. 122, 8807-8813). This compound supports activity for diol dehydrase at 0.02% of that observed with AdoCbl. In a side reaction, however, anAdoCbl induces suicide inactivation by an electron-transfer mechanism. Homolytic cleavage of the Co-C bond of anAdoCbl at the active site of diol dehydrase was observed by spectrophotometric detection of cob(II)alamin. Anaerobic conversion of enzyme bound cob(II)alamin to cob(III)alamin, both in the absence and presence of substrate, indicates that the coenzyme derived 5'-deoxy-3',4'-anhydroadenosine-5'-yl serves as the oxidizing agent. This hypothesis is supported by the stoichiometric formation of 3',5'-dideoxyadenosine-4',5'-ene as the nucleoside cleavage product, as determined by high-performance liquid chromatography, mass spectrometry, and nuclear magnetic resonance spectroscopy. Experiments performed in deuterium oxide show that a single solvent exchangeable proton is incorporated into the product. These data are consistent with the intermediate formation of a transient allylic anion formed after one electron transfer from cob(II)alamin to the allylic 5'-deoxy-3',4'-anhydroadenosyl radical. Selective protonation at C3' was demonstrated by spectroscopic characterization of the purified product. This study provides an example of suicide inactivation of a radical enzyme brought about by a side reaction of an analogue of the radical intermediate.

Published

2002

47. [Radical-catalyzed enzymatic reactions: structure and mechanism of B12 enzymes].

Author

Toraya T

Subjects

Adenine metabolism, Binding Sites physiology, Catalysis, Cobamides physiology, Free Radicals, Molecular Conformation, Potassium physiology, Propanediol Dehydratase chemistry, Propanediol Dehydratase metabolism, Cobamides chemistry, Vitamin B 12 metabolism

Published

2002

48. Enzymatic radical catalysis: coenzyme B12-dependent diol dehydratase.

Author

Toraya T

Subjects

Adenine metabolism, Amino Acids chemistry, Bacteria enzymology, Bacteria genetics, Binding Sites, Catalysis, Cobamides metabolism, Crystallography, X-Ray, Electron Spin Resonance Spectroscopy, Free Radicals chemistry, Free Radicals metabolism, Kinetics, Models, Molecular, Molecular Structure, Potassium metabolism, Propanediol Dehydratase metabolism, Thermodynamics, Vitamin B 12 chemistry, Cobamides chemistry, Propanediol Dehydratase chemistry, Vitamin B 12 metabolism

Abstract

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., (Copyright 2002 The Japan Chemical Journal Forum and Wiley Periodicals, Inc. Chem Rec 2: 352-366, 2002: Published online in Wiley InterScience (www.interscience.wiley.com) DOI 10.1002/tcr.10035)

Published

2002

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

Author

Masuda J, Shibata N, Morimoto Y, Toraya T, and Yasuoka N

Subjects

Crystallography, X-Ray, Free Radicals chemistry, Free Radicals radiation effects, In Vitro Techniques, Macromolecular Substances, Models, Molecular, Photochemistry, Protein Conformation, Static Electricity, Organometallic Compounds chemistry, Organometallic Compounds radiation effects, Propanediol Dehydratase chemistry, Propanediol Dehydratase radiation effects

Abstract

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.

Published

2001

50. Understanding the mechanism of B(12)-dependent diol dehydratase: a synergistic retro-push--pull proposal.

Author

Smith DM, Golding BT, and Radom L

Subjects

Catalysis, Cobamides chemistry, Electron Transport, Models, Chemical, Propanediol Dehydratase chemistry, Cobamides metabolism, Propanediol Dehydratase metabolism

Abstract

Ab initio molecular orbital theory is used to investigate the coenzyme B(12)-dependent reactions catalyzed by diol dehydratase. The key step in such reactions is believed to be a 1,2-hydroxyl migration, which occurs within free-radical intermediates. The barrier for this migration, if unassisted, is calculated to be too high to be consistent with the observed reaction rate. However, we find that "pushing" the migrating hydroxyl, through interaction with a suitable acid, is able to provide significant catalysis. This is denoted retro-push catalysis, the retro prefix signifying that the motion of the migrating group is in the direction opposite to the electron motion. Similarly, the "pulling" of the migrating group, through interaction of the spectator hydroxyl with an appropriate base, is found to substantially reduce the rearrangement barrier. Importantly, the combination of these two effects results in a barrier reduction that is notably greater than additive. This synergistic interplay of the push and the pull provides an attractive means of catalysis. Our proposed retro-push--pull mechanism leads to results that are consistent with isotope-labeling experiments, with experimental rate data, and with the crystal structure of the enzyme.

Published

2001