Pathogenic and Commensal Gut Bacteria Harboring Glycerol/Diol Dehydratase Metabolize Glycerol and Produce DNA-Reactive Acrolein.

Bacteria harboring glycerol/diol dehydratase (GDH) encoded by the genes pduCDE metabolize glycerol and release acrolein during growth. Acrolein has antimicrobial activity, and exposure of human cells to acrolein gives rise to toxic and mutagenic responses. These biological responses are related to acrolein's high reactivity as a chemical electrophile that can covalently bind to cellular nucleophiles including DNA and proteins. Various food microbes and gut commensals transform glycerol to acrolein, but there is no direct evidence available for bacterial glycerol metabolism giving rise to DNA adducts. Moreover, it is unknown whether pathogens, such as Salmonella Typhymurium, catalyze this transformation. We assessed, therefore, acrolein formation by four GDH-competent strains of S. Typhymurium grown under either aerobic or anaerobic conditions in the presence of 50 mM glycerol. On the basis of analytical derivatization with a heterocyclic amine, all wild-type strains were observed to produce acrolein, but to different extents, and acrolein production was not detected in fermentations of a pduC-deficient mutant strain. Furthermore, we found that, in the presence of calf thymus DNA, acrolein-DNA adducts were formed as a result of bacterial glycerol metabolism by two strains of Limosilactobacillus reuteri, but not a pduCDE mutant strain. The quantification of the resulting adducts with increasing levels of glycerol up to 600 mM led to the production of up to 1.5 mM acrolein and 3600 acrolein-DNA adducts per 108 nucleosides in a model system. These results suggest that GDH-competent food microbes, gut commensals, and pathogens alike have the capacity to produce acrolein from glycerol. Further, the acrolein production can lead to DNA adduct formation, but requires high glycerol concentrations that are not available in the human gut.

Structural Insights into the Very Low Activity of the Homocoenzyme B12 Adenosylmethylcobalamin in Coenzyme B12 -Dependent Diol Dehydratase and Ethanolamine Ammonia-Lyase.

The X-ray structures of coenzyme B12 (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 CH2 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.

The roles of diol dehydratase from pdu operon on glycerol catabolism in Klebsiella pneumoniae.

The dha operon of Klebsiella pneumoniae is responsible for glycerol catabolism and 1,3-propanediol formation. Subunits of glycerol dehydratase and the large subunit of glycerol dehydratase reactivating factor are encoded by dhaBCE and dhaF, respectively. Proteins of pdu operon form a microcompartment (bacteria organelle) and responsible for 1,2-propanediol catabolism. In this operon, pduCDE and pduG encode subunits of diol dehydratase and its reactivating factor. Diol dehydratase is an isofunctional enzyme of glycerol dehydratase, but its role in glycerol catabolism was not entirely clear. In this study, dhaBCE, pduCDE, dhaF, and pduG in K. pneumoniae were knocked out individually or combinedly. These strains were cultured with glycerol as a substrate, and dehydratase activities in the cytoplasm and microcompartment were detected. Results showed that glycerol dehydratase and diol dehydratase were simultaneously responsible for glycerol catabolism in K. pneumoniae. Besides being packaged in microcompartment, large amounts of diol dehydratase was also presented in the cytoplasm. However, the Pdu microcompartment reduced the accumulation of 3-hydroxypropionaldehyde in the fermentation broth. PduG can cross reactivate glycerol dehydratase instead of DhaF. However, DhaF is not involved in reactivation of diol dehydratase. In conclusion, diol dehydratase and Pdu microcompartment play important roles in glycerol catabolism in K. pneumoniae.

Computational Study of Glycerol Binding within the Active Site of Coenzyme B12-Dependent Diol Dehydratase.

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 B12-dependent diol dehydratase (B12-dDDH). A peculiar feature of the B12-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 B12-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 B12-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 B12-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 B12-dDDH, where the slightly preferred conformer is C3-OH···Ser301. However, in AdoCbl B12-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 B12-dDDH enzyme.

Gut microbial beta-glucuronidase and glycerol/diol dehydratase activity contribute to dietary heterocyclic amine biotransformation.

BACKGROUND: Consuming red and processed meat has been associated with an increased risk of colorectal cancer (CRC), which is partly attributed to exposure to carcinogens such as heterocyclic amines (HCA) formed during cooking and preservation processes. The interaction of gut microbes and HCA can result in altered bioactivities and it has been shown previously that human gut microbiota can transform mutagenic HCA to a glycerol conjugate with reduced mutagenic potential. However, the major form of HCA in the colon are glucuronides (HCA-G) and it is not known whether these metabolites, via stepwise microbial hydrolysis and acrolein conjugation, are viable precursors for glycerol conjugated metabolites. We hypothesized that such a process could be concurrently catalyzed by bacterial beta-glucuronidase (B-GUS) and glycerol/diol dehydratase (GDH) activity. We therefore investigated how the HCA-G PhIP-N2-ß-D-glucuronide (PhIP-G), a representative liver metabolite of PhIP (2-Amino-1-methyl-6-phenylimidazo [4,5-b] pyridine), which is the most abundant carcinogenic HCA in well-cooked meat, is transformed by enzymatic activity of human gut microbial representatives of the phyla Firmicutes, Bacteroidetes, and Proteobacteria. RESULTS: We employed a combination of growth and enzymatic assays, and a bioanalysis approach combined with metagenomics. B-GUS of Faecalibacterium prausnitzii converted PhIP-G to PhIP and GDH of Flavonifractor plautii, Blautia obeum, Eubacterium hallii, and Lactobacillus reuteri converted PhIP to PhIP-M1 in the presence of glycerol. In addition, B-GUS- and GDH-positive bacteria cooperatively converted PhIP-G to PhIP-M1. A screen of genes encoding B-GUS and GDH was performed for fecal microbiome data from healthy individuals (n = 103) and from CRC patients (n = 53), which revealed a decrease in abundance of taxa with confirmed GDH and HCA transformation activity in CRC patients. CONCLUSIONS: This study for the first time demonstrates that gut microbes mediate the stepwise transformation of PhIP-G to PhIP-M1 via the intermediate production of PhIP. Findings from this study suggest that targeted manipulation with gut microbes bearing specific functions, or dietary glycerol supplementation might modify gut microbial activity to reduce HCA-induced CRC risk.

Discovering radical-dependent enzymes in the human gut microbiota.

Human gut microbes have a tremendous impact on human health, in part due to their unique chemical capabilities. In the anoxic environment of the healthy human gut, many important microbial metabolic transformations are performed by radical-dependent enzymes. Although identifying and characterizing these enzymes has been challenging, recent advances in genome and metagenome sequencing have enabled studies of their chemistry and biology. Focusing on the glycyl radical enzyme family, one of the most enriched protein families in the human gut microbiota, we highlight different approaches for discovering radical-dependent enzymes that influence host health and disease.

Rational engineering of diol dehydratase enables 1,4-butanediol biosynthesis from xylose.

Establishing novel synthetic routes for microbial production of chemicals often requires overcoming pathway bottlenecks by tailoring enzymes to enhance bio-catalysis or even achieve non-native catalysis. Diol dehydratases have been extensively studied for their interactions with C2 and C3 diols. However, attempts on utilizing these insights to enable catalysis on non-native substrates with more than two hydroxyl groups have been plagued with low efficiencies. Here, we rationally engineered the Klebsiella oxytoca diol dehydratase to enable and enhance catalytic activity toward a non-native C4 triol, 1,2,4-butanetriol. We analyzed dehydratase's interaction with 1,2-propanediol and glycerol, which led us to develop rationally conceived hypotheses. An in silico approach was then developed to identify and screen candidate mutants with desired activity. This led to an engineered diol dehydratase with nearly 5 fold higher catalytic activity toward 1,2,4-butanetriol than the wild type as determined by in vitro assays. Based on this result, we then expanded the 1,2,4-butanetriol pathway to establish a novel 1,4-butanediol production platform. We engineered Escherichia coli's xylose catabolism to enhance the biosynthesis of 1,2,4-butanetriol from 224mg/L to 1506mg/L. By introducing the complete pathway in the engineered strain we achieve de novo biosynthesis of 1,4-butanediol at 209mg/L from xylose. This work expands the repertoire of substrates catalyzed by diol dehydratases and serves as an elucidation to establish novel biosynthetic pathways involving dehydratase based biocatalysis.

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

Many bacteria encode proteinaceous bacterial microcompartments (BMCs) that encapsulate sequential enzymatic reactions of diverse metabolic pathways. Well-characterized BMCs include carboxysomes for CO2-fixation, and propanediol- and ethanolamine-utilizing microcompartments that contain B12-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 B12-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.

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

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.

Fermentative production of 1-propanol from d-glucose, l-rhamnose and glycerol using recombinant Escherichia coli.

Fermentative production of 1-propanol, which is one of the promising precursors of polypropylene production, from d-glucose, l-rhamnose and glycerol using metabolically engineered Escherichia coli was examined. To confer the ability to produce 1-propanol from 1,2-propanediol (1,2-PD) in recombinant E. coli, a part of the pdu regulon including the diol dehydratase and the propanol dehydrogenase genes together with the adenosylcobalamin (AdoCbl) regeneration enzyme genes of Klebsiella pneumoniae was cloned, and an expression vector for these genes (pRSF_pduCDEGHOQS) was constructed. Recombinant E. coli harboring pRSF_pduCDEGHOQS with 1,2-PD synthetic pathway (pKK_mde) genes, which was constructed in our previous report (Urano et al., Appl. Microbiol. Biotechnol., 99, 2001-2008, 2015), produced 16.1 mM of 1-propanol from d-glucose with a molar yield of 0.36 mol/mol after 72 h cultivation. 29.9 mM of 1-propanol was formed from l-rhamnose with a molar yield of 0.81 mol/mol using E. coli carrying only pRSF_pduCDEGHOQS. In addition, 1-propanol production from glycerol was achieved by addition of the ATP-dependent dihydroxyacetone kinase gene to E. coli harboring pKK_mde and pRSF_pduCDEGOQS. In all cases, 1-propanol production was achieved by adding only a small amount of AdoCbl.

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

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

Metabolic Engineering of Klebsiella pneumoniae for the Production of 2-Butanone from Glucose.

2-Butanone is an important commodity chemical of wide application in different areas. In this study, Klebsiella pneumoniae was engineered to directly produce 2-butanone from glucose by extending its native 2, 3-butanediol synthesis pathway. To identify the potential enzyme for the efficient conversion of 2, 3-butanediol to 2-butanone, we screened different glycerol dehydratases and diol dehydratases. By introducing the diol dehydratase from Lactobacillus brevis and deleting the ldhA gene encoding lactate dehydrogenase, the engineered K. pneumoniae was able to accumulate 246 mg/L of 2-butanone in shake flask. With further optimization of culture condition, the titer of 2-butanone was increased to 450 mg/L. This study lays the basis for developing an efficient biological process for 2-butanone production.

Systematically engineering Escherichia coli for enhanced production of 1,2-propanediol and 1-propanol.

The biological production of high value commodity 1,2-propanediol has been established by engineering the glycolysis pathway. However, the simultaneous achievement of high titer and high yield has not been reported yet, as all efforts in increasing the titer have resulted in low yields. In this work, we overcome this limitation by employing an optimal minimal set of enzymes, channeling the carbon flux into the 1,2-propanediol pathway, increasing NADH availability, and improving the anaerobic growth of the engineered Escherichia coli strain by developing a cell adaptation method. These efforts lead to 1,2-propanediol production at a titer of 5.13 g/L with a yield of 0.48 g/g glucose in 20 mL shake flask studies. On this basis, we pursue the enhancement of 1-propanol production from the 1,2-propanediol platform. By constructing a fusion diol dehydratase and developing a dual strain process, we achieve a 1-propanol titer of 2.91 g/L in 20 mL shake flask studies. To summarize, we report the production of 1,2-propanediol at enhanced titer and enhanced yield simultaneously in E. coli for the first time. Furthermore, we establish an efficient system for the production of biofuel 1-propanol biologically.

2-Butanol and butanone production in Saccharomyces cerevisiae through combination of a B12 dependent dehydratase and a secondary alcohol dehydrogenase using a TEV-based expression system.

2-Butanol and its chemical precursor butanone (methyl ethyl ketone--MEK) are chemicals with potential uses as biofuels and biocommodity chemicals. In order to produce 2-butanol, we have demonstrated the utility of using a TEV-protease based expression system to achieve equimolar expression of the individual subunits of the two protein complexes involved in the B12-dependent dehydratase step (from the pdu-operon of Lactobacillus reuteri), which catalyze the conversion of meso-2,3-butanediol to butanone. We have furthermore identified a NADH dependent secondary alcohol dehydrogenase (Sadh from Gordonia sp.) able to catalyze the subsequent conversion of butanone to 2-butanol. A final concentration of 4±0.2 mg/L 2-butanol and 2±0.1 mg/L of butanone was found. A key factor for the production of 2-butanol was the availability of NADH, which was achieved by growing cells lacking the GPD1 and GPD2 isogenes under anaerobic conditions.

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

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 (α2ß2γ2) 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.

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

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.

The effect of cell immobilization on the antibacterial activity of Lactobacillus reuteri DPC16 cells during passage through a simulated gastrointestinal tract system.

Cell immobilization has the ability to influence the survival and functional characteristics of probiotic bacterial strains in harsh environments. This study investigated the effect of cell immobilization and passage through a simulated gastrointestinal tract (GI) on the antibacterial activity of Lactobacillus reuteri DPC16. Antibacterial activity, reuterin production and diol dehydratase activity were assayed in recovered isolates of L. reuteri that had been immobilized in Ca alginate-skim milk, and incubated in simulated GI fluids. Among all the recovered isolates tested, any that had undergone immobilization followed by immediate recovery of the cells without subsequent incubation in any fluids demonstrated the highest reuterin production, antimicrobial activity and diol dehydratase enzyme activity. L. reuteri DPC16 cells that had been immobilized, incubated in simulated GI fluids, and subsequently recovered from the beads often showed some loss of antimicrobial activity compared to the immobilized cells. The data confirm that the process of immobilization of L. reuteri in Ca alginate-skim milk, rather than the passage through simulated GI fluids, resulted in enhanced antibacterial activity. This is attributed to increased diol dehydratase activity, resulting in increased reuterin production.

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.

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).

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

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.

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

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.