An Activity, Stability and Selectivity Comparison of Propioin Synthesis by Thiamine Diphosphate-Dependent Enzymes in a Solid/Gas Bioreactor

Enzymatic carboligation in a solid/gas bioreactor represents a new challenge in biotechnology. In this paper, the continuous gas-phase production of propioin from two propanal molecules by using thiamine diphosphate-dependent enzymes was studied. Two enzymes were used, namely benzaldehyde lyase (BAL) from Pseudomonas fluorescens and benzoylformate decarboxylase (BFD) from Pseudomonas putida. The enzymes are homologous and catalyze carboligase and carbolyase reactions in which no external cofactor regeneration is needed. The influence of water and substrate activity on the initial reaction rate and biocatalyst stability was investigated. An increase in water activity raised the initial reaction rates to the maximal values of 250 and 80 U g(-1) for BAL and BFD, respectively. The half-life showed the same trend with maximal values of 50 and 78 min for BAL and BFD, respectively. The increase in the half-life by increasing water activity was unexpected. It was also observed that BFD is more stable than BAL in the presence of the substrate propanal. Both enzymes showed substrate inhibition in the kinetic studies, and BAL was also deactivated during the reaction. Unexpectedly, the stereoselectivity of both enzymes (ee of 19 % for BAL and racemic mixture for BFD) was significantly impaired in the gas phase compared to the liquid phase.

Dihydroxyacetone variants in the organocatalytic construction of carbohydrates: mimicking tagatose and fuculose aldolases

Dihydroxyacetone variants have been explored as donors in organocatalytic aldol reactions with various aldehyde and ketone acceptors. The protected form of dihydroxyacetone that was chosen for in-depth study was 2,2-dimethyl-1,3-dioxan-5-one, 1. Among the catalysts surveyed here, proline proved to be superior in terms of yield and stereoselectivities in the construction of various carbohydrate scaffolds. In a fashion analogous to aldolase enzymes, the de novo preparation of L-ribulose, L-lyxose, D-ribose, D-tagatose, 1-amino-1-deoxy-D-lyxitol, and other carbohydrates was accomplished via the use of 1 and proline. In reactions using 2,2-dimethyl-1,3-dioxan-5-one 1 as a donor, (S)-proline can be used as a functional mimic of tagatose aldolase, whereas (R)-proline can be regarded as an organocatalytic mimic of fuculose aldolase.

In vivo selection for the directed evolution of L-rhamnulose aldolase from L-rhamnulose-1-phosphate aldolase (RhaD)

Dihydroxyacetone phosphate (DHAP)-dependent aldolases have been widely used for organic synthesis. The major drawback of DHAP-dependent aldolases is their strict donor substrate specificity toward DHAP, which is expensive and unstable. Here we report the development of an in vivo selection system for the directed evolution of the DHAP-dependent aldolase, L-rhamnulose-1-phosphate aldolase (RhaD), to alter its donor substrate specificity from DHAP to dihydroxyacetone (DHA). We also report preliminary results on mutants that were discovered with this screen. A strain deficient in the L-rhamnose metabolic pathway in Escherichia coli (DeltarhaDAB, DE3) was constructed and used as a selection host strain. Co-expression of L-rhamnose isomerase (rhaA) and rhaD in the selection host did not restore its growth on minimal plate supplemented with L-rhamnose as a sole carbon source, because of the lack of L-rhamnulose kinase (RhaB) activity and the inability of WT RhaD aldolase to use unphosphorylated L-rhamnulose as a substrate. Use of this selection host and co-expression vector system gives us an in vivo selection for the desired mutant RhaD which can cleave unphosphorylated L-rhamnulose and allow the mutant to grow in the minimal media. An error-prone PCR (ep-PCR) library of rhaD gene on the co-expression vector was constructed and introduced into the rha-mutant, and survivors were selected in minimal media with l-rhamnose (MMRha media). An initial round of screening gave mutants allowing the selection strain to grow on MMRha plates. This in vivo selection system allows rapid screening of mutated aldolases that can utilize dihydroxyacetone as a donor substrate.

Biochemical and structural exploration of the catalytic capacity of Sulfolobus KDG aldolases

Aldolases are enzymes with potential applications in biosynthesis, depending on their activity, specificity and stability. In the present study, the genomes of Sulfolobus species were screened for aldolases. Two new KDGA [2-keto-3-deoxygluconate (2-oxo-3-deoxygluconate) aldolases] from Sulfolobus acidocaldarius and Sulfolobus tokodaii were identified, overexpressed in Escherichia coli and characterized. Both enzymes were found to have biochemical properties similar to the previously characterized S. solfataricus KDGA, including the condensation of pyruvate and either D,L-glyceraldehyde or D,L-glyceraldehyde 3-phosphate. The crystal structure of S. acidocaldarius KDGA revealed the presence of a novel phosphate-binding motif that allows the formation of multiple hydrogen-bonding interactions with the acceptor substrate, and enables high activity with glyceraldehyde 3-phosphate. Activity analyses with unnatural substrates revealed that these three KDGAs readily accept aldehydes with two to four carbon atoms, and that even aldoses with five carbon atoms are accepted to some extent. Water-mediated interactions permit binding of substrates in multiple conformations in the spacious hydrophilic binding site, and correlate with the observed broad substrate specificity.

Cloning and characterization of a gene encoding phosphoketolase in a Lactobacillus paraplantarum isolated from Kimchi

A gene coding for phosphoketolase, a key enzyme of carbohydrate catabolism in heterofermentative lactic acid bacteria (LAB), was cloned from a Lactobacillus paraplantarum C7 and expressed in Escherichia coli. The gene is 2502 bp long and codes for a 788-amino-acids polypeptide with a molecular mass of 88.7 kDa. A Shine-Dalgamo sequence (aaggag) and an inverted-repeat terminator sequence are located upstream and downstream of the phosphoketolase gene, respectively. The gene exhibits an identity of >52% with phosphoketolases of other LAB. The phosphoketolase of Lb. paraplantarum C7 (LBPK) contains several highly conserved phosphoketolase signature regions and typical thiamine pyrophosphate (TPP) binding sites, as reported for other TPP-dependent enzymes. The phosphoketolase gene was fused to a glutathione S-transferase (GST::LBPK) gene for purification. The GST::LBPK fusion protein was detected in the soluble fraction of a recombinant Escherichia coli BL21. The GST::LBPK fusion protein was purified with a yield of 4.32 mg/400 ml by GSTrap HP affinity column chromatography and analyzed by N-terminal sequencing. LBPK was obtained by factor Xa treatment of fusion protein and the final yield was 3.78 mg/400 ml. LBPK was examined for its N-terminal sequence and phosphoketolase activity. The K(M) and Vmax values for fructose-6-phosphate were 5.08 +/- 0.057 mM (mean +/- SD) and 499.21 +/- 4.33 micromol/min/mg, respectively, and the optimum temperature and pH for the production of acetyl phosphate were 45 degrees C and 7.0, respectively.

Directed Evolution of 2-Keto-3-deoxy-6-phosphogalactonate Aldolase To Replace 3-Deoxy-d-arabino-heptulosonic Acid 7-Phosphate Synthase

Directed evolution of 2-keto-3-deoxy-6-phosphogalactonate (KDPGal) aldolase for microbial synthesis of shikimate pathway products provides an alternate strategy to circumvent the competition for phosphoenolpyruvate between 3-deoxy-D-arabino-heptulosonic acid 7-phosphate (DAHP) synthase and the phosphoenolpyruvate:carbohydrate phosphotransferase system in Escherichia coli. E. coli KDPGal aldolase was evolved using a combination of error-prone polymerase chain reaction, DNA shuffling, and multiple-site-directed mutagenesis to afford KDPGal aldolase variant NR8.276-2, which exhibits a 60-fold improvement in the ratio kcat/KM relative to that of wild-type E. coli KDPGal aldolase in catalyzing the addition of pyruvate to d-erythrose 4-phosphate to form DAHP. On the basis of its nucleotide sequence, NR8.276-2 contains seven amino acid changes from the wild-type E. coli KDPGal aldolase. Amplified expression of NR8.276-2 in the DAHP synthase and shikimate dehydrogenase-deficient E. coli strain NR7 under fed-batch fermentor-controlled cultivation conditions resulted in synthesis of 13 g/L 3-dehydroshikimic acid in 6.5% molar yield from glucose. Increased coexpression of the irreversible downstream enzyme 3-dehydroquinate synthase increased production of 3-dehydroshikimic acid to 19 g/L in 9.7% molar yield from glucose. Coamplification with transketolase, which increases d-erythrose 4-phosphate availability, afforded 16 g/L 3-dehydroshikimic acid in 8.5% molar yield.

Stereoselective Biocatalytic Synthesis of (S)-2-Hydroxy-2-Methylbutyric Acid via Substrate Engineering by Using “Thio-Disguised” Precursors and Oxynitrilase Catalysis

3-Tetrahydrothiophenone (4) and 4-phenylthiobutan-2-one (7) were used as masked 2-butanone equivalents to give the corresponding cyanohydrins 5 (79 % yield, 91 % ee) and 8 (95 % yield, 96 % ee) in an enzymatic cyanohydrin reaction applying the hydroxynitrile lyase (HNL) from Hevea brasiliensis. After hydrolysis and desulphurisation the desired intermediate (S)-2-hydroxy-2-methylbutyric acid (10) was obtained with 99 % ee. Interestingly, when applying (R)-selective HNL from Prunus amygdalus again the (S)-cyanohydrin 5 was formed (62 % ee). The absolute configuration of 5 was verified by crystal structure determination of the corresponding hydrolysis derived carboxylate. The fact that both enzymes yield the same enantiomer was analysed and interpreted by molecular modelling calculations.

Mechanism of dihydroneopterin aldolase

Dihydroneopterin aldolase (DHNA) catalyzes both the cleavage of 7,8-dihydro-D-neopterin (DHNP) to form 6-hydroxymethyl-7,8-dihydropterin (HP) and glycolaldehyde and the epimerization of DHNP to form 7,8-dihydro-L-monapterin (DHMP). Whether the epimerization reaction uses the same reaction intermediate as the aldol reaction or the deprotonation and reprotonation of C2' of DHNP has been investigated by NMR analysis of the reaction products in a D2O solvent. No deuteration of C2' was observed for the newly formed DHMP. This result strongly suggests that the epimerization reaction uses the same reaction intermediate as the aldol reaction. In contrast with an earlier observation, the DHNA-catalyzed reaction is reversible, which also supports a nonstereospecific retroaldol/aldol mechanism for the epimerization reaction. The binding and catalytic properties of DHNAs from both Staphylococcus aureus (SaDHNA) and Escherichia coli (EcDHNA) were determined by equilibrium binding and transient kinetic studies. A complete set of kinetic constants for both the aldol and epimerization reactions according to a unified kinetic mechanism was determined for both SaDHNA and EcDHNA. The results show that the two enzymes have significantly different binding and catalytic properties, in accordance with the significant sequence differences between them.

Structural and mechanistic changes along an engineered path from metallo to nonmetallo 3-deoxy-D-manno-octulosonate 8-phosphate synthases

There are two classes of KDO8P synthases characterized respectively by the presence or absence of a metal in the active site. The nonmetallo KDO8PS from Escherichia coli and the metallo KDO8PS from Aquifex aeolicus are the best characterized members of each class. All amino acid residues that make important contacts with the substrates are conserved in both enzymes with the exception of Pro-10, Cys-11, Ser-235, and Gln-237 of the A. aeolicus enzyme, which correspond respectively to Met-25, Asn-26, Pro-252, and Ala-254 in the E. coli enzyme. Interconversion between the two forms of KDO8P synthases can be achieved by substituting the metal-coordinating cysteine of metallo synthases with the corresponding asparagine of nonmetallo synthases, and vice versa. In this report we describe the structural changes elicited by the C11N mutation and by three combinations of mutations (P10M/C11N, C11N/S235P/Q237A, and P10M/C11N/S235P/Q237A) situated along possible evolutionary paths connecting the A. aeolicus and the E. coli enzyme. All four mutants are not capable of binding metal and lack the structural asymmetry among subunits with regard to substrate binding and conformation of the L7 loop, which is typical of A. aeolicus wild-type KDO8PS but is absent in the E. coli enzyme. Despite the lack of the active site metal, the mutant enzymes display levels of activity ranging from 46% to 24% of the wild type. With the sole exception of the quadruple mutant, metal loss does not affect the thermal stability of KDO8PS. The free energy of unfolding in water is also either unchanged or even increased in the mutant enzymes, suggesting that the primary role of the active site metal in A. aeolicus KDO8PS is not to increase the enzyme stability. In all four mutants A5P binding displaces a water molecule located on the si side of PEP. In particular, in the double and triple mutant, A5P binds with the aldehyde carbonyl in hydrogen bond distance of Asn-11, while in the wild type this functional group points away from Cys-11. This alternative conformation of A5P is likely to have functional significance as it resembles the conformation of the acyclic reaction intermediate, which is observed here for the first time in some of the active sites of the triple mutant. The direct visualization of this intermediate by X-ray crystallography confirms earlier mechanistic models of KDO8P synthesis. In particular, the configuration of the C2 chiral center of the intermediate supports a model of the reaction in nonmetallo KDO8PS, in which water attacks an oxocarbenium ion or PEP from the si side of C2. Several explanations are offered to reconcile this observation with the fact that no water molecule is observed at this position in the mutant enzymes in the presence of both PEP and A5P. Significant differences were observed between the wild-type and the mutant enzymes in the Km values for PEP and A5P and in the Kd values for inorganic phosphate and R5P. These differences may reflect an evolutionary adaptation of metallo and nonmetallo KDO8PS's to the cellular concentrations of these metabolites in their respective hosts.

Structural determinants of the enantioselectivity of the hydroxynitrile lyase from Hevea brasiliensis

The hydroxynitrile lyase from the tropical rubber tree Hevea brasiliensis (HbHNL) is utilized as a biocatalyst in stereospecific syntheses of alpha-hydroxynitriles from aldehydes and methyl-ketones. The catalyzed reaction represents one of the few industrially relevant examples of enzyme mediated C-C coupling reactions. In this work, we determined the X-ray crystal structures (at 1.54 and 1.76 Angstroms resolution) of HbHNL complexes with two chiral substrates -- mandelonitrile and 2,3-dimethyl-2-hydroxy-butyronitrile -- by soaking and rapid freeze quenching techniques. This is the first structural observation of the complex between a HNL and chiral substrates. Consistent with the known selectivity of the enzyme, only the S-enantiomers of the two substrates were observed in the active site. The binding modes of the chiral substrates were identical to that observed for the biological substrate acetone cyanohydrin. This indicates that the transformation of these non-natural substrates follows the same mechanism. A large hydrophobic pocket was identified in the active site of HbHNL which accommodates the more voluminous substituents of the two substrates. A three-point binding mode of the substrates -- hydrophobic pocket, hydrogen bonds between the hydroxyl group and Ser80 and Thr11, electrostatic interaction of the cyano group with Lys236 -- offers a likely structural explanation for the enantioselectivity of the enzyme. The structural data rationalize the observed (S)-enantioselectivity and form the basis for modifying the stereospecificity through rational design. The structures also revealed the necessity of considerable flexibility of the sidechain of Trp128 in order to bind and transform larger substrates.

Biosynthesis of Polyunsaturated Short Chain Aldehydes in the DiatomThalassiosira rotula

The diatom Thalassiosira rotula releases polyunsaturated short chain aldehydes (PUA) such as 2E,4Z,7-octatrienal (7a) and 2E,4Z,7Z-decatrienal (3a) upon wounding. Using labeling experiments and synthetic standards, we demonstrate that the mechanism of fatty acid transformation does not follow established lipoxygenase/hydroperoxide lyase pathways known from higher plants or mammals but rather relies on a unique transformation of polyunsaturated hydroperoxy fatty acids. These intermediates are transformed to PUA and short chain hydroxylated fatty acids, which are novel oxylipins. [reaction: see text]

Serine scanning—A tool to prove the consequences of N-glycosylation of proteins

N-Glycosylation of proteins is a common posttranslational modification in eukaryotes. Often this results in enhanced protein stability through protection by the attached sugar moieties. Due to its 13 potential N-glycosylation motifs (N-X-T/S), recombinant hydroxynitrile lyase isoenzyme 5 from almonds (PaHNL5) is secreted by the heterologous host Pichia pastoris in a massively glycosylated form, and it shows extraordinary stability at low pH. The importance of N-glycosylation in general, and individual glycosylation sites in particular for stability at low pH were investigated. To identify especially important glycosylation sites asparagine from all N-X-S/T-motifs was replaced by serine. Thus, critical sites, which contributed to overall enzyme activity and/or stability, were identified individually. One glycosylation site revealed to be essential for stability at low pH. After enzymatic deglycosylation, leaving only one acetylglucosamine attached to asparagines, PaHNL5 retained most of its stability at low pH. Protonation effects in the active site as well as higher-order aggregational events upon incubation in low pH were excluded. This study provides evidence for the interconnection of N-glycosylation and stability at low pH for PaHNL5. Moreover, serine scanning was proven to be applicable for quick identification of critical glycosylation sites.

A novel screening assay for hydroxynitrile lyases suitable for high-throughput screening

Hydroxynitrile lyases (Hnls) are important biocatalysts for the synthesis of optically pure cyanohydrins, which are used as precursors and building blocks for a wide range of high price fine chemicals. Although two Hnl enzymes, from the tropical rubber tree Hevea brasiliensis and from the almond tree Prunus amygdalus, are already used for large scale industrial applications, the enzymes still need to be improved and adapted to the special demands of industrial processes. In many cases directed evolution has been the method of choice to improve enzymes, which are applied as industrial biocatalysts. The screening procedure is the most crucial point in every directed evolution experiment. Herein, we describe the successful development of a novel screening assay for Hnls and its application in high-throughput screening of Escherichia coli mutant libraries. The new assay allows rapid screening of mutant libraries and facilitates the discovery of improved enzyme variants. Hnls catalyze the cleavage of cyanohydrins to hydrocyanic acid and the corresponding aldehyde or ketone. The enzyme assay is based on the detection of hydrocyanic acid produced, making it an all-purpose screening assay, without restriction to any kind of substrate. The gaseous HCN liberated within the Hnl reaction is detected by a visible colorimetric reaction. The facile, highly sensitive and reproducible screening method was validated by identifying new enzyme variants with novel substrate specificities.

Structural basis for the aldolase and epimerase activities of Staphylococcus aureus dihydroneopterin aldolase

Dihydroneopterin aldolase (DHNA) catalyzes the conversion of 7,8-dihydroneopterin (DHNP) to 6-hydroxymethyl-7,8-dihydropterin (HP) and the epimerization of DHNP to 7,8-dihydromonopterin (DHMP). Although crystal structures of the enzyme from several microorganisms have been reported, no structural information is available about the critical interactions between DHNA and the trihydroxypropyl moiety of the substrate, which undergoes bond cleavage and formation. Here, we present the structures of Staphylococcus aureus DHNA (SaDHNA) in complex with neopterin (NP, an analog of DHNP) and with monapterin (MP, an analog of DHMP), filling the gap in the structural analysis of the enzyme. In combination with previously reported SaDHNA structures in its ligand-free form (PDB entry 1DHN) and in complex with HP (PDB entry 2DHN), four snapshots for the catalytic center assembly along the reaction pathway can be derived, advancing our knowledge about the molecular mechanism of SaDHNA-catalyzed reactions. An additional step appears to be necessary for the epimerization of DHMP to DHNP. Three active site residues (E22, K100, and Y54) function coordinately during catalysis: together, they organize the catalytic center assembly, and individually, each plays a central role at different stages of the catalytic cycle.

Mechanism of dihydroneopterin aldolase: functional roles of the conserved active site glutamate and lysine residues

Dihydroneopterin aldolase (DHNA) catalyzes the conversion of 7,8-dihydroneopterin (DHNP) to 6-hydroxymethyl-7,8-dihydropterin (HP) in the folate biosynthetic pathway. There are four conserved active site residues at the active site, E22, Y54, E74, and K100 in Staphylococcus aureus DHNA (SaDHNA), corresponding to E21, Y53, E73, and K98, respectively, in Escherichia coli DHNA (EcDHNA). The functional roles of the conserved glutamate and lysine residues have been investigated by site-directed mutagenesis in this work. E22 and E74 of SaDHNA and E21, E73, and K98 of EcDHNA were replaced with alanine. K100 of SaDHNA was replaced with alanine and glutamine. The mutant proteins were characterized by equilibrium binding, stopped-flow binding, and steady-state kinetic analyses. For SaDHNA, none of the mutations except E74A caused dramatic changes in the affinities of the enzyme for the substrate or product analogues or the rate constants. The Kd values for SaE74A were estimated to be >3000 microM, suggesting that the Kd values of the mutant are at least 100 times those of the wild-type enzyme. For EcDHNA, the E73A mutation increased the Kd values for the substrate or product analogues neopterin (MP), monapterin (NP), and 6-hydroxypterin (HPO) by factors of 340, 160, and 5600, respectively, relative to those of the wild-type enzyme. The K98A mutation increased the Kd values for NP, MP, and HPO by factors of 14, 3.6, and 230, respectively. The E21A mutation increased the Kd values for NP and HPO by factors of 2.2 and 42, respectively, but decreased the Kd value for MP by a factor of 3.3. The E22 (E21) and K100 (K98) mutations decreased the kcat values by factors of 1.3-2 x 10(4). The E74 (E73) mutation decreased in the kcat values by factors of approximately 10. The results suggested that E74 of SaDHNA and E73 of EcDHNA are important for substrate binding, but their roles in catalysis are minor. In contrast, E22 and K100 of SaDHNA are important for catalysis, but their roles in substrate binding are minor. On the other hand, E21 and K98 of EcDHNA are important for both substrate binding and catalysis.

Characterization of benzaldehyde lyase from Pseudomonas fluorescens: A versatile enzyme for asymmetric C–C bond formation

The thiamin-diphosphate-dependent enzyme benzaldehyde lyase is a very import catalyst for chemoenzymatic synthesis catalyzing the formation and cleavage of (R)-hydroxy ketones. We have studied the stability of the recombinant enzyme and some enzyme variants with respect to pH, temperature, buffer salt, cofactors and organic cosolvents. Stability of BAL in chemoenzymatic synthesis requires the addition of cofactors to the buffer. Reaction temperature should not exceed 37 degrees C. The enzyme is stable between pH 6 and 8, with pH 8 being the pH-optimum of both the lyase and the ligase reaction. Potassium phosphate and Tris were identified as optimal reaction buffers and the addition of 20 vol% DMSO is useful to enhance both the solubility of aromatic substrates and products and the stability of BAL. The initial broad product range of BAL-catalyzed reactions has been enlarged to include highly substituted hydroxybutyrophenones and aliphatic acyloins.

Purification, crystallization and preliminary crystallographic studies on 2-dehydro-3-deoxygalactarate aldolase from Leptospira interrogans

2-Dehydro-3-deoxygalactarate (DDG) aldolase is a member of the class II aldolase family and plays an important role in the pyruvate-metabolism pathway, catalyzing the reversible aldol cleavage of DDG to pyruvate and tartronic semialdehyde. As it is a potential novel antibiotic target, it is necessary to elucidate the catalytic mechanism of DDG aldolase. To determine the crystal structure, crystals of DDG aldolase from Leptospira interrogans were obtained by the hanging-drop vapour-diffusion method. The crystals diffracted to 2.2 A resolution using a Cu K alpha rotating-anode X-ray source. The crystal belonged to space group C2, with unit-cell parameters a = 293.5, b = 125.6, c = 87.6 A, beta = 100.9 degrees. The V(M) is calculated to be 2.4 A3 Da(-1), assuming there to be 12 protein molecules in the asymmetric unit.

Factors Mediating Activity, Selectivity, and Substrate Specificity for the Thiamin Diphosphate-Dependent Enzymes Benzaldehyde Lyase and Benzoylformate Decarboxylase

Benzaldehyde lyase from Pseudomonas fluorescens and benzoylformate decarboxylase from Pseudomonas putida are homologous thiamin diphosphate-dependent enzymes that catalyze carboligase and carbolyase reactions. Both enzymes catalyze the formation of chiral 2-hydroxy ketones from aldehydes. However, the reverse reaction has only been observed with benzaldehyde lyase. Whereas benzaldehyde lyase is strictly R specific, the stereoselectivity of benzoylformate decarboxylase from P. putida is dependent on the structure and orientation of the substrate aldehydes. In this study, the binding sites of both enzymes were investigated by using molecular modelling studies to explain the experimentally observed differences in the activity, stereo- and enantioselectivity and substrate specificity of both enzymes. We designed a detailed illustration that describes the shape of the binding site of both enzymes and sufficiently explains the experimental effects observed with the wild-type enzymes and different variants. These findings demonstrate that steric reasons are predominantly responsible for the differences observed in the (R)-benzoin cleavage and in the formation of chiral 2-hydroxy ketones.

A Point Mutation Converts Dihydroneopterin Aldolase to a Cofactor-Independent Oxygenase

Dihydroneopterin aldolase (DHNA) catalyzes the conversion of 7,8-dihydroneopterin (1) to 6-hydroxymethyl-7,8-dihydropterin (4) in the folate biosynthetic pathway. Substitution of a conserved tyrosine residue at the active site of DHNA by phenylalanine converts the enzyme to a cofactor-independent oxygenase, which generates mainly 7,8-dihydroxanthopterin (6) rather than 4. 6 is generated via the same enol intermediate as in the wild-type enzyme-catalyzed reaction, but this species undergoes an oxygenation reaction to form 6. The conserved tyrosine residue plays only a minor role in the formation of the enol reaction intermediate but a critical role in the protonation of the enol intermediate to form 4.

Enzymatic synthesis of (R)-cyanohydrins by a novel (R)-oxynitrilase from Vicia sativa L

The defatted seed meal of common vetch (Vicia sativa L.) served as a source of (R)-oxynitrilase which catalyzed the enantioselective addition of HCN to aromatic, heteroaromatic, fluoro-substituted aromatic aldehydes to produce the corresponding enantiomeric pure cyanohydrins in yields of 52-100% and 88-99% ee at 12 degrees C under micro-aqueous medium (diisopropyl ether) without addition of buffer solution.

New superfamily members identified for Schiff-base enzymes based on verification of catalytically essential residues

Enzymes that utilize a Schiff-base intermediate formed with their substrates and that share the same alpha/beta barrel fold comprise a mechanistically diverse superfamily defined in the SCOPS database as the class I aldolase family. The family includes the "classical" aldolases fructose-1,6-(bis)phosphate (FBP) aldolase, transaldolase, and 2-keto-3-deoxy-6-phosphogluconate aldolase. Moreover, the N-acetylneuraminate lyase family has been included in the class I aldolase family on the basis of similar Schiff-base chemistry and fold. Herein, we generate primary sequence identities based on structural alignment that support the homology and reveal additional mechanistic similarities beyond the common use of a lysine for Schiff-base formation. The structural and mechanistic correspondence comprises the use of a catalytic dyad, wherein a general acid/base residue (Glu, Tyr, or His) involved in Schiff-base chemistry is stationed on beta-strand 5 of the alpha/beta barrel. The role of the acid/base residue was probed by site-directed mutagenesis and steady-state and pre-steady-state kinetics on a representative member of this family, FBP aldolase. The kinetic results are consistent with the participation of this conserved residue or position in the protonation of the carbinolamine intermediate and dehydration of the Schiff base in FBP aldolase and, by analogy, the class I aldolase family.

Mechanism of dihydroneopterin aldolase: a molecular dynamics study of the apo enzyme and its product complex

Dihydroneopterin aldolase (DHNA), an enzyme in the pathway that generates folic acid in bacteria, is investigated by a series of molecular dynamics simulations in its free form and complexed with its product, 6-hydroxymethyl-7,8-dihydropterin (HP). The active sites in DHNA are formed at the interface between pairs of protomers in this octameric protein. On the basis of root-mean-square deviation and root-mean-square fluctuation analyses of the trajectories, which take advantage of the presence of eight active sites, flexible regions of the apo protein surrounding the active site are identified and, upon binding HP, show that the active site is rigidified. Specific residues, associated with binding and the catalytic mechanism of DHNA, are associated with these flexible regions, and their interactions with HP account for most of the binding energy. A Principal Component Analysis shows rigidification of DHNA upon HP binding and that only a few modes of motion capture most of the atomic fluctuations in both apo and HP-bound forms. HP is pushed out of the active site in a series of simulations with different restrained positions between HP and DHNA to obtain a view of the exit pathway and energetic barrier to product release. The chosen pathway leads to a minimal disturbance of the system and provides a barrier consistent with the experimentally determined rate of product release. An analysis of the various components that contribute to the exit path energy and entropy provides insight into the energy-entropy compensation for product release.