Pyruvate aldolases in chiral carbon-carbon bond formation

A procedure for the preparation of optically pure alpha-keto-gamma-hydroxy carboxylic acids through stereospecific aldol addition catalyzed by pyruvate aldolases from the Entner-Doudoroff and the DeLey-Doudoroff glycolytic pathways is described. This highly versatile fragment serves as a precursor for a variety of commonly encountered functionalities, including beta-hydroxy aldehydes and carboxylic acids, alpha-amino-gamma-hydroxy carboxylic acids and alpha,gamma-dihydroxy carboxylic acids. The protocol described here uses recombinant His6-tagged KDPG aldolase for the synthesis of (S)-4-hydroxy-2-keto-4-(2'-pyridyl)butyrate. A protocol for evaluating enantiomeric excess through formation of the gamma-lactone of the dithioacetal followed by chiral-phase gas-liquid chromatography is also described. Enzyme expression and enzymatic synthesis can be accomplished in approximately 1 week. The enzymatic aldol addition proceeds in nearly quantitative yields with enantiomeric excesses greater than 99.7%.     

A novel strategy for enzymatic synthesis of 4-hydroxyisoleucine: identification of an enzyme possessing HMKP (4-hydroxy-3-methyl-2-keto-pentanoate) aldolase activity

A two-step enzymatic synthesis process of 4-hydroxyisoleucine is suggested. In the first step, the aldol condensation of acetaldehyde and alpha-ketobutyrate catalyzed by specific aldolase results in the formation of 4-hydroxy-3-methyl-2-keto-pentanoate (HMKP). In the second step, amination of HMKP by the branched-chain amino acid aminotransferase leads to synthesis of 4-hydroxyisoleucine. An enzyme possessing HMKP aldolase activity (asHPAL) was purified 2500-fold from a crude extract of Arthrobacter simplex strain AKU 626. Sequencing of the asHPAL structural gene showed that the purified enzyme belongs to the HpcH/HpaI aldolase family. The 4-hydroxyisoleucine was synthesized in vitro from acetaldehyde, alpha-ketobutyrate and l-glutamate using a coupled aldolase/branched-chain amino acid aminotransferase bienzymatic reaction.     

Accessibility of N-acyl-D-mannosamines to N-acetyl-D-neuraminic acid aldolase

N-Acetyl-D-neuraminic acid (NeuNAc) aldolase is an important enzyme for the metabolic engineering of cell-surface NeuNAc using chemically modified D-mannosamines. To explore the optimal substrates for this application, eight N-acyl derivatives of D-mannosamine were prepared, and their accessibility to NeuNAc aldolase was quantitatively investigated. The N-propionyl-, N-butanoyl-, N-iso-butanoyl-, N-pivaloyl-, and N-phenylacetyl-D-mannosamines proved to be as good substrates as, or even better than, the natural N-acetyl-D-mannosamine, while the N-trifluoropropionyl and benzoyl derivatives were poor. It was proposed that the electronic effects might have a significant influence on the enzymatic aldol condensation reaction of D-mannosamine derivatives, with electron-deficient acyl groups having a negative impact. The results suggest that N-propionyl-, N-butanoyl-, N-iso-butanoyl-, and N-phenylacetyl-D-mannosamines may be employed to bioengineer NeuNAc on cells.     

High-throughput screening methods for selecting -threonine aldolases with improved activity

More and more, aldolases are being recognized as useful catalysts that carry out the reversible addition of a ketone donor to an aldehyde acceptor in achieving high stereoselectivity. Threonine aldolases catalyze the synthesis of variable β-hydroxy-α-amino acids, which are important structural units of various antibiotics and immunosuppressants. However, the enzymatic properties need to be improved to support a broader application to synthetic chemistry. Although directed-evolution is a powerful tool for improving enzymatic properties, the successful outcome depends on the efficiency of screening systems. We designed and proposed two high-throughput screening schemes for selecting -threonine aldolase mutants with improved properties. These schemes utilized the toxicity of aldehyde, which acts as an acceptor in the aldol condensation. In these schemes, the following occurs: (1) the higher -threonine aldolase activity reduces the toxic effect of aldehyde, which leads to the survival of the corresponding clone (the positive-selection scheme), and (2) the higher -threonine aldolase activity produces more toxic aldehyde, which causes the death of the corresponding clone (the negative-selection scheme). According to the positive-selection scheme, we successfully selected -threonine aldolase mutants with higher activities than the wild-type, from a randomly generated LTA library.     

Identification and application of threonine aldolase for synthesis of valuable α-amino, β-hydroxy-building blocks

Chiral β-hydroxy α-amino acid structural motifs are interesting and common synthons present in multiple APIs and drug candidates. To access these chiral building blocks either multistep chemical syntheses are required or the application of threonine aldolases, which catalyze aldol reactions between an aldehyde and glycine. Bioinformatics tools have been utilized to identify the gene encoding threonine aldolase from Vanrija humicola and subsequent preparation of its recombinant version from E. coli fermentation. We planned to implement this enzyme as a key step to access the synthesis of our target API. Beyond this specific application, the aldolase was purified, characterized and the substrate scope of this enzyme further investigated. A number of enzymatic reactions were scaled-up and the products recovered to assess the diastereoselectivity and scalability of this asymmetric synthetic approach towards β-hydroxy α-amino acid chiral building blocks.     

Carboxyl terminus region modulates catalytic activity of recombinant maize aldolase

Site-directed mutagenesis was utilized to study the functional role of the COOH-terminal region in recombinant maize aldolase. A single mutation was created in each of the last nine amino acids of the COOH terminus and characterized kinetically. Point mutations in the COOH-terminal region were found to influence both the rate of fructose 1,6-bisphosphate and fructose 1-phosphate cleavage. Catalytic efficiency, kcat/Km, was not affected by the mutations within experimental error consistent with this region of the COOH terminus modulating product release. Concentrations of the carbanion-enamine enzyme intermediate complex produced upon substrate cleavage increased with the severity of the point mutation. A condensation assay was developed to directly measure fructose 1,6-bisphosphate synthesized by aldolases in the presence of high triose phosphate concentrations. The maximal rate of aldol condensation of triose phosphates, D-glyceralehyde-3-P and dihydroxyacetone-P, was affected by the point mutations to the same extent as the maximal rate of substrate cleavage. Interpretation of the data is consistent with point mutations in the COOH terminus predominantly affecting the proton exchange with the dihydroxyacetone-P enzymatic complex at the carbanion-enamine step and that this step is probably rate-limiting in the catalytic mechanism of recombinant maize aldolase. The role of the COOH-terminal region in aldolases is thus consistent with a sequence dependent modulation of catalytic activity.     

Purification and characterization of l-allo-threonine aldolase from Aeromonas jandaei DK-39

l-allo-Threonine aldolase (l-allo-threonine acetaldehyde-lyase), which exhibited specificity for l-allo-threonine but not for l-threonine, was purified from a cell-free extract of Aeromonas jandaei DK-39. The purified enzyme catalyzed the aldol cleavage reaction of l-allo-threonine (K_m=1.45 mM, V_max=45.2 μmol min⁻¹ mg⁻¹). The activity of the enzyme was inhibited by carbonyl reagents, which suggests that pyridoxal-5′-phosphate participates in the enzymatic reaction. The enzyme does not act on either l-serine or l-threonine, and thus it can be distinguished from serine hydroxy-methyltransferase (l-serine:tetrahydrofolate 5,10-hydroxy-methyltransferase, EC 2.1.2.1) or l-threonine aldolase (EC 4.1.2.5).     

Structure-based mutagenesis approaches toward expanding the substrate specificity of D-2-deoxyribose-5-phosphate aldolase

2-Deoxyribose-5-phosphate aldolase (DERA, EC 4.1.2.4) catalyzes the reversible aldol reaction between acetaldehyde and D-glyceraldehyde-3-phosphate to generate D-2-deoxyribose-5-phosphate. It is unique among the aldolases as it catalyzes the reversible asymmetric aldol addition reaction of two aldehydes. In order to expand the substrate scope and stereoselectivity of DERA, structure-based substrate design as well as site-specific mutation has been investigated. Using the 1.05 A crystal structure of DERA in complex with its natural substrate as a guide, five site-directed mutants were designed in order to improve its activity with the unnatural nonphosphorylated substrate, D-2-deoxyribose. Of these, the S238D variant exhibited a 2.5-fold improvement over the wild-type enzyme in the retroaldol reaction of 2-deoxyribose. Interestingly, this S238D mutant enzyme was shown to accept 3-azidopropinaldehyde as a substrate in a sequential asymmetric aldol reaction to form a deoxy-azidoethyl pyranose, which is a precursor to the corresponding lactone and the cholesterol-lowering agent Lipitor. This azidoaldehyde is not a substrate for the wild-type enzyme. Another structure-based design of new nonphosphorylated substrates was focused on the aldol reaction with inversion in enantioselectivity using the wild type or the S238D variant as the catalyst and 2-methyl-substituted aldehydes as substrates. An example was demonstrated in the asymmetric synthesis of a deoxypyranose as a new effective synthon for the total synthesis of epothilones. In addition, to facilitate the discovery of new enzymatic reactions, the engineered E. coli strain SELECT (Deltaace, adhC, DE3) was developed to be used in the future for selection of DERA variants with novel nonphosphorylated acceptor specificity.     

The origin of enantioselectivity in aldolase antibodies: crystal structure, site-directed mutagenesis, and computational analysis

Catalytic aldolase antibodies, generated by reactive immunization, catalyze the aldol reaction with the efficiency of natural enzymes, but accept a much broader range of substrates. Two separate groups of aldolase antibodies that catalyze the same aldol reactions with antipodal selectivity were analyzed by comparing their amino acid sequences with their crystal structures, site-directed mutagenesis data, and computational docking of the transition states of the aldol reaction. The crystal structure of aldolase antibody 93F3 Fab' at 2.5A resolution revealed a combining site with two lysine residues, including LysL89 that reacts to form the covalent enamine intermediate. In contrast, antibody 33F12 has one active site lysine, LysH93. The reactive lysine residues in each group of antibodies are differentially located on the heavy and light chain variable regions in pseudo-symmetric opposite orientations, but both within highly hydrophobic environments. Thus, the defining feature for the observed enantioselectivities of these aldolase antibody catalysts is the respective location and relative disposition of the reactive lysine residues within the active sites of these catalysts.     

Continuous spectrophotometric assay of a sepharose-bound enzyme and its use to study kinetics of coupling of the enzyme to sepharose

Continuous spectrophotometric assay of Sepharose-bound aldolase was performed using a commercial spectrophotometer with a built-in magnetic stirrer. Under most conditions likely to be encountered, the turbidity of the stirred Sepharose suspension did not interfere significantly with the optical measurements. The method is similar in convenience and sensitivity to the corresponding assay for soluble aldolase. It is also possible in one assay procedure to determine both soluble and bound enzyme in any particular sample. This assay technique should be applicable to the insoluble derivatives of many other enzymes.     

Purification of aldolase C from rat brain and hepatoma.

An isolation procedure for rat brain aldolase C has been developed which also permits the isolation of aldolase C from experimental hepatomas. Certain enzymatic properties (specific activity and Michaelis constant towards the two specific substrates: fructose 1,6-biphosphate and fructose 1-phosphate) and physico-chemical properties (molecular weight, N-terminal amino-acid) of the two enzymes have been studied and compared. Moreover, an amino-acid analysis has been carried out for rat brain aldolase C. Within experimental errors, the two enzymes appear to be identical.     

2-Keto-4-hydroxyglutarate aldolase: purification and characterization of the homogeneous enzyme from bovine kidney.

2-Keto-4-hydroxyglutarate aldolase, which catalyzes the reversible cleavage of 2-keto-4-hydroxyglutarate, yielding pyruvate plus glyoxylate, has been purified from extracts of bovine kidney to apparent homogeneity as judged by polyacrylamide gel electrophoresis, gel filtration chromatography, sucrose density gradient centrifugation, and meniscus depletion sedimentation equilibrium experiments. The enzyme from this source has a native and a subunit mass of 144 and 36 kDa, respectively; the pH-activity optimum is 8.8. Rather than being stimulated, aldolase activity is inhibited to varying degrees by added divalent metal ions, whereas a number of metal ion-chelating agents have no effect. An absolute requirement for added thiol compounds could not be shown, but 2-mercaptoethanol enhances activity 2-fold, and added Hg2+ as well as p-mercuribenzoate or dithiodipyridine markedly inhibit catalysis. Incubation of the enzyme with either pyruvate or glyoxylate in the presence of NaBH4 causes extensive loss of aldolase activity concomitant with stable binding of approximately 1.0-1.5 mol of 14C-labeled substrate/mol of enzyme. The circular dichroism spectrum for native aldolase is characteristic of an alpha-helix; incubation of the enzyme with glyoxylate has no effect on this spectrum, but it is considerably altered by pyruvate. Bovine kidney aldolase shows no stereospecificity in catalyzing the aldol cleavage of the two optical isomers of 2-keto-4-hydroxyglutarate, and although it also catalyzes the beta-decarboxylation of oxalacetate, its decarboxylase/aldolase activity ratio is lower than that seen with the pure enzyme from either bovine liver or Escherichia coli.     

Microbial production of 4-hydroxybenzylidene acetone, the direct precursor of raspberry ketone

AIMS: To investigate the enzymatic aldol reaction between acetone as a donor and 4-hydroxybenzaldehyde as a receptor to generate 4-(4-hydroxyphenyl)-but-3-ene-2-one or 4-hydroxybenzylidene acetone, the direct precursor of 4-(4-hydroxyphenyl)-butan-2-one or raspberry ketone, using different species of filamentous fungi and bacteria. METHODS AND RESULTS: Different classes of micro-organisms were tested in a medium containing mainly acetone and 4-hydoxybenzaldehyde. Of the micro-organisms tested, only bacteria were able to synthesize significant amounts of 4-hydroxybenzylidene acetone, ranging from 15 to 160 mg l(-1) after 21 h of bioconversion, as a function of the bacteria tested. CONCLUSIONS: The biological production of 4-hydroxybenzylidene acetone has been described with bacteria possessing 2-deoxyribose-5-phosphate aldolase (DERA, EC 4.1.2.4). This result suggests that DERA is involved in the catalytic aldolization of precursors for the production of 4-hydroxybenzylidene acetone. SIGNIFICANCE AND IMPACT OF THE STUDY: Raspberry ketone or frambinone represents a total market value of between euro6 million and euro10 million. The possibility of producing its direct precursor through a simple process using bacteria is of considerable interest to the flavour market and the food industry as a whole. This paper broadens the spectrum for the use of aldolase to achieve the biological synthesis of compounds of interest.     

Analysis of the class I aldolase binding site architecture based on the crystal structure of 2-deoxyribose-5-phosphate aldolase at 0.99A resolution

The crystal structure of the bacterial (Escherichia coli) class I 2-deoxyribose-5-phosphate aldolase (DERA) has been determined by Se-Met multiple anomalous dispersion (MAD) methods at 0.99A resolution. This structure represents the highest-resolution X-ray structure of an aldolase determined to date and enables a true atomic view of the enzyme. The crystal structure shows the ubiquitous TIM alpha/beta barrel fold. The enzyme contains two lysine residues in the active site. Lys167 forms the Schiff base intermediate, whereas Lys201, which is in close vicinity to the reactive lysine residue, is responsible for the perturbed pK(a) of Lys167 and, hence, also a key residue in the reaction mechanism. DERA is the only known aldolase that is able to use aldehydes as both aldol donor and acceptor molecules in the aldol reaction and is, therefore, of particular interest as a biocatalyst in synthetic organic chemistry. The uncomplexed DERA structure enables a detailed comparison with the substrate complexes and highlights a conformational change in the phosphate-binding site. Knowledge of the enzyme active-site environment has been the basis for exploration of catalysis of non-natural substrates and of mutagenesis of the phosphate-binding site to expand substrate specificity. Detailed comparison with other class I aldolase enzymes and DERA enzymes from different organisms reveals a similar geometric arrangement of key residues and implies a potential role for water as a general base in the catalytic mechanism.     

Galactose metabolism in Rhizobium meliloti L5-30.

Data from previous studies of Rhizobium meliloti mutants have been consistent with the catabolism of hexoses via the Entner-Doudoroff pathway. However, galactose metabolism was not impaired in those mutants. We show here by enzymatic assay and by identification of a galactose mutant lacking 2-keto-3-deoxy-6-phosphogalactonate aldolase that the De Ley-Doudoroff pathway is used for galactose metabolism. Mutants in this pathway have not been previously reported for any organism.     

Enzymatic synthesis of D-sorbose and D-psicose with aldolase RhaD: effect of acceptor configuration on enzyme stereoselectivity

It was previously reported that DHAP-dependent aldolase RhaD selectively chooses L-glyceraldehyde from racemic glyceraldehyde to produce l-fructose exclusively. Contrastingly, we discovered that D-glyceraldehyde is also tolerated as an acceptor and the stereoselectivity of the enzyme is lost in the corresponding aldol addition. Furthermore, we applied this property to efficiently synthesize two rare sugars D-sorbose and D-psicose.     

A sialic acid aldolase from Peptoclostridium difficile NAP08 with 4-hydroxy-2-oxo-pentanoate aldolase activity

Sialic acid aldolases (E.C.4.1.3.3) catalyze the reversible aldol cleavage of N-acetyl-d-neuraminic acid (Neu5Ac) to from N-acetyl-d-mannosamine (ManNAc) and pyruvate. In this study, a sialic acid aldolase (PdNAL) from Peptoclostridium difficile NAP08 was expressed in Escherichia coli BL21 (DE3). This homotetrameric enzyme was purified with a specific activity of 18.34 U/mg for the cleavage of Neu5Ac. The optimal pH and temperature for aldol addition reaction were 7.4 and 65 °C, respectively. PdNAL was quite stable at neutral and alkaline pH (6.0–10.0) and maintained about 89% of the activity after incubation at pH 10.0 for 24 h. After incubation at 70 °C for 15 min, almost no activity loss was observed. The high thermostability simplified the purification of this enzyme. Interestingly, substrate profiling showed that PdNAL not only accepted ManNAc but also short chain aliphatic aldehydes such as acetaldehyde, propionaldehyde and n-butyraldehyde as the substrates. This is the first example that a sialic acid aldolase is active toward aliphatic aldehyde acceptors with two or more carbons. The amino acid sequence analysis indicates that PdNAL belongs to the NAL subfamily rather than 4-hydroxy-2-oxopentanoate (HOPA) aldolase, but it is interesting that the enzyme possesses the activity of HOPA aldolase.     

D-Xylulose-1-phosphate: enzymatic assay and production in isolated rat hepatocytes

A specific enzymatic assay for D-xylulose-1-phosphate (D-threopentulose-1-phosphate) was developed, based on the measurement of glycolaldehyde, which is formed by aldolase cleavage of the D-xylulose-1-phosphate. This assay was used to confirm the identity of the product of fructokinase phosphorylation of D-xylulose and the production of glycolaldehyde and D-xylulose-1-phosphate in D-xylulose-treated isolated rat hepatocytes. An alternative pathway of xylitol metabolism in the liver, through D-xylulose-1-phosphate to glycolaldehyde, is proposed. Because glycolaldehyde is a known oxalate precursor, this pathway may explain the synthesis of oxalate from xylitol.     

Mechanism of dihydroneopterin aldolase. NMR, equilibrium and transient kinetic studies of the Staphylococcus aureus and Escherichia coli enzymes

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.