DHAP-dependent aldolases from (hyper)thermophiles: biochemistry and applications.

Generating new carbon-carbon (C-C) bonds in an enantioselective way is one of the big challenges in organic synthesis. Aldolases are a natural tool for stereoselective C-C bond formation in a green and sustainable way. This review will focus on thermophilic aldolases in general and on dihydroxyacetone phosphate-dependent aldolases in particular. Biochemical properties and applications for synthesis of rare sugars and carbohydrates will be discussed.

Cloning and expression of hydroxynitrile lyase gene from Eriobotrya japonica in Pichia pastoris.

Hydroxynitrile lyase gene (hnl) from Eriobotrya japonica was successfully amplified using the method of SEFA PCR (Self-Formed Adaptor PCR). The complete sequence was 5.5 kbp in length, including 3100 bp of the upstream promoter region, 1659 bp of the coding sequence, three introns and 315 bp of the downstream transcription terminator. The phylogenetic analysis illustrated that the obtained hnl exhibited 66-70% identity to the reported isozymes from almond, black cherry and Japanese apricot. The EjHNL had 552 amino acids including a 25 amino acid-long signal peptide. The conserved characteristic structures of HNLs, such as FAD-binding motif, N-glycosylation sites and active sites were observed. The coding sequence of the hnl was inserted into pPIC9K vector for heterologous expression in Pichia pastoris. The HNL activity of the culture supernatant reached 15 U/ml after 96 h of induction by methanol. The specific activity of the recombinant HNL was about 197 U/mg. The enantiomeric excess value of the product R-mandelonitrile attained 98.6% and the value of K(m) of the recombinant HNL was determined to be 0.47 mM based on the kinetic data. The optimum temperature and pH of the recombinant HNL were 40°C and 6.0 respectively. The experimental data indicated that the obtained recombinant HNL showed similar catalytic characteristics with the natural EjHNL. The expression of the recombinant HNL in P. pastoris could present another available biocatalyst for the synthesis of R-selective cyanohydrins.

CYP74C3 and CYP74A1, plant cytochrome P450 enzymes whose activity is regulated by detergent micelle association, and proposed new rules for the classification of CYP74 enzymes.

CYP74C3 (cytochrome P450 subfamily 74C3), an HPL (hydroperoxide lyase) from Medicago truncatula (barrel medic), and CYP74A1, an AOS (allene oxide synthase) from Arabidopsis thaliana, are key membrane-associated P450 enzymes in plant oxylipin metabolism. Both recombinant detergent-free enzymes are monomeric proteins with dual specificity and very low enzyme activity that can be massively activated with detergent. This effect is a result of the formation of a complex between the protein monomer and a single detergent micelle and, in the case of CYP74A1, has a major effect on the substrate specificity of the enzyme. Association with a detergent micelle without an effect on protein oligomeric state represents a new mechanism of activation for membrane-associated P450 enzymes. This may represent a second unifying feature of CYP74 enzymes, in addition to their known differences in reaction mechanism, which separates them functionally from more classical P450 enzymes. Highly concentrated and monodispersed samples of detergent-free CYP74C3 and CYP74A1 proteins should be suitable for structural resolution. On the basis of recent evidence for incorrect assignment of CYP74 function, using the current rules for CYP74 classification based on sequence relatedness, we propose an alternative based on substrate and product specificity for debate and discussion.

A class II aldolase mimic.

[structures: see text] A class II aldolase-mimicking synthetic polymer was prepared by the molecular imprinting of a complex of cobalt (II) ion and either (1S,3S,4S)-3-benzoyl-1,7,7-trimethylbicyclo[2.2.1]heptan-2-one (4a) or (1R,3R,4R)-3-benzoyl-1,7,7-trimethylbicyclo[2.2.1]heptan-2-one (4b) in a 4-vinylpyridine-styrene-divinylbenzene copolymer. Evidence for the formation of interactions between the functional monomer and the template was obtained from NMR and VIS titration studies. The polymers imprinted with the template demonstrated enantioselective recognition of the corresponding template structure, and induced a 55-fold enhancement of the rate of reaction of camphor (1) with benzaldehyde (2), relative to the solution reactions, and were also compared to reactions with a series of reference polymers. Substrate chirality was observed to influence reaction rate, and the reaction could be competitively inhibited by dibenzoylmethane (6). Collectively, the results presented provide the first example of the use of enantioselective molecularly imprinted polymers for the catalysis of carbon-carbon bond formation.

Microbial aldolases as C-C bonding enzymes--unknown treasures and new developments.

Aldolases are a specific group of lyases that catalyze the reversible stereoselective addition of a donor compound (nucleophile) onto an acceptor compound (electrophile). Whereas most aldolases are specific for their donor compound in the aldolization reaction, they often tolerate a wide range of aldehydes as acceptor compounds. C-C bonding by aldolases creates stereocenters in the resulting aldol products. This makes aldolases interesting tools for asymmetric syntheses of rare sugars or sugar-derived compounds as iminocyclitols, statins, epothilones, and sialic acids. Besides the well-known fructose 1,6-bisphosphate aldolase, other aldolases of microbial origin have attracted the interest of synthetic bio-organic chemists in recent years. These are either other dihydroxyacetone phosphate aldolases or aldolases depending on pyruvate/phosphoenolpyruvate, glycine, or acetaldehyde as donor substrate. Recently, an aldolase that accepts dihydroxyacetone or hydroxyacetone as a donor was described. A further enlargement of the arsenal of available chemoenzymatic tools can be achieved through screening for novel aldolase activities and directed evolution of existing aldolases to alter their substrate- or stereospecifities. We give an update of work on aldolases, with an emphasis on microbial aldolases.

Biosynthesis of C9-aldehydes in the moss Physcomitrella patens.

After wounding, the moss Physcomitrella patens emits fatty acid derived volatiles like octenal, octenols and (2E)-nonenal. Flowering plants produce nonenal from C18-fatty acids via lipoxygenase and hydroperoxide lyase reactions, but the moss exploits the C20 precursor arachidonic acid for the formation of these oxylipins. We describe the isolation of the first cDNA (PpHPL) encoding a hydroperoxide lyase from a lower eukaryotic organism. The physiological pathway allocation and characterization of a downstream enal-isomerase gives a new picture for the formation of fatty acid derived volatiles from lower plants. Expression of a fusion protein with a yellow fluorescent protein in moss protoplasts showed that PpHPL was found in clusters in membranes of plastids. PpHPL can be classified as an unspecific hydroperoxide lyase having a substrate preference for 9-hydroperoxides of C18-fatty acids but also the predominant substrate 12-hydroperoxy arachidonic acid is accepted. Feeding experiments using arachidonic acid show an increase in the 12-hydroperoxide being metabolized to C8-aldehydes/alcohols and (3Z)-nonenal, which is rapidly isomerized to (2E)-nonenal. PpHPL knock out lines failed to emit (2E)-nonenal while formation of C8-volatiles was not affected indicating that in contrast to flowering plants, PpHPL is only involved in formation of a specific subset of volatiles.

Mechanism of the Class I KDPG aldolase.

In vivo, 2-keto-3-deoxy-6-phosphogluconate (KDPG) aldolase catalyzes the reversible, stereospecific retro-aldol cleavage of KDPG to pyruvate and D-glyceraldehyde-3-phosphate. The enzyme is a lysine-dependent (Class I) aldolase that functions through the intermediacy of a Schiff base. Here, we propose a mechanism for this enzyme based on crystallographic studies of wild-type and mutant aldolases. The three dimensional structure of KDPG aldolase from the thermophile Thermotoga maritima was determined to 1.9A. The structure is the standard alpha/beta barrel observed for all Class I aldolases. At the active site Lys we observe clear density for a pyruvate Schiff base. Density for a sulfate ion bound in a conserved cluster of residues close to the Schiff base is also observed. We have also determined the structure of a mutant of Escherichia coli KDPG aldolase in which the proposed general acid/base catalyst has been removed (E45N). One subunit of the trimer contains density suggesting a trapped pyruvate carbinolamine intermediate. All three subunits contain a phosphate ion bound in a location effectively identical to that of the sulfate ion bound in the T. maritima enzyme. The sulfate and phosphate ions experimentally locate the putative phosphate binding site of the aldolase and, together with the position of the bound pyruvate, facilitate construction of a model for the full-length KDPG substrate complex. The model requires only minimal positional adjustments of the experimentally determined covalent intermediate and bound anion to accommodate full-length substrate. The model identifies the key catalytic residues of the protein and suggests important roles for two observable water molecules. The first water molecule remains bound to the enzyme during the entire catalytic cycle, shuttling protons between the catalytic glutamate and the substrate. The second water molecule arises from dehydration of the carbinolamine and serves as the nucleophilic water during hydrolysis of the enzyme-product Schiff base. The second water molecule may also mediate the base-catalyzed enolization required to form the carbon nucleophile, again bridging to the catalytic glutamate. Many aspects of this mechanism are observed in other Class I aldolases and suggest a mechanistically and, perhaps, evolutionarily related family of aldolases distinct from the N-acetylneuraminate lyase (NAL) family.

Substrate ambiguity and crystal structure of Pyrococcus furiosus 3-deoxy-D-arabino-heptulosonate-7-phosphate synthase: an ancestral 3-deoxyald-2-ulosonate-phosphate synthase?

3-deoxy-D-arabino-heptulosonate-7-phosphate synthase (DAH7PS) catalyzes the condensation reaction between phosphoenolpyruvate (PEP) and the four-carbon monosaccharide D-erythrose 4-phosphate (E4P). DAH7PS from the hyperthermophile Pyrococcus furiosus is a member of the DAH7PS Ibeta subfamily, which also includes the KDO8PS enzymes. KDO8PS (3-deoxy-D-manno-octulosonate-8-phosphate synthase) catalyzes a closely related reaction of PEP with the five-carbon monosaccharide D-arabinose 5-phosphate (A5P). DAH7PS from P. furiosus requires a metal ion for activity and, unlike other characterized DAH7PS enzymes, is not inhibited by aromatic amino acids. Purified P. furiosus DAH7PS is able to utilize not only the four-carbon phosphorylated monosaccharides E4P and 2-deoxy-D-erythrose 4-phosphate but also the five-carbon phosphorylated monosaccharides A5P, D-ribose 5-phosphate, and 2-deoxy-D-ribose 5-phosphate with similar kcat but much increased KM values. DL-glyceraldehyde 3-phosphate and D-glucose 6-phosphate are not substrates. The structure of recombinant P. furiosus DAH7PS in complex with PEP was determined to 2.25 A resolution. The asymmetric unit consists of a dimer of (beta/alpha)8-barrel subunits. Analysis of the buried surfaces formed by dimerization and tetramerization, as observed in the crystal structure, provides insight into both the oligomeric status in solution and the substrate ambiguity of P. furiosus DAH7PS. P. furiosus DAH7PS is both the first archaeal and the first "naked" DAH7PS (without N-terminal extensions) to be fully characterized functionally and structurally. The broad substrate specificity of this DAH7PS, the lack of allosteric inhibition, and various structural features indicate that, of the enzymes characterized to date, P. furiosus DAH7PS may be the contemporary protein closest to the ancestral type I enzyme.

Purification and biochemical characterization of a pyruvate-specific class II aldolase, HpaI.

HpaI, a class II pyruvate-specific aldolase involved in the catabolic pathway of hydroxyphenylacetate, is overexpressed and purified. A previous suggestion that phosphate is involved in proton transfer of pyruvate, based on the crystal structure of the homologous 2-dehydro-3-deoxygalactarate aldolase, is not substantiated from biochemical studies with HpaI. Thus, specific activities of the enzyme for the substrate 4-hydroxy-2-ketopentanoate in sodium HEPES and Tris-acetate buffers are higher than in sodium phosphate buffer. The enzyme also catalyzed the partial reaction of pyruvate proton exchange with an initial rate of 0.77 mmol min(-)(1) mg(-)(1) in phosphate-free buffer, as monitored by nuclear magnetic resonance. Steady-state kinetic analysis shows that the enzyme is also able to catalyze the aldol cleavage of 4-hydroxy-2-ketohexanoate and 3-deoxy-d-manno-oct-2-ulosonic acid (KDO). The enzyme exhibits significant oxaloacetate decarboxylase activity, with a k(cat) value 2.4-fold higher than the corresponding value for the aldol cleavage of 4-hydroxy-2-ketopentanoate. Sodium oxalate, an analogue of the enolate intermediate of the enzyme-catalyzed reaction, is a competitive inhibitor of the enzyme, with a K(i) value of 5.5 microM. Replacement of an active site arginine residue (R70) with alanine by site-specific mutagenesis resulted in an enzyme that lacks both aldolase and decarboxylase activities. The mutant enzyme is also unable to catalyze pyruvate proton exchange. The dissociation constant for pyruvate in the R70A mutant, determined by fluorescence titration, is similar to that of the wild-type enzyme, indicating that pyruvate binding is not affected by this mutation. Together, the results show that R70 influences catalysis in HpaI, particularly at the pyruvate proton exchange step.

Hydroperoxide-lyase activity in mint leaves. Volatile C6-aldehyde production from hydroperoxy-fatty acids.

The extraction of 13-hydroperoxide-lyase activity from mint leaves as well as its use for C6-aldehyde production was studied in this work. The enzyme cleaves 13(S)-hydroperoxy-C18 fatty acids into C6-aldehyde and C12-oxo-acid. Two mint species were tested: Mentha veridis and Mentha pulegium. The headspace injection method coupled to gas chromatography was used for volatile compound analysis. The optimal conditions for temperature and pH were, respectively, 15 and 7 degrees C. We also studied the specific synthesis of hexanal and hexenals respectively from 13(S)-hydroperoxy-linoleic acid and 13(S)-hydroperoxy-linolenic acid. Considerable quantities of aldehyde (up to 2.58 micromol) were produced after 15 min of cleavage reaction in 2 ml stirred at 100 rpm, especially in presence of extract of M. veridis. The conversion yields decreased from 52.5% as maximum to 3.3% when using initial hydroperoxide concentrations between 0.2 and 15 mM. An unsaturated aldehyde, the 3(Z)-hexenal was produced from 13(S)-hydroperoxy-linolenic acid. The 3(Z)-isomer was unstable and isomerized in part to 2(E)-hexenal. In this work, we observed a very limited isomerization of 3(Z)-hexenal to 2(E)-hexenal, since the reaction and the volatile purge were carried out successively in the same flask without delay or any contact with the atmosphere. These aldehydes contribute to the fresh green odor in plants and are widely used in perfumes and in food technology. Their importance increases especially when the starting materials are of natural biological origin as used in this work. GC-MS analysis allowed the identification of the products.

Crystal structure of decameric fructose-6-phosphate aldolase from Escherichia coli reveals inter-subunit helix swapping as a structural basis for assembly differences in the transaldolase family.

Fructose-6-phosphate aldolase from Escherichia coli is a member of a small enzyme subfamily (MipB/TalC family) that belongs to the class I aldolases. The three-dimensional structure of this enzyme has been determined at 1.93 A resolution by single isomorphous replacement and tenfold non-crystallographic symmetry averaging and refined to an R-factor of 19.9% (R(free) 21.3%). The subunit folds into an alpha/beta barrel, with the catalytic lysine residue on barrel strand beta 4. It is very similar in overall structure to that of bacterial and mammalian transaldolases, although more compact due to extensive deletions of additional secondary structural elements. The enzyme forms a decamer of identical subunits with point group symmetry 52. Five subunits are arranged as a pentamer, and two ring-like pentamers pack like a doughnut to form the decamer. A major interaction within the pentamer is through the C-terminal helix from one monomer, which runs across the active site of the neighbouring subunit. In classical transaldolases, this helix folds back and covers the active site of the same subunit and is involved in dimer formation. The inter-subunit helix swapping appears to be a major determinant for the formation of pentamers rather than dimers while at the same time preserving importing interactions of this helix with the active site of the enzyme. The active site lysine residue is covalently modified, by forming a carbinolamine with glyceraldehyde from the crystallisation mixture. The catalytic machinery is very similar to that of transaldolase, which together with the overall structural similarity suggests that enzymes of the MipB/TALC subfamily are evolutionary related to the transaldolase family.

Two class II D-tagatose-bisphosphate aldolases from enteric bacteria.

Escherichia coli, Salmonella enterica, Klebsiella pneumoniaeand Klebsiella oxytocawere found to contain two D-tagatose 1,6-bisphosphate (TagBP)-specific aldolases involved in catabolism of galactitol (genes gatY gatZ) and of N-acetyl-galactosamine and D-galactosamine (genes kbaY kbaZ,also called agaY agaZ). The two aldolases were closely related (> or = 53.8% identical amino acids) and could substitute for each other in vivo. The catalytic subunits GatY or KbaY alone were sufficient to show aldolase activity. Although substantially shorter than other aldolases (285 amino acids, instead of 358 and 349 amino acids), these subunits contained most or all of the residues that have been identified as essential in substrate/product recognition and catalysis for class II aldolases. In contrast to these, both aldolases required subunits GatZ or KbaZ (420 amino acids) for full activity and for good in vivo and in vitro stability. The Z subunits alone did not show any aldolase activity. Close relatives of these new TagBP aldolases were found in several gram-negative and gram-positive bacteria, e.g., Streptomyces coelicolor.

Inositol-1-phosphate synthase from Archaeoglobus fulgidus is a class II aldolase.

A gene putatively identified as the Archaeoglobus fulgidus inositol-1-phosphate synthase (IPS) gene was overexpressed to high level (about 30-40% of total soluble cellular proteins) in Escherichia coli. The recombinant protein was purified to homogeneity by heat treatment followed by two column chromatographic steps. The native enzyme was a tetramer of 168 +/- 4 kDa (subunit molecular mass of 44 kDa). At 90 degrees C the K(m) values for glucose-6-phosphate and NAD(+) were estimated as 0.12 +/- 0.04 mM and 5.1 +/- 0.9 microM, respectively. Use of (D)-[5-(13)C]glucose-6-phosphate as a substrate confirmed that the stereochemistry of the product of the IPS reaction was L-myo-inositol-1-phosphate. This archaeal enzyme, with the highest activity at its optimum growth temperature among all IPS reported (k(cat) = 9.6 +/- 0.4 s(-1) with an estimated activation energy of 69 kJ/mol), was extremely heat stable. However, the most unique feature of A. fulgidus IPS was that it absolutely required divalent metal ions for activity. Zn(2+) and Mn(2+) were the best activators with K(D) approximately 1 microM, while NH(4)(+) (a critical activator for all the other characterized IPS enzymes) had no effect on the enzyme. These properties suggested that this archaeal IPS was a class II aldolase. In support of this, stoichiometric reduction of NAD(+) to NADH could be followed spectrophotometrically when EDTA was present along with glucose-6-phosphate.

Crystal structures of the metal-dependent 2-dehydro-3-deoxy-galactarate aldolase suggest a novel reaction mechanism.

Carbon-carbon bond formation is an essential reaction in organic chemistry and the use of aldolase enzymes for the stereochemical control of such reactions is an attractive alternative to conventional chemical methods. Here we describe the crystal structures of a novel class II enzyme, 2-dehydro-3-deoxy-galactarate (DDG) aldolase from Escherichia coli, in the presence and absence of substrate. The crystal structure was determined by locating only four Se sites to obtain phases for 506 protein residues. The protomer displays a modified (alpha/beta)(8) barrel fold, in which the eighth alpha-helix points away from the beta-barrel instead of packing against it. Analysis of the DDG aldolase crystal structures suggests a novel aldolase mechanism in which a phosphate anion accepts the proton from the methyl group of pyruvate.