Baker's yeast mediated reduction of β-keto esters and β-keto amides in an organic solvent system

The baker's yeast mediated reduction of four β-keto esters in petroleum ether indicated that the size of the group attached to the keto carbon affected their reactivity. Ethyl 3-phenyl-3-oxopropanoate (1), which has a phenyl group directly attached to the keto carbon, is incompletely reduced using 20 g yeast/mmol substrate, ethyl 4-phenyl-3-oxobutanoate (2), which has one methylene group between the phenyl and keto carbon, was also incompletely reduced using 20 g yeast/mmol, although the extent of reduction was about double that of (1), ethyl 5-phenyl-3-oxopentanoate (3), which has two methylene groups between the phenyl and keto carbon, is completely reduced using 10 g yeast/mmol and ethyl 3-oxobutanoate (4), which has a methyl group attached to the keto carbon shows complete reduction using only 1 g yeast/mmol. The corresponding β-keto amides are considerably less reactive than the corresponding β-keto esters with only the amides derived from ethyl 3-oxobutanoate indicating any significant reduction using 20 g yeast/mmol.     

Structural and functional studies of a trans‐acyltransferase polyketide assembly line enzyme that catalyzes stereoselective α‐ and β‐ketoreduction

While the cis‐acyltransferase modular polyketide synthase assembly lines have largely been structurally dissected, enzymes from within the recently discovered trans‐acyltransferase polyketide synthase assembly lines are just starting to be observed crystallographically. Here we examine the ketoreductase (KR) from the first polyketide synthase module of the bacillaene nonribosomal peptide synthetase/polyketide synthase at 2.35‐Å resolution. This KR naturally reduces both α‐ and β‐keto groups and is the only KR known to do so during the biosynthesis of a polyketide. The isolated KR not only reduced an N‐acetylcysteamine‐bound β‐keto substrate to a D ‐β‐hydroxy product, but also an N‐acetylcysteamine‐bound α‐keto substrate to an L ‐α‐hydroxy product. That the substrates must enter the active site from opposite directions to generate these stereochemistries suggests that the acyl‐phosphopantetheine moiety is capable of accessing very different conformations despite being anchored to a serine residue of a docked acyl carrier protein. The features enabling stereocontrolled α‐ketoreduction may not be extensive since a KR that naturally reduces a β‐keto group within a cis‐acyltransferase polyketide synthase was identified that performs a completely stereoselective reduction of the same α‐keto substrate to generate the D ‐α‐hydroxy product. A sequence analysis of trans‐acyltransferase KRs reveals that a single residue, rather than a three‐residue motif found in cis‐acyltransferase KRs, is predictive of the orientation of the resulting β‐hydroxyl group. Proteins 2014; 82:2067–2077. © 2014 Wiley Periodicals, Inc.     

Maple syrup urine disease: branched-chain keto acid decarboxylation in fibroblasts as measured with amino acids and keto acids.

Branched-chain keto acid decarboxylase activity in skin fibroblasts from control subjects and from patients with classical and variant forms of maple syrup urine disease (MSUD) was measured with leucine and alpha-ketoisocaproic acid. When the keto acid was used as substrate in high concentrations (more than 5 mM), the three groups overlapped extensively, even classical cases of MSUD exhibiting decarboxylase activity. With leucine as substrate, decarboxylase activity plateaued at about 1.5 mM, and the three groups could be clearly differentiated. Classical cases of MSUD had minimal or no decarboxylase activity.     

Purification and characterization of an aldehyde reductase from Candida magnoliae

An NADPH-dependent aldehyde reductase was purified to homogeneity from Candida magnoliae AKU4643 through four steps, including Blue-Sepharose affinity chromatography. The relative molecular mass of the enzyme was estimated to be 33,000 on high performance gel-permeation chromatography and 35,000 on sodium dodecyl sulfate polyacrylamide gel electrophoresis. The substrate specificity of the enzyme was broad and resembled those of other aldo–keto reductases. The partial amino acid sequences of the enzyme showed that it belongs to the aldo–keto reductase superfamily. The enzyme catalyzed the stereoselective reduction of ethyl 4-chloro-3-oxobutanoate to the corresponding (R)-alcohol, with a 100% enantiomeric excess. The enzyme was inhibited by 1 mM quercetin, CuSO₄, ZnSO₄ and HgCl₂. The thermostability of the enzyme was inferior to that of the (S)-CHBE-producing enzyme from the same strain.     

From malate dehydrogenase to phenyllactate dehydrogenase. Incorporation of unnatural amino acids to generate an improved enzyme-catalyzed activity

Malate dehydrogenase (MDH) from Escherichia coli is highly specific for its keto acid substrate. The placement of the active site-binding groups in MDH effectively discriminates against both the shorter and the longer keto dicarboxylic acids that could potentially serve as alternative substrates. A notable exception to this specificity is the alternative substrate phenylpyruvate. This aromatic keto acid can be reduced by MDH, albeit at a somewhat slower rate and with greatly diminished affinity, despite the presence of several substrate-binding arginyl residues and the absence of a hydrophobic pocket in the active site. The specificity of MDH for phenylpyruvate has now been enhanced, and that for the physiological substrate oxaloacetate has been diminished, through the replacement of one of the binding arginyl residues with several unnatural alkyl and aryl amino acid analogs. This approach, called site-specific modulation, incorporates systematic structural variations at a site of interest. Molecular modeling studies have suggested a structural basis for the affinity of native MDH for phenylpyruvate and a rationale for the improved catalytic activity that is observed with these new, modified phenyllactate dehydrogenases.     

Computational studies on pterins and speculations on the mechanism of action of dihydrofolate reductase

The significance of the enol form of the pterin ring in enzymatic reduction of dihydrofolate by DHFR is discussed on the basis of the results of ab initio calculations carried out on the keto/enol tautomers of 6-methyl-7, 8-dihydropterin as the model compound for the natural substrate, dihydrofolate.     

Remarkable acceleration of a DNA/RNA inter-strand functionality transfer reaction to modify a cytosine residue: the proximity effect via complexation with a metal cation

Modified nucleosides in natural RNA molecules are essential for their functions. Non-natural nucleoside analogues have been introduced into RNA to manipulate its structure and function. We have recently developed a new strategy for the in situ modification of RNA based on the functionality transfer reaction between an oligodeoxynucleotide probe and an RNA substrate. 2′-Deoxy-6-thioguanosine (6-thio-dG) was used as the platform to anchor the transfer group. In this study, a pyridinyl vinyl ketone moiety was newly designed as the transfer group with the expectation that a metal cation would form a chelate complex with the pyridinyl-2-keto group. It was demonstrated that the (E)-pyridinyl vinyl keto group was efficiently and specifically transferred to the 4-amino group of the opposing cytosine in RNA in the presence of NiCl₂ with more than 200-fold accelerated rate compared with the previous system with the use of the diketo transfer group. Detailed mechanistic studies suggested that NiCl₂ forms a bridging complex between the pyridinyl keto moiety and the N7 of the purine residue neighboring the cytosine residue of the RNA substrate to bring the groups in close proximity.     

Enzymatic and Molecular Characterization of Arabidopsis ppGpp Pyrophosphohydrolase,AtNUDX26

Three α-keto ester reductases (yeast keto ester reductase, YKER-II, -IV, -V) were purified from bakers’ yeast. YKER-II, -IV, and -V are dimeric, monomeric, and dimeric enzymes, respectively, and molecular masses are estimated to be 58, 31–39, and 83kDa, respectively, based on gel filtration and SDS- polyacrylamide electrophoresis. Kinetic parameters and stereoselectivities in reduction of α-keto esters have been measured. YKER-IV contributes mainly to reduction by bakers’ yeast at low substrate concentrations, and is useful for synthetic purposes.     

Selective reduction of oxo bile acids: synthesis of 3 beta-, 7 beta-, and 12 beta-hydroxy bile acids

Preparation of some biologically important keto bile acids is described. Advantage is taken of the preferential ketalization of 3-oxo group in bile acids over 7- and 12-oxo groups for the selective reduction of these keto groups. The method was found to be specially useful for preparation of 7 beta-, 12 alpha, and 12 beta-[3H]-3-oxo bile acids. Improved methods are also described for the preparation of epimers of naturally occurring bile acids at C-3, C-7, and C-12. 3 beta-Hydroxy bile acids (iso-bile acids) were prepared with the use of diethylazodicarboxylate/triphenylphosphine/formic acid. Iso-bile acids were obtained in excellent yields (80-95%) except during synthesis of isoursodeoxycholic acid (yield, 50%). Isoursodeoxycholic acid was, however, prepared in very good yield via epimerization of 3 alpha-hydroxyl group in 7-oxolithocholic acid followed by stereoselective reduction of 7-oxo group. A highly efficient method for the reduction of 7-oxo and 12-oxo groups was developed. Thus, 7-oxolithocholic acid and 7-oxoisolithocholic acid on reduction with potassium/tertiary amyl alcohol yielded ursodeoxycholic acid and isoursodeoxycholic acid in yields of 96% and 94%, respectively, while reduction of 7-oxodeoxycholic acid resulted in ursocholic acid in 93% yield. In a similar manner, reduction of 12-oxolithocholic acid and 12-oxochenodeoxycholic acid yielded 3 alpha, 12 beta-dihydroxy-5 beta-cholanoic acid (lagodeoxycholic acid; 92% yield) and 3 alpha, 7 alpha, 12 beta-trihydroxy-5 beta-cholanoic acid (lagocholic acid, 86% yield).     

Substrate form of D-frutose 1,6-bisphosphate utilized by fructose 1,6-bisphosphatase.

Rapid quench kinetic experiments on fructose 1,6-bisphosphatase demonstrate a stereospecificity for the alpha anomer of fructose 1,6-bisphosphate relative to the beta configuration. The beta anomer is only utilized after mutarotation to the alpha form in a process that is not enzyme catalyzed. Studies employing analogues of the acyclic keto configuration indicate that the keto form is utilized at a rate less than 5% that of the alpha anomer, a finding also confirmed by computer simulation of the rapid quench data. Chemical trapping experiments of the keto analogue, xylulose 1,5-bisphosphate, and the normal substrate suggest that interconversion of the acyclic and anomeric configurations is retarded by their binding to the enzyme. A hypothesis is advanced attributing substrate inhibition of fructose 1,6-bisphosphatase to possible binding of the keto species.     

Novel biosynthetic routes to non-proteinogenic amino acids as chiral pharmaceutical intermediates

Transaminases catalyse the reversible transfer of amino and keto groups between an amino acid and keto acid substrate pair. Many bacterial transaminases accept a wide array of keto acids as amino acceptors and are useful as commercial biocatalysts in the preparation of amino acids. Since the reaction equilibrium typically lies close to unity, several approaches have been described to improve upon the 50% product yield, using additional enzymes. The present work describes an efficient means to significantly increase product yield in transamination using the aromatic transaminase of Escherichia coli encoded by the tyrB gene, with -aspartate as the amino donor. This is achieved by the introduction of the alsS gene encoding the acetolactate synthase of Bacillus subtilis, which eliminates pyruvate and alanine produced as a by-product of aspartate transamination. The biosynthesis of the non-proteinogenic amino acid -2-aminobutyrate is described using a recombinant strain of E. coli containing the cloned tyrB and alsS genes. The strain additionally carries the cloned ilvA gene of E. coli encoding threonine deaminase to produce the substrate 2-ketobutyrate from -threonine. An alternate coupled process uses lysine -aminotransferase in concert with a transaminase using -glutamate as the amino donor.     

Measurement of alpha-keto acids in plasma using an amino acid analyzer

A method for measuring keto acid concentrations in physiological fluids using an amino acid analyzer was developed. After preliminary deproteinization and removal of amino acids, reduction with sodium cyanoborohydride at 105 degrees C resulted in efficient conversion of the keto acids to their corresponding amino acids. In applying the technique to plasma samples, the use of MeOH for deproteinization was necessary to avoid the large losses of keto acids that occurred during precipitation of proteins with perchloric acid. The method was used to follow plasma ketoisocaproate concentrations in rat plasma after administration of leucine, and was sufficiently sensitive to detect concomitant changes in other branched-chain keto acid concentrations.     

NADH-dependent cinerulose reductase in rat liver microsomes.

In the course of studies on the metabolism of a new antitumor anthracycline antibiotic, aclacinomycin A, the new keto reductase which catalyzes the reduction of keto group of L-cinerulose of aclacinomycin A to L-rhodinose was found in rat liver microsomal membrane. The enzyme requires NADH for the reduction and showed optimum pH at 7.0. Km value for aclacinomycin A, 2.1 × 10^?5 M and the concentration of NADH need to half maximal activity, 6.2 × 10^?5 M were obtained. The activity was potently inhibited by detergents, such as Triton X-100, sodium deoxycholate and sodium dodecyl sulfate.     

Functional characterization of PLP fold type IV transaminase with a mixed type of activity from Haliangium ochraceum

Pyridoxal-5′-phosphate (PLP)-dependent transaminases are industrially important enzymes catalyzing the stereoselective amination of ketones and keto acids. Transaminases of PLP fold type IV are characterized by (R)- or (S)-stereoselective transfer of amino groups, depending on the substrate profile of the enzyme. PLP fold type IV transaminases include branched-chain amino acid transaminases (BCATs), D-amino acid transaminases and (R)-amine:pyruvate transaminases. Recently, transaminases with a mixed type of activity were identified and characterized. Here, we report biochemical and structural characterization of a transaminase from myxobacterium Haliangium ochraceum (Hoch3033), which is active towards keto analogs of branched-chain amino acids (specific substrates for BCATs) and (R)-(+)-α-methylbenzylamine (specific substrate for (R)-amine:pyruvate transaminases). The enzyme is characterized by an alkaline pH optimum (pH 10.0–10.5) and a tolerance to high salt concentrations (up to 2 M NaCl). The structure of Hoch3033 was determined at 2.35 Å resolution. The overall fold of the enzyme was similar to those of known enzymes of PLP fold type IV. The mixed type of activity of Hoch3033 was implemented within the BCAT-like active site. However, in the active site of Hoch3033, we observed substitutions of specificity-determining residues that are important for substrate binding in canonical BCATs. We suggest that these changes result in the loss of activity towards α-ketoglutarate and increase the affinity towards (R)-(+)-α-methylbenzylamine. These results complement our knowledge of the catalytic diversity of transaminases and indicate the need for further research to understand the structural basis of substrate specificity in these enzymes.     

Characterization of an aldo–keto reductase from Thermotoga maritima with high thermostability and a broad substrate spectrum

A novel aldo–keto reductase gene, Tm1743, from Thermotoga maritima was overexpressed in Escherichia coli. The enzyme displayed the highest activity at 90 °C and at pH 9. It retained 63 % of its activity after 15 h at 85 °C. The enzyme also could tolerate (up to 10 % v/v) acetonitrile, ethanol and 2-propanol with slightly increased activities. Methanol, DMSO and acetone decreased activity slightly. Furthermore, Tm1743 exhibited broad substrate specificity towards various keto esters, ketones and aldehydes, with relative activities ranging from 2 to 460 % compared to the control. Its optimum substrate, 2,2,2-trifluoroacetophenone, was asymmetrically reduced in a coupled NADPH-regeneration system with an enantioselectivity of 99.8 % and a conversion of 98 %.     

Accumulation of α-Keto Acids as Essential Components in Cyanide Assimilation by Pseudomonas fluorescens NCIMB 11764

Pyruvate (Pyr) and α-ketoglutarate (αKg) accumulated when cells of Pseudomonas fluorescens NCIMB 11764 were cultivated on growth-limiting amounts of ammonia or cyanide and were shown to be responsible for the nonenzymatic removal of cyanide from culture fluids as previously reported (J.-L. Chen and D. A. Kunz, FEMS Microbiol. Lett. 156:61–67, 1997). The accumulation of keto acids in the medium paralleled the increase in cyanide-removing activity, with maximal activity (760 μmol of cyanide removed min⁻¹ ml of culture fluid⁻¹) being recovered after 72 h of cultivation, at which time the keto acid concentration was 23 mM. The reaction products that formed between the biologically formed keto acids and cyanide were unambiguously identified as the corresponding cyanohydrins by ¹³C nuclear magnetic resonance spectroscopy. Both the Pyr and α-Kg cyanohydrins were further metabolized by cell extracts and served also as nitrogenous growth substrates. Radiotracer experiments showed that CO₂ (and NH₃) were formed as enzymatic conversion products, with the keto acid being regenerated as a coproduct. Evidence that the enzyme responsible for cyanohydrin conversion is cyanide oxygenase, which was shown previously to be required for cyanide utilization, is based on results showing that (i) conversion occurred only when extracts were induced for the enzyme, (ii) conversion was oxygen and reduced-pyridine nucleotide dependent, and (iii) a mutant strain defective in the enzyme was unable to grow when it was provided with the cyanohydrins as a growth substrate. Pyr and αKg were further shown to protect cells from cyanide poisoning, and excretion of the two was directly linked to utilization of cyanide as a growth substrate. The results provide the basis for a new mechanism of cyanide detoxification and assimilation in which keto acids play an essential role.     

Reversed-phase high-performance liquid chromatographic analysis of branched-chain keto acid hydrazone derivatives: optimization of techniques and application to branched-chain keto acid balance studies across the forearm

A sensitive method of quantifying branched-chain keto acids in plasma and whole blood samples is described. It is based on the separation by ion-pair reversed-phase liquid chromatography of 2,4-dinitrophenylhydrazine derivatives with ultraviolet detection. The sample clean-up steps that are usually required for reversed-phase high-performance liquid chromatography are eliminated. A reduction in ketoisocaproate isomer formation is obtained by incubation of derivatives in ice. The method is reproducible (coefficient of variation 2%, n = 5, at the 200-pmol level) and the ultraviolet response is linearly related to branched-chain keto acid concentration. Recoveries are high (>95%). Other keto acids do not co-elute with branched-chain keto acids. Because of its sensitivity and precision, this method can be proposed for whole blood branched-chain keto acid balance studies across organs.     

Functional residues at the active site of horse liver phosphopantothenoylcysteine decarboxylase

Horse liver phosphopantothenoylcysteine decarboxylase (EC 4.1.1.36) is rapidly inactivated by N-acetoacetylation with diketene following a pseudo-first-order kinetics: the presence of substrate quantitatively protects against this inactivation. Histidine photo-oxidation with methylene blue or rose bengal brings about the total loss of activity. These results indicate the presence of functional lysyl and histidyl groups at the active site of the enzyme. The substrate sulphydryl group is essential for enzyme activity. Enzymatic decarboxylation is proposed to result from a combined action of the keto group of the enzyme-bound pyruvate protonated by an essential histidine and a protonated amino group of a lysine.     

Dynamic mechanistic modeling of the multienzymatic one‐pot reduction of dehydrocholic acid to 12‐keto ursodeoxycholic acid with competing substrates and cofactors

Ursodeoxycholic acid (UDCA) is a bile acid which is used as pharmaceutical for the treatment of several diseases, such as cholesterol gallstones, primary sclerosing cholangitis or primary biliary cirrhosis. A potential chemoenzymatic synthesis route of UDCA comprises the two‐step reduction of dehydrocholic acid to 12‐keto‐ursodeoxycholic acid (12‐keto‐UDCA), which can be conducted in a multienzymatic one‐pot process using 3α‐hydroxysteroid dehydrogenase (3α‐HSDH), 7β‐hydroxysteroid dehydrogenase (7β‐HSDH), and glucose dehydrogenase (GDH) with glucose as cosubstrate for the regeneration of cofactor. Here, we present a dynamic mechanistic model of this one‐pot reduction which involves three enzymes, four different bile acids, and two different cofactors, each with different oxidation states. In addition, every enzyme faces two competing substrates, whereas each bile acid and cofactor is formed or converted by two different enzymes. First, the kinetic mechanisms of both HSDH were identified to follow an ordered bi–bi mechanism with EBQ‐type uncompetitive substrate inhibition. Rate equations were then derived for this mechanism and for mechanisms describing competing substrates. After the estimation of the model parameters of each enzyme independently by progress curve analyses, the full process model of a simple batch‐process was established by coupling rate equations and mass balances. Validation experiments of the one‐pot multienzymatic batch process revealed high prediction accuracy of the process model and a model analysis offered important insight to the identification of optimum reaction conditions. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:375–386, 2015     

Synthesis of a tetracyclic, conformationally constrained analogue of Δ-THC

A tetracyclic, conformationally constrained analogue of Δ⁸-THC (2) has been synthesized in which a two carbon bridge exists between C2 and C2′. Two conceptually related syntheses of 2 are described, both of which employ 5,7-dimethoxy-4-oxo-1,2,3,4-tetrahydronaphthoic acid (11) as starting material. This substrate was converted to 5,7-dimethoxy-2-propyl-1,2,3,4-tetrahydronaphthalene (7) and its 4-keto derivative (18). Demethylation of 11 and 18 provided the corresponding resorcinols, which were condensed with trans-p-menthadienol to afford cannabinoid 2, and a keto derivative (20). LiAlH₄/AlCl₃ reduction of 20 provided 2. Cannabinoid 2 has relatively low affinity for the cannabinoid brain receptor (K_i = 703 ± 98nM).