Development of an Efficient and Cost-Effective Enzymatic Process for Production of (R)-[3,5-bis(trifluoromethyl)phenyl] Ethanol Using Carbonyl Reductase Derived from Leifsonia sp. S749.

(R)-[3,5-bis(trifluoromethyl) phenyl] ethanol [(R)-3,5-BTPE] is a crucial chiral intermediate for the synthesis of the NK-1 receptor antagonists aprepitant, rolapitant and fosaprepitant. The carbonyl reductase KR01 from Leifsonia sp. S749, discovered by protein sequence alignment, could convert 3',5'-bis(trifluoromethyl) acetophenone (3,5-BTAP) into (R)-3,5-BTPE with excellent activity and enantioselectivity. In order to enhance the conversion efficiency at high substrate concentrations, the reaction conditions were optimized by response surface analysis. The results showed that 600 g/L 3,5-BTAP was bioreduced to (R)-3,5-BTPE (> 99.9% enantiomeric excess) by the recombinant Escherichia coli/pET-28a (+)-KR01 whole cells, with a 98.3% conversion and 59 g/L/h productivity under the optimized reaction conditions. In addition, the recombinant E. coli cells could be repeatedly used up to seven times in the reaction mixture containing 90% isopropanol (IPA). This is the highest substrate loading and productivity for the bioreduction of 3,5-BTAP by carbonyl reductase ever reported, and this method represents an efficient and cost-effective process for production of (R)-3,5-BTPE.

Application of ω-Transaminases in the Pharmaceutical Industry.

Chiral amines are valuable building blocks for the pharmaceutical industry. ω-TAms have emerged as an exciting option for their synthesis, offering a potential "green alternative" to overcome the drawbacks associated with conventional chemical methods. In this review, we explore the application of ω-TAms for pharmaceutical production. We discuss the diverse array of reactions available involving ω-TAms and process considerations of their use in both kinetic resolution and asymmetric synthesis. With the aid of specific drug intermediates and APIs, we chart the development of ω-TAms using protein engineering and their contribution to elegant one-pot cascades with other enzymes, including carbonyl reductases (CREDs), hydrolases and monoamine oxidases (MAOs), providing a comprehensive overview of their uses, beginning with initial applications through to the present day.

The ins and outs of vanillyl alcohol oxidase: Identification of ligand migration paths.

Vanillyl alcohol oxidase (VAO) is a homo-octameric flavoenzyme belonging to the VAO/PCMH family. Each VAO subunit consists of two domains, the FAD-binding and the cap domain. VAO catalyses, among other reactions, the two-step conversion of p-creosol (2-methoxy-4-methylphenol) to vanillin (4-hydroxy-3-methoxybenzaldehyde). To elucidate how different ligands enter and exit the secluded active site, Monte Carlo based simulations have been performed. One entry/exit path via the subunit interface and two additional exit paths have been identified for phenolic ligands, all leading to the si side of FAD. We argue that the entry/exit path is the most probable route for these ligands. A fourth path leading to the re side of FAD has been found for the co-ligands dioxygen and hydrogen peroxide. Based on binding energies and on the behaviour of ligands in these four paths, we propose a sequence of events for ligand and co-ligand migration during catalysis. We have also identified two residues, His466 and Tyr503, which could act as concierges of the active site for phenolic ligands, as well as two other residues, Tyr51 and Tyr408, which could act as a gateway to the re side of FAD for dioxygen. Most of the residues in the four paths are also present in VAO's closest relatives, eugenol oxidase and p-cresol methylhydroxylase. Key path residues show movements in our simulations that correspond well to conformations observed in crystal structures of these enzymes. Preservation of other path residues can be linked to the electron acceptor specificity and oligomerisation state of the three enzymes. This study is the first comprehensive overview of ligand and co-ligand migration in a member of the VAO/PCMH family, and provides a proof of concept for the use of an unbiased method to sample this process.

Assessment of a putative proton relay in Arabidopsis cinnamyl alcohol dehydrogenase catalysis.

Extended proton relay systems have been proposed for various alcohol dehydrogenases, including the Arabidopsis thaliana cinnamyl alcohol dehydrogenases (AtCADs). Following a previous structural biology investigation of AtCAD5, the potential roles of three amino acid residues in a putative proton relay system, namely Thr49, His52 and Asp57, in AtCAD5, were investigated herein. Using site-directed mutagenesis, kinetic and isothermal titration calorimetry (ITC) analyses, it was established that the Thr49 residue was essential for overall catalytic conversion, whereas His52 and Asp57 residues were not. Mutation of the Thr49 residue to Ala resulted in near abolition of catalysis, with thermodynamic data indicating a negative enthalpic change (ΔH), as well as a significant decrease in binding affinity with NADPH, in contrast to wild type AtCAD5. Mutation of His52 and Asp57 residues by Ala did not significantly change either catalytic efficiency or thermodynamic parameters. Therefore, only the Thr49 residue is demonstrably essential for catalytic function. ITC analyses also suggested that for AtCAD5 catalysis, NADPH was bound first followed by p-coumaryl aldehyde.

Bioinformatic and biochemical characterization of DCXR and DHRS2/4 from Caenorhabditis elegans.

Several reductases belonging to the large enzyme superfamily of the short-chain dehydrogenases/reductases (SDR) are involved in the reductive metabolism of carbonyl containing xenobiotics. In order to characterize the human enzymes dicarbonyl/l-xylulose reductase (DCXR), and dehydrogenase/reductase members 2 and 4 (DHRS2, DHRS4) in terms of metabolism of xenobiotics, orthologues from the model organism Caenorhabditis elegans (C. elegans) were identified by using hidden Markov models that were developed in the present study. Accordingly, we describe the characterization of proteins from C. elegans as orthologous to the human enzymes DCXR and DHRS2/4 using a combined approach of bioinformatic and biochemical methods. With the hidden Markov model based system we identified the C. elegans proteins SDR20C18, SDR25C21 and SDR25C22 as being homologous to the human enzymes DCXR, and DHRS2 or DHRS4, respectively. After cloning and overexpression of these three C. elegans genes in Escherichia coli we could purify SDR20C18 and SDR25C22 as soluble proteins by Ni-affinity chromatography, whereas recombinant SDR25C21 was only found in inclusion bodies. Both SDR20C18 (UniProtAcc: Q21929) and SDR25C22 (UniProtAcc: Q93790) were tested with a variety of xenobotic carbonyl compounds as substrates. A comparison of the catalytic activities of SDR20C18 and SDR25C22 with well-known substrates of the human forms revealed that SDR20C18 is the DCXR-orthologue enzyme to the human enzyme and that SDR25C22 might be a DHRS2/4 homologue. Due to their high sequence identity, it was so far not possible to distinguish between SDR25C22 and the human DHRS2/4 proteins by means of sequence analysis alone. However, the study of homologue genes in the model organism C. elegans can provide valuable information on the putative physiological role of the corresponding human form.

Highly selective L-threonine 3-dehydrogenase from Cupriavidus necator and its use in determination of L-threonine.

l-Threonine level in blood plasma is a biomarker of some diseases and nitrogen imbalance in the body. The determination of l-threonine is interesting and is required for diagnosis and management of inherited metabolic disorder. This is the first report of the specific enzymatic determination of l-threonine by a newly discovered l-threonine 3-dehydrogenase (ThrDH, EC 1.1.1.103) from Cupriavidus necator NBRC 102504. ThrDH, a key enzyme in l-threonine catabolism in microorganisms and animals, catalyzes the NAD(+)-dependent oxidation of l-threonine to 2-amino-3-oxobutyrate. ThrDH from C. necator was purified to homogeneity and fully characterized. l-Threonine and dl-2-amino-3-hydroxyvalerate are the only substrates for ThrDH among other l-amino acids, alcohols, and amino alcohols. The primary amino acid structure of ThrDH belongs to the extended short-chain alcohol dehydrogenase superfamily and is related to GDP-mannose-3',5'-epimerase (GME) from Arabidopsis thaliana. Both enzymes have a glycine-rich NAD(+)-binding domain at the N terminal and conserved catalytic triad of YxxxK residues, but substrate-binding residues of GME were not found in the ThrDH sequence. ThrDH significantly differs from known bacterial and archaea ThrDHs that belong to zinc-binding medium chain alcohol dehydrogenase because of low sequence similarity and the lack of a zinc-binding domain in the sequence. A specific, quantitative, and sensitive enzymatic endpoint method for l-threonine determination was developed by using a ThrDH microplate assay. The assay was successfully applied for determination of l-threonine in human serum and plasma. Our specific determination is simple, convenient, inexpensive, accurate, and suitable for mass screening determination of l-threonine in a number of samples.

Safety assessment of bacterial choline oxidase protein introduced in transgenic crops for tolerance against abiotic stress.

Genetically modified crops have resistance to abiotic stress by introduction of choline oxidase protein. In the present study, the safety of choline oxidase protein derived from Arthrobacter globiformis was assessed for toxicity and allergenicity. The protein was stable at 90 degrees C for 1 h. Toxicity studies of choline oxidase in mice showed no significant difference (p > 0.05) from control in terms of growth, body weight, food consumption, and blood biochemical indices. Histology of gut tissue of mice fed protein showed normal gastric mucosal lining and villi in jejunum and ileum sections. Specific IgE in serum and IL-4 release in splenic culture supernatant were low in choline oxidase treated mice, comparable to control. Intravenous challenge with choline oxidase did not induce any adverse reaction, unlike ovalbumin group mice. Histology of lung tissues from choline oxidase sensitized mice showed normal airways, whereas ovalbumin-sensitized mice showed inflamed airways with eosinophilic infiltration and bronchoconstriction. ELISA carried out with food allergic patients' sera revealed no significant IgE affinity with choline oxidase. Also, choline oxidase did not show any symptoms of toxicity and allergenicity in mice.

Allergenicity assessment of transgenic mustard (Brassica juncea) expressing bacterial codA gene.

BACKGROUND: Assessing the allergenicity and toxicity of genetically modified (GM) crops is essential before they become a regular part of our food supply. The present study aimed to assess the allergenicity of Brassica juncea (mustard) expressing choline oxidase (codA) gene from Arthrobacter globiformis that provides resistance against abiotic stresses. METHODS: SDAP, Farrp, and Swiss-Prot databases were used to study allergenicity of choline oxidase. Digestibility of choline oxidase was assessed in simulated gastric fluid (SGF). Specific immunoglobulin E (IgE) reactivity of native and GM mustard was compared by using enzyme-linked immunosorbent assay (ELISA) and skin tests in respiratory-allergic patients. Allergenicity of GM and native mustard proteins was compared in Balb/c mice. RESULTS: Choline oxidase showed no significant homology with allergenic proteins in SDAP and Farrp databases. Cross-reactive epitope search showed a stretch similar to Hev b 6 having some antigenic properties. Purified choline oxidase showed complete degradation with SGF. Skin prick test of native and GM mustard extract on respiratory allergic patients showed significant correlation (P < 0.05). ELISA with 96 patients' sera showed comparable IgE reactivity. Balb/c mice immunized with native and GM mustard proteins showed low IgE response. Presensitized mice on intravenous challenge with Brassica extract showed no anaphylactic symptoms unlike ovalbumin (OVA) sensitization that showed anaphylactic reaction in mice. Lung histology of OVA-sensitized mice showed narrowing of airway and large eosinophilic infiltration, whereas native and GM Brassica extract showed normal airway. CONCLUSION: Genetically modified mustard with the codA gene possessed allergenicity similar to that of native mustard and no enhancement of IgE binding was observed due to genetic manipulation.