The biochemical characterization of three imine-reducing enzymes from Streptosporangium roseum DSM43021, Streptomyces turgidiscabies and Paenibacillus elgii

Applied Microbiology and Biotechnology - Recently imine reductases (IREDs) have emerged as promising biocatalysts for the synthesis of a wide variety of chiral amines. To promote their application,...     

NAD(P)H依赖型氧化还原酶不对称还原胺化制备手性胺的研究进展

不对称还原胺化反应是制备医药中间体手性胺结构单元的重要反应。目前已有许多不同种类的酶被应用于合成手性胺,其中NAD(P)H依赖型氧化还原酶催化的还原胺化反应最为引人注目,因为其能够一步将潜手性酮化合物完全转化为光学纯的手性胺化合物。文中以亚胺还原酶、氨基酸脱氢酶、冠瘿碱脱氢酶和还原性酮胺化酶为例,从NAD(P)H依赖型氧化还原酶的结构特征、作用机理、分子改造及催化应用等方面,综述了其在不对称还原胺化合成手性胺领域的研究进展。     

Use of the anti-Prelog stereospecific alcohol dehydrogenase from Leifsonia and Pseudomonas for producing chiral alcohols

The asymmetric reduction of ketones is one of the most promising processes for producing chiral alcohols. However, dehydrogenases or reductases that can catalyze the reduction of ketones to give anti-Prelog chiral alcohols have been limited to some NADP⁺/NADPH-dependent enzymes. Recently, we reported a novel NAD⁺/NADH-dependent alcohol dehydrogenase (ADH) from Leifsonia sp. and Pseudomonas ADH homologs from soil metagenomes. Moreover, we have established an efficient hydrogen-transfer bioreduction process with 2-propanol as a hydrogen donor using Leifsonia ADH. This review focuses on the recent development of novel ADHs for producing industrially useful anti-Prelog chiral alcohols from various ketones.     

High-performance liquid chromatography of imine stereoisomers on cellulose-based chiral stationary phases

A high-performance liquid chromatographic method has been developed for the analysis of the intermediate imines and end products in an asymmetric isomerization route toward optically active amines. Separation of the imine enantiomers was performed on commercially available Chiralcel OD-H, Chiralcel OJ, and Chiralpak AD chiral stationary phases. All substituted imine enantiomers could be readily resolved with selectivities (α) higher than 1.10 using the Chiralpak AD column. By derivatization with ring-substituted benzaldehydes, aromatic amines were converted into Schiff base derivatives and the enantiopurity of these amines was determined. Chirality 9:727–731, 1997. © 1997 Wiley-Liss, Inc.     

Biocatalytic asymmetric amination of carbonyl functional groups – a synthetic biology approach to organic chemistry

Transaminases catalyze amino transfer reactions from amino donors such as amino acids or amines to keto acids or ketones to give chiral amino acid or amines in optically pure form. α-Amino acid dehydrogenases catalyze the asymmetric reductive amination of α-keto acids using ammonia as amino donor to furnish L -amino acids. The distinct features and synthetic application of these two enzymes are reviewed in an effort to illustrate their promising and challenging aspects in serving as approaches to the direct asymmetric synthesis of optically pure amines from the corresponding keto compounds, a formidable problem in organic chemistry.     

Exploring sequence space: profile analysis and protein-ligand docking to screen omega-aminotransferases with expanded substrate specificity

omega-Aminotransferase (omegaAT) is an interesting biocatalyst for the preparation of chiral amines, which are widely used as building blocks for pharmaceuticals, agrochemicals and fine chemicals. With the assumption that substrate and sequence spaces are in the process of co-evolution, we explored sequences space to screen the enzymes showing activity to new target compounds. Bacterial genome sequences (n=527) were analyzed by the profiles of subgroups in aminotransferase group II including ornithine aminotransferase (orAT), acetylornithine aminotransferase (aoAT), omegaAT, gamma-aminobutyrate aminotransferase (GABAAT) and 7,8-diaminopelargonate aminotransferase (DAPAAT). We selected the sequences having a Z score of 0-1.8 to guarantee the omegaAT reaction and to avoid the typical omegaAT sequences. Among the selected sequences, we filtered out the sequences with very low Z scores for the rest of four subgroups in aminotransferase group II to consider the diversity. For the selected sequences, we performed protein-ligand docking simulations to predict the docking pose of amino acceptor. Throughout all the analysis procedures, several candidate aminotransferase sequences for the asymmetric synthesis of chiral amines were obtained. An efficient procedure for virtual screening of novel enzymes was demonstrated.     

w-转氨酶分子改造研究进展

ω-转氨酶能催化羰基化合物发生不对称还原胺化反应,在制备手性胺类化合物方面具有较好的应用前景。由于底物结合区域特殊的空间结构,野生型ω-转氨酶在合成大位阻手性胺方面的应用受到了限制。此外,在立体选择性和稳定性方面这一类酶也存在一些不足,目前满足工业应用需求的ω-转氨酶仍较为有限。文中首先介绍了ω-转氨酶的结构特征和催化机制,并探讨S型和R型酶在结构特征方面的主要差异。然后对ω-转氨酶的分子改造研究进行了综述,重点阐述了基于结构特征和催化机制进行的分子改造研究,包括底物特异性改造、立体选择性改造和稳定性改造三方面。最后,对ω-转氨酶分子改造研究进展进行总结和展望。     

Derivatization,complexation, and absolute configurational assignment of chiral primary amines: application of exciton-coupled circular dichroism

We report here a sensitive method for the determination of the absolute configurations of primary amines using exciton-coupled circular dichroism (ECCD). The method works on a microgram scale by derivatization of chiral amines with quinoline chromophores. Complexation of the chiral ligands with metal ion fixes the geometry of the chromophores, resulting in a twist that is governed by the asymmetric carbon configuration and steric environment of the amine. The absolute configurations of the primary amines can be interpreted from the couplets of the ECCD spectra of the derivatized complexes. Crystal structures, 2D NMR studies, and semiempirical calculations provide structural evidence for our model.     

Amine transaminases in chiral amines synthesis: recent advances and challenges

Transaminases, which catalyze the stereoselective transfer of an amino group between an amino donor and a prochiral ketone substrate, are interesting biocatalytic tools for the generation of optically pure chiral amines. In particular, amine transaminases (ATAs) are of industrial interest because they are capable of performing reductive amination reactions using a broad range of amine donors and acceptors. The most remarkable example of ATAs industrial application is in the production process of the anti-hyperglycaemic drug sitagliptin (Januvia^®/Janumet^®), which generated around 6 billion U.S. dollars of revenue to Merck in 2016. In this review, an update about the availability of microbial ATAs, discovered by both screening and database-mining approaches, or obtained by protein engineering of wild-type enzymes, will be provided. Current challenges in ATAs application and possible solutions will be also discussed. In particular, innovative biocatalytic process strategies aimed at the improvement of ATAs performances in chiral amines synthesis, e.g., using in situ product removal process strategies or flow reactors, will be presented. The progress in the industrial exploitation of these enzymes will be highlighted by selected examples of large-scale ATA-catalyzed processes.     

VCD study of α‐methylbenzyl amine derivatives: Detection of the unchanged chiral motif

Chiral α‐methylbenzyl amine is a well known and often used chiral auxiliary, e.g., in the resolution of racemates or asymmetric catalysis. In this work, α‐methylbenzyl amine and its derivatives N,α‐dimethylbenzyl amine, N,N,α‐trimethylbenzyl amine, and bis[α‐methylbenzyl] amine were investigated by vibrational circular dichroism (VCD) spectroscopy and density functional theory (DFT). For all compounds, stable low energy conformers were obtained by the DFT calculations and based on those, the theoretical vibrational absorption (VA) and VCD spectra were calculated and compared with experimental spectra. Hence, the absolute configurations and conformational preferences were determined. A qualitative comparison of all the experimental VCD spectra of the investigated chiral molecules supported by the calculated ones is given which clearly shows similarities between the spectra of the different chiral amines. These can be assigned to vibrations of the unchanged chiral center. Chirality 2010. © 2010 Wiley‐Liss, Inc.     

Substrate profiling of cyclohexylamine oxidase and its mutants reveals new biocatalytic potential in deracemization of racemic amines

A cyclohexylamine oxidase (CHAO) of bacterial origin was previously shown to be a potentially useful catalyst in the deracemization of racemic primary amines. To further explore the properties and application of this enzyme, five single-amino acid substitution mutants (L199A, M226A, Y321A, Y321F, and L353M) were created based on superimposition of the tertiary structure of CHAO and the monoamine oxidase (MAO) B homolog. The substrate specificity of the purified wild-type and five mutant enzymes were examined towards 38 structurally diverse amines. All the enzymes exhibited better activity for primary amines than secondary and tertiary amines and in general exhibited high stereoselectivity. Among the mutant enzymes, M226A displayed an enhanced activity (5–400 %) towards most substrates, and L353M showed 7–445 % higher activity towards primary aliphatic amines with cycloalkane or aromatic moieties. Kinetic parameters revealed that both Y321 mutants showed higher catalytic efficiency towards cyclooctanamine, whereas the wild-type CHAO (wt CHAO) was most efficient towards cyclohexylamine. The wt CHAO or variant L353M in combination with a borane–ammonia complex as reducing agent was applied to the deracemization of 1-aminotetraline to give the (R)-enantiomer, a precursor of an antidepressant drug Norsertraline, in good yield (73–76 %), demonstrating their application potential in chiral amine synthesis.     

Microbial Engineering for Production of N‐Functionalized Amino Acids and Amines

N‐functionalized amines play important roles in nature and occur, for example, in the antibiotic vancomycin, the immunosuppressant cyclosporine, the cytostatic actinomycin, the siderophore aerobactin, the cyanogenic glucoside linamarin, and the polyamine spermidine. In the pharmaceutical and fine‐chemical industries N‐functionalized amines are used as building blocks for the preparation of bioactive molecules. Processes based on fermentation and on enzyme catalysis have been developed to provide sustainable manufacturing routes to N‐alkylated, N‐hydroxylated, N‐acylated, or other N‐functionalized amines including polyamines. Metabolic engineering for provision of precursor metabolites is combined with heterologous N‐functionalizing enzymes such as imine or ketimine reductases, opine or amino acid dehydrogenases, N‐hydroxylases, N‐acyltransferase, or polyamine synthetases. Recent progress and applications of fermentative processes using metabolically engineered bacteria and yeasts along with the employed enzymes are reviewed and the perspectives on developing new fermentative processes based on insight from enzyme catalysis are discussed.     

Chiral porphyrin imine manganese complex as catalyst for asymmetric epoxidation of styrene derivatives

New chiral porphyrin imine was synthesized from (S)‐3‐benzyl‐2‐methyl‐4‐phenylbutanal according to dipyrromethane method using trifluoroacetic acid, BF₃ etherate, and p‐chloranil. Manganese complex of this chiral porphyrin imine ligand was used as catalyst in the asymmetric epoxidation of styrene derivatives possessing different substituents. Styrene derivatives possessing electron withdrawing groups gave the corresponding chiral epoxides in high yield up to 98% and ee up to 99%. The mechanism for the catalytic asymmetric epoxidation was also discussed based on transfer of oxygen.     

Extending substrate sensing capabilities of zinc tris(2‐pyridylmethyl)amine‐based stereodynamic probe

Tripodal metal complexes have been widely used for catalysis and more recently also for molecular recognition applications. Their ability in recognition and signal amplification of chiral substrates is because of the setup of the ligand around the metal in a propeller shape. Within this subject, we have recently reported tris(2‐pyridylmethyl)amine‐ and triphenolamine‐based complexes for the determination of the enantiomeric excess of various substrates. Herein, we show the versatility of the zinc tris(2‐pyridylmethyl)amine‐based stereodynamic probe by performing a detailed study of the imine formation process, by the extension of the sensing capabilities to other chiral compounds. A principal component analysis study of the system together with TD‐DFT studies highlights the molecular origin of the observed chiroptical properties.     

Features and technical applications of ω-transaminases

Chiral amines in enantiopure forms are important chemical building blocks, which are most well recognized in the pharmaceutical industries for imparting desirable biological activity to chemical entities. A number of synthetic strategies to produce chiral amines via biocatalytic as well as chemical transformation have been developed. Recently, ω-transaminase (ω-TA) has attracted growing attention as a promising catalyst which provides an environment-friendly access to production of chiral amines with exquisite stereoselectivity and excellent catalytic turnover. To obtain enantiopure amines using ω-TAs, either kinetic resolution of racemic amines or asymmetric amination of achiral ketones is employed. The latter is usually preferred because of twofold higher yield and no requirement of conversion of a ketone product back to racemic amine. However, the choice of a production process depends on several factors such as reaction equilibrium, substrate reactivity, enzyme inhibition, and commercial availability of substrates. This review summarizes the biochemical features of ω-TA, including reaction chemistry, substrate specificity, and active site structure, and then introduces recent advances in expanding the scope of ω-TA reaction by protein engineering and public database searching. We also address crucial factors to be considered for the development of efficient ω-TA processes.     

Synthesis of new chiral pincer-complex catalysts for asymmetric allylation of sulfonimines

Four new chiral pincer-complexes were prepared based on coupling of BINOL and TADDOL moieties with iodoresorcinol followed by oxidative addition of palladium(0). The X-ray analysis of complex 5a revealed that the BINOL rings form a well-defined chiral pocket around the palladium atom. This chiral environment can be further modified by γ-substitution of the BINOL rings. Preliminary studies for electrophilic allylation of sulfonimine 2 with allylstannane revealed that the presented chiral complexes are promising asymmetric catalysts for preparation of chiral homoallyl amines. The best result was achieved employing catalytic amounts of γ-Me BINOL complex 6 affording homoallyl amine 4 with 59% ee and 74% isolated yield.     

The Asymmetric Imino-aldol Approach to the Enantioselective Synthesis of β-amino acids

Two approaches, based on imino-aldol additions, to the asymmetric synthesis of cyclic β-amino acids are reported. In each case a chiral auxiliary was employed attached either to the enolate or to the imine. The relative efficacy of these two synthetic methods is also briefly compared with the former still the preferred route as the latter is currently limited to the preparation of N-sulfonyl β-amino acids.     

Crystal Structure of an (R)-Selective ω-Transaminase from Aspergillus terreus

Chiral amines are important building blocks for the synthesis of pharmaceutical products, fine chemicals, and agrochemicals. ω-Transaminases are able to directly synthesize enantiopure chiral amines by catalysing the transfer of an amino group from a primary amino donor to a carbonyl acceptor with pyridoxal 5′-phosphate (PLP) as cofactor. In nature, (S)-selective amine transaminases are more abundant than the (R)-selective enzymes, and therefore more information concerning their structures is available. Here, we present the crystal structure of an (R)-ω-transaminase from Aspergillus terreus determined by X-ray crystallography at a resolution of 1.6 Å. The structure of the protein is a homodimer that displays the typical class IV fold of PLP-dependent aminotransferases. The PLP-cofactor observed in the structure is present in two states (i) covalently bound to the active site lysine (the internal aldimine form) and (ii) as substrate/product adduct (the external aldimine form) and free lysine. Docking studies revealed that (R)-transaminases follow a dual binding mode, in which the large binding pocket can harbour the bulky substituent of the amine or ketone substrate and the α-carboxylate of pyruvate or amino acids, and the small binding pocket accommodates the smaller substituent.     

Non-conventional hydrolase chemistry: amide and carbamate bond formation catalyzed by lipases

Biocatalysis in nonaqueous media is becoming increasingly important in organic synthesis. Lipases are the most used enzymes, especially in transesterification reactions. However, in the last years the amidation reaction catalyzed by lipases has also been shown to be a useful tool for the organic chemists. In this review, we discuss the possibilities of the enzymatic aminolysis and ammonolysis reactions for the preparation of different amides and for the resolution of esters, amines and aminoalcohols. The enzymatic alkoxycarbonylation of amines opens a new way for the synthesis of chiral carbamates.     

Circular dichroism of bilirubin-amine association complexes: insights into bilirubin-albumin binding

Bichromophoric (4Z, 15Z)-bilirubin-IX alpha, the yellow-orange cytotoxic pigment of jaundice, adopts either of two intramolecularly hydrogen-bonded enantiomeric conformations that are in dynamic equilibrium in solution. The addition of optically active amines induces the pigment solutions to exhibit intense bisignate circular dichroism in the region of the bilirubin long wavelength uv-visible absorption band. The most intense circular dichroism Cotton effects, (delta epsilon) approximately equal to 130, are induced by beta-arylamines and are comparable to those exhibited by bilirubin complexes with serum albumin and other proteins. Like serum albumin and other proteins, the optically active base acts as a chiral complexation agent to induce an asymmetric transformation of bilirubin, whose induced bisignate circular dichroism Cotton effect is characteristic of exciton splitting of the component pyrromethenone chromophores. The amines thus serve as chiral templates for molecular recognition, and the complementary action of the amine complexation sites provides insight into the binding forces important in protein-bilirubin heteroassociation.