Engineering aromaticL-amino acid transaminase for the asymmetric synthesis of constrained analogs ofL-phenylalanine

Cho, Byung-Kwan; Seo, Joo‐Hyun; Kang, Taehee; Kim, Juhan; Park, Hyung-Yeon; Lee, Bon-Su; Kim, Byung‐Gee

doi:10.1002/bit.20902

Cited by 19 publications

(8 citation statements)

References 42 publications

(67 reference statements)

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“…To select a template structure for the homology modeling, the primary structure of v-ATVf was compared with other aminotransferases using family profile analysis and sequence alignment (Eddy, 1998;Gribskov et al, 1987). The normalized log-odd score of v-ATVf calculated by the family profile of aminotransferase subgroup II (Cho et al, 2006;Mehta et al, 1993) showed a high positive value (profile score ¼ 194.4), whereas the values based on the family profiles of the other aminotransferase subgroups were negative values (profile score of subgroup I ¼ À197.2; profile score of subgroup III ¼ À198.6; profile score of subgroup IV ¼ À261.0). This result suggested that the v-ATVf is one of the aminotransferase subgroup II enzymes, whose members are ornithine aminotransferase (Orn-AT, EC 2.6.1.13), 4-aminobutyrate aminotransferase (GABA-AT, EC 2.6.1.19), DAPA aminotransferase (DAPA-AT, EC 2.6.1.62), glutamate-1-semialdehyde aminotransferase (GSA, EC 5.4.3.8), and 2,2-dialkylglycine decarboxylase (DGD, EC 4.1.1.64) (11,15,21,24).…”

Section: Resultsmentioning

confidence: 99%

Redesigning the substrate specificity of ω‐aminotransferase for the kinetic resolution of aliphatic chiral amines

Cho

Park

Seo

et al. 2007

Biotech & Bioengineering

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Substrate specificity of the omega-aminotransferase obtained from Vibrio fluvialis (omega-ATVf) was rationally redesigned for the kinetic resolution of aliphatic chiral amines. omega-ATVf showed unique substrate specificity toward aromatic amines with a high enantioselectivity (E > 100) for (S)-enantiomers. However, the substrate specificity of this enzyme was much narrower toward aliphatic amines. To overcome the narrow substrate specificity toward aliphatic amines, we redesigned the substrate specificity of omega-ATVf using homology modeling and the substrate structure- activity relationship. The homology model and the substrate structure-activity relationship showed that the active site of omega-ATVf consists of one large substrate-binding site and another small substrate-binding site. The key determinant in the small substrate-binding site was D25, whose role was expected to mask R415 and to generate the electrostatic repulsion with the substrate's alpha-carboxylate group. In the large substrate-binding site, R256 was predicted to recognize the alpha-carboxylate group of substrate thus obeying the dual substrate recognition mechanism of aminotransferase subgroup II enzymes. Among the several amino acid residues in the large substrate-binding site, W57 and W147, with their bulky side chains, were expected to restrict the recognition of aliphatic amines. Two mutant enzymes, W57G and W147G, showed significant changes in their substrate specificity such that they catalyzed transamination of a broad range of aliphatic amines without losing the original activities toward aromatic amines and enantioselectivity.

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Section: Resultsmentioning

confidence: 99%

Redesigning the substrate specificity of ω‐aminotransferase for the kinetic resolution of aliphatic chiral amines

Cho

Park

Seo

et al. 2007

Biotech & Bioengineering

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“…Moreover, transaminases allow asymmetric synthesis from prochiral ketone compounds depending upon the properties of target chemical compounds (1,4,10,11,17,49,50). Though transaminases are not widespread, we have reported an -transaminase of Alcaligenes denitrificans which can catalyze mainly the transamination between aliphatic ␤-amino acids and pyruvate (56).…”

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confidence: 99%

Cloning and Characterization of a Novel β-Transaminase fromMesorhizobiumsp. Strain LUK: a New Biocatalyst for the Synthesis of Enantiomerically Pure β-Amino Acids

Kim

Kyung

Yun

et al. 2007

Appl Environ Microbiol

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A novel ␤-transaminase gene was cloned from Mesorhizobium sp. strain LUK. By using N-terminal sequence and an internal protein sequence, a digoxigenin-labeled probe was made for nonradioactive hybridization, and a 2.5-kb gene fragment was obtained by colony hybridization of a cosmid library. Through Southern blotting and sequence analysis of the selected cosmid clone, the structural gene of the enzyme (1,335 bp) was identified, which encodes a protein of 47,244 Da with a theoretical pI of 6.2. The deduced amino acid sequence of the ␤-transaminase showed the highest sequence similarity with glutamate-1-semialdehyde aminomutase of transaminase subgroup II. The ␤-transaminase showed higher activities toward D-␤-aminocarboxylic acids such as 3-aminobutyric acid, 3-amino-5-methylhexanoic acid, and 3-amino-3-phenylpropionic acid. The ␤-transaminase has an unusually broad specificity for amino acceptors such as pyruvate and ␣-ketoglutarate/ oxaloacetate. The enantioselectivity of the enzyme suggested that the recognition mode of ␤-aminocarboxylic acids in the active site is reversed relative to that of ␣-amino acids. After comparison of its primary structure with transaminase subgroup II enzymes, it was proposed that R43 interacts with the carboxylate group of the ␤-aminocarboxylic acids and the carboxylate group on the side chain of dicarboxylic ␣-keto acids such as ␣-ketoglutarate and oxaloacetate. R404 is another conserved residue, which interacts with the ␣-carboxylate group of the ␣-amino acids and ␣-keto acids. The ␤-transaminase was used for the asymmetric synthesis of enantiomerically pure ␤-aminocarboxylic acids. (3S)-Amino-3-phenylpropionic acid was produced from the ketocarboxylic acid ester substrate by coupled reaction with a lipase using 3-aminobutyric acid as amino donor.

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“…with unknown structure and no substrate specificity toward aromatic amino acid analogs was used to synthesize the l-phenylalanine analog l-diphenylalanine. Based on the interaction of the substrate with the active site of the enzyme, site-directed mutagenesis can alter the substrate specificity of the transaminase toward substrates with bulky side chains [118].…”

Section: Protein Engineering By Rational Enzyme Designmentioning

confidence: 99%

Transaminases and their Applications

2016

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Engineering aromaticL-amino acid transaminase for the asymmetric synthesis of constrained analogs ofL-phenylalanine

Cited by 19 publications

References 42 publications

Redesigning the substrate specificity of ω‐aminotransferase for the kinetic resolution of aliphatic chiral amines

Redesigning the substrate specificity of ω‐aminotransferase for the kinetic resolution of aliphatic chiral amines

Cloning and Characterization of a Novel β-Transaminase fromMesorhizobiumsp. Strain LUK: a New Biocatalyst for the Synthesis of Enantiomerically Pure β-Amino Acids

Transaminases and their Applications

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