Structural and biochemical characterization of the dual substrate recognition of the (<i>R</i>)‐selective amine transaminase from <i>Aspergillus fumigatus</i>

Skalden, Lilly; Thomsen, Maren; Höhne, Matthias; Bornscheuer, Uwe T.; Hinrichs, W.

doi:10.1111/febs.13149

Cited by 31 publications

(34 citation statements)

References 39 publications

(62 reference statements)

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“…ATAs transfer an amino group of a chiral amine compound to a ketone compound using the cofactor pyridoxal 5’-phosphate (PLP) (Supplementary Fig. 1a) with a high turnover rate, stable catalytic activity, broad substrate specificity and excellent stereoselectivity7, which is achieved by a proposed large-binding pocket (L pocket) and small-binding pocket (S pocket) in the substrate-binding site8910111213141516 (Supplementary Fig. 1b).…”

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confidence: 99%

“…Up to now, several structures of S -ATAs9101112 and R -ATAs13141516 have been determined, providing some information about the dual substrate recognition30 of ATAs, which is a unique ability of transaminases to accept both the hydrophilic and hydrophobic substrates in the same active site. In the S -ATAs, a “flipping” arginine residue in a loop near the active site was proposed to play a key role in dual substrate recognition by moving the guanidino group in the active site to interact with the carboxylate of substrates or moving out of the active site to provide a hydrophobic environment9.…”

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confidence: 99%

“…In the S -ATAs, a “flipping” arginine residue in a loop near the active site was proposed to play a key role in dual substrate recognition by moving the guanidino group in the active site to interact with the carboxylate of substrates or moving out of the active site to provide a hydrophobic environment9. Recently, R -ATAs from Aspergillus terreus , Nectria haematococca and Aspergillus fumigatus were reported and an arginine residue near the active site was assumed to possess the similar function, binding carboxylated groups, as that in the S -ATAs141516.…”

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A new target region for changing the substrate specificity of amine transaminases

Guan

Ohtsuka

Okai

et al. 2015

Sci Rep

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(R)-stereospecific amine transaminases (R-ATAs) are important biocatalysts for the production of (R)-amine compounds in a strict stereospecific manner. An improved R-ATA, ATA-117-Rd11, was successfully engineered for the manufacture of sitagliptin, a widely used therapeutic agent for type-2 diabetes. The effects of the individual mutations, however, have not yet been demonstrated due to the lack of experimentally determined structural information. Here we describe three crystal structures of the first isolated R-ATA, its G136F mutant and engineered ATA-117-Rd11, which indicated that the mutation introduced into the 136th residue altered the conformation of a loop next to the active site, resulting in a substrate-binding site with drastically modified volume, shape, and surface properties, to accommodate the large pro-sitagliptin ketone. Our findings provide a detailed explanation of the previously reported molecular engineering of ATA-117-Rd11 and propose that the loop near the active site is a new target for the rational design to change the substrate specificity of ATAs.

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A new target region for changing the substrate specificity of amine transaminases

Guan

Ohtsuka

Okai

et al. 2015

Sci Rep

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“…Interestingly, a flexible loop (e.g. aa K125-I135 in AT-ωTA), which is present in ( R )-ATAs13151735 as part of the active site (the loop of chain B as part of the active site of chain A and vice versa containing an arginine residue, which is discussed to play a role in dual substrate recognition of ( R )-ATAs131535) is significantly shorter in Cpu TA1 (aa E125-G128) and does not contain any positively charged amino acid. Thus, the loop is located further away from the PLP binding site creating more space in the active site (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…6F). This loop changes its conformation from a closed to an open form upon binding of the inhibitor gabaculin in the ( R )-ATA of A. fumigatus 35 thereby moving R126 out of the active site, and due to high B-factors of the amino acid residues the loop is also expected to be flexible in AT-ωTA of A. terreus 15. Moreover, an altered conformation of the respective loop in ATA-117-Rd11 variant compared to its wildtype might be one of the reasons for its ability to accommodate the pro-sitagliptin ketone13.…”

Section: Resultsmentioning

confidence: 99%

Discovery and structural characterisation of new fold type IV-transaminases exemplify the diversity of this enzyme fold

Pavkov‐Keller

Strohmeier

Diepold

et al. 2016

Sci Rep

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Transaminases are useful biocatalysts for the production of amino acids and chiral amines as intermediates for a broad range of drugs and fine chemicals. Here, we describe the discovery and characterisation of new transaminases from microorganisms which were enriched in selective media containing (R)-amines as sole nitrogen source. While most of the candidate proteins were clearly assigned to known subgroups of the fold IV family of PLP-dependent enzymes by sequence analysis and characterisation of their substrate specificity, some of them did not fit to any of these groups. The structure of one of these enzymes from Curtobacterium pusillum, which can convert d-amino acids and various (R)-amines with high enantioselectivity, was solved at a resolution of 2.4 Å. It shows significant differences especially in the active site compared to other transaminases of the fold IV family and thus indicates the existence of a new subgroup within this family. Although the discovered transaminases were not able to convert ketones in a reasonable time frame, overall, the enrichment-based approach was successful, as we identified two amine transaminases, which convert (R)-amines with high enantioselectivity, and can be used for a kinetic resolution of 1-phenylethylamine and analogues to obtain the (S)-amines with e.e.s >99%.

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Transaminases – A Biosynthetic Route for Chiral Amines

Brundiek¹,

Höhne

2016

Applied Biocatalysis: From Fundamental Science to Industrial Applications

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Structural and biochemical characterization of the dual substrate recognition of the (R)‐selective amine transaminase from Aspergillus fumigatus

Cited by 31 publications

References 39 publications

A new target region for changing the substrate specificity of amine transaminases

A new target region for changing the substrate specificity of amine transaminases

Discovery and structural characterisation of new fold type IV-transaminases exemplify the diversity of this enzyme fold

Transaminases – A Biosynthetic Route for Chiral Amines

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