Hyungdon Yun

In Vivo Residue‐Specific Dopa‐Incorporated Engineered Mussel Bioglue with Enhanced Adhesion and Water Resistance

Misaminoacylation of 3,4-dihydroxyphenylalanine (Dopa) molecules to tRNA(Tyr) by endogenous tyrosyl-tRNA synthetase allowed the quantitative replacement of tyrosine residues with a yield of over 90u2009% by an inu2005vivo residue-specific incorporation strategy, to create, for the first time, engineered mussel adhesive proteins (MAPs) in Escherichia coli with a very high Dopa content, close to that of natural MAPs. The Dopa-incorporated MAPs exhibited a superior surface adhesion and water resistance ability by assistance of Dopa-mediated interactions including the oxidative Dopa cross-linking, and furthermore, showed underwater adhesive properties comparable to those of natural MAPs. These results propose promising use of Dopa-incorporated engineered MAPs as bioglues or adhesive hydrogels for practical underwater applications.

Unnatural amino acid mutagenesis-based enzyme engineering

Traditional enzyme engineering relies on substituting one amino acid by one of the other 19 natural amino acids to change the functional properties of an enzyme. However, incorporation of unnatural amino acids (UAAs) has been harnessed to engineer efficient enzymes for biocatalysis. Residue-specific and site-specific in vivo incorporation methods are becoming the preferred approach for producing enzymes with altered or improved functions. We describe the contribution of in vivo UAA incorporation methodologies to enzyme engineering as well as the future prospects for the field, including the integration of UAAs with other new advances in enzyme engineering.

Versatile biocatalysis of fungal cytochrome P450 monooxygenases

Cytochrome P450 (CYP) monooxygenases, the nature’s most versatile biological catalysts have unique ability to catalyse regio-, chemo-, and stereospecific oxidation of a wide range of substrates under mild reaction conditions, thereby addressing a significant challenge in chemocatalysis. Though CYP enzymes are ubiquitous in all biological kingdoms, the divergence of CYPs in fungal kingdom is manifold. The CYP enzymes play pivotal roles in various fungal metabolisms starting from housekeeping biochemical reactions, detoxification of chemicals, and adaptation to hostile surroundings. Considering the versatile catalytic potentials, fungal CYPs has gained wide range of attraction among researchers and various remarkable strategies have been accomplished to enhance their biocatalytic properties. Numerous fungal CYPs with multispecialty features have been identified and the number of characterized fungal CYPs is constantly increasing. Literature reveals ample reviews on mammalian, plant and bacterial CYPs, however, modest reports on fungal CYPs urges a comprehensive review highlighting their novel catalytic potentials and functional significances. In this review, we focus on the diversification and functional diversity of fungal CYPs and recapitulate their unique and versatile biocatalytic properties. As such, this review emphasizes the crucial issues of fungal CYP systems, and the factors influencing efficient biocatalysis.

Biochemical characterization of thermostable ω-transaminase from Sphaerobacter thermophilus and its application for producing aromatic β- and γ-amino acids.

An (S)-ω-transaminase from the thermophilic eubacterium Sphaerobacter thermophilus was expressed and functionally characterized. The enzyme showed good stability at high temperature and in the presence of various substrates. Substrate specificity analysis showed that the enzyme had activity towards a broad range of substrates including amines, β- and γ-amino acids. The purified enzyme showed a specific activity of 3.3U/mg towards rac-β-phenylalanine at 37°C. The applicability of this enzyme as an attractive biocatalyst was demonstrated by synthesizing optically pure β- and γ-amino acids. Among the various beta and gamma amino acids produced via asymmetric synthesis, (S)-4-amino-4-(4-methoxyphenyl)-butanoic acid showed highest analytical yield (82%) with excellent enantiomeric excess (>99%).

Fungal cytochrome P450 monooxygenases of Fusarium oxysporum for the synthesis of ω-hydroxy fatty acids in engineered Saccharomyces cerevisiae

BackgroundOmega hydroxy fatty acids (ω-OHFAs) are multifunctional compounds that act as the basis for the production of various industrial products with broad commercial and pharmaceutical implications. However, the terminal oxygenation of saturated or unsaturated fatty acids for the synthesis of ω-OHFAs is intricate to accomplish through chemocatalysis, due to the selectivity and controlled reactivity in C-H oxygenation reactions. Cytochrome P450, the ubiquitous enzyme is capable of catalyzing the selective terminal omega hydroxylation naturally in biological kingdom.ResultsTo gain a deep insight on the biochemical role of fungal P450s towards the production of omega hydroxy fatty acids, two cytochrome P450 monooxygenases from Fusarium oxysporum (FoCYP), FoCYP539A7 and FoCYP655C2; were identified, cloned, and heterologously expressed in Saccharomyces cerevisiae. For the efficient production of ω-OHFAs, the S. cerevisiae was engineered to disrupt the acyl-CoA oxidase enzyme and the β-oxidation pathway inactivated (ΔPox1) S. cerevisiae mutant was generated. To elucidate the significance of the interaction of redox mechanism, FoCYPs were reconstituted with the heterologous and homologous reductase systems - S. cerevisiae CPR (ScCPR) and F. oxysporum CPR (FoCPR). To further improve the yield, the effect of pH was analyzed and the homologous FoCYP-FoCPR system efficiently hydroxylated caprylic acid, capric acid and lauric acid into their respective ω-hydroxy fatty acids with 56%, 79% and 67% conversion. Furthermore, based on computational simulations, we identified the key residues (Asn106 of FoCYP539A7 and Arg235 of FoCYP655C2) responsible for the recognition of fatty acids and demonstrated the structural insights of the active site of FoCYPs.ConclusionFungal CYP monooxygenases, FoCYP539A7 and FoCYP655C2 with its homologous redox partner, FoCPR constitutes a promising catalyst due to its high regio- and stereo-selectivity in the hydroxylation of fatty acids and in the substantial production of industrially valuable ω-hydroxy fatty acids.

Engineering Transaminase for Stability Enhancement and Site‐Specific Immobilization through Multiple Noncanonical Amino Acids Incorporation

In general, conventional enzyme engineering utilizes 20 canonical amino acids to alter and improve the functional properties of proteins such as stability, and activity. In this study, we utilized the noncanonical amino acid incorporation technique to enhance the functional properties of ω‐transaminase (ω‐TA). Herein, we enhanced the stability of ω‐TA by residue‐specific incorporation of (4R)‐fluoroproline [(4R)‐FP] and successfully immobilized onto chitosan or polystyrene (PS) beads with site‐specifically incorporated L‐3,4‐dihydroxyphenylalanine (DOPA) moiety. The immobilization of ω‐TAdopa and ω‐TAdp[(4R)‐FP] onto PS beads showed excellent reusability for 10 cycles in the kinetic resolution of chiral amines. Compared to the ω‐TAdopa, the ω‐TAdp[(4R)‐FP] immobilized onto PS beads exerted more stability that can serve as suitable biocatalyst for the asymmetric synthesis of chiral amines.

Incorporating unnatural amino acids to engineer biocatalysts for industrial bioprocess applications.

The bioprocess engineering with biocatalysts broadly spans its development and actual application of enzymes in an industrial context. Recently, both the use of bioprocess engineering and the development and employment of enzyme engineering techniques have been increasing rapidly. Importantly, engineering techniques that incorporate unnatural amino acids (UAAs) in vivo has begun to produce enzymes with greater stability and altered catalytic properties. Despite the growth of this technique, its potential value in bioprocess applications remains to be fully exploited. In this review, we explore the methodologies involved in UAA incorporation as well as ways to synthesize these UAAs. In addition, we summarize recent efforts to increase the yield of UAA engineered proteins in Escherichia coli and also the application of this tool in enzyme engineering. Furthermore, this protein engineering tool based on the incorporation of UAA can be used to develop immobilized enzymes that are ideal for bioprocess applications. Considering the potential of this tool and by exploiting these engineered enzymes, we expect the field of bioprocess engineering to open up new opportunities for biocatalysis in the near future.

Engineering class I cytochrome P450 by gene fusion with NADPH-dependent reductase and S. avermitilis host development for daidzein biotransformation

Daidzein C6 hydroxylase (6-DH, nfa12130), which is a class I type of cytochrome P450 enzyme, catalyzes a hydroxylation reaction at the C6-position of the daidzein A-ring and requires auxiliary electron transfer proteins. Current utilization of cytochrome P450 (CYP) enzymes is limited by low coupling efficiency, which necessitates extramolecular electron transfers, and low driving forces, which derive electron flows from tightly regulated NADPH redox balances into the heterogeneous CYP catalytic cycle. To overcome such limitations, the heme domain of the 6-DH enzyme was genetically fused with the NADPH-reductase domain of self-sufficient CYP102D1 to enhance electron transfer efficiencies through intramolecular electron transfer and switching cofactor preference from NADH into NADPH. 6-DH-reductase fusion enzyme displayed distinct spectral properties of both flavoprotein and heme proteins and catalyzed daidzein hydroxylation more efficiently with a kcat/Km value of 120.3u2009±u200911.5 [103xa0M−1xa0s−1], which was about three times higher than that of the 6-DH-FdxC-FdrA reconstituted system. Moreover, to obtain a higher redox driving force, a Streptomyces avermitilis host system was developed for heterologous expression of fusion 6-DH enzyme and whole cell biotransformation of daidzein. The whole cell reaction using the final recombinant strain, S. avermitilisΔcyp105D7::fusion 6-DH (nfa12130), resulted in 8.3u2009±u20091.4xa0% of 6-OHD yield from 25.4xa0mg/L of daidzein.

Asymmetric synthesis of aromatic β-amino acids using ω-transaminase: Optimizing the lipase concentration to obtain thermodynamically unstable β-keto acids

Synthesized aromatic β‐amino acids have recently attracted considerable attention for their application as precursors in many pharmacologically relevant compounds. Previous studies on asymmetric synthesis of aromatic β‐amino acids using ω‐transaminases could not be done efficiently due to the instability of β‐keto acids. In this study, a strategy to circumvent the instability problem of β‐keto acids was utilized to generate β‐amino acids efficiently via asymmetric synthesis. In this work, thermodynamically stable β‐ketoesters were initially converted to β‐keto acids using lipase, and the β‐keto acids were subsequently aminated using ω‐transaminase. By optimizing the lipase concentration, we successfully overcame the instability problem of β‐keto acids and enhanced the production of β‐amino acids. This strategy can be used as a general approach to efficiently generate β‐amino acids from β‐ketoesters.

Production of chiral β-amino acids using ω-transaminase from Burkholderia graminis

Optically pure β-amino acids are of high pharmacological significance since they are used as key ingredients in many physiologically active compounds. Despite a number of enzymatic routes to these compounds, an efficient synthesis of β-amino acids continues to pose a major challenge for researchers. ω-Transaminase has emerged as an important class of enzymes for generating amine compounds. However, only a few ω-transaminases have been reported so far which show activity towards aromatic β-amino acids. In this study, (S)-ω-transaminase from Burkholderia graminis C4D1M has been functionally characterized and used for the production of chiral aromatic β-amino acids via kinetic resolution. The enzyme showed a specific activity of 3.1 U/mg towards rac-β-phenylalanine at 37°C. The Km and Kcat values of this enzyme towards rac-β-phenylalanine with pyruvate as the amino acceptor were 2.88 mM and 91.57 min(-1) respectively. Using this enzyme, racemic β-amino acids were kinetically resolved to produce (R)-β-amino acids with an excellent enantiomeric excess (> 99%) and ∼ 50% conversion. Additionally, kinetic resolution of aromatic β-amino acids was performed using benzaldehyde as a cheap amino acceptor.