Gene_locus Report for: aspng-q1ktb5

Only a few known epoxide hydrolases (EHs) displayed activity towards o-nitrostyrene oxide (4a), presumably owing to the large steric hindrance caused by o-nitro substituent. Therefore, excavating EHs with high activity and enantio- and/or regio-selectivity towards racemic (rac-) 4a is essential but challenging. Here, AuEH2 from Aspergillus usamii was expressed in E. coli BL21(DE3). E. coli/Aueh2, an E. coli transformant expressing AuEH2, possessed EH activities of 16.2-184 U/g wet cell towards rac-styrene oxide (1a) and its derivatives (2a-13a), and the largest enantiomeric ratio of 96 towards rac-4a. The regioselectivity coefficients, beta(R) and beta(S), of AuEH2 were determined to be 99.2% and 98.9%, suggesting that it regiopreferentially attacks the C(beta) in the oxirane rings of (R)- and (S)-4a. Then, the nearly perfect kinetic resolution of 20 mM rac-4a in pure water was carried out using 20 mg/mL wet cells of E. coli/Aueh2 at 25 degreesC for 50 min, retaining (S)-4a with over 99% ee(s) and 48.9% yield(s), while producing (R)-o-nitrophenyl-1,2-ethanediol (4b) with 95.3% ee(p) and 49.8% yield(p). To elucidate the molecular mechanism of AuEH2 with high enantiopreference for (R)-4a, its crystal structure was solved by X-ray diffraction and the molecular docking of AuEH2 with (R)- or (S)-4a was simulated.

Microtuning the substrate-binding pocket (SBP) of EHs has emerged as an effective approach to manipulate their enantio- or regio-selectivities and activities towards target substrates. Here, the enantioselectivity (enantiomeric ratio, E) of AuEH2 towards a racemic (rac-) ortho-trifluoromethyl styrene oxide (o-TFMSO) was improved via microtuning its SBP. Based on the analysis on the crystal structure of AuEH2, its specific residues I192, Y216, R322 and L344 lining the SBP in close to the catalytic triad were identified for site-saturation mutagenesis. After screening, five single-site mutants were selected with E values elevated from 8 to 12-25 towards rac-o-TFMSO. To further improve E, four double-site mutants were constructed by combinatorial mutagenesis of AuEH2(R322V) separately with AuEH2(I192V), AuEH2(Y216F), AuEH2(L344A) and AuEH2(L344C). Among all the mutants, AuEH2(R322V/L344C) possessed the largest E of 83 with activity of 67 U/g wet cell. The kinetic resolution of 200 mM rac-o-TFMSO was conducted at 0 degreesC for 5.5 h using 80 mg/mL wet cells of E. coli/Aueh2(R322V/L344C), a transformant expressing AuEH2(R322V/L344C), retaining (S)-o-TFMSO with 98.4 % ee(s) and 49.3 % yield(s). Furthermore, the molecular docking simulation analysis indicated that AuEH2(R322V/L344C) more enantiopreferentially attacks the terminal carbon (C(beta)) in the oxirane ring of (R)-o-TFMSO than AuEH2.

OBJECTIVES: To prepare (R)-phenyl-1,2-ethanediol ((R)-PED) with high enantiomeric excess (ee p) and yield from racemic styrene oxide (rac-SO) at high concentration by bi-enzymatic catalysis.
RESULTS: The bi-enzymatic catalysis was designed for enantioconvergent hydrolysis of rac-SO by a pair of novel epoxide hydrolases (EHs), a Vigna radiata EH3 (VrEH3) and a variant (AuEH2A250I) of Aspergillus usamii EH2. The simultaneous addition mode of VrEH3 and AuEH2A250I, exhibiting the highest average turnover frequency (aTOF) of 0.12 g h-1 g-1, was selected, by which rac-SO (10 mM) was converted into (R)-PED with 92.6% ee p and 96.3% yield. Under the optimized reaction conditions: dry weight ratio 14:1 of VrEH3-expressing E. coli/vreh3 to AuEH2A250I-expressing E. coli/Aueh2 A250I and reaction at 20 degrees C, rac-SO (10 mM) was completely hydrolyzed in 2.3 h, affording (R)-PED with 98% ee p. At the weight ratio 0.8:1 of rac-SO to two mixed dry cells, (R)-PED with 97.4% ee p and 98.7% yield was produced from 200 mM (24 mg/ml) rac-SO in 10.5 h.
CONCLUSIONS: Enantioconvergent hydrolysis of rac-SO at high concentration catalyzed by both VrEH3 and AuEH2A250I is an effective method for preparing (R)-PED with high ee p and yield.

Structure-guided microtuning of an Aspergillus usamii epoxide hydrolase was executed. One mutant, A214C/A250I, displayed a 12.6-fold enhanced enantiomeric ratio (E = 202) toward rac-styrene oxide, achieving its nearly perfect kinetic resolution at 0.8 M in pure water or 1.6 M in n-hexanol/water. Several other beneficial mutants also displayed significantly improved E values, offering promising biocatalysts to access 19 structurally diverse chiral monosubstituted epoxides (97.1 - <= 99% ee(s)) and vicinal diols (56.2-98.0% ee(p)) with high yields.

Only a few known epoxide hydrolases (EHs) displayed activity towards o-nitrostyrene oxide (4a), presumably owing to the large steric hindrance caused by o-nitro substituent. Therefore, excavating EHs with high activity and enantio- and/or regio-selectivity towards racemic (rac-) 4a is essential but challenging. Here, AuEH2 from Aspergillus usamii was expressed in E. coli BL21(DE3). E. coli/Aueh2, an E. coli transformant expressing AuEH2, possessed EH activities of 16.2-184 U/g wet cell towards rac-styrene oxide (1a) and its derivatives (2a-13a), and the largest enantiomeric ratio of 96 towards rac-4a. The regioselectivity coefficients, beta(R) and beta(S), of AuEH2 were determined to be 99.2% and 98.9%, suggesting that it regiopreferentially attacks the C(beta) in the oxirane rings of (R)- and (S)-4a. Then, the nearly perfect kinetic resolution of 20 mM rac-4a in pure water was carried out using 20 mg/mL wet cells of E. coli/Aueh2 at 25 degreesC for 50 min, retaining (S)-4a with over 99% ee(s) and 48.9% yield(s), while producing (R)-o-nitrophenyl-1,2-ethanediol (4b) with 95.3% ee(p) and 49.8% yield(p). To elucidate the molecular mechanism of AuEH2 with high enantiopreference for (R)-4a, its crystal structure was solved by X-ray diffraction and the molecular docking of AuEH2 with (R)- or (S)-4a was simulated.

Microtuning the substrate-binding pocket (SBP) of EHs has emerged as an effective approach to manipulate their enantio- or regio-selectivities and activities towards target substrates. Here, the enantioselectivity (enantiomeric ratio, E) of AuEH2 towards a racemic (rac-) ortho-trifluoromethyl styrene oxide (o-TFMSO) was improved via microtuning its SBP. Based on the analysis on the crystal structure of AuEH2, its specific residues I192, Y216, R322 and L344 lining the SBP in close to the catalytic triad were identified for site-saturation mutagenesis. After screening, five single-site mutants were selected with E values elevated from 8 to 12-25 towards rac-o-TFMSO. To further improve E, four double-site mutants were constructed by combinatorial mutagenesis of AuEH2(R322V) separately with AuEH2(I192V), AuEH2(Y216F), AuEH2(L344A) and AuEH2(L344C). Among all the mutants, AuEH2(R322V/L344C) possessed the largest E of 83 with activity of 67 U/g wet cell. The kinetic resolution of 200 mM rac-o-TFMSO was conducted at 0 degreesC for 5.5 h using 80 mg/mL wet cells of E. coli/Aueh2(R322V/L344C), a transformant expressing AuEH2(R322V/L344C), retaining (S)-o-TFMSO with 98.4 % ee(s) and 49.3 % yield(s). Furthermore, the molecular docking simulation analysis indicated that AuEH2(R322V/L344C) more enantiopreferentially attacks the terminal carbon (C(beta)) in the oxirane ring of (R)-o-TFMSO than AuEH2.

OBJECTIVES: To prepare (R)-phenyl-1,2-ethanediol ((R)-PED) with high enantiomeric excess (ee p) and yield from racemic styrene oxide (rac-SO) at high concentration by bi-enzymatic catalysis.
RESULTS: The bi-enzymatic catalysis was designed for enantioconvergent hydrolysis of rac-SO by a pair of novel epoxide hydrolases (EHs), a Vigna radiata EH3 (VrEH3) and a variant (AuEH2A250I) of Aspergillus usamii EH2. The simultaneous addition mode of VrEH3 and AuEH2A250I, exhibiting the highest average turnover frequency (aTOF) of 0.12 g h-1 g-1, was selected, by which rac-SO (10 mM) was converted into (R)-PED with 92.6% ee p and 96.3% yield. Under the optimized reaction conditions: dry weight ratio 14:1 of VrEH3-expressing E. coli/vreh3 to AuEH2A250I-expressing E. coli/Aueh2 A250I and reaction at 20 degrees C, rac-SO (10 mM) was completely hydrolyzed in 2.3 h, affording (R)-PED with 98% ee p. At the weight ratio 0.8:1 of rac-SO to two mixed dry cells, (R)-PED with 97.4% ee p and 98.7% yield was produced from 200 mM (24 mg/ml) rac-SO in 10.5 h.
CONCLUSIONS: Enantioconvergent hydrolysis of rac-SO at high concentration catalyzed by both VrEH3 and AuEH2A250I is an effective method for preparing (R)-PED with high ee p and yield.

Using the cell-free extract of engineered E. coli/Aueh2, expressing the recombinant Aspergillus usamii epoxide hydrolase (reAuEH2), as a biocatalyst, the kinetic resolution technique of racemic styrene oxide (rac-SO) was examined. In a phosphate buffer system (50mM, pH 7.0), 200mM rac-SO was efficiently resolved, obtaining (S)-SO with 98.1% enantiomeric excess (e.e.), whereas (S)-SO only with 45.2% e.e. was obtained from 750mM rac-SO. The analytical results verified that reAuEH2 shows tolerance towards high substrate concentration but is inactivated at a product concentration of 300mM. To produce (S)-SO with the high concentration, e.e. and volumetric productivity, n-hexanol was selected from a variety of water-miscible and water-immiscible organic solvents to construct an n-hexanol/buffer biphasic system. The optimal phase volume ratio, substrate over enzyme ratio and temperature were 1:1 (v/v), 6:1 (w/w) and 25 degrees C, respectively. In an optimized biocatalytic system, a gram-scale resolution of rac-SO at a high concentration of 1M (120g/L) was performed at 25 degrees C for 2h, obtaining (S)-SO with 98.2% e.e., 34.3% yield (maximum yield of 50%). The substrate concentration and volumetric productivity (1M, 20.6g/L/h) in a biphasic system significantly increased compared with those (0.2M, 3.1g/L/h) in a phosphate buffer system. The efficient resolution of rac-SO at a high concentration in a biphasic system makes it a promising technique for preparing a highly value-added enantiopure (S)-SO with high volumetric productivity.

The full-length cDNA sequence of Aueh2, a gene encoding an epoxide hydrolase of Aspergillus usamii E001 (abbreviated to AuEH2), was amplified from the total RNA. Synchronously, the complete DNA sequence containing 5', 3' flanking regions, eight exons and seven introns was cloned from the genomic DNA. In addition, a cDNA fragment of Aueh2 encoding a 395-aa AuEH2 was expressed in Escherichia coli. The catalytic activity of recombinant AuEH2 (re-AuEH2) was 1.44 U/ml using racemic styrene oxide (SO) as the substrate. The purified re-AuEH2 displayed the maximum activity at pH 7.0 and 35 degrees C. It was highly stable at a pH range of 5.0-7.5, and at 40 degrees C or below. Its activity was not obviously influenced by beta-mercaptoethanol, EDTA and most of metal ions tested, but was inhibited by Hg(2+), Sn(2+), Cu(2+), Fe(3+) and Zn(2+). The K m and V max of re-AuEH2 were 5.90 mM and 20.1 U/mg towards (R)-SO, while 7.66 mM and 3.19 U/mg towards (S)-SO. Its enantiomeric ratio (E) for resolution of racemic SO was 24.2 at 10 degrees C. The experimental result of re-AuEH2 biasing towards (R)-SO was consistent with the analytical one by molecular docking (MD) simulation.