Summary
A novel strain, Microbacterium sp., which can be used as a catalyst in the asymmetric reduction of simple aromatic ketones to produce chiral aromatic alcohols, was isolated from soil by microbial screening. Using acetophenone as a model substrate for asymmetric reduction, 82 % reaction yield with more than 99 % enantiomeric excess of (R)-1-phenylethanol were achieved under the optimal conditions. Furthermore, the key reductase responsible for the asymmetric reduction was purified from the newly isolated Microbacterium sp. through (NH^sub 4^)^sub 2^S0^sub 4^ fractional precipitation, anion exchange chromatography and gel filtration chromatography. The purified reductase is a NADH-dependent aromatic ketone reductase. Gel filtration chromatography and SDS-PAGE results reveal that it is a homodimer with two 28-kDa subunits. The enzymatic properties of the reductase indicate that it is a highly efficient catalyst for the asymmetric reduction of simple aromatic ketone.
Key words: asymmetric reduction, Microbacterium sp., aromatic ketone reductase, acetophenone
(ProQuest: ... denotes formulae omitted.)
Introduction
Because of safety, therapeutical and regulatory concerns, there is an increasing interest in the development of a process capable of producing single-enantiomer pharmaceuticals (1). Usually, chiral building blocks, such as single-enantiomer alcohols and amines, are important intermediates in the construction of target chiral products. Due to the structural superiority, enantiopure aromatic alcohols are the key chiral building blocks for many important chiral pharmaceuticals, such as L-chlorpheniramine, S-fluoxetine, R-tomoxetine, R-denopamine, etc. (26). Asymmetric reduction of the corresponding prochiral simple aromatic ketones with chemical catalyst or biocatalyst is one of the most promising routes to the enantiopure aromatic alcohol production (7,8). Since 1980s, both biological and chemical methods have been developed to produce the chiral aromatic alcohols by this route (9-11). Compared with the chemical process, biological approach has many advantages, such as high enantioselectivity, mild reaction conditions and environmental compatibility (9,12).
Both whole-cell biocatalyst and isolated oxidoreductase from a microorganism are applied in this kind of biocatalytic asymmetric reduction. In recent research, more than 200 microbes, plants and microalgae have been reported for the production of various enantiopure alcohols through asymmetric reduction of the corresponding ketones (13-15). To discover the bioreduction reaction mechanism and evolve the key enzyme, many kinds of reductases have been purified from these microorganisms (16-21).
In our previous work, we devoted our efforts to exploring the asymmetric reduction of aromatic ketones and ß-ketoesters by microalgae, plant tissue and yeast (14,15,22). We also developed techniques to improve the asymmetric reduction processes by introducing resin adsorption and organic solvent-aqueous biphasic system (23-25). Furthermore, screening and obtaining an excellent microbe strain is always the most important and essential way to improve the asymmetric reduction. In this paper, we will devote our efforts to isolation of a novel microbe which can reduce prochiral simple aromatic ketones to produce enantiopure aromatic alcohols with high stereospecificity. Acetophenone was used as the model substrate for the asymmetric reduction. To determine the mechanism of this asymmetric reduction catalyzed by the microbe, the key reductase which is responsible for the asymmetric reduction was purified from the newly isolated microbe. Furthermore, the enzymatic properties of this reductase were also evaluated.
Materials and Methods
Materials and media
Acetophenone (ACP) and benzaldehyde were purchased from Sinopharm Chemical Reagent Co, Ltd (Shanghai, PR China), both of analytical grade. (R)-l-phenylethanol (R-PEA) and (S)-l-phenylethanol (S-PEA) were purchased from ACROS Organics (Thermo Fisher Scientific, Hoboken, NJ, USA), both of laboratory reagent grade. NADH disodium salt, dithiothreitol (DTT) and phenylmethylsulphonyl fluoride (PMSF) were purchased from Sigma-Aldrich (St. Louis, MO, USA). All other reagents were of analytical grade and commercially available. Materials for enzyme protein separation were purchased from GE Healthcare Life Sciences (Piscataway, NJ, USA).
The following media were used for microbe screening and cultivation: the medium used to enrich the microbe was composed of (in g/L): glucose 20.0, peptone 20.0, yeast extract 10.0, beef extract 30.0, KH2P04 2.0 and NaCl 1.0. Mineral salt medium (MSM) was used to screen the target microbe, and it was composed of (in g/L): (NH4)2S04 2.0, KH2P04 2.0, NaCl 1.0 and MgS04-7H20 0.2. Fermentation medium was used to cultivate the isolated microbe, and it was composed of (in g/L): glucose 15.0, yeast extract 5.0, peptone 5.0, KH2P04 1.0, K2HP04 1.0, NaCl 1.0, MgS04-7H20 0.5 and (NH4)2S04 2.0. All media were adjusted to pH=7.0 and autoclaved at 121 °C for 30 min. The corresponding solid media were prepared by supplementation with 2 % agar.
Screening the microbe for asymmetric reduction of ACP and microbe identification
The microorganisms for asymmetric reduction of ACP were isolated from a soil sample collected from Wuhan Botanical Garden (30°32'52" N, and 114°24'02" E, Wuhan, PR China). Soil sample (2.0 g) was suspended in 20 mL of sterile distilled water. Then, 0.2 mL of the supernatant were inoculated into 50 mL of enrichment medium and incubated in an orbital shaker operating at 150 rpm and 30 °C for 24 h. The enrichment broth was inoculated into the MSM plate (containing 0-5 g/L of glucose and 10-15 mmol/L of ACP) for the isolation of target microbe. The plates and a 25-mL glass beaker containing 10 mL of ACP were sealed in a plastic bag and incubated at 30 °C for 2 days. Colonies that appeared on the plate were inoculated individually into slant culture media (with fermentation medium) and cultured in an incubator for 1 day at 30 °C. Then different ACP-utilizing microorganisms were obtained and their ability as catalysts in the asymmetric reduction of simple aromatic ketones was assayed.
Morphological and physiological analyses of the isolated microbe were done according to the Bergey's Manual of Determinative Bacteriology (26). A light microscope was used to observe its morphological features. Genomic DNA for molecular identification of the strain was extracted using the modified benzyl chloride method (27). In order to identify the isolated microbe, the 16S rDNA was cloned by PCR. The PCR amplification of 16S rDNA was carried out in 25 pL of reaction mixture containing lOx Pfu reaction buffer (with Mg2+), 10 mmol/L of each deoxynucleoside triphosphate, 1.25 U of Pfu DNA polymerase (Tiangen Biotech, Beijing, PR China), 1.25 pmol/L of each forward primer (5'-GAGAGTTTGATCCTGGCTCAG-3') and reverse primer (5'-AAGGAGGTGATCCAGCC-3') and 50-100 ng of template DNA. The PCR reaction conditions were as follows: 5 min at 95 °C for initial dénaturation, 1 min at 94 °C for dénaturation, 1 min at 67 °C for annealing of DNA, 2 min at 72 °C for extension with total of 30 cycles of amplification and 10 min at 72 °C of final extension. The PCR-amplified products were purified by Gel Extraction kit (Omega Bio-Tek, Norcross, GA, USA) and sequenced by Sangon Biotech (Shanghai, PR China). The 16S rDNA was compared with sequences in nucleotide database (NCBI) using the BLAST algorithm (28). Multiple sequence alignment was carried out with CLUSTALW (Conway Institute UCD, Dublin, Ireland) multiple sequence alignment. The neighbour-joining phylogenetic analysis was constructed with MEGA v. 4.0 software (Center for Evolutionary Medicine and Informatics, The Biodesign Institute, Tempe, AZ, USA).
Microbial culture and asymmetric reduction
To obtain plenty of cells for the biocatalysis of the asymmetric reduction and enzyme separation and purification, the microbe was aerobically cultured in a 7-litre fermentar (BIOSTAT®A plus, Sartorius AG, Goettingen, Germany) with 5 L of fermentation medium for 24 h. The fermentor was operated at 30 °C, 300 rpm and pH= 7.0. The cells were harvested by centrifugation (10 000xg for 10 min, at 4 °C), and were washed with normal saline. Finally, the resting cells were conserved at -86 °C for enzyme separation and bioreduction.
Properties of this isolated microorganism as a biocatalyst for asymmetric reduction of ACP were also studied. The resting cells were used to investigate the effects of reduction conditions, such as temperature, pH, substrate concentration, cosubstrate and reaction time on the asymmetric reduction of ACP.
Key ketone reductase separation and purification procedure
The key ketone reductase, used for the asymmetric reduction of aromatic ketones, was separated and purified by cell-free extract, fractionation salting out, anion exchange chromatography and gel filtration chromatography. The anion exchange chromatography and gel filtration were performed with an AKTA prime chromatography system (GE Healthcare Life Sciences). All separation and purification steps were carried out at 4 °C. Detailed information for the separation and purification procedure is given in the Supplementary material SI.
Determination of the enzyme molecular mass
The molecular mass of the native enzyme was evaluated by gel filtration column chromatography using a Sephadex G-75 column with phosphate buffer containing 0.14 mol/L of NaCl as the mobile phase at a flow rate of 0.5 mL/min. The column was precalibrated with a standard protein ladder: bovine serum albumin (66.2 kDa), ovalbumin (43.0 kDa), protease K (28.5 kDa) and lysozyme (14.4 kDa).
The molecular mass of the subunit of the purified enzyme was determined by sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE) with an unstained SDS-PAGE molecular mass ladder (composed of seven standard proteins from 14.4 to 116 kDa) as the standard.
Evaluation of enzymatic properties
The following enzymatic properties of the purified ketone reductase were evaluated: cofactor requirement, the optimum pH and pH stability, the optimum temperature and thermal stability, effect of metal ions, and storage stability. The standard experimental procedure for the general evaluation of enzymatic properties was used.
Analysis of the reaction products
The concentrations of ACP, R-PEA and S-PEA were determined by a gas chromatography (GC) with a ß-cyclodextrin (Cyclodex B) chiral capillary chromatographic column. The GC analytical approach was the same as in our previous work (14,15). The reaction degree and the enantioselectivity were indicated by chemical yield and enantiomeric excess (e.e.), respectively, which were calculated as follows:
... /1/
... /2/
where cQ is initial substrate concentration, cP is final product concentration, cR is final R-PEA concentration, and cs is final S-PEA concentration.
Enzyme activity assay
The aromatic ketone reductase activity of ACP was assayed using spectrophotometrical method (29) based on the reduction of one molecule of ACP coupled with oxidation of one molecule of NADH to NAD+. NADH has a characteristic absorbance at 340 nm, therefore the decrease of the absorbance at 340 nm can represent the ketone reductase activity. The standard assay mixture contained 700 pL of phosphate buffer (0.1 mol/L, pH= 7.0), 5 mmol/L of ACP and 0.25 mmol/L of NADH. The mixture was preheated to 30 °C, and then the enzyme solution was added. The reaction mixture was monitored by absorbance decrease at 340 nm for 2 min with a spectrophotometer (Ultrospec 3300 Pro UV/VIS Spectrophotometer, GE Healthcare Life Sciences) using reaction kinetics application modules of SWIFT II software (GE Healthcare Life Sciences). One unit of the enzyme activity was defined as the amount of enzyme that catalyzed the oxidation of 1 pmol of NADH to NAD+ per minute, accompanied by the reduction of ACP. Specific activity was expressed as units per milligram of protein.
Protein content assay
Protein content was estimated by Bradford protein-dye binding method using bovine serum albumin as the protein standard (30).
Results and Discussion
Microbial screening and identification
The purpose of screening procedure was to obtain a microbial strain that possessed satisfactory catalytic activity and excellent stereoselectivity. Also, it should tolerate high concentrations of the substrate. With the novel screening procedure, a total of 18 microbial strains were obtained, which were able to reduce ACP to the corresponding chiral alcohol. In terms of yield and e.e., strain no. 1-2 was the best for the asymmetric reduction of simple aromatic ketone. The reaction yield and e.e. were more than 72 and 90 %, respectively. The superior enantiomer of the product is R-PEA, which demonstrates that the asymmetric reaction catalyzed by the newly isolated strain follows anti-Prelog rule.
To identify strain no. 1-2, its 16S rDNA region was cloned by PCR and sequenced. The nucleotide blast analysis was conducted in NCBI (28) to find homologous sequences. Fourteen corresponding sequences of representative species were selected and used to construct an unrooted phylogenetic tree (using MEGA v. 4.0 software). The 16S rDNA sequence and the unrooted phylogenetic tree are given in Supplementary material S2 and S3. The results show that strain no. 1-2 is a Microbacterium sp. Furthermore, the morphological and physiological identification experiments also confirm that the strain no. 1-2 is a Microbacterium sp. according to Bergey's Manual of Determinative Bacteriology (26). The morphological, physiological and biochemical data are given in Supplementary material S4. The newly isolated strain, Microbacterium sp., was deposited in the China Center for Type Culture Collection (CCTCC) with CCTCC Accession No. M 2011449. The 16S rDNA sequence of the newly isolated Microbacterium sp. was deposited at the GenBank database with the Accession No. JQ080914.
Asymmetric reduction of ACP with Microbacterium sp. resting cells
The reaction characteristics of asymmetric reduction of ACP catalyzed by the newly isolated Microbacterium sp. were determined. The effects of substrate concentration, reaction time, pH, temperature and cosubstrate on the asymmetric reduction of ACP were investigated.
The results in Fig. 1 show that these factors markedly affected the reaction yield. In all cases, the stereoselectivity was outstanding, and the e.e. was almost 100 %. The optimal reduction conditions were: 30 °C, pH=5.0, 15 mmol/L of ACP, reaction time of 30 h and 2-propanol as the cosubstrate. With the optimal reduction conditions, 82 % reaction yield and >99 % e.e. of R-PEA were achieved. The reaction followed anti-Prelog rule, which indicated that the novel Microbacterium sp. was an efficient biocatalyst for the asymmetric reduction of prochiral simple aromatic ketones. In previous report, Microbacterium sp. MA 5614 was able to produce MK-0476 (S)-hydroxy ester by asymmetric reduction of the corresponding keto ester (31). This indicates that Microbacterium sp. has a broad substrate range.
Purification of the ketone reductase from Microbacterium sp.
The reductase responsible for the asymmetric reduction of simple aromatic ketones was purified from the newly isolated Microbacterium sp. With the three complementary separation steps (fractional precipitation, anion exchange chromatography and gel filtration chromatography), it was purified 87.5-fold to a SDS-PAGE purity with a 29.9 % yield. The results of each separation step are given in Table 1. The SDS-PAGE of the purified ketone reductase is shown in Fig. 2.
Molecular mass of the enzyme
The molecular mass of the whole native aromatic ketone reductase is about 61.9 kDa as determined by gel filtration chromatography in comparison with the elution volume of standard proteins. The gel filtration chromatography data are given in Supplementary material S5. The molecular mass of the subunit is 28 kDa as determined by SDS-PAGE and presented in Fig. 2. According to the results of gel filtration chromatography and SDS-PAGE, it could be deduced that the Microbacterium sp. aromatic ketone reductase is a homodimer with two 28-kDa subunits. This result coincides with the ACP reductase from Geotrichum candidum NBRC 4597 (17), which consists of two 36-kDa identical subunits. In general, dehydrogenases and reductases are low-molecular-mass monomeric enzymes (32). However, many reported reductases consist of two subunits, such as carbonyl reductase from C. parapsilosis DSM 70125, which comprises two 67-kDa identical subunits (33), and heterodimeric carbonyl reductase from Geotrichum capitatum JCM 3908, which comprises a 39- and 41-kDa subunits (20).
Enzymatic properties
Coenzyme requirement
The coenzyme requirement for the purified reductase showed that the specific enzyme activity was about 16.3 U/mg with NADH as the coenzyme, whereas its activity was null with NADPH as the coenzyme. These results clearly indicate that the aromatic ketone reductase from Microbacterium sp. is NADH-dependent. The coenzyme requirement of other reported ketone reductases from various microorganisms were compared and listed in Table 2 (16,17,32,34-38). The results clearly show that the specific activity of the purified ketone reduc- tases from different microorganisms lies in a broad range from 0.89-590 U/mg. The disparity in the activity is due to their different microorganism source or protein structure.
Effect of pH
The effect of pH on the purified reductase activity is given in Fig. 3a with pH ranges from 4.0-9.0. In a broad pH range, from 6.0 to 9.0, this reductase showed good activity. The optimum pH was 7.0. However, the reductase activity rapidly decreased with pH decrease from 6.0 to 4.0. The optimum pH zone of the enzyme in a neutral pH was also observed for other carbonyl reductases from Geotrichum capitatum JCM 3908 (20) and Candida magnolia KFCC 11023 (39).
The pH stability of purified reductase was determined in a pH range from 3.0 to 9.0. The results are presented in Fig. 3b. It shows that the reductase was stable in pH= 6.0-8.0. The residual activity was able to keep more than 90 % in this pH range. The reductase stability sharply decreased when pH was lower than 6.0 or higher than 8.0, which proves that the reductase was sensitive to pH. A similar trend of the stability profile of reductases was observed with other reported carbonyl reductases such as those from Candida viswanathii MTCC 5158 (34) and Rhodococcus ruber DSM 44541 (40), which showed good stability at pH=6.5-7.0 and pH=6.0-7.0, respectively.
Effect of temperature
The effect of temperature on the reductase activity was investigated by measuring the enzyme activity at different temperatures (from 20 to 60 °C). The results are given in Fig. 4a. The optimum temperature was 40 °C, at which the reductase showed the highest enzymatic activity. Its activity rapidly increased with the increase of the reaction temperature from 20 to 40 °C. Further increase of the reaction temperature resulted in the decrease of reductase activity. Regarding the optimum temperature of the purified aromatic ketone reductase, it was similar to the carbonyl reductase from Rhodococcus erythropolis DSM 743 (41). However, it was different from the carbonyl reductases from Geotrichum candidum NCIM 980 (32), Candida viswanathii MTCC 5158 (34) and Rhodococcus ruber DSM 44541 (40); their optimum temperatures are about 50 to 65 °C. On the other hand, carbonyl reductases from Candida krusei SW 2026 (16) and Geotrichum capitatum JCM 3908 (20) showed lower optimum temperature, about 30 °C.
The thermal stability of the reductase was also evaluated. The preincubation temperature range was from 10 to 60 °C. The results in Fig. 4b demonstrate that this reductase is thermally stable. Although it was preincubated at 60 °C for 1 h, it still retained about 80 % residual activity. The good thermal stability indicated that this reductase possessed a good prospect for practical application.
Effect of metal ions
Cu2+, Ca2+, Fe2+, Zn2+, Mg2+ and Mn2+ were used to evaluate the effect of metal ions on the aromatic ketone reductase from Microbacterium sp. Also, EDTA was used to chelate the possible metal ion in the solution in order to find the effect of the absence of trace metal ions.
The experimental results (Table 3) show that Fe2+ could significantly improve the activity of the reductase, more than 30 %, while Cu2+ could remarkably inhibit the reductase activity, even cause a total loss of its activity. Generally, ketone reductases have thiol group at the catalytic site. Cu2+ is a thiol-specific ion, and it can bind with the group to deactivate its activity (32). With the addition of EDTA, the relative activity was just about 85 %, which proved that the reductase from Microbacterium sp. needed the metal ions to perform its highest activity.
Storage stability
Stability of the reductase from Microbacterium sp. was also measured. The results in Fig. 5 show that the enzyme possessed good storage stability. After 13.5 days at 4 °C, it still retained more than 80 % residual activity.
Conclusion
A novel Microbacterium sp. was isolated that can catalyze the asymmetric reduction of prochiral simple aromatic ketones with high catalytic activity and excellent enantioselectivity. Using acetophenone as a model substrate for asymmetric reduction, the reaction yield of 82 % and e.e. of 99 % were obtained under the optimal reaction conditions. The key reductase, which was responsible for the reduction, was purified from the newly isolated Microbacterium sp. It is a 61.9-kDa NADH-dependent dimeric reductase. The enzymatic properties show that it is an excellent reductase for the asymmetric reduction of simple aromatic ketones. Based on these findings, it can be concluded that this newly obtained microbe has a good prospect for practical application.
Acknowledgements
This work was partially supported by the Foundation of Educational Commission of Hubei Province of PR China (grant no. D20121108), the National Natural Science Foundation of China (grant no. 21376184), the open fund of Research Center of Green Manufacturing and Energy-Saving & Emission Reduction Technology at Wuhan University of Science and Technology (grant no. B1013) and the Key Youth Researcher fund of Wuhan University of Science and Technology (grant no. 2012XZ012), PR China. We are grateful to Ms Yu Wang, Mr Xiao-Hu Wang and Mr Xu Chang for their technical assistance.
Supplementary material
51. Aromatic ketone reductase separation and purification procedure
Step 1. Preparation of cell-free extract. Washed cells (6.0 g) were suspended in 10-mL buffer A (20 mM, pH=7.0, phosphate buffer) with 1 mM DTT and 1 mM PMSF. The cells were disrupted by ultrasonication (200-240 W, pulse 4 s, pause 7 s) for 30 min. Cell debris was removed by centrifugation (10 OOOxg for 25 min) at 4 °C. Then the clear supernatant, crude enzyme solution designated as cell-free extract (CFE) was obtained.
Step 2. Ammonium sulphate fractional precipitation. Initially, ammonium sulphate was added to the CFE to a final content of 50 % saturation and the mixture was settled at 4 °C for 1 h. The precipitate was removed by centrifugation (10 OOOxg for 25 min). The clear supernatant was subjected to increased concentration of ammonium sulphate to 70 % saturation. The solution was further settled for 1 h at 4 °C. The resulting precipitate was collected by centrifugation (10 OOOxg for 25 min). Then it was resuspended in buffer A and dialyzed against the same buffer containing 1 mM DTT at 4 °C overnight.
Step 3. Anion exchange chromatography. The dialyzed fraction was filtered through a 0.45-|.Lm micropore membrane, and loaded on a DEAE Sepharose Fast Flow column (1.6x20 cm, GE Healthcare Life Sciences) prebalanced with buffer A. The column was washed with buffer A. Then the enzyme was eluted with a linear gradient of NaCl (from 0 to 0.8 M) in the same buffer with a flow rate of 1 mL/min. Fractions containing aromatic ketone reductase activity were collected and concentrated with polyethylene glycol. The concentrated protein solution was dialyzed against buffer A containing 1 mM DTT at 4 °C overnight.
Step 4. Gel filtration chromatography. The dialyzed solution was then loaded on Sephadex G-75 column (1.6x70 cm). The column was balanced and eluted with buffer A mixed in 0.14 M NaCl until the basic line was plain. The active fraction was collected. It was a purified enzyme solution, which was used for the following enzyme characterization experiment.
52. 16S rDNA sequence of strain no. 1-2
S3. Unrooted phylogenetic tree
The unrooted phylogenetic tree was constructed based on the BLAST results from NCBI with the 16S rDNA sequences (28)
S4. Morphological, physiological and biochemical analyses of strain no. 1-2
S5. Standard curve of gel filtration chromatography to determine the ketone reductase molecular mass
Mr=molecular mass, kav=(Ve-Vo)/(Vt-Vo), Ve=elution volume, Vo-void volume, Vt=total liquid volume standard proteins: bovine serum albumin (66.2 kDa), ovalbumin (43.0 kDa), protease K (28.5 kDa), lysozyme (14.4 kDa)
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Li Luo1, Zhong-Hua Yang1*, Rong Zeng2*, Wei Zhou1, Yan Zhao1, Geng-Hua Chen1
and Hao Huang1
College of Chemical Engineering and Technology, Wuhan University of Science and Technology,
Wuhan 430081, PR China
o
College of Chemistry and Chemical Engineering, Hubei University, Wuhan 430062, PR China
Received: August 8, 2012
Accepted: November 6, 2012
^Corresponding author; Phone: ++86 27 8656 3448, ++86 27 6392 7637; E-mail: [email protected], [email protected]
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Copyright Sveuciliste u Zagrebu, Prehramheno-Biotehnoloski Fakultet 2013
Abstract
A novel strain, Microbacterium sp., which can be used as a catalyst in the asymmetric reduction of simple aromatic ketones to produce chiral aromatic alcohols, was isolated from soil by microbial screening. Using acetophenone as a model substrate for asymmetric reduction, 82 % reaction yield with more than 99 % enantiomeric excess of (R)-1-phenylethanol were achieved under the optimal conditions. Furthermore, the key reductase responsible for the asymmetric reduction was purified from the newly isolated Microbacterium sp. through (NH^sub 4^)^sub 2^S0^sub 4^ fractional precipitation, anion exchange chromatography and gel filtration chromatography. The purified reductase is a NADH-dependent aromatic ketone reductase. Gel filtration chromatography and SDS-PAGE results reveal that it is a homodimer with two 28-kDa subunits. The enzymatic properties of the reductase indicate that it is a highly efficient catalyst for the asymmetric reduction of simple aromatic ketone. [PUBLICATION ABSTRACT]
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