Screening carbonyl reductases with the ability to catalyze the reduction of complex carbonyl compounds is of great significance for the biosynthesis of R-tolvaptan(R-TVP). In this study, the target carbonyl reductase in the crude enzyme extract of rabbit liver was separated, purified, and identified by ammonium sulfate precipitation, gel-filtration chromatography, ion exchange chromatography, affinity chromatography, and protein mass spectrometry. With the rabbit liver genome as the template, the gene encoding the carbonyl reductase rlsr5 was amplified by PCR and the recombinant strain was successfully constructed. After RLSR5 was purified by affinity chromatography, its enzymatic properties were characterized. The results indicated that the gene sequence of rlsr5 was 972 bp, encoding a protein with a molecular weight of 40 kDa. RLSR5 was a dimeric protein, and each monomer was composed of a (α/β)₈-barrel structure. RLSR5 could asymmetrically reduce 7-chloro-1-[2-methyl-4-[(2- methylbenzoyl)amino]benzoyl]-5-oxo-2,3,4,5-tetrahydro-1H-1-benzazepine (prochiral ketone, PK) to synthesize R-TVP. The specific activity of the enzyme was 36.64 U/mg, and the optical purity of the product was 99%. This enzyme showcased the optimal performance at pH 6.0 and 30 °C. It was independent of metal ions, with the activity enhanced by Mn²⁺. This study lays a foundation for the biosynthesis of tolvaptan of optical grade.
Animals ; Rabbits ; Alcohol Oxidoreductases/biosynthesis* ; Recombinant Proteins/metabolism* ; Escherichia coli/metabolism* ; Liver/enzymology*

Carbonyl reductases catalyze carbonyl compounds to chiral alcohols that are important building blocks in fine chemical industry. To study carbonyl reductase from Pichia pastoris GS115 (ppcr), we discovered a new gene (ppcr) encoding an NADPH-dependent carbonyl reductase by genomic data mining. It was amplified by PCR from the genomic DNA, and expressed in Escherichia coli BL21 (DE3). The recombinant protein was purified to homogeneity. The optimum temperature was 37 degrees C and the optimum pH of PPCR was 6.0. PPCR was stable below 45 degrees C. The Km and k(cat) value of the enzyme for ethyl 3-methyl-2-oxobutanoate were 9.48 mmol/L and 0.12 s, respectively. The enzyme had broad substrate specificity and high enantioselectivity. It catalyzed the reduction of aldehydes, a-ketoesters, beta-ketoesters and aryl ketones to give the corresponding alcohols with >97% ee with only a few exceptions, showing its application potential in the synthesis of chiral alcohols.
Alcohol Oxidoreductases ; biosynthesis ; chemistry ; genetics ; Amino Acid Sequence ; Biotechnology ; methods ; Cloning, Molecular ; Escherichia coli ; genetics ; metabolism ; Molecular Sequence Data ; Pichia ; enzymology ; Recombinant Proteins ; biosynthesis ; chemistry ; genetics ; Stereoisomerism ; Substrate Specificity ; Temperature

In order to successfully express the carbonyl reductase gene mldh in Bacillus subtilis and complete coenzyme regeneration by B. subtilis glucose dehydrogenase, the promoter PrpsD and the terminator TrpsD from B. subtilis rpsD gene were used as the expression cassette to be a recombinant plasmid pHY300plk-PrpsD-TrpsD. After that, the carbonyl reductase gene mldh was inserted into the previous plasmid and a plasmid pHY300plk-PrpsD-mldh-TrpsD was achieved, followed by transformed into B. subtilis Wb600 to obtain a recombinant B. subtilis Wb600 (pHY300plk-PrpsD-mldh-TrpsD). Subsequently, the results for whole-cell biotransformation from recombinant B. subtilis showed that it could be used to catalyze MAK (1-phenyl- 1-keto-2-methylaminopropane) to d-pseudoephedrine in the presence of glucose. The yield of d-pseudoephedrine could be up to 97.5 mg/L and the conversion rate of MAK was 24.1%. This study indicates the possibility of biotransformation production of d-pseudoephedrine from recombinant B. subtilis.
Alcohol Oxidoreductases ; genetics ; Bacillus subtilis ; genetics ; metabolism ; Glucose 1-Dehydrogenase ; chemistry ; metabolism ; Mutagenesis, Insertional ; Pseudoephedrine ; metabolism ; Recombinant Proteins ; biosynthesis ; genetics ; Recombination, Genetic

To improve the expression level and catalytic efficiency of (R)-carbonyl reductase from Candida parapsilosis in Escherichia coli, we optimized the mRNA secondary structure of (R)-carbonyl reductase gene in translation initiation region (from +1 to +78), and constructed the corresponding variant. The formation of hairpin structure was significantly reduced and the Gibbs free energy was dramatically decreased from -9.5 kcal/mol to -5.0 kcal/mol after optimization. As a result, the expression level of (R)-carbonyl reductase in the variant was increased by 4-5 times and its specific activity in cell-free extract was enhanced by 61.9% compared to the wild-type strain. When using the whole cells as catalyst and 2-hydroxyacetophenone as substrate with a high concentration of 5.0 g/L, the variant showed excellent performance to give (R)-1-phenyl-1, 2-ethanediol with optical purity of 93.1% enantiomeric excess and a yield of 81.8%, which were increased by 27.5% and 40.5% respectively than those of the wild-type. In conclusion, the optimization of mRNA secondary structure in translation initiation region can overcome the steric hindrance of translation startup, promote translation smoothly to acquire high expression of target protein, and favor protein folding correctly to efficiently improve the enzyme specific activity and biotransformation function.
Alcohol Oxidoreductases ; biosynthesis ; chemistry ; genetics ; Base Sequence ; Biocatalysis ; Candida ; enzymology ; Catalysis ; Escherichia coli ; genetics ; metabolism ; Molecular Sequence Data ; Mutant Proteins ; genetics ; Nucleic Acid Conformation ; Peptide Chain Initiation, Translational ; RNA, Messenger ; chemistry ; Recombinant Proteins ; biosynthesis ; genetics ; Stereoisomerism

Using response surface method, we optimized the medium for the asymmetric whole cell biotransformation by Candida tropicalis 104. This strain was used for microbial reduction of 1-[3,5-bis(trifluoromethyl)phenyl] ethanone to (S)-l-[3,5-bis(trifluoromethyl)phenyl] alcohol, with enantiomeric excess(e.e.) reached more than 99.9%. Fractional factorial design was used to evaluate the effects of medium components on carbonyl reductase activity of Candida tropicalis 104. Yeast extract, glucose and NH4Cl were the most important factors among six tested variables that influence the enzyme activity for the biotransformation process. Based on the experimental results, the path of steepest ascent was undertaken to approach the optimal region of these factors. Central composite design and response surface analysis were subsequently employed for further optimization. The optimal medium for Candida tropicalis 104 was composed of (in g/L): glucose 47.14, yeast extract 13.25, NH4Cl 2.71, MgSO4.7H2O 0.4, KH2PO4 1, K2HPO4 1. Under the optimum conditions, the maximum enzyme activity of 852.75 U/L in theory and 851.13 U/L in the experiment were obtained, with an increase of 65.2% compared to the original medium components.
Alcohol Oxidoreductases ; biosynthesis ; metabolism ; Ammonium Chloride ; pharmacology ; Candida tropicalis ; growth & development ; metabolism ; Culture Media ; Fermentation ; Models, Theoretical

OBJECTIVETo study the activities of the key enzymes in reteplase production by Pichia pastoris.

METHODSIn shaking flasks, a series of samples were maintained after methanol induction. The cells were sonicated to prepare cell-free suspensions, in which the activities of AOX, FAD, PDC, G-6-PD, ID, alpha-KGD and SD were measured.

RESULTSThe specific activity of AOX increased during the initial 6 h, reaching the maximum of 44.5 U/mg protein. The activity decreased quickly between 6 and 24 h, followed by increment in the following 24 h and decreased afterwards. The specific activity of FAD increased gradually in the initial 48 h and then decreased, with the peak level of 6.72 U/mg protein occurred at 48 h. The specific activity of G-6-PD increased at in 2-6 h and 24-48 h, but decreased in 6-24 h and after 48 h. The specific activity of PDC decreased during the initial 6 h and increased slowed afterwards. The specific activities of ID, alpha-KGD and SD all showed a rapid decrease in the initial 6 h and a slow decrease in 6-24 h. After 24 h, the activity of ID continued to decrease, but the other two increased in the following 24 h and then decreased, reaching the maximum at 48 h.

CONCLUSIONSAccording to the changes of these enzyme activities, the whole induction phase can be divided into 4 stages: the methanol-adaptive period in the initial 6 h, the fast growth period between 6 and 24 h, the product accumulation period in 24-48 h and the metabolism lag period in 48-72 h. In the methanol-adaptive period, complete oxidation of methanol is the dominant pathway. But in the following two stages, the metabolic pathway shifts towards glycolysis and TCA cycle.

Alcohol Oxidoreductases ; metabolism ; Fermentation ; Genetic Vectors ; Glucosephosphate Dehydrogenase ; metabolism ; Methanol ; pharmacology ; Pichia ; genetics ; metabolism ; Recombinant Proteins ; biosynthesis ; genetics ; metabolism ; Tissue Plasminogen Activator ; biosynthesis ; genetics ; metabolism

The key and crucial step of metabolic engineering during quinic acid biosynthesize using shikimic acid pathway is high expression of quinate 5-dehydrogenase. The gene qa-3 which code quinate 5-dehydrogenase from Neurospora crassa doesn't express in Escherichia coli. By contrast with codon usage in Escherichia coli, there are 27 rare codons in qa-3, including eight AGG/AGA (Arg) and nine GGG (Gly). Two AGG are joined together (called box R) and some GGG codons are relative concentrate (called box G). Along with the secondary structure of mRNA analysed in computer, the free energy of mRNA changes a lot from -374.3 kJ/mol to least -80.5 kJ/mol when some bases in the end of qa-3 were transformed, and moreover, the change of free energy is quite small when only some bases in the box G and box R transformed. After the change of rare codon and optimization of some bases in the end, qa-3 was expression in E. coli and also the enzyme activity of quinate 5-dehydrogenase can be surveyed accurately. All the work above benefit the further research on producing quinic acid engineering bacterium.
Alcohol Oxidoreductases ; biosynthesis ; genetics ; Base Sequence ; Codon ; chemistry ; genetics ; Escherichia coli ; genetics ; metabolism ; Hydro-Lyases ; genetics ; Molecular Sequence Data ; Neurospora crassa ; enzymology ; genetics ; RNA, Messenger ; chemistry ; genetics ; Recombinant Proteins ; biosynthesis ; genetics ; Shikimic Acid ; metabolism ; Transformation, Bacterial