The earliest industrial biotechnology originated in ancient China and developed into a vibrant industry in traditional Chinese liquor, rice wine, soy sauce, and vinegar. It is now a significant component of the Chinese economy valued annually at about 150 billion RMB. Although the production methods had existed and remained basically unchanged for centuries, modern developments in biotechnology and related fields in the last decades have greatly impacted on these industries and led to numerous technological innovations. In this chapter, the main biochemical processes and related technological innovations in traditional Chinese biotechnology are illustrated with recent advances in functional microbiology, microbial ecology, solid-state fermentation, enzymology, chemistry of impact flavor compounds, and improvements made to relevant traditional industrial facilities. Recent biotechnological advances in making Chinese liquor, rice wine, soy sauce, and vinegar are reviewed.
An alcohol dehydrogenase from Candida parapsilosis CCTCC M203011 was characterized along with its biochemical activity and structural gene. The amino acid sequence shows similarity to those of the short-chain dehydrogenase/reductases but no overall identity to known proteins. This enzyme with unusual stereospecificity catalyzes an anti-Prelog reduction of 2-hydroxyacetophenone to (S)-1-phenyl-1,2-ethanediol.
An economical and convenient biocatalytic process was developed for the preparation of (S)-1-phenyl-1,2-ethanediol (PED),
which is a valuable chiral building block for pharmaceuticals
and liquid crystals, by stereoselective microbial conversion from
the corresponding racemate. As a result of screening bacteria,
yeasts, and molds, the enantioselective conversion of racemic
PED by Candida parapsilosis CCTCC M203011 was found to
be the most efficient process to produce (S)-PED with high
optical purity of 98% ee and yield of 92%. By detecting the
intermediate produced in the reaction by GC−MS, it was
suggested that (S)-enantiomer was produced from the intermediate identified as β-hydroxyacetophenone by asymmetric
reduction after stereoselective oxidation of (R)-enantiomer to
β-hydroxyacetophenone. After investigating the cofactor requirement and stereospecificity of the reaction catalyzed by the
cell-free extract from C. parapsilosis CCTCC M203011, it was
found that the stereoselective conversion involved the oxidation
of (R)-PED to the intermediate with NADP+ as the cofactor
and the reduction reaction that formed the product used NADH
as the cofactor, which was catalyzed by a novel cofactor-dependent oxidoreduction system. The NADP+-dependent (R)-specific alcohol dehydrogenase involved in stereoinversion was
purified from C. parapsilosis CCTCC M203011, which has a
relative molecular mass of 45kD.
Pullulanase plays an important role in specific hydrolysis of branch points in amylopectin and is generally employed as an important enzyme in starch-processing industry. So far, however, the production level of pullulanase is still somewhat low from wide-type strains and even heterologous expression systems. Here the gene encoding Bacillus naganoensis pullulanase was amplified and cloned. For expression of the protein, two recombinant systems, Escherichia coli BL21(DE3)/pET-20b(+)-pul and E. coli BL21(DE3)/pET-22b(+)-pul, were constructed, both bearing T7 promoter and signal peptide sequence, but different in the existance of lac operator and lacI gene encoding lac repressor. Recombinant pullulanase was initially expressed with the activity of up to 14 U/mL by E. coli BL21(DE3)/pET-20b(+)-pul with IPTG induction in LB medium, but its expression level reduced continually with the extension of cryopreservation time and basal expression was observed. However, E. coli BL21(DE3)/pET-22b(+)-pul , involving lac operator downstream of T7 promoter to regulate foreign gene transcription, exhibited pullulanase activity consistently without detected basal expression. By investigating the effect of lac operator, basal expression of foreign protein was found to cause expression instability and negative effect on production of target protein. Thus double-repression strategy was proposed that lac operators in both chromosome and plasmid were bound with lac repressor to repress T7 RNA polymerase synthesis and target protein expression before induction. Consequently, the total activity of pullulanase was remarkably increased to 580 U/mL with auto-induction by lac operator-involved E. coli BL21(DE3)/pET-22b(+)-pul. When adding 0.6% glycine in culture, the extracellular production of pullulanase was significantly improved with the extracellular activity of 502 U/mL, which is a relatively higher level achieved to date for extracellular production of pullulanase. The successful expression of pullulanase with lac operator regulation provides an efficient way for enhancement of expression stability and hence high-level production of target protein in recombinant E. coli.
The discovery of (R)-specific oxidoreductase exhibiting unusual stereospecificity towards hydroxyl ketone is valuable for the synthesis of both enantiomers of useful chiral alcohols, and provides research basis for the achievement of profound knowledge on the relationship between structure and catalytic function of (R)-specific enzymes, which is meaningful for the alteration of stereospecificity by molecular methods to obtain the enzymes with desired stereospecificity.
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