Ai-Tao Li

Isolation of Rhodococcus sp. Strain ECU0066, a New Sulfide Monooxygenase-Producing Strain for Asymmetric Sulfoxidation

ABSTRACT A new and efficient sulfide monooxygenase-producing strain, ECU0066, was isolated and identified as a Rhodococcus sp. that could transform phenylmethyl sulfide (PMS) to (S)-sulfoxide with 99% enantiomeric excess via two steps of enantioselective oxidations. Its enzyme activity could be effectively induced by adding PMS or phenylmethyl sulfoxide (PMSO) directly to a rich medium at the early log phase (6 h) of fermentation, resulting in over 10-times-higher production of the enzyme. This bacterial strain also displayed fairly good activity and enantioselectivity toward seven other sulfides, indicating a good potential for practical application in asymmetric synthesis of chiral sulfoxides.

Available methods for assembling expression cassettes for synthetic biology

Studies in the structural biology of the multicomponent protein complex, metabolic engineering, and synthetic biology frequently rely on the efficient over-expression of these subunits or enzymes in the same cell. As a first step, constructing the multiple expression cassettes will be a complicated and time-consuming job if the classic and conventional digestion and ligation based cloning method is used. Some more efficient methods have been developed, including (1) the employment of a multiple compatible plasmid expression system, (2) the rare-cutter-based design of vectors, (3) in vitro recombination (sequence and ligation independent cloning, the isothermally enzymatic assembly of DNA molecules in a single reaction), and (4) in vivo recombination using recombination-efficient yeast (in vivo assembly of overlapping fragments, reiterative recombination for the chromosome integration of foreign expression cassettes). In this review, we systematically introduce these available methods.

Resolution of racemic sulfoxides with high productivity and enantioselectivity by a Rhodococcus sp. strain as an alternative to biooxidation of prochiral sulfides for efficient production of enantiopure sulfoxides

Whole cells of Rhodococcus sp. ECU0066 were used a catalyst for resolution of racemic sulfoxides, as an alternative to asymmetric oxidation of sulfides for efficient production of enantiopure sulfoxides. Racemic sulfoxides were excellent substrates for biotransformation because of their lower biotoxicity compared to sulfides. Determination of apparent kinetic parameters indicated that phenyl methyl sulfide (PMS), but not racemic phenyl methyl sulfoxide (rac-PMSO) caused substrate inhibition. (S)-PMSO was formed at a higher concentration and good enantiomeric excess (37.8 mM and 93.7% ee(S)) in a fed-batch reaction, than by an asymmetric oxidation of PMS (10 mM and 80% eeP (S)). The bacterium also displayed fairly good activity (yields, 22.7-43.2%; within 1-8 h) and enantioselectivity (ee(S)>99.0%) towards para-substituted (methyl and chloro) phenyl methyl sulfoxides and ethyl phenyl sulfoxide, indicating it could be a promising agent for synthetic applications.

A Simple and Universal Method to Express Protein in Unfused form

The effect of additional amino acid residue(s) fused to the N- and/or C-terminal on properties of the heterogeneously expressed protein is usually difficult to be predicted. Recombinant proteins expressed without any fused sequence should be the most desired materials for related studies, such as protein drug preparation, biochemistry investigations. Here, we report a very simple and universal method enabling the expression of protein in its unfused form between the same two restriction enzyme sites (at a higher level) if a plasmid can support the fused expression. The method provided an assessable solution for unfused expression without increase in experimental resource; the necessary material is an additional primer. The method is especially useful for making whole-cell biocatalyst in which no purification steps are required.