•The bioactivity of aquaporin in E.coli was demonstrated by in-vivo expression of AqpSS9 from P. profundum SS9.•A high productivity of soluble AqpSS9 (571 mg/l) was achieved by using in-vitro E. coli cell-free expression system (D-CF mode).•High water permeability (Pf 310.7 ± 3.2 μm/s) was determined with AqpSS9 incorporated proteoliposome.•The construction of AqpSS9 embedded layer-by-layer (LbL) membrane with improved water permeability and salt rejection.AqpSS9 is a novel aquaporin derived from the deep sea bacterium Photobactetrium profundum SS9 and has attracted many attentions in developing water filtration biomimetic membranes. Functional characterization of AqpSS9 was carried out first by its expression in E. coli MM1211 (aqpZ−). Results showed that it was similar to bacterial aquaporin Z (AqpZ) and functioned as a real aquaporin. In-vitro expression of AqpSS9 were systematically investigated using three different modes: precipitate-based cell-free (P-CF) mode, the detergent-based cell-free (D-CF) mode and lipid-based cell-free expression mode (L-CF). D-CF mode showed more superiority than P-CF and L-CF mode, and the highest expression level of 571 mg/l was achieved by adding 0.7% Brij-78. Then AqpSS9 was purified by affinity chromatograph and incorporated into DOPC liposomes. Osmotic water permeability values (Pf) of reconstituted AqpSS9 proteoliposomes was measured as 310.7 ± 3.2 μm/s, which was about 3.5 times of empty control liposomes and comparable to reported Aqps. The AqpSS9 embedded layer-by-layer (LbL) membrane was fabricated and tested, which showed enhanced water permeability and salt rejection in comparison with the control membrane. This work demonstrated the good performance of AqpSS9 as a water channel protein, which may become an alternative candidate for biomimetic membrane construction for water filtration.Download high-res image (141KB)Download full-size image

In order to improve the production of alcohol oxidase (AOX), a recombinant Pichia pastoris (P. pastoris) system was constructed by transformation of the plasmid pPIC9K-AOX into P. pastoris GS115. The effects of different expression conditions on alcohol oxidase activity in the culture supernatant were investigated in the shake flask scale. The results showed that the highest extracellular activity (562 U/L) of alcohol oxidase was obtained after 56 h induction with 4% methanol at OD600 1.0 in the medium containing 50 g/L maltose, which is about 4.2 folds higher than previously reported. High-purity functional recombinant AOX (>90%) was purified from the culture with the Ni-NTA affinity column and Sephadex G-100 chromatographical methods, with a total recovery rate of 68.9%. Further studies showed that the purified rAOX had similar enzymatic characteristics as the native enzyme, except that the thermal stability and resistance to H2O2 inhibition of rAOX were significantly greater compared to the previous report. The purified rAOX was well tolerant to various water-miscible organic solvents. This efficient expression and purification process will be promising for large-scale production of rAOX as an important diagnostic enzyme for alcohol detection in many areas.

Hydrolysate of Jerusalem artichoke was applied for the production of l-lactic acid by immobilized Lactococcus lactis cells in a fibrous bed bioreactor system. Preliminary experiments had indicated that the high quality hydrolysate, which was derived from the 40 min acid treatment at 95 °C and pH 1.8, was sufficient to support the cell growth and synthesis of l-lactic acid. With the addition of 5 g/l yeast extract, the fermentative performance of free cell system was evidently improved. After the basal settlement of hydrolysate based fermentation, the batch mode and the fed-batch mode fermentation were carried out in the free cell system and the fibrous bed bioreactor system, respectively. In all cases the immobilized cells presented the superior ability to produce l-lactic acid. The comparison of batch mode and fed-batch mode also indicated that the growth-limiting feeding strategy could reduce the lag phase of fermentation process and enhance the production of l-lactic acid. The achieved maximum concentration of l-lactic acid was 142 g/l in the fed-batch mode. Subsequent repeated-batch fermentation of the fibrous bed bioreactor system had further exhibited the persistence and stability of this system for the high production of l-lactic acid in a long term. Our work suggested the great potential of the fibrous bed bioreactor system and hydrolysate of J. artichoke in the economical production of l-lactic acid at industrial scale.Highlights► High yield of sugars from Jerusalem artichoke was obtained using mild acid treatment. ► JA hydrolysate could support the high level production of lactic acid in FBB. ► Immobilization of Lactococcus lactis greatly improved the lactic acid productivity.