ABSTRACT
Displaying Candida antarctica lipase B (CALB) on the cell surface of Aspergillus niger is effectively applied for the industries of food, cosmetics, pharmaceutical and so on. Displaying CALB using induced promoter of glucoamylase on the cell surface of A. niger SH-1 has some problems such as inhibiting its expression under high concentration of glucose, mycelium cleavage and decreasing enzyme activity in the later period of fermentation process. Displaying CALB manipulated by constitutive promoter from glyceraldehyde-3-phosphate dehydrogenase instead of glucoamylase on the cell surface of A. niger SH-1, called AN-GpdA, could solve the above problems effectively. Furthermore, it can not only use glucose, but also xylose as a sole carbon source. Enzyme activity of AN-GpdA using xylose for fermentation reached 1 100.28 U/g of dry cell. We also used lignocellulose such as the hydrolysate of bagasse for fermentation with good performance. The result would provide a novel strategy for the utilization of bagasse.
ABSTRACT
Previous studies have verified the feasibility of using Escherichia coli systems that display organophosphorous hydrolase (OPH) on the cell surface as whole-cell catalysts. However, the inefficient display of the enzyme on cell surfaces remains unaddressed. In the present study, multiple optimization experiments on full-length and truncated ice nucleation protein anchors, E. coli host cells, culture media, and culture conditions were performed to optimize whole-cell OPH enzymatic activity. The results show that apart from the dramatic effect of isopropyl-b-d-thiogalactoside concentration and culture temperature, the coordination between the anchor protein, culture media, and host cells is essential for highly efficient OPH display. Under optimal conditions, namely, culturing in M9 medium, 20 °C induction temperature, 0.1 mmol l-1 IPTG, and 100 μmol l-1 Co2+, the engineered E. coli strain MB109-406 that expresses the fusion enzyme InaK-N-OPH exhibited a whole-cell OPH activity of 0.62 U mg-1 ?cell d.wt. This result is much higher than that of several currently available OPH-displaying systems, which shows the potential of the current system for further large-scale industrial or environmental applications.
ABSTRACT
A bacterial cell surface display technique based on an ice nucleation protein has been employed for the development of live vaccine against viral infection.Due to its ubiquitous ability to invade host cells,Salmonella typhimurium might be a good candidate for displaying viral antigens.We demonstrated the surface display of domain III of Japanese encephalitis virus E protein and the enhanced green fluorescent protein on S.typhimurium BRD509 using the ice nucleation protein.The effects of the motif in the ice nucleation protein on the effective display of integral protein were also investigated.The results showed that display motifs in the protein can target integral foreign protein on the surface of S.typhimurium BRD509.Moreover,recombinant strains with surface displayed viral proteins retained their invasiveness,suggesting that the recombinant S.typhimurium can be used as live vaccine vector for eliciting complete immunogenicity.The data may yield better understanding of the mechanism by which ice nucleation protein displays foreign proteins in the Salmonella strain.
ABSTRACT
Microbe cell-surface engineering , which use the microbe cell surface display technology to display foreign proteins on the microbe cell surface to produce cell-surface proteins, was developed in recent years. I t can be utilizedto develop cell-catalyst, cell-adsorbent , live vaccine, biosensor and so on, and have a wide application perspective. But in our county, the microbe cell-surface engineering is studied just now. This review explain the development of the microbe cell surface engineering, overview the study and progress of microbe cell-surface engineering, and look this technology into the future.