The activity of whole-cell biocatalysts is strongly compromised by the cell envelope, which is a permeability harrier against the diffusion of substrates and products. Although common chemical or physical permeahiliza...The activity of whole-cell biocatalysts is strongly compromised by the cell envelope, which is a permeability harrier against the diffusion of substrates and products. Although common chemical or physical permeahilization methods used in cultured cells enhance cell permeability, these methods inevitably add several extra processing steps after cell cultivation, as well as impede large scale processing. To increase membrane permeability and cell- bound glutamate decarboxylase (GAD) activity of recombinant Escherichia coil (BL21 (DE3)-pET28a-gadB) cells without the need for an additional permeabilization step, we investigated the permeabilizing effects of adding cell wall synthesis inhibitors or suffactants to the culture media. Ampidllin was the most effective at improving cell-bound GAD activity of the BL21 (DE3)-pET28a-gadB, although it decreased the cell biomass yield. The best permeabilization effect was observed using an ampicillin concentration of 5 pg. ml-1. Using this concentration, the cell hiomass did decrease by 40.58%, but the cell-bound GAD activity of BL21 (DE3)-pET28a-gadB and total cell-bound GAD activity per milliliter of culture was enhanced by 6.24- and 3.64-fold, respectively. Treatment ofBL21 (DE3)-pET28a-gadB cells with 5 tag.ml 1 ampicillin resulted in structural changes to the cell envelope, but did not substantially affect GAD expression. By entrapping the ampicillin-treated cells in an open pore gelation matrix, which is a polymer derived from polyvinyl alcohol (PVA), alginate, and boric acid, the transfor- mation rate of γ-aminobutyric acid (GABA) at the 10th cycle produced by immobilized and permeabilized cells remained 46% of the first cycle. GAD activity of the immobilized, permeabilized cells remained over 90% after 30 days of storage at 4 ℃.展开更多
Carbohydrates constitute the most abundant organic matter in nature, serving as structural components and energy sources, and mediating a wide range of cellular activities. The emergence of nanomaterials with distinct...Carbohydrates constitute the most abundant organic matter in nature, serving as structural components and energy sources, and mediating a wide range of cellular activities. The emergence of nanomaterials with distinct optical, magnetic, and electronic properties has witnessed a rapid adoption of these materials for biomedical research and applications. Nanomaterials of various shapes and sizes having large specific surface areas can be used as multivalent scaffolds to present carbohydrate ligands. The resulting glyconanomaterials effectively amplify the glycan-mediated interactions, making it possible to use these materials for sensing, imaging, diagnosis, and therapy. In this review, we summarize the synthetic strategies for the preparation of various glyconanomaterials. Examples are given where these glyconanomaterials have been used in sensing and differentiation of proteins and cells, as well as in imaging glycan-medicated cellular responses.展开更多
基金Supported by the grants from the National Natural Science Foundation of China(21176220,20876143,31470793)the Natural Science Foundation of Zhejiang Province(Z13B060008)the Key Technology Research and Development Project of Ningbo(2011C11023)
文摘The activity of whole-cell biocatalysts is strongly compromised by the cell envelope, which is a permeability harrier against the diffusion of substrates and products. Although common chemical or physical permeahilization methods used in cultured cells enhance cell permeability, these methods inevitably add several extra processing steps after cell cultivation, as well as impede large scale processing. To increase membrane permeability and cell- bound glutamate decarboxylase (GAD) activity of recombinant Escherichia coil (BL21 (DE3)-pET28a-gadB) cells without the need for an additional permeabilization step, we investigated the permeabilizing effects of adding cell wall synthesis inhibitors or suffactants to the culture media. Ampidllin was the most effective at improving cell-bound GAD activity of the BL21 (DE3)-pET28a-gadB, although it decreased the cell biomass yield. The best permeabilization effect was observed using an ampicillin concentration of 5 pg. ml-1. Using this concentration, the cell hiomass did decrease by 40.58%, but the cell-bound GAD activity of BL21 (DE3)-pET28a-gadB and total cell-bound GAD activity per milliliter of culture was enhanced by 6.24- and 3.64-fold, respectively. Treatment ofBL21 (DE3)-pET28a-gadB cells with 5 tag.ml 1 ampicillin resulted in structural changes to the cell envelope, but did not substantially affect GAD expression. By entrapping the ampicillin-treated cells in an open pore gelation matrix, which is a polymer derived from polyvinyl alcohol (PVA), alginate, and boric acid, the transfor- mation rate of γ-aminobutyric acid (GABA) at the 10th cycle produced by immobilized and permeabilized cells remained 46% of the first cycle. GAD activity of the immobilized, permeabilized cells remained over 90% after 30 days of storage at 4 ℃.
基金The authors are grateful for financial supports from the National Institutes of Health (Nos. R01GM080295 and 2R15GM066279), the National Science Foundation (No. CHE-1112436), the University of Massachusetts Lowell, and KTH--Royal Institute of Technology, Sweden.
文摘Carbohydrates constitute the most abundant organic matter in nature, serving as structural components and energy sources, and mediating a wide range of cellular activities. The emergence of nanomaterials with distinct optical, magnetic, and electronic properties has witnessed a rapid adoption of these materials for biomedical research and applications. Nanomaterials of various shapes and sizes having large specific surface areas can be used as multivalent scaffolds to present carbohydrate ligands. The resulting glyconanomaterials effectively amplify the glycan-mediated interactions, making it possible to use these materials for sensing, imaging, diagnosis, and therapy. In this review, we summarize the synthetic strategies for the preparation of various glyconanomaterials. Examples are given where these glyconanomaterials have been used in sensing and differentiation of proteins and cells, as well as in imaging glycan-medicated cellular responses.
