Novel approach to obtain biologically active recombinant heterodimeric proteins in Escherichia coli
- 作者:Austin ; Corrine
- 关键词:Escherichia coli ; Recombinant heterodimeric protein
- 刊名:Journal of Chromatography B ; Analytical Technologies in the Biomedical and Life Sciences
- 出版年:2003
- 期刊代码:124_15700232
- 类别:ch
- 出版时间:March 25, 2003
- 卷:786
- 期:1-2
- 页码:93-107
- 文件大小:663 K
摘要
The strategy described in this paper provides a novel approach for recombinant expression of heterodimeric proteins, and is especially suitable for the production of proteins whose characteristics lead to aggregation in E. coli expression systems. Pheromaxein, a steroid-binding protein isolated from boar saliva, is a heterodimeric protein consisting of 10×103 rel. mol. mass units (pheromaxein A) and 8×103 rel. mol. mass units (pheromaxein C) subunits. Expression of pheromaxein subunits in E. coli resulted in extensive insoluble aggregation. The difficulty faced in obtaining soluble recombinant pheromaxein subunits was clearly evident when native pheromaxein immediately formed aggregates when it was separated into its individual subunits. An increase in soluble pheromaxein expression in E. coli was obtained when the subunits were expressed as fusion proteins with thioredoxin. Pheromaxein genes were inserted separately into pET32a+ vectors at the NcoI site, resulting in thioredoxin, S·Tag™ and His·Tag™ coding regions being upstream of the inserted gene. Soluble pheromaxein A–thioredoxin (pheroA/trx) and pheromaxein C–thioredoxin (pheroC/trx) fusions were purified to homogeneity, using a laboratory scale S-protein agarose affinity column. Cleavage of thioredoxin under normal conditions was not feasible due to the extensive aggregation problems experienced when pheromaxein subunits exist separately. PheroA/trx and pheroC/trx were therefore mixed together and cleaved from thioredoxin simultaneously so that pheromaxein subunits were given an instant opportunity to associate under oxido-shuffling conditions. The glutathione oxido-shuffling system allowed the disulphide bridges between pheromaxein A and C to rearrange until the correct native structure was formed. This novel approach combines affinity purification with a coupled fusion protein-cleavage and refolding technique.