Ukkonen Kaisa, Mayer Sonja, Vasala Antti, Neubauer Peter
Bioprocess Engineering Laboratory, Department of Process and Environmental Engineering, University of Oulu, P.O. Box 4300, FI-90014 Oulu, Finland; BioSilta Oy, P.O. Box 4300, FI-90014 Oulu, Finland.
Protein Expr Purif. 2013 Oct;91(2):147-54. doi: 10.1016/j.pep.2013.07.016. Epub 2013 Aug 11.
Recombinant protein expression from lac derived promoters by the autoinduction regime is based on diauxic growth of Escherichia coli on glucose and lactose. Glycerol is used as a supporting carbon source during the lactose-induced expression. While this glycerol-based formulation usually provides high cell densities, successful protein expression by autoinduction is often very dependent on correct aeration level. This complicates the reproducibility and scalability of the cultures. In this study we investigate the use of an alternative autoinduction formulation, in which the supporting carbon source is provided by fed-batch-like slow glucose feed from a biocatalytically degraded polysaccharide. The glucose feed as supporting carbon source allowed for high level of autoinduced target protein expression from T7lac promoter in E. coli BL21(DE3) and from T5lac promoter in E. coli K-12 RB791(lacI(q)) with lactose concentrations of 0.5-2gl(-1). Cell densities and protein yields per culture volume were similar to or higher than in the glycerol-based ZYM-5052 medium. In the glycerol-based medium, protein production was adversely influenced by high aeration level, resulting in 75-90% reduction in protein yield per cell compared to more moderately aerated conditions. The glucose fed-batch medium attenuated this oxygen-sensitivity and provided robust high-yield expression also under high aeration rates. It is concluded that the slow glucose feed as supporting carbon source mitigates aeration-related scale differences in autoinduced protein expression, and combined with the benefit of high product yields this makes the fed-batch autoinduction medium ideal for high-throughput screening and scale-up of the production process.
通过自诱导机制从乳糖衍生启动子表达重组蛋白是基于大肠杆菌在葡萄糖和乳糖上的双相生长。在乳糖诱导表达期间,甘油用作辅助碳源。虽然这种基于甘油的配方通常能提供高细胞密度,但通过自诱导成功表达蛋白往往非常依赖于正确的通气水平。这使得培养物的可重复性和可扩展性变得复杂。在本研究中,我们研究了一种替代自诱导配方的使用,其中辅助碳源由生物催化降解的多糖以补料分批式缓慢添加葡萄糖提供。以葡萄糖作为辅助碳源,在乳糖浓度为0.5 - 2 g l⁻¹的情况下,能使大肠杆菌BL21(DE3)中的T7lac启动子和大肠杆菌K - 12 RB791(lacI(q))中的T5lac启动子高水平自诱导表达目标蛋白。每培养体积的细胞密度和蛋白产量与基于甘油的ZYM - 5052培养基相似或更高。在基于甘油的培养基中,高通气水平对蛋白生产有不利影响,与通气较适度的条件相比,每细胞的蛋白产量降低了75 - 90%。葡萄糖补料分批培养基减弱了这种氧敏感性,并且在高通气速率下也能提供稳定的高产表达。得出的结论是,以缓慢添加葡萄糖作为辅助碳源可减轻自诱导蛋白表达中与通气相关的规模差异,再加上高产率的优势,这使得补料分批自诱导培养基非常适合高通量筛选和生产过程的放大。
