Removal of Residual DNA and Host Cell Proteins for the Purification of Recombinant Staphylokinase Expressed in Escherichia coli

IF 1.3 Q4 CHEMISTRY, ANALYTICAL
Li Guang, Li jing, Zhenxing Zou, Liu Bo, Weiping Li, Ding Yang, Song Xuri, Xiaolan Fang, Hu Daoqi
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Abstract

The elimination of residual host cell DNA (HCD) and proteins (HCPs) is a pivotal step in the purification process for biological products such as monoclonal antibodies, recombinant proteins, vaccines, gene therapy vectors, and cell‐based therapies. During the preparation of recombinant staphylokinase (r‐SAK), a potential therapeutic protein for thrombotic disorders expressed in Escherichia coli cells, an efficient chromatography purification process, incorporating anion exchange, cation exchange, and gel filtration techniques, was developed to effectively eliminate HCPs and residual DNA. This multistep chromatography approach yielded r‐SAK with a residual HCD concentration below 1 ng/mL, a residual HCP concentration below 0.01%, and purity exceeding 98%. Comparative analysis revealed that modified cellulose‐based matrix resins exhibited superior efficiency compared to dextran and agarose matrix resins for eliminating residual HCPs and HCD under identical conditions. Based on the different properties of the matrix, deductions were made regarding the reasons for the differentiation in separation efficiency. The physical strength of the cellulose‐based matrix ensures the structural stability of macroporous resin and can guarantee efficient separation under conditions of high flow and heavy load. This study suggests that maintaining the structural stability of macropores in bioseparation materials is crucial for improving the efficiency of separating biological products.
去除残留 DNA 和宿主细胞蛋白以纯化大肠杆菌表达的重组葡萄球菌激酶
消除残留的宿主细胞 DNA(HCD)和蛋白质(HCP)是单克隆抗体、重组蛋白质、疫苗、基因治疗载体和细胞疗法等生物制品纯化过程中的关键步骤。在制备重组葡萄球菌激酶(r-SAK)(一种在大肠杆菌细胞中表达的治疗血栓性疾病的潜在蛋白)的过程中,开发了一种高效的层析纯化工艺,该工艺结合了阴离子交换、阳离子交换和凝胶过滤技术,可有效去除 HCP 和残留 DNA。这种多步层析方法得到的 r-SAK 的残留 HCD 浓度低于 1 ng/mL,残留 HCP 浓度低于 0.01%,纯度超过 98%。比较分析表明,与葡聚糖和琼脂糖基质树脂相比,改性纤维素基质树脂在相同条件下消除残留 HCP 和 HCD 的效率更高。根据基质的不同特性,推断出了分离效率不同的原因。纤维素基质的物理强度确保了大孔树脂的结构稳定性,并能保证在高流量和重负荷条件下的高效分离。这项研究表明,保持生物分离材料中大孔的结构稳定性对于提高生物产品的分离效率至关重要。
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来源期刊
SEPARATION SCIENCE PLUS
SEPARATION SCIENCE PLUS CHEMISTRY, ANALYTICAL-
CiteScore
1.90
自引率
9.10%
发文量
111
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