Schlapschy Martin, Theobald Ina, Mack Hildegard, Schottelius Margret, Wester Hans-Jürgen, Skerra Arne
Lehrstuhl für Biologische Chemie, Technische Universität München, 85350 Freising-Weihenstephan, Germany.
Protein Eng Des Sel. 2007 Jun;20(6):273-84. doi: 10.1093/protein/gzm020. Epub 2007 Jun 26.
Chemical conjugation of small recombinant proteins with polyethylene glycol (PEG) is an established strategy to extend their typically short circulation times to a therapeutically useful range. We have investigated the production of a genetic fusion with a glycine-rich homo-amino-acid polymer (HAP) as an alternative way to attach a solvated random chain with large hydrodynamic volume. The anti-HER2 Fab fragment 4D5 was used as a model system and fused with either 100 or 200 residue polymers of the repetitive sequence (Gly(4)Ser)(n) to its light chain. Both fusion proteins were successfully produced in the periplasm of Escherichia coli and obtained as homogeneous preparations after two-step affinity chromatography via the His(6) tag fused to the heavy chain and the Strep-tag II fused to the extended light chain. Both modified Fab fragments showed binding activity towards the HER2 antigen indistinguishable from the conventional recombinant Fab fragment. When compared with the unfused Fab fragment, a significantly increased hydrodynamic volume, by ca. 120%, was observed during gel filtration for the 200 residue HAP fusion protein and, to a lesser extent, in the case of the 100 residue HAP. Difference CD measurements revealed a characteristic random coil spectrum for the 100 and 200 residue HAP fusion moieties. Finally, pharmacokinetic experiments were carried out in mice after radioiodination of the recombinant Fab fragments. Although the 100 residue HAP fusion showed a behavior very similar to the unfused Fab fragment, with a terminal plasma half-life of ca. 2 h, the 200 residue HAPylated Fab fragment gave rise to a significantly prolonged half-life of ca. 6 h. While this moderate effect may so far be most beneficial for specialized medical applications, such as in vivo imaging, the genetic engineering of optimized HAP sequences should yield pharmacokinetic properties similar to PEGylation, yet without necessitating in vitro modification steps.
将小的重组蛋白与聚乙二醇(PEG)进行化学偶联是一种既定策略,可将其通常较短的循环时间延长至治疗有效范围。我们研究了与富含甘氨酸的同型氨基酸聚合物(HAP)进行基因融合的生产方法,作为连接具有大流体动力学体积的溶剂化无规链的另一种方式。抗HER2 Fab片段4D5用作模型系统,并与重复序列(Gly(4)Ser)(n)的100或200个残基聚合物融合至其轻链。两种融合蛋白均在大肠杆菌周质中成功产生,并通过与重链融合的His(6)标签和与延伸轻链融合的链霉亲和素标签II进行两步亲和层析后获得均一制剂。两种修饰的Fab片段对HER2抗原的结合活性与传统重组Fab片段无异。与未融合的Fab片段相比,在凝胶过滤过程中,200个残基的HAP融合蛋白的流体动力学体积显著增加,约增加120%,100个残基的HAP情况则增加幅度较小。差示圆二色性测量揭示了100和200个残基的HAP融合部分具有特征性的无规卷曲光谱。最后,在对重组Fab片段进行放射性碘化后,在小鼠中进行了药代动力学实验。尽管100个残基的HAP融合蛋白表现出与未融合的Fab片段非常相似的行为,终末血浆半衰期约为2小时,但200个残基的HAP化Fab片段的半衰期显著延长,约为6小时。虽然到目前为止这种适度的效果可能对专门的医学应用(如体内成像)最为有益,但优化HAP序列的基因工程应能产生与聚乙二醇化相似的药代动力学特性,而无需体外修饰步骤。
