Université de Strasbourg, UMR7242 Biotechnologie et Signalisation Cellulaire, Ecole Supérieure de Biotechnologie Strasbourg, F-67412 Illkirch, France.
IMPReSs Facility, Biotechnology and Cell Signaling, CNRS-University of Strasbourg, Illkirch, F-67412 Illkirch, France.
Bioconjug Chem. 2020 Oct 21;31(10):2421-2430. doi: 10.1021/acs.bioconjchem.0c00482. Epub 2020 Sep 30.
Immunotoxins are emerging candidates for cancer therapeutics. These biomolecules consist of a cell-targeting protein combined to a polypeptide toxin. Associations of both entities can be achieved either chemically by covalent bonds or genetically creating fusion proteins. However, chemical agents can affect the activity and/or stability of the conjugate proteins, and additional purification steps are often required to isolate the final conjugate from unwanted byproducts. As for fusion proteins, they often suffer from low solubility and yield. In this report, we describe a straightforward conjugation process to generate an immunotoxin using coassociating peptides (named K3 and E3), originating from the tetramerization domain of p53. To that end, a nanobody targeting the human epidermal growth factor receptor 2 (nano-HER2) and a protein toxin fragment from exotoxin A (TOX) were genetically fused to the E3 and K3 peptides. Entities were produced separately in in soluble forms and at high yields. The nano-HER2 fused to the E3 or K3 helixes (nano-HER2-E3 and nano-HER2-K3) and the coassembled immunotoxins (nano-HER2-K3E3-TOX and nano-HER2-E3K3-TOX) presented binding specificity on HER2-overexpressing cells with relative binding constants in the low nanomolar to picomolar range. Both toxin modules (E3-TOX and K3-TOX) and the combined immunotoxins exhibited similar cytotoxicity levels compared to the toxin alone (TOX). Finally, nano-HER2-K3E3-TOX and nano-HER2-E3K3-TOX evaluated on various breast cancer cells were highly potent and specific to killing HER2-overexpressing breast cancer cells with IC values in the picomolar range. Altogether, we demonstrate that this noncovalent conjugation method using two coassembling peptides can be easily implemented for the modular engineering of immunotoxins targeting different types of cancers.
免疫毒素是癌症治疗的新兴候选药物。这些生物分子由靶向细胞的蛋白质与多肽毒素组成。两种物质的结合可以通过化学方法(通过共价键)或通过遗传方法(创建融合蛋白)来实现。然而,化学试剂可能会影响缀合物蛋白的活性和/或稳定性,并且通常需要额外的纯化步骤来从不需要的副产物中分离最终的缀合物。对于融合蛋白,它们往往溶解度低,产量低。在本报告中,我们描述了一种使用共缔合肽(命名为 K3 和 E3)生成免疫毒素的直接缀合方法,这些肽源自 p53 的四聚化结构域。为此,针对人表皮生长因子受体 2(纳米 HER2)的纳米抗体和来自外毒素 A(TOX)的蛋白毒素片段被分别遗传融合到 E3 和 K3 肽上。这些实体以可溶形式和高产量分别进行生产。纳米 HER2 与 E3 或 K3 螺旋(nano-HER2-E3 和 nano-HER2-K3)融合以及共组装的免疫毒素(nano-HER2-K3E3-TOX 和 nano-HER2-E3K3-TOX)在过表达 HER2 的细胞上表现出结合特异性,相对结合常数在纳摩尔到皮摩尔范围内。两种毒素模块(E3-TOX 和 K3-TOX)和组合的免疫毒素与单独的毒素(TOX)相比表现出相似的细胞毒性水平。最后,在各种乳腺癌细胞上评估的 nano-HER2-K3E3-TOX 和 nano-HER2-E3K3-TOX 对过表达 HER2 的乳腺癌细胞具有高度的效力和特异性,IC 值在皮摩尔范围内。总之,我们证明了这种使用两个共缔合肽的非共价缀合方法可以很容易地用于针对不同类型癌症的免疫毒素的模块化工程。
