Turnbull Alice, Bermejo-Rodríguez Camino, Preston Mark A, Garrido-Barros María, Pimentel Belén, de la Cueva-Méndez Guillermo
MRC Cancer Cell Unit , Hutchison/MRC Research Centre , Hills Road , Cambridge CB2 0XZ , U.K.
Synthetic Biology and Smart Therapeutic Nanosystems Laboratory , Andalusian Centre for Nanomedicine and Biotechnology-BIONAND , 29590 Málaga , Spain.
ACS Synth Biol. 2019 Aug 16;8(8):1730-1736. doi: 10.1021/acssynbio.9b00172. Epub 2019 Aug 1.
Although not evolved to function in eukaryotes, prokaryotic toxin Kid induces apoptosis in human cells, and this is avoided by coexpression of its neutralizing antitoxin, Kis. Inspired by the way Kid becomes active in bacterial cells we had previously engineered a synthetic toxin-antitoxin system bearing a Kis protein variant that is selectively degraded in cells expressing viral oncoprotein E6, thus achieving highly selective killing of cancer cells transformed by human papillomavirus. Here we aimed to broaden the type of oncogenic insults, and therefore of cancer cells, that can be targeted using this approach. We show that appropriate linkage of the gene to a single, fully complementary, target site for an oncogenic human microRNA enables the construction of a synthetic toxin-antitoxin pair that selectively kills cancer cells overexpressing that particular microRNA. Importantly, the resulting system spares nontargeted cells from collateral damage, even when they overexpress highly homologous, though nontargeted, microRNAs.
尽管原核毒素Kid并非为在真核生物中发挥功能而进化,但它能诱导人类细胞凋亡,而其解毒抗毒素Kis的共表达可避免这种情况。受Kid在细菌细胞中激活方式的启发,我们之前设计了一种合成毒素 - 抗毒素系统,该系统带有一种Kis蛋白变体,它在表达病毒癌蛋白E6的细胞中被选择性降解,从而实现对人乳头瘤病毒转化的癌细胞的高度选择性杀伤。在这里,我们旨在拓宽可使用这种方法靶向的致癌损伤类型以及癌细胞类型。我们表明,将该基因与致癌性人类微小RNA的单个完全互补靶位点进行适当连接,能够构建一种合成毒素 - 抗毒素对,该对可选择性杀死过度表达该特定微小RNA的癌细胞。重要的是,即使非靶向细胞过度表达高度同源但非靶向的微小RNA,所得系统也能使它们免受附带损害。
