Yu Rui, Albarenque Stella Maris, Cool Robbert H, Quax Wim J, Mohr Andrea, Zwacka Ralf M
a National University of Ireland; Galway; National Centre for Biomedical Engineering Science and Apoptosis Research Centre; Molecular Therapeutics Group ; Galway , Ireland.
Cancer Biol Ther. 2014;15(12):1658-66. doi: 10.4161/15384047.2014.972183.
Current treatment modalities for pancreatic carcinoma afford only modest survival benefits. TRAIL, as a potent and specific inducer of apoptosis in cancer cells, would be a promising new treatment option. However, since not all pancreatic cancer cells respond to TRAIL, further improvements and optimizations are still needed. One strategy to improve the effectiveness of TRAIL-based therapies is to specifically target one of the 2 cell death inducing TRAIL-receptors, TRAIL-R1 or TRAIL-R2 to overcome resistance. To this end, we designed constructs expressing soluble TRAIL (sTRAIL) variants that were rendered specific for either TRAIL-R1 or TRAIL-R2 by amino acid changes in the TRAIL ectodomain. When we expressed these constructs, including wild-type sTRAIL (sTRAIL(wt)), TRAIL-R1 (sTRAIL(DR4)) and TRAIL-R2 (sTRAIL(DR5)) specific variants, in 293 producer cells we found all to be readily expressed and secreted into the supernatant. These supernatants were subsequently transferred onto target cancer cells and apoptosis measured. We found that the TRAIL-R1 specific variant had higher apoptosis-inducing activity in human pancreatic carcinoma Colo357 cells as well as PancTu1 cells that were additionally sensitized by targeting of XIAP. Finally, we tested TRAIL-R1 specific recombinant TRAIL protein (rTRAIL(DR4)) on Colo357 xenografts in nude mice and found them to be more efficacious than rTRAIL(wt). Our results demonstrate the benefits of synthetic biological approaches and show that TRAIL-R1 specific variants can potentially enhance the therapeutic efficacy of TRAIL-based therapies in pancreatic cancer, suggesting that they can possibly become part of individualized and tumor specific combination treatments in the future.
目前胰腺癌的治疗方式仅能带来有限的生存获益。TRAIL作为一种在癌细胞中诱导凋亡的强效且特异性的诱导剂,将是一种有前景的新治疗选择。然而,由于并非所有胰腺癌细胞都对TRAIL有反应,仍需要进一步改进和优化。提高基于TRAIL治疗效果的一种策略是特异性靶向两种诱导细胞死亡的TRAIL受体之一,即TRAIL-R1或TRAIL-R2,以克服耐药性。为此,我们设计了表达可溶性TRAIL(sTRAIL)变体的构建体,通过TRAIL胞外域的氨基酸变化使其对TRAIL-R1或TRAIL-R2具有特异性。当我们在293生产细胞中表达这些构建体,包括野生型sTRAIL(sTRAIL(wt))、TRAIL-R1特异性变体(sTRAIL(DR4))和TRAIL-R2特异性变体(sTRAIL(DR5))时,我们发现它们都能很容易地表达并分泌到上清液中。随后将这些上清液转移到靶癌细胞上并测量凋亡情况。我们发现TRAIL-R1特异性变体在人胰腺癌Colo357细胞以及通过靶向XIAP而增敏的PancTu1细胞中具有更高的凋亡诱导活性。最后,我们在裸鼠的Colo357异种移植瘤上测试了TRAIL-R1特异性重组TRAIL蛋白(rTRAIL(DR4)),发现它比rTRAIL(wt)更有效。我们的结果证明了合成生物学方法的益处,并表明TRAIL-R1特异性变体可能增强基于TRAIL的疗法在胰腺癌中的治疗效果,这表明它们未来可能成为个体化和肿瘤特异性联合治疗的一部分。