Alidori Simone, Akhavein Nima, Thorek Daniel L J, Behling Katja, Romin Yevgeniy, Queen Dawn, Beattie Bradley J, Manova-Todorova Katia, Bergkvist Magnus, Scheinberg David A, McDevitt Michael R
Department of Radiology, Memorial Sloan Kettering Cancer Center, New York, NY 10065, USA.
Division of Nuclear Medicine and Molecular Imaging, Department of Radiology and Radiological Science, Johns Hopkins University School of Medicine, Baltimore, MD 21205, USA.
Sci Transl Med. 2016 Mar 23;8(331):331ra39. doi: 10.1126/scitranslmed.aac9647.
RNA interference has tremendous yet unrealized potential to treat a wide range of illnesses. Innovative solutions are needed to protect and selectively deliver small interfering RNA (siRNA) cargo to and within a target cell to fully exploit siRNA as a therapeutic tool in vivo. Herein, we describe ammonium-functionalized carbon nanotube (fCNT)-mediated transport of siRNA selectively and with high efficiency to renal proximal tubule cells in animal models of acute kidney injury (AKI). fCNT enhanced siRNA delivery to tubule cells compared to siRNA alone and effectively knocked down the expression of several target genes, includingTrp53,Mep1b,Ctr1, andEGFP A clinically relevant cisplatin-induced murine model of AKI was used to evaluate the therapeutic potential of fCNT-targeted siRNA to effectively halt the pathogenesis of renal injury. Prophylactic treatment with a combination of fCNT/siMep1band fCNT/siTrp53significantly improved progression-free survival compared to controls via a mechanism that required concurrent reduction of meprin-1β and p53 expression. The fCNT/siRNA was well tolerated, and no toxicological consequences were observed in murine models. Toward clinical application of this platform, fCNTs were evaluated for the first time in nonhuman primates. The rapid and kidney-specific pharmacokinetic profile of fCNT in primates was comparable to what was observed in mice and suggests that this approach is amenable for use in humans. The nanocarbon-mediated delivery of siRNA provides a therapeutic means for the prevention of AKI to safely overcome the persistent barrier of nephrotoxicity during medical intervention.
RNA干扰在治疗多种疾病方面具有巨大但尚未实现的潜力。需要创新的解决方案来保护并选择性地将小干扰RNA(siRNA)输送到靶细胞内,以充分发挥siRNA作为体内治疗工具的作用。在此,我们描述了在急性肾损伤(AKI)动物模型中,铵功能化碳纳米管(fCNT)介导的siRNA选择性且高效地转运至肾近端小管细胞。与单独的siRNA相比,fCNT增强了siRNA向小管细胞的递送,并有效敲低了包括Trp53、Mep1b、Ctr1和EGFP在内的多个靶基因的表达。使用临床上相关的顺铂诱导的AKI小鼠模型来评估fCNT靶向siRNA有效阻止肾损伤发病机制的治疗潜力。与对照组相比,联合使用fCNT/siMep1b和fCNT/siTrp53进行预防性治疗通过一种需要同时降低meprin-1β和p53表达的机制,显著提高了无进展生存期。fCNT/siRNA耐受性良好,在小鼠模型中未观察到毒理学后果。为了该平台的临床应用,首次在非人类灵长类动物中评估了fCNT。fCNT在灵长类动物中快速且具有肾脏特异性的药代动力学特征与在小鼠中观察到的情况相当,表明这种方法适用于人类。纳米碳介导的siRNA递送为预防AKI提供了一种治疗手段,以安全地克服医疗干预期间肾毒性这一持续存在的障碍。