DOI: 10.1172/jci195639 ISSN: 1558-8238

Discovery and therapeutic delivery of microRNAs targeting deregulated glioblastoma pathways inhibits tumor growth in mice

Shekhar Saha, Ying Zhang, Myron K. Gibert Jr., Collin Dube, Farina Hanif, Elizabeth Qian Xu Mulcahy, Sylwia Bednarek, Yunan Sun, Pawel Marcinkiewicz, Xiantao Wang, Gijung Kwak, Ahsan H. Polash, Haolin Li, Kadie Hudson, Manikarna Dinda, Tapas Saha, Matthew McCord, Fadila Guessous, Nichola Cruickshanks, Rossymar Rivera Colon, Lily Dell'Olio, Rajitha Anbu, Wenjie Liu, Songy Choi, Benjamin Kefas, Pankaj Kumar, Alexander L. Klibanov, David Schiff, Jung Soo Suk, Justin Hanes, Jamie Mata, Markus Hafner, Roger Abounader

Glioblastoma is a fatal primary malignant brain tumor, with an average survival of 15 months despite surgical resection, chemotherapy, and radiation therapy. Due to the concurrent deregulation of numerous genes in glioblastoma, molecular monotherapies have not improved clinical outcomes. Evidence suggests that targeting multiple deregulated molecules is essential for better therapies; however, this is limited by the lack of suitable drugs and increased toxicity of combination therapies. To address this, we hypothesized that miRNAs, small gene-regulatory RNAs that suppress mRNA, could simultaneously inhibit multiple deregulated genes in glioblastoma, and be used for more effective therapies. We identified regulatory miRNAs — those that target several deregulated genes in glioblastoma — using a combination of PAR-CLIP screening, TCGA data analyses and an algorithm to rank target importance and miRNA therapeutic potential. We selected two tumor suppressor miRNAs, miR-340 and miR-382, and one oncogenic miRNA, miR-17 and showed that they target critical glioblastoma pathways and alter cell growth, survival, invasion, and in vivo tumor growth. We developed and successfully applied a miRNA therapeutic delivery approach using Brain Penetrating Nanoparticles combined with MRI-guided focused ultrasound and microbubbles, to inhibit established tumor growth and to extend animal survival. This strategy offers a promising approach for translating miRNA-based therapies into clinical trials for glioblastoma and other cancers.

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