Multiplexed RNAi Therapy Against Brain Tumor-initiating Cells Via Lipopolymeric Nanoparticle Infusion Delays Glioblastoma Progression

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2017 Jul 12

PMID 28696296

Citations 56

Authors

Dou Yu

Omar F Khan

Mario L Suva

Biqin Dong

Wojciech K Panek

Ting Xiao

Meijing Wu

Yu Han

Atique U Ahmed

Irina V Balyasnikova

Hao F Zhang

Cheng Sun

Robert Langer

Daniel G Anderson

Maciej S Lesniak

Affiliations

Soon will be listed here.

Abstract

Brain tumor-initiating cells (BTICs) have been identified as key contributors to therapy resistance, recurrence, and progression of diffuse gliomas, particularly glioblastoma (GBM). BTICs are elusive therapeutic targets that reside across the blood-brain barrier, underscoring the urgent need to develop novel therapeutic strategies. Additionally, intratumoral heterogeneity and adaptations to therapeutic pressure by BTICs impede the discovery of effective anti-BTIC therapies and limit the efficacy of individual gene targeting. Recent discoveries in the genetic and epigenetic determinants of BTIC tumorigenesis offer novel opportunities for RNAi-mediated targeting of BTICs. Here we show that BTIC growth arrest in vitro and in vivo is accomplished via concurrent siRNA knockdown of four transcription factors (SOX2, OLIG2, SALL2, and POU3F2) that drive the proneural BTIC phenotype delivered by multiplexed siRNA encapsulation in the lipopolymeric nanoparticle 7C1. Importantly, we demonstrate that 7C1 nano-encapsulation of multiplexed RNAi is a viable BTIC-targeting strategy when delivered directly in vivo in an established mouse brain tumor. Therapeutic potential was most evident via a convection-enhanced delivery method, which shows significant extension of median survival in two patient-derived BTIC xenograft mouse models of GBM. Our study suggests that there is potential advantage in multiplexed targeting strategies for BTICs and establishes a flexible nonviral gene therapy platform with the capacity to channel multiplexed RNAi schemes to address the challenges posed by tumor heterogeneity.

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