RNAi nanoparticles in the service of personalized medicine

Efficacy of a novel class of RNA interference therapeutic agents

RNA interference (RNAi) is being widely used in functional gene research and is an important tool for drug discovery. However, canonical double-stranded short interfering RNAs are unstable and induce undesirable adverse effects, and thus there is no currently RNAi-based therapy in the clinic. We have developed a novel class of RNAi agents, and evaluated their effectiveness in vitro and in mouse models of acute lung injury (ALI) and pulmonary fibrosis. The novel class of RNAi agents (nkRNA®, PnkRNA™) were synthesized on solid phase as single-stranded RNAs that, following synthesis, self-anneal into a unique helical structure containing a central stem and two loops. They are resistant to degradation and suppress their target genes. nkRNA and PnkRNA directed against TGF-β1mRNA ameliorate outcomes and induce no off-target effects in three animal models of lung disease. The results of this study support the pathological relevance of TGF-β1 in lung diseases, and suggest the potential usefulness of these novel RNAi agents for therapeutic application.

Promise and Challenge of RNA Interference–Based Therapy for Cancer

Cancer therapeutics still fall far short of our goals for treating patients with locally advanced or metastatic disease. Until recently, almost all cancer drugs were crude cytotoxic agents that discriminate poorly between cancer cells and normally dividing cells. The development of targeted biologics that recognize tumor cell surface antigens and of specific inhibitors of pathways dysregulated in cancer cells or normal cellular pathways on which a cancer cell differentially depends has provided hope for converting our increasing understanding of cellular transformation into intelligently designed anticancer therapeutics. However, new drug development is painfully slow, and the pipeline of new therapeutics is thin. The discovery of RNA interference (RNAi), a ubiquitous cellular pathway of gene regulation that is dysregulated in cancer cells, provides an exciting opportunity for relatively rapid and revolutionary approaches to cancer drug design. Small RNAs that harness the RNAi machinery may become the next new class of drugs for treating a variety of diseases. Although it has only been 9 years since RNAi was shown to work in mammalian cells, about a dozen phase I to III clinical studies have already been initiated, including four for cancer. So far there has been no unexpected toxicity and suggestions of benefit in one phase II study. However, the obstacles for RNAi-based cancer therapeutics are substantial. This article will discuss how the endogenous RNAi machinery might be harnessed for cancer therapeutics, why academic researchers and biotech and pharmaceutical companies are so excited, and what the obstacles are and how they might be overcome.

Induction of therapeutic gene silencing in leukocyte-implicated diseases by targeted and stabilized nanoparticles: a mini-review

RNA interference (RNAi) is a highly conserved endogenous mechanism that uses small RNA species to guide the sequence-specific silencing of gene expression. The discovery that RNAi functions in mammalian cells to regulate important cellular processes suggested that harnessing these endogenous gene-silencing pathways can prove to be an effective method for the targeted silencing of gene expression. Yet, the key challenge in translating the discovery of RNAi into a novel therapeutic modality is the lack of effective and safe delivery strategies. Here, we describe the major systemic delivery platforms that have been developed. Focus is given to the development of new strategies to target leukocytes, which are among the most difficult cells to transduce with RNAi. Finally, we discuss our strategies to target subsets of leukocytes using integrin-targeted and stabilized nanoparticles (I-tsNPs).

RNAi nanomedicines: challenges and opportunities within the immune system

RNAi, as a novel therapeutic modality, has an enormous potential to bring the era of personalized medicine one step further from notion into reality. However, delivery of RNAi effector molecules into their target tissues and cells remain extremely challenging. Major attempts have been made in recent years to develop sophisticated nanocarriers that could overcome these hurdles. This review will present the recent progress with the challenges and opportunities in this emerging field, focusing mostly on the in vivo applications with special emphasis on the strategies for RNAi delivery into immune cells.