Amphiphilic poly(α)glutamate polymeric micelles for systemic administration of siRNA to tumors.

RNAi therapeutics carried a great promise to the area of personalized medicine: the ability to target "undruggable" oncogenic pathways. Nevertheless, their efficient tumor targeting via systemic administration had not been resolved yet. Amphiphilic alkylated poly(α)glutamate amine (APA) can serve as a cationic carrier to the negatively-charged oligonucleotides. APA polymers complexed with siRNA to form round-shaped, homogenous and reproducible nano-sized polyplexes bearing ~50 nm size and slightly negative charge. In addition, APA:siRNA polyplexes were shown to be potent gene regulators in vitro. In light of these preferred physico-chemical characteristics, their performance as systemically-administered siRNA nanocarriers was investigated. Intravenously-injected APA:siRNA polyplexes accumulated selectively in tumors and did not accumulate in the lungs, heart, liver or spleen. Nevertheless, the polyplexes failed to induce specific mRNA degradation, hence neither reduction in tumor volume nor prolonged mice survival was seen.

Structure-Function Correlation of Aminated Poly(α)glutamate as siRNA Nanocarriers.

It has been two decades since cationic polymers were introduced to the world of oligonucleotides delivery. However, the optimal physicochemical properties to make them a successful delivery vehicle are yet unknown. An ideal system became particularly interesting and necessary with the introduction of RNA interference as a promising therapeutic approach. Such nanocarrier should overcome challenges such as low plasma stability, poor cellular internalization and endosomal escape to induce gene silencing. To that end, we synthesized a library of biodegradable aminated poly(α)glutamate varied by amine moieties. In an attempt to elucidate the structure-function relationship, our polyplexes were physicochemically characterized and their silencing activity and cytotoxicity were evaluated. We found several structures that demonstrated improved cellular internalization. These candidates silenced gene expression to less than 50% of their initial levels, while being safe to cells and mice. Based on our research, an improved and promising tailor-designed siRNA delivery platform can be developed.

Molecular Weight-Dependent Activity of Aminated Poly(α)glutamates as siRNA Nanocarriers.

RNA interference (RNAi) can contribute immensely to the area of personalized medicine by its ability to target any gene of interest. Nevertheless, its clinical use is limited by lack of efficient delivery systems. Polymer therapeutics can address many of the challenges encountered by the systemic delivery of RNAi, but suffer from inherent drawbacks such as polydispersity and batch to batch heterogeneity. These characteristics may have far-reaching consequences when dealing with therapeutic applications, as both the activity and the toxicity may be dependent on the length of the polymer chain. To investigate the consequences of polymers' heterogeneity, we have synthesized two batches of aminated poly(α)glutamate polymers (PGAamine), differing in their degree of polymerization, but not in the monomer units or their conjugation. Isothermal titration calorimetry study was conducted to define the binding affinity of these polymers with siRNA. Molecular dynamics simulation revealed that Short PGAamine:siRNA polyplexes exposed a higher amount of amine moieties to the surroundings compared to Long PGAamine. This resulted in a higher zeta potential, leading to faster degradation and diminished gene silencing. Altogether, our study highlights the importance of an adequate physico-chemical characterization to elucidate the structure⁻function-activity relationship, for further development of tailor-designed RNAi delivery vehicles.

Amphiphilic nanocarrier-induced modulation of PLK1 and miR-34a leads to improved therapeutic response in pancreatic cancer.

The heterogeneity of pancreatic ductal adenocarcinoma (PDAC) suggests that successful treatment might rely on simultaneous targeting of multiple genes, which can be achieved by RNA interference-based therapeutic strategies. Here we show a potent combination of microRNA and siRNA delivered by an efficient nanocarrier to PDAC tumors. Using proteomic-microRNA profiles and survival data of PDAC patients from TCGA, we found a novel signature for prolonged survival. Accordingly, we used a microRNA-mimic to increase miR-34a together with siRNA to silence PLK1 oncogene. For in vivo dual-targeting of this combination, we developed a biodegradable amphiphilic polyglutamate amine polymeric nanocarrier (APA). APA-miRNA-siRNA polyplexes systemically administered to orthotopically inoculated PDAC-bearing mice showed no toxicity and accumulated at the tumor, resulting in an enhanced antitumor effect due to inhibition of MYC oncogene, a common target of both miR-34a and PLK1. Taken together, our findings warrant this unique combined polyplex's potential as a novel nanotherapeutic for PDAC.

Systemic delivery of siRNA by aminated poly(α)glutamate for the treatment of solid tumors.

Small interfering RNA (siRNA) can silence the expression of a targeted gene in a process known as RNA interference (RNAi). As a consequence, RNAi has immense potential as a novel therapeutic approach in cancer targeted therapy. However, successful application of siRNA for therapeutic purposes is challenging due to its rapid renal clearance, degradation by RNases in the bloodstream, poor cellular penetration, immunogenicity and aggregation in the blood. In addition, the few oligonucleotide-based nanomedicines that reached clinical trials either go to the liver following systemic administration or are applied topically. Treatment of solid tumors requires selective distribution of siRNA to the target tissue, hence there is an unmet medical need for an efficacious and safe nano-sized delivery system for their clinical use. To overcome these hurdles, we have designed, synthesized and physico-chemically characterized a novel nanocarrier based on aminated poly(α)glutamate (PGAamine). This cathepsin B-biodegradable polymer interacts electrostatically with the siRNA to form a nano-sized polyplex stable in plasma. Treatment with PGAamine-Rac1 siRNA polyplex (siRac1-polyplex) caused specific gene silencing by 80% in HeLa and SKOV-3 human ovarian adenocarcinoma cells as opposed to PGAamine-control non-targeting siRNA polyplex (siCtrl-polyplex) leading to inhibition of cell migration and wound healing abilities. A stepwise dose escalation was performed in order to determine the in vivo maximum tolerated dose (MTD). This was followed by intraperitoneal administration of siRac1-polyplex to mCherry-labeled ovarian adenocarcinoma-bearing mice leading to preferred tumor accumulation of siRac1 (8-fold) which resulted in 38% Rac1 knockdown. Furthermore, the polyplex was administered intravenously to lung carcinoma-bearing mice in which it caused 33% Rac1 knockdown. These promising results led to efficacy studies administering systemic treatment with an anticancer siRNA, siPlk1-polyplex, which inhibited tumor growth by 73% and 87% compared with siCtrl-polyplex or saline-treated mice, respectively, leading to prolonged overall survival. These findings represent the first time that a polyaminated poly(α)glutamate polymer is used for an efficacious and safe tumor delivery of RNAi following systemic administration.