Synthetic Polyamines to Regulate mRNA Translation through the Preservative Binding of Eukaryotic Initiation Factor 4E to the Cap Structure.

Polyion complexes (PICs) of mRNA with synthetic polyamines are receiving increasing attention as mRNA delivery vehicles, and the search for polyamine structure maximizing the translational efficiency of complexed mRNA becomes a critical research topic. Herein, we discovered that fine-tuning of the protonation status of synthetic polyamines can regulate mRNA translation through the preservative binding of eukaryotic initiation factor 4E to m(7)GpppN (cap structure) on the 5' end of mRNA. A series of polyamines with varied numbers of aminoethylene repeats in their side chains were prepared by an aminolysis reaction of poly(ß-benzyl-l-aspartate) and paired with mRNA to form PICs. PICs formed from polyamines with higher numbers of aminoethylene repeats preserved the original translational efficiency to naked mRNA, whereas the efficiency significantly dropped by decreasing the number of aminoethylene repeats in the polyamines. Immunoprecipitation assays using anti-eIF4E antibodies revealed that the binding affinity of eIF4E to the cap structure of mRNA in the PIC was sensitive to the number of charged aminoethylene repeats in the polyamine side chain and was strongly correlated with their translational efficiency. These results indicate that the fine-tuning of the polyamine structure plays a critical role in maximizing the translational efficiency of mRNA in the PICs having potential utility as mRNA delivery vehicles.

Messenger RNA delivery of a cartilage-anabolic transcription factor as a disease-modifying strategy for osteoarthritis treatment.

Osteoarthritis (OA) is a chronic degenerative joint disease and a major health problem in the elderly population. No disease-modifying osteoarthritis drug (DMOAD) has been made available for clinical use. Here we present a disease-modifying strategy for OA, focusing on messenger RNA (mRNA) delivery of a therapeutic transcription factor using polyethylene glycol (PEG)-polyamino acid block copolymer-based polyplex nanomicelles. When polyplex nanomicelles carrying the cartilage-anabolic, runt-related transcription factor (RUNX) 1 mRNA were injected into mouse OA knee joints, OA progression was significantly suppressed compared with the non-treatment control. Expressions of cartilage-anabolic markers and proliferation were augmented in articular chondrocytes of the RUNX1-injected knees. Thus, this study provides a proof of concept of the treatment of degenerative diseases such as OA by the in situ mRNA delivery of therapeutic transcription factors; the presented approach will directly connect basic findings on disease-protective or tissue-regenerating factors to disease treatment.

Systemic delivery of messenger RNA for the treatment of pancreatic cancer using polyplex nanomicelles with a cholesterol moiety.

Systemic delivery of messenger RNA (mRNA) is technically challenging because mRNA is highly susceptible to enzymatic degradation in the blood circulation. In this study, we used a nanomicelle-based platform, prepared from mRNA and poly(ethylene glycol) (PEG)-polycation block copolymers. A cholesterol (Chol) moiety was attached to the ω-terminus of the block copolymer to increase the stability of the nanomicelle by hydrophobic interaction. After in vitro screening, polyaspartamide with four aminoethylene repeats in its side chain (PAsp(TEP)) was selected as the cationic segment of the block copolymer, because it contributes to enhance nuclease resistance and high protein expression from the mRNA. After intravenous injection, PEG-PAsp(TEP)-Chol nanomicelles showed significantly enhanced blood retention of mRNA in comparison to nanomicelles without Chol. We used the nanomicelles for treating intractable pancreatic cancer in a subcutaneous inoculation mouse model through the delivery of mRNA encoding an anti-angiogenic protein (sFlt-1). PEG-PAsp(TEP)-Chol nanomicelles generated efficient protein expression from the delivered mRNA in tumor tissue, resulting in remarkable inhibition of the tumor growth, whereas nanomicelles without Chol failed to show a detectable therapeutic effect. In conclusion, the stabilized nanomicelle system led to the successful systemic delivery of mRNA in therapeutic application, holding great promise for the treatment of various diseases.

Regulated protonation of polyaspartamide derivatives bearing repeated aminoethylene side chains for efficient intracellular siRNA delivery with minimal cytotoxicity.

The effects of the repeated number (RN) of aminoethylene (AE) units in polyaspartamide side chains were investigated for polyion complex (PIC)-based siRNA delivery. Reduction of the apparent RN from 3 to 2 by thiourea introduction increased a protonatable amine fraction in AE units at endosomal pH, leading to the efficient endosomal escape of siRNA-loaded PICs.

Modulated protonation of side chain aminoethylene repeats in N-substituted polyaspartamides promotes mRNA transfection.

Fine-tuning of chemical structures of polycation-based carriers (polyplexes) is an attractive strategy for safe and efficient mRNA transfaction. Here, mRNA polyplexes comprising N-substituted polyaspartamides with varied numbers of side chain aminoethylene repeats were constructed, and their transfection ability against human hepatoma cells was examined. Transfection efficacy clearly correlated with the number of aminoethylene repeats: polyplexes with odd number repeats (PA-Os) produced sustained increases in mRNA expression compared with those with even number repeats (PA-Es). This predominant efficacy of PA-Os over PA-Es was contradictory to our previous findings for pDNA polyplexes prepared from the same N-substituted polyaspartamides, that is, PA-Es revealed superior transfection efficacy of pDNA than PA-Os. Intracellular FRET analysis using flow cytometry and polyplex tracking under confocal laser scanning microscopy revealed that overall transfection efficacy was determined through the balance between endosomal escaping capability and stability of translocated mRNA in cytoplasm. PA-Es efficiently transported mRNA into the cytoplasm. However, their poor cytoplasmic stability led to facile degradation of mRNA, resulting in a less durable pattern of transfection. Alternatively, PA-Os with limited capability of endosomal escape eventually protect mRNA in the cytoplasm to induce sustainable mRNA expression. Higher cytoplasmic stability of pDNA compared to mRNA may shift the limiting step in transfection from cytoplasmic stability to endosomal escape capacity, thereby giving an opposite odd-even effect in transfection efficacy. Endosomal escaping capability and nuclease stability of polyplexes are correlated with the modulated protonation behavior in aminoethylene repeats responding to pH, appealing the substantial importance of chemistry to design polycation structures for promoted mRNA transfection.

In vivo messenger RNA introduction into the central nervous system using polyplex nanomicelle.

Messenger RNA (mRNA) introduction is a promising approach to produce therapeutic proteins and peptides without any risk of insertion mutagenesis into the host genome. However, it is difficult to introduce mRNA in vivo mainly because of the instability of mRNA under physiological conditions and its strong immunogenicity through the recognition by Toll-like receptors (TLRs). We used a novel carrier based on self-assembly of a polyethylene glycol (PEG)-polyamino acid block copolymer, polyplex nanomicelle, to administer mRNA into the central nervous system (CNS). The nanomicelle with 50 nm in diameter has a core-shell structure with mRNA-containing inner core surrounded by PEG layer, providing the high stability and stealth property to the nanomicelle. The functional polyamino acids possessing the capacity of pH-responsive membrane destabilization allows smooth endosomal escape of the nanomicelle into the cytoplasm. After introduction into CNS, the nanomicelle successfully provided the sustained protein expression in the cerebrospinal fluid for almost a week. Immune responses after mRNA administration into CNS were effectively suppressed by the use of the nanomicelle compared with naked mRNA introduction. In vitro analyses using specific TLR-expressing HEK293 cells confirmed that the nanomicelle inclusion prevented mRNA from the recognition by TLRs. Thus, the polyplex nanomicelle is a promising system that simultaneously resolved the two major problems of in vivo mRNA introduction, the instability and immunogenicity, opening the door to various new therapeutic strategies using mRNA.

Enhanced stability and gene silencing ability of siRNA-loaded polyion complexes formulated from polyaspartamide derivatives with a repetitive array of amino groups in the side chain.

The delivery of siRNA therapeutics owes its success to the development of carrier systems with high efficacy and minimum toxicity. Here, cationic polyaspartamide derivatives with a regulated number and spacing of positively charged amino groups in the side chain were prepared from a single platform polymer of poly(ß-benzyl l-aspartate) to assess their availability as siRNA carriers through polyion complex (PIC) formation. These polymers have 1,2-diaminoethane, 1,3-diaminopropane, and N,N'-bis(2-aminoethyl)-1,2-diaminoethane moieties in the side chain, and are termed as PAsp(DET), PAsp(DPT), and PAsp(TEP), respectively. siRNA-loaded PICs stable in serum-containing media were formed from PAsp(TEP) and PAsp(DPT) with two positive charges in the side chain at pH 7.4, whereas no such stable PIC was obtained from PAsp(DET) with only a single charge in the side chain, suggesting facilitated multivalent interactions with siRNA molecules to increase the PIC stability. The PAsp(DPT) and PAsp(TEP) PICs stable in the serum-containing media underwent an appreciably enhanced uptake into cultured cells through endocytosis, and subsequently exerted effective endosomal escape for the significant silencing of target gene expression. Notably, PAsp(TEP) PIC displayed negligible cytotoxicity in sharp contrast to the highly toxic feature of PAsp(DPT) PIC. This cytotoxicity is apparently correlated with the minimal damage to the cytoplasmic membrane of cells exposed to PAsp(TEP) at pH 7.4 evidenced from the fluorescent dye (YO-PRO-1) permeation assay. There was, in turn, a significant increase in YO-PRO-1 permeability at endosomal pH of 5.5 for PAsp(TEP)-exposed cells, indicating that PAsp(TEP) exerts membrane damage in a pH-selective manner, and eventually facilitates the translocation of siRNA-loaded PIC from the acidic endosomal compartment into the cytoplasm for effective gene silencing without any severe toxicity at physiological conditions. This acidic pH modulated enhancement in membrane damage of PAsp(TEP) may be explained by an increased protonation of the arrayed amino groups in the side chain that strongly perturb the endosomal membrane integrity. Eventually, PAsp(TEP) with a side chain array of pH-sensitive amino groups was demonstrated to be a promising component for constructing siRNA carriers exerting effective gene silencing in a less toxic context.

Odd-even effect of repeating aminoethylene units in the side chain of N-substituted polyaspartamides on gene transfection profiles.

A series of the N-substituted polyaspartamides possessing repeating aminoethylene units in the side chain was prepared in this study to identify polyplexes with effective endosomal escape and low cytotoxicity. All cationic N-substituted polyaspartamides showed appreciably lower cytotoxicity than that of commercial transfection reagents. Interestingly, a distinctive odd-even effect of the repeating aminoethylene units in the polymer side chain on the efficiencies of endosomal escape and transfection to several cell lines was observed. The polyplexes from the polymers with an even number of repeating aminoethylene units (PA-Es) achieved an order of magnitude higher transfection efficiency, without marked cytotoxicity, than those of the polymers with an odd number of repeating aminoethylene units (PA-Os). This odd-even effect agreed well with the buffering capacity of these polymers as well as their capability to disrupt membrane integrity selectively at endosomal pH, leading to highly effective endosomal escape of the PA-E polyplexes. Furthermore, the formation of a polyvalent charged array with precise spacing between protonated amino groups in the polymer side chain was shown to be essential for effective disruption of the endosomal membrane, thus facilitating transport of the polyplex into the cytoplasm. These data provide useful knowledge for designing polycations to construct safe and efficient nonviral gene carriers.