Gaëlle Creusat

Proton Sponge Trick for pH-Sensitive Disassembly of Polyethylenimine-Based siRNA Delivery Systems

Small interfering RNAs offer novel opportunities to inhibit gene expression in a highly selective and efficient manner but depend on cytosolic translocation with synthetic delivery systems. The polyethylenimine (PEI) is widely used for plasmid DNA transfection. However, the water-soluble PEI does not form siRNA polyplexes stable enough in extracellular media for effective delivery. We previously showed that rendering PEI insoluble in physiological media, without modifying drastically its overall cationic charge density, by simple conjugation with natural hydrophobic alpha-amino acids, can lead to effective siRNA delivery in mammalian cells. In here, we comprehensively investigated the mechanism behind the excellent efficacy of the leading PEIY vector. Our data revealed that the underlining proton sponge property is key to the effectiveness of the tyrosine-polyethylenimine conjugate as it may allow both endosomal rupture and siRNA liberation via an optimal pH-sensitive dissolution of the PEIY self-aggregates. Altogether, these results should facilitate the development of novel and more sophisticated siRNA delivery systems.

Self-Assembling Polyethylenimine Derivatives Mediate Efficient siRNA Delivery in Mammalian Cells

Synthetic 21–22-nt-long RNA duplexes (siRNAs) can trigger specific mRNA degradation and selectively control gene expression, and because of this they have potential therapeutic applications. Unfortunately, the intracellular localization of siRNA targets and the inability of oligonucleotides to diffuse across cellular membranes requires siRNA conjugation or formulation with synthetic delivery vectors. Interestingly, polyACHTUNGTRENNUNGethylenimine (PEI), a popular gene transfection agent that showed promise for cancer gene therapy, appears inefficient for siRNA delivery in vitro. The poor performance of PEI could be linked with the length of the siRNA anionic segment, which is too short to maintain electrostatic cohesion with the soluble cationic polymer. Consequently, siRNA polyplexes break apart too readily upon contact with polyanions present at cell surfaces. We reasoned that the transformation of water-soluble PEI into a molecule with self-assembly properties should stabilize siRNA polyplexes and hence favor overall siRNA delivery. A water-soluble polymer could acquire new aggregating properties through the addition of hydrophobic domains. We avoided using alkyl chains, which, by mixing with the cell lipid bilayer, might act as a detergent and cause cell death. Our preference was instead for natural a-amino acids with decreasing hydropathy indices, such as leucine (L), phenylalanine (F), tryptophan (W), and tyrosine (Y). Indeed, these amino acids constitute the cores of globular proteins and help maintain protein structures. They also can be coupled to PEI amines without destroying nucleic acid binding properties, because over the course of the reaction a cationic amine replaces the reacted one. Commercially available 25 kDa branched PEI contains primary, secondary, and tertiary amines in a ratio of 1:1:1. The primary amines were allowed to react fully with the succinimidyl esters of butyloxycarbonyl-protected amino-acids (Bocaa-OSu) (Scheme 1). Removal of the Boc groups with trifluoroacetic acid (TFA) and subsequent dialysis in aqueous HCl gave the desired products, with a-amino acid contents of 30 % per ethylenimine, in 30–60 % overall yields. The aggregating properties of the polymers were evaluated by measurement of dynamic light scattering (Table 1). All polymers, as hydrochloride salts, were soluble in water, even at a concentration of 0.5 m. Upon dilution in RPMI cell culture medium, no light scattering signals were detected in the cases of PEI and PEIL. On the other hand, PEIF, PEIW, and PEIY self-assembled into particles with apparent diameters between 0.3– 0.7 mm. Addition of siRNA permitted PEI and PEIL to form complexes and led to slight increases in the sizes of the self-assembling polymers in a range that had previously been observed to be effective for PEI-mediated gene delivery. Transmission electron micrographs showed that PEIY (Figure 1 A) forms fiber-like structures of fused irregular spheroids roughly 20 nm in diameter. Addition of siRNA (Figure 1 B) led to a twofold ACHTUNGTRENNUNGdiminution in the fiber diameters and to further clustering. Nanoparticles, including viruses, are too large to diffuse freely across membranes and thus need to divert the cell machinery for translocation. They first anchor to receptors on the cellular surface and are then actively dragged into cells within membrane-coated vesicles (often endosomes). Evidence suggests that the high buffer capacity of PEI enables rupture of the endosome membranes and hence effective nucleic acid translocation. We therefore examined whether amino acid modification impacted this important function by acid–base ACHTUNGTRENNUNGtitration (Figure 1). Profiles of modified PEIs superposed almost perfectly in the pH 6.0–8.0 range and showed that the polymers have higher buffering capacities than PEI, probably due to the electron-withdrawing effect of carboxamide on the aterminal amines. This greater “proton sponge” ability should Scheme 1. Synthesis. a) Boc-aa-OSu. b) TFA.

Pyridylthiourea-grafted polyethylenimine offers an effective assistance to siRNA-mediated gene silencing in vitro and in vivo

Success of synthetic interfering nucleic acids (siRNAs)-based therapy relies almost exclusively on effective, safe and preferably nanometric delivery systems which can be easily prepared, even at high concentrations. We prepared by chemical synthesis various self-assembling polymers to entrap siRNAs into stable polyplexes outside cells but with a disassembly potential upon sensing endosomal acidity. Our results revealed that pyridylthiourea-grafted polyethylenimine (πPΕΙ) followed the above-mentioned principles. It led to above 90% siRNA-mediated gene silencing in vitro on U87 cells at 10 nM siRNA concentration and did not have a hemolytic activity. Assembly of siRNA/πPΕΙ at high concentration was then studied and 4.5% glucose solution, pH 6.0, yielded stable colloidal solutions with sizes slightly below 100 nm for several hours. A single injection of these concentrated siRNA polyplexes into luciferase-expressing human glioblastoma tumors, which were subcutaneously xenografted into nude mice, led to a significant 30% siRNA-mediated luciferase gene silencing 4 days post-injection. Our results altogether substantiate the potential of self-assembling cationic polymers with a pH-sensitive disassembly switch for siRNA delivery in vitro and also in vivo experiments.

Preparation and characterization of mTHPC-loaded solid lipid nanoparticles for photodynamic therapy

Among various attempts to enhance the therapeutic efficacy of photodynamic therapy (PDT), the specific delivery of photosensitizer (PS) in the tumor tissue is expected to improve its clinical applications. The aim of this study was to engineer lipid nanoparticles (LNP) with different sizes and various PS contents, using simple solvent-free and easily scale up manufacturing processes. Meso-(tetrahydroxyphenyl) chlorin (mTHPC) is one of the most potent photoactive compounds for clinical use. We demonstrated that mTHPC was efficiently incorporated into the lipid core of LNP, leading to a large range of stable and reproducible mTHPC-loaded LNP with narrow size distribution. Photophysical and physico-chemical properties of mTHPC-loaded LNP were assessed as well as absorption spectra and singlet oxygen emission, colloidal stability, particle size and zeta potential. The photocytotoxicity of selected mTHPC-loaded solid LNP was demonstrated on MCF-7 cells under irradiation at 652nm with a range of light fluence from 1.0 to 10J/cm(2). All physico-chemical, photophysical and biological results allow us to conclude that solid LNP appear as a very promising nano-mTHPC delivery system for PDT.

A Cationic Phospholipid–Detergent Conjugate as a New Efficient Carrier for siRNA Delivery

Nucleic acids have a huge intrinsic therapeutic potential that, however, relies heavily on the development of methods for their delivery to their intracellular target site. Cationic lipids and polymers were introduced more than twenty years ago for the delivery of DNA molecules to cells. Since then, they have become useful tools for biomedical research and have also been adopted for siRNA delivery. Their mode of action has been roughly determined. It is based on the property of adherent cell lines to easily internalize large quantities of cationic complexes in endocytic compartments, and on the incorporation of membrane-perturbing elements within internalized complexes to trigger subsequent release of the nucleic acid payload into the cytosol. Cationic lipids forming hexagonal phase or formulations of cationic lipids with the fusogenic lipid 1,2-dioleoyl-snglycero-3-phosphoethanolamine (DOPE) enable both the formation of cationic nucleic acid complexes (lipoplexes) and rupture of the endosome membrane. Yet, the endosomolytic activity of the current effective synthetic nucleic acid delivery systems remains low and effective delivery is only achieved by using cell entry pathways with a high flow rate. The membrane-disruptive properties of detergents have been considered for improving nucleic acid delivery. However, the use of detergents remains delicate because direct plasma membrane permeation might have an irreversible impact on cell viability. Cationic detergents have been shown to provoke DNA condensation but the resulting lipoplexes have turned out to be inactive or only poorly active, in vitro, when particles are prepared from cationic detergent mixed with DOPE. This is explained by the rapid exchange of the detergent molecules between the complex and the aqueous environment, which results in an irreversible decondensation of the nucleic acid even before entry into the cells. On the other hand, preparation of DNA lipoplexes from cationic lipids in the presence of Tween-80, a non-ionic detergent, has led to systems with enhanced gene transfection properties both in vitro and in vivo. These results led us to explore the consequences on nucleic acid delivery of the conjugation of a detergent molecule to a cationic lipid so that the detergent cannot be depleted from the transfection particle. We selected Triton X-100 (TX100) for its well-known detergent properties and for synthetic convenience. Furthermore, TX100 does not solubilize cholesterol-enriched raft domains, which might be involved in cationic lipoplexes internalization. TX100 was covalently linked to the phosphate group of 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC), a major component of biological membranes (Figure 1). Diacylglycerophosphocholines (PCs) are normal cellular metabolites and offer the opportunity to easily generate cationic lipids by O-alkylation of the phosphate group. Gorman et al. first demonstrated that a PC-derived phosphotriester (1,2-dimyristoyl-sn-glycero-3-ethylphosphocholine, EDMPC) can mediate efficient gene transfer. Later on, derivatives of DOPC (i.e., ethyl-DOPC, EDOPC, Figure 1) and other PCs were developed by MacDonald et al. , the physical and transfection properties of which were extensively investigated. We hypothesized that the covalent attachment of a detergent molecule and a natural phospholipid to form a cationic phospholipid–detergent conjugate might improve cell uptake and transfection efficiency of lipoplexes prepared thereof. TX100 conjugation to DOPC was realized according to Scheme 1. Detergent activation with trifluoromethanesulfonyl anhydride provided the corresponding sulfonyl ester. This compound is unstable and decomposes in a few hours on standing at room temperature in chloroform. Analysis of degradation products is consistent with a deoligomerization process leading to the formation of dioxane as reported previously with other PEG derivatives. Consequently, the sulfonyl ester (1 equiv) was directly submitted to nucleophilic displacement by the anionic phosphate in DOPC (3 equiv). Conjugate 1 was obtained in 32% yield and unreacted DOPC (61%) was recovered after purification. The use of a larger excess of activated TX100 (7 equiv) improved the DOPC conversion but finally proved detrimental as the purification of the product became difficult (1: 22%; recovered DOPC: 24%). Control compound 2 was prepared similarly, by replacing Triton X-100 by polyethylene glycol mono[a] Dr. P. Pierrat, Dr. G. Creusat, Dr. G. Laverny, Prof. F. Pons, Dr. G. Zuber, Dr. L. Lebeau Laboratoire de Conception et Application de Mol!cules Bioactives CNRS, Universit! de Strasbourg, Facult! de Pharmacie 74 Route du Rhin, BP 60024, Illkirch (France) Fax: (+33)333-6885-4306 E-mail : llebeau@unistra.fr Supporting information for this article is available on the WWW under http://dx.doi.org/10.1002/chem.201103645.

Phospholipid–Detergent Conjugates as Novel Tools for siRNA Delivery

One of the potential benefits of drug delivery systems in medicine is the creation of nanoparticle-based vectors that deliver a therapeutic cargo in sufficient quantity to a target site to enable a selective effect, width of the therapeutic window depending on the toxicity of the vector and the cargo. In this work, we intended to improve the siRNA delivery efficiency of a new kind of nucleic acid carrier, which is the result of the conjugation of the membrane phospholipid 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) to the membrane-active species Triton X-100 (TX100). We hypothesized that by improving the biodegradability the cytotoxicity of the conjugate might by reduced, whereas its original transfection potential would be tentatively preserved. DOPC was conjugated to Triton X-100 through spacers displaying various resistance to chemical hydrolysis and enzyme degradation. The results obtained through in vitro siRNA delivery experiments showed that the initial phosphoester bond can be replaced with a phospho(alkyl)enecarbonate group with no loss in the transfection activity, whereas the associated cytotoxicity was significantly decreased, as assessed by metabolic activity and membrane integrity measurements. The toxicity of the conjugates incorporating a phospho(alkyl)enesuccinnate moiety proved even lower but was clearly balanced with a reduction of the siRNA delivery efficiency. Hydrolytic stability and intracellular degradation of the conjugates were investigated by NMR spectroscopy and mass spectrometry. A general trend was that the more readily degraded conjugates were those with the lower toxicity. Otherwise, the phospho(alkyl)enecarbonate conjugates revealed some hemolytic activity, whereas the parent phosphoester did not. The reason why these conjugates behave differently with respect to hemolysis might be a consequence of unusual fusogenic properties and probably reflects the difference in the stability of the conjugates in the intracellular environment.

Novel glycolipid TLR2 ligands of the type Pam2Cys-α-Gal: Synthesis and biological properties

A more complete understanding of the mechanism of action of TLR agonists has fueled the investigation of new synthetic immunoadjuvants. In this context, we designed and synthesized glycolipids of the type Pam(2)Cys-α-Galactose as novel immunoadjuvants. Their synthesis required modifying a hydrophobic tBoc-[2,3-bispalmitoyloxy-(2R)-propyl]-R-cysteinyl moiety, i.e. the minimal structure required for TLR2 agonist activity, by addition of a hydrophilic head, either an α-Galactosylpyranose or an α-Galactosylfuranose to gain respectively Pam(2)CGalp and Pam(2)CGalf. While preparing a carbohydrate building block, an unexpected stereoselectivity was observed during a halide ion-catalytic process on a protected galactofuranose: the alpha anomer was obtained with surprisingly high selectivity (α/β ratio>9) and with good isolated yield (51%). The TLR2 binding properties of Pam(2)CGalp and Pam(2)CGalf were then fully evaluated. Their efficiency in triggering the proliferation of BALB/c mouse splenocytes was also compared to that of Pam(2)CAG and Pam(3)CAG, two well-established ligands of TLRs. Moreover, the maturation state of murine dendritic cells previously incubated with either Pam(2)CGalp or Pam(2)CGalf was monitored by flow cytometry and compared to that induced by lipopolysaccharide. Pam(2)CGalp and Pam(2)CGalf were found to be equivalent TLR2 agonists, and induced splenocyte proliferation and DC maturation. With very similar activity, Pam(2)CGalp and Pam(2)CGalf were also 10-fold to 100-fold better than Pam(2)CAG and Pam(3)CAG at inducing B cell proliferation. This represents the first time a glucidic head has been added to the tBoc-[2,3-bispalmitoyloxy-(2R)-propyl]-R-cysteinyl moiety whilst maintaining the immunomodulating activity. This should greatly enrich the data available on Pam(2)C structure/activity relationships.