Systemic delivery of siRNA down regulates brain prion protein and ameliorates neuropathology in prion disorder.

One of the main challenges for neurodegenerative disorders that are principally incurable is the development of new therapeutic strategies, which raises important medical, scientific and societal issues. Creutzfeldt-Jakob diseases are rare neurodegenerative fatal disorders which today remain incurable. The objective of this study was to evaluate the efficacy of the down-regulation of the prion protein (PrP) expression using siRNA delivered by, a water-in-oil microemulsion, as a therapeutic candidate in a preclinical study. After 12 days rectal mucosa administration of Aonys/PrP-siRNA in mice, we observed a decrease of about 28% of the brain PrP(C) level. The effect of Aonys/PrP-siRNA was then evaluated on prion infected mice. Several mice presented a delay in the incubation and survival time compared to the control groups and a significant impact was observed on astrocyte reaction and neuronal survival in the PrP-siRNA treated groups. These results suggest that a new therapeutic scheme based an innovative delivery system of PrP-siRNA can be envisioned in prion disorders.

A non-covalent strategy combining cationic lipids and CPPs to enhance the delivery of splice correcting oligonucleotides.

Modulation of pre-mRNA splicing by steric-block oligonucleotides constitutes a promising strategy for the treatment of many diseases, but requires efficient delivery to cell nuclei. In the present study, we evaluated the efficacy of a non-covalent strategy that combines a cell penetrating peptide with a lipoplex-based formulation to mediate the delivery of splice-switching oligonucleotides. The splice correcting ability of these new formulations was assessed using splice-switching oligonucleotides targeted towards the mutated splicing site of human beta-globin pre-mRNA in the HeLa pLuc/705 splice correction model. Importantly, the optimal splice correcting activity was exhibited by the formulation containing both lipid and peptide components, the order of component addition in these formulations being crucial for their efficacy. Our results demonstrate that the inclusion of cationic liposomes in the formulation provides the ability to improve release from endocytic vesicles, a barrier that severely limits the efficiency of oligonucleotide delivery by cell penetrating peptides. On the other hand, cell penetrating peptides potentiate the cellular uptake and delivery of the oligonucleotides by the lipoplexes. Moreover, when combining cell penetrating peptides with the lipoplex formulations, a significant reduction in the amount of required cationic lipid could be achieved, while maintaining or even enhancing biological activity.

Physico-chemical characteristics of lipoplexes influence cell uptake mechanisms and transfection efficacy.

BACKGROUND: Formulation of DNA/cationic lipid complexes (lipoplexes) designed for nucleic acid delivery mostly results in positively charged particles which are thought to enter cells by endocytosis. We recently developed a lipoplex formulation called Neutraplex that allows preparation of both cationic and anionic stable complexes with similar lipid content and ultrastructure. METHODOLOGY/PRINCIPAL FINDINGS: To assess whether the global net charge could influence cell uptake and activity of the transported oligonucleotides (on), we prepared lipoplexes with positive and negative charges and compared: (i) their physicochemical properties by zeta potential analysis and dynamic light scattering, (ii) their cell uptake by fluorescence microscopy and flow cytometry, and (iii) the biological activity of the transported ON using a splicing correction assay. We show that positively or negatively charged lipoplexes enter cells cells using both temperature-dependent and -independent uptake mechanisms. Specifically, positively charged lipoplexes predominantly use a temperature-dependent transport when cells are incubated OptiMEM medium. Anionic lipoplexes favour an energy-independent transport and show higher ON activity than cationic lipoplexes in presence of serum. However, lipoplexes with high positive global net charge and OptiMEM medium give the highest uptake and ON activity levels. CONCLUSIONS: These findings suggest that, in addition to endocytosis, lipoplexes may enter cell via a temperature-independent mechanism, which could be mediated by lipid mixing. Such characteristics might arise from the specific lipoplex ultrastructure and should be taken into consideration when developing lipoplexes designed for in vivo or ex vivo nucleic acid transfer.

Lipoplex and peptide-based strategies for the delivery of steric-block oligonucleotides.

Synthetic oligonucleotides offer interesting prospects for the control of gene expression but clinical applications have been severely limited by their poor bioavailability. Cationic lipids have been widely used for the delivery of charged oligonucleotide (ON) analogues but most of the commercial formulations are toxic and poorly stable in the presence of serum proteins. We have developed a DOGS/DOPE liposome formulation named DLS (for delivery liposomal system), that allows for the efficient nuclear delivery of negatively charged antisense ON analogues as monitored by fluorescence microscopy and by their ability to correct deficient pre-mRNA splicing, even in serum-supplemented cell culture. Uncharged DNA mimics such as peptide nucleic acids (PNA), or phosphorodiamidate morpholino (PMO) ON are particularly interesting for their high metabolic stability and affinity for complementary RNA targets but they cannot be delivered with cationic lipids. Cell penetrating peptides (CPP), such as Tat or penetratin, have been used widely as conjugates for the delivery of various biomolecules and might be appropriate for neutral ON analogues. However, entrapment within endocytic vesicles severely limits the efficiency of PNA delivery by CPPs in the absence of endosomolytic drugs, such as chloroquine. The conjugation of new arginine-rich CPPs to PNA allows efficient nuclear delivery in the absence of chloroquine as monitored in a splicing correction assay. Both strategies have their advantages but DLS-mediated delivery remains more efficient than CPP delivery for the nuclear targeting of splice correcting ON analogues in vitro.

Switching on transgene expression by correcting aberrant splicing using multi-targeting steric-blocking oligonucleotides.

BACKGROUND: Mutations leading to aberrant splicing are found as a cause of numerous pathologies. Splice-switching oligonucleotides (SSOs), which modify aberrant expression patterns of alternatively spliced mRNAs, are a novel means of potentially controlling such diseases. METHODS: We used an experimental model in which a mutated beta-globin intron, carrying an aberrant splice site at nucleotide 705, interrupts the coding region of the luciferase reporter gene inserted in HeLa pLuc/705 cells. We have optimized delivery of splice correcting, steric-blocking 2'-O-methyl SSOs targeting the 705 mutated region (2'-O-Me SSO(705)) with DLS (DLS: delivery liposomal system) lipoplexes. RESULTS: Optimal luciferase activity for DLS/2'-O-Me SSO(705) was achieved at 100 nM and was detectable at concentrations as low as 10 nM in serum-containing culture medium, confirming the potential of DLS lipoplex-mediated nuclear SSO delivery as observed in cellular uptake studies. We confirmed by cytofluorometry and epifluorescence microscopy the high potential of the DLS lipoplex for cellular and nuclear oligonucleotide uptake. The DLS lipoplex was then used to directly compare the intracellular efficacy of various SSO chemistries and sequences in correction of aberrant splicing. 2'-O-Methoxyethyl-oligodeoxyribonucleoside phosphorothioates had a greater activity than 2'-O-methyl phosphodiester or 2'-O-methyl-phosphorothioate oligoribonucleotides. Targeting the splicing enhancer 623 region upstream was as efficient as targeting the 705 splice site, and, remarkably, simultaneous targeting of both sites was more efficient than treatment of the cells either with 2'-O-Me SSO(705) or 2'-O-Me SSO(623) alone. CONCLUSIONS: We demonstrated that SSOs can switch on luciferase activity in HeLa cells previously transfected with the pLuc/705 plasmid via the same DLS vector and provides a novel approach to modulate the expression of a transgene.

Comparison of basic peptides- and lipid-based strategies for the delivery of splice correcting oligonucleotides.

Expression of alternatively spliced mRNA variants at specific stages of development or in specific cells and tissues contributes to the functional diversity of the human genome. Aberrations in alternative splicing were found as a cause or a contributing factor to the development, progression, or maintenance of numerous diseases. The use of antisense oligonucleotides (ON) to modify aberrant expression patterns of alternatively spliced mRNAs is a novel means of potentially controlling such diseases. Oligonucleotides can be designed to repair genetic mutations, to modify genomic sequences in order to compensate for gene deletions, or to modify RNA processing in order to improve the effects of the underlying gene mutation. Steric block ON approach have proven to be effective in experimental model for various diseases. Here, we describe our experience in investigating two strategies for ON delivery: ON conjugation with basic peptides and lipid-based particulate system (lipoplex). Basic peptides or Cell Penetrating Peptides (CPP) such as the TAT-derived peptide appear to circumvent many problems associated with ON and drug delivery. This strategy may represent the next paradigm in our ability to modulate cell function and offers a unique avenue for the treatment of disease. Lipoplexes result from the intimate interaction of ON with cationic lipids leading to ON carrying particles able to be taken up by cells and to release ON in the cytoplasm. We have used as an experimental model the correction of a splicing alteration of the mutated beta-globin intron causing thalassemia. Data on cell penetration and efficacy of correction of specific steric block ON delivered either by basic peptides or lipoplex are described. A comparison of the properties of both delivery systems is made respective to the use of this new class of therapeutic molecules.