Photoactivated bioinspired lipoplexes with a chalcone/flavylium photoswitch enhance siRNA delivery—towards precise spatiotemporal control in gene delivery

Abstract

The efficient delivery of nucleic acids (NAs) remains a major challenge in gene therapy due to their poor stability and limited cellular uptake. Even though non-viral vectors have been pivotal to overcoming some of these challenges, significant barriers, such as intracellular digestion of NAs and limited endosomal escape, still remain. Here, we developed novel stimuli-responsive lipoplexes integrating a 2-hydroxychalcone-based cationic amphiphile (C_nNCh, with 4 or 6 carbons in their alkyl chains, n = 4 or 6) and monoolein (MO). This combination leverages the photoisomerization and pH-sensitivity of chalcone derivatives, along with the fusogenic capabilities of MO, to achieve enhanced transfection efficiency via light irradiation. To reach this goal, we first assessed the cytotoxicity of the cationic amphiphiles in healthy and tumor cells. We then prepared mixtures with varying C_nNCh/MO molar ratios, yielding net cationic vesicles with long-term colloidal stability. Subsequently, NAs were efficiently compacted into lipoplexes at N/P ratios (positively charged nitrogen/negatively charged phosphate) higher than 1, attaining near-complete compaction. Light and pH stimuli induce the formation of the expected products, but without compromising lipoplex stability or activating premature NA release. Vesicles with different C_nNCh/MO molar ratios do not induce the loss of viability of normal fibroblasts for concentrations up to 50 µM. Crucially, siRNA-lipoplex mixtures having C₄NCh/MO molar ratios of 1/1 and 2/1 (N/P = 6) achieve significant GFP knockdown after irradiation, indicative of successful siRNA delivery and biological effects. Using biomimicking endosomal membranes, we show that photoactivation enhances membrane fusion, suggesting a mechanism entailing light-mediated endosomal escape. Our study provides proof-of-concept for a “light-switch” mechanism offering precise spatiotemporal control over gene silencing, a highly desirable feature in therapeutic applications.