Abstract
Multicomponent lipoplexes have recently emerged as especially promising transfection candidates, as they are from 10 to 100 times more efficient than binary complexes usually employed for gene delivery purposes. Previously, we investigated a number of chemical-physical properties of DNA-lipid complexes that were proposed to affect transfection efficiency (TE) of lipoplexes, such as nanoscale structure, size, surface potential, DNA-protection ability and DNA release from complexes upon interaction with cellular lipids. Although some minor differences between multicomponent and binary lipoplexes were found, they did not correlate clearly with efficiency. Instead, here we show that a marked difference between the cell internalization mechanism of binary and multicomponent lipoplexes does exist. Multicomponent lipoplexes significantly transfect cells at 4 °C, when endocytosis does not take place suggesting that they can enter cells via a temperature-independent mechanism. Confocal fluorescence microscopy experiments showed the existence of a correlation between endosomal escape and TE. Multicomponent lipoplexes exhibited a distinctive ability of endosomal escape and release DNA into the nucleus, whereas, poorly efficient binary lipoplexes exhibited minor, if any, endosomal rupture ability and remained confined in perinuclear late endosomes. Stopped-flow mixing measurements showed that the fusion rates of multicomponent cationic liposomes with anionic vesicles, used as model systems of cell membranes, were definitely shorter than those of binary liposomes. As either lipoplex uptake and endosomal escape involve fusion between lipoplex and cellular membranes, we suggest that a mechanism of lipoplex-cellular membrane interaction, driven by lipid mixing between cationic and anionic cellular lipids, does explain the TE boost of multicomponent lipoplexes.
Highlights
Research efforts are currently focused on studying diseases of genetic origin by introducing the defective gene(s) in malfunctioning target cells.[1]
TE was found to decrease (Table 1) with decreasing factor TE(37 1C)/TE(4 1C) varying from B20 for DOTAP–DOPC/DNA to B5.6 for DC-CholÀDOPE/DNA lipoplexes and to B2.4 for MC lipoplexes (Table 1)
TE was modeled as the sum of two distinct contributions: a TI term, (TE)TI 1⁄4 TE(4 1C), which is due to lipoplexes entered via a mechanism other than endocytosis and a second TD term, (TE)TD 1⁄4 TE(37 1C)À(TE)TI, which is due by lipoplexes internalized by endocytosis
Summary
Research efforts are currently focused on studying diseases of genetic origin by introducing the defective gene(s) in malfunctioning target cells.[1]. To better understand the mechanisms of cellular transfection and the phenomena responsible for efficiency differences between transfection reagents, we investigated the mechanisms of uptake and intracellular trafficking of three lipoplex formulations. These were chosen because they exhibited the most striking difference in TE.[14,15,16] The first formulation was the widely used delivery system made of the cationic lipid 1,2-dioleoyl-3trimethylammonium-propane (DOTAP) and the zwitterionic lipid dioleoylphosphocholine (DOPC). A clear correlation between the internalization mechanism of lipoplexes and their TE was found
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