Cationic liposome-DNA complexes: from liquid crystal science to gene delivery applications.

At present, there is an unprecedented level of interest in the properties and structures of complexes consisting of DNA mixed with oppositely charged cationic liposomes (CLs). The interest arises because the complexes mimic natural viruses as chemical carriers of DNA into cells in worldwide human gene therapy clinical trials. However, since our understanding of the mechanisms of action of CL-DNA complexes interacting with cells remains poor, significant additional insights and discoveries will be required before the development of efficient chemical carriers suitable for long-term therapeutic applications. Recent studies describe synchrotron X-ray diffraction, which has revealed the liquid crystalline nature of CL-DNA complexes, and three-dimensional laser-scanning confocal microscopy, which reveals CL-DNA pathways and interactions with cells. The importance of the liquid crystalline structures in biological function is revealed in the application of these modern techniques in combination with functional transfection efficiency measurements, which shows that the mechanism of gene release from complexes in the cell cytoplasm is dependent on their precise liquid crystalline nature and the physical and chemical parameters (for example, the membrane charge density) of the complexes. In [section sign] 5, we describe some recent new results aimed at developing bionanotube vectors for gene delivery.

Lipoplex structures and their distinct cellular pathways.

Cationic liposomes (CLs) are used as non-viral vectors in worldwide clinical trials of gene therapy. Among other advantages, CL-DNA complexes have the ability to transfer very large genes into cells. However, since the understanding of their mechanisms of action is still incomplete, their transfection efficiencies remain low compared to those of viruses. We describe recent studies which have started to unravel the relationship between the distinct structures and physicochemical properties of CL-DNA complexes and their transfection efficiency by combining several techniques: synchrotron X-ray diffraction for structure determination, laser-scanning confocal microscopy to probe the interactions of CL-DNA particles with cells, and luciferase reporter-gene expression assays to measure transfection efficiencies in mammalian cells. Most CL-DNA complexes form a multilayered structure with DNA sandwiched between the cationic lipids (lamellar complexes, LalphaC). Much more rarely, an inverted hexagonal structure (HIIC) with single DNA strands encapsulated in lipid tubules is observed. An important recent insight is that the membrane charge density sigmaM of the CL-vector, rather than, for example, the charge of the cationic lipid, is a universal parameter governing the transfection efficiency of LalphaC complexes. This has led to a new model of the intracellular release of LalphaC complexes, through activated fusion with endosomal membranes. In contrast to LalphaC complexes, HIIC complexes exhibit no dependence on sigmaM, since their structure leads to a distinctly different mechanism of cell entry. Surface-functionalized complexes with poly(ethyleneglycol)-lipids (PEG-lipids), potentially suitable for transfection in vivo, have also been investigated, and the novel aspects of these complexes are discussed.

Three-dimensional imaging of lipid gene-carriers: membrane charge density controls universal transfection behavior in lamellar cationic liposome-DNA complexes.

Cationic liposomes (CLs) are used worldwide as gene vectors (carriers) in nonviral clinical applications of gene delivery, albeit with unacceptably low transfection efficiencies (TE). We present three-dimensional laser scanning confocal microscopy studies revealing distinct interactions between CL-DNA complexes, for both lamellar L(alpha)(C) and inverted hexagonal H(II)(C) nanostructures, and mouse fibroblast cells. Confocal images of L(alpha)(C) complexes in cells identified two regimes. For low membrane charge density (sigma(M)), DNA remained trapped in CL-vectors. By contrast, for high sigma(M), released DNA was observed in the cytoplasm, indicative of escape from endosomes through fusion. Remarkably, firefly luciferase reporter gene studies in the highly complex L(alpha)(C)-mammalian cell system revealed an unexpected simplicity where, at a constant cationic to anionic charge ratio, TE data for univalent and multivalent cationic lipids merged into a single curve as a function of sigma(M), identifying it as a key universal parameter. The universal curve for transfection by L(alpha)(C) complexes climbs exponentially over approximately four decades with increasing sigma(M) below an optimal charge density (sigma(M)(*)), and saturates for at a value rivaling the high transfection efficiency of H(II)(C) complexes. In contrast, the transfection efficiency of H(II)(C) complexes is independent of sigma(M). The exponential dependence of TE on sigma(M) for L(alpha)(C) complexes, suggests the existence of a kinetic barrier against endosomal fusion, where an increase in sigma(M) lowers the barrier. In the saturated TE regime, for both L(alpha)(C) complexes and H(II)(C), confocal microscopy reveals the dissociation of lipid and DNA. However, the lipid-released DNA is observed to be in a condensed state, most likely with oppositely charged macro-ion condensing agents from the cytoplasm, which remain to be identified. Much of the observed bulk of condensed DNA may be transcriptionally inactive and may determine the current limiting factor to transfection by cationic lipid gene vectors.