Ayesha Ahmad scite author profile

Complexes with low sigmaM remain trapped in the endosome. In the high sigmaM regime, accessible for the first time with the new MVLs, complexes escape by overcoming a kinetic barrier to fusion with the endosomal membrane (activated fusion), yet they exhibit a reduced level of efficiency, presumably due to the inability of the DNA to dissociate from the highly charged membranes in the cytosol. The intermediate, optimal regime reflects a compromise between the opposing demands on sigmaM for endosomal escape and dissociation in the cytosol.

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Three-Dimensional Imaging of Lipid Gene-Carriers: Membrane Charge Density Controls Universal Transfection Behavior in Lamellar Cationic Liposome-DNA Complexes

Lin

Slack

Ahmad

et al. 2003

Biophysical Journal

224

313

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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.

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Cationic Lipid-DNA Complexes for Gene Therapy: Understanding the Relationship Between Complex Structure and Gene Delivery Pathways at the Molecular Level

Ewert¹,

Slack²,

Ahmad³

et al. 2004

CMC

171

197

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Cationic liposomes (CLs) are used as gene vectors (carriers) in worldwide human clinical trials of non-viral gene therapy. These lipid-gene complexes have the potential of transferring large pieces of DNA of up to 1 million base-pairs into cells. As our understanding of the mechanisms of action of CL-DNA complexes remains poor, transfection efficiencies are still low when compared to gene delivery with viral vectors. We describe recent studies with a combination of 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), which collectively are beginning to unravel the relationship between the distinctly structured CL-DNA complexes and their transfection efficiency. The work described here is applicable to transfection optimization in ex vivo cell transfection, where cells are removed and returned to patients after transfection. CL-DNA complexes primarily form a multilayered sandwich structure with DNA layered between the cationic lipids (labeled L,~). On rare occasions, an inverted hexagonal structure with DNA encapsulated in lipid tubules (labeled H~~~) is observed. A major recent insight is that for L ,~ complexes the membrane charge density OM of the CL-vector, rather than the charge of the cationic lipid alone, is a key universal parameter that governs the transfection efficiency of L, ' complexes in cells. The parameter aM is a measure of the average charge per unit area of the membrane, thus taking into account the amount of neutral lipids. In contrast to LaC complexes, HITC complexes containing the lipid 1,2-dioleoyl-sn-glycerophosphatidylethanolamine (DOPE) exhibit no dependence on OM. The currenl limiting factor to transfection by cationic lipid vectors appears to be the tight association of a fraction of the delivered exogenous DNA with cationic cellular molecules, which may prevent optimal transcriptional activity. Future directions are outlined, which make use of surface-functionalized CL-DNA complexes suitable for transfection in vivo.

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Ayesha Ahmad

The UCL–Lancet Commission on Migration and Health: the health of a world on the move

New multivalent cationic lipids reveal bell curve for transfection efficiency versus membrane charge density: lipid–DNA complexes for gene delivery

Three-Dimensional Imaging of Lipid Gene-Carriers: Membrane Charge Density Controls Universal Transfection Behavior in Lamellar Cationic Liposome-DNA Complexes

Cationic Lipid-DNA Complexes for Gene Therapy: Understanding the Relationship Between Complex Structure and Gene Delivery Pathways at the Molecular Level

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