Ilya Koltover scite author profile

Cationic liposomes complexed with DNA (CL-DNA) are promising synthetically based nonviral carriers of DNA vectors for gene therapy. The solution structure of CL-DNA complexes was probed on length scales from subnanometer to micrometer by synchrotron x-ray diffraction and optical microscopy. The addition of either linear lambda-phage or plasmid DNA to CLs resulted in an unexpected topological transition from liposomes to optically birefringent liquid-crystalline condensed globules. X-ray diffraction of the globules revealed a novel multilamellar structure with alternating lipid bilayer and DNA monolayers. The lambda-DNA chains form a one-dimensional lattice with distinct interhelical packing regimes. Remarkably, in the isoelectric point regime, the lambda-DNA interaxial spacing expands between 24.5 and 57.1 angstroms upon lipid dilution and is indicative of a long-range electrostatic-induced repulsion that is possibly enhanced by chain undulations.

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An Inverted Hexagonal Phase of Cationic Liposome-DNA Complexes Related to DNA Release and Delivery

Koltover

Salditt

Rädler

et al. 1998

Science

1,246

1,228

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A two-dimensional columnar phase in mixtures of DNA complexed with cationic liposomes has been found in the lipid composition regime known to be significantly more efficient at transfecting mammalian cells in culture compared to the lamellar (LalphaC) structure of cationic liposome-DNA complexes. The structure, derived from synchrotron x-ray diffraction, consists of DNA coated by cationic lipid monolayers and arranged on a two-dimensional hexagonal lattice (HIIC). Two membrane-altering pathways induce the LalphaC --> HIIC transition: one where the spontaneous curvature of the lipid monolayer is driven negative, and another where the membrane bending rigidity is lowered with a new class of helper-lipids. Optical microscopy revealed that the LalphaC complexes bind stably to anionic vesicles (models of cellular membranes), whereas the more transfectant HIIC complexes are unstable and rapidly fuse and release DNA upon adhering to anionic vesicles.

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Phase Diagram, Stability, and Overcharging of Lamellar Cationic Lipid–DNA Self-Assembled Complexes

Koltover

Salditt

Safinya

1999

Biophysical Journal

301

347

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Cationic lipid-DNA (CL-DNA) complexes comprise a promising new class of synthetic nonviral gene delivery systems. When positively charged, they attach to the anionic cell surface and transfer DNA into the cell cytoplasm. We report a comprehensive x-ray diffraction study of the lamellar CL-DNA self-assemblies as a function of lipid composition and lipid/DNA ratio, aimed at elucidating the interactions determining their structure, charge, and thermodynamic stability. The driving force for the formation of charge-neutral complexes is the release of DNA and lipid counterions. Negatively charged complexes have a higher DNA packing density than isoelectric complexes, whereas positively charged ones have a lower packing density. This indicates that the overcharging of the complex away from its isoelectric point is caused by changes of the bulk structure with absorption of excess DNA or cationic lipid. The degree of overcharging is dependent on the membrane charge density, which is controlled by the ratio of neutral to cationic lipid in the bilayers. Importantly, overcharged complexes are observed to move toward their isoelectric charge-neutral point at higher concentration of salt co-ions, with positively overcharged complexes expelling cationic lipid and negatively overcharged complexes expelling DNA. Our observations should apply universally to the formation and structure of self-assemblies between oppositely charged macromolecules.

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Structure and Interfacial Aspects of Self-Assembled Cationic Lipid−DNA Gene Carrier Complexes

et al. 1998

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Cationic lipid−DNA (CL−DNA) complexes were recently found to exhibit a novel multilamellar structure composed of alternating lipid bilayer and DNA monolayer with distinct interhelical DNA spacings (Rädler et al. Science 1997, 275, 810). We report on the aggregation behavior, morphology, and interfacial properties related to the solution structure of DOPC/DOTAP−DNA complexes. Using optical microscopy and synchrotron X-ray diffraction, we found two discrete regimes for the complex size and surface charge as a function of the lipid-to-DNA mass ratio. The regimes correspond to the coexistence of complexes with either excess DNA or excess liposomes, characterized by a negative and positive surface potential of the complexes, respectively. The internal structure in these cases exhibited different but constant DNA packing distances of 35 and 46 Å, respectively. The regimes are separated by a transition region around the isoelectric point, where the number of cationic lipids equals the number of DNA phosphate groups. At the isoelectric point the average complex size diverged and the DNA packing spacing is described by a simple volume fraction calculation. The complex formation occurred on three time scales: rapid condensation, a slower colloidal aggregation, and finally, a long term reorganization or compaction. Complexes with positive surface charge were shown to adhere to negatively charged giant liposomes.

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DNA condensation in two dimensions

Koltover

Wagner

Safinya

2000

Proc. Natl. Acad. Sci. U.S.A.

206

224

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We have found that divalent electrolyte counterions common in biological cells (Ca(2+), Mg(2+), and Mn(2+) ) can condense anionic DNA molecules confined to two-dimensional cationic surfaces. DNA-condensing agents in vivo include cationic histones and polyamines spermidine and spermine with sufficiently high valence (Z) 3 or larger. In vitro studies show that electrostatic forces between DNA chains in bulk aqueous solution containing divalent counterions remain purely repulsive, and DNA condensation requires counterion valence Z >/= 3. In striking contrast to bulk behavior, synchrotron x-ray diffraction and optical absorption experiments show that above a critical divalent counterion concentration the electrostatic forces between DNA chains adsorbed on surfaces of cationic membranes reverse from repulsive to attractive and lead to a chain collapse transition into a condensed phase of DNA tethered by divalent counterions. This demonstrates the importance of spatial dimensionality to intermolecular interactions where nonspecific counterion-induced electrostatic attractions between the like-charged polyelectrolytes overwhelm the electrostatic repulsions on a surface for Z = 2. This new phase, with a one-dimensional counterion liquid trapped between DNA chains at a density of 0.63 counterions per DNA bp, represents the most compact state of DNA on a surface in vitro and suggests applications in high-density storage of genetic information and organo-metallic materials processing.

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Ilya Koltover

Structure of DNA-Cationic Liposome Complexes: DNA Intercalation in Multilamellar Membranes in Distinct Interhelical Packing Regimes

An Inverted Hexagonal Phase of Cationic Liposome-DNA Complexes Related to DNA Release and Delivery

Phase Diagram, Stability, and Overcharging of Lamellar Cationic Lipid–DNA Self-Assembled Complexes

Structure and Interfacial Aspects of Self-Assembled Cationic Lipid−DNA Gene Carrier Complexes

DNA condensation in two dimensions

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