Conformational transition of DNA induced by cationic lipid vesicle in acidic solution: spectroscopy investigation

The conformational transition of DNA induced by the interaction between DNA and a cationic lipid vesicle, didodecyldimethylammonium bromide (DDAB), had been investigated by circular dichroism (CD) and UV spectroscopy methods. We used singular value decomposition least squares method (SVDLS) to analyze the experimental CD spectra. Although pH value influenced the conformation of DNA in solution, the results showed that upon binding to double helical DNA, positively charged liposomes induced a conformational transition of DNA molecules from the native B-form to more compact conformations. At the same time, no obvious conformational changes occurred at single-strand DNA (ssDNA). While the cationic lipid vesicles and double-strand DNA (dsDNA) were mixed at a high molar ratio of DDAB vesicles to dsDNA, the conformation of dsDNA transformed from the B-form to the C-form resulting in an increase in duplex stability (DeltaT(m)=8+/-0.4 degrees C). An increasing in T(m) was also observed while the cationic lipid vesicles interacted with ssDNA.     

Physico-chemical aspects of the interaction between DNA and oppositely charged mixed liposomes

The mechanism of complex formation between DNA and oppositely charged dioctadecyldimethylammonium bromide/dioleoyl phosphatidylethanolamine (DODAB/DOPE) and 1,2-dioleoyl-3-trimethylammonium propane (DOTAP)/DOPE mixed liposomes, as well as the physico-chemical properties of DNA-mixed liposome complexes, were examined. Fluorescence microscopy showed that the interaction between DNA and oppositely charged mixed liposomes started at very low liposome concentrations and induced a discrete coil-globule transition in individual DNA molecules. The DNA size distribution was bimodal in a wide range of liposome concentrations. The critical concentration of the cationic lipid needed for the complete compaction of single DNA molecules depended on the composition of the charged mixed DODAB/DOPE and DOTAP/DOPE liposomes. Cryogenic transmission electron microscopy (cryo-TEM) observations of DNA complexes with mixed liposomes revealed that the lamellar packing of lipid molecules was typical for the complexes formed from the cationic lipid-enriched mixtures, while inverted hexagonal arrays were found for the neutral lipid-enriched complexes. The microstructures of the complexes were also examined with the use of the small-angle X-ray scattering (SAXS) technique, which confirmed the results obtained by cryo-TE microscopy and enabled the quantitative characterization of lipid packaging in the complexes with DNA macromolecules. We also found that the introduction of the neutral lipid into the complexes between DNA and oppositely charged lipids, DODAB and DOTAP, moderately increased the thermal stability of the complexes and changed the quantitative characteristics of the melting profiles of the complexes.     

Surfactant-DNA gel particles: formation and release characteristics

Aqueous mixtures of oppositely charged polyelectrolytes undergo associative phase separation, resulting in coacervation, gelation, or precipitation. This phenomenon has been exploited here to form DNA gel particles by interfacial diffusion. We report on the formation of DNA gel particles by mixing solutions of DNA (either single-stranded (ssDNA) or double-stranded (dsDNA)) with solutions of cationic surfactant cetyltrimetrylammonium bromide (CTAB). By using CTAB, the formation of DNA reservoir gel particles, without adding any kind of cross-linker or organic solvent, has been demonstrated. Particles have been characterized with respect to the degree of DNA entrapment, surface morphology, and secondary structure of DNA in the particles. The swelling/deswelling behavior and the DNA release have been investigated in response to salt additions. Analysis of the data has suggested a higher degree of interaction between ssDNA and the cationic surfactant, confirming the stronger amphiphilic character of the denatured DNA. Fluorescence microscopy studies have suggested that the formation of these particles is associated with a conservation of the secondary structure of DNA.     

Isothermal titration calorimetric analysis of the interaction between cationic lipids and plasmid DNA

The effects of buffer and ionic strength upon the enthalpy of binding between plasmid DNA and a variety of cationic lipids used to enhance cellular transfection were studied using isothermal titration calorimetry at 25.0 degrees C and pH 7.4. The cationic lipids DOTAP (1,2-dioleoyl-3-trimethyl ammonium propane), DDAB (dimethyl dioctadecyl ammonium bromide), DOTAP:cholesterol (1:1), and DDAB:cholesterol (1:1) bound endothermally to plasmid DNA with a negligible proton exchange with buffer. In contrast, DOTAP: DOPE (L-alpha-dioleoyl phosphatidyl ethanolamine) (1:1) and DDAB:DOPE (1:1) liposomes displayed a negative enthalpy and a significant uptake of protons upon binding to plasmid DNA at neutral pH. These findings are most easily explained by a change in the apparent pKa of the amino group of DOPE upon binding. Complexes formed by reverse addition methods (DNA into lipid) produced different thermograms, sizes, zeta potentials, and aggregation behavior, suggesting that structurally different complexes were formed in each titration direction. Titrations performed in both directions in the presence of increasing ionic strength revealed a progressive decrease in the heat of binding and an increase in the lipid to DNA charge ratio at which aggregation occurred. The unfavorable binding enthalpy for the cationic lipids alone and with cholesterol implies an entropy-driven interaction, while the negative enthalpies observed with DOPE-containing lipid mixtures suggest an additional contribution from changes in protonation of DOPE.     

Dendritic cationic lipids with highly charged headgroups for efficient gene delivery

Gene therapy is expected to lead to powerful new approaches for curing many diseases, a potential that is currently explored in worldwide clinical trials. Nonviral DNA delivery systems are desirable to overcome the inherent problems of viral vectors, but their current efficiency requires improvement and the understanding of their mechanism of action is incomplete. We have synthesized new multivalent cationic lipids with highly charged dendritic headgroups to probe the structure-transfection efficiency relationships of cationic liposome (CL)-DNA complexes, a prevalent nonviral vector. The lipid headgroups are constructed from ornithine cores and ornithine or carboxyspermine endgroups. The dendritic lipids were prepared on a gram scale, using a synthetic scheme that permits facile variation of the lipid building blocks headgroup, spacer, and hydrophobic moiety. They carry four to sixteen positive charges in their headgroups. Complexes of DNA with mixtures of the dendritic lipids and neutral 1,2-dioleoyl-sn-glycero phosphatidylcholine (DOPC) exhibit novel structures at high contents of the highly charged lipids, while the well-known lamellar phase is formed at high contents of DOPC. DNA complexes of the new dendritic lipids efficiently transfect mammalian cells in culture without cytotoxicity and, in contrast to lamellar complexes, maintain high transfection efficiency over a broad range of composition.     

The phase behavior of cationic lipid-DNA complexes

We present a theoretical analysis of the phase behavior of solutions containing DNA, cationic lipids, and nonionic (helper) lipids. Our model allows for five possible structures, treated as incompressible macroscopic phases: two lipid-DNA composite (lipoplex) phases, namely, the lamellar (L(alpha)(C)) and hexagonal (H(II)(C)) complexes; two binary (cationic/neutral) lipid phases, that is, the bilayer (L(alpha)) and inverse-hexagonal (H(II)) structures, and uncomplexed DNA. The free energy of the four lipid-containing phases is expressed as a sum of composition-dependent electrostatic, elastic, and mixing terms. The electrostatic free energies of all phases are calculated based on Poisson-Boltzmann theory. The phase diagram of the system is evaluated by minimizing the total free energy of the three-component mixture with respect to all the compositional degrees of freedom. We show that the phase behavior, in particular the preferred lipid-DNA complex geometry, is governed by a subtle interplay between the electrostatic, elastic, and mixing terms, which depend, in turn, on the lipid composition and lipid/DNA ratio. Detailed calculations are presented for three prototypical systems, exhibiting markedly different phase behaviors. The simplest mixture corresponds to a rigid planar membrane as the lipid source, in which case, only lamellar complexes appear in solution. When the membranes are "soft" (i.e., low bending modulus) the system exhibits the formation of both lamellar and hexagonal complexes, sometimes coexisting with each other, and with pure lipid or DNA phases. The last system corresponds to a lipid mixture involving helper lipids with strong propensity toward the inverse-hexagonal phase. Here, again, the phase diagram is rather complex, revealing a multitude of phase transitions and coexistences. Lamellar and hexagonal complexes appear, sometimes together, in different regions of the phase diagram.     

Phase diagram, stability, and overcharging of lamellar cationic lipid-DNA self-assembled complexes.

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.     

Lipid-DNA and lipid-polyelectrolyte mesophases: structure and exchange kinetics.

Cationic lipid-DNA complexes are used as gene transfer vehicles in molecular biology and potentially in human gene therapy. In recent synchrotron X-ray scattering studies the molecular structure of such self-assembling aggregates was elucidated. A rich polymorphism of lamellar, hexagonal, lamellar-columnar and micellar mesophases was found. In this article we describe composite phases of cationic lipid mixed with hyaluronic acid and dextran sulfate which likewise form intercalated lamellar complexes. Heterogeneous phases of lipid/dextran sulfate mixed with lipid/DNA exhibit macroscopic phase separation. When dextran sulfate is added to preformed cationic lipid DNA complexes the latter are dissolved in favor of the lipid-polyelectrolyte phases. We investigated the kinetics of the DNA replacement by dextran sulfate. The experiments are intended to mimic the interaction of cationic lipid gene delivery complexes with highly charged extracellular matrix components.     

Effect of lipid composition upon fusion of liposomes with Sendai virus membranes

How the lipid composition of liposomes determines their ability to fuse with Sendai virus membranes was tested. Liposomes were made of compositions designed to test postulated mechanisms of membrane fusion that require specific lipids. Fusion does not require the presence of lipids that can form micelles such as gangliosides or lipids that can undergo lamellar to hexagonal phase transitions such as phosphatidylethanolamine (PE), nor is a phosphatidylinositol (PI) to phosphatidic acid (PA) conversion required, since fusion occurs with liposomes containing phosphatidylcholine (PC) and any one of many different negatively charged lipids such as gangliosides, phosphatidylserine (PS), phosphatidylglycerol, dicetyl phosphate, PI, or PA. A negatively charged lipid is required since fusion does not occur with neutral liposomes containing PC and a neutral lipid such as globoside, sphingomyelin, or PE. Fusion of Sendai virus membranes with liposomes that contain PC and PS does not require Ca2+, so an anhydrous complex with Ca2+ or a Ca2+-induced lateral phase separation is not required although the possibility remains that viral binding causes a lateral phase separation. Sendai virus membranes can fuse with liposomes containing only PS, so a packing defect between domains of two different lipids is not required. The concentration of PS required for fusion to occur is approximately 10-fold higher than that required for ganglioside GD1a, which has been shown to act as a Sendai virus receptor. When cholesterol is added as a third lipid to liposomes containing PC and GD1a, the amount of fusion decreases if the GD1a concentration is low.(ABSTRACT TRUNCATED AT 250 WORDS)     

Plasmid DNA size does not affect the physicochemical properties of lipoplexes but modulates gene transfer efficiency.

Clinical applications of gene therapy mainly depend on the development of efficient gene transfer vectors. Large DNA molecules can only be transfected into cells by using synthetic vectors such as cationic lipids and polymers. The present investigation was therefore designed to explore the physicochemical properties of cationic lipid-DNA particles, with plasmids ranging from 900 to 52 500 bp. The colloidal stability of the lipoplexes formed by complexing lipopolyamine micelles with plasmid DNA of various lengths, depending on the charge ratio, resulted in the formation of three domains, respectively corresponding to negatively, neutrally and positively charged lipoplexes. Lipoplex morphology and structure were determined by the physicochemical characteristics of the DNA and of the cationic lipid. Thus, the lamellar spacing of the structure was determined by the cationic lipid and its spherical morphology by the DNA. The main result of this study was that the morphological and structural features of the lipopolyamine-DNA complexes did not depend on plasmid DNA length. On the other hand, their gene transfer capacity was affected by the size of plasmid DNA molecules which were sandwiched between the lipid bilayers. The most effective lipopolyamine-DNA complexes for gene transfer were those containing the shortest plasmid DNA.     

DNA-cationic surfactant interactions are different for double- and single-stranded DNA

The stability of DNA in solution and the phase behavior in mixtures with dodecyltrimethylammonium bromide (DTAB) were investigated. By means of circular dichroism, UV absorption, and differential scanning calorimetry, we found that for dilute solutions of DNA with no addition of salt the DNA molecules are in the single-stranded conformation, whereas the addition of a small amount of NaBr, 1 mM, is sufficient to stabilize the DNA double-helix. Furthermore, at higher DNA concentrations, native DNA becomes the most stable structure, which is due to a self-screening effect. By phase diagram determinations of the DNA-surfactant system, we found that the effect of salt on phase behavior mainly relates to a difference in interaction of the amphiphile between single-stranded DNA (ssDNA) and double-stranded DNA (dsDNA). The difference in association between ss and dsDNA with surfactants of different chain lengths can be interpreted in terms of an interplay between hydrophobic and electrostatic interactions, the latter being influenced by polymer flexibility. In this way, a nonmonotonic variation can be rationalized. A crossing of the phase separation lines with DNA concentration can be rationalized in terms of a change in relative stability of ss and dsDNA. The fact that ssDNA phase separates earlier than dsDNA in association with DTAB, may serve as a basis for a method of easily separating dsDNA from ssDNA by the addition of surfactant; this is verified as monitored by circular dichroism measurements.     

Interaction between covalent DNA gels and a cationic surfactant

The interaction of covalently cross-linked double-stranded (ds) DNA gels and cetyltrimethylammonium bromide (CTAB) is investigated. The volume transition of the gels that follows the absorption of the oppositely charged surfactant from aqueous solution is studied. As do other polyelectrolyte networks, DNA networks form complexes with oppositely charged surfactant micelles at surfactant concentrations far below the critical micelle concentration (cmc) of the polymer-free solution. The size of the absorbed surfactant aggregates is determined from time-resolved fluorescence quenching (TRFQ). At low surfactant concentrations, small discrete micelles (160 < N < 210) are found, whereas large micelles (N > 500) form at surfactant concentrations of 1 mM. When the DNA is in excess of the surfactant, the surfactant binding is essentially quantitative. The gel volume decreases by 90% when the surfactant to DNA charge ratio, beta, increases from 0 to 1.     

Osmotically Induced Reversible Transitions in Lipid-DNA Mesophases

We follow the effect of osmotic pressure on isoelectric complexes that self-assemble from mixtures of DNA and mixed neutral and cationic lipids. Using small angle x-ray diffraction and freeze-fracture cryo-electron microscopy, we find that lamellar complexes known to form in aqueous solutions can reversibly transition to hexagonal mesophases under high enough osmotic stress exerted by adding a neutral polymer. Using molecular spacings derived from x-ray diffraction, we estimate the reversible osmotic pressure-volume (Π-V) work needed to induce this transition. We find that the transition free energy is comparable to the work required to elastically bend lipid layers around DNA. Consistent with this, the required work is significantly lowered by an addition of hexanol, which is known to soften lipid bilayers. Our findings not only help to resolve the free-energy contributions associated with lipid-DNA complex formation, but they also demonstrate the importance that osmotic stress can have to the macromolecular phase geometry in realistic biological environments.     

Electrochemistry and spectroscopy study on the interaction of microperoxidase-11 with lipid membrane.

The interaction of microperoxidase-11 (MP11) with cationic lipid vesicles of didodecyldimethylammonium bromide (DDAB) induces an alpha-helical conformation from random coil conformations in solution and this change then makes heme macrocycle more distorted. DDAB-induced MP11 conformations were investigated by cyclic votammetry (CV), circular dichroism (CD) and UV-vis spectrometry. All results indicate that the binding of MP11 in solution to DDAB vesicles and the ordered structure formation are driven by mostly electrostatic interaction between negatively charged residues in the undecapeptide and positively charged lipid headgroups on the membrane surface. Upon binding to DDAB, its half-peak potential was also changed. The mechanism of the interaction between MP11 and DDAB was also discussed.     

Loading/release behavior of (chitosan/DNA)n layer-by-layer films toward negatively charged anthraquinone and its application in electrochemical detection of natural DNA damage

In the present work, positively charged chitosan (CS) and negatively charged DNA were alternately adsorbed on the surface of pyrolytic graphite (PG) electrodes, forming (CS/DNA)(n) layer-by-layer films. Cyclic voltammetry (CV) results showed that negatively charged electroactive probe, 9,10-anthraquinone-2,6-disulfonate (AQDS), could be loaded into the (CS/DNA)(n) films from its solution (1 mM at pH 7.0, containing 0.1 M NaCl), designated as (CS/DNA)(n)-AQDS, and then released from the films in blank buffers. The loading/release behavior of (CS/DNA)(n) films toward AQDS was found to be obviously different between double-stranded (dsDNA) and single-stranded DNA (ssDNA). The release rate of AQDS from (CS/dsDNA)(n) films was much slower than that from the ssDNA counterparts mainly because AQDS could be intercalated into the double helix structure of dsDNA despite the repulsion between likely charged AQDS and DNA. The loading/release behavior of (CS/DNA)(n) films toward AQDS in recognition of dsDNA and ssDNA was then successfully applied to electrochemically detect the damage of natural DNA caused by Fenton reaction. To further understand the essence of the interactions involved in the AQDS loading/release process for (CS/DNA)(n) films, comparison experiments were performed, in which either positively charged intercalator brilliant cresyl blue (BCB) was used to replace AQDS as the redox probe, or poly(diallyldimethylammonium) (PDDA) with relatively high positive charge density was used to replace CS as the constituent of layer-by-layer films with DNA. The loading/release behavior of DNA films toward electroactive intercalator may open new possibilities for dsDNA/ssDNA recognition and of DNA damage detection by electrochemistry.     

The interaction of the A and A* proteins of bacteriophage phi X174 with single-stranded and double-stranded phi X DNA in vitro

The binding of the bacteriophage phi X 174-coded A and A* proteins to single-stranded (ssDNA) and double-stranded (dsDNA ) phi X DNA was studied by electron microscopy. The interaction of the A* protein with ssDNA and dsDNA was also studied by sedimentation velocity centrifugation. It was shown that the binding of the A and A* proteins to ssDNA occurs in a non-cooperative manner and requires no or very little sequence specificity under the conditions used here. Both protein-ssDNA complexes have the same compact structure caused by intrastrand cross-linking through the interaction of protein molecules with separate parts of the ssDNA molecule. The A protein does not bind to phi X dsDNA in the absence of divalent cations. The A* protein does bind to dsDNA, although it has a strong preference for binding to ssDNA. The structure of the A* protein-dsDNA complexes is different from that of the A* protein-ssDNA complexes, as the former have a rosette-like structure caused by protein-protein interactions. High ionic strengths favour the formation of large condensed aggregates.     

Response of the phosphatidylcholine headgroup to membrane surface charge in ternary mixtures of neutral, cationic, and anionic lipids: a deuterium NMR study.

Deuterium nuclear magnetic resonance (2H NMR) spectroscopy was used to investigate the response of the phosphatidylcholine headgroup of 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC) to changes in surface electrostatic charge in membranes consisting of ternary mixtures of lipids. DMPC was deuterated at the choline alpha- and beta-methylene segments. The membrane surface charge was manipulated by the simultaneous addition of cationic didodecyldimethylammonium bromide (DDAB) and anionic 1,2-dimyristoyl-sn-glycero-3-phosphoglycerol (DMPG) to neutral DMPC. Addition of increasing amounts of DDAB caused a progressive decrease (increase) in the 2H NMR quadrupole splitting from DMPC-alpha-d2 (DMPC-beta-d2). Addition of increasing amounts of DMPG caused a progressive increase (decrease) in the quadrupole splitting from DMPC-alpha-d2 (DMPC-beta-d2). Qualitatively, the 2H NMR quadrupole splitting charge response exhibited the same main features for ternary mixtures of DDAB/DMPG/DMPC and binary mixtures of DDAB/DMPC or DMPG/DMPC. Quantitatively, however, the 2H NMR quadrupole splittings obtained from ternary mixtures did not coincide with those obtained from binary mixtures of nominally identical surface charge densities. Hence, the quadrupole splitting did not respond directly to the net membrane surface charge. Instead, the quadrupole splitting measured for a given ternary lipid composition could be reproduced by summing the individual effects of the charged lipids in binary mixtures, weighted according to their appropriate mole fractions.     

Interaction of dimeric intercalating dyes with single-stranded DNA.

The unsymmetrical cyanine dye thiazole orange homodimer (TOTO) binds to single-stranded DNA (ssDNA, M13mp18 ssDNA) to form a fluorescent complex that is stable under the standard conditions of electrophoresis. The stability of this complex is indistinguishable from that of the corresponding complex of TOTO with double-stranded DNA (dsDNA). To examine if TOTO exhibits any binding preference for dsDNA or ssDNA, transfer of TOTO from pre-labeled complexes to excess unlabeled DNA was assayed by gel electrophoresis. Transfer of TOTO from M13 ssDNA to unlabeled dsDNA proceeds to the same extent as that from M13 dsDNA to unlabeled dsDNA. A substantial amount of the dye is retained by both the M13 ssDNA and M13 dsDNA even when the competing dsDNA is present at a 600-fold weight excess; for both dsDNA and ssDNA, the pre-labeled complex retains approximately one TOTO per 30 bp (dsDNA) or bases (ssDNA). Rapid transfer of dye from both dsDNA and ssDNA complexes is seen at Na+ concentrations > 50 mM. Interestingly, at higher Na+ or Mg2+ concentrations, the M13 ssDNA-TOTO complex appears to be more stable to intrinsic dissociation (dissociation in the absence of competing DNA) than the complex between TOTO and M13 dsDNA. Similar results were obtained with the structurally unrelated dye ethidium homodimer. The dsDNA- and ssDNA-TOTO complexes were further examined by absorption, fluorescence and circular dichroism spectroscopy. The surprising conclusion is that polycationic dyes, such as TOTO and EthD, capable of bis-intercalation, interact with dsDNA and ssDNA with very similar high affinity.     

Phase behavior, DNA ordering, and size instability of cationic lipoplexes. Relevance to optimal transfection activity

Mechanisms of cationic lipid-based nucleic acid delivery are receiving increasing attention, but despite this the factors that determine high or low activity of lipoplexes are poorly understood. This study is focused on the fine structure of cationic lipid-DNA complexes (lipoplexes) and its relevance to transfection efficiency. Monocationic (N-(1-(2,3-dioleoyloxy)propyl),N,N,N-trimethylammonium chloride, N-(1-(2,3-dimyristyloxypropyl)-N,N-dimethyl-(2-hydroxyethyl)ammonium bromide) and polycationic (2,3-dioleyloxy-N-[2(sperminecarboxamido)ethyl]-N,N-dimethyl-1-propanammonium trifluoroacetate) lipid-based assemblies, with or without neutral lipid (1,2-dioleoyl-sn-glycero-3-phosphatidylethanolamine, 1,2-dioleoyl-sn-glycero-3-phosphatidylcholine, cholesterol) were used to prepare lipoplexes of different L(+)/DNA(-) charge ratios. Circular dichroism, cryogenic-transmission electron microscopy, and static light scattering were used for lipoplex characterization, whereas expression of human growth hormone or green fluorescent protein was used to quantify transfection efficiency. All monocationic lipids in the presence of inverted hexagonal phase-promoting helper lipids (1,2-dioleoyl-sn-glycero-3-phosphatidylethanolamine, cholesterol) induced appearance of Psi(-) DNA, a chiral tertiary DNA structure. The formation of Psi(-) DNA was also dependent on cationic lipid-DNA charge ratio. On the other hand, monocationic lipids either alone or with 1,2-dioleoyl-sn-glycero-3-phosphatidylcholine as helper lipid, or polycationic 2,3-dioleyloxy-N-[2(sperminecarboxamido)ethyl]-N,N-dimethyl-1-propanammonium trifluoroacetate-based assemblies, neither of which promotes a lipid-DNA hexagonal phase, did not induce the formation of Psi(-) DNA. Parallel transfection studies reveal that the size and phase instability of the lipoplexes, and not the formation of Psi(-) DNA structure, correlate with optimal transfection.