While such investigations are novel, overall RAD001 ic50 knowledge regarding anionic lipofection is as yet limited
due to a lack of extensive testing; DNA entrapment in anionic liposomes is still inefficient, and cytotoxicity data remain inadequate. Divalent cations can be incorporated into the system to enable the condensation of nucleic acids prior to envelopment by anionic lipids. Several divalent cations have been tested for use in anionic lipoplexes such as Ca2+, Mg2+, Mn2+, and Ba2+, but it has been observed that the use of Ca2+ yielded the highest transfection efficiency due to its higher DNA Inhibitors,research,lifescience,medical binding affinity [70, 71]. An investigation conducted by Srinivasan and Burgess confirmed that Ca2+ was the most effective cation for DNA compaction as compared to Na+ and Mg2+ [66]. This affinity is potentially a result of the smaller hydrodynamic radius of calcium which gives a larger charge per unit surface area. The use of Ca2+ not only overcame the strong electrostatic Inhibitors,research,lifescience,medical repulsion between the DNA and the lipids, but also promoted uptake Inhibitors,research,lifescience,medical of the lipoplexes by the cell [8]. However, the use of
high concentrations of calcium (in excess of 25mM) was shown to be detrimental to transfection efficiency because of the creation of aggregate lipoplexes, having particle sizes of 500nm and higher [66]. Optimum transfection efficiency is achieved with particles sizes of about 200nm due to factors thought to be related to clathrin-mediated uptake [72]. Mixtures of the anionic lipid dioleoylphosphatidylglycerol (DOPG) and the neutral lipid DOPE have been investigated to determine an optimal ratio for transfection [66]. It was
suggested that a 1:4 ratio Inhibitors,research,lifescience,medical of Inhibitors,research,lifescience,medical DOPG to DOPE was a proper balance to allow the negatively charged phospholipids to form lipoplexes while still having enough of the neutrally charged phospholipids to allow for endosomal escape. DOPG has a packing parameter less than 1 and tends to form flexible bilayers and vesicles (Figure 2) [73]. This characteristic can be contrasted to that of DOPE, which has a packing parameter greater than one and is known to adopt an inverted hexagonal structure that through promotes membrane destabilization [13, 70]. Transmission electron microscopy revealed that this particular formulation yields liposomes of a spherical multilamellar structure [66]. However, upon relocation to the late endosome or endolysosome, the lipoplex may alter its morphology due to the effects of pH upon the DOPE. The 1 : 4 ratio was seen to exhibit higher transfection efficiency and cell viability versus the cationic formulation Lipofectamine 2000 [66]. Despite some favorable investigations into the use of anionic liposomes for gene delivery, there are some potential downfalls associated with systemic delivery that must be further explored.