Specially-Made Lipid-Based Assemblies for Improving
Transmembrane Gene Delivery: Comparison of Basic Amino Acid Residue
Rich Periphery
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Abstract
Cationic lipid based
assemblies provide a promising platform for
effective gene condensation into nanosized particles, and the peripheral
properties of the assemblies are vital for complexation and interaction
with physical barriers. Here, we report three cationic twin head lipids,
and each of them contains a dioleoyl-glutamate hydrophobic tail and
a twin polar head of lysine, arginine, or histidine. Such lipids were
proven to self-assemble in aqueous solution with well-defined nanostructures
and residual amino-, guanidine-, or imidazole-rich periphery, showing
strong buffering capacity and good liquidity. The assemblies with
arginine (RL) or lysine (KL) periphery exhibited positive charges
(∼+35 mV) and complete condensation of pDNA into nanosized
complexes (∼120 nm). In contrast, assemblies composed of histidine-rich
lipids (HL) showed relatively low cationic electric potential (∼+10
mV) and poor DNA binding ability. As expected, the designed RL assemblies
with guanidine-rich periphery enhanced the <i>in vitro</i> gene transfection up to 190-fold as compared with the golden standard
PEI<sub>25k</sub> and Lipofectamine 2000, especially in the presence
of serum. Meanwhile, interaction with cell and endo/lysosome membrane
also revealed the superiority of RL complexes, that the guanidine-rich
surface efficiently promoted transmembrane process in cellular internalization
and endosomal disruption. More importantly, RL complexes also succeeded
beyond others <i>in vivo</i> with significantly (∼7-fold)
enhanced expression in HepG2 tumor xenografts in mice, as well as
stronger green fluorescence protein imaging in isolated tumors and
tumor frozen sections