posted on 2022-03-17, 13:39authored byHithavani Rapaka, Shireesha Manturthi, Porkizhi Arjunan, Vigneshwaran Venkatesan, Saravanabhavan Thangavel, Srujan Marepally, Srilakshmi V Patri
Intracellular
delivery of biomolecules using non-viral vectors
critically depends on the vectors’ ability to allow the escape
and release of the contents from the endosomes. Prior findings demonstrated
that aromatic/hydrophobic group-containing amino acids such as phenylalanine
(F) and tryptophan (W) destabilize cellular membranes by forming pores
in the lipid bilayer. Taking cues from these findings, we have developed
four α-tocopherol-based cationic amphiphiles by varying the
aromatic/hydrophobic amino acids such as glycine (G), proline (P),
phenylalanine (F), and tryptophan (W) as head groups and triazole
in the linker region to study their impact on endosomal escape for
the enhanced transfection efficacy. The lipids tocopherol-triazole-phenylalanine
(TTF) and tocopherol-triazole-tryptophan (TTW) exhibited similar potential
to commercial transfecting reagents, Lipofectamine (LF) 3000 and Lipofectamine
Messenger Max (LFMM), respectively, in transfecting plasmid DNA and
messenger RNA in multiple cultured cell lines. The TTW liposome was
also found to be effective in delivering Cas9 mRNA and demonstrated
equal efficiency of gene editing AAVS1 locus compared to LFMM in CHO,
Neuro-2a, and EA.HY926 cell lines. In this current investigation,
it is shown that the synthesized cationic lipids with aromatic hydrophobic
R group-containing amino acids are safe, economic, and actually more
efficient in nucleic acid delivery and genome-editing applications.
These findings can be further explored in the genome-editing approach
for treating genetic disorders.