We present experimental evidence that a complex made of a double long chain cationic amphiphile and recombinant mRNA facilitates the entry and expression of genetic material into cells. Combining the properties of the self replicating recombinant mRNA driven by the Semliki Forest Virus (SFV) replicon and the transfection potentialities of a new cationic amphiphile (N-t-butyl-N'-tetradecyl-3-tetradecylaminopropionamidine) yields a highly efficient mRNA transfection system conferring up to 100% infectivity. The preparation and characterization of the long chain amidine cationic amphiphile-mRNA complex as well as the influence of the diC14-amidinelRNA ratio on the infective activity are described.
We used a '~2P-labeled pCMV-CAT plasmid DNA to estimate the DNA uptake efficiency and unlabeled pCMV-CAT plasmid DNA to quantify the CAT activity after transfection of COS cells using each of the three following cationic compounds:
Difficulties in specific detection of transfected DNA in cells represent an important limitation in the study of the gene transfer process. We studied the cellular entry and fate of a plasmid DNA complexed with a cationic lipid, Vectamidine (3-tetradecylamino-N-tert-butyl-N'-tetradecylpropionamidine) in BHK21 cells. To facilitate its detection inside the cells, bromodeoxyuridine (BrdU) was incorporated into plasmid DNA under conditions that minimize plasmid alteration. BrdU was localized in cells incubated with Vectamidine/BrdU-labeled plasmid DNA complexes by immunogold labeling and electron microscopy (EM). Labeling was predominantly associated with aggregated liposome structures at the surface of and inside the cells. EM observations of cells transfected with Vectamidine/DNA complexes showed that the liposome/DNA aggregates accumulate in large vesicles in the cell cytosol. On the other hand, using rhodamine-labeled Vectamidine and revealing BrdU with FITC-conjugated antibodies permitted simultaneous detection in the cells of both components of the complexes with confocal laser scanning microscopy. The DNA and lipids co-localized at the surface of and inside the cells, indicating that the complex is internalized as a whole. Our results show that the BrdU-labeled plasmid DNA detection system can be a useful tool to visualize exogenous DNA entry into cells by a combination of electron and confocal microscopy.
We recently synthesized a novel cationic amphiphile (N-t-butyl-N'-tetradecyl-3-tetradecylaminopropionamidine or Vectamidine (previously described as diC14-amidine)) that associates with DNA and RNA and facilitates their entry and expression into eukaryotic cells. Among several parameters that have been shown to influence the transfection process, the surface charge density plays a key role. Quantitative information about that charge density associated to the cationic amphiphiles organized in liposomal structure is not yet available. We provide here evidence by titration and microelectrophoresis measurements that an evaluation of the intrinsic acidity constants, the surface pH and the counterion binding constants allows to determine the charge density at physiological pH of Vectamidine liposomes. The knowledge of this superficial charge is a prerequisite to a molecular understanding of the DNA-cationic amphiphile complex formation. The method described could be extended to any kind of cationic amphiphile.
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