Abstract

This renewal application is to continue a fruitful investigation of positively-charged lipids (triesters of the natural product, phosphatidyicholine) as vehicles of gene delivery to cells. The project was successful in meeting its original goals as well as revealing previously unrecognized but important aspects of liposome-mediated gene delivery. Phosphatidylcholine triesters were synthesized for the first time and found to have a host of useful properties in addition to the originally proposed application of delivering DNA to cells. These compounds exhibited low toxicity, remained efficient transfection agents after incubation in serum, required no co-lipids, and were metabolized at a rate appropriate for use as a gene or drug delivery vehicle in vivo. Variations in chemical structure led to derivatives with widely different properties. All liquid-crystalline versions generated effective transfection agents, provided formulation conditions were carefully optimized. The standard formulation of the complexes of prototype lipid and DNA generated a multi-decker sandwich structure with DNA and lipid in alternating layers. Development of sophisticated methods of studying the structure of the complex by titration calorimetry, flow cytometry and several spectrofluorometric procedures revealed that its process of formation is more complicated than generally appreciated and variation in formulation procedures greatly influence both the structure and transfection activity of a given lipid. Hence, to progress to clinical uses of cationic lipids, it is essential to elucidate the relationship between formulation conditions, lipid-DNA complex structure, stability under in vivo conditions and transfection efficiency. Accordingly, the specific aims of the renewal application are: 1. To build on our experience with the first generation compounds by synthesizing a limited number of new cationic phospholipids with specific properties to enhance transfection. 2. To understand how formulation conditions affect the structure, stability in serum and ability to modify for targeting, the transfection complexes of these and a select group of other important cationic lipids. 3. To relate those properties of the transfection complexes to transfection efficiency under conditions relevant in vitro and in vivo (including targeting of the complex to specific cell surface markers). 4. To expand collaborations to facilitate development of in vivo applications that should become important clinically.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM052329-08
Application #
6636119
Study Section
Medical Biochemistry Study Section (MEDB)
Program Officer
Okita, Richard T
Project Start
1995-09-30
Project End
2004-09-30
Budget Start
2003-04-01
Budget End
2004-03-31
Support Year
8
Fiscal Year
2003
Total Cost
$264,600
Indirect Cost

  Institution

Name
Northwestern University at Chicago
Department
Biochemistry
Type
Schools of Arts and Sciences
DUNS #
160079455
City
Evanston
State
IL
Country
United States
Zip Code
60201

  Publications

Marcoux, Julien; Politis, Argyris; Rinehart, Dennis et al. (2014) Mass spectrometry defines the C-terminal dimerization domain and enables modeling of the structure of full-length OmpA. Structure 22:781-90
Zhuang, Tiandi; Tamm, Lukas K (2014) Control of the conductance of engineered protein nanopores through concerted loop motions. Angew Chem Int Ed Engl 53:5897-902
Buchanan, Kyle D; Huang, Shao-Ling; Kim, Hyunggun et al. (2010) Encapsulation of NF-kappaB decoy oligonucleotides within echogenic liposomes and ultrasound-triggered release. J Control Release 141:193-8
Lei, Guohua; MacDonald, Robert C (2008) Effects on interactions of oppositely charged phospholipid vesicles of covalent attachment of polyethylene glycol oligomers to their surfaces: adhesion, hemifusion, full fusion and ""endocytosis"". J Membr Biol 221:97-106
Koynova, Rumiana; Wang, Li; Macdonald, Robert C (2008) Cationic phospholipids forming cubic phases: lipoplex structure and transfection efficiency. Mol Pharm 5:739-44
Koynova, Rumiana; Wang, Li; MacDonald, Robert C (2007) Synergy in lipofection by cationic lipid mixtures: superior activity at the gel-liquid crystalline phase transition. J Phys Chem B 111:7786-95
Koynova, Rumiana; Macdonald, Robert C (2007) Natural lipid extracts and biomembrane-mimicking lipid compositions are disposed to form nonlamellar phases, and they release DNA from lipoplexes most efficiently. Biochim Biophys Acta 1768:2373-82
Koynova, Rumiana; Tarahovsky, Yury S; Wang, Li et al. (2007) Lipoplex formulation of superior efficacy exhibits high surface activity and fusogenicity, and readily releases DNA. Biochim Biophys Acta 1768:375-86
Pozharski, Edwin V; MacDonald, Robert C (2007) Single lipoplex study of cationic lipoid-DNA, self-assembled complexes. Mol Pharm 4:962-74
Wang, Li; MacDonald, Robert C (2007) Synergistic effect between components of mixtures of cationic amphipaths in transfection of primary endothelial cells. Mol Pharm 4:615-23

Showing the most recent 10 out of 40 publications