Design, Synthesis, and Evaluation of Enhanced DNA Binding New Lipopolythioureas | Zendy

Jeanne Leblond | Zendy; Nathalie Mignet | Zendy; Lucie Leseurre | Zendy; Céline Largeau | Zendy; Michel Bessodes | Zendy; Daniel Scherman | Zendy; Jean Herscovici | Zendy

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Design, Synthesis, and Evaluation of Enhanced DNA Binding New Lipopolythioureas

Author(s) -

Jeanne Leblond,

Nathalie Mignet,

Lucie Leseurre,

Céline Largeau,

Michel Bessodes,

Daniel Scherman,

Jean Herscovici

Publication year - 2006

Publication title -

bioconjugate chemistry

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 1.279

H-Index - 172

eISSN - 1520-4812

pISSN - 1043-1802

DOI - 10.1021/bc060110g

Subject(s) - chemistry , thiourea , dna , liposome , cationic polymerization , cationic liposome , gene delivery , biophysics , membrane , transfection , cell , combinatorial chemistry , ligand (biochemistry) , biochemistry , microbiology and biotechnology , gene , receptor , organic chemistry , biology

Nonviral gene delivery is limited to a large extent by the cationic nature of most of the chemical vector. We have shown that lipopolythioureas interact with DNA. However, lipopolythioureas were not very efficient at transfecting cells, probably due to reduced interaction between the noncationic synthetic lipid and the cell membrane. Here, we report that liposomes made from a new thiourea lipid, DPPC, and a lipid bearing an RGD ligand allowed very efficient entry of the lipopolythioureas into integrin alpha(v)beta(3) expressing cells. In addition, we show that a stable interaction between DNA and lipopolythiourea could be obtain with two thiourea groups. Moreover, the addition of a hydrophilic terminus improves the formulation of these new DNA binding agents.

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