BACKGROUND: Efficient and target-specific in vivo gene delivery is a major challenge in gene therapy. Compared to cell culture application, in vivo gene delivery faces a variety of additional obstacles such as anatomical size constraints, interactions with biological fluids and extracellular matrix, and binding to a broad variety of non-target cell types. METHODS: Polycation-based vectors, including adenovirus-enhanced transferrinfection (AVET) and transferrin-polyethylenimine (Tf-PEI), were tested for gene delivery into subcutaneously growing tumors after local and systemic application. DNA biodistribution and reporter gene expression was measured in the major organs and in the tumor. RESULTS: Gene transfer after intratumoral application was 10-100 fold more efficient with Tf-PEI/DNA or AVET complexes in comparison to naked DNA. Targeted gene delivery into subcutaneously growing tumors after systemic application was achieved using electroneutral AVET complexes and sterically stabilized PEGylated Tf-PEI/DNA complexes, whereas application of positively charged polycation/DNA complexes resulted in predominant gene expression in the lungs and was associated by considerable toxicity. CONCLUSION: For systemic application, the physical and colloidal parameters of the transfection complexes, such as particle size, stability, and surface charge, determine DNA biodistribution, toxicity, and transfection efficacy. By controlling these parameters, DNA biodistribution and gene expression can be targeted to different organs.
BACKGROUND: Efficient and target-specific in vivo gene delivery is a major challenge in gene therapy. Compared to cell culture application, in vivo gene delivery faces a variety of additional obstacles such as anatomical size constraints, interactions with biological fluids and extracellular matrix, and binding to a broad variety of non-target cell types. METHODS: Polycation-based vectors, including adenovirus-enhanced transferrinfection (AVET) and transferrin-polyethylenimine (Tf-PEI), were tested for gene delivery into subcutaneously growing tumors after local and systemic application. DNA biodistribution and reporter gene expression was measured in the major organs and in the tumor. RESULTS: Gene transfer after intratumoral application was 10-100 fold more efficient with Tf-PEI/DNA or AVET complexes in comparison to naked DNA. Targeted gene delivery into subcutaneously growing tumors after systemic application was achieved using electroneutral AVET complexes and sterically stabilized PEGylated Tf-PEI/DNA complexes, whereas application of positively charged polycation/DNA complexes resulted in predominant gene expression in the lungs and was associated by considerable toxicity. CONCLUSION: For systemic application, the physical and colloidal parameters of the transfection complexes, such as particle size, stability, and surface charge, determine DNA biodistribution, toxicity, and transfection efficacy. By controlling these parameters, DNA biodistribution and gene expression can be targeted to different organs.
Authors: Gillis R Otten; Mary Schaefer; Barbara Doe; Hong Liu; Indresh Srivastava; Jan zur Megede; Jina Kazzaz; Ying Lian; Manmohan Singh; Mildred Ugozzoli; David Montefiori; Mark Lewis; David A Driver; Thomas Dubensky; John M Polo; John Donnelly; Derek T O'Hagan; Susan Barnett; Jeffrey B Ulmer Journal: J Virol Date: 2005-07 Impact factor: 5.103
Authors: Tracy R Daniels; Ezequiel Bernabeu; José A Rodríguez; Shabnum Patel; Maggie Kozman; Diego A Chiappetta; Eggehard Holler; Julia Y Ljubimova; Gustavo Helguera; Manuel L Penichet Journal: Biochim Biophys Acta Date: 2011-08-05
Authors: Gemma Navarro; Rupa R Sawant; Sean Essex; Conchita Tros de Ilarduya; Vladimir P Torchilin Journal: Drug Deliv Transl Res Date: 2011-02-01 Impact factor: 4.617