• Ex vivo culture of patient tissue & examination of gene delivery.

      Rajendran, Simon; Salwa, Slawomir; Gao, Xuefeng; Tabirca, Sabin; O'Hanlon, Deirdre; O'Sullivan, Gerald C; Tangney, Mark; Cork Cancer Research Centre, Mercy University Hospital and Leslie C. Quick Jnr., Laboratory, University College Cork. (2012-01-31)
      This video describes the use of patient tissue as an ex vivo model for the study of gene delivery. Fresh patient tissue obtained at the time of surgery is sliced and maintained in culture. The ex vivo model system allows for the physical delivery of genes into intact patient tissue and gene expression is analysed by bioluminescence imaging using the IVIS detection system. The bioluminescent detection system demonstrates rapid and accurate quantification of gene expression within individual slices without the need for tissue sacrifice. This slice tissue culture system may be used in a variety of tissue types including normal and malignant tissue and allows us to study the effects of the heterogeneous nature of intact tissue and the high degree of variability between individual patients. This model system could be used in certain situations as an alternative to animal models and as a complementary preclinical mode prior to entering clinical trial.
    • A novel Listeria monocytogenes-based DNA delivery system for cancer gene therapy.

      van Pijkeren, Jan Peter; Morrissey, David; Monk, Ian R; Cronin, Michelle; Rajendran, Simon; O'Sullivan, Gerald C; Gahan, Cormac G M; Tangney, Mark; Cork Cancer Research Centre, Mercy University Hospital and Leslie C. Quick Jnr., Laboratory, University College Cork, Cork, Ireland. (2012-01-31)
      Bacteria-mediated transfer of plasmid DNA to mammalian cells (bactofection) has been shown to have significant potential as an approach to express heterologous proteins in various cell types. This is achieved through entry of the entire bacterium into cells, followed by release of plasmid DNA. In a murine model, we show that Listeria monocytogenes can invade and spread in tumors, and establish the use of Listeria to deliver genes to tumors in vivo. A novel approach to vector lysis and release of plasmid DNA through antibiotic administration was developed. Ampicillin administration facilitated both plasmid transfer and safety control of vector. To further improve on the gene delivery system, we selected a Listeria monocytogenes derivative that is more sensitive to ampicillin, and less pathogenic than the wild-type strain. Incorporation of a eukaryotic-transcribed lysin cassette in the plasmid further increased bacterial lysis. Successful gene delivery of firefly luciferase to growing tumors in murine models and to patient breast tumor samples ex vivo was achieved. The model described encompasses a three-phase treatment regimen, involving (1) intratumoral administration of vector followed by a period of vector spread, (2) systemic ampicillin administration to induce vector lysis and plasmid transfer, and (3) systemic administration of combined moxifloxacin and ampicillin to eliminate systemic vector. For the first time, our results reveal the potential of Listeria monocytogenes for in vivo gene delivery.