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A Preclinical Model for the Analysis of Genetically Modified Human Skin In Vivo

2002; Mary Ann Liebert, Inc.; Volume: 13; Issue: 8 Linguagem: Inglês

10.1089/10430340252939069

1557-7422

Marcela Del Río, Fernando Larcher, Fernando E. Serrano, Álvaro Meana, Marta Muñoz, Marta García, Evangelina Muñoz, Clara Martín, António Bernad, José L. Jorcano,

Transgenic Plants and Applications

Although skin is perhaps the most accessible of all somatic tissues for therapeutic gene transfer, it is a challenging site when attempting gene delivery. In addition to the transience of gene expression, important obstacles to cutaneous gene therapy have included the inability to sustain gene expression in a large proportion of keratinocytes within a given skin compartment. In this study, we have developed a novel experimental strategy that allows long-term regeneration of entirely genetically engineered human skin on the backs of NOD/SCID mice. Primary human keratinocytes were infected with a retroviral vector encoding the enhanced green fluorescent protein (EGFP) produced by transient transfection of 293T cells. EGFP expression allowed cell-sorting selection of a polyclonal population of productively transduced keratinocytes that were assembled in a live fibroblast-containing fibrin dermal matrix and orthotopically grafted onto mice. Epifluorescent illumination of the transplanted zone allowed in vivo monitoring of the genetically modified graft. EGFP-positive human skin was present on mice for 22 weeks after grafting. In addition, frozen sections prepared from the grafts displayed consistently strong EGFP-based fluorescence in all epidermal strata at every time point examined. Persistence of transgene expression was further confirmed through EGFP protein immunodetection. Purified EGFP-positive keratinocytes grafted as part of the fibrin-based artificial skin were capable of generating multilayer human epidermis on mice, with well-developed granulosum and corneum strata, and clearly defined rete ridges. Finally, the large proportion of transduced keratinocytes in our grafts allowed us to study, for the first time, the long-term in vivo clonal reconstitution pattern of the regenerated skin. Analysis of the provirus insertion sites indicates that a discrete number of epidermal stem cell clones was responsible for the maintenance of human skin regenerated in NOD/SCID recipients.