Fernando Serrano

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

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.

A cutaneous gene therapy approach to human leptin deficiencies: correction of the murine ob/ob phenotype using leptin-targeted keratinocyte grafts

Leptin deficiency produces a phenotype of obesity, diabetes, and infertility in the ob/ob mouse. In humans, leptin deficiency occurs in some cases of congenital obesity and in lipodystrophic disorders characterized by reduced adipose tissue and insulin resistance. Cutaneous gene therapy is considered an attractive potential method to correct circulating protein deficiencies, since gene‐transferred human keratinocytes can produce and secrete gene products with systemic action. However, no studies showing correction of a systemic defect have been reported. We report the successful correction of leptin deficiency using cutaneous gene therapy in the ob/ob mouse model. As a feasibility approach, skin explants from transgenic mice overexpressing leptin were grafted on immunodeficient ob/ob mice. One month later, recipient mice reached body weight values of lean animals. Other biochemical and clinical parameters were also normalized. In a second human gene therapy approach, a retroviral vector encoding both leptin and EGFP cDNAs was used to transduce HK and, epithelial grafts enriched in high leptin‐producing HK were transplanted to immunosuppressed ob/ob mice. HK‐derived leptin induced body weight reduction after a drop in blood glucose and food intake. Leptin replacement through genetically engineered HK grafts provides a valuable therapeutic alternative for permanent treatment of human leptin deficiency conditions.—Larcher, F., Del Rio, M., Serrano, F., Segovia, J. C., Ramírez, A., Meana, A., Page, A., Abad, J. L., González, M. A., Bueren, J., Bernad, A., Jorcano, J. L. A cutaneous gene therapy approach to human leptin deficiencies: correction of the murine ob/ob phenotype using leptin‐tar‐geted keratinocyte grafts. FASEB J. 15, 1529–1538 (2001)

Single-step, multiple retroviral transduction of human T cells.

Retroviral transduction of human peripheral blood T cells has considerable potential in the development of gene therapy strategies for immunological disorders. New vectors and experimental procedures have been developed for efficient transduction of several genes into human T cells.

Novel interfering bifunctional molecules against the CCR5 coreceptor are efficient inhibitors of HIV-1 infection

CCR5 is the major coreceptor for the HIV-1 strains responsible for primary infection. Individuals homozygous for a 32-bp deletion in the CCR5 coding region are resistant to HIV-1 infection. Strategies to delete CCR5 functionally could thus be of substantial benefit in preventing HIV-1 infection or delaying disease. We evaluated new molecules for their ability to inhibit cell membrane CCR5 expression and to prevent HIV-1 infection. These inhibitors include several truncated forms of CCR5 that may act as negative transdominants, as well as bifunctional molecules resulting from the combination of a previously described anti-CCR5 ribozyme or a truncated CCR5 variant with an intracellular chemokine (RANTES-KDEL). These constructs efficiently blocked membrane CCR5 expression when cotransfected into HEK 293 cells. When expressed by retroviral transduction, some of these molecules significantly inhibited CCR5-dependent chemotaxis in the MCF-7 cell line and reduced CCR5 expression and HIV-1 infection in human T cells. Analysis of inhibitors with different efficiencies showed a strong linear correlation between CCR5 expression inhibition and prevention of HIV-1 infection. This study indicates the potential clinical application of several new CCR5 inhibitory molecules for HIV-1 gene therapy.

A Comparison of Targeting Performance of Oncoretroviral Versus Lentiviral Vectors on Human Keratinocytes

The epidermis, like other rapidly renewing tissues, relies on a stem cell compartment to undergo constant regeneration. In order to develop realistic and long-lasting therapeutic approaches for some skin disorders, gene transfer to these critical cells must be obtained. While efficient retroviral ex vivo targeting and transgene integration in human keratinocytes is tightly dependent on proliferation, transferring genetic information to quiescent cells in culture also presents advantages, including the possibility of targeting putative dormant epidermal stem cells. In the present study we compared the efficiency of transduction achieved with a third-generation of human immunodeficiency virus (HIV)-based lentiviral vector to that obtained with a Moloney murine leukemia oncoretroviral vector (MLV) on proliferating and quiescent human keratinocytes growing in vitro in standard Rheinwald and Green cultures as well as in confluent organotypic cultures. Each viral vector contained the enhanced green fluorescent protein (EGFP) as a reporter gene. The lentiviral vector, but not the MLV vector, led to EGFP expression both in nondividing and proliferating epidermal cell populations in vitro. This feature was clearly evident when direct targeting of human keratinocytes, forming part of the epidermal component of an organotypic skin culture, was attempted. Keratinocytes modified by both MLV and the lentiviral vector allowed long-term regeneration of genetically engineered human skin on the backs of immunodeficient nonobese diabetic/severe combined immunodeficiency disorders (NOD/SCID) mice. However, EGFP transgene expression in the context of the MLV (long-terminal repeat [LTR]-driven) or lentiviral vector (cytomegalovirus [CMV]-driven) demonstrated clear differences both in quantitative terms and in the in vivo localization pattern.

DeltahGHR, a Novel Biosafe Cell Surface-Labeling Molecule for Analysis and Selection of Genetically Transduced Human Cells

We describe a new selectable marker for retroviral transduction and selection of human and murine cells. The molecule expressed on the cell surface of the transduced population is a truncated version of human growth hormone receptor (deltahGHR), capable of ligand (hGH) binding, but devoid of the domains involved in signal triggering. We demonstrate that the engineered molecule is stably expressed in the target cells as an inert protein unable to trigger proliferation or to rescue the cells from apoptosis after ligand binding. This new marker will probably have a wide application spectrum, since hGHR in the human adult is highly expressed only in liver cells, and lower levels have been reported in certain lymphocyte cell populations. The deltahGHR label has high biosafety potential, as it belongs to a well-characterized hormonal system that is nonessential in adults, and there is extensive clinical experience with hGH administration in humans. This record allows us to hypothesize the lack of relevant clinical consequences resulting from massive transgene expression caused by successful replacement of a large tissue with genetically transduced cells. We take advantage of the differential binding properties of several monoclonal antibodies (MAbs) in describing a cell rescue method in which the antibody used to select deltahGHR-transduced cells is eluted by competition with hGH or, alternatively biotinylated hGH is used to capture tagged cells. In the latter system, the final purified population would be recovered free of attached antibodies in hGH (a substance approved for human use)-containing medium, providing additional biosafety relative to currently existing methods that rely on the use of murine MAb to rescue genetically labeled cells.

860. Sustained Long_Term In Vivo Expression of Human Factor IX from Keratinocytes Transduced with HIV_Based Vectors

Hemophilia B is caused by a deficiency in coagulation factor IX (FIX), and is due to mutations in the factor IX gene. Patients suffer from severe bleeding disorders that may cause chronic tissue inflammation and degeneration. The only treatments currently available are paliative. Hemophilia B is a good candidate for cutaneous gene therapy, since factor levels as low as 1% of normal (3-5 |[mu]|g/ml) will ameliorate symptoms and keratinocytes can synthesize biologically active FIX.