KIR-HLA receptor-ligand mismatch associated with a graft-versus-tumor effect in haploidentical stem cell transplantation for pediatric metastatic solid tumors.

Killer immunoglobulin-like receptors (KIRs) on natural killer cells (NKs) recognize groups of human leukocyte antigen (HLA) class I alleles. Cells without an inhibitory HLA ligand may trigger NK activation. Reduced risk of relapse has been reported in malignant hematologic diseases after haploidentical transplantation when HLA ligands against the inhibitory KIRs present in the donor were absent in the recipient.

An in vivo model of wound healing in genetically modified skin-humanized mice.

Cutaneous wound-healing disorders are a major health problem that requires the development of innovative treatments. Whithin this context, the search for reliable human wound-healing models that allow us to address both mechanistic and therapeutic matters is warranted. In this study, we have developed a novel invivo wound-healing model in a genetically modified human context.

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.

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.