2-Mercaptonicotinoyl glycine, a new potent melanogenesis inhibitor, exhibits a unique mode of action while preserving melanocyte integrity.

Research on new ingredients that can prevent excessive melanin production in the skin while considering efficacy, safety but also environmental impact is of great importance to significantly improve the profile of existing actives on the market and avoid undesirable side effects. Here, the discovery of an innovative technology for the management of hyperpigmentation is described. High-throughput screening tests on a wide chemical diversity of molecules and in silico predictive methodologies were essential to design an original thiopyridinone backbone and select 2-mercaptonicotinoyl glycine (2-MNG) as exhibiting the most favorable balance between the impact on water footprint, skin penetration potential and performance. The effectiveness of 2-MNG was confirmed by topical application on pigmented reconstructed epidermis and human skin explants. In addition, experiments have shown that unlike most melanogenesis inhibitors on the market, this molecule is not a tyrosinase inhibitor. 2-MNG binds to certain melanin precursors, preventing their integration into growing melanin and leading to inhibition of eumelanin and pheomelanin synthesis, without compromising the integrity of melanocytes.

Genetic correction of stem cells in the treatment of inherited diseases and focus on xeroderma pigmentosum.

Somatic stem cells ensure tissue renewal along life and healing of injuries. Their safe isolation, genetic manipulation ex vivo and reinfusion in patients suffering from life threatening immune deficiencies (for example, severe combined immunodeficiency (SCID)) have demonstrated the efficacy of ex vivo gene therapy. Similarly, adult epidermal stem cells have the capacity to renew epidermis, the fully differentiated, protective envelope of our body. Stable skin replacement of severely burned patients have proven life saving. Xeroderma pigmentosum (XP) is a devastating disease due to severe defects in the repair of mutagenic DNA lesions introduced upon exposure to solar radiations. Most patients die from the consequences of budding hundreds of skin cancers in the absence of photoprotection. We have developed a safe procedure of genetic correction of epidermal stem cells isolated from XP patients. Preclinical and safety assessments indicate successful correction of XP epidermal stem cells in the long term and their capacity to regenerate a normal skin with full capacities of DNA repair.

Preclinical corrective gene transfer in xeroderma pigmentosum human skin stem cells.

Xeroderma pigmentosum (XP) is a devastating disease associated with dramatic skin cancer proneness. XP cells are deficient in nucleotide excision repair (NER) of bulky DNA adducts including ultraviolet (UV)-induced mutagenic lesions. Approaches of corrective gene transfer in NER-deficient keratinocyte stem cells hold great hope for the long-term treatment of XP patients. To face this challenge, we developed a retrovirus-based strategy to safely transduce the wild-type XPC gene into clonogenic human primary XP-C keratinocytes. De novo expression of XPC was maintained in both mass population and derived independent candidate stem cells (holoclones) after more than 130 population doublings (PD) in culture upon serial propagation (>10(40) cells). Analyses of retrovirus integration sequences in isolated keratinocyte stem cells suggested the absence of adverse effects such as oncogenic activation or clonal expansion. Furthermore, corrected XP-C keratinocytes exhibited full NER capacity as well as normal features of epidermal differentiation in both organotypic skin cultures and in a preclinical murine model of human skin regeneration in vivo. The achievement of a long-term genetic correction of XP-C epidermal stem cells constitutes the first preclinical model of ex vivo gene therapy for XP-C patients.

[Cutaneous gene therapy: the graft takes]. / Thérapie génique cutanée : La greffe prend.

Prospects of ex vivo cutaneous gene therapy rely on stable corrective gene transfer in epidermal stem cells followed by engraftment of corrected cells in patients. In the case of cancer prone genodermatoses, such as xeroderma pigmentosum, cells that received the corrective gene must be selected. However, this step is potentially harmful and can increase risks of immune rejection of grafts. These obstacles have recently been overcome thanks to the labeling of genetically modified stem cells using a small epidermal protein naturally absent in stem cells. This approach was shown to be respectful of the fate of epidermal stem cells that retained full growth and differentiation capacities, as well as their potential to regenerate normal human skin when grafted in a mouse model in the long term. These progresses now open realistic avenues towards ex vivo cutaneous gene therapy of cancer prone genodermatoses such as xeroderma pigmentosum. However, major technical improvements are still necessary to preserve skin appendages which would contribute to aesthetic features and comfort of patients.

[Epidermal stem cells and ex vivo cutaneous gene therapy: application to xeroderma pigmentosum]. / Cellules souches épidermiques et thérapie génique cutanée ex vivo: application au xeroderma pigmentosum.

Ex vivo cutaneous gene therapy is an alternative treatment for recessively inherited diseases with cutaneous traits. It relies on the transfer in cultured epidermal keratinocytes of the wild-type allele of the gene whose mutation is responsible for the disease. As for severely burnt patients, epithelial sheets developed from genetically corrected cells may then be grafted back to the patients. Long term correction and graft take depend on the genetic correction of stem cells. Success of such an approach has recently been reported in the case of one patient suffering from a severe case of junctional epidermolysis bullosae. Here we report a method for safely selecting keratinocytes populations after genetic manipulation. The method is non invasive and non immunogenic and allows high enrichment of genetically manipulated stem keratinocytes. This could perhaps contribute to ex vivo gene therapy approaches of cancer prone genodermatoses such as xeroderma pigmentosum.