Evaluation of Human Skin-Derived Stem Cell Characteristics After Non-Invasive Quantum Dot Labeling.

BACKGROUND/AIMS: The use of skin-derived stem cells and stem cells of other origins in regenerative medicine requires knowledge of stem cell fate after transplantation. In order to achieve non-invasive long-term imaging and tracking of transplanted stem cells in preclinical studies, a non-toxic, efficient labeling technique that does not alter stem cell characteristics must be used. Our aim was to investigate a method for such a long-term cell-compatible cell tracer using nanoparticles. METHODS: Nanotechnology, in particular the use of quantum dots (QDs), offers great advantages for this crucial requirement. In this study, we used nanocrystals coated with a specific target peptide that enables delivery into the cytoplasm of cells, resulting in an intense and stable fluorescent labeling. We analyzed the influence of biocompatible CdSe/ZnS-QDs on epidermal stem cells (EpiSCs) isolated from adult human skin. Thereby we analyzed on QD loading, cell proliferation including QD transfer to descendent daughter cells as well as the influence on the differentiation potential of stem cells after QD labeling. RESULTS: FACS analysis revealed a dose-dependent QD incorporation into the cells. Thereby, a high initial concentration of nanocrystals resulted in a more stable long-term labeling. QD labeled cells showed normal viability and unchanged ability to proliferate. The spread of QDs during cell division was monitored by time lapse microscopy and two modes of QD distribution could be observed. Daughter cells either received an equal amount of QDs after cell division, which led to a homogenously faded fluorescence signal, or there was an uneven transmission of QDs, which led to unchanged labeling of one cell and a complete loss of the fluorescence signal of the other cell. The spontaneous differentiation potential remained unaffected after QD exposure, since skin-derived EpiSCs showed an unchanged protein and gene expression profile. CONCLUSION: In summary, we can conclude that QDs offer a successful, non-invasive and efficient labeling technique for EpiSCs, which makes their in vitro and in vivo use in skin regeneration and wound healing models traceable. Nevertheless, the uneven transmission of QDs should not be disregarded and the extent and frequency should be investigated in further studies.

Multipotent nestin-positive stem cells reside in the stroma of human eccrine and apocrine sweat glands and can be propagated robustly in vitro.

Human skin harbours multiple different stem cell populations. In contrast to the relatively well-characterized niches of epidermal and hair follicle stem cells, the localization and niches of stem cells in other human skin compartments are as yet insufficiently investigated. Previously, we had shown in a pilot study that human sweat gland stroma contains Nestin-positive stem cells. Isolated sweat gland stroma-derived stem cells (SGSCs) proliferated in vitro and expressed Nestin in 80% of the cells. In this study, we were able to determine the precise localization of Nestin-positive cells in both eccrine and apocrine sweat glands of human axillary skin. We established a reproducible isolation procedure and characterized the spontaneous, long-lasting multipotent differentiation capacity of SGSCs. Thereby, a pronounced ectodermal differentiation was observed. Moreover, the secretion of prominent cytokines demonstrated the immunological potential of SGSCs. The comparison to human adult epidermal stem cells (EpiSCs) and bone marrow stem cells (BMSCs) revealed differences in protein expression and differentiation capacity. Furthermore, we found a coexpression of the stem cell markers Nestin and Iα6 within SGSCs and human sweat gland stroma. In conclusion the initial results of the pilot study were confirmed, indicating that human sweat glands are a new source of unique stem cells with multilineage differentiation potential, high proliferation capacity and remarkable self renewal. With regard to the easy accessibility of skin tissue biopsies, an autologous application of SGSCs in clinical therapies appears promising.