3D In vitro model of the re-epithelialization phase in the wound-healing process.

Keratinocytes of the basal layer function are to maintain tissue homoeostasis and to fulfil skin repair in response to an external aggression. In wound-healing, during re-epithelialization phase, epithelial precursor cells gradually migrate from the edges of the wound. The epidermal reconstruction model called standard model allows the vertical skin regeneration process (proliferation/differentiation) to being investigated, and keratinocyte function in preserving skin homoeostasis to being assessed. Here, we developed and characterized a 3D migration model, which introduces a step of keratinocytes migration such as the one observed in the phase of re-epithelialization in wound-healing process. We validated the added value and the discriminative potential of this model by demonstrating pro-epithelializing effects of compounds. This new model allows the role of keratinocytes in different biomechanical and environmental requests to being better understood, and brings a new tool for compound screening and the study of mechanisms involved in skin regeneration.

Ageing and colony-forming efficiency of human hair follicle keratinocytes.

The decline of tissue regenerative potential of skin and hair is a hallmark of physiological ageing and may be associated with age-related changes in tissue-specific stem cells and/or their environment. Human hair follicles (hHF) contain keratinocytes having the property of stem cells such as clonogenic potential. Growth capacity of hHF keratinocytes shows that most of the colony-forming cells are classified as holoclones, meroclones or paraclones when analysed in a clonal assay (Cell, Volume 76, page 1063). Despite the well-known impact of ageing on human hair growth, little is known about changes in hHF keratinocyte clonogenic potential with age. This study aimed at assessing the clone-forming efficiency (CFE) of hHF keratinocytes from three age groups of human donors. It demonstrates that ageing affects hHF keratinocyte CFE.

Cellular adhesion on collagen: a simple method to select human basal keratinocytes which preserves their high growth capacity.

The regenerative capacity of human interfollicular epidermis is closely linked to the potential of immature keratinocytes present within its basal layer. The availability of selection methods and culture systems allowing precise assessment of basal keratinocyte characteristics is critical for increasing our knowledge of this cellular compartment. This report presents a multi-parametric comparative study of basal keratinocytes selected according to two different principles: 1) high adhesion capacity on a type-I collagen-coated substrate [Adh⁺⁺⁺], 2) high cell-surface expression of α6-integrin [Itg-α6 (high)]. Importantly, analysis performed at the single-cell level revealed similar primary clone-forming efficiency values of 45.5% ±â€Š6.7% [Itg-α6(high)] and 43.7% ±â€Š7.4% [Adh⁺⁺⁺], which were markedly higher than those previously reported. In addition, both methods selected keratinocytes exhibiting an extensive long-term growth potential exceeding 100 cell doublings and the capacity for generating a pluristratified epidermis. Our study also included a global transcriptome comparison. Genome-wide profiling indicated a strong similarity between [Adh⁺⁺⁺] and [Itg-α6(high)] keratinocytes, and revealed a common basal-associated transcriptional signature. In summary, cross-analysis of [Adh⁺⁺⁺] and [Itg-α6(high)] keratinocyte characteristics showed that these criteria identified highly equivalent cellular populations, both characterized by unexpectedly high growth capacities. These results may have broad impacts in the tissue engineering and cell therapy fields.

Human long-term deregulated circadian rhythm alters regenerative properties of skin and hair precursor cells.

In mammals, desynchronized circadian rhythm leads to various biological symptoms. In skin and hair, human epidermal stem cell function in vitro is regulated by circadian oscillations, and thus contributes to tissue aging when deregulated. In mice, circadian arrhythmia of hair follicle stem cells contributes to age-related hair follicle cycling defects. Despite the well-described impact of circadian oscillations through a feedback loop involving the clock pathway on hair and skin stem cell function in vitro, little is known about the change in characteristics or regenerative properties of hHF (human hair follicle keratinocytes), hEpi (human interfollicular epidermal keratinocytes), and hHFDP (hair follicle dermal papilla stem cells) after long-term alteration of circadian rhythm in vivo. The present study was designed to asses hHF, hEpi, and hHFDP precursors and stem cell properties in response to clock pathway alteration due to long-term deregulated circadian rhythm in vivo. A clinical study protocol was designed to include two groups of women: diurnal workers (control) and shift workers (deregulated). After informed consent, two 3-mm fresh punch biopsies were taken from the occipital region of each donor (10 donors/group). Cell culture characterization, measurement of colony area, culture medium analysis, and RT-qPCR analysis were carried out. Long-term circadian rhythm deregulation affected clock pathway protein expression and correlated with alterations in hHF, hEpi, and hHFDP properties. This study provides, for the first time in humans, evidence that in vivo deregulation of the clock pathway affects regenerative properties of human skin and hair precursor cells.

Evolution of the clonogenic potential of human epidermal stem/progenitor cells with age.

A number of clinical observations have indicated that the regenerative potential and overall function of the epidermis is modified with age. The epidermis becomes thinner, repairs itself less efficiently after wounding, and presents modified barrier function recovery. In addition, the dermal papillae fatten out with increasing age, suggesting a modification in the interaction between epidermal and dermal compartments. As the epidermal regenerative capacity is dependent upon stem and progenitor cell function, it is naturally of interest to identify and understand age-related changes in these particular keratinocyte populations. Previous studies have indicated that the number of stem cells does not decrease with age in mouse models but little solid evidence is currently available concerning human skin. The objective of this study was to evaluate the clonogenic potential of keratinocyte populations isolated from the epidermis of over 50 human donors ranging from 18 to 71 years old. The data indicate that the number of epidermal cells presenting high regenerative potential does not dramatically decline with age in human skin. The authors believe that changes in the microenvironment controlling epidermal basal cell activity are more likely to explain the differences in epidermal function observed with increasing age.

[Origins and selection of epidermal progenitors and stem cells: a challenge for tissue engineering]. / Origines & sélection de progéniteurs et cellules souches épidermiques: Un défi pour l'ingénierie tissulaire.

The use of epidermal stem cells and their progeny for tissue engineering and cell therapy represents a source of hope and major interest in view of applications such as replacing the loss of functionality in failing tissues or obtaining physiologic skin equivalents for skin grafting. The use of such cells necessitates the isolation and purification of rare populations of keratinocytes and then increasing their numbers by mass culture. This is not currently possible since part of the specific phenotype of these cells is lost once the cells are placed in culture. Furthermore, few techniques are available to unequivocally detect the presence of skin stem cells and/or their progeny in culture and thus quantify them. Two different sources of stem cells are currently being studied for skin research and clinical applications: skin progenitors either obtained from embryonic stem cells (ESC) or from selection from adult skin tissue. It has been shown that "keratinocyte-like" cells can be derived from ESC; however, the culturing processes must still be optimized to allow for the mass culture of homogeneous populations at a controlled stage of differentiation. The functional characterization of such populations must also be more thoroughly achieved. In order to use stem cells from adult tissues, improvements must be made in order to obtain a satisfactory degree of purification and characterization of this rare population. Distinguishing stem cells from progenitor cells at the molecular level also remains a challenge. Furthermore, stem cell research inevitably requires cultivating these cells outside their physiological environment or niche. It will thus be necessary to better understand the impact of this specific environmental niche on the preservation of the cellular phenotypes of interest.