An integrative multi-omic analysis reveals a major metabolic rewiring between baby foreskin keratinocytes and adult female abdominal keratinocytes.

Even though its development starts early in utero, neonatal skin is still immature at birth relative to adult and undergoes a maturation process extending to the first years of life. It is now established that the stratum corneum is thinner and dryer and that skin contains less natural moisturizing factors and lipids in newborns compared to children and adults. Moreover, it has been shown that skin surface area expansion is not linear throughout life and is peaking perinatally, suggesting that baby skin has a higher epidermal cellular turnover. Despite growing resources showing differences between adult and infant skin physiology, molecular and metabolic specificities of baby skin are still poorly understood. To address this critical knowledge gap, we performed an integrative transcriptomic and metabolomic study comparing human primary foreskin and abdominal keratinocytes from male babies and female adults, respectively. Based on state-of-the-art integrative frameworks, our analyses revealed a major shift in the global energetic metabolism in baby foreskin keratinocytes compared to adult abdominal keratinocytes, highlighting increased amino acid metabolism and mitochondrial oxidative phosphorylation in baby cells to fuel the citric acid cycle, while showing glycolysis as the major cell energy source in adult cells.

In Vitro Differentiation of Human Skin-Derived Cells into Functional Sensory Neurons-Like.

Skin-derived precursor cells (SKPs) are neural crest stem cells that persist in certain adult tissues, particularly in the skin. They can generate a large type of cell in vitro, including neurons. SKPs were induced to differentiate into sensory neurons (SNs) by molecules that were previously shown to be important for the generation of SNs: purmorphamine, CHIR99021, BMP4, GDNF, BDNF, and NGF. We showed that the differentiation of SKPs induced the upregulation of neurogenins. At the end of the differentiation protocol, transcriptional analysis was performed on BRN3A and a marker of pain-sensing nerve cell PRDM12 genes: 1000 times higher for PRDM12 and 2500 times higher for BRN3A in differentiated cells than they were in undifferentiated SKPs. Using immunostaining, we showed that 65% and 80% of cells expressed peripheral neuron markers BRN3A and PERIPHERIN, respectively. Furthermore, differentiated cells expressed TRPV1, PAR2, TRPA1, substance P, CGRP, HR1. Using calcium imaging, we observed that a proportion of cells responded to histamine, SLIGKV (a specific agonist of PAR2), polygodial (a specific agonist of TRPA1), and capsaicin (a specific agonist of TRPV1). In conclusion, SKPs are able to differentiate directly into functional SNs. These differentiated cells will be very useful for further in vitro studies.

Phenotypic and functional changes in dermal primary fibroblasts isolated from intrinsically aged human skin.

Dermal fibroblasts play a key role in maintaining skin homoeostasis by synthesizing and degrading extracellular matrix components. During ageing, they are subjected to changes, such as the loss of type I collagen expression and an increased synthesis of metalloproteinase I, leading to fragmentation of collagen fibrils with consequent reduction of the mechanical tension and defects of skin wound healing. Most information about fibroblast ageing was obtained from experiments performed on replicative-senescent dermal fibroblasts in vitro. However, the senescence status of fibroblasts isolated from intrinsically aged skins and its consequences on functionality need to be deeper investigated. Herein, we studied age-related phenotypic and functional alteration of fibroblasts from 'young' (<35 years) and 'old' (>50 years) donors. Our results brought evidence of the senescent status of 'old' fibroblasts by senescence associated ß-galactosidase (SA-ßgal) positive staining and p16 expression. A PCR array focusing on senescence highlighted a subset of downregulated genes including cell cycle progression and ECM genes in 'old' fibroblasts as well as a subset of upregulated genes involved in senescence features. In 'old' fibroblasts, we measured a downregulation of proliferative and contractile capacities of migratory potential under PDGF stimulation and activation into myofibroblasts under TGFß. Old fibroblasts were also more sensitive to oxidative stress than 'young' ones. Of interest, downregulation of p16 expression partially reversed the senescent phenotype of 'old' fibroblasts but failed to restore their functional properties. In conclusion, our data brought evidence of phenotypic and functional differences between fibroblasts from young and intrinsically aged skin that may contribute to the alterations observed with ageing.

T-plastin expression downstream to the calcineurin/NFAT pathway is involved in keratinocyte migration.

Cutaneous wound healing requires keratinocyte proliferation, migration and differentiation to restore the barrier function of the skin. The calcineurin/nuclear factor of activated-T-cell (NFAT) signaling pathway has been recently shown to be involved in keratinocyte growth, differentiation and migration. It is induced by an increased intracellular calcium rate and its inhibition results in decreased capacities of keratinocytes to migrate. Nevertheless, the link between calcineurin activation and keratinocyte migration remains unknown. Recently, Orai1, a pore subunit of a store-operated calcium channel that favors calcium influx, was shown to play a critical role to control proliferation and migration of basal keratinocytes. Of interest, the actin-bundling T-plastin is crucial in cell motility through cross-linking to actin filament and its synthesis was shown to be induced by calcium influx and regulated by the calcineurin/NFAT pathway in tumor Sezary cells. We investigated herein the role of the calcineurin/NFAT pathway-dependent T-plastin in keratinocyte migration, by quantifying T-plastin expression in keratinocytes and by analyzing their migration under calcineurin inhibition or knockdown of NFAT2 or T-plastin. We did confirm the role of the calcineurin/NFAT pathway in keratinocyte migration as shown by their decreased capacities to migrate after FK506 treatment or siNFAT2 transfection in both scratching and Boyden assays. The expression of NFAT2 and T-plastin in keratinocytes was decreased under FK506 treatment, suggesting that T-plastin plays a role in keratinocyte migration downstream to the calcineurin/NFAT pathway. Accordingly, siRNA knockdown of T-plastin expression also decreased their migration capacities. Actin lamellipodia formation as well as FAK and ß6-integrin expression were also significantly decreased after treatment with FK506 or siRNA, reinforcing that NFAT2-dependent T-plastin expression plays a role in keratinocyte migration. These results indicate that T-plastin might be considered as a major actor in the mechanisms underlying calcineurin/NFAT-dependent keratinocyte migration and may explain wound-healing defects observed in patients under calcineurin inhibitor long-term treatment.

Expression of transforming growth factor ß receptor II in mesenchymal stem cells from systemic sclerosis patients.

OBJECTIVES: The present work aimed to evaluate the expression of transforming growth factor-ß (TGF-ß) receptors on bone marrow-derived multipotent mesenchymal stromal cells (MSCs) in patients with systemic sclerosis (SSc) and the consequences of TGF-ß activation in these cells, since MSC have potential therapeutic interest for SSc patients and knowing that TGF-ß plays a critical role during the development of fibrosis in SSc. DESIGN: This is a prospective research study using MSC samples obtained from SSc patients and compared with MSC from healthy donors. SETTING: One medical hospital involving collaboration between an internal medicine department for initial patient recruitment, a clinical biotherapeutic unit for MSC preparation and an academic laboratory for research. PARTICIPANTS: 9 patients with diffuse SSc for which bone marrow (BM) aspiration was prescribed by sternum aspiration before haematopoietic stem cell transplantation, versus nine healthy donors for normal BM. PRIMARY AND SECONDARY OUTCOME MEASURES: TGF-ß, TGF-ß receptor types I (TBRI) and II (TBRII) mRNA and protein expression were assessed by quantitative PCR and flow cytometry, respectively, in MSC from both SSc patients and healthy donors. MSC were exposed to TGF-ß and assessed for collagen 1α2 synthesis and Smad expression. As positive controls, primary cultures of dermal fibroblasts were also analysed. RESULTS: Compared with nine controls, MSC from nine SSc patients showed significant increase in mRNA levels (p<0.002) and in membrane expression (p<0.0001) of TBRII. In response to TGF-ß activation, a significant increase in collagen 1α synthesis (p<0.05) and Smad-3 phosphorylation was upregulated in SSc MSC. Similar results were obtained on eight SSc-derived dermal fibroblasts compared to six healthy controls. CONCLUSIONS: TBRII gene and protein expression defect in MSC derived from SSc patients may have pathological significance. These findings should be taken into account when considering the use of MSC-based therapies in an autologous setting.