Characterization of neurons from adult human skin-derived precursors in serum-free medium : a PCR array and immunocytological analysis.

Adult stem cells could be small sources of neurons or other cellular types for regenerative medicine and tissue engineering. Recently, pluripotent stem cells have been extracted from skin tissue, which opened a new accessible source for research. To routinely obtain a high yield of functional neurons from adult human skin stem cells with defined serum-free medium, stem cells from abdominal skin were cultured in serum-free medium. To differentiate them, we used a defined medium containing growth factors. Differentiated cells were identified using the following methods: (i) Oil-red-O staining for adipocytes, immunocytochemistry with antibodies recognising (ii) neurofilaments and PGP9.5 for neural differentiation, (iii) glial fibrillary acidic protein (GFAP) for glial differentiation, (iv) Ki-67 for proliferative cells, (v) FM1-43 staining to analyse vesicle trafficking in neuronal cells and (vi) a PCR array was used. Stem cells were floating in spheres and were maintained in culture for 4 months or more. They expressed nestin and Oct 4 and were proliferative. We induced specific differentiation into adipocytes, glial and neuronal cells. The yields of differentiated neurons were high and reproducible. They were maintained for long time (1 month) in the culture medium. Furthermore, these neurons incorporated FM1-43 dye, which indicates a potent acquisition of synaptic features in neurons. Stem cells from adult human skin could be valuable and reproducible tools/source to obtain high numbers of functional specific cellular types, such as neurons, for tissue engineering. In this work, the possibility to obtain a high yield of differentiated neurons, with the ability of endocytosis and vesicle cell trafficking, was shown.

Regulation of stem cell fate by HSPGs: implication in hair follicle cycling.

Heparan sulfate proteoglycans (HSPGs) are part of proteoglycan family. They are composed of heparan sulfate (HS)-type glycosaminoglycan (GAG) chains covalently linked to a core protein. By interacting with growth factors and/or receptors, they regulate numerous pathways including Wnt, hedgehog (Hh), bone morphogenic protein (BMP) and fibroblast growth factor (FGF) pathways. They act as inhibitor or activator of these pathways to modulate embryonic and adult stem cell fate during organ morphogenesis, regeneration and homeostasis. This review summarizes the knowledge on HSPG structure and classification and explores several signaling pathways regulated by HSPGs in stem cell fate. A specific focus on hair follicle stem cell fate and the possibility to target HSPGs in order to tackle hair loss are discussed in more dermatological and cosmeceutical perspectives.

Hair Histology and Glycosaminoglycans Distribution Probed by Infrared Spectral Imaging: Focus on Heparan Sulfate Proteoglycan and Glypican-1 during Hair Growth Cycle.

The expression of glypicans in different hair follicle (HF) compartments and their potential roles during hair shaft growth are still poorly understood. Heparan sulfate proteoglycan (HSPG) distribution in HFs is classically investigated by conventional histology, biochemical analysis, and immunohistochemistry. In this report, a novel approach is proposed to assess hair histology and HSPG distribution changes in HFs at different phases of the hair growth cycle using infrared spectral imaging (IRSI). The distribution of HSPGs in HFs was probed by IRSI using the absorption region relevant to sulfation as a spectral marker. The findings were supported by Western immunoblotting and immunohistochemistry assays focusing on the glypican-1 expression and distribution in HFs. This study demonstrates the capacity of IRSI to identify the different HF tissue structures and to highlight protein, proteoglycan (PG), glycosaminoglycan (GAG), and sulfated GAG distribution in these structures. The comparison between anagen, catagen, and telogen phases shows the qualitative and/or quantitative evolution of GAGs as supported by Western immunoblotting. Thus, IRSI can simultaneously reveal the location of proteins, PGs, GAGs, and sulfated GAGs in HFs in a reagent- and label-free manner. From a dermatological point of view, IRSI shows its potential as a promising technique to study alopecia.

The Glypican-1/HGF/C-Met and Glypican-1/VEGF/VEGFR2 Ternary Complexes Regulate Hair Follicle Angiogenesis.

The hair renewal involves changes in the morphology of the hair follicle and its micro-vascularization. In alopecia, the hair cycle is accelerated, resulting in the formation of thinner and shorter hair. In addition, alopecia is associated with a decrease in the micro-vascularization of the hair follicles. In this study, the role of glypicans (GPCs) was analyzed in the regulation of the angiogenesis of human dermal microvascular endothelial cells (HDMEC). The analysis of glypican gene expression showed that GPC1 is the major glypican expressed by human keratinocytes of outer root sheath (KORS), human hair follicle dermal papilla cells (HHFDPC) and HDMEC. KORS were demonstrated to secrete VEGF and HGF. The HDMEC pseudotube formation was induced by KORS conditioned media (KORSCM). It was totally abrogated after GPC1 siRNA transfection of HDMEC. Moreover, when cleaved by phospholipase C (PLC), GPC1 promotes the proliferation of HDMEC. Finally, GPC1 was shown to interact directly with VEGFR2 or c-Met to regulate angiogenesis induced by the activation of these receptors. Altogether, these results showed that GPC1 is a key regulator of microvascular endothelial cell angiogenesis induced by VEGF and HGF secreted by KORS. Thus, GPC1 might constitute an interesting target to tackle alopecia in dermatology research.

Ultraviolet-B irradiation induces epidermal up-regulation of heparanase expression and activity.

Heparan sulfate (HS) glycosaminoglycans are abundant components of basement membranes and cell surfaces where they are present associated with specific core-proteins to form proteoglycans, mainly perlecan, glypicans and syndecans. They play many roles such as modulation of cell proliferation and differentiation, cell-matrix adhesion and assembly. It was previously shown that HS content decreases during skin aging. This decrease could be explained either by a decrease of HS synthesis or by an increased activity of its degrading enzyme, heparanase (Hpse-1). Since UV-B irradiation is one of the most important factor for skin photo-damage, we decided to study the effects of UV-B irradiation on heparanase expression and activity in human epidermal keratinocytes. Normal human keratinocytes and reconstructed epidermis were submitted to increasing doses of UV-B. HPSE1 mRNA levels were measured using real time PCR and heparanase enzymatic activity was quantified in human keratinocyte cultures using a microtiter-based assay. Expression and distribution of Hpse-1 were also studied in reconstructed epidermis by immunofluorescence. Both HPSE1 mRNA level and heparanase enzymatic activity were increased after UV-B irradiation of keratinocyte cultures in a time and dose-dependent manner. Protein expression of Hpse-1 was also up-regulated with increasing doses of UV-B in reconstructed epidermis. Increase of Hpse-1 expression and activity in the epidermis after UV-B irradiation could contribute to skin photo-aging.

Ultraviolet-B irradiation induces differential regulations of hyaluronidase expression and activity in normal human keratinocytes.

Skin aging is a complex process determined by genetic factors (intrinsic aging) and environmental factors (extrinsic aging). One of the most influential environmental factor is UV-B irradiation. Hyaluronic acid (HA) is an abundant component of skin extracellular matrix where it plays many roles such as hydration and architectural support. Downregulation of HA during photoaging was reported previously. Changes in expression and function of its degrading enzymes, the hyaluronidases (Hyals) might be involved in this decrease. In the present study, normal human keratinocytes were submitted to increasing doses of UV-B. The mRNA expression of HYAL1, HYAL2 and HYAL3 and the hyaluronidase enzymatic activity were quantified using real-time PCR and a microtiter-based assay, respectively. After UV-B irradiation, HYAL1 mRNA expression was upregulated whereas HYAL2 and HYAL3 mRNAs were downregulated and hyaluronidase enzymatic activity was increased in both cell layer and culture medium. In parallel, immunohistochemical studies performed on UV-B irradiated reconstructed epidermis confirmed that Hyal-1, Hyal-2 and Hyal-3 protein expression were differently regulated by UV-B. Taken together, our results demonstrate that UV-B irradiation induces differential regulations of hyaluronidase expression and enzymatic activity in human keratinocytes. These differential modulations of hyaluronidase expression and activity by UV-B could contribute to cutaneous photoaging.

Characterization of the molecular mechanisms involved in the differential production of erythrose-4-phosphate dehydrogenase, 3-phosphoglycerate kinase and class II fructose-1,6-bisphosphate aldolase in Escherichia coli.

A gapA-pgk gene tandem coding the glyceraldehyde 3-phosphate dehydrogenase and 3-phosphoglycerate kinase, is most frequently found in bacteria. However, in Enterobacteriaceae, gapA is replaced by an epd open reading frame (ORF) coding an erythrose-4-phosphate dehydrogenase and an fbaA ORF coding the class II fructose-1,6-bisphosphate aldolase follows pgk. Although epd expression is very low in Escherichia coli, we show that, in the presence of glucose, the 3 epd, pgk and fbaA ORFs are efficiently cotranscribed from promoter epd P0. Conservation of promoter epd P0 is likely due to its important role in modulation of the metabolic flux during glycolysis and gluconeogenesis. As a consequence, we found that the epd translation initiation region and ORF have been adapted in order to limit epd translation and to create an efficient RNase E entry site. We also show that fbaA is cotranscribed with pgk, from promoter epd P0 or an internal pgk P1 promoter of the extended -10 class. The differential expression of pgk and fbaA also depends upon an RNase E segmentation process, leading to individual mRNAs with different stabilities. The secondary structures of the RNA regions containing the RNase E sites were experimentally determined which brings important information on the structural features of RNase E ectopic sites.