Androgens induce sebaceous differentiation in sebocyte cells expressing a stable functional androgen receptor.

Androgens act through non-genomic and androgen receptor (AR)-dependent genomic mechanisms. AR is expressed in the sebaceous gland and the importance of androgens in the sebaceous function is well established. However, the in vitro models used to date have failed to evidence a clear genomic effect (e.g., modification of gene expression profile) of androgens on human sebocyte cells. In order to study the impact of active androgens in sebocytes, we constructed a stable human sebocyte cell line derived from SEBO662 [17] constitutively expressing a fully functional AR. In these SEBO662 AR+ cells, dihydrotestosterone (DHT) induced AR nuclear translocation and the strong modulation of a set of transcripts (RASD1, GREB1...) known to be androgen-sensitive in other androgenic cells and tissues. Moreover, we observed that DHT precociously down-regulated markers for immature follicular cells (KRT15, TNC) and for hair lineage (KRT75, FST) and up-regulated the expression of genes potentially related to sebocyte differentiation (MUC1/EMA, AQP3, FADS2). These effects were fully confirmed at the protein level. In addition, DHT-stimulated SEBO662 AR+, cultured in a low-calcium defined keratinocyte medium without serum or any complement, neosynthesize lipids, including sebum lipids, and store increased amounts of triglycerides in lipid droplets. DHT also induces morphological changes, increases cell size, and treatments over 7 days lead to a time-dependent increase in the population of apoptotic DNA-fragmented cells. Taken together, these results show for the first time that active androgens alone can engage immature sebocytes in a clear lipogenic differentiation process (Graphical abstract). These effects depend on the expression of a functional AR in these cells. This model should be of interest for revisiting the mechanisms of the sebaceous function in vitro and for the design of relevant pharmacological models for drug or compound testing.

Immortalized sebocytes can spontaneously differentiate into a sebaceous-like phenotype when cultured as a 3D epithelium.

Sebocytes originate from the same lineage as keratinocytes, and both cell types may have similarities in terms of growth and differentiation. We were interested in studying the behaviour of human sebocytes when cultured in conditions validated for epidermal reconstruction. For this purpose, we established a HPV16-E6/7-immortalized human sebocyte cell line (SEBO662) growing in keratinocyte defined media. Postconfluent SEBO662 cells in monolayers express the early sebocyte marker, cytokeratin 7 (K7), do not express Epithelia Membrane Antigen (EMA) and do not exhibit strong lipogenic activity. However, when placed at the air-liquid interface, SEBO662 multilayers spontaneously differentiate into a sebaceous-like structure as shown by the strong polarized expression of the late sebaceous marker EMA, the overexpression of some lipogenic markers and lipid production on the upper side of the epithelium. This work highlights the value of simple 3D models for exhibiting spontaneous differentiation and polarization.

In-vitro effects of polyphenols from cocoa and beta-sitosterol on the growth of human prostate cancer and normal cells.

Cocoa contains many different types of physiologically active components. It was shown that cocoa beans are rich in specific antioxidants such as flavonoids, catechins, epicatechins and proanthocyanidins. Additionally, beta-sitosterol, the most common phytosterol, may play a protective role in the development of cancer. The aim of this in-vitro study was to evaluate the inhibitory effect of different cocoa polyphenols extracts, alone or combined with beta-sitosterol, on two human prostate cancer cell lines (nonmetastatic 22Rv1 cells and metastatic DU145 cells) and a normal human prostate cell line (RWEP-1). A synergy between beta-sitosterol and cocoa polyphenols extract was also researched. Cells were treated independently with five products from 1 to 72 h: (1/) synthetic beta-sitosterol, (2/) a cocoa polyphenols extract supplemented with beta-sitosterol, (3/) three different cocoa polyphenols extracts naturally containing beta-sitosterol. In the experiment, beta-sitosterol was tested from 10(-6) to 10(-3)%; cocoa polyphenols extract supplementation was with 0.72% beta-sitosterol; finally cocoa polyphenols extracts were added to the cells at very low concentrations ranging from 0.001 to 0.2%. The growth and viability of cells were measured using colorimetric assay at 1, 3, 6, 24, 48 and 72 h of treatment. IC50 and IC100 corresponding to the concentration leading to a decrease of 50% and 100% of cell growth were determined. At the highest tested concentration, cocoa polyphenols extracts induced a complete inhibition of growth of metastatic and nonmetastatic cancer cell lines. In addition, cocoa polyphenols extracts were more active against local cancer cells than against metastatic cells. Moreover, at the highest tested concentration, cocoa polyphenols extracts are not effective on a normal prostate cell lines. Beta-sitosterol induced low growth inhibition of both cancer cell line. Cocoa polyphenols extracts, however, were significantly more active and showed a strong and fast inhibition of cell growth than beta-sitosterol alone. No synergy or addition was observed when beta-sitosterol was tested together with the cocoa polyphenols extract. Our results show that cocoa polyphenols extracts have an antiproliferative effect on prostate cancer cell growth but not on normal cells, at the highest tested concentration.

Comparison of gene expression profiles in human keratinocyte mono-layer cultures, reconstituted epidermis and normal human skin; transcriptional effects of retinoid treatments in reconstituted human epidermis.

In order to validate a model for predictive screening of dermatological drugs, we used a customized cDNA macro-array system containing 475 skin-related genes to analyze the gene expression patterns in human keratinocytes from different origins: (1) normal human epidermal keratinocyte mono-layer cultures, (2) the commercially available SkinEthic reconstituted human epidermis model, and (3) biopsies of normal human epidermis. Few markers of those that were detected significantly in keratinocyte mono-layers or in reconstituted epidermis were undetected or detected at very low level in the normal epidermis biopsies. A comparative expression of more than 100 markers could be evidenced in both normal epidermis and reconstituted epidermis samples; however, only 90% of these were detected in keratinocyte mono-layers: expression of several terminal differentiation markers, such as filaggrin, loricrin, and corneodesmosin were strongly detected in normal epidermis and reconstituted epidermis, but were not significantly expressed in keratinocyte mono-layers. Under the experimental conditions described herein, the reconstituted human epidermis model was found to significantly reproduce the gene expression profile of normal human epidermis. Using the same methodology, we then investigated the effects of all-trans retinoic acid, 9-cis retinoic acid, all-trans retinol and a commercialized tretinoin-containing cream (Retacnyl) on the gene expression profiles of reconstituted human epidermis. According to the nature and the length of the treatments, more than 40 genes were found significantly modified. Among the genes whose expression was decreased, we found cytokeratins 1, 10, 2E, and 6B, several cornified envelope precursors, integrins alpha 3, alpha 6, beta 1, beta 4, some components of desmosomes, of hemi-desmosomes and of the epidermal basement membrane. Transcriptional upregulation was observed for keratins 18 and 19, autocrine and paracrine growth factors such as HB-EGF, IGF 1, PDGF-A, calgranulins A and B, interleukin-1 alpha and the other IL-1-related markers, type II IL-1 receptor and type I IL-1-receptor antagonist. Our results confirm most of the known effects of retinoids on human epidermis, but also give new insights into their complex pharmacological activity on skin. The reconstituted human epidermis used proves to be a highly predictive model for efficacy evaluation of skin-targeted compounds, such as retinoids.