Tyrosine 769 of the keratinocyte growth factor receptor is required for receptor signaling but not endocytosis

Keratinocyte growth factor receptor (KGFR) is a receptor tyrosine kinase expressed on epithelial cells which belongs to the family of fibroblast growth factor receptors (FGFRs). Following ligand binding, KGFR is rapidly autophosphorylated on specific tyrosine residues in the intracellular domain, recruits substrate proteins, and is rapidly internalized by clathrin-mediated endocytosis. The role of different autophosphorylation sites in FGFRs, and in particular the role of the tyrosine 766 in FGFR1, first identified as PLCgamma binding site, has been extensively studied. We analyzed here the possible role of the tyrosine 769 in KGFR, corresponding to tyrosine 766 in FGFR1, in the regulation of KGFR signal transduction and MAPK activation as well as in the control of the endocytic process of KGFR. A mutant KGFR in which tyrosine 769 was substituted by phenylalanine was generated and transfected in NIH3T3 and HeLa cells. Our results indicate that tyrosine 769 is required for the binding to KGFR and tyrosine phosphorylation of PLCgamma as well as for the full activation of MAPKs and for cell proliferation through the regulation of FRS2 tyrosine phosphorylation, suggesting that this residue represents a key regulator of KGFR signal transduction. Our data also show that tyrosine 769 is not involved in the regulation of the endocytic process of KGFR.     

Cellular and molecular facets of keratinocyte reepithelization during wound healing

Cutaneous wound healing is a highly coordinated physiological process that rapidly and efficiently restores skin integrity. Reepithelization is a crucial step during wound healing, which involves migration and proliferation of keratinocytes to cover the denuded dermal surface. Recent advances in wound biology clarified the molecular pathways governing keratinocyte reepithelization at wound sites. These new findings point towards novel therapeutic targets and provide suitable methods to promote faster tissue regeneration in vivo.     

dsRNA-mediated innate immunity of epidermal keratinocytes

MIP-1alpha, a CC chemokine, recruits monocytes, natural killer cells, lymphocytes, and neutrophils, and plays a critical role in viral infection. Since, the lesional epidermis of herpes zoster expressed MIP-1alpha, we hypothesized that keratinocytes produce MIP-1alpha in response to virus-associated dsRNA via TLR3. To investigate this, we examined cultured human keratinocytes for MIP-1alpha production induced by poly(I:C), a TLR3 ligand. Poly(I:C) treatment induced MIP-1alpha production, interestingly, poly(I:C)-induced IFN-alpha and -beta production preceded MIP-1alpha production. A neutralizing antibody for IFN-beta significantly inhibited the poly(I:C)-induced MIP-1alpha production indicating that MIP-1alpha production is via IFN-beta. IFN-alpha priming enhanced TLR3 expression and MIP-1alpha production in poly(I:C)-treated keratinocytes. This suggests that IFN-alpha enhanced the TLR3 expression and reinforced the response of keratinocytes to poly(I:C), which resulted in an increase in MIP-1alpha production. In conclusion, normal human keratinocytes produce MIP-1alpha in response to dsRNA via TLR3, and this production is regulated by IFN-alpha/beta.     

Identification of extra- and intracellular alanyl aminopeptidases as new targets to modulate keratinocyte growth and differentiation

Aminopeptidase inhibitors strongly affect proliferation, differentiation, and function of immune cells and show therapeutic potential in inflammatory disorders. In psoriatic lesions, keratinocytes display increased cellular turnover and disturbed differentiation, leading to epidermal hyperplasia accompanied by the loss of stratum granulosum. Here, we report in the HaCaT hyperproliferative keratinocyte cell line as well as in two primary keratinocyte strains in vitro a molecular and biochemical analysis of the expression of both membrane and cytosol alanyl aminopeptidase (cAAP) on the mRNA, protein, and enzymatic activity level. We found a clear dose-dependent suppression of DNA synthesis in vitro in the presence of the inhibitors actinonin, bestatin, and the cAAP-specific inhibitor PAC-22 correlating well with the simultaneous decrease in enzyme activity. In vivo, actinonin dose-dependently restored the stratum granulosum and ameliorated the impaired keratinocyte differentiation in the mouse tail model of psoriasis. Taken together, these data suggest that targeting alanyl aminopeptidases may be beneficial for psoriasis and other inflammatory skin disorders.     

Formation of silk fibroin matrices with different texture and its cellular response to normal human keratinocytes

Three forms of silk fibroin (SF) matrices, woven (microfiber), non-woven (nanofiber), and film form, were used to perform a conformational analysis and cell culture using normal human oral keratinocytes (NHOK). To obtain the SF microfiber (SF-M) matrix, natural grey silk was degummed, while the SF film (SF-F) and nanofiber (SF-N) matrices were prepared by casting and electrospinning the formic acid solutions of the regenerated SF, respectively. For insolubilization, as-prepared SF-F and SF-N matrices were chemically treated with an aqueous methanol solution of 50%. The conformational structures of as-prepared and chemically treated SF matrices were investigated using attenuated total reflectance infrared spectroscopy (ATR-IR) and solid-state ¹³C CP/MAS nuclear magnetic resonance (NMR) spectroscopy. The as-cast SF-F matrix formed a mainly β-sheet structure that was similar to the SF-M matrix, whereas the as-spun SF-N matrix had a random coil conformation as the predominant secondary structure. Conformational transitions from random coil to β-sheet of the as-spun SF-N occurred rapidly within 10 min following aqueous methanol treatment, and were confirmed by solid-state ¹³C NMR analysis. To assess the cytocompatibility and cells behavior on the different textures of SF, we examined the cell attachment and spreading of NHOK that was seeded onto the SF matrices, as well as the interaction between the cells and SF matrices. Our results indicate that the SF nanofiber matrix may be more preferable than SF film and SF microfiber matrices for biomedical applications, such as wound dressings and scaffolds for tissue engineering.     

Migration and differentiation of Langerhans cell precursors

Epidermal Langerhans cells (LC) are the first sentinels of the skin immune system. To study immigration of human LC precursor cells into the skin, we established a two-compartmental skin model consisting of a dermal matrix and an epidermal sheet of keratinocytes. We tested the individual components of the skin model for their influence on phenotype and function of LC precursors. A time window at day 5/6 of differentiation was determined, during which in vitro generated LC precursors expressed adhesion molecules and chemokine receptors required for transmigration across endothelial cell layers and the dermis towards the epidermis. They expressed L-selectin, integrins, platelet endothelial cell adhesion molecule-1, E-cadherin and CC-chemokine receptor 6 and were thus fitted out for transendothelial migration and immigration into the dermis. In a transwell system, these LC precursors migrated towards the chemokine MIP3alpha, demonstrating functional integrity of chemokine receptor 6. For the in vitro reconstituted skin, keratinocytes were grown on a de-epidermized dermis for one to three weeks and formed an epidermal sheet. We allowed LC precursor cells to migrate into this two-compartmental model from the dermal side and examined the presence of CD1alpha--positive cells. LC precursors migrated through the dermal matrix towards the layer of keratinocytes representing the epidermis and could be identified by immunohistology. Experiments designed to investigate the influence of signals provided by both the skin components and by the LC precursors on LC immigration into the skin are in progress.     

Plasminogen activator inhibitor 2: expression and role in differentiation of epidermal keratinocyte

Plasminogen activator inhibitor 2 (PAI-2) is an enzyme inhibitor which is involved in cell differentiation, tissue growth and regeneration. In this study, immunocytochemistry, in situ hybridization and confocal laser scanning microscopy were used to investigate the expression and role of PAI-2 in differentiation of keratinocytes in vitro. The result showed that in the mono-layer differentiated keratinocytes induced by high calcium concentration, the expression of PAI-2 and its mRNA increased significantly, accompanied by expression increase of the differentiation marker keratin 10; and in the multi-layer differentiated keratinocytes induced by high calcium, PAI-2 expressed strongly mainly in the keratinocytes of middle as well as upper stratified layers, while K10 expressed in the keratinocytes of all stratified layers. Furthermore, the changes of the parameters related to keratinocyte differentiation were detected after inhibition of PAI-2 functions by its antibody, and the data showed that when treated by PAI-2 antibody, involucrin in the keratinocytes envelope expressed increasingly with an altering distribution from part to the whole envelope area. Our results indicate that during differentiation of epidermal keratinocyte, PAI-2 expresses mainly in the more differentiated keratinocytes and may protect the terminal differentiated keratinocytes from prematuration through inhibiting involucrin expression in cornified envelope.     

Involvement of keratinocyte growth factor (KGF)-KGF receptor signaling in developmental estrogenization syndrome of mouse vagina

Exposure of mice to estrogen or keratinocyte growth factor (KGF) in vivo during the neonatal period results in estrogen-independent persistent proliferation and cornification of the vaginal epithelium when the animals become adults. Here, whether and how KGF-signaling is involved in the effects of estrogen on the neonatal mouse vagina were studied with an in vitro method. Newborn mouse vaginae were cultured for 3 days in serum-free medium containing various combinations of estradiol-17 (E₂), KGF, anti-KGF antibody, KGFR inhibitory peptide and heparin, and then transplanted into ovariectomized host mice for 35 days. The vaginae cultured with 5 g/ml E₂ or 5 g/ml KGF had a cornified thick epithelium, while the epithelium of the vehicle-treated controls stayed thin. The E₂ effect was blocked by concurrent treatment with anti-KGF antibody or KGFR inhibitory peptide. KGF treatment alone at doses less than 500 ng/ml did not induce permanent vaginal changes but such changes did occur in vaginae treated with heparin plus as little as 10 ng/ml KGF. On the other hand, heparin inhibited the permanent vaginal changes induced by estrogen. These results suggest that irreversible vaginal changes are induced by the direct action of KGF on the developing vagina and that the developmental estrogenization syndrome of mouse vagina is caused by intensification of endogenous KGF/KGFR signaling by exogenous estrogen.This work was supported by Grants-in-Aid for Scientific Research on Priority Areas (A) and for Encouragement of Young Scientists from the Ministry of Education Science, Sports and Culture, Japan to M.M.     

Unique behavior of dermal cells from regenerative mammal,the African Spiny Mouse,in response to substrate stiffness

The African Spiny Mouse (Acomys spp.) is a unique outbred mammal capable of full, scar-free skin regeneration. In vivo, we have observed rapid reepithelialization and deposition of normal dermis in Acomys after wounding. Acomys skin also has a lower modulus and lower elastic energy storage than normal lab mice, Mus musculus. To see if the different in vivo mechanical microenvironments retained an effect on dermal cells and contributed to regenerative behavior, we examined isolated keratinocytes in response to physical wounding and fibroblasts in response to varying substrate stiffness. Classic mechanobiology paradigms suggest stiffer substrates will promote myofibroblast activation, but we do not see this in Acomys dermal fibroblasts (DFs). Though Mus DFs increase organization of α-smooth muscle actin (αSMA)-positive stress fibers as substrate stiffness increases, Acomys DFs assemble very few αSMA-positive stress fibers upon changes in substrate stiffness. Acomys DFs generate lower traction forces than Mus DFs on pliable surfaces, and Acomys DFs produce and modify matrix proteins differently than Mus in 2D and 3D culture systems. In contrast to Acomys DFs “relaxed” behavior, we found that freshly isolated Acomys keratinocytes retain the ability to close wounds faster than Mus in an in vitro scratch assay. Taken together, these preliminary observations suggest that Acomys dermal cells retain unique biophysical properties in vitro that may reflect their altered in vivo mechanical microenvironment and may promote scar-free wound healing.     

S100A7: A rAMPing up AMP molecule in psoriasis

S100A7 (psoriasin), an EF-hand type calcium binding protein localized in epithelial cells, regulates cell proliferation and differentiation. An S100A7 overexpression may occur in response to inflammatory stimuli, such in psoriasis, a chronic inflammatory autoimmune-mediated skin disease. Increasing evidence suggests that S100A7 plays critical roles in amplifying the inflammatory process in psoriatic skin, perpetuating the disease phenotype. This review will discuss the interactions between S100A7 and cytokines in psoriatic skin. Furthermore, we will focus our discussion on regulation and functions of S100A7 in psoriasis. Finally, we will discuss the possible use of S100A7 as therapeutic target in psoriasis.