Novel redistribution of myosin-containing filaments in cultured keratinocytes identified by a human monoclonal autoantibody

Summary A time-dependent redistribution of microfilaments was observed in cultured human keratinocytes using a human monoclonal autoantibody specific for myosin. Immunofluorescent staining revealed that 5 days after plating keratinocytes in either 0.1 mM or 2.0 mM Ca⁺⁺, myosin was distributed uniformly throughout the cytoplasm. At day 6, parallel arrays of myosin-containing microfilaments were prominent in the cell peripheries. At day 7 the microfilaments formed circumferential rings. The distribution of the microfilaments was disrupted by cytochalasin but not by colchicine, indicating that this novel distribution of myosin was not dependent on colchicine-sensitive vimentin intermediate filaments. The time-dependent redistribution of myosin was not influenced by cell population density, cell shape or cell cycle phase, except for mitotic cells in which myosin was distributed diffusely through the cytoplasm. If, as suggested by Kolega (9), microfilaments align parallel to the direction of applied tension, the redistribution of myosin-containing microfilaments in cultured keratinocytes may reflect the increased tension between cells resulting from increasing strength of cell-cell junctions over time. In sectioned human skin, myosin was localized in the peripheral cytoplasm of stratified epidermal cells. Tensions arising from the numerous desmosomal junctions between cellsin vivo could account for this distribution of myosin. Supported by grant NS-23537 (V. A. L.) from the National Institutes of Health, Bethesda, MD, and by the Mayo Foundation. C. L. W. is recipient of the Kermit E. Osserman and Blanche McClure Fellowship, 1987, National Myasthenia Gravis Foundation.     

In vitro toxicity of various classes of test agents using the neutral red assay on a human three-dimensional physiologic skin model

Summary A new three-dimensional human skin model consisting of several layers of actively dividing and metabolically active human neonatal foreskin-derived fibroblasts and epidermal keratinocytes grown on nylon mesh has been used to assess the in vitro toxicity of test agents from various classes. Utilizing a slight modification of the published neutral red viability assay for endpoint determination, we have assayed and obtained dose-dependent toxicity curves for test agents from the following classes: detergents (n=15), alcohols (n=5), metal chlorides (n=10), perfumes and colognes (n=5), shampoos (n=4), conditioners (n=3), moisturizers (n=3), pesticides (n=3), and antimicrobial preservatives (n=4). Limited comparisons to in vivo ocular irritancy data with alcohols and detergents are encouraging. We have demonstrated the utility of this metabolically active dermal substrate containing naturally secreted collagen and other extracellular matrix proteins along with the neutral red viability assay for assessing the toxicity of a number of test agents from a variety of different classes with broad industrial applications.     

Effects of fibroblasts of different origin on long term maintenance of xenotransplanted human epidermal kerationocytes in immunodeficient mice

We examined effects of fibroblasts of different origin on long-term maintenance of xenotransplanted human epidermal keratinocytes. A suspension of cultured epidermal cells, originating from adult human trunk skin, was injected into double mutant immunodeficient (BALB/c nu/scid) mice subcutaneously, with or without cultured fibroblastic cells of different origin. At one week after transplantation, the epidermal cells generated epidermoid cysts consisting of human epidermis-like tissue. When the epidermal cells were injected alone or together with fibroblastic cells derived from human bone marrow, muscle fascia, or murine dermis, organized epidermoid cysts regressed within 6 weeks. In contrast, when the epidermal cells were injected together with human dermal fibroblasts, generated epidermoid cysts were maintained in vivo for more than 24 weeks. Histological examination showed that the reorganized epidermis, after injection of both epidermal keratinocytes and dermal fibroblasts, retained normal structures of the original epidermis during 6 to 24 weeks after transplantation. The results indicate that human dermal fibroblasts facilitate the long-term maintenance of the reorganized epidermis after xenotransplantation of cultured human epidermal keratinocytes by supporting self renewal of the human epidermal tissue in vivo.     

The effect of isolation and culture methods on epithelial stem cell populations and their progeny—toward an improved cell expansion protocol for clinical application

Background aimsThe use of cultured epithelial keratinocytes in the treatment of burns and skin graft donor sites is well established in clinical practice. The most widely used culture method for clinical use was originally developed by Rheinwald and Green 40 years ago. This system uses irradiated mouse dermal fibroblasts as a feeder cell layer to promote keratinocyte growth, a process that is costly and labor-intensive for health care providers. The medium formulation contains several components of animal origin, which pose further safety risks for patients. Improvements and simplification in the culturing process would lead to clear advantages: improved safety through reduction of xenobiotic components and reduction in cost for health care providers by dispensing with feeder cells.MethodsWe compared the Rheinwald and Green method to culture in three commercially available, feeder-free media systems with defined/absent components of animal origin.ResultsDuring the isolation process, short incubation times in high-strength trypsin resulted in increased numbers of liberated keratinocyte stem cells compared with longer incubation times. All three commercially available media tested in this study could support the expansion of keratinocytes, with phenotypes comparable to cells expanded using the established Rheinwald and Green method. Growth rates varied, with two of the media displaying comparable growth rates, whereas the third was significantly slower.Discussion.Our study demonstrates the suitability of such feeder-free media systems in clinical use. It further outlines a range of techniques to evaluate keratinocyte phenotype when assessing the suitability of cells for clinical application.     

microRNA-106b derived from endothelial cell–secreted extracellular vesicles prevents skin wound healing by inhibiting JMJD3 and RIPK3

Intriguingly, microRNAs (miRs) transferred as cargo in extracellular vesicles (EVs) can modulate wound healing through their regulation of fibroblast functions. In this study, we investigated the effects of miR-106b transfer via EVs derived from human umbilical vein endothelial cells (HUVECs) on skin wound healing. Dual-luciferase reporter gene assay identified that miR-106b could target and inhibit JMJD3. RT-qPCR analysis showed EVs isolated from HUVECs had enriched expression of miR-106b. LL29 fibroblast cells and HaCaT keratinocytes were co-cultured with HUVEC-derived EVs, in which miR-106b had been up-regulated or down-regulated by its mimic or inhibitor. The co-culture with HUVEC-derived EVs increased miR-106b expression, and reduced the viability and adhesion of LL29 and HaCaT cells, whereas the inhibition of miR-106b in HUVEC-derived EVs enhanced the viability and adhesion of LL29 and HaCaT cells through up-regulation of JMJD3. Next, we showed that JMJD3 overexpression enhanced LL29 and HaCaT cell viability and adhesion through elevating RIPK3, which induced the phosphorylation of AKT during the wound-healing process. We next developed a mouse skin wound model to investigate the actions of miR-106b in vivo after 14 days. The delivery of miR-106b via HUVEC-derived EVs delayed wound healing through suppression of collagen I content and angiogenesis, but had no effects on pro-inflammatory cytokines. In conclusion, miR-106b from HUVEC-derived EVs inhibits JMJD3 and RIPK3, leading to the inhibition of skin wound healing, thus constituting a new therapeutic target.     

Clonal growth of human keratinocytes with small amounts of dialyzed serum

Summary A survey of commercially availabla media revealed that medium F-12 was superior to medium 199 for clonal growth of human epidermal keratinocytes (HK) when supplemented with 10 μg/ml hydrocortisone (HC) plus dialyzed fetal bovine serum protein (FBSP), rather than the whole serum used in previous studies. Qualitative and quantitative adjustment of the medium composition for optimal clonal growth with minimal amounts of FBSP generated a new medium, MCDB 151, which supports clonal growth of HK with 10 μg/ml HC and as little as 1 mg/ml FBSP (equivalent in protein concentration to 2.0% whole serum). MCDB 151 differs significantly from MCDB 105, previously developed in this laboratory for normal human fibroblasts, and each medium selectively favors growth of its own type of cell in primary cultures of disaggregated human neonatal foreskin cells. Differences in the amounts of calcium and adenine in the two media appear to be among the most influential factors mediating the selective growth. Optimal growth of HK occurs at a very low level of Ca²⁺ that causes the colonies to remain as monolayers rather than stratifying as they do in the presence of higher levels of calcium. However, keratin synthesis, which was examined through use of highly specific fluorescent antibodies, is not affected by the Ca²⁺ concentration. Agents that increase intracellular cyclic AMP levels appear to have no effect on HK growth in MCDB 151 with 10 μg/ml HC and 1.0 mg/ml FBSP. This paper contains material from a thesis submitted to the Graduate School of the University of Colorado, Boulder, by Donna M. Peehl in partial fulfillment of the requirements for the Ph.D. degree. This work was supported by Grant CA 15305 from the National Cancer Institute and Grant AG 00310 from the National Institute on Aging.     

Molecular and Functional Characterization of the Four-Transmembrane Molecule L6 in Epidermal Keratinocytes

In normal human epidermal keratinocytes (NHEK) proteolytic detachment from the substrate induces a complex activation cascade including expression of new proteins, morphological alterations, and the onset of migration for epidermal regeneration. By subtractive cloning we have shown that L6, a four-transmembrane protein, is newly expressed after proteolytic keratinocyte detachment. In this study, we have generated a novel anti-L6 antibody (clone HD-pKe#104-1.1) and investigated L6 expression regulation in vitro and in vivo as well as L6 function in keratinocyte migration. Dispase-mediated detachment induced L6 expression in NHEK at the mRNA and protein level. Immunohistology of skin biopsies displayed a strong expression of L6 in follicular epidermis and epidermolytic lesions of autoimmune bullous dermatoses (bullous pemphigoid, pemphigus vulgaris), but not in normal interfollicular epidermis. In contrast to normal keratinocytes, HaCaT cells showed constitutive L6 expression, indicating a constitutively active phenotype. After artificial wounding of confluent HaCaT cultures, anti-L6 antibody strongly impaired cell migration velocity and migratory reepithelization of the defect, indicating L6 involvement in keratinocyte migration. These findings suggest that L6 is an important activation-dependent regulator of keratinocyte function and epidermal tissue regeneration.     

Generation of oxidant response to copper and iron nanoparticles and salts: Stimulation by ascorbate

The present work describes a two-stage approach to analyzing combustion-generated samples for their potential to produce oxidant stress. This approach is illustrated with the two commonly encountered transition metals, copper and iron. First, their abilities to generate hydroxyl radical were measured in a cell-free, phosphate-buffered saline solution containing ascorbate and/or citrate. Second, their abilities to induce heme oxygenase-1 in cultured human epidermal keratinocytes were assessed in cell culture. Combustion-generated copper oxide nanoparticles were active in both assays and were found to be soluble in culture medium. Depletion of glutathione in the cells or loading the cells with ascorbate greatly increased heme oxygenase-1 induction in the presence of copper. By contrast, iron oxide nanoparticles were active in the phosphate-buffered saline but not in cell culture, and they aggregated in culture medium. Soluble salts of copper and iron exhibited the same contrast in activities as the respective combustion-generated particles. The results suggest that the capability of combustion-generated environmental samples to produce oxidant stress can be screened effectively in a two step process, first in phosphate-buffered saline with ascorbate and subsequently in epithelial cell culture for those exhibiting activity initially. The results also point to an unanticipated interaction in cells of oxidant stress-generating metals with an antioxidant (ascorbate) that is usually missing in culture medium formulations. Thus, ascorbate supplementation of cultured human cells is likely to improve their ability to model the in vivo effects of particulate matter containing copper and other redox-active metals.