Chromosomal rearrangements during human epidermal keratinocyte differentiation

Undifferentiated human epidermal keratinocytes are self‐renewing stem cells that can be induced to undergo a program of differentiation by varying the calcium chloride concentration in the culture media. We utilize this model of cell differentiation and a 3D chromosome painting technique to document significant changes in the radial arrangement, morphology, and interchromosomal associations between the gene poor chromosome 18 and the gene rich chromosome 19 territories at discrete stages during keratinocyte differentiation. We suggest that changes observed in chromosomal territorial organization provides an architectural basis for genomic function during cell differentiation and provide further support for a chromosome territory code that contributes to gene expression at the global level. J. Cell. Physiol. J. Cell. Physiol. 221: 139–146, 2009. © 2009 Wiley‐Liss, Inc.     

TGF-beta and retinoic acid: regulators of growth and modifiers of differentiation in human epidermal cells.

In the epidermis of skin, a fine balance exists between proliferating progenitor cells and terminally differentiating cells. We examined the effects of TGF-beta s and retinoic acid (RA) on controlling this balance in normal and malignant human epidermal keratinocytes cultured under conditions where most morphological and biochemical features of epidermis in vivo are retained. Our results revealed marked and pleiotropic effects of both TGF-beta and RA on keratinocytes. In contrast to retinoids, TGF-beta s acted on mitotically active basal cells to retard cell proliferation. Although withdrawal from the cell cycle is a necessary prerequisite for commitment to terminal differentiation, TGF-beta s inhibited normal keratinization in suprabasal cells and promoted the type of differentiation commonly associated with wound-healing and epidermal hyperproliferation. The actions of TGF-beta s and RA on normal keratinization were synergistic, whereas those on abnormal differentiation associated with hyperproliferation were antagonistic. These observations underscore the notion that environmental changes can act separately on proliferating and differentiating cells within the population. Under the conditions used here, the action of TGF-beta s on human keratinocytes was dominant over RA, and TGF-beta s did not seem to be induced as a consequence of RA treatment. This finding is consistent with the fact that RA accelerated, rather than inhibited, proliferation in raft cultures. Collectively, our data suggest that the effects of both factors on epidermal growth and differentiation are multifaceted and the extent to which their action is coupled in keratinocytes may vary under different conditions and/or in different species.     

Retinoic acid improves epidermal morphogenesis

Hyper- and hypovitaminosis A both provoke epithelial pathologies in animals and humans. This suggests that a critical level of retinoic acid (RA) is required in vivo for the maintenance of normal architecture and function of these tissues. However, no beneficial, but only adverse effects of RA on epithelia have been so far observed in vitro. For instance, addition of RA to keratinocyte cultures has been shown to inhibit epidermal differentiation while this process is stimulated by serum delipidization, which reduces RA concentration in the medium. Assuming that the previous failure to demonstrate beneficial effects of RA on the epidermal phenotype in vitro was due to culture conditions too far from the in vivo conditions we decided to reevaluate the effect of RA in a culture system optimized for epidermal morphogenesis: the "emerged dermal equivalent." When human keratinocytes were grown in such a system with total fetal calf serum, the resulting epithelium was very similar to normal epidermis. But when delipidized serum was used, the epithelium was abnormal in the direction of excessive maturation (hyperkeratosis). When physiological concentrations of RA (10(-9) and 10(-8) M) were added to the delipidized serum supplement, a normal architecture (orthokeratosis) was restored. However, as classically described in the literature, higher RA concentrations (greater than 10(-7) M) reduced epidermal maturation and produced parakeratosis. Thus, although it is unquestionable that RA reduces the synthesis of epidermal-specific differentiation markers, an optimal epidermal morphogenesis seems to be achieved only in the presence of a critical RA concentration.     

Ceramide-dependent regulation of human epidermal keratinocyte CD1d expression during terminal differentiation

Human keratinocytes (KC), when cultured under conditions to remain undifferentiated or to terminally differentiate, changed their cellular distribution of CD1d. As studied by confocal microscopy, undifferentiated KC had a pool of cytoplasmic CD1d, whereas after terminal differentiation, this molecule localized in the cell membrane, which recapitulates CD1d expression in vivo. A comparison of undifferentiated and differentiated cultured KC did not reveal any differences in the association with beta(2)-microglobulin, invariant chain of class II MHC, or patterns of glycosylation, suggesting that these biochemical properties are not regulating the cellular distribution of CD1d. Time-course studies of CD1d gene expression indicated that KC slowly increased gene expression with CaCl(2)-induced terminal differentiation. Increased CD1d gene expression was dependent on ceramide synthesis, because fumonisin B1, a ceramide synthetase inhibitor, blocked the increase in CD1d gene expression during terminal differentiation. Similarly, exogenous ceramide or the ceramidase inhibitor, B13, induced CD1d gene expression by undifferentiated, but not terminally differentiated, KC. A protein kinase C-zeta (PKC-zeta) inhibitor (a pseudosubstrate oligopeptide), but not a PKC-alphabeta inhibitor, significantly decreased CD1d gene expression by undifferentiated or ceramide-stimulated cultured, undifferentiated KC. As expected, downstream signaling events of PKC-zeta (JNK phosphorylation and NF-kappaBeta accumulation in the nucleus) were also attenuated. The calcineurin phosphatase inhibitor cyclosporine A, which blocks KC terminal differentiation, also blocked CD1d gene expression by cultured KC. In conclusion, this novel function of cellular ceramides extends the importance of this class of biologically active lipids beyond that of terminal differentiation and barrier function in normal human skin.     

Retinoic acid alters epithelial differentiation during palatogenesis.

Retinoids are teratogenic in humans and animals, producing a syndrome of craniofacial malformations that includes cleft palate. This study investigates the mechanism through which retinoic acid induces cleft palate. Murine palatogenesis after exposure to retinoic acid in utero is compared to normal development and to alterations observed after exposure in organ culture to retinoic acid or epidermal growth factor (EGF). Human embryonic palatal shelves were placed in the organ culture system and the responses to retinoic acid and EGF were compared to those of the murine palatal shelves. Growth factors play a role in normal development and are found in the embryonic palate. In other cell culture systems, retinoids alter the expression of EGF receptors. Our results suggest that in the medial epithelial cells of the palate, retinoic acid sustains the expression of the EGF receptor and the binding of EGF at a time when the expression in control medial cells has declined, and these control cells subsequently undergo programmed cell death. The continued DNA synthesis, proliferation, survival, and shift in phenotype of the medial cells is believed to interfere with the adhesion and fusion of opposing palatal shelves, resulting in cleft palate.     

Retinoic acid upregulates interleukin-2 receptors on activated human thymocytes

It has previously been demonstrated that retinoic acid (RA) enhances the blastogenic responses of human thymocytes. We have now delineated the cellular mechanism of this activity. When RA was added to resting thymocyte cultures in the presence of recombinant interleukin-2 (rIL-2), blastogenesis was increased two- to fourfold. By assessing the proportion of cells that became Tac-positive and showed DNA synthesis early in the activation process, we determined that the augmentation by RA was not caused by an increased recruitment of resting cells that are activated to undergo blast transformation. Instead, RA markedly potentiated the growth rate of long-term rIL-2-dependent thymocyte blasts and, correspondingly, increased the Tac expression on these proliferating cells. Thus, RA enhancement of thymocyte responses appears to be mediated by an increase in IL-2-receptor expression on thymocyte blasts, resulting in augmented IL-2-dependent growth. This effect is independent of the original activating stimulus since enhancement of thymocyte responses to phytohemagglutinin (PHA) was also shown to be caused solely by increased proliferation of IL-2-dependent blast growth. In contrast to these effects on thymocytes, peripheral blood lymphocyte (PBL) proliferative responses were unaffected by RA treatment and, correspondingly, RA affected neither IL-2 receptor expression on PBL blasts nor the growth of these cells. Taken together, the results of this study suggest that RA can modulate IL-2-dependent immune responses, in part, by upregulating the expression of IL-2 receptors on proliferating T lymphoblasts generated from cells at restricted stages of development.     

Retinoic acid potentiates TNF-alpha-induced ICAM-1 expression in normal human epidermal keratinocytes

ICAM-1 protein in keratinocytes is thought to contribute to cutaneous inflammatory reactions. Its induction depends-among others-on cytokines such as TNF-alpha, IFN-gamma, IL-1 or on retinoic acid (RA), a key regulator of epidermal homeostasis. We investigated the effect of treatments with TNF-alpha, RA or their combination on ICAM-1 expression on proliferative or differentiating keratinocytes over an 8 day culture period. Basal ICAM-1 levels were undetectable at low (30 microM) and standard (88 microM) Ca2+ and RA alone did not induce ICAM-1. However, at high Ca2+ (1500 microM), ICAM-1 levels were augmented in response to RA-treatment. TNF-alpha induced a transient ICAM-1 increase in NHK, which reached peak-levels 2-4 days post cytokine stimulus. RA potentiated the TNF-alpha-induced ICAM-1 response in all Ca2+-concentrations. This potentiating effect of RA was confirmed at the mRNA level. In summary, our results establish retinoic acid as an enhancer of TNF-alpha-induced ICAM-1 levels in NHK.     

Characterization of microfluidic human epidermal keratinocyte culture

Human epidermal keratinocytes (HEK) are skin cells of primary importance in maintaining the body’s defensive barrier and are used in vitro to assess the irritation potential and toxicity of chemical compounds. Microfluidic systems hold promise for high throughput irritant and toxicity assays, but HEK growth kinetics have yet to be characterized within microscale culture chambers. This research demonstrates HEK patterning on microscale patches of Type I collagen within microfluidic channels and maintenance of these cells under constant medium perfusion for 72 h. HEK were shown to maintain 93.0%–99.6% viability at 72 h under medium perfusion ranging from 0.025–0.4 μl min⁻¹. HEK maintained this viability while ∼100% confluent—a level not possible in 96 well plates. Microscale HEK cultures offer the ability to precisely examine the morphology, behavior and viability of individual cells which may open the door to new discoveries in toxicological screening methods and wound healing techniques.     

Retinoic acid negatively regulates p34cdc2 expression during human neuroblastoma differentiation.

p34cdc2 is a protein kinase that has an important role in controlling cell cycle progression and may regulate tumor suppressor gene activity. In this work, we show that the arrest of cell growth and induction of differentiation in a tumorigenic neuroblastoma cell line by retinoic acid (RA) is associated with a 75-fold decrease in the level of p34cdc2 protein. The RA induced decrease in p34cdc2 levels does not simply reflect the arrest of cell growth, because p34cdc2 levels are not reduced when neuroblastoma cells are growth arrested by nutrient deprivation. Furthermore, dephosphorylation of the tumor suppressor gene product RB, a substrate for the p34cdc2 kinase activity, is observed only when p34cdc2 levels are decreased in RA treated cells. These studies link regulation of cdc2 level, RB phosphorylation state, and induction of differentiation by RA and suggest that alterations in the cdc2 gene or in genes controlling its regulation contribute to tumorigenesis.     

Vitamin A receptors. Retinoic acid binding in ocular tissues.

Analysis of the sucrose-density-gradient patterns of the 110 000g supernatant fractions of adult and foetal retina and pigment epithelium showed them to contain a limited number of highly specific binding sites ('receptors') for [3H]retinoic acid that sediment at approx. 2S. Binding in pigment epithelium is higher than in any tissue yet reported. A 5S binding component is also observed and is probably due to serum contamination. Fractionation studies indicate that [3H]retinoic acid binding in the retina is lower in the photoreceptor units than in the retinal inner layers. This is in contrast with previous results that show greater [3H]retinol binding in photoreceptors. Studies with dystrophic human and rat retinas, which lack the photoreceptor layers, confirm that [3H]retinoic acid binding is greater in the non-photoreceptor layers of the retina. No specific [3H]retinoic acid binding is found in corneal epithelium, although endothelium and the conjunctiva demonstrate specific 2S binding. Such differences in retinol and retinoic acid binding may indicate different roles for the two compounds in ocular tissues.     

Purification and partial amino acid sequence of proteins from human epidermal keratinocyte conditioned medium

Keratinocytes are the main cell type of the epidermis. They secrete a variety of proteins and peptides that have diverse roles in epidermal physiology. In this report, we present purification and partial amino acid sequence of LEKTI, a serine proteinase inhibitor, and DAN (NO₃) zinc-finger protein, a tumor suppressor protein of neuroblastoma, from human keratinocyte conditioned medium. Epidermal keratinocytes were isolated from human foreskin and serially passaged in a defined medium (MSBM). At confluence of the fourth passage, MSBM medium was replaced with protein-free Dulbecco's modified Eagle medium/F12 (DMEM:F12) 3:1 base medium and collected every 24 h for 4 days. Medium was pooled and concentrated using a stirred cell concentrator. Concentrated medium was diluted 1:1 in 50 mM sodium phosphate, pH 8 buffer, and loaded onto a preparative heparin affinity column. Proteins/peptides were purified from heparin column passthrough by the combination of preparative and analytical FPLC-based gel filtration chromatography and reversed-phase HPLC. Samples electroblotted onto a PVDF support were sequenced by Edman degradation in a gas-phase sequencing system.     

Retinoic acid repatterns axolotl lateral line receptors

The effects of all-trans retinoic acid on the development of the lateral line placodes of axolotls was studied. Late gastrula and early neurula were exposed to 10(-7) to 10(-5) M retinoic acid for one hour and then reared until they would normally be feeding larvae. As in other vertebrates, the extent of the developmental abnormalities is concentration dependent. Those embryos exposed to the highest concentration of retinoic acid failed to form much of the forebrain and midbrain, including the olfactory, optic and otic organs, which were reduced or absent. Although all lateral line placodes continued to generate fully formed receptors and cranial nerves, the production of neuromasts and the organization of these receptors into lines were markedly reduced. Equally important, all of the placodes at the highest concentration of retinoic acid failed to generate ampullary organs, thereby indicating a strong posteriorizing effect of retinoic acid on these placodes.     

Retinoids inhibit human epidermal keratinocyte RNase P activity

Ribonuclease P (RNase P) is a ubiquitous and essential enzyme that endonucleolytically cleaves all tRNA precursors to produce the mature 5'-end. We have investigated the effect of synthetic rertinoids (all-trans retinoic acid, acitretin) and arotinoids (Ro 13-7410, Ro 15-0778, Ro, 13-6298 and Ro 15-1570) on RNase P activity isolated for the first time from normal human epidermal keratinocytes (NHEK). All tested compounds but one (Ro 15-1570) revealed a dose-dependent inhibition of RNase P activity, indicating that they may have a direct effect on tRNA biogenesis. Detailed kinetic analysis showed that all retinoids behave as classic competitive inhibitors. On the basis of the Ki values Ro 13-7410 was found to be the strongest inhibitor among all compounds tested.     

Retinoic acid and retinoic acid receptors in craniofacial development

Interest in retinoids and craniofacial development originated independently from nutritional and teratological studies; however, the site of action of retinoids in normal development remains contentious. Recent transgenic strategies have shown that retinoic acid and nuclear retinoid receptors are required for the morphogenetic specification of cranial neural crest cells and their mesenchymal derivatives during craniofacial development. Interestingly, while some aspects of the RA teratogenicity have been shown to be receptor-mediated, there is as yet no clear evidence that this is the case for the embryonic head and face. Hox genes are one important set of targets for RA in the developing neural primordium and cranial neural crest, but it remains unclear as to how retinoid-mediated regulation of such targets is realized as the morphogenetic specification of cell fate.     

Augmentation of keratinocyte differentiation by the epidermal mitogen, 8-bromo-cAMP

The effect of the epidermal mitogen, 8-bromo-cAMP, on keratinocyte differentiation was studied. A 3 X 10(-4) M dose of 8-bromo-cAMP was added to primary neonatal mouse epidermal keratinocyte cultures that slowly proliferate, stratify and differentiate over 2-3 weeks time. [3H]Thymidine autoradiography coupled with an NH4Cl plus reducing agent technic which separates basal and differentiating keratinocytes was used to determine the target cell for the 8-bromo-cAMP mitogenic effect. A histologic stain and a four buffer protein extraction protocol, in conjunction with PAGE and fluorographic technics, were used to assess the differentiation of the cultures. The data indicated that 8-bromo-cAMP primarily stimulated the proliferation of the basal cell monolayer. Simultaneous with the mitogenic effect was an increase in the production of keratohyalin granule, keratin and cell envelope proteins, which are specific markers of epidermal differentiation. The results indicate that keratinocytes stimulated by the epidermal mitogen 8-bromo-cAMP simultaneously express differentiation-related processes.