Influence of dermal equivalent maturation on the development of a cultured skin equivalent.

Histologic and immunofluorescence methods were used to analyse the presence of fibronectin, chondroitin-4-sulphate and chondroitin-6-sulphate, type III and IV collagens, laminin, and keratins to assess the maturation level of cultured dermal and skin equivalents. In a first phase, fibroblasts in monolayer culture were compared with dermal equivalents in which fibroblasts are embedded in a type I collagen gel. Different fluorescent patterns were observed depending on the culture system used. A sequential appearance of macromolecules was noticed in dermal equivalents. Fibronectin was first detected after 4 days of culture, whereas chondroitin-4-sulphate and chondroitin-6-sulphate and type III collagen were present after 7 days. In contrast, all three macromolecules were detected at 24 h of culture in fibroblastic monolayer cultures. In a second phase, the quality of our skin equivalents was evaluated according to the seeding time of epidermal cells upon dermal equivalents (1, 4, or 7 days). A satisfactory stratification was obtained when keratinocytes were seeded after 4 and 7 days of dermal equivalent culture. Laminin and fibronectin were detected at the dermo-epidermal junction, but type IV collagen was absent. Various keratins, as detected by the AE1, AE2, and AE3 antibodies, were present in the epidermal layer. Following keratinocyte confluence, a change in the organization pattern of type III collagen in the dermal fraction of the skin equivalent was also noticed. Our comparative results show that seeding of epidermal cells on a more mature dermal equivalent leads to improved differentiation status of the epidermal layer.     

Effects of fibroblasts and microenvironment on epidermal regeneration and tissue function in long-term skin equivalents

In vitro generated skin models find growing interest as promising tools in basic research and clinical application in regenerative medicine. Here, we present further details of an improved long-term skin equivalent (SE) enabling mechanistic studies on skin reconstruction and epidermal function. Growth conditions of fibroblasts in a 3D scaffold were analysed to optimise the dermal microenvironment by providing an authentic dermal matrix for regular tissue reconstruction and function of cocultured keratinocytes. These SEs demonstrate sustained epidermal viability - over 12 weeks - with regular differentiation as substantiated by in vivo-like patterns of all differentiation products, exemplified here by the cornified envelope components loricrin and repetin. The continuous expression of all major tight junction components in the granular layer, shown here for ZO-1 in coherence with the presence of epidermal barrier lipids, and ultrastructural accumulation of lamellar bodies, collectively indicate proper epidermal barrier structures. Remarkably, cocultured keratinocytes exerted an ongoing proliferation-stimulating effect on fibroblasts colonising the scaffold comparable to a cocktail of fibroblast growth factors. Consequently, precultivation of dermal equivalents (DEs) in basal or growth factor-enriched media had only minor effects on the quality of epidermal regeneration in cocultures. As to the role of fibroblast numbers, complete absence of dermal cells resulted in atrophic epithelia but the effect of cell numbers as low as 5 x 10(4)cells/cm(2) on epidermal tissue quality equalled that of the standard density (2 x 10(5)cells/cm(2)). Surprisingly, precultivation of fibroblasts in the DEs for 7 days (standard) showed no better effect on epidermal tissue reformation as compared to 2 days whereas a precultivation period of 14 days resulted in atrophic epidermal and dermal tissue development. These data demonstrate, (i) the strict dependence of epidermal tissue regeneration on the presence of fibroblasts, (ii) the mutual keratinocyte-fibroblast interactions for cell proliferation and organogenesis, and (iii) the importance of the proper microenvironment for epidermal tissue function and supposedly for establishment of a stem cell niche in vitro.     

Bone marrow stromal cells, preadipocytes, and dermal fibroblasts promote epidermal regeneration in their distinctive fashions

Mesenchymal cell types, under mesenchymal-epithelial interaction, are involved in tissue regeneration. Here we show that bone marrow stromal cells (BMSCs), subcutaneous preadipocytes, and dermal fibroblasts distinctively caused keratinocytes to promote epidermal regeneration, using a skin reconstruction model by their coculture with keratinocytes. Three mesenchymal cell types promoted the survival, growth, and differentiation of keratinocytes, whereas BMSCs and preadipocytes inhibited their apoptosis. BMSCs and preadipocytes induced keratinocytes to reorganize rete ridge- and epidermal ridge-like structures, respectively. Keratinocytes with fibroblasts or BMSCs expressed the greatest amount of interleukin (IL)-1alpha protein, which is critical for mesenchymal-epithelial cross-talk in skin. Keratinocytes with or without three mesenchymal supports displayed another cross-talk molecule, c-Jun protein. Without direct mesenchymal-epithelial contact, the rete ridge- and epidermal ridge-like structures were not replicated, whereas the other phenomena noted above were. DNA microarray analysis showed that the mesenchymal-epithelial interaction affected various gene expressions of keratinocytes and mesenchymal cell types. Our results suggest that not only skin-localized fibroblasts and preadipocytes but also BMSCs accelerate epidermal regeneration in complexes and that direct contact between keratinocytes and BMSCs or preadipocytes is required for the skin-specific morphogenesis above, through mechanisms that differ from the IL-1alpha/c-Jun pathway.     

Notch-deficient skin induces a lethal systemic B-lymphoproliferative disorder by secreting TSLP, a sentinel for epidermal integrity

Epidermal keratinocytes form a highly organized stratified epithelium and sustain a competent barrier function together with dermal and hematopoietic cells. The Notch signaling pathway is a critical regulator of epidermal integrity. Here, we show that keratinocyte-specific deletion of total Notch signaling triggered a severe systemic B-lymphoproliferative disorder, causing death. RBP-j is the DNA binding partner of Notch, but both RBP-j–dependent and independent Notch signaling were necessary for proper epidermal differentiation and lipid deposition. Loss of both pathways caused a persistent defect in skin differentiation/barrier formation. In response, high levels of thymic stromal lymphopoietin (TSLP) were released into systemic circulation by Notch-deficient keratinocytes that failed to differentiate, starting in utero. Exposure to high TSLP levels during neonatal hematopoiesis resulted in drastic expansion of peripheral pre- and immature B-lymphocytes, causing B-lymphoproliferative disorder associated with major organ infiltration and subsequent death, a previously unappreciated systemic effect of TSLP. These observations demonstrate that local skin perturbations can drive a lethal systemic disease and have important implications for a wide range of humoral and autoimmune diseases with skin manifestations.     

Effects of amiprilose hydrochloride on the components of human skin equivalents

Summary Amiprilose hydrochloride has been shown to inhibit the proliferation of a number of hyperproliferative cell types including psoriatic skin cells. In the present study, the effects of amiprilose hydrochloride on human tissue equivalents were examined by incubating a) dermal equivalents, b) skin equivalents in the process of epidermalization, and c) mature skin equivalents, with varying concentrations of the drug. In all three models amiprilose hydrochloride concentrations of 0.1% (wt/vol) and lower were not toxic to fibroblasts and keratinocytes and did not interfere with the differentiation of the skin equivalent and the developing skin equivalent. When tested in dermal equivalents, concentrations of amiprilose hydrochloride between 0.1 and 0.5% resulted in changes in fibroblast morphology with development of large intracellular vacuoles, and concentrations greater than 5% were toxic. In mature skin equivalents, in addition to changes in fibroblast morphology, amiprilose hydrochloride in concentrations of 1 to 10% affected the epidermis. When 0.5% amiprilose hydrochloride was present in the developing skin equivalent during differentiation, the epidermal keratinocytes were also affected. Thus the morphology of basal keratinocytes was modified, the differentiation was incomplete, and the dermalepidermal attachment was compromised. These studies suggest the possibility of an extracellular mechanism of action of amiprilose hydrochloride and delineate acceptable dosage ranges for the potential drug. Supported in part by research grant AG01274 from the National Institutes of Health, Bethesda, MD, The R. A. Welch Foundation (B0502), The Texas Advanced Technology and Research Program (Wound Healing and Aging no. 2147), and Greenwich Pharmaceuticals, Inc. R. W. G. is the recipient of a MERIT award from the National Institute on Aging, Bethesda, MD.     

Effects of subepithelial fibroblasts on epithelial differentiation in human skin and oral mucosa: heterotypically recombined organotypic culture model

The stratified squamous epithelia differ regionally in their patterns of morphogenesis and differentiation. Although some reports suggested that the adult epithelial phenotype is an intrinsic property of the epithelium, there is increasing evidence that subepithelial connective tissue can modify the phenotypic expression of the epithelium. The aim of this study was to elucidate whether the differentiation of cutaneous and oral epithelia is influenced by underlying mesenchymal tissues. Three normal skin samples and three normal buccal mucosa samples were used for the experiments. Skin equivalents were constructed in four ways, depending on the combinations of keratinocytes (cutaneous or mucosal keratinocytes) and fibroblasts (dermal or mucosal fibroblasts), and the effects of subepithelial fibroblasts on the differentiation of oral and cutaneous keratinocytes were studied with histological examinations and immunohistochemical analyses with anti-cytokeratin (keratins 10 and 13) antibodies. For each experiment, three paired skin equivalents were constructed by using single parent keratinocyte and fibroblast sources for each group; consequently, nine (3 x 3) organotypic cultures per group were constructed and studied. The oral and cutaneous epithelial cells maintained their intrinsic keratin expression. The keratin expression patterns in oral and cutaneous epithelia of skin equivalents were generally similar to their original patterns but were partly modified exogenously by the topologically different fibroblasts. The mucosal keratinocytes were more differentiated and expressed keratin 10 when cocultured with dermal fibroblasts, and the expression patterns of keratin 13 in cutaneous keratinocytes cocultured with mucosal fibroblasts were different from those in keratinocytes cocultured with cutaneous fibroblasts. The results suggested that the epithelial phenotype and keratin expression could be extrinsically modified by mesenchymal fibroblasts. In epithelial differentiation, however, the intrinsic control by epithelial cells may still be stronger than extrinsic regulation by mesenchymal fibroblasts.     

RXR-alpha ablation in skin keratinocytes results in alopecia and epidermal alterations

RXR-alpha is the most abundant of the three retinoid X receptors (RXRs) in the epidermis. In this study, we have used Cre-mediated recombination to selectively disrupt the mouse gene for RXR-alpha in epidermal and hair follicle keratinocytes. We show that RXR-alpha is apparently dispensable for prenatal epidermal development, while it is involved in postnatal skin maturation. After the first hair pelage, mutant mice develop a progressive alopecia, histologically characterised by the destruction of hair follicle architecture and the formation of utriculi and dermal cysts in adult mice. Our results demonstrate that RXR-alpha plays a key role in anagen initiation during the hair follicle cycle. In addition, RXR-alpha ablation results in epidermal interfollicular hyperplasia with keratinocyte hyperproliferation and aberrant terminal differentiation, accompanied by an inflammatory reaction of the skin. Our data not only provide genetic evidence that RXR-alpha/VDR heterodimers play a major role in controlling hair cycling, but also suggest that additional signalling pathways mediated by RXR-alpha heterodimerised with other nuclear receptors are involved in postnatal hair follicle growth, and homeostasis of proliferation/differentiation of epidermal keratinocytes and of the skin's immune system.     

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.     

Three-dimensional epidermis-like growth of human mesenchymal stem cells on dermal equivalents: contribution to tissue organization by adaptation of myofibroblastic phenotype and function

Abstract Human mesenchymal stem cells (hMSC) are able to differentiate into mature cells of various mesenchymal tissues. Recent studies have reported that hMSC may even give rise to cells of ectodermal origin. This indication of plasticity makes hMSC a promising donor source for cell-based therapies. This study explores the differentiation potential of hMSC in a tissue-specific microenvironment simulated in vitro . HMSC were cultured air-exposed on dermal equivalents (DEs) consisting of collagen types I and III with dermal fibroblasts and subjected to conditions similar to those used for tissue engineering of skin with keratinocytes. Culture conditions were additionally modified by pre-treating the cells with 5-azacytidine or supplementing the medium with all trans retinoic acid (RA). HMSC were capable of adaptation to epidermis-specific conditions without losing their mesenchymal multipotency. However, despite the viability and evident three-dimensional epidermis-like growth pattern, hMSC showed a persistent expression of mesenchymal but not of epithelial markers, thus indicating a lack of epidermal (trans) differentiation. Further, electron microscopy and immunohistochemical analyses demonstrated that hMSC cultured under epidermis-specific conditions adopted a myofibroblastic phenotype and function, promoted in particular by air exposure. In conclusion, multipotent hMSC failed to differentiate into E-cadherin- or cytokeratin-expressing cells under optimized organotypic culture conditions for keratinocytes but differentiated into myofibroblast-like cells contracting the extracellular matrix, a phenomenon that was enhanced by RA and 5-azacytidine. These results indicate that hMSC might contribute to wound-healing processes by extracellular matrix reorganization and wound contraction but not by differentiation into keratinocytes.     

Retention of differentiated characteristics in human fetal keratinocytes in vitro

Summary Many of the morphologic and biochemical changes that occur during human fetal skin development have been described, yet there has been little experimental analysis of the processes that regulate the development of human fetal skin. This is due in part to difficulties in culturing human fetal epidermal keratinocytes. We have successfully cultured fetal keratinocytes in two different in vitro systems; in a serum-free keratinocyte growth medium (KGM) on tissue culture plastic and cocultured with dermal fibroblasts as spheroidal aggregates. To characterize these fetal keratinocytes in vitro we have assessed their ability to express several markers of epidermal differentiation. Human fetal keratinocytes grown on plastic in KGM stratify and express some of the components of the differentiated epidermis, such as involucrin and the high molecular weight keratins. However, these keratinocytes co-express keratins and vimentin and do not form a structured basement membrane. More characteristics of fetal skin are preserved in mixed aggregates of epidermal keratinocytes and dermal fibroblasts including epidermal stratification, synthesis of basement membrane components, tissue-specific expression of intermediate filaments, involucrin, and expression of high molecular weight keratins. The maintenance of human fetal epidermal keratinocytes in these two in vitro systems and their ability to express many differentiated characteristics suggests that these cultures will be valuable for studies of the molecular mechanisms that regulate the regionally specific differentiation of the human fetal epidermis. This work was supported by the Dermatology Foundation Fellowships funded by Herbert Laboratories and The Upjohn Company and awarded to A. R. H., NIH Training Program in Dermatological Research #5T32AR07472, and NIH grant #5R01HD20996 to A. T. L. Publication no. 74 of the Dermatology Department, University of Rochester, Rochester, NY.     

Enrichment of epidermal stem cells by rapid adherence and analysis of the reciprocal interaction of epidermal stem cells with neighboring cells using an organotypic system

Keratinocytes have the ability to adhere to extracellular matrix rapidly. With this in mind, in this study we isolated keratinocytes known as rapidly adhering (RA) cells. To compare epidermal regenerative abilities, skin substitutes were reconstructed by adding keratinocytes or RA cells to two groups of bioengineered dermis made by fibroblasts and hair follicle dermal cells respectively. After transplantation, the results illustrated that the skin substitutes including RA cells were integrated into the host tissue. Furthermore, with hair follicle dermal cells' influences, the RA cells could form structures very similar to normal hair follicles. These results indicate that RA cells are predominately comprised of epidermal stem cells. The results also demonstrated that besides the reciprocal interaction of epidermal stem cells with dermal cells, the interaction of epidermal stem cells with keratinocytes were critical in epidermis morphogenesis and self-renewal, and application of RA cells could optimize engineering of skin substitutes.     

Establishment of 3D organotypic cultures using human neonatal epidermal cells

This protocol describes an ex vivo three-dimensional coculture system optimized to study the skin regenerative ability of primary human keratinocytes grown at the air-liquid interface on collagen matrices embedded with human dermal fibroblasts. An option for enrichment of keratinocyte stem cells and their progeny using fluorescence-activated cell sorting is also provided. Initially, dermal equivalents, comprising human passaged fibroblasts seeded in a collagen matrix, are grown on porous filters (3 mum) placed in transwells. After 1 week, primary human keratinocytes are seeded on this base. One week later, an air-lift transition is performed, leading to the differentiation of the keratinocytes, which are macroscopically visible as artificial skin after a couple of days. The cultures can be harvested 1 week after the air-lift and processed for immunohistochemistry or gene expression analysis. The overall procedure can be completed in 3 weeks, including the preparation of the dermal equivalent and the seeding of the primary keratinocytes.     

Identification of functional markers in a self-assembled skin substitute in vitro

Some functional parameters were identified and assessed in a tissue-engineered self-assembled skin substitute. This skin substitute was produced using fibroblasts and keratinocytes isolated from adult human skin. Keratinocytes were seeded on a dermal layer, composed of two fibroblast sheets cultured for 35 d. The epidermal cells formed a stratified and cornified epidermis and expressed differentiation markers, notably involucrin and transglutaminase. Interestingly and for the first time, the receptor for vitamin D3 was detected in all of the epidermal cell layers of the skin substitute, as it is reported for normal human skin. This observation suggests that keratinocytes retain key receptors during their differentiation in the skin model. A network of collagen fibers was observed by electron microscopy in the dermal layer of the model. In the dermis, collagen fibers remodeling and assembly is dependent on enzymes, notably prolyl-4-hydroxylase. For the first time in a skin construct, the expression of prolyl-4-hydroxylase was detected in dermal fibroblasts by in situ hybridization. The secretion of collagenases by the cells seeded in our skin substitute was confirmed by zymography. We conclude that the self-assembly approach allows the maintenance of several functional activities of human skin cells in a skin model in vitro.     

Induction of proteins and mRNAs after uv irradiation of human epidermal keratinocytes

uv sensitivity of cultured human epidermal keratinocytes was analyzed at different growth conditions and compared with the sensitivity of dermal fibroblasts derived from the same skin specimen. No significant differences in survival curves were found between these two cell types, although keratinocytes grown under standard conditions were slightly more resistant to uv irradiation than fibroblasts. The extracellular concentration of calcium appeared to be critical not only in the regulation of keratinocyte proliferation and differentiation, but also in the uv sensitivity of these cells: keratinocytes grown under conditions which favor cell proliferation (low calcium concentration) are more resistant to uv irradiation than those grown under conditions favoring differentiation (high calcium concentration). Two-dimensional protein gel electrophoresis was used to detect a possible effect of uv irradiation on the accumulation of specific mRNAs in the cytoplasm and/or on the synthesis of specific proteins. Proteins were pulse labeled in vivo with [35S]methionine or synthesized in vitro in rabbit reticulocyte lysates on mRNA isolated from keratinocytes that were irradiated with different uv doses at different periods of time prior to isolation. Alterations in expression were demonstrated for several proteins in both in vivo and in vitro experiments.     

12R-lipoxygenase deficiency disrupts epidermal barrier function

12R-lipoxygenase (12R-LOX) and the epidermal LOX-3 (eLOX-3) constitute a novel LOX pathway involved in terminal differentiation in skin. This view is supported by recent studies showing that inactivating mutations in 12R-LOX and eLOX-3 are linked to the development of autosomal recessive congenital ichthyosis. We show that 12R-LOX deficiency in mice results in a severe impairment of skin barrier function. Loss of barrier function occurs without alterations in proliferation and stratified organization of the keratinocytes, but is associated with ultrastructural anomalies in the upper granular layer, suggesting perturbance of the assembly/extrusion of lamellar bodies. Cornified envelopes from skin of 12R-LOX-deficient mice show increased fragility. Lipid analysis demonstrates a disordered composition of ceramides, in particular a decrease of ester-bound ceramide species. Moreover, processing of profilaggrin to monomeric filaggrin is impaired. This study indicates that the 12R-LOX-eLOX-3 pathway plays a key role in the process of epidermal barrier acquisition by affecting lipid metabolism, as well as protein processing.     

11β-Hydroxysteroid dehydrogenase-1 is a novel regulator of skin homeostasis and a candidate target for promoting tissue repair

11β-Hydroxysteroid dehydrogenase 1 (11β-HSD1) catalyzes the interconversion of cortisone and cortisol within the endoplasmic reticulum. 11β-HSD1 is expressed widely, most notably in the liver, adipose tissue, and central nervous system. It has been studied intensely over the last 10 years because its activity is reported to be increased in visceral adipose tissue of obese people. Epidermal keratinocytes and dermal fibroblasts also express 11β-HSD1. However, the function of the enzymatic activity 11β-HSD1 in skin is not known. We found that 11β-HSD1 was expressed in human and murine epidermis, and this expression increased as keratinocytes differentiate. The expression of 11β-HSD1 by normal human epidermal keratinocytes (NHEKs) was increased by starvation or calcium-induced differentiation in vitro. A selective inhibitor of 11β-HSD1 promoted proliferation of NHEKs and normal human dermal fibroblasts, but did not alter the differentiation of NHEKs. Topical application of selective 11β-HSD1 inhibitor to the dorsal skin of hairless mice caused proliferation of keratinocytes. Taken together, these data suggest that 11β-HSD1 is involved in tissue remodeling of the skin. This hypothesis was further supported by the observation that topical application of the selective 11β-HSD1 inhibitor enhanced cutaneous wound healing in C57BL/6 mice and ob/ob mice. Collectively, we conclude that 11β-HSD1 is negatively regulating the proliferation of keratinocytes and fibroblasts, and cutaneous wound healing. Hence, 11β-HSD1 might maintain skin homeostasis by regulating the proliferation of keratinocytes and dermal fibroblasts. Thus 11β-HSD1 is a novel candidate target for the design of skin disease treatments.     

PTH-1R responses to PTHrP and regulation by vitamin D in keratinocytes and adjacent fibroblasts

Vitamin D and PTHrP are essential for the differentiation of keratinocytes and epidermal development. The action of PTHrP on skin is mediated via its PTH-1R receptors present in both epidermal and dermal cells. This suggests that PTHrP may have a paracrine/autocrine role, and its receptors may act in association or in negative cooperativity. We compared the intracellular signaling pathways in response to PTHrP (1-34) and to various PTHrP peptides, the N-terminal (1-34), Mid region (67-89), and C-terminal (107-139) fragments, and the possible modulation of PTHrP and its receptor mRNA expressions by vitamin D. Adjacent dermal fibroblasts as freshly isolated keratinocytes expressed both PTHrP and PTH-1R mRNAs, and responded to the various PTHrP fragments. bPTH and PTHrP(1-34) increased both cellular cAMP and [Ca(2+)]i in keratinocytes and fibroblasts. In contrast, PTHrP (107-139) increased [Ca(2+)]i but not cAMP in the two cell types. PTHrP (67-89) had no effect in keratinocytes, and only increased [Ca(2+)]i in fibroblasts. Vitamin D deficiency in weaned rats increased the expression of PTHrP mRNA in keratinocytes, and decreased it in fibroblasts and kidneys. Vitamin D deficiency increased PTH-1R mRNA expression in keratinocytes and kidneys, but not in fibroblasts. Although keratinocytes and skin fibroblasts are target cells for PTHrP and express PTH-1R, the two adjacent cell types differ as regards their intracellular signaling in response to PTHrP peptides. Moreover vitamin D regulates PTHrP and PTH-1R in a cell-specific manner.     

Liver X receptor is a therapeutic target for photoaging and chronological skin aging

Liver X receptors (LXRalpha and -beta) are liposensors that exert their metabolic effects by orchestrating the expression of macrophage genes involved in lipid metabolism and inflammation. LXRs are also expressed in other tissues, including skin, where their natural oxysterol ligands induce keratinocyte differentiation and improve epidermal barrier function. To extend the potential use of LXR ligands to dermatological indications, we explored the possibility of using LXR as a target for skin aging. We demonstrate that LXR signaling is down-regulated in cell-based models of photoaging, i.e. UV-activated keratinocytes and TNFalpha-activated dermal fibroblasts. We show that a synthetic LXR ligand inhibits the expression of cytokines and metalloproteinases in these in vitro models, thus indicating its potential in decreasing cutaneous inflammation associated with the etiology of photoaging. Furthermore, a synthetic LXR ligand induces the expression of differentiation markers, ceramide biosynthesis enzymes, and lipid synthesis and transport genes in keratinocytes. Remarkably, LXRbeta-null mouse skin showed some of the molecular defects that are observed in chronologically aged human skin. Finally, we demonstrate that a synthetic LXR agonist inhibits UV-induced photodamage and skin wrinkle formation in a murine model of photoaging. Therefore, the ability of an LXR ligand to modulate multiple pathways underlying the etiology of skin aging suggests that LXR is a novel target for developing potential therapeutics for photoaging and chronological skin aging indications.