Sodium butyrate selectively antagonizes the inhibitory effect of retinoids on cornified envelope formation in cultured human keratinocytes

Sodium butyrate affects cell differentiation in confluent epidermal keratinocyte cultures by considerably increasing the spontaneous formation of cross-linked envelopes in normal human keratinocytes (NHK). It also favors the development of envelope competence in the Simian virus-40 (SV-40)-transformed human foreskin keratinocyte line SV-K14. It completely abolishes the inhibitory effect of serum and retinoic acid on the expression of plasma membrane-associated transglutaminase. However, other markers of epidermal differentiation that are also under the control of retinoids such as keratins or the enzyme cholesterol sulfotransferase are not affected by butyrate. The level of the cellular retinoic acid binding protein (CRABP) is considerably increased in its presence. Butyrate does not interfere with the binding of retinoids to their cellular binding proteins. Our observations suggest that sodium butyrate stimulates cornified envelope formation via the induction of the plasma membrane-associated transglutaminase required for cornified envelope synthesis and, additionally, by abolishing the inhibitory effect of retinoids on the expression of this enzyme.     

All-trans-retinoic acid and 13-cis-retinoic acid: pharmacokinetics and biological activity in different cell culture models of human keratinocytes.

Despite its known biological effect on epithelial cells, 13- CIS-retinoic acid shows low binding affinity to either cellular retinoic acid-binding proteins or nuclear retinoid receptors compared to its isomer all- TRANS-retinoic acid. We have postulated a prodrug-drug relation with 13- CIS-retinoic acid which isomerizes to all- TRANS-retinoic acid. On the other hand, the biological effects of these two compounds can differ in the widely used cell culture models of HaCaT and normal primary keratinocytes. In this study, we seeded HaCaT and normal keratinocytes at high densities leading to early confluence in order to imitate high keratinocyte proliferation, such as in acne and psoriasis, while to model decreased keratinocyte proliferation, as in aged and steroid-damaged skin, cells were seeded at a low density. High performance liquid chromatography was administered to examine retinoid uptake and metabolism in monolayer HaCaT and normal keratinocyte cultures and the 4-methylumbelliferyl heptanoate assay to estimate cell growth at different cell densities. Major qualitative and quantitative differences were detected in the two cell types regarding intracellular 13- CIS-retinoic acid isomerization to all- TRANS-retinoic acid. On the other hand, the two retinoic acid isomers showed similar effects on cell growth of both cell types tested with increasing proliferation at low cell densities, but being rather inactive at high ones in normal keratinocytes and exhibiting an antiproliferative effect in HaCaT keratinocytes. The missing effect of retinoids on cell proliferation in high seeding densities of normal keratinocytes may indicate that the normalizing activity of retinoids on hyperkeratotic diseases, such as acne or psoriasis, is likely to be carried out by modulation of cell differentiation than cell growth. On the other hand, induced keratinocyte proliferation in low seeding densities may provide an explanation for the acanthosis induced by topical retinoids in aged and steroid-damaged skin.     

The Activity of Collagenase-1 Is Required for Keratinocyte Migration on a Type I Collagen Matrix

We have shown in a variety of human wounds that collagenase-1 (MMP-1), a matrix metalloproteinase that cleaves fibrillar type I collagen, is invariably expressed by basal keratinocytes migrating across the dermal matrix. Furthermore, we have demonstrated that MMP-1 expression is induced in primary keratinocytes by contact with native type I collagen and not by basement membrane proteins or by other components of the dermal or provisional (wound) matrix. Based on these observations, we hypothesized that the catalytic activity of MMP-1 is necessary for keratinocyte migration on type I collagen. To test this idea, we assessed keratinocyte motility on type I collagen using colony dispersion and colloidal gold migration assays. In both assays, primary human keratinocytes migrated efficiently on collagen. The specificity of MMP-1 in promoting cell movement was demonstrated in four distinct experiments. One, keratinocyte migration was completely blocked by peptide hydroxymates, which are potent inhibitors of the catalytic activity of MMPs. Two, HaCaTs, a line of human keratinocytes that do not express MMP-1 in response to collagen, did not migrate on a type I collagen matrix but moved efficiently on denatured type I collagen (gelatin). EGF, which induces MMP-I production by HaCaT cells, resulted in the ability of these cells to migrate across a type I collagen matrix. Three, keratinocytes did not migrate on mutant type I collagen lacking the collagenase cleavage site, even though this substrate induced MMP-1 expression. Four, cell migration on collagen was completely blocked by recombinant tissue inhibitor of metalloproteinase-1 (TIMP-1) and by affinity-purified anti–MMP-1 antiserum. In addition, the collagen-mediated induction of collagenase-1 and migration of primary keratinocytes on collagen was blocked by antibodies against the α2 integrin subunit but not by antibodies against the α1 or α3 subunits. We propose that interaction of the α2β1 integrin with dermal collagen mediates induction of collagenase-1 in keratinocytes at the onset of healing and that the activity of collagenase-1 is needed to initiate cell movement. Furthermore, we propose that cleavage of dermal collagen provides keratinocytes with a mechanism to maintain their directionality during reepithelialization.     

Synthesis of cellular and extracellular glycoproteins by cultured human keratinocytes and their response to retinoids

The glycoproteins synthesized by human keratinocytes cultured on 3T3 feeder layers were studied by metabolic labelling. Keratinocytes freed of feeder cells synthesized a complex pattern of cellular and extracellular glycoproteins that was distinct from that of 3T3 cells, dermal fibroblasts and epidermal melanocytes. The effect of low concentrations of all-trans-retinoic acid and arotinoid ethyl ester on glycoprotein synthesis was examined in keratinocyte cultures depleted of vitamin A. Treatment with either retinoid resulted in a 2-3-fold increase in the amount of D-[3H]glucosamine-labelled material in the culture medium. Gel electrophoresis revealed increased incorporation of D-[3H]glucosamine into extracellular glycoproteins of Mr 245,000, 170,000, 140,000, 130,000, 120,000 and 105,000 as well as into glycosaminoglycans in retinoid-treated cultures. The labelling of extracellular glycoproteins with L-[3H]leucine and L-[35S]methionine was also increased by retinoids suggesting increased synthesis of these components rather than an effect on their glycosylation. The Mr 245 000 glycoprotein was identified as keratinocyte-derived fibronectin by immunoblotting, immunoprecipitation and specific binding to gelatin. The results show that retinoids increase the synthesis of glycoprotein as well as glycosaminoglycan components of the extracellular matrix in human keratinocyte cultures. It is suggested that retinoids select for a population of cells that synthesize relatively large amounts of glycosaminoglycan, fibronectin and other as yet unidentified extracellular glycoproteins.     

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.     

Involvement of the 92-kDa gelatinase (matrix metalloproteinase-9) in the ceramide-mediated inhibition of human keratinocyte growth.

Triggering the ceramide pathway by exogenous treatment with neutral sphingomyelinase (Smase) inhibited human keratinocyte growth rate, while having no influence on cell apoptosis. Increasing the ceramide content of keratinocytes with Smase (100 U/ml) or C6-ceramide (1 microM) enhanced matrix metalloproteinase (MMP)-9 production. On the contrary, levels of MMP-2 secretion were unchanged. The inhibition of keratinocyte growth rate induced by ceramide could be annihilated by a peptide hydroxamate MMP inhibitor or an MMP-9 blocking antibody. In addition, inhibiting MMP-9 activity in control keratinocyte culture was found to stimulate keratinocyte proliferation. These data suggest a pivotal function of MMP-9 in the control of keratinocyte growth.     

Acylceramides and lanosterol-lipid markers of terminal differentiation in cultured human keratinocytes: Modulating effect of retinoic acid

Summary Epidermal differentiation is accompanied by profound changes in the synthesis of a variety of intracellular proteins and intercellular lipids. In conventional, submerged culture keratinocytes have been shown to lose the ability to synthesize the protein markers of differentiation. They re-express them, however, when they are cultured in medium supplemented with delipidized [retinoic acid (RA)-depleted] serum or in air-exposed cultures using de-epidermized dermis (DED) as a substrate. Recent studies have revealed that acylceramides (AC) and lanosterol (LAN), which are present only in trace amounts in cultures of keratinocytes grown under submerged conditions on DED in medium supplemented with normal serum, become expressed in significant amounts when the culture is lifted to the air-liquid interface. Inasmuch as culture conditions may markedly affect the extent of keratinocyte differentiation, the present study aimed to investigate the effect of normal (RA-containing) or delipidized (RA-depleted) serum and of RA administration on lipid composition (especially of the AC and LAN contents) in cells cultured under submerged and air-exposed conditions. To test a possible effect of dermal substrate (used in the air-exposed model), the lipid composition of keratinocytes grown under submerged conditions on a plastic and on a dermal substrate (de-epidermized dermis, DED) has also been compared. The results revealed that under all culture conditions, RA deprivation of fetal bovine serum resulted in a marked increase of total ceramide content. Even under submerged conditions, the presence of both AC and LAN could be detected. In air-exposed culture, the content of these lipids was markedly increased. Addition of RA at 1 μM concentration to cultures grown in RA-depleted medium induced marked changes in lipid composition under all culture conditions tested. In cells grown under submerged conditions (both on plastic and on DED) AC and LAN were no longer present in detectable amounts. Also in air-exposed culture, a marked decrease in the content of these lipids was observed. These results suggest that liposoluble serum components, like RA, control the synthesis of lipids that are present in later stages of epidermal differentiation.     

The interaction of human papillary and reticular fibroblasts and human keratinocytes in the contraction of three-dimensional floating collagen lattices

Fibroblasts derived from the papillary and reticular dermis of human skin and human keratinocytes show differences in their abilities to contract floating three-dimensional gels constructed from type I collagen. Reticular fibroblasts produce greater gel contraction than papillary fibroblasts. When equal numbers of papillary and reticular fibroblasts are mixed in the gels, papillary fibroblasts consistently inhibit gel contraction by reticular fibroblasts indicating interaction between these cell types in the contraction process. Surprisingly, keratinocytes alone produce greater gel contraction than that produced by either fibroblast type. Cooperativity in the gel contraction process is observed when fibroblasts are incorporated into the collagen matrix and keratinocytes are seeded onto the gel surface. Keratinocytes and dermal fibroblasts adhere to the collagen fibril to induce gel contraction by different mechanisms. Fibroblast contraction of collagen gels does not require fibronectin but is a serum-dependent reaction. In contrast, keratinocyte contraction of collagen gels occurs in a serum-free environment. Polyclonal, affinity-purified antibodies to human plasma fibronectin at high concentrations do not inhibit gel contraction by keratinocytes, making unlikely the possibility that fibronectin synthesized by the keratinocyte is a significant factor in the gel contraction process. We are currently examining the possibilities either that keratinocytes are synthesizing other adhesion proteins or that receptors on the cell surface can interact directly with the collagen fiber.     

Induction of Invasion and Tubulogenesis in Primary Human Keratinocyte Culture

In this study we used invasion and tubulogenesis assays to measure the morphogenetic potential of primary human keratinocytes in vitro. We also used human embryonic and dermal fibroblasts in coculture with keratinocytes and compared their influence on keratinocyte behavior in these different cell culture systems. The keratinocytes retained morphogenetic potential in vitro. In the presence of embryonic fibroblasts, the keratinocytes formed tubes and invaded collagen gel. A three-dimensional architecture of invasion clusters was reconstructed. We conclude that the cellular mechanisms of invasion and tubulogenesis are similar.     

Fibronectin receptors of human keratinocytes and their expression during cell culture

Keratinocyte attachment to fibronectin (FN) substrata was inhibited by the peptide Gly-Arg-Gly-Asp-Ser-Pro-Cys, but not by the variant peptide Gly-Arg-Gly-Glu-Ser-Pro. The RGDS-containing peptide did not inhibit keratinocyte adhesion to collagen. Keratinocyte adhesion to FN substrata also was inhibited by polyclonal anti-FN receptor antibodies originally prepared against the 140-kD FN receptors of Chinese hamster ovary (CHO) cells. Anti-CHO FN receptor antibodies did not, however, inhibit keratinocyte adhesion to collagen substrata. A monoclonal antibody designated VM-1 that was prepared against human basal keratinocytes inhibited keratinocyte adhesion to collagen but not to FN. Based on these results, we conclude that keratinocytes have distinct FN and collagen receptors. Experiments were performed to compare the expression of FN receptors on keratinocytes freshly isolated from skin and keratinocytes harvested from cell cultures. Cells harvested from keratinocyte cultures were able to neutralize the inhibitory activity of anti-CHO FN receptor antibodies and were able to attach and spread on anti-CHO FN receptor-coated substrata. Cells freshly harvested from skin, however, did not neutralize the antibodies, nor did they attach and spread on antibody-coated substrata. To learn more about the biochemical nature of the keratinocyte FN receptors, we performed immunoaffinity chromatography and immunoprecipitation experiments using the anti-CHO FN receptor antibodies. Extracts from metabolically radiolabeled, 10-d cultured keratinocytes contained FN receptors that had a 135-kD component under reducing conditions and 115- and 155-kD components under nonreducing conditions. Similar components were observed in extracts from surface- radiolabeled cells indicating that the FN receptors were expressed on keratinocyte cell surfaces. On the other hand, extracts from metabolically radiolabeled, 1-d cultured keratinocytes lacked intact FN receptors but contained a component that migrated at 48 kD under reducing conditions and 50 kD under nonreducing conditions. Because this fragment was not detected in surface-radiolabeled keratinocytes that were freshly isolated from skin, it seems likely that the fragment was located inside the cells rather than on the cell surface. A 50-kD FN receptor fragment also was observed in extracts from 10-d cultured keratinocytes if leupeptin and pepstatin were omitted from the extraction buffer. The results suggested that human keratinocytes cultured for 10 d express the 140-kD class of FN receptors, but that these receptors are not expressed on the surfaces of keratinocytes freshly isolated from skin.(ABSTRACT TRUNCATED AT 400 WORDS)     

Interaction of cultured skin cells with the polylactide matrix coved with different collagen structural isoforms

These experiments were done to optimize the surface properties of polylactide film designed for human keratinocyte cultivation. The film was covered with type 1 collagen to increase its hydrophilic properties. The method of protein application determines the consistency the matrix coating and the formation of different collagen structures on the film. Substrates modified by collagen affect the growth of cultured keratinocytes. Our data on keratinocyte spreading, morphology and cytoskeleton organization demonstrate that the best form of collagen to use to cover the polymeric surface is the fibrillar isoform.     

Characterization of the living skin equivalent as a model of cutaneous re-epithelialization

The living skin equivalent, a three-dimensional organotypic model, has been widely used to investigate many aspects of cutaneous biology. However, there are relatively few studies assessing how faithfully the skin equivalent reproduces normal skin biology. The skin equivalent was fabricated by seeding human epidermal keratinocytes onto the upper surface of a hydrated collagen lattice populated with human dermal fibroblasts and subsequently raised to the air-liquid interface where keratinocyte stratification and differentiation led to the formation of a tissue which showed many common morphological features to that of normal skin. Histology and immunohistochemical detection of keratinocyte integrins and matrix metalloproteinases (MMPs) were used as cytological markers to assess the accuracy of the model during cutaneous re-epithelialization. Analysis of expression of keratinocyte integrins revealed that whilst there were a number of similarities to normal skin, skin equivalent keratinocytes appeared to be 'activated' and hyper-proliferating. Wounding of the skin equivalent, by complete bisection, induced re-epithelialization from both wound edges within 8-12 h, which completely restored the epidermis within 4 days. This migration, like that in vivo, was associated with nascent expression of MMPs and upregulation of certain integrins. However, whilst integrin expression, was similar to in vivo re-epithelialization, there were subtle differences in the level of expression and distribution of certain integrins.     

Construction of a microstructured collagen membrane mimicking the papillary dermis architecture and guiding keratinocyte morphology and gene expression

A papillary-structured collagen fibril membrane is created, mimicking the 3D-architecture of the human papillary dermis. Primary human keratinocytes cultured to confluency on papillar-structured films are compared to keratinocytes cultured on flat membranes. Microscopical evaluation reveals the presence of morphologically distinct cells at the base of the papillar structures that are not observed on flat membranes. Gene expression microarrays and RT-qPCR indicate that these cells are in a more proliferative/migrational state, whereas cells on flat membranes have a more differentiated expression profile. Immunohistochemical stainings confirm these results. In conclusion, specific collagen architecture can direct keratinocyte behavior, and this may be used to further improve skin regeneration.     

Reconstitution of human epidermis in vitro is accompanied by transient activation of basal keratinocyte spreading

Frozen human cadaver skin obtained from the skin bank was thawed and incubated in serum-free medium for 1–2 days, after which the original epidermis could be removed mechanically. Transmission electron microscopic observations showed that the dermal matrix remaining behind contained intact bundles of collagen fibrils but no live cells and that a continuous lamina densa persisted in the basement membrane region. Indirect immunofluorescence analyses demonstrated linear staining of the basement membrane region by antibodies against laminin and type IV collagen and discontinuous staining with antibodies against fibronectin. Scanning electron microscopic observations revealed a normal topographical arrangement of dermal matrix papilla and interspersed crypts on the surface of the matrix. Epidermal cells placed on the dermal matrix attached in 1–2 h and spread by 24 h. After 1 week of culture the epidermis was reconstituted, at which time approximately 30% of the epidermal cells were basal keratinocytes and the remainder were more differentiated keratinocytes. A high degree of differentiation of the reconstituted epidermis was shown by the formation of hemidesmosomes along the basement membrane, the formation of desmosomes characterized by intercellular dense lines, and the presence of a cell layer containing keratohyalin granules. At various times during epidermal reconstitution, cells were harvested and tested in short-term assays for adhesion to fibronectin substrata. During the first several days there was a transient activation of basal keratinocyte spreading analogous to the modulation of keratinocyte spreading that we have observed during epidermal reconstitution in vivo.     

Ultrastructural and immunocytochemical detection of keratins and extracellular matrix proteins in lizard skin cultured in vitro

The present study shows the localization of epidermal and dermal proteins produced in lizard skin cultivated in vitro. Cells from the skin have been cultured for up to one month to detect the expression of keratins, actin, vimentin and extracellular matrix proteins (fibronectin, chondroitin sulphate proteoglycan, elastin and collagen I). Keratinocytes and dermal cells weakly immunoreact for Pan-Cytokeratin but not with the K17-antibody at the beginning of the cell culture when numerous keratin bundles are present in keratinocyte cytoplasm. The dense keratin network disappears after 7-12 days in culture, and K17 becomes detectable in both keratinocytes and mesenchymal cells isolated from the dermis. While most epidermal cells are lost after 2 weeks of in vitro cultivation dermal cells proliferate and form a pellicle of variable thickness made of 3-8 cell layers. The fibroblasts of this dermal equivalent produces an extracellular matrix containing chondroitin sulphate proteoglycan, collagen I, elastic fibers and fibronectin, explaining the attachment of the pellicle to the substratum. The study indicates that after improving keratinocyte survival a skin equivalent for lizard epidermis would be feasible as a useful tool to analyze the influence of the dermis on the process of epidermal differentiation and the control of the shedding cycle in squamates.     

Identification of different isoforms of 14-3-3 protein family in human dermal and epidermal layers

We have previously demonstrated a high level of stratifin, also known as 14-3-3 sigma in differentiated keratinocyte cell lysate and conditioned medium (CM). In this study, we asked the question of whether other 14-3-3 isoforms are expressed in human dermal fibroblasts, keratinocytes, intact dermal and epidermal layers of skin. In order to address this question, total proteins extracted from cultured cells or skin layers were subjected to western blot analysis using seven different primary antibodies specific to well-known mammalian isoforms, beta, gamma, epsilon, eta, sigma, tau, and zeta of 14-3-3 protein family. The autoradiograms corresponding to each isoform were then quantified and compared. The results revealed the presence of very high levels of all seven isoforms in cultured keratinocyte and conditioned medium. With the exception of tau isoform, other 14-3-3 isoforms were also present in intact epidermal layer of normal skin. The profile of 14-3-3 proteins in whole skin was similar to that of epidermis. In contrast, only gamma 14-3-3 isoform, was present in dermal layer obtained from the same skin sample. On the other hand, cultured fibroblasts express a high level of beta, epsilon, gamma and eta and a low level of zeta and tau, but not sigma isoform. However, the levels of 14-3-3 epsilon, gamma and eta were barely detectable in fibroblast conditioned medium. Further, we also used immunohistochemical staining to identify the 14-3-3 isoform expressing cells in human skin sections. The finding revealed different expression profile for each of these isoforms mainly in differentiated keratinocytes located within the layer of lucidum. However, fibroblasts located within the dermal layer did not show any detectable levels of these proteins. In conclusion, all members of 14-3-3 proteins are expressed by cells of epidermal but not dermal layer of skins and that these proteins are mainly expressed by differentiated keratinocytes.     

Site-matched papillary and reticular human dermal fibroblasts differ in their release of specific growth factors/cytokines and in their interaction with keratinocytes

The interfollicular dermis of adult human skin is partitioned into histologically and physiologically distinct papillary and reticular zones. Each of these zones contains a unique population of fibroblasts that differ in respect to their proliferation kinetics, rates at which they contract type I collagen gels, and in their relative production of decorin and versican. Here, site-matched papillary and reticular dermal fibroblasts couples were compared to determine whether each population interacted with keratinocytes in an equivalent or different manner. Papillary and reticular fibroblasts grown in monolayer culture differed significantly from each other in their release of keratinocyte growth factor (KGF) and granulocyte-macrophage colony stimulating factor (GM-CSF) into culture medium. Some matched fibroblast couples also differed in their constitutive release of interleukin-6 (IL-6). Papillary fibroblasts produced a higher ratio of GM-CSF to KGF than did corresponding reticular fibroblasts. Interactions between site-matched papillary and reticular couples were also assayed in a three-dimensional culture system where fibroblasts and keratinocytes were randomly mixed, incorporated into type I collagen gels, and allowed to sort. Keratinocytes formed distinctive cellular masses in which the keratinocytes were organized such that the exterior most layer of cells exhibited characteristics of basal keratinocytes and the interior most cells exhibited characteristics of terminally differentiated keratinocytes. In the presence of papillary dermal fibroblasts, keratinocyte masses were highly symmetrical and cells expressed all levels of differentiation markers. In contrast, keratinocyte masses that formed in the presence of reticular fibroblasts tended to have irregular shapes, and terminal differentiation was suppressed. Furthermore, basement membrane formation was retarded in the presence of reticular cells. These studies indicate that site-matched papillary and reticular dermal fibroblasts qualitatively differ in their support of epidermal cells, with papillary cells interacting more effectively than corresponding reticular cells.