Differentiation of human keratinocytes: changes in lipid synthesis, plasma membrane lipid composition, and 125I-EGF binding upon administration of 25-hydroxycholesterol and mevinolin

Exploring the dermotoxicity of the mycotoxin deoxynivalenol: combined morphologic and proteomic profiling of human epidermal cells reveals alteration of lipid biosynthesis machinery and membrane structural integrity relevant for skin barrier function

Deoxynivalenol (vomitoxin, DON) is a secondary metabolite produced by Fusarium spp. fungi and it is one of the most prevalent mycotoxins worldwide. Crop infestation results not only in food and feed contamination, but also in direct dermal exposure, especially during harvest and food processing. To investigate the potential dermotoxicity of DON, epidermoid squamous cell carcinoma cells A431 were compared to primary human neonatal keratinocytes (HEKn) cells via proteome/phosphoproteome profiling. In A431 cells, 10 µM DON significantly down-regulated ribosomal proteins, as well as mitochondrial respiratory chain elements (OXPHOS regulation) and transport proteins (TOMM22; TOMM40; TOMM70A). Mitochondrial impairment was reflected in altered metabolic competence, apparently combined with interference of the lipid biosynthesis machinery. Functional effects on the cell membrane were confirmed by live cell imaging and membrane fluidity assays (0.1–10 µM DON). Moreover, a common denominator for both A431 and HEKn cells was a significant downregulation of the squalene synthase (FDFT1). In sum, proteome alterations could be traced back to the transcription factor Klf4, a crucial regulator of skin barrier function. Overall, these results describe decisive molecular events sustaining the capability of DON to impair skin barrier function. Proteome data generated in the study are fully accessible via ProteomeXchange with the accession numbers PXD011474 and PXD013613.

Addressing Differentiation in Live Human Keratinocytes by Assessment of Membrane Packing Order

Differentiation of keratinocytes is critical for epidermal stratification and formation of a protective stratum corneum. It involves a series of complex processes leading through gradual changes in characteristics and functions of keratinocytes up to their programmed cell death via cornification. The stratum corneum is a relatively impermeable barrier, comprised of dead cell remnants (corneocytes) embedded in lipid matrix. Corneocyte membranes are comprised of specialized lipids linked to late differentiation proteins, contributing to the formation of a stiff and mechanically strengthened layer. To date, the assessment of the progression of keratinocyte differentiation is only possible through determination of specific differentiation markers, e.g., by using proteomics-based approaches. Unfortunately, this requires fixation or cell lysis, and currently there is no robust methodology available to study keratinocyte differentiation in living cells in real-time. Here, we explore new live-cell based approaches for screening differentiation advancement in keratinocytes, in a "calcium switch" model. We employ a polarity-sensitive dye, Laurdan, and Laurdan general polarization function (GP) as a reporter of the degree of membrane lateral packing order or condensation, as an adequate marker of differentiation. We show that the assay is straightforward and can be conducted either on a single cell level using confocal spectral imaging or on the ensemble level using a fluorescence plate reader. Such systematic quantification may become useful for understanding mechanisms of keratinocyte differentiation, such as the role of membrane in homogeneities in stiffness, and for future therapeutic development.

Orchestrated control of filaggrin-actin scaffolds underpins cornification

Epidermal stratification critically depends on keratinocyte differentiation and programmed death by cornification, leading to formation of a protective skin barrier. Cornification is dynamically controlled by the protein filaggrin, rapidly released from keratohyalin granules (KHGs). However, the mechanisms of cornification largely remain elusive, partly due to limitations of the observation techniques employed to study filaggrin organization in keratinocytes. Moreover, while the abundance of keratins within KHGs has been well described, it is not clear whether actin also contributes to their formation or fate. We employed advanced (super-resolution) microscopy to examine filaggrin organization and dynamics in skin and human keratinocytes during differentiation. We found that filaggrin organization depends on the cytoplasmic actin cytoskeleton, including the role for α- and β-actin scaffolds. Filaggrin-containing KHGs displayed high mobility and migrated toward the nucleus during differentiation. Pharmacological disruption targeting actin networks resulted in granule disintegration and accelerated cornification. We identified the role of AKT serine/threonine kinase 1 (AKT1), which controls binding preference and function of heat shock protein B1 (HspB1), facilitating the switch from actin stabilization to filaggrin processing. Our results suggest an extended model of cornification in which filaggrin utilizes actins to effectively control keratinocyte differentiation and death, promoting epidermal stratification and formation of a fully functional skin barrier.

Incorporation of phytosterols in human keratinocytes

We have designed experimental conditions allowing the replacement of 50% of cholesterol of human keratinocytes (SVK14 line) with sitosterol or stigmasterol without affecting cellular viability. We have investigated the influence of incorporating phytosterol on the ultraviolet-A-induced formation of lipid-peroxidation products (thiobarbituric reactive substances (TBARS)) in these cells. Our results show that ultraviolet-A-induced lipid peroxidation depends on the nature of the phytosterol. Sitosterol induces a significant decrease (-30%) of TBARS relative to the control whereas stigmasterol markedly increases lipid peroxidation (+70%). We have also studied the effect of plant sterols on prostaglandin release by using the Ca(2+) ionophore A23187 as an in vitro model of the inflammation induced by UVA radiation. We show that in the presence of 50% of phytosterol (particularly stigmasterol), the release of prostaglandin (6-ketoPG(1alpha), PGE(2)) is increased compared to untreated cells. This pro-inflammatory effect of phytosterols is correlated with a loss of the regulation of the intracellular Ca(2+) concentration.

Effects of gemfibrozil on in vitro cultured normal human skin explants

BACKGROUND

Several lipid-lowering agents, when given topically, show a profound effect on skin morphology. Because of low bioavailability of these drugs for keratinocytes, the incidence is extremely low clinically. The most appropriate way to study the effect of hypolipidemic drugs on keratinocytes is by artificial exposure of the skin to high drug concentrations.

OBJECTIVE

To study the effects of gemfibrozil on the morphology of in vitro cultured normal human skin explants. As gemfibrozil induces barrier disruption by inhibiting epidermal sterologenesis, essential for a competent permeability barrier, it is interesting to investigate the morphologic changes associated with this phenomenon. Studying the epidermal changes induced by lipid-lowering agents is important, not only because it might lead to a better understanding of the effects of these drugs on keratinocytes, but as it might also unlock the door to a wider knowledge of the pathomechanism of disorders of cornification.

METHODS

Normal human skin from patients undergoing mastectomy was cultured in the presence of 2, 5, and 10 mM of gemfibrozil for 4 days The morphologic changes were evaluated by three blinded observers. Their reports were matched and collated.

RESULTS

The cultured skin in the presence of gemfibrozil showed cell crowding of keratinocytes in the lower part of the epidermis, indicating epidermal hyperplasia and increased proliferation. Intercellular edema with the formation of small cavities in the epidermis, intracellular edema, and vacuolar alteration of keratinocytes in the upper portion of the epidermis were also observed. The intensity of these changes tended to parallel the gemfibrozil concentration. Some dermo-epidermal detachments did not correlate with the gemfibrozil concentration, but rather with tissue characteristics peculiar to each explant.

CONCLUSIONS

The morphologic changes caused by gemfibrozil to normal human skin were not characteristic of psoriasis, and included intracellular and intercellular edema in the upper portion of the epidermis and cell crowding, indicating epidermal hyperplasia in the lower portion of the epidermis. The present experimental study gives further support to the hypothesis that hypolipidemic drugs cause an initial break in the barrier function of the epidermis, followed by a physiologic epidermal response, aimed at barrier restoration. This rather nonspecific stimulus to epidermal proliferation may trigger psoriasis in predisposed patients.

UVB radiation affects the mobility of epidermal growth factor receptors in human keratinocytes and fibroblasts

Growth factor receptors transmit biological signals for the stimulation of cell growth in vitro and in vivo and their autocrine stimulation may be involved in tumorigenesis. It is therefore, of great value to understand receptor reactions in response to ultraviolet (UV) light which certain normal human cells are invaribly exposed to during their growth cycle. UV irradiation has recently been shown to deplete antioxidant enzymes in human skin. The aims of the present study were a) to compare the lateral mobility of epidermal growth factor receptors (EGF-R) in cultured human keratinocytes and human foreskin fibroblasts, b) to investigate effects of ultraviolet B radiation on the mobility of EGF-R in these cells, and c) study the response of EGF-R on addition of antioxidant enzymes. The epidermal growth factor receptors were labeled with rhodaminated EGF, the lateral diffusion was determined and the fraction of mobile EGF-R assessed with the fluorescence recovery after photobleaching (FRAP). We found that human keratinocytes display a higher basal level of EGF-R mobility than human skin fibroblasts, viz. with diffusion coefficients (D +/- standard error of the mean, SEM) of 4.2 +/- 0.2 x 10(-10) cm2/s, and 1.8 +/- 0.2 x 10(-10) cm2/s, respectively. UVB-irradiated fibroblasts showed an almost four-fold increase in the diffusion coefficient; D was 6.3 +/- 0.3 x 10(-10) cm2/s. The keratinocytes, however, displayed no significant increase in receptor diffusion after irradiation; D was 5.1 +/- 0.8 x 10(-10) cm2/s. In both cell types the percentage of EGF-R fluorescence recovery after photobleaching, i.e. the fraction of mobile receptors, was significantly increased after irradiation. In keratinocytes it increased from 69% before irradiation to 78% after irradiation. Analogous figures for fibroblasts were 61% and 73%. The effect of UVB on fibroblast receptors was abolished by prior addition of superoxide dismutase (SOD) and catalase (CAT). It is concluded that UVB radiation of fibroblasts and keratinocytes can affect their biophysical properties of EGF-R. The finding that addition of antioxidant enzymes prevented the UVB effect in fibroblasts may indicate the involvement of reactive oxygen metabolites.

Potentiation by cholesterol and vitamin D3 oxygenated derivatives of arachidonic acid release and prostaglandin E2 synthesis induced by the epidermal growth factor in NRK 49F cells: the role of protein kinase C

We have previously demonstrated that oxysterols and calcitriol potentiate arachidonic acid (AA) release and prostaglandin (PG) synthesis when NRK cells (fibroblastic clone 49F) are activated by foetal calf serum. As serum is essential for a full oxysterol effect, we hypothesized that these compounds could act on one or more of the events triggered by serum growth factor binding to their specific receptors and leading to PLA2 activation; we showed that the oxysterol effect on AA release is synergistic with, but not fully dependent on, protein kinase C (PKC) activity and Ca2+ ion fluxes, suggesting that oxysterols could effect early events in the cell signalling pathway. In the present paper, we investigated the effect of some oxysterols and calcitriol on epidermal growth factor (EGF)-induced AA release and PGE2 synthesis in NRK cells. The clear potentiation of EGF effect by most of the oxygenated sterols--chiefly when polyoxidized--cannot be explained by a modification of EGF high affinity binding site number which was only moderately increased after a 4 h incubation of cells with these compounds, and moreover was not related to the ability of a given oxysterol to increase PLA2 activity; whatever the compound, the dissociation constant (Kd) of either a high or low affinity binding site was unchanged (respectively, 3.5 x 10(-11) M and 4.4 x 10(-10) M). Genistein, a known inhibitor of EGF receptor tyrosine kinase, changed neither the EGF effect on AA release nor its potentiation by oxysterol, whereas it inhibited PGE2 synthesis in both situations. PKC activation by phorbol ester TPA increased the effect of EGF alone as well as the oxysterol potentiating effect, whereas PKC down-regulation strongly decreased both of these effects, showing that both are dependent on PKC activity. Nevertheless staurosporine, a PKC inhibitor, did not reproduce the effects of PKC down-regulation on EGF activation: stimulatory when AA release was induced by EGF alone, inhibitory when AA release is induced by TPA alone, this compound did not modify the oxysterol potentiating effect. In conclusion, the potentiating effect of oxysterols on AA release seems to be exerted downstream to the growth factor receptor (as demonstrated here with EGF) and probably at the PKC level, but not exclusively.

Effect of hydrostatic pressure and cholesterol depletion on the expression of a tumor-associated antigen

The molecular events related to the expression of three tumor-associated epitopes, Ca-MOv17, Ca-MOv18 and Ca-MOv19 have been addressed. The epitopes are carried by a 38-kDa glycoprotein (gp38), recently cloned and identified as a human folate-binding protein. They were found to be coexpressed on the surface of the ovarian carcinoma cell line OVCA432, while they are not coordinately expressed on other adenocarcinoma cell lines (IGROV1, HT-29). This lack of coexpression was investigated from a molecular point of view. We studied three carcinoma cell lines, characterized by a different reactivity with the three relevant monoclonal antibodies MOv17, MOv18 and MOv19. The epitope expression was examined after modifying the membrane properties by using hydrostatic pressure and/or the variation of cholesterol content. Measurement of the expression after cell labelling by mAbs was performed by indirect immunofluorescence, using both fluorescence microscopy and flow cytometry. At variance with HT-29 cells, treatment of ovarian carcinoma IGROV1 cells with hydrostatic pressure failed to exert any effect. On IGROV1, instead, cholesterol depletion affected the expression Ca-MOv17, increasing, in the indirect immunofluorescence tests, the proportion of positive cells from 0 to 66 +/- 9%. Moreover, restoring the cholesterol content of the plasma membrane did not reverse the induced epitope expression. In parallel, immunoprecipitation experiments confirmed that, on IGROV1 surface, gp38 was recognized by all three mAbs. The data presented suggest that in IGROV1 cells the selective lacking of the epitope expression is related to the physical state of the plasma membrane. An explanation is provided by the model of membrane microdomains in which epitope expression may be influenced by the cholesterol level of different plasma membrane regions.

Epidermal growth factor induces terminal differentiation in human epidermoid carcinoma cells

Previous studies have reported that the proliferation of A431 cells, a human squamous cell carcinoma cell line, was stimulated by picomolar epidermal growth factor (EGF) but inhibited by nanomolar EGF. This biphasic dose-response phenomenon is not observed in normal human epithelial cells where nanomolar EGF is usually mitogenic. We have examined the effects of inhibitory and stimulatory concentrations of EGF on the growth and differentiation of A431 cells. In the presence of 100 pM EGF, A431 cells showed a mild increase in growth rate (129% of control) compared to cells grown in the absence of EGF. At 10 nM EGF, growth inhibition to 63% of control was observed. EGF at 10 nM stimulates a twofold increase both in cornified envelope formation and in epidermal transglutaminase activity, suggesting that high concentrations of EGF induce terminal differentiation in A431 cells. Mitogenic concentrations of EGF (100 pM) had no significant effect on these differentiation markers. Chronic exposure of A431 cells to 20 or 50 nM EGF resulted in EGF-resistant A431 variants that are neither growth arrested nor induced to terminally differentiate by 10 nM EGF. Removal of EGF from the growth medium of the EGF-resistant cells resulted in the reversion of these cells back to the wild-type A431 biphasic response pattern within 2 weeks. Our results suggest that A431 cells have the capacity to non-mutatively alter their response pattern to EGF in vitro to maintain themselves in a state of optimum proliferation and away from terminal differentiation.

An immunofluorescence study of the calcium-induced coordinated reorganization of microfilaments, keratin intermediate filaments, and microtubules in cultured human epidermal keratinocytes

Indirect immunofluorescence microscopy has been used to investigate the coordinated reorganization of microtubules, microfilaments, and keratin intermediate filaments in cultured human epidermal keratinocytes following a switch from low-Ca++ (0.15 mM) medium to high-Ca++ (1.05 mM) medium. A dramatic reorganization occurs concurrently in the three major cytoskeletal components shortly after the calcium switch. The most prominent features are the alignment of keratin filaments at the plasma membranes of apposed cells, the induction of microfilament rings, the restriction of microtubules to the area within the boundaries of the microfilament rings, and the alignment of actin bundles at cell borders. Additional changes are observed in terminally differentiated cells. This is the first report that describes simultaneous changes in the organization of the three major cytoskeletal components of epidermal keratinocytes. Cytochalasin D and demecolcine (colcemid) studies were performed to determine whether the organization of microtubules, microfilaments, and keratin filaments, as well as the calcium-induced reorganization of these cytoskeletal elements, may be dependent on the existence of structural relationships between them. These studies demonstrate that the disruption of microfilaments results in the formation of a latticelike keratin network, with a close association of actin and keratin being maintained. The formation of keratin filament alignments occurs even in the absence of intact microfilaments. In addition, it was found that the Ca(++)-induced reorganization of microfilaments and keratin filaments is not dependent on an intact microtubule network. Furthermore, the reorganization of actin into concentric rings can be dissociated from changes in the organization of keratin filaments.

Regulation of low-density lipoprotein receptor expression during keratinocyte differentiation

Transformed keratinocytes (i.e., SCC-4, SCC-15, SCC-12F2, SVK14) or normal keratinocytes which differ in their differentiation program, were used to study the regulation of low-density lipoprotein (LDL)-receptor expression. The capacity of the cells to differentiate was modulated by changing the extracellular calcium concentration. We now demonstrate that LDL-receptor expression in normal and transformed keratinocytes depends on the cell type and one or more levels of regulatory control. Cells express elevated mRNA levels when cultured under low Ca++ (proliferating) conditions. In contrast, SV40-transformed keratinocytes express decreased message under similar condition. In addition, LDL-receptor protein is decreased in transformed cells when extracellular Ca++ is increased (1.6 mM) to stimulate differentiation; the decrease in protein is comparable to the decrease in mRNA expression. Under the same conditions, normal keratinocytes show markedly decreased LDL-receptor protein relative to the decrease in mRNA. Incubation with LDL-cholesterol decreases the number of cell surface-exposed LDL-receptors. The LDL-receptor in fibroblasts is regulated differently from SCC-4 cells. The addition of LDL-cholesterol to fibroblasts causes decreased LDL-receptor mRNA and protein expression whereas SCC-4 cells show the opposite effect. The addition of cholesterol in non-lipoprotein form causes decreased LDL-receptor mRNA and protein expression in both cell types. These results suggest another, yet unidentified, regulatory mechanism that affects LDL-receptor expression in these two cell types.

Regulation of epidermal growth factor receptor expression in normal and transformed keratinocytes

Transformed keratinocytes (SCC-4, SCC-15, SCC-12F2, SVK14) or normal keratinocytes which differ in their differentiation programme were used to study the regulation of EGF-receptor expression. The capacity of the cells to differentiate was modulated by changing the extracellular calcium concentration. We were able to demonstrate that EGF-receptor expression in normal and transformed keratinocytes depends upon the cell type and one or more levels of regulatory control. At the DNA level, EGF-receptor gene amplification occurred in poorly differentiating cells. At the mRNA level, cells showing EGF-receptor gene amplification expressed elevated mRNA and protein levels when cultured under low Ca2+ conditions. Cells not exhibiting EGF-receptor gene amplification showed equal mRNA expression, regardless the Ca2+ concentration in the culture medium. At the protein level, EGF-receptor protein was decreased in cells exhibiting EGF-receptor gene amplification when extracellular Ca2+ was increased (to 1.6 mM) to stimulate differentiation, the decrease in protein being comparable to mRNA expression. Cells not exhibiting EGF-receptor gene amplification showed equal protein expression, regardless of the Ca2+ concentration in the culture medium. Under the same conditions, SV40 transformed keratinocytes showed equal mRNA but elevated protein expression in cells grown under low Ca2+ conditions. At the membrane level, normal keratinocytes and SCC-17F2 cells showed elevated numbers of cell surface exposed EGF-receptors in cells grown under low Ca2+ conditions, but equal mRNA and protein expression.(ABSTRACT TRUNCATED AT 250 WORDS)

The lovastatin-treated rodent: a new model of barrier disruption and epidermal hyperplasia

Recent studies have linked epidermal cholesterol synthesis with maintenance of the permeability barrier. To assess directly the importance of cholesterol synthesis, we applied lovastatin, a potent inhibitor of cholesterol synthesis, to hairless mouse skin. Transepidermal water loss (TEWL) began to increase after four to six daily applications. Co-application of cholesterol blocked the expected increase in TEWL, demonstrating the importance of cholesterol for development of the lesion. The histology of lovastatin-treated skin revealed epidermal hyperplasia, accompanied by accelerated DNA synthesis. Whereas cholesterol synthesis initially was reduced in lovastatin-treated epidermis, with further treatment cholesterol synthesis normalized, while fatty acid synthesis accelerated greatly. Although the total free sterol content of lovastatin-treated epidermis remained normal, the fatty acid content increased coincident with barrier disruption. Finally, morphologic abnormalities of both lamellar body structure and their deposited, intercellular contents occurred coincident with the emerging biochemical abnormalities. Thus, the abnormal barrier function in this model can be ascribed to an initial inhibition of epidermal sterol synthesis followed by an alteration in cholesterol and fatty acid synthesis, leading to an imbalance in stratum corneum lipid composition and abnormal membrane bilayer structure.

Lipid modulators of epidermal proliferation and differentiation

The importance of lipids within the skin as components of the permeability barrier has been appreciated for quite some time. However, the more recent work reviewed here suggests numerous alternative bioactive functions for lipid molecules within the skin and other tissues. The precise roles of lipids in epidermal proliferation and differentiation have only begun to be studied and are far from being defined.

The EGF/TGF alpha receptor in skin

In responsive cells, all known effects of epidermal growth factor (EGF), transforming growth factor alpha (TGF alpha), and related proteins are mediated through binding to a specific membrane receptor. The EGF/TGF alpha receptor is a single-chain glycoprotein (1186 amino acids) containing three functional domains: 1) an extracellular, glycosylated portion that binds EGF; 2) a small transmembrane portion; and 3) a cytoplasmic portion that has the intrinsic tyrosine kinase activity and multiple sites that can be phosphorylated. When EGF binds to the receptor its intrinsic tyrosine kinase is activated, resulting in increased phosphorylation of intracellular tyrosine residues both on the receptor (autophosphorylation sites) and on exogenous proteins involved in regulating cellular functions. Site-specific mutagenesis has established that the tyrosine-kinase activity of the receptor is essential for nearly all of the effects of EGF including its ability to elevate cellular calcium levels and to induce DNA synthesis. The binding of EGF and the kinase activity of the receptor are both regulated by the phosphorylation of the receptor on specific threonine/serine sites catalyzed by other protein kinases. Specific lipids such as sphingosine also can regulate kinase activity. Tyrosine-specific phosphoprotein phosphatases and perhaps proteases must be important in terminating the cellular response to EGF. In human skin, the response to EGF/TGF alpha is determined by the location and number of receptors and is modulated by processes affecting the binding affinity, internalization, and tyrosine-kinase activity of the receptor. Specific patterns of EGF binding and of immunoreactive receptors characterize normal growth and differentiation and these are altered during the abnormal growth and differentiation associated with diseases such as psoriasis, viral infections, neoplasms, and paraneoplastic syndromes. It is not clear if the altered patterns reflect the consequence of the disease or are the cause of the disease. As a cause, the EGF receptor may have undetected point mutations that result in internalization and degradation defects, aberrant phosphorylation, and dephosphorylation or abnormal glycosylation.

Variations of membrane cholesterol alter the kinetics of Ca2(+)-dependent K+ channels and membrane fluidity in vascular smooth muscle cells

The patch-clamp technique and fluorescence polarization analysis were used to study the dependence of Ca2(+)-dependent K+ channel kinetics and membrane fluidity on cholesterol (CHS) levels in the plasma membranes of cultured smooth muscle rabbit aortic cells. Mevinolin (MEV), a potent inhibitor of endogenous CHS biosynthesis was used to deplete the CHS content. Elevation of CHS concentration in the membrane was achieved using a CHS-enriching medium. Treatment of smooth muscle cells with MEV led to a nearly twofold increase in the rotational diffusion coefficient of DPH (D) and to about a ninefold elevation of probability of the channels being open (Po). The addition of CHS to the cells membrane resulted in a nearly twofold decrease in D and about a twofold decrease in Po. Elementary conductance of the channels did not change under these conditions. These data suggest that variations of the CHS content in the plasma membrane of smooth muscle cells affect the kinetic properties of Ca2(+)-dependent K+ channels presumably due to changes in plasma membrane fluidity. Our results give a possible explanation for the reported variability of Ca2(+)-dependent K+ channels kinetics in different preparations.

Proliferation and differentiation of human squamous carcinoma cell lines and normal keratinocytes: effects of epidermal growth factor, retinoids, and hydrocortisone

Exposure of squamous carcinoma cell (SCC) lines, exhibiting high levels of epidermal growth factor (EGF) receptors, to EGF for 6 d caused a dose-dependent inhibition of cell proliferation. This EGF-induced inhibition of cell proliferation occurred under both low (0.06 mM) and normal (1.6 mM) Ca2+ concentrations. Furthermore, the extent of EGF-induced inhibition of cell proliferation seemed to be independent of the number of EGF-receptors. This conclusion is based on the notion that the various SCC lines exhibited an increasing number of EGF receptors accompanied by a decreasing ability to differentiate, whereas no relationship was observed with the EGF-induced inhibition of cell proliferation in these cell lines. Retinoids caused also a dose-dependent inhibition of cell proliferation. The effects of EGF and retinoids were additive, indicating that different regulatory mechanisms are involved. On the other hand, hydrocortisone caused a stimulation of SCC-proliferation, also independent of EGF. In contrast to SCC cells, EGF did not affect significantly the rate of proliferation of normal keratinocytes. However, the simultaneous addition of EGF and hydrocortisone resulted in a significant increase in the rate of keratinocyte proliferation only in cells grown under normal calcium conditions. Differentiation capacity of normal keratinocytes and SCC lines was not affected by EGF. Furthermore, the retinoid-induced decrease and hydrocortisone-induced increase of competence of cells to form cornified envelopes was not affected by EGF. These observations suggest that the action of retinoids and hydrocortisone on both cell proliferation and cell differentiation occurs independently of EGF receptors.

Lateral mobility of plasma membrane lipids in normal and transformed keratinocytes

In this study we have examined possible differentiation-dependent modulations in plasma membrane lipid properties in normal keratinocytes, SV-40 transformed keratinocytes (SVK14) and a number of squamous carcinoma (SCC) cells. In normal keratinocytes the lateral diffusion coefficient of plasma membrane lipids (D) differs significantly for cells cultured permanently under low and normal Ca2+-conditions (5.16 x 10(-9) and 3.27 x 10(-9) cm2/s, respectively). When differentiation is induced by exposing low Ca2+-cultured cells to normal Ca2+ concentrations D increases to 7.07 x 10(-9) cm2/s during the initial hours of differentiation followed by a gradual sustained decrease to values also observed in cells cultured permanently under normal Ca2+-conditions. In SCC and SVK14 cells a similar initial transient increase in lateral lipid mobility is observed upon initiation of differentiation, but, in contrast to normal keratinocytes, no sustained decrease in D is seen upon prolonged culturing under normal Ca2+ conditions. The results indicate that the deficiency of the transformed cells to respond to Ca2+-induced differentiation might involve transformation-dependent alterations in membrane structure and function.