Imiquimod-induced interleukin-1 alpha stimulation improves barrier homeostasis in aged murine epidermis

In response to acute disruption of the permeability barrier of aged mammals there is a diminished capacity for barrier recovery, analogous to other aged organs when stressed. Acute barrier disruption increases levels of epidermal cytokines, and cytokines are known regulators of keratinocyte mitogenesis, as well as lipid synthesis in extracutaneous tissues. Underlying the sluggish barrier recovery in aged skin are diminished mRNA and protein levels for the interleukin-1 cytokine family, and its receptors. To further elucidate the role of the interleukin-1 family of cytokines in the barrier repair response, cytokine production was stimulated in aged murine skin with topical imiquimod application. Imiquimod accelerated barrier recovery after acute insults to aged and young skin. These functional results correlated temporally with increased interleukin-1 alpha production in the epidermis following topical imiquimod administration to murine skin. Furthermore, intracutaneous injections of interleukin-1 alpha accelerated barrier recovery in aged mice. Finally, we showed that interleukin-1 alpha added to cultured human keratinocytes stimulates epidermal lipid synthesis. These studies provide further evidence for the role of reduced interleukin-1 alpha signaling in the decline of permeability barrier function in aged skin, and point to the potential use of cytokine augmentation in barrier dysfunction of the aged.     

Cutaneous barrier repair and pathophysiology following barrier disruption in IL-1 and TNF type I receptor deficient mice

Disruption of the permeability barrier elicits a homeostatic repair response which rapidly restores barrier function while repeated barrier perturbation results in cutaneous pathology. In response to barrier disruption there is a marked increase in epidermal TNF-alpha and IL-1 production. To determine the potential role of TNF and IL-1 in mediating the cutaneous changes that occur following barrier disruption we compared the kinetics of barrier recovery and the degree of epidermal hyperplasia and cutaneous inflammation in TNF type I (p55) receptor and IL-1 receptor type I (p80) deficient mice. No abnormalities in epidermal morphology were observed with light or electron microscopy in receptor deficient mice. Under baseline conditions epidermal barrier function was unchanged in receptor deficient mice. Following barrier disruption the kinetics of barrier recovery were similar in control vs TNF receptor deficient mice regardless if the barrier was disrupted by acetone treatment, SDS treatment, or tape stripping. In contrast, barrier recovery was slightly but significantly accelerated regardless of the method of barrier disruption in IL-1 receptor deficient mice. The degree of epidermal hyperplasia and cutaneous inflammation following repeated barrier disruption was similar in control, TNF receptor, and IL-1 receptor deficient mice. The present study demonstrates that barrier recovery is not delayed and the degree of epidermal hyperplasia and inflammation are not altered in either TNF receptor or IL-1 receptor deficient mice, indicating that neither TNF nor IL-1 alone are essential for either barrier repair or the cutaneous pathology induced by barrier perturbation. Whereas the increase in IL-1 following barrier disruption may delay components of the repair response, whether either TNF-alpha or IL-1 regulate aspects of the homeostatic response remains unresolved.     

IL-1α stimulation restores epidermal permeability and antimicrobial barriers compromised by topical tacrolimus

In a previous study, we showed that barrier recovery was delayed after acute barrier disruption in the skin treated with topical calcineurin inhibitors. Tacrolimus decreases lipid synthesis and the expressions of antimicrobial peptide (AMP) and IL-1α in the epidermis. IL-1α is an important cytokine for improving barrier function, lamellar body (LB) production, and lipid synthesis in keratinocytes (KCs). We aimed to evaluate whether IL-1α stimulation could restore the barrier dysfunction observed in tacrolimus-treated skin. Topical imiquimod, an IL-1α inducer, restored the epidermal permeability barrier recovery that had been inhibited by tacrolimus treatment in human (n=15) and murine (n=10) skins, and improved stratum corneum integrity by restoring corneodosmosomes in murine skin (n=6). Imiquimod co-applied on the epidermis resulted in an increase in the production of LB and three major lipid synthesis-related enzymes, and in the expressions of mBD3, CRAMP, and IL-1α (n=5). Furthermore, intracutaneous injection of IL-1α restored permeability barrier recovery (n=6). In IL-1 type 1 receptor knockout mice, topical imiquimod was unable to restore permeability barrier recovery after tacrolimus treatment (n=21). In conclusion, IL-1α stimulation induced positive effects on epidermal permeability and antimicrobial barrier functions in tacrolimus-treated skin. These positive effects were mediated by an increase in epidermal lipid synthesis, LB production, and AMP expression.     

Topical mevalonic acid stimulates de novo cholesterol synthesis and epidermal permeability barrier homeostasis in aged mice

Extracellular lipids of the stratum corneum, which are composed of cholesterol, fatty acid, and ceramides, are essential for the epidermal permeability barrier function. With damage to the barrier, a decreased capacity for epidermal lipid biosynthesis in aged epidermis results in an impaired repair response. Mevalonic acid is an intermediate after the rate-limiting step in cholesterol biosynthesis, which is catalyzed by 3-hydroxy-3-methylglutaryl coenzyme A reductase. In the present study, we investigated the effect of topical mevalonic acid on the murine epidermal permeability barrier function, comparing it with that of cholesterol. Topical treatment with acetone caused linear increases in transepidermal water loss, in proportion to the number of treatments more rapidly in aged mice than in young mice. Administration of mevalonic acid on aged murine epidermis enhanced its resistance against damage and the recovery rate of barrier function from acute barrier disruption. In contrast, although cholesterol also had the same effect, it required a much higher amount than mevalonic acid. In young mice, neither mevalonic acid nor cholesterol had any effect on resistance against acetone damage nor the recovery rate from acetone damage. In the skin of mice topically administered with mevalonic acid, stimulation of cholesterol synthesis and 3-hydroxy-3-methylglutaryl coenzyme A reductase activity were both observed, whereas none was seen with stimulation by equimolar cholesterol. These data indicate that a topical application of mevalonic acid enhances barrier recovery in aged mice, which is accompanied by not only acceleration of cholesterol synthesis from mevalonic acid but also stimulation of the whole cholesterol biosynthesis.     

Barrier disruption increases gene expression of cytokines and the 55 kD TNF receptor in murine skin

Abstract The signalling mechanisms that regulate epidermal permeability barrier homeostasis arc not known. Previous Northern blot analysis showed that both acute and chronic barrier disruption increase mRNA levels of several cytokines in murine epidermis. To further characterize the epidermal response to barrier abrogation, we used more sensitive, multi-probe RNasc protection assays to measure the mRNA levels of additional cytokines. as well as cytokine receptors in acute and chronic models of barrier disruption. Normal mouse epidermis expressed interleukin (IL)-lα, interferon-γ (IFN-γ). tumor necrosis factor-α (TNF-α) and IL-6 mRNAs. Following tape-stripping, only the mRNA levels for TNF-α, IL-lα, IL-lβ and IL-6 increased at 2.5 and 7 h, and returned toward normal levels by IX h. No mRNAs encoding TNF-β. IL-2, IL-3. IL-4 or IL-5, were detected in the epidermis either under basal conditions or after tape-stripping. Similarly, in a chronic model, essential fatty acid deficiency, epidermal levels of TNF-α, IL-lα, IL-lβ and IL-6 mRNAs, but not IFN-γ mRNA. were elevated over controls; and again, mRNAs for the remaining probed cytokines were not detected. In contrast, in the dermis. only IL-Iβ mRNA levels increased 2.5 h after tape-stripping, and remained elevated at I8 h. mRNAs encoding the IL-1 (p60), IFN-γ ami IL-6 receptors were present in epidermis, but their levels remained unchanged following either acute or chronic barrier disruption. In contrast, epidermal TNF (p55) receptor mRNA levels were increased by 87% (P<0.01) at 2.5 h, returned to control levels at 7 h and were increased by 68% (p<0.03) at 18 h after tape-stripping. The increase at 2 h was confirmed by Northern blot analysis and was not prevented by latex occlusion performed immediately after tape-stripping. mRNAs for the IL-I (p80) receptor and TNF (p75) receptor were not detected in epidermis. Low levels of TNF (p55) receptor mRNA were present in the dermis. and they remained unchanged after tape-stripping. The presence of specific receptor mRNAs in the epidermis and dermis suggests that these tissues are capable of responding in an autocrine and/or paracrine fashion to the cognate cytokines. These results suggest that epidermal cytokines produced after barrier disruption may initiate a cytokine cascade which could regulate cytokine and cytokine receptor production and/or inflammatory responses.     

Localization of epidermal sphingolipid synthesis and serine palmitoyl transferase activity: alterations imposed by permeability barrier requirements

Sphingolipids, the predominant lipid species in mammalian stratum corneum play, a central role in permeability barrier homeostatis. Prior studies have shown that the epidermis synthesizes abundant sphingolipids, a process regulated by barrier requirements, and that inhibition of sphingolipid synthesis interferes with barrier homeostasis. To investigate further the relationship between epidermal sphingolipid metabolism and barrier function, we localized sphingolipid synthetic activity in murine epidermis under basal conditions, and following acute (acetone treatment) or chronic (essential fatty acid deficiency, EFAD) barrier perturbation, using dithiothreitol and/or the staphylococcal epidermolytic toxin to isolate the lower from the outer epidermis. Under basal conditions, both the activity of serine palmitoyl transferase (SPT), the rate-limiting enzyme of sphingolipid synthesis, and the rates of³H-H₂O incorporation into sphingolipids were nearly equivalent in the lower and the outer epidermis. Following acute barrier perturbation, SPT activity increased significantly in both the lower (35%;P < 0.05) and the outer epidermal layers (60%;P < 0.01). The rates of³H-H₂O incorporation into each major sphingolipid family, including ceramides, glucosylceramides and sphingomyelin, increased significantly in both the lower and the outer epidermis of treated flanks after acute barrier disruption. Finally, SPT activity was modestly elevated (20%;P < 0.01) in the lower but not in the outer epidermis of EFAD animals. These studies demonstrate the ability of both lower and outer epidermal cells to generate sphingolipids, and that permeability barrier homeostatic mechanisms appear to differentially regulate SPT acitivity and sphingolipid synthesis in the lower and the outer epidermis in response to acute and chronic barrier perturbation. Moreover, intraepidermal sites of sphingolipid synthesis displayed distinctive differences in the localization and alterations of cholesterologenesis in response to equivalent barrier perturbations.     

IL‐6 Stimulates but is not essential for stratum corneum formation and permeability barrier development during gestation

Please cite this paper as: IL‐6 Stimulates but is not essential for stratum corneum formation and permeability barrier development during gestation. Experimental Dermatology 2010; 19 : e31–e36. Abstract: The regulation of epidermal ontogenesis is a complex process. Previous studies have shown that cytokines (IL‐1, TNFα and IL‐6) regulate permeability barrier homeostasis in adult mice. Recently, we reported that IL‐1 and TNFα accelerate stratum corneum (SC) formation and permeability barrier development in foetal rodents. Here, we determined whether IL‐6 also regulates SC formation and permeability barrier development during late gestation. Using a rat skin explant model, we demonstrated that IL‐6 accelerates permeability barrier formation in a time‐ and dose‐dependent fashion. This acceleration of barrier formation is attributable to (a) accelerated lamellar membrane maturation, (b) formation of a multi‐layer SC and (c) enhanced expression of epidermal differentiation markers. When comparing epidermis of IL‐6‐deficient (knockout mice) and wild‐type foetal mice at days 16–18, we could not detect any abnormalities in either SC formation or the expression of differentiation markers in knockout (KO) mice. In parallel, the basal expression levels of IL‐6 mRNA in epidermis and IL‐6 protein in amniotic fluid were very low, with only a minimal change in IL‐6 receptor mRNA levels in epidermis of days 16–22 foetal mice. These low IL‐6 levels may account, at least in part, for the absence of epidermal abnormalities in IL‐6 KO mice. In conclusion, exogenous IL‐6 accelerates epidermal ontogenesis, but it is not essential for normal epidermal maturation.     

Iontophoresis and sonophoresis stimulate epidermal cytokine expression at energies that do not provoke a barrier abnormality: lamellar body secretion and cytokine expression are linked to altered epidermal calcium levels

We performed this study to identify whether the expression of epidermal cytokines is altered by changes in epidermal calcium content, independent of skin barrier disruption. Iontophoresis and sonophoresis with the energies that do not disrupt the skin barrier, but induce changes in the epidermal calcium gradient, were applied to the skin of hairless mice. Immediately after iontophoresis and sonophoresis, immersion in a solution containing calcium was carried out, and iontophoresis in either high- or low-calcium solutions was performed. The biopsy specimens were taken for real-time quantitative RT-PCR to detect changes in mRNA level of interleukin-1alpha (IL-1alpha), tumor necrosis factor-alpha (TNF-alpha), and transforming growth factor-beta in the epidermis and for immunohistochemical stain with primary antibodies to IL-1alpha and TNF-alpha. The expression of each cytokine mRNA increased in the epidermis treated with iontophoresis and sonophoresis compared to a nontreated control as well as in tape-stripped skin used as a positive control and was lower after immersion in a high-calcium solution than in low-calcium solution. IL-1alpha and TNF-alpha immunohistochemical protein staining increased with iontophoresis at low calcium. These studies suggest that changes in epidermal calcium can directly signal expression of epidermal cytokines in vivo, independent of changes in barrier function.     

Calcium and potassium inhibit barrier recovery after disruption, independent of the type of insult in hairless mice

Abstract Disruption of the cutaneous permeability barrier induces metabolic responses in the epidermis which result in barrier recovery. Barrier disruption by either solvent treatment or tape stripping results in the loss of the epidermal calcium gradient. Previous studies in acetone treated hairless mice have shown that maintaining this calcium gradient inhibits barrier repair, suggesting that alterations in the epidermal calcium concentration may be an important signal for barrier homeostasis. In the present study, we show that in hairless mice disruption of the barrier by treatment with the detergent. SDS, also results in the loss of the calcium gradient, as demonstrated both semi-quantitatively with ultrastructural cytochemical localization and quantitatively using proton induced X-ray emission (PIXE). Additionally, immersion in calcium containing solutions delays barrier repair after either detergent (SDS treatment) or mechanical (tape stripping) disruption of the barrier, as reported previously for acetone treated skin. These results indicate that barrier disruption, regardless of the insult, induces changes in the epidermal calcium gradient which may play an important role in signaling the metabolic changes required for barrier homeostasis.     

Expression of voltage-gated calcium channel subunit alpha1C in epidermal keratinocytes and effects of agonist and antagonists of the channel on skin barrier homeostasis

Recent studies demonstrated that skin surface electric conditions affect epidermal permeability barrier homeostasis. These results suggest the existence of voltage sensor on the keratinocytes of the epidermis. On the contrary, specific blockers of the voltage-gated calcium channel (VGCC) also affect epidermal barrier homeostasis, but the existence and function of the channel has not been determined. We demonstrated here immunohistochemically the expression of the main subunit of the L-type VGCC, alpha1C, which alone has a calcium channel function, in mouse and human epidermis. Immunostaining, RT-PCR, and Western blotting were carried out to detect the channel protein. Messenger RNA of alpha1C was also detected in mouse epidermis and human keratinocyte culture by RT-PCR. We also evaluated the function of the channel in the cultured human keratinocytes. Previously, we demonstrated that influx of calcium ion into epidermal keratinocytes delayed the barrier recovery after barrier disruption and topical application of calcium channel blocker accelerated the barrier recovery. In this study, topical application of nifedipine and R-(+)-BAY K8644 after tape stripping of hairless mice accelerated the barrier repair rate while application of S-(-)-BAY K8644 delayed the barrier recovery. These results suggest that the VGCC exists on epidermal keratinocytes and plays an important role in skin barrier homeostasis.     

Barrier function coordinately regulates epidermal IL-1 and IL-1 receptor antagonist mRNA levels

Abstract Disruption of the cutaneous permeability barrier increases mRNA levels for TNF, GM-CSF, FL-1 alpha, and IL-1 beta in the epidermis. We have hypothesized that the cylokines mediate the changes in lipid and DNA synthesis which occur following barrier disruption. To further characterize the cytokine response to barrier abrogation, we examined the levels of epidermal IL-Ira mRNA in two acute models and one chronic model in the hairless mouse. IL-Ira mRNA levels increased shortly after acute disruption of the barrier with acetone, reached a peak at 3–4 h after treatment, and returned to control levels by 8h. These changes in mRNA levels parallel those which occur for IL-1 alpha and beta. Furthermore, IL-Ira mRNA levels were elevated 5-fold and 4-fold, at 2.5 h and 4 h, respectively, following tape-stripping, a second acute model of barrier disruption. Finally, IL-Ira mRNA levels were elevated 2.5-fold in the epidermis of EFAD mice, which have a chronic barrier defect. Thus, the cutaneous response to barrier disruption includes mechanisms which increase IL-I and IL-Ira mRNA levels in a coordinate manner. The net result provides a regulatory mechanism for controlling the biological effects of increased IL-1 production.     

Hyaluronan-CD44 interaction stimulates keratinocyte differentiation, lamellar body formation/secretion, and permeability barrier homeostasis

In this study we investigated whether hyaluronan (HA)-CD44 interaction influences epidermal structure and function. Our data show that CD44 deficiency is accompanied by reduction in HA staining in CD44 knockout (k/o) mouse skin leading to a marked thinning of epidermis versus wild-type mouse skin. A significant delay in the early barrier recovery (following acute barrier disruption) occurs in CD44 k/o versus wild-type mouse skin. To assess the basis for these alterations in CD44 k/o mouse epidermis, we determined that differentiation markers are greatly reduced in the epidermis of CD44 k/o versus wild-type mice, while conversely HA binding to CD44 triggers differentiation in cultured human keratinocytes. CD44 downregulation (using CD44 small interfering RNAs) also inhibits HA-mediated keratinocyte differentiation. Slower barrier recovery in CD44 k/o mice could be further attributed to reduced lamellar body formation, loss of apical polarization of LB secretion, and downregulation of cholesterol synthesis. Accordingly, HA-CD44 binding stimulates both LB formation and secretion. Together, these observations demonstrate new roles for HA-CD44 interaction in regulating both epidermal differentiation and lipid synthesis/secretion, which in turn influence permeability barrier homeostasis. HA-CD44 signaling could comprise a novel approach to treat skin disorders characterized by abnormalities in differentiation, lipid synthesis, and/or barrier function.     

Effect of endothelial nitric oxide synthase on epidermal permeability barrier recovery after disruption

Background We previously demonstrated that neuronal nitric oxide synthase (nNOS) in epidermal keratinocytes is associated with epidermal permeability barrier homeostasis. Objectives In the present study, we examined the contributions of inducible nitric oxide synthase (iNOS) and endothelial nitric oxide synthase (eNOS) to epidermal permeability barrier homeostasis. Methods We measured the barrier recovery rate after tape stripping of the epidermis of iNOS and eNOS knockout mice, and carried out electron‐microscopic observation of the epidermis after acetone treatment. Results The barrier recovery rate of eNOS knockout mice was significantly faster than that of the wild‐type control, while no significant difference was observed between iNOS knockout mice and wild‐type mice. Electron‐microscopic observation at 1 h after acetone treatment indicated that barrier recovery of both nNOS and eNOS mice was faster than that of wild‐type mice, and lamellar body secretion was accelerated in both types of knockout mice. Conclusions These results suggested that both nNOS and eNOS play roles in epidermal barrier homeostasis and lamellar body secretion.     

The changes of epidermal calcium gradient and transitional cells after prolonged occlusion following tape stripping in the murine epidermis.

Disruption of the epidermal permeability barrier causes an immediate loss of the calcium gradient, and barrier recovery is parallel with the restoration of the calcium gradient in the epidermis. Artificial restoration of the barrier function by occlusion with a water vapor-impermeable membrane abrogate the expected increase in lipid synthesis and retard the barrier recovery, as well as block the normalization of the epidermal calcium gradient. To clarify the long-term effects of occlusion after acute barrier perturbation, we studied the calcium distribution and epidermal keratinocytes response after occlusion with a water vapor-impermeable membrane immediately following tape stripping in the murine epidermis. Acute barrier disruption caused an immediate depletion of most calcium ions in the upper epidermis, obliterating the normal calcium gradient. When the skin barrier function was artificially corrected by occlusion, the return of calcium ions to the epidermis was blocked. After 2 h of air exposure or occlusion, the density of epidermal calcium precipitates remained negligible. The transitional cell layers appeared with occlusion, but not or negligibly with air exposure. By 6 h though, calcium precipitates could be seen, the density of the calcium precipitates with occlusion was more sparse than with air exposure. With the air exposure, the thickness of the stratum corneum had normalized and the calcium gradient nearly recovered to normal after 24 h. The longer the occlusion period, the greater was the increase of transitional cells. By 60 h of occlusion, the thickness of the stratum corneum had increased and the transitional cell layers had disappeared, in parallel with the calcium gradient which was almost normalized. These results show that prolonged occlusion of tape-stripped epidermis induced transitional cells and delayed the restoration of the epidermal calcium gradient, the stratum corneum was then restored, transitional cells having disappeared, in parallel with normalization of the epidermal calcium gradient.     

Stimulation of PPARalpha promotes epidermal keratinocyte differentiation in vivo

Our recent studies have demonstrated that PPARalpha activators stimulate differentiation and inhibit proliferation in cultured human keratinocytes and accelerate epidermal development and permeability barrier formation in fetal rat skin explants. As the role of PPARalpha activation in adult epidermis is not known, the aim of this study was to determine if topically applied PPARalpha ligands regulate keratinocyte differentiation in murine epidermis. Topical treatment with PPARalpha activators resulted in decreased epidermal thickness. Expression of structural proteins of the upper spinous/granular layers (involucrin, profilaggrin-filaggrin, loricrin) increased following topical treatment with PPARalpha activators. Furthermore, topically applied PPARalpha activators also increased apoptosis, decreased cell proliferation, and accelerated recovery of barrier function following acute barrier abrogation. Experiments with PPARalpha-/- knockout mice showed that these effects are specifically mediated via PPARalpha. Compared with the epidermis of PPARalpha+/+ mice, involucrin, profilaggrin-filaggrin, and loricrin expression were slightly decreased in PPARalpha-/- mice. Moreover, topical clofibrate treatment did not increase epidermal differentiation in PPARalpha-/- mice. Furthermore, in cultured human keratinocytes we have demonstrated that PPARalpha activators induce an increase in involucrin mRNA levels. We have also shown that this increase in gene expression requires an intact AP-1 response element at -2117 to -2111 bp. Thus, stimulation of PPARalpha stimulates keratinocyte/epidermal differentiation and inhibits proliferation.     

Deficiency of PPARbeta/delta in the epidermis results in defective cutaneous permeability barrier homeostasis and increased inflammation

In cultured human keratinocytes or murine epidermis, peroxisome proliferator-activated receptor beta/delta (PPARbeta/delta) (NR1C2) activators (1) stimulate keratinocyte differentiation; (2) decrease keratinocyte proliferation; (3) accelerate permeability barrier repair; (4) increase epidermal lipid synthesis; and (5) reduce cutaneous inflammation. Since these results suggest that PPARbeta/delta could play an important role in cutaneous homeostasis, we assessed here the skin phenotype of mice deficient in PPARbeta/delta. Gross cutaneous abnormalities were not evident, and both stratum corneum (SC) skin hydration and surface pH were normal. However, the epidermis was thickened and proliferating cell nuclear antigen (PCNA) staining was increased, indicating increased cell proliferation. No change in apoptosis was observed but the expression of differentiation markers, such as filaggrin, involucrin, and loricrin, was slightly increased in PPARbeta/delta(-/-) mice. Although basal permeability barrier function was normal, PPARbeta/delta knockout (KO) mice show a significant delay in barrier recovery rates following acute barrier disruption by either acetone treatment or tape-stripping. Delayed barrier recovery correlated with decreased production and secretion of lamellar bodies (LBs), and with reduced numbers of extracellular lamellar membranes in the SC. Finally, PPARbeta/delta KO mice displayed increased inflammation in response to 12-O-tetradecanoylphorbol-13-acetate (TPA) treatment. Together, these results further demonstrate that PPARbeta/delta in the epidermis: (1) is required for permeability barrier homeostasis; (2) regulates keratinocyte proliferation; and (3) modulates cutaneous inflammation.     

Peroxisome-proliferator-activated receptor (PPAR)-gamma activation stimulates keratinocyte differentiation

Previous studies demonstrated that peroxisome-proliferator-activated receptor (PPAR)-alpha or PPAR-delta activation stimulates keratinocyte differentiation, is anti-inflammatory, and improves barrier homeostasis. Here we demonstrate that treatment of cultured human keratinocytes with ciglitazone, a PPAR-gamma activator, increases involucrin and transglutaminase 1 mRNA levels. Moreover, topical treatment of hairless mice with ciglitazone or troglitazone increases loricrin, involucrin, and filaggrin expression without altering epidermal morphology. These results indicate that PPAR-gamma activation stimulates keratinocyte differentiation. Additionally, PPAR-gamma activators accelerated barrier recovery following acute disruption by either tape stripping or acetone treatment, indicating an improvement in permeability barrier homeostasis. Treatment with PPAR-gamma activators also reduced the cutaneous inflammatory response that is induced by phorbol 12-myristate-13-acetate, a model of irritant contact dermatitis and oxazolone, a model of allergic contact dermatitis. To determine whether the effects of PPAR-gamma activators are mediated by PPAR-gamma, we next examined animals deficient in PPAR-gamma. Mice with a deficiency of PPAR-gamma specifically localized to the epidermis did not display any cutaneous abnormalites on inspection, but on light microscopy there was a modest increase in epidermal thickness associated with an increase in proliferating cell nuclear antigen (PCNA) staining. Key functions of the skin including permeability barrier homeostasis, stratum corneum surface pH, and water-holding capacity, and response to inflammatory stimuli were not altered in PPAR-gamma-deficient epidermis. Although PPAR-gamma activators stimulated loricrin and filaggrin expression in wild-type animals, however, in PPAR-gamma-deficient mice no effect was observed indicating that the stimulation of differentiation by PPAR-gamma activators is mediated by PPAR-gamma. In contrast, PPAR-gamma activators inhibited inflammation in both PPAR-gamma-deficient and wild-type mouse skin, indicating that the inhibition of cutaneous inflammation by these PPAR-gamma activators does not require PPAR-gamma in keratinocytes. These observations suggest that thiazolidindiones and perhaps other PPAR-gamma activators maybe useful in the treatment of cutaneous disorders.     

Co-regulation and interdependence of the mammalian epidermal permeability and antimicrobial barriers

Human epidermis elaborates two small cationic, highly hydrophobic antimicrobial peptides (AMP), beta-defensin 2 (hBD2), and the carboxypeptide cleavage product of human cathelicidin (hCAP18), LL-37, which are co-packaged along with lipids within epidermal lamellar bodies (LBs) before their secretion. Because of their colocalization, we hypothesized that AMP and barrier lipid production could be coregulated by altered permeability barrier requirements. mRNA and immunostainable protein levels for mBD3 and cathelin-related antimicrobial peptide (CRAMP) (murine homologues of hBD2 and LL-37, respectively) increase 1-8 hours after acute permeability barrier disruption and normalize by 24 hours, kinetics that mirror the lipid metabolic response to permeability barrier disruption. Artificial permeability barrier restoration, which inhibits the lipid-synthetic response leading to barrier recovery, blocks the increase in AMP mRNA/protein expression, further evidence that AMP expression is linked to permeability barrier function. Conversely, LB-derived AMPs are also important for permeability barrier homeostasis. Despite an apparent increase in mBD3 protein, CRAMP-/- mice delayed permeability barrier recovery, attributable to defective LB contents and abnormalities in the structure of the lamellar membranes that regulate permeability barrier function. These studies demonstrate that (1) the permeability and antimicrobial barriers are coordinately regulated by permeability barrier requirements and (2) CRAMP is required for permeability barrier homeostasis.