Filaggrin breakdown to water binding compounds during development of the rat stratum corneum is controlled by the water activity of the environment

Filaggrin is a specific epidermal protein which is the precursor of the free amino acids, urocanic acid and pyrrolidone carboxylic acid which are largely responsible for the ability of the stratum corneum of the skin to remain hydrated at low environmental humidity. The distribution of filaggrin shown by immunofluorescence in the stratum corneum of the rat changed dramatically during the first hours of postnatal life. During late foetal development, filaggrin accumulated through the entire thickness of the stratum corneum, indicating that there was a block on the subsequent processing of the protein which normally would convert it to free amino acids. Immediately after birth this block was lifted and normal proteolysis of the filaggrin took place in the outer part of the stratum corneum, leaving the normal adult pattern of a thin zone of cells containing filaggrin at the bottom of the stratum corneum. This activation of filaggrin proteolysis was dependent on the drop in external water activity caused by the transition from an aqueous environment in utero to a dryer environment after birth and it could be blocked by maintaining a 100% humidity atmosphere around the newborn rat after birth. In isolated stratum corneum in vitro, filaggrin proteolysis took place only between 80 and 95% relative humidity, both higher and lower relative humidity blocked the proteolysis. Application of occlusive patches to adult rats prevented the normal proteolysis of filaggrin, indicating that this mechanism controls not only the massive filaggrin proteolysis occurring after birth but also the proteolysis occurring during normal stratum corneum maturation. The stratum corneum therefore has the ability to respond to changes in external humidity by altering the level of the stratum corneum where it converts its reserves of filaggrin into water binding amino acids, such that under humid conditions water binding components will be produced in only the most superficial stratum corneum, or even not produced at all.     

The effects of layer properties on shear disturbance propagation in skin

The effects of the stratum corneum and dermis on shear wave propagation along the skin surface was investigated using a mathematical model. The skin was modeled as two distinct viscoelastic layers, one representing the stratum corneum and the other representing the dermis. The layers were supported by a semi-infinite visco-elastic half-space representing the subcutaneous fat. Physical and mechanical properties of the materials in the model were determined from the literature and from our own experimental measurements. Although the stratum corneum is very thin (12-15 microns), results showed that it could have a strong effect on the wave propagation due to its high stiffness relative to the dermis. Results of the analysis are discussed with respect to an experimental procedure used to determine age-related changes in mechanical properties of skin.     

Biological and physical factors influencing the successful engraftment of a cultured human skin substitute

Skin tissue may be engineered in a variety of ways. Our cultured skin substitute (Graftskin, living skin equivalent or G-LSE), Apligraftrade mark, is an organotypic culture of skin, containing both a "dermis" and "epidermis." The epidermis is an important functional component of skin, responsible for biologic wound closure. The epidermis possesses a stratum corneum which develops with time in culture. The stratum corneum provides barrier function properties and gives the LSE improved strength and handling characteristics. Clinical experience indicated that the stratum corneum might play an important role in improving the clinical utility of the LSE. Handling and physical characteristics improved with time in culture. We examined the LSE at different stages of epidermal maturation for barrier function and ability to persist as a graft. LSE grafted onto athymic mice before significant development of barrier function did not withstand bandage removal at 7 days postgraft. LSE grafted after barrier function had been established in vitro were able to withstand bandage removal at day 7. Corneum lipid composition and structure are critical components for barrier function. Media modifications were used in an attempt to improve the fatty acid composition of the stratum corneum. The barrier developed more rapidly and was improved in a serum-free, lipid-supplemented condition. Lipid lamellar structure was improved with 10% of the stratum corneum exhibiting broad-narrow-broad lipid lamellar arrangements similar to human skin. Fatty acid metabolism was not appreciably altered. Barrier function in vitro was 4- to 10-fold more permeable than human skin. Epidermal differentiation does not compromise engraftment or the wound healing ability of the epidermis. The stratum corneum provides features beneficial for engraftment and clinical use. (c) 1996 John Wiley & Sons, Inc.     

In vitro measurement of the mechanical properties of skin by nano/microindentation methods

The elastic behaviors of stratum corneum, viable epidermis, dermis, and whole skin were investigated by nano/microindentation techniques. Insignificant differences in reduced elastic modulus of skin samples obtained from three different porcine breeds revealed breed type independent measurements. The reduced elastic modulus of stratum corneum is shown to be about three orders of magnitude higher than that of dermis. As a result, for relatively shallow and deep indentations, skin elasticity is controlled by that of stratum corneum and dermis, respectively. Skin deformation is interpreted in the context of a layered structure model consisting of a stiff and hard surface layer on a compliant and soft substrate, supported by microscopy observations and indentation measurements.     

In vitro indentation to determine the mechanical properties of epidermis

The lack of understanding of the mechanical behavior of the human skin layers makes the development of drug delivery using microneedles or microjets a challenging task. In particular, the key mechanical properties of the epidermis composed of stratum corneum and viable epidermis should be better understood. Micro-indentation experiments were applied, using a spherical tip with a large diameter to the sample thickness ratio. The Young's moduli were derived via an analytical and a numerical method. The tests showed that the analytical method was not appropriate to assess the Young's moduli. That is why a numerical model was used to obtain the correct stiffness. When loaded perpendicularly, the stiffness of both the epidermis and stratum corneum vary between 1 and 2MPa. No significant differences in stiffness between the stratum corneum and viable epidermis were observed.     

DNase 2 is the main DNA-degrading enzyme of the stratum corneum

The cornified layer, the stratum corneum, of the epidermis is an efficient barrier to the passage of genetic material, i.e. nucleic acids. It contains enzymes that degrade RNA and DNA which originate from either the living part of the epidermis or from infectious agents of the environment. However, the molecular identities of these nucleases are only incompletely known at present. Here we performed biochemical and genetic experiments to determine the main DNase activity of the stratum corneum. DNA degradation assays and zymographic analyses identified the acid endonucleases L-DNase II, which is derived from serpinB1, and DNase 2 as candidate DNases of the cornified layer of the epidermis. siRNA-mediated knockdown of serpinB1 in human in vitro skin models and the investigation of mice deficient in serpinB1a demonstrated that serpinB1-derived L-DNase II is dispensable for epidermal DNase activity. By contrast, knockdown of DNase 2, also known as DNase 2a, reduced DNase activity in human in vitro skin models. Moreover, the genetic ablation of DNase 2a in the mouse was associated with the lack of acid DNase activity in the stratum corneum in vivo. The degradation of endogenous DNA in the course of cornification of keratinocytes was not impaired by the absence of DNase 2. Taken together, these data identify DNase 2 as the predominant DNase on the mammalian skin surface and indicate that its activity is primarily targeted to exogenous DNA.     

The extraction and characterization of bovine epidermal alpha-keratin.

1. The alpha-fibrous protein (alpha-keratin) component of bovine epidermis has been extracted and characterized. 2. Prekeratin, a multichain unit of the epidermal tonofilaments, was shown to consist of six different polypeptide chains on polyacrylamide-gel systems containing sodium dodecyl sulphate or sodium decyl sulphate with discontinuous gel buffers, but only three chains were seen when a gel system containing sodium dodecyl sulphate with a continuous gel buffer was used. 3. Extraction of the 'keratinized' stratum corneum and the living part of the epidermis with urea buffers at pH 7.6 or 9.0 released 60% of the total dry weight of the tissues in the form of alpha-helical polypeptides. 4. The numbers, relative amounts and properties of the extracted polypeptides were the same as the subunits of prekeratin and thus are derived from the tonofilaments in situ. 5. The subunits of prekeratin and the polypeptides extracted from the living cell layers contained an average of six cysteine residues, but those from the stratum corneum contained an average of three intrachain disulphide bonds. 6. The polypeptide chains aggregated through non-covalent interactions in vitro into filaments that were similar to the tonofilaments. 7. Since the polypeptides could be released from the stratum corneum without breaking covalent bonds, it is concluded that such bonds do not cross-link the tonofilaments and non-fibrous keratohyalin. It is suggested that the tonofilaments and keratohyalin of bovine epidermis are associated by secondary bonding forces.     

A covalently cross-linked gel derived from the epidermis of the pilot whale Globicephala melas

The rheological properties of the stratum corneum of the pilot whale (Globicephala melas) were investigated with emphasis on their significance to the self-cleaning abilities of the skin surface smoothed by a jelly material enriched with various hydrolytic enzymes. The gel formation of the collected fluid was monitored by applying periodic-harmonic oscillating loads using a stress-controlled rheometer. In the mechanical spectrum of the gel, the plateau region of the storage modulus G' (<1200 Pa) and the loss modulus G" (>120 Pa) were independent of frequency (omega = 43.98 to 0.13 rad x s(-1), tau = 15 Pa, T = 20 degrees C), indicating high elastic performance of a covalently cross-linked viscoelastic solid. In addition, multi-angle laser light scattering experiments (MALLS) were performed to analyse the potential time-dependent changes in the weight-average molar mass of the samples. The observed increase showed that the gel formation is based on the assembly of covalently cross-linked aggregates. The viscoelastic properties and the shear resistance of the gel assure that the enzyme-containing jelly material smoothing the skin surface is not removed from the stratum corneum by shear regimes during dolphin jumping. The even skin surface is considered to be most important for the self-cleaning abilities of the dolphin skin against biofouling.     

An analysis on the rates and regulation of insensible water loss through the eccrine sweat glands

An analysis is presented on insensible water loss from the human body at rest through exposed skin surfaces into still air. Possible sites of moisture release are identified as the stratum corneum of the skin, free surfaces of dilute sweat liquids perpetually present in the microscopic ducts of a large population of eccrine sweat glands, and moist microvillous processes which line part of the periductal surfaces in the glands, particularly in the helical coils within the stratum spinosum of the epidermis. Water supply to the sites involves transepidermal migration across skin tissue layers, secretion and partial reabsorption of solutes and water within eccrine glands, and transport across periductal lining of eccrine glands from the surrounding connective tissues respectively. Evaporation and gas phase diffusion within eccrine ducts were modelled. Basal loss rates of water (as regulated by the ambient temperature and relative humidity and by aspects of the anatomy of and physiological factors for eccrine glands, the epidermis and the dermis) were calculated at between 1 and 20 g hr-1 at an ambient temperature of 25 degrees C and a relative humidity of 60% as an example. Such rates are significant fractions of experimental values for insensible water loss rates reported at between 4 and 35 g hr-1 in air at 22-30 degrees C and a relative humidity of 30-60%.     

The mechanical properties of stratum corneum. I. The effect of water and ambient temperature on the tensile properties of newborn rat stratum corneum.

The tensile properties of the outermost layer of skin of neonatal rats, the stratum corneum, were investigated at a constant strain rate as a function of moisture content and ambient test temperature. The results show that the mechnical behavior of this membrane, whose primary constituent is the fibrous protein keratin, can be significantly altered by variations in both the sorbed water content and ambient temperature. In particular, a brittle to ductile transition was observed at 25 degrees C once the hydration level exceeded 70% relative humidity. Similarly, an identical phenomenon was detected at temperatures beyond 40 degrees C for specimens whose equilibrium moisture concentrations were maintained at 10 g H2 O/100 g dry protein. Differential scanning calrimetry measurements showed the presence of a molecular relaxation process which migrated from 42 degrees C at 40% relative humidity to --18 degrees C at 95% relative humidity. It is postulated that this relaxation process, possibly corresponding to the glass transition of the fibrous protein component of stratum corneum, is primarily responsible for the observed behavior.     

Using the method of homogenization to calculate the effective diffusivity of the stratum corneum with permeable corneocytes

The stratum corneum is the outermost layer of the skin, which acts as a barrier membrane against the penetration of molecules into and out of the body. It has a biphasic structure consisting of keratinized cells (corneocytes) that are embedded in a lipid matrix. The macroscopic transport properties of the stratum corneum are functions of its microstructure and the transport properties of the corneocytes and the lipid matrix, and are of considerable interest in the context of transdermal drug delivery and quantifying exposure to toxins, as well as for determining the relation of skin disorders to disruption of the stratum corneum barrier. Due to the complexity of the tissue and the difference in length scales involved in its microstructure, a direct analysis of the mass transport properties of the stratum corneum is not feasible. In this study, we undertake an approach where the macroscopic diffusion tensor of the stratum corneum is obtained through homogenization using the method of asymptotic expansions. The biphasic structure of the stratum corneum is fully accounted for by allowing the corneocytes to be permeable and considering the partitioning between the corneocytes and the lipid phases. By systematically exploring the effect of permeable corneocytes on the macroscopic transport properties of the stratum corneum, we show that solute properties such as lipophilicity and relative permeabilities in the two phases have large effects on its transdermal diffusion behavior.     

Human epidermal lipids: characterization and modulations during differentiation

Using thin-layer chromatography and glass capillary gas-liquid chromatography, we have quantitated the lipids in the germinative, differentiating, and fully cornified layers in human epidermis. As previously noted in nonhuman species, we found progressive depletion of phospholipids coupled with repletion of sterols and sphingolipids during differentiation. The sphingolipids, present only in small quantities in the lower epidermis, accounted for about 20% of the lipid in the stratum corneum, and were the major repository for the long-chain fatty acids that predominate in the outer epidermis. Although the absolute quantities of sphingolipids increased in the outer epidermis, the glycolipid:ceramide ratio diminished in the stratum corneum, and glycolipids virtually disappeared in the outer stratum corneum. Squalene and n-alkanes were distributed evenly in all epidermal layers, suggesting that these hydrocarbons are not simply of environmental or pilosebaceous origin. Cholesterol sulfate, previously considered only a trace metabolite in epidermis, was found in significant quantities, with peak levels immediately beneath the stratum corneum in the stratum granulosum. These studies: 1) provide new quantitative data about human epidermal lipids; 2) implicate certain classes of lipids for specific functions of the stratum corneum; and, 3) shed light on possible product-precursor relationships of these lipids.     

The mechanical properties of stratum corneum: I. The effect of water and ambient temperature on the tensile properties of newborn rat stratum corneum

The tensile properties of the outermost layer of skin of neonatal rats, the stratum corneum, were investigated at a constant strain rate as a function of moisture content and ambient test temperature. The results show that the mechanical behavior of this membrane, whose primary constituent is the fibrous protein keratin, can be significantly altered by variations in both the sorbed water content and ambient temperature. In particular, a brittle to ductile transition was observed at 25°C once the hydration level exceeded 70% relative humidity. Similarly, an identical phenomenon moisture concentrations were maintained at 10 g H₂O/100 g dry protein. Differential scanning calorimetry measurements showed the presence of a molecular relaxation process which migrated from 42°C at 40% relative humidity to −18°C at 95% relative humidity. It is postulated that this relaxation process, possibly corresponding to the glass transition of the fibrous protein component of stratum corneum, is primarily respnsible for the observed behavior.     

Avian permeability barrier function reflects mode of sequestration and organization of stratum corneum lipids: reevaluation utilizing ruthenium tetroxide staining and lipase cytochemistry.

The epidermis of avians and terrestrial mammals has evolved distinct, but related mechanisms to survive in a terrestrial environment. In both phyla, stratum corneum lipids form the basis of the cutaneous permeability barrier, but barrier function is less efficient in avians. Whereas in mammals the epidermal lamellar body (LB) secretes its contents into the intercellular spaces, in the feathered epidermis of avians, its distinctive secretory organelle, the multigranular body (MGB), does not secrete its contents into the stratum corneum intercellular spaces. Yet, neutral lipid-enriched droplets, derived from the cytosolic breakdown of MGB, ultimately are squeezed through membrane pores into the stratum corneum interstices. In this study we determined: a) using ruthenium tetroxide (RuO4) fixation, whether these droplets form membrane structures after deposition in the stratum corneum interstices; and b) the similarities and differences between avian MGB and mammalian LB, using enzyme cytochemistry as a marker for secretion, and optical diffraction computer-aided image analysis and reconstruction to compare the internal structure of MGB vs. LB. MGB were shown to possess a similar lamellar substructure to LB in RuO4-fixed specimens, exhibiting comparable dimensions on optical diffraction and computer transform analysis. Moreover, the intercellular lipids of avian stratum corneum lacked membrane-substructure, as was present in parallel samples of mammalian stratum corneum. Thus, both the absence of MGB secretion, and the failure of intercellular lipids to form membrane bilayers may explain the inherent differences in barrier function in these two taxa.     

Experimental penetration of Trichophyton mentagrophytes into human stratum corneum

We present confirmation of the experimental penetration of Trichophyton mentagrophytes into human stratum corneum under designated conditions of temperature and humidity. When stratum corneum, obtained from healthy human heel region, was incubated at 100% humidity, mycelium was observed in the corneum layer on day 2 at 35 °C and 27 °C, and on day 4 at 15 °C. At 90% humidity, the hyphae penetrated into the stratum corneum on day 4 at 35 °C, and on day 6 at 27 °C. Whereas, at 80% humidity, no fungal elements were observed in the stratum corneum at both 27 °C and 35 °C for up to 7 day. These data suggested that humidity was a more important environmental factor for penetration than temperature, and that at least 90% humidity is necessary for dermatophytes to penetrate into the stratum corneum within a few days. Mean humidity in the interdigital space between the fourth and fifth toes was found to be approximately 98%. This revised version was published online in June 2006 with corrections to the Cover Date.     

Heterogeneous drying stresses in stratum corneum

We study the drying of stratum corneum, the skin's outermost layer and an essential barrier to mechanical and chemical stresses from the environment. Even though stratum corneum exhibits structural features across multiple length-scales, contemporary understanding of the mechanical properties of stratum corneum is based on the assumption that its thickness and composition are homogeneous. We quantify spatially resolved in-plane traction stress and deformation at the interface between a macroscopic sample of porcine stratum corneum and an adherent deformable elastomer substrate. At length-scales greater than a millimeter, the skin behaves as a homogeneous elastic material. At this scale, a linear elastic model captures the spatial distribution of traction stresses and the dependence of drying behavior on the elastic modulus of the substrate. At smaller scales, the traction stresses are strikingly heterogeneous and dominated by the heterogeneous structure of the stratum corneum.     

The proteins of living psoriatic epidermis

Psoriatic epidermis has a rapid rate of tunrover and produces a stratum corneum with an abnormal tonofilament composition. One polypeptide chain, (M_r 70 000) is absent or greatly decreased in relative amount and two other chains, (M_r 63 000 and 55 000), which are normally modified in the living cells, persists into the stratum corneum. Increasing the turnover of normal epidermis has been shown to cause the persistence of 63 and 55 kilodalton chains in the stratum corneum but does not affect the relative amount of 70 kilodalton chain. It has, therefore, been suggested that, in psoriasis, the deficiency of the 70 kilodalton chain may occur prior to or simultaneuously with the induction of increased tissue turnover. In the present study, the polypeptide chain composition of living psoriatic epidermis has been examined. It is shown that the relative amounts of 70 kilodalton chain in psoriatic stratum corneum and involved living epidermis from the same site are not significantly different. The abnormality is therefore, already present in the living cells and it appears that, in psoriasis, the synthesis of the 70 kilodalton chain is defective. The uninvolved epidermis of psoriatics is intermediate between normal and involved psoriatic epidermis both in the ability to synthesise the 70 kilodalton chain and to modify the 63 and 55 kilodalton chains. Comparisons of amino acid compositions of proteins containing different proportions of 70 kilodalton chain suggest that it has a considerably higher content of glycine and serine than the other tonofilament chains. These studies suggest that the 70 kilodalton chain may be functionally different from the other tonofilament chains. The defect in its synthesis in psoriasis is a relatively early event and may be involved with the induction of increased tissue turnover or induced by the same abnormal conditions as the increased tissue turnover.     

Physical characterization of the stratum corneum of an in vitro human skin equivalent produced by tissue engineering and its comparison with normal human skin by ATR-FTIR spectroscopy and thermal analysis (DSC).

An in vitro human skin equivalent may be obtained by culturing human keratinocytes on a collagen gel containing fibroblasts. The anchored skin equivalent cultured at the air-liquid interface closely resembles human skin and is acceptable for in vitro percutaneous absorption. However, it is still more permeable than human skin. Since intercellular lipids have been recognized to play an important role in skin permeability, infrared spectroscopy and differential scanning calorimetry were performed on the stratum corneum of bovine or human skin equivalents grown at different days of air-liquid culture. The symmetric and asymmetric CH(2) stretching vibrations suggested that for all days observed, the intercellular lipids were less organized than those in human skin, irrespective of whether bovine or human collagen was used. Different culture conditions were also tested and the medium without serum and no epidermal growth factor at the air-liquid culture showed results significantly more comparable to human skin. Actually, the thermal behavior of in vitro stratum corneum showed transitions at lower temperatures than human skin. The transition around 80 degrees C, in the form of a lipid-protein complex, was absent. These results showed that the structural arrangement of intercellular lipids and their thermodynamic properties hold a crucial role in the barrier function of the stratum corneum.     

Physical characterization of the stratum corneum of an in vitro psoriatic skin model by ATR-FTIR and Raman spectroscopies

The stratum corneum is an important permeability barrier for the skin. The disorganization of the skin protective barrier characterizes some skin diseases such as psoriasis. Indeed, psoriatic skin is known to be more permeable than normal human skin. An in vitro human skin substitute may be obtained by the auto-assembly method. This method was adapted to produce psoriatic substitutes. FTIR spectroscopy is a well-established method to evaluate the order of hydrocarbon chains in terms of population of trans and gauche conformers. Using ATR-FTIR, we have compared the physicochemical properties of the stratum corneum in skin models derived from uninvolved and involved psoriatic cells with those derived from normal cells. Our results suggest that the stratum corneum of involved psoriatic skin substitutes is less organized than that of normal skin substitutes. Also, it seems that the properties of uninvolved psoriatic skin may vary with seriousness of the disease. The development of a new psoriatic skin model would be helpful in the design of new treatments and to increase the understanding of the mechanisms of this pathology.     

Free sphingosines in porcine epidermis

Sphingosines and phytosphingosines serve as intermediates in the synthesis of ceramides and glucosylceramides, which are prominent components of mammalian epidermis. In the present study, we have investigated the possibility that free sphingoid bases also may be present in epidermal tissue. Samples of pig epidermis were trypsinized to separate the stratum corneum from the unkeratinized portion of the epidermis. After drying, the lipids were extracted and analyzed by thin-layer chromatography using ninhydrin to detect free amino groups. Both the stratum corneum and the unkeratinized epidermal material contained a ninhydrin-positive material with the same mobility as the sphingosine standard. Quantitation of the chromatograms by photodensitometry indicated that free sphingosine bases account for 0.44% by weight of the total stratum corneum lipid and 0.09% of the lipid in the viable portion of the epidermis. To further identify this material, it was treated with 1-fluoro-2,4-dinitrobenzene, which resulted in the production of an intensely yellow N-2,4-dinitrophenyl derivative with the same mobility as N-2,4-dinitrophenylsphingosine on thin-layer chromatography. Oxidation of the isolated dinitrophenyl derivative with lead tetraacetate produced a mixture of aldehydes which were analyzed by gas-liquid chromatography. This analysis indicates that the free sphingoid bases from the stratum corneum consist of a mixture of mainly 16- through 20-carbon sphingenines and sphinganines, the most abundant components being d17:0, d17:1, d18:1 and d20:1. The production of these free sphingosine bases may be significant in regulating epidermal differentiation.