Comparative study of Langerhans cells in normal and pathological human scars. I. Atrophic scars.

In the present study, we investigated Langerhans cells (LCs) in the epidermal component of human atrophic scars, comparing them with those in control skin and normotrophic scars. A preliminary analysis of the histological features was first carried out on vertical serial sections, stained with hematoxylin and eosin. The total epidermal thickness and the thickness of the single epidermal layers were then measured, by means of a digitizing tablet and a morphometric program run on an Apple IIe computer. These parameters were found to be significantly lower (40%) in atrophic scars, if compared to control skin and normotrophic scars (p less than 0.05). CDla-positive and HLA-DR-positive LCs were marked by indirect immunofluorescence. Their position among the epidermal layers, their dimensions, their density and their morphology were examined. In atrophic scars, LCs were densely and evenly distributed in all the epidermal layers. Their density was increased (about 1200 cells/mm2 of epidermal area), if compared to control skin and normotrophic scars (both 300-400 cells/mm2 of epidermal area; p less than 0.001). The CDla-positive definite cell bodies, exhibiting an unstained nucleus, were as large as those evidentiated in the normotrophic scars and twice as much the control skin values (p less than 0.001). The present results provide morphological data that distinguish atrophic scars from control skin and normotrophic scars, and suggest an involvement of the Langerhans cells in this particular case of pathological scarring.     

Ontogeny of Langerhans cells in human embryonic and fetal skin: cell densities and phenotypic expression relative to epidermal growth

Langerhans cells (LCs) positive for HLA-DR antigens were present in developing human epidermis by at least 7 weeks estimated gestational age (EGA). Most were negative for CD1 (T6) until 12-13 weeks EGA when they underwent a dramatic increase in CD1 reactivity. To gain insight into the density of LCs during ontogeny and to assess whether their distribution was coordinated with epidermal growth, the number of cells positive for both HLA-DR and CD1 antigens was determined relative to surface area and to volume of developing, interfollicular epidermis. LCs differed in their phenotype, distribution (follicular vs. interfollicular), size, and shape between 7 and 21 weeks EGA; however, during this period they maintained a statistically equivalent (P greater than .25) density (65 cells/mm2 and 1,750/mm3) even though the epidermis increased in thickness and the fetus rapidly expanded its surface area. While LCs were evenly distributed within the epidermal sheets at all gestational ages, those in embryonic skin were much smaller and less dendritic than the older cells. The density, size, and shape of LCs in developing skin seemed to be independent of epidermal status (e.g., thickness of keratinization, and number of cell layers) but rather were correlated with gestational age. The number of fetal LCs, through at least 23 weeks EGA, was only 10-20% of the adult LC density. Thus, we can conclude that the increase in LC density to adult levels must occur either during the third trimester or after birth.     

Transforming growth factor-beta(1), -beta(2), -beta(3), basic fibroblast growth factor and vascular endothelial growth factor expression in keratinocytes of burn scars

Keratinocytes are increasingly recognized as key regulators of skin inflammation and remodeling, as they are capable of producing growth factors and cytokines that are important mediators in the wound healing process. We investigated the expression and distribution of TGF-beta 1 mRNA by mRNA in situ hybridization and of TGF-beta 1, TGF-beta 2, TGF-beta 3, bFGF and VEGF protein expression using immunohistochemistry in spontaneously healed, partial-thickness burns and compared this with the expression of these markers in matched unburned skin. This was done to assess their role in the remodeling phase of burn wound healing. Punch biopsies were taken from both partial-thickness burns after re-epithelialization and from matched, unburned skin. At 4 and 7 months post-burn, biopsies were taken of normotrophic and hypertrophic scars that had developed in these wounds. We observed a higher expression of all mentioned growth factors in keratinocytes in scars at 1 month post-burn compared with matched unburned skin. At 4 months, keratinocytes still displayed a higher expression of TGF-beta 3 and bFGF, but the expression of TGF-beta 1, TGF-beta 2 and VEGF was normalized. The expression of TGF-beta 3 in the epidermis of hypertrophic scars was slightly higher than in normotrophic scars. At 7 months post-burn, all growth factors studied showed a normal expression on keratinocytes. Our results suggest that keratinocytes are not only involved in re-epithelialization, but also in the scar maturation. The data support the idea that keratinocytes not only respond to cytokines and growth factors in an autocrine fashion, but also exert regulatory paracrine effects on contiguous cells.     

Expression and localization of insulin-like growth factor-1 in normal and post-burn hypertrophic scar tissue in human

The migration of epithelial cells from dermal appendages toward the wound surface is essential for re-epithelialization of partial thickness burn injuries. This study provides evidence that these cells in vivo synthesize a mitogenic and fibrogenic factor, insulin-like growth factor-1 (IGF-1), which may promote the development of the post-burn fibroproliferative disorder, hypertrophic scarring (HSc). An evaluation of 7 post-burn hypertrophic scars, 7 normal skin samples obtained from the same patients and 4 mature scars revealed that IGF-1 expressing cells from the disrupted sweat glands tend to reform small sweat glands of 4-10 cells/gland in post-burn HSc. The number of these cells increases with time and the glands become larger in mature scar. Other epithelial cells such as those found in sebaceous glands and basal and suprabasal keratinocytes, also express IGF-1 protein and mRNA as detected by Northern and RT-PCR analysis of RNA obtained from whole skin and separated epidermis and dermis. However, cultured keratinocytes did not express mRNA for IGF-1. Histological comparisons between normal and HSc sections show no mature sebaceous glands in dermal fibrotic tissues but the number of IGF-1 producing cells including infiltrated immune cells was markedly higher in the dermis of hypertrophic scar tissues relative to that of the normal control. In these tissues, but not in normal dermis, IGF-1 protein was found associated with the extracellular matrix. By in situ hybridization, IGF-1 mRNA was localized to both epithelial and infiltrated immune cells. Collectively, these findings suggest that in normal skin, fibroblasts have little or no access to diffusible IGF-1 expressed by epithelial cells of the epidermis, sweat and sebaceous glands; while following dermal injury when these structures are disrupted, IGF-1 may contribute to the development of fibrosis through its fibrogenic and mitogenic functions. Reformation of sweat glands during the later stages of healing may, therefore, limit this accessibility, and lead to scar maturation.     

Spatiotemporal expression of periostin during skin development and incisional wound healing: lessons for human fibrotic scar formation

Differentiation of fibroblasts to myofibroblasts and collagen fibrillogenesis are two processes essential for normal cutaneous development and repair, but their misregulation also underlies skin-associated fibrosis. Periostin is a matricellular protein normally expressed in adult skin, but its role in skin organogenesis, incisional wound healing and skin pathology has yet to be investigated in any depth. Using C57/BL6 mouse skin as model, we first investigated periostin protein and mRNA spatiotemporal expression and distribution during development and after incisional wounding. Secondarily we assessed whether periostin is expressed in human skin pathologies, including keloid and hypertrophic scars, psoriasis and atopic dermatitis. During development, periostin is expressed in the dermis, basement membrane and hair follicles from embryonic through neonatal stages and in the dermis and hair follicle only in adult. In situ hybridization demonstrated that dermal fibroblasts and basal keratinocytes express periostin mRNA. After incisional wounding, periostin becomes re-expressed in the basement membrane within the dermal-epidermal junction at the wound edge re-establishing the embryonic deposition pattern present in the adult. Analysis of periostin expression in human pathologies demonstrated that it is over-expressed in keloid and hypertrophic scars, atopic dermatitis, but is largely absent from sites of inflammation and inflammatory conditions such as psoriasis. Furthermore, in vitro we demonstrated that periostin is a transforming growth factor beta 1 inducible gene in human dermal fibroblasts. We conclude that periostin is an important ECM component during development, in wound healing and is strongly associated with pathological skin remodeling.     

Collagen fibril network and elastic system remodeling in a reconstructed skin transplanted on nude mice.

Wound healing of deep and extensive burns can induce hypertrophic scar formation, which is a detrimental outcome for skin functionality. These scars are characterized by an impaired collagen fibril organization with fibril bundles oriented parallel to each other, in contrast with a basket weave pattern arrangement in normal skin. We prepared a reconstructed skin made of a collagen sponge seeded with human fibroblasts and keratinocytes and grown in vitro for 20 days. We transplanted it on the back of nude mice to assess whether this reconstructed skin could prevent scar formation. After transplantation, murine blood vessels had revascularized one-third of the sponge thickness on the fifth day and were observed underneath the epidermis at day 15. The reconstructed skin extracellular matrix was mostly made of human collagen I, organized in loosely packed fibrils 5 days after transplantation, with a mean diameter of 45 nm. After 40-90 days, fibril bundles were arranged in a basket weave pattern while their mean diameter increased to 56 nm, therefore exactly matching mouse skin papillary dermis organization. Interestingly, we showed that an elastic system remodeling was started off in this model. Indeed, human elastin deposits were organized in thin fibrils oriented perpendicular to epidermis at day 90 whereas elastic system usually took years to be re-established in human scars. Our reconstructed skin model promoted in only 90 days the remodeling of an extracellular matrix nearly similar to normal dermis (i.e. collagen fibril diameter and arrangement, and the partial reconstruction of the elastic system).     

Characterization of the collagen of human hypertrophic and normal scars.

The collagen produced in response to an injury of human skin is initially stabilized by a cross-link derived from hydroxyallysine, and characteristic of embryonic skin. In normal healing there is a change over with time to the cross-link derived from allysine, which is typical of young skin collagen. In contrast, hypertrophic scars fail to follow the time-related changes of normal skin, but retain the characteristics of embryonic collagen, indicating a continued rapid turnover of the collagen. This is further supported by the high proportion of the embryonic Type III collagen present in hypertrophic scars.     

Changes in the number and distribution of Langerhans cells in the hydantoin hyperplasic gingiva as compared with the clinically normal one.

A study was made of the number of Langerhan's cells (LCs) per mm2 of section which express the antigens T6 and/or HLA-DR in seriated gingival sections of diphenylhydantoine-induced hyperplasia (HG) and clinically normal gingivae (NG). NG showed histological correlation with its macroscopic appearance. In HG the classical histopathological findings were verified, as well as the epithelial maturation irregularities, conductive to the development of epithelial gaps. In the immunostained samples, LCs appear amply distributed in the epithelium in greater numbers than in NG and more branched except in the immature areas, where they mostly express HLA-DR. In HG keratinocytes, HLA-DR+ are observed in the basal layer, except in developing epithelial gap zones. The Wilcoxon test for the NG-T6/NG-DR and HG-T6/HG-DR was not significant; but the Mann Whitney test for NG-T6/HG-T6 and NG-DR/HG-DR was significant to p less than 0.05. It is understood that the increase in LC numbers in HG is a manifestation of their active participation in local immune reactions. The presence of DR+/T6- LCs in the less keratinized areas seems to indicate the relationship of LCs with epithelial proliferation and/or differentiation.     

Measurement of collagen-proteoglycan interaction in hypertrophic scars

Collagen-proteoglycan interaction in hypertrophic scars was measured by staining tissue collagen with Sirius red, followed by elution of the bound stain, and photometric quantitation before and after papain digestion. Control sections from each of the specimens were treated with buffer solution instead of papain. The difference in dye concentration observed between respective untreated and digested sections was considered to be due to the unmasked basic groups of collagen originally bound to proteoglycans. The results suggest a significantly increased collagen-proteoglycan interaction in human hypertrophic scars as compared with nonhypertrophic scars, normal skin, and granulation tissues.     

Migration and differentiation of Langerhans cell precursors

Epidermal Langerhans cells (LC) are the first sentinels of the skin immune system. To study immigration of human LC precursor cells into the skin, we established a two-compartmental skin model consisting of a dermal matrix and an epidermal sheet of keratinocytes. We tested the individual components of the skin model for their influence on phenotype and function of LC precursors. A time window at day 5/6 of differentiation was determined, during which in vitro generated LC precursors expressed adhesion molecules and chemokine receptors required for transmigration across endothelial cell layers and the dermis towards the epidermis. They expressed L-selectin, integrins, platelet endothelial cell adhesion molecule-1, E-cadherin and CC-chemokine receptor 6 and were thus fitted out for transendothelial migration and immigration into the dermis. In a transwell system, these LC precursors migrated towards the chemokine MIP3alpha, demonstrating functional integrity of chemokine receptor 6. For the in vitro reconstituted skin, keratinocytes were grown on a de-epidermized dermis for one to three weeks and formed an epidermal sheet. We allowed LC precursor cells to migrate into this two-compartmental model from the dermal side and examined the presence of CD1alpha--positive cells. LC precursors migrated through the dermal matrix towards the layer of keratinocytes representing the epidermis and could be identified by immunohistology. Experiments designed to investigate the influence of signals provided by both the skin components and by the LC precursors on LC immigration into the skin are in progress.     

Structural and functional evaluation of modifications in the composite skin graft: cryopreserved dermis and cultured keratinocytes.

Structural and functional aspects of modifications in the composite skin graft consisting of cultured keratinocytes and cryopreserved dermis were determined. Cryopreserved human cadaveric dermis separated from skin by short and mild trypsinization was compared with dermis obtained by prolonged incubation in medium and with fresh dermis obtained by the same methods. All types of dermis were shown to retain normal ultrastructure and topographic organization, as detected by scanning and transmission electron microscope and immunofluorescence analysis. However, in fresh skin, the layers were more firmly attached, mechanical separation was more difficult, and residual epidermis often remained attached to the dermis. Keratinocytes attached better, began replication earlier, and generally reached higher cell numbers when cultured on trypsinized dermis than on medium-treated dermis. The performance of several modifications in the reconstitution and grafting procedures of the composite skin graft after transplantation to athymic mice was examined. Cultured epidermis combined onto trypsinized or medium-treated whole and meshed dermis, dermis pregrafted and allowed to take before transplanting epidermis on top, and keratinocytes grown into multiple epithelia on top of trypsinized meshed or whole dermis prior to grafting. The best grafting results were obtained with an "instant" reconstituted skin model: multiple epithelia grown in vitro combined immediately before grafting onto meshed trypsinized dermis. The transplantation results of this modification were significantly better than those of all the other modifications, including initial growth of keratinocytes into multiple epithelia on top of trypsinized dermis prior to grafting.     

Immunoglobulins in hypertrophic scars and keloids

Immunoglobulins A, G, and M were localized in normal skin, hypertrophic scars, keloids, and mature scars by the direct immunofluorescent antibody method. All three immunoglobulins appeared increased in the lesions above levels observed in normal skin. Extractions of the immunoglobulins from the same type of tissues also suggested an increase above levels from normal skin. The data suggest attritional leakage of several plasma proteins from the microvasculature in the lesions. No one immunoglobulin appears significantly increased in the lesions compared with others.     

Tissue gases in human hypertrophic burn scars

The partial pressures of oxygen and carbon dioxide have been measured in hypertrophic scars in burned patients, using mass spectroscopy. The pO2 in scar tissue was significantly depressed in comparison to the pO2 in normal dermis (a decrease of 13.1 +/- 2.9 mm Hg). The pCO2 was noted to be increased in the scar tissue (2.6 +/- 1.6 mm Hg). The possible significance of these findings is discussed.     

Histopathological and cellular studies of a case of cutaneous radiation syndrome after accidental chronic exposure to a cesium source.

This study was designed for the histopathological, cellular and biochemical characterization of a skin lesion removed surgically from a young male several months after accidental exposure to cesium-137, with an emphasis on expression of transforming growth factor beta1 (TGFB1) and tumor necrosis factor alpha (TNFA) and the occurrence of apoptosis. Under a hypertrophic epidermis, a highly inhomogeneous inflammatory dermis was observed, together with fibroblastic proliferation in necrotic areas. Immunostaining revealed overexpression of TGFB1 and TNFA inside the keratinocytes of the hypertrophic epidermis as well as in the cytoplasm of the fibroblasts and connective tissue of the mixed fibrotic and necrotic dermis. Inside this dermis, the TUNEL assay revealed areas containing numerous apoptotic fibroblasts next to areas of normal viable cells. Overexpression of TGFB1 was found in the conditioned medium and cellular fractions of both hypertrophic keratinocytes and fibrotic fibroblasts. This overexpression lasted for at least three passages in tissue culture. The present observations were consistent with the central role of TGFB1 in the determination of chronic radiation-induced damage to the skin and a significant involvement of TNFA. In addition, programmed cell death appeared to take place during the remodeling of the mixed fibrotic and necrotic tissue.     

Effects of platelet derived growth factor (PDGF) on fibronectin (FN) production by human skin and scar fibroblasts

The fibroblast-type cell found in hypertrophic scars and keloids demonstrates an elevated fibronectin (FN) production, compared to the same type of cell in normal dermis. We wished to determine if the effects of platelet derived growth factor (PDGF) on FN production in these cell types would be equivalent or different. Cell lines were established from the dermis (reticularis) of hypertrophic scars, keloids, uninvolved normal skin adjacent to the lesions, including an assumed normal skin adjacent to a keloid (AS), and normal skin from a different uninjured patient (DS). Each parent tissue from which the cell lines originated was diagnosed histologically. Each hypertrophic scar, keloid and normal adjacent skin, with one exception, showed typical histologic findings confirming the clinical diagnosis. DS was also normal. AS, although assumed to be normal, in fact, demonstrated portions of nodules from the adjacent keloid. All cell lines were grown under standard conditions with subconfluent cells metabolically labeled for radioimmunoassays measuring FN at passage 3 (8 to 9 weeks in culture) in the absence and presence of PDGF. Significant differences in production of FN/cell and FN/PR/cell between two hypertrophic scars and their matched normal skins and for one keloid and its matched normal skin were observed. However, no significant difference was observed between the other keloid and AS, nor between the other hypertrophic scar and DS. PDGF significantly stimulated FN production in 2 of 4 NS cell lines, and in the AS cell line. By FN/cell values, 2 of 5 cell lines from the lesions were inhibited and one was increased. In terms of FN/PR/cell, 1 of 5 cell lines from the lesions was stimulated and the others showed no differences. The mixed results may be attributable to the likelihood that the cell lines represent mixed populations. This study demonstrates the importance of: 1) histological characterization of all parent tissues from which cell lines are derived, and 2) matching cell lines from lesions with cell lines from uninvolved normal dermis, in the same individual.     

Wnt5a在增生性瘢痕中的表达及其临床意义

目的：探讨wnt5a在增生性瘢痕中的表达及其临床意义。方法：选择12例增生性瘢痕患者,术中取成熟期增生性瘢痕6份,增殖期增生性瘢痕6份,正常皮肤组织6份。光镜下观察其形态学的差异,通过免疫组化技术检测和比较其Wnt5a阳性表达的细胞面积率。结果：与正常皮肤相比,增殖期增生性瘢痕中有大量的成纤维细胞,胶原纤维含量丰富,且排列紊乱,其间有大量的炎性细胞,成熟期增生性瘢痕也含有丰富的成纤维细胞和胶原,但炎性细胞很少。增殖期增生性瘢痕和成熟期增生性瘢痕组织中真皮浅层和真皮深层Wnt5a阳性表达的细胞面积率均显著高于正常皮肤组织（P〈0．05）,且增殖期增生性瘢痕组织中wnt5a阳性表达的细胞面积率显著高于成熟期增生性瘢痕（P〈0．05）。但正常皮肤组织、成熟期增生性瘢痕、增殖期增生性瘢痕各组间真皮浅层与真皮深层Wnt5a阳性表达的细胞面积率比较均无显著性差异（P〉0．05）。结论：Wnt5a的表达上调可能在增生性瘢痕的形成中起重要作用,并可能与增生性瘢痕的增殖活性有关。     

Spatial and Temporal Localization of the Melanocortin 1 Receptor and Its Ligand ���CMelanocyte-Stimulating Hormone during Cutaneous Wound Repair

Growing evidence indicates that the melanocortin 1 receptor (MC1R) and its ligand α–melanocyte-stimulating hormone (α-MSH) have other functions in the skin in addition to pigment production. Activation of the MC1R/α-MSH signaling pathway has been implicated in the regulation of both inflammation and extracellular matrix homeostasis. However, little is known about the role of MC1R/α-MSH signaling in the regulation of inflammatory and fibroproliferative responses to cutaneous injury. Although MC1R and α-MSH localization has been described in uninjured skin, their spatial and temporal expression during cutaneous wound repair has not been investigated. In this study, the authors report the localization of MC1R and α-MSH in murine cutaneous wounds, human acute burns, and hypertrophic scars. During murine wound repair, MC1R and α-MSH were detected in inflammatory cells and suprabasal keratinocytes at the leading edge of the migrating epithelial tongue. MC1R and α-MSH protein levels were upregulated in human burn wounds and hypertrophic scars compared to uninjured human skin, where receptor and ligand were absent. In burn wounds and hypertrophic scars, MC1R and α-MSH localized to epidermal keratinocytes and dermal fibroblasts. This spatiotemporal localization of MC1R and α-MSH in cutaneous wounds warrants future investigation into the role of MC1R/α-MSH signaling in the inflammatory and fibroproliferative responses to cutaneous injury. This article contains online supplemental material at http://www.jhc.org. Please visit this article online to view these materials.     

Melanocytes in Human Embryonic and Fetal Skin: A Review and New Findings

Melanocytes account for approximately 5–10% percent of the cells in adult epidermis. Unlike the ectodermally derived keratinocytes, they originate in the neural crest and migrate into the epidermis early in development. There has been an interest in melanocytes in developing human skin since the late 1800s, when concentrated pigmented cells were identified in the sacro-coccygeal skin of Japanese fetuses. This observation led to speculation and subsequent investigation about the racial nature of the melanocytes in this site (the Mongolian spot), the presence of melanocytes in fetuses of other races, the timing of appearance of these cells in both the dermis and epidermis, and their origin. The early investigators relied primarily on histochemical methods that stained either the premelanosome or the pigmented melanosome, or relied upon the activity of tyrosinase within the melanosome to effect the DOPA reaction. Studies by electron microscopy added further documentation to the presence of melanocytes in the skin by resolving the structure of the melanosome regardless of its state of pigmentation. All of these methods recognized, however, only differentiated melanocytes. The thorough investigations of melanocytes in the skin from a large number of black embryos and fetuses by Zimmerman and colleagues between 1948 and 1955 provided insight into the time of appearance of melanocytes in the dermis (10–11 weeks' menstrual age) and the epidermis (11–12 weeks) and revealed the density of these cells in both zones of the skin of several regions of the body. The precise localization of the melanocytes in the developing hair follicles was contributed by the studies of Mishima and Widlan (J Invest Dermatol 1966; 46:263–277). More recently, monoclonal antibodies have been developed that recognize common oncofetal or oncodifferentiation antigens on the surface or in the cytoplasm of melanoma cells and developing melanocytes (but not normal adult melanocytes). These antibodies recognize the cells irrespective of the presence or absence of melanosomes or their activity in the synthesis of pigment and therefore are valuable tools for re-examining the presence, density, and distribution patterns of melanocytes in developing human skin. Using one of these antibodies (HMB-45), it was found that dendritic melanocytes are present in the epidermis between 40 and 50 days estimated gestational age in a density comparable with that of newborn epidermis and are distributed in relatively non-random patterns. A number of questions about the influx of cells into the epidermis, potential reservoirs of melanoblasts retained within the dermis, division of epidermal melanocytes, and the interaction of melanocytes and keratinocytes during development remain unresolved. The tools now appear to be available, however, to begin to explore many of these questions.     

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

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