Fc gamma RII/CD32-negative human Langerhans cells may be responsible for the immunostimulatory activity of freshly isolated epidermal cells.

Cultured murine and human epidermal Langerhans cells (LC) undergo a phenotypical and functional maturation process. In fact, they loose Fc gamma RII and Birbeck granules, increase HLA-DR expression, and become potent accessory cells for allogeneic MLR. However, resident/freshly isolated human epidermal LC represent a phenotypically heterogeneous cell population. Indeed, a subset of CD1a+ LC lacks Birbeck granules, is Fc gamma RII/CD32-, and strongly expresses HLA-DR and the RFD1 antigen that is considered to be specific for interdigitating cells. In the present study the functional capacity of this Fc gamma RII/CD32- CD1a+ LC subset was investigated in MLR assays by comparing the stimulatory activity of freshly isolated crude epidermal cells (EC) with that of freshly isolated EC depleted in CD1a+ or in Fc gamma RII+ cells. Thereby, we observed that crude EC stimulated allogeneic PBMC while the removal of CD1a+ cells abrogated this stimulation. However, crude EC depleted in Fc gamma RII/CD32+ cells still exhibited a stimulatory capacity that was at least equal to that of crude EC. Taken together, these data suggest that among resident human epidermal LC there exists a subset of phenotypically and functionally more differentiated cells that may be solely responsible for the stimulatory capacity of freshly isolated crude EC.     

Rapid recovery of Langerhans cell alloreactivity, without induction of autoreactivity, after in vivo ultraviolet A, but not ultraviolet B exposure of human skin

For therapeutic medical, cosmetic, and recreational reasons, humans expose themselves to increasing amounts of UVA. However, little is known of the photobiologic events associated with cutaneous carcinogenesis and photoaging that occur as a result of UVA exposure. UVB exposure of human skin abrogates the function of epidermal CD1+DR+ Langerhans cells and induces the appearance of CD1-DR+ non-Langerhans cell APC. This non-Langerhans cell APC population activates autoreactive immunoregulatory T cells that lead to suppressor-effector T cell function. In this report we show that, similarly to UBV, UVA exposure abrogates the function of CD1+DR+ Langerhans cells. However, in contrast to UVB, there is rapid recovery of Langerhans cell antigen-presenting cell activity and that CD1-DR+ non-Langerhans cell APC failed to appear to a significant degree. In keeping with the lack of CD1-DR+ epidermal cells, UVA exposed epidermal cells harvested 3 days after exposure functioned similarly to normal epidermis in that they activated alloreactive T cells but not autoreactive T cells in the absence of added Ag. This was in contrast to UVB irradiated epidermal cells that potently activate autoreactive T cells and contain CD1-DR+ cells. Thus, although both UVA and UVB initially depletes and inactivates CD1+DR+ Langerhans cells, the subsequent APC function of epidermal cells exposed to UVA differ profoundly from that of cells exposed to UVB. UVA radiation is less carcinogenic than UVB; differences in host responses to UV tumors may be linked to the rapid recovery of Langerhans cell function and the lack of induction of CD1-DR+ non-Langerhans cell APC after UVA exposure.     

Characterization of cryopreserved human Langerhans cells

Epidermal Langerhans cells are potent antigen-presenting cells in the epidermis. The establishment of a cryopreservation method for human Langerhans cells would greatly contribute to our ability to successfully conduct various experiments dealing with Langerhans cells. Since Langerhans cells are known to be sensitive to cold injury, there have been no reports concerning the cryopreservation of Langerhans cells. We have investigated the effect of cryopreservation on the function and phenotype of human Langerhans cells. Langerhans cells from human foreskins were isolated with the immunomagnetic microbead method using monoclonal antibodies for CD1a. Langerhans cells were cryopreserved in the presence of dimethylsulfoxide (DMSO) 10% and fetal calf serum 90%. Cryopreserved Langerhans cells were phenotypically assessed by flowcytometry using monoclonal antibodies to HLA-DR and CD1a. The ultrastructures of the Langerhans cells were compared using electron microscopy. An autologous T cell stimulation test was performed to compare the functions of cryopreserved Langerhans cells and fresh Langerhans cells. The viability of the cryopreserved Langerhans cells was able to be maintained at more than 90%. Cryopreserved Langerhans cells expressed high levels of HLA-DR and CD1a antigens and stimulated autologous T cells to an extent almost identical to that obtained from fresh Langerhans cells. These findings indicate that the cryopreservation of human Langerhans cells could lead to a breakthrough in various experiments dealing with human Langerhans cells.     

Immune functions of the human skin. Models of in vitro studies using Langerhans cells

Human skin constitutes the first immune defense barrier. Among the epidermal cells, the Langerhans cells, which belong to the dendritic cells, represent the pivotal cells in cutaneous immune reactions. The possibility of obtaining human Langerhans cells either from human skin or by in vitro generation from CD34+ hematopoietic precursors opens the way to studies reproducing the successive steps of the Langerhans cells' role in contact dermatitis.     

Hyperstimulatory CD1a+CD1b+CD36+ Langerhans cells are responsible for increased autologous T lymphocyte reactivity to lesional epidermal cells of patients with atopic dermatitis.

We studied whether abnormalities in epidermal APC could be responsible for intracutaneous T cell activation in atopic dermatitis (AD). In the absence of added Ag, patients' peripheral blood T cells demonstrated significantly increased proliferation to their autologous lesional epidermal cells (mean +/- SEM = 19,726 +/- 9,754 cpm [3H]TdR uptake) relative to epidermal cells from uninvolved AD skin (2179 +/- 697 cpm) (n = 10) (p = 0.0001, log transformed data). AD T cell proliferative responses to autologous epidermal cells were dependent upon cells expressing HLA-DR, CD1a, and CD36, and not upon keratinocytes or their cytokines. Ultrastructurally, these cells ranged from typical Langerhans cells to indeterminate cells with irregular nuclear contours. Enriched populations of lesional AD Langerhans cells were highly stimulatory for autologous T cells, whereas equal numbers of Langerhans cells from non atopic epidermis were poor stimulators, even at high concentrations. The dermal perivascular dendritic cell markers CD36 and CD1b, not usually present on normal epidermal APC, were expressed by 40 and 60% of lesional AD CD1a+ epidermal Langerhans cells, respectively. Addition of anti-CD1b to cocultures of AD epidermal cells and autologous T lymphocytes augmented T cell activation, suggesting that the expression of CD1b by AD Langerhans cells may represent over expression of a molecule functionally linked to the enhanced T cell stimulatory capacity of these cells. Thus, stimulatory signals for T cells contained within AD epidermis are carried by cells in an abnormal differentiation state as indicated by expression of phenotypic characteristics of both epidermal and dermal antigen presenting cells (HLA-DR+, CD1a+, CD1b+, CD36+). We propose that activation of autologous T cells by an altered cutaneous APC population may represent a mechanism for the hyperactive and disordered cell-mediated immune response that characterizes the dermatitic lesions of AD.     

Phenotyping of epidermal dendritic cells: clinical applications of a flow cytometric micromethod.

BACKGROUND: The differential diagnosis of inflammatory skin diseases is largely based on the patient's history and the morphological analysis of the skin lesion. Laboratory data, such as serum IgE-level and prick and patch tests, may be helpful but do not assess individual lesions. The assumption of our approach is that each individual lesion is associated with a specific microenvironment and that the immunophenotype of the two epidermal dendritic cell populations, Langerhans cells (LC) and inflammatory dendritic epidermal cells (IDEC), reflects this environment in a disease-specific manner. METHODS: A flow cytometric micromethod was developed to directly analyze individual inflammatory human skin lesions. Crude epidermal single cell suspensions were prepared by trypsinization, stained for three-color analysis with different monoclonal antibodies and the vital stain 7-amino-actinomycin-D, and finally analyzed on a single laser equipped FACScan flow cytometer. RESULTS: With a limited set of cell surface markers, such as FcepsilonRI, FcgammaRII/CD32, CD1b and CD36, highly specific diagnostic criteria for atopic dermatitis and inflamed human skin could be established. CONCLUSIONS: Phenotyping of epidermal dendritic cells is a useful procedure helpful in differential diagnosis of inflammatory skin diseases.     

Effects of ultraviolet radiation on human epidermal cell alloantigen presentation: initial depression of Langerhans cell-dependent function is followed by the appearance of T6- Dr+ cells that enhance epidermal alloantigen presentation

The effects of ultraviolet radiation (UV) on the immune parameters of human epidermis were studied. We determined the effects of both in vitro and in vivo UV on human epidermal cell surface markers and on epidermal immune function in the allogeneic epidermal cell-lymphocyte reaction (ELR). Epidermal cells obtained immediately after in vitro and in vivo UV exposure exhibited a dose-dependent decrease in alloantigen-presenting function in the ELR. This was not the result of a decrease in the number of T6+ Dr+ Langerhans cells but was due to their being less efficient at alloantigen presentation than equivalent numbers of Langerhans cells from unirradiated skin. The reduced stimulation in the ELR immediately after UV was not reversible by the addition of exogenous IL 1 or indomethacin and thus appeared to be due to a direct effect of UV on the alloantigen-presenting function of Langerhans cells. In contrast to this suppression of the epidermal immune function when epidermal cells were obtained immediately after UV, epidermal cells harvested 24 hr or later after in vivo UV exhibited a dose-dependent enhancement of allostimulatory capacity in the ELR that peaked 3 days after UV. The time course of the enhancement of allostimulation in the ELR after in vivo UV coincided with a decrease in the percentage of Langerhans cells and the appearance within the epidermis of T6- Dr+ cells, which are derived from the bone marrow, as evidenced by their expression of the bone marrow derivation markers HLe 1 and T200. Removal of Dr+ cells but not of T6+ cells from epidermal cell suspensions harvested 3 days after in vivo UV abrogated allostimulation in the ELR, demonstrating that the T6- Dr+ cells were responsible for the observed UV-induced enhancement of alloantigen presentation. Taken together, the results indicate that the timing and dosage of UV exposure are critical factors determining whether suppression or enhancement of epidermal immune function follows UV.     

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.     

Down-regulation of Toll-like receptor expression in monocyte-derived Langerhans cell-like cells: implications of low-responsiveness to bacterial components in the epidermal Langerhans cells

In the skin, there are unique dendritic cells called Langerhans cells, however, it remains unclear why this particular type of dendritic cell resides in the epidermis. Langerhans cell-like dendritic cells (LCs) can be generated from CD14(+) monocytes in the presence of GM-CSF, IL-4, and TGF-beta1. We compared LCs with monocyte-derived dendritic cells (DCs) generated from CD14(+) monocytes in the presence of GM-CSF and IL-4 and examined the effect of exposure to two distinct bacterial stimuli via Toll-like receptors (TLRs), such as peptidoglycan (PGN) and lipopolysaccharide (LPS) on LCs and DCs. Although stimulation with both ligands induced a marked up-regulation of CD83 expression on DCs, PGN but not LPS elicited up-regulation of expression CD83 on LCs. Consistent with these results, TLR2 and TLR4 were expressed on DCs, whereas only TLR2 was weakly detected on LCs. These findings suggest the actual feature of epidermal Langerhans cells with low-responsiveness to skin commensals.     

In vivo ultraviolet-exposed human epidermal cells activate T suppressor cell pathways that involve CD4+CD45RA+ suppressor-inducer T cells

In vivo UV exposure of human epidermis abrogates the function of CD1+DR+ Langerhans cells and induces the appearance of CD1-DR+ Ag-presenting macrophages. Epidermal cells from UV-exposed skin, in contrast to epidermal cells from normal skin, potently activate autologous CD4+ T cells, and, in particular, the CD45RA+ (2H4+) (suppressor-inducer) subset. We therefore determined whether UV-exposure in humans leads to a T cell response in which suppression dominates. Autologous blood T cells were incubated with epidermal cell suspensions from in vivo UV-irradiated skin. After activation, repurified T cells were transferred in graded numbers to autologous mononuclear cells (MNC) stimulated with PWM and the resultant IgG production analyzed by ELISA. Relative to T cells activated by unirradiated control epidermal cells, T cells activated by UV-exposed epidermal cells demonstrated enhanced capacity to suppress IgG production (n = 6; p less than or equal to 0.03). Within the T cell population, CD8+ cells stimulated by UV-exposed epidermal cells could be directly activated to suppress PWM-stimulated MNC Ig production if IL-2 was provided in the reaction mixture. The suppressive activity was also transferable with purified CD4+ T cells stimulated by UV-exposed epidermal cells (n = 10; p less than or equal to 0.01), and was radiosensitive. Suppression was decreased when PWM-stimulated MNC were depleted of CD8+ T cells before mixing with CD4+ T cells activated by UV-exposed epidermal cells, suggesting indirect induction of CD8+ Ts cells contained within the responding MNC populations. Indeed, physical depletion of CD45RA+ cells resulted in total abrogation of the suppressor function contained in the CD4+ T cells. Activation of suppressor function was critically dependent on DR+ APC contained in UV-exposed epidermis. The data suggest that UV-exposure modulates cutaneous APC activity in humans, as in mice, such that the dominant immune response is tilted toward suppression. These mechanisms in normal individuals may function to dampen responses to UV-induced endogenous Ag that are pathogenic in autoimmune disorders. However, these mechanisms might also facilitate the growth of UV-induced skin cancers.     

Infiltration by inflammatory cells required for solar-simulated ultraviolet radiation enhancement of skin tumor growth

In this study we compared the effects of subinflammatory and inflammatory doses of solar-simulated ultraviolet (UV) radiation on enhancement of skin tumor growth, sensitization to haptens and cellular changes within the epidermis of C3H/HeN mice. Tumors transplanted into mice 3 days after exposure to inflammatory, but not subinflammatory, doses of UV radiation had a higher growth rate than those tumors inoculated into unirradiated control mice. Both doses of UV radiation suppressed the induction of contact hypersensitivity and induced tolerance when hapten was painted onto the skin 3 days after irradiation. Skin exposed to the higher, but not the lower, dose of UV radiation contained significantly increased numbers of CD11b+, CD45+ MHC class II- and CD45+ MHC class II(hi) inflammatory cells 3 days post-irradiation. The immunosuppression correlated with a reduction in Langerhans cells and dendritic epidermal T cells. Collectively, this suggests that suppression to contact sensitizers is due to the UV radiation effects on Langerhans cells and dendritic epidermal T cells. While these effects may also suppress the induction of anti-tumor immunity, at higher doses of UV radiation inflammatory cells may enhance tumor growth by a non-immunological mechanism.     

Relay of Herpes Simplex Virus between Langerhans Cells and Dermal Dendritic Cells in Human Skin

The mechanism by which immunity to Herpes Simplex Virus (HSV) is initiated is not completely defined. HSV initially infects mucosal epidermis prior to entering nerve endings. In mice, epidermal Langerhans cells (LCs) are the first dendritic cells (DCs) to encounter HSV, but it is CD103⁺ dermal DCs that carry viral antigen to lymph nodes for antigen presentation, suggesting DC cross-talk in skin. In this study, we compared topically HSV-1 infected human foreskin explants with biopsies of initial human genital herpes lesions to show LCs are initially infected then emigrate into the dermis. Here, LCs bearing markers of maturation and apoptosis formed large cell clusters with BDCA3⁺ dermal DCs (thought to be equivalent to murine CD103⁺ dermal DCs) and DC-SIGN⁺ DCs/macrophages. HSV-expressing LC fragments were observed inside the dermal DCs/macrophages and the BDCA3⁺ dermal DCs had up-regulated a damaged cell uptake receptor CLEC9A. No other infected epidermal cells interacted with dermal DCs. Correspondingly, LCs isolated from human skin and infected with HSV-1 in vitro also underwent apoptosis and were taken up by similarly isolated BDCA3⁺ dermal DCs and DC-SIGN⁺ cells. Thus, we conclude a viral antigen relay takes place where HSV infected LCs undergo apoptosis and are taken up by dermal DCs for subsequent antigen presentation. This provides a rationale for targeting these cells with mucosal or perhaps intradermal HSV immunization.     

Lectin ligands on human dendritic cells and identification of a peanut agglutinin positive subset in blood

As only a few cell surface markers for dendritic cells (DC) have been identified to date, this study examined the expression of ligands for lectin on different human DC populations. The ability of Concanavalin A (Con A), Wheat Germ Agglutinin (WGA), peanut agglutinin (PNA), and Helix pomatia (HPA) to bind to cell lines and PBMC and DC populations was analyzed by flow cytometry and specificity of binding confirmed using inhibitory and noninhibitory sugars. The cell lines showed non-lineage-restricted binding with Con A and WGA, independent of sialidase treatment. HPA and PNA bound to a restricted number of lines, but showed broad reactivity after sialidase treatment. The peripheral blood mononuclear cells (PBMC) and directly isolated blood DC, activated CD83(+) blood DC, epidermal Langerhans cells (LC), and monocyte-derived DC (Mo-DC) showed strong binding of Con A and WGA, both before and after sialidase treatment. No HPA binding ligands were detected on PBMC populations, including directly isolated blood DC. Following sialidase treatment CD3(+), CD16(+), and a subset of CD19(+) lymphocytes bound HPA. The lectin PNA bound weakly to CD14(+) monocytes and a subpopulation of circulating DC that were HLA-DR(hi)CDw123 Dr(hi)CDw123(dim)/(neg)CD11c(+). The HLA-DR(mod)CDw123(hi)CD11c(neg) subpopulation did not bind PNA. Without sialidase treatment LC expressed both HPA and PNA ligands, but these were either absent on activated CD83(+) blood DC or weakly expressed on Mo-DC. Following sialidase treatment PBMC populations, activated CD83(+) blood DC, and Mo-DC became PNA positive. Thus human DC express several lectin ligands and PNA binding identifies a subset of blood DC. That may reflect discrete changes associated with stages of DC development or functional maturation.     

A developmental study of murine epidermal Langerhans cells

Prospective skin prior to invasion by neural crest cells was dissected from 10.5-day mouse embryos and cultivated in chick embryo hosts. The graft tissue was prepared for the demonstration of both mouse and chick cells, pigment cells, and Langerhans cells. Chick cells were not found in the graft mouse epidermis; however, ATPase-positive and osmium iodide-positive cells were present. Electron microscopic examination revealed that, in younger grafts, only indeterminate cells could be found among the keratinocytes. In older grafts, both indeterminate cells and Langerhans cells with granules were seen. The evidence affirms that epidermal Langerhans cells are not related to pigment cells.Based on the developmental nature of Birbeck (Langerhans) granules from the cytomembrane, it is proposed that the granule no longer be considered as specific to and characteristic of epidermal Langerhans cells. Rather, Langerhans cells should be defined as ATPase-positive, desmosome-free cells within stratified squamous, potentially keratinizing, epithelia. Thus epidermal, ATPase-positive indeterminate cells and such cells with Birbeck granules both should be considered as components of the Langerhans cell series.Normal chick skin does not show ATPase-positive cells. However, when 10.5-day mouse embryo ectoderm was inserted under the ectoderm of chick embryos, the resulting chimeric epidermis possessed ATPase-positive cells. It is proposed that epidermal Langerhans cells are of ectodermal origin.     

Effect of glucocorticosteroids on epidermal cell-induced immune responses

Recent reports indicate that pharmacologic doses of glucocorticosteroids induce structural alterations in epidermal Langerhans cells. In this study we hoped to determine whether steroid-induced changes in Langerhans cell surface characteristics are paralleled by alterations in Langerhans cell-dependent immunologic functions of epidermal cells. We found that both topically and systemically administered steroids led to a dose-dependent reduction in the number of Ia-bearing epidermal cells. This numerical decrease was paralleled by a substantial impairment of Langerhans cell-dependent immunologic functions of epidermal cells in that their capacity to induce antigen-specific, syngeneic, and allogeneic proliferation of T cells from non-steroid-treated animals was substantially reduced. The capacity of epidermal cells to generate ETAF activity, however, was not adversely affected by the steroid treatment. After cessation of treatment, Langerhans cell numbers and Langerhans cell-dependent in vitro functions slowly and gradually returned to normal values. We propose that the ability of glucocorticosteroids to interfere with the generation of T cell-dependent immune responses may be due, at least in part, to their interference with antigen-presenting cell function.     

Dose response of Langerhans cells in mouse footpad epidermis after X irradiation

Effects of a range (2-50 Gy) of single doses of 250 kV X rays on epidermal Langerhans cells in vivo were quantified in groups of CBA/CaH mice. Animals were sacrificed and compared with controls on the 10th day after local irradiation of their hind feet, when Langerhans cell numbers were at a minimum. ATPase-positive Langerhans cells in sheets of footpad epidermis were counted by light microscopy and cells with Birbeck granules were enumerated by electron microscopy. Both methods revealed a dose-dependent loss of Langerhans cells after ionizing radiation. Fifty percent of the ATPase-positive cells were lost after 14.4 +/- 1.3 Gy, and 50% of Birbeck granule-containing cells were lost after 17.9 +/- 4.2 Gy, suggesting that differentiated epidermal Langerhans cells are radioresistant. Loss of equivalent proportions of ATPase-positive and ultrastructurally identifiable cells after a range of doses indicates that X rays do not merely alter Langerhans cell surface markers but actually deplete the epidermal population of these cells.     

Use of periodate-lysine-paraformaldehyde for the fixation of multiple antigens in human skin biopsies

Periodate-lysine-paraformaldehyde (PLP) has been proposed as a fixative for glycoprotein antigens which should stabilize periodate oxidized polysaccharide chains through lysine mediated crosslinks, either directly or by the intermediation of formaldehyde. In spite of premises and attempts reported in the literature, this fixative has never become popular for the study of membrane antigens of immune system cells, which leads to doubts on its real efficacy. We have addressed this issue in biopsies of human skin and found that PLP followed by cryoprotection with 30% sucrose and cryosectioning, or PLP fixation of isolated epidermal sheets, consistently provided for good preservation of morphology and intense labeling of major histocompatibility complex class II molecules, CD 1 a, CD4, CD8, E-cadherin, cytokeratins in general, cytokeratin-18 in particular, and bromodeoxyuridine, incorporated by cycling cells in vitro, and for the demonstration of tyrosinase enzyme activity. PLP-fixed, osmicated and epon-embedded epidermal sheets proved as good as sheets fixed with a mixture of formaldehyde and glutaraldehyde for electron microscopic morphological analysis. Also, these sheets were amenable to immunoperoxidase staining of Langerhans cell membrane antigen CD1a and keratinocyte membrane antigen E-cadherin before being osmicated and prepared for electron microscopy. In a parallel paper, we had also shown that oral mucosa biopsies fixed in PLP showed good morphology and immunolabeling of CD54, CD80, CD83 and CD86. Therefore, we conclude that PLP can be proposed as a multi-task fixative for light and electron microscopic analysis of membrane, cytoplasmic and nuclear antigens of immune system cells and keratinocytes.     

Concurrent exposure to a dectin-1 agonist suppresses the Th2 response to epicutaneously introduced antigen in mice

Background

Epicutaneous sensitization with protein allergen that induces predominant Th2 responses is an important sensitization route in atopic dermatitis. Fungal components have been shown to modulate Th cell differentiation. However, the effects of fungal components on epicutaneous sensitization are unclear.

Results

In this study, we showed that co-administration of curdlan, a dectin-1 agonist, during epicutaneous ovalbumin sensitization of BALB/c mice decreased the IL-5 and IL-13 levels in supernatants of lymph node cell ovalbumin reactivation cultures. Mechanistically, curdlan co-administration decreased IL-4 and IL-1β expressions in draining lymph nodes. Curdlan co-administration also lower the migration of langerin⁺ CD103^- epidermal Langerhans cells into draining lymph nodes at 96 hours post-sensitization which might be attributed to decreased expressions of IL-18 and IL-1β in patched skin. Moreover, adoptive transfer of CFSE-labeled transgenic CD4 T cells confirmed that curdlan co-administration decreased the proliferation and IL-4-production of ovalbumin -specific T cells primed by epidermal Langerhans cells.

Conclusions

These results indicated that concurrent exposure to a dectin-1 agonist suppresses the epicutaneously induced Th2 response by modulating the cytokine expression profiles in draining LNs and the migration of epidermal Langerhans cells. These results highlight the effects of fungal components on epicutaneous allergen sensitization in atopic diseases.     

Activated CD34-derived Langerhans cells mediate transinfection with human immunodeficiency virus

Langerhans cells (LCs) are a subset of dendritic cells (DCs) that reside within epidermal and mucosal tissue. Because of their location, LCs are potentially the first cells to encounter human immunodeficiency virus (HIV) during sexual transmission. We report that LCs purified from CD34(+)-derived DCs can facilitate the transinfection of target cells but only after activation. Virions were observed in an intracellular compartment that contains several tetraspanins, in addition to the unique LC markers langerin and CD1a. This reveals that the trafficking of HIV within LCs is reminiscent of that which occurs in mature monocyte-derived DCs and that it varies with the activation state of the cell. The observation that activated LCs can mediate transinfection suggests a potential role for these cells in the known increase in HIV transmission associated with sexually transmitted infections that would cause inflammation of the genital lining.     

Cell surface expression of invariant gamma-chain of class II histocompatibility antigens in human skin

A rat monoclonal antibody (McAb 21:9) reactive with the human invariant gamma-chain of class II major histocompatibility complex (MHC)-encoded antigens was isolated and was shown to react with the carbohydrate-carrying, COOH-terminal part of the gamma-chain. The McAb 21:9 binds to a molecule that is identified as the gamma-chain for the following reasons: it has an apparent m.w. of 33,000, similar to that of the gamma-chain; it has a two-dimensional gel migration pattern identical to that of the gamma-chain; and it associates with immature, but not processed class II antigens. When used for immunohistochemical staining on sections of normal human skin, only dendritic, class II MHC antigen, and anti-Leu-6 reactive Langerhans cells are labeled in the epidermis. HLA-DR-expressing keratinocytes present in the tuberculin reaction, cutaneous T cell lymphoma, and lichen planus, however, did not react with the anti-gamma-chain antibody, nor with a HLA-DQ-reactive antibody. Cell surface expression of the gamma-chain was observed on 1 to 3% of normal viable epidermal cells in suspension. By using double indirect immunofluorescence, it was possible to demonstrate the simultaneous binding of anti-gamma-chain, anti-HLA-DR, anti-Leu-10, and anti-Leu-6 antibodies, respectively, on the same cells, thus confirming their identity as Langerhans cells. The presence of the gamma-chain on the surface of the immunocompetent Langerhans cells may indicate that the cell surface, not the cytoplasm as has been suggested, is the site of the primary function of the gamma-chain.