Comparative analysis of CD80 and CD86 on human Langerhans cells: expression and function

Abstract Although both CD80 (B7–1) and CD86 (B7–2/B70) have been recently identified in cultured human Langerhans cells (LC), little is known of the role and regulatory properties of CD80 and CD86 on human LC. We present here the results of a study comparing the expression and function of CD80 and CD86 in human LC using the T-helper type-1 cytokines IL-2 and interferon γ (IFN)-γ, and the T-helper type-2 cytokines IL-10, IL-4 and granulocyte/macrophage colony-stimulating factor (GM-CSF). Freshly isolated human LC expressed little CD80 and CD86 in vitro, but the expression of both molecules was rapidly induced during a 72-h incubation with cytokines and the expression of CD86 occurred much earlier and more strongly than that of CD80. The expression of both CD80 and CD86 was upregulated by GM-CSF and downregulated by IL-10, and the expression of CD86, but not that of CD80, was upregulated by both IL-4 and IFN-γ. Finally, pretreatment of LC with GM-CSF and IFN-γ, but not with IL-4, enhanced the alloreactive T-cell proliferation induced by the LC, and IL-10 pretreatment of LC decreased their capacity for alloreaction. These results indicate that the expression of both CD80 and CD86 on human LC may be regulated by these cytokines (IL-2, IL-4, GM-CSF, IFN-γ and IL-10) secreted from helper T cells infiltrating into the inflammatory microenvironment. Received: 4 December 1997     

In situ expression of the costimulatory molecules CD80 and CD86 on Langerhans cells and inflammatory dendritic epidermal cells (IDEC) in atopic dermatitis

Abstract The functional expression of costimulatory molecules on antigen-presenting cells may be a key event in the pathogenesis of atopic dermatitis (AD). Recently, the expression of CD86 (B7-2/B70) has been demonstrated on CD1a⁺ epidermal dendritic cells (DC) in AD lesions by immunohistological and functional analysis. Therefore, we sought to further characterize the in situ expression of costimulatory molecules on these cells, considering the two subpopulations of (1) CD1a⁺⁺⁺/CD11b^– Langerhans cells (LC) containing Birbeck granules and (2) CD1a⁺/CD11b⁺⁺⁺ inflammatory dendritic epidermal cells (IDEC), devoid of Birbeck granules, from AD and other inflammatory skin diseases. Flow cytometry, skin mixed lymphocyte reactions (SMLR) and immunohistological analysis were performed, and showed that IDEC and not LC are the relevant cells expressing the costimulatory molecules CD80 and CD86 in situ. This expression varied with the underlying diagnosis, with AD showing the highest expression of both CD80 and CD86 in situ. Furthermore, the expression of CD80, CD86 and CD36 were significantly correlated. With short-term culture, both CD80 and CD86 were further upregulated on LC and IDEC. Finally, anti-CD86 antibody reduced the stimulatory activity of epidermal DC. These results indicate that costimulatory molecules on LC and IDEC might play a role in the pathogenesis of AD. Received: 7 June 2000 / Accepted: 21 January 2001     

Interferon-gamma differentially regulates CD80 (B7-1) and CD86 (B7-2/B70) expression on human Langerhans cells

CD80 (B7-1) and CD86 (B7-2/B70) have recently been identified in cultured human Langerhans cells (LCs), although their role and regulatory properties remain unclear. We present our comparison of the expression of the molecules, mRNAs and the function between CD80 and CD86 in human LCs treated by interferon γ (IFN_-γ). We examined the regulatory properties of CD80 and CD86 expression in human LCs pretreated with IFN_-γ. Flow cytometric analysis indicated that the mean fluorescence intensity of CD86 but not CD80 was enhanced. However, the percentage modulation of both CD80 and CD86 positive cells were significantly up-regulated in a dose-dependent manner, after 48-h culturing with IFN_-γ. The regulatory properties of CD80 and CD86 mRNA expressions in human LC were studied using polymerase chain reaction methods. We found that both CD80 and CD86 mRNA of enriched LCs following IFN_-γ pretreatment for 12 h were higher than those without pretreatment. We have demonstrated that the primary allogeneic mixed epidermal cell-lymphocyte reaction induced by human LCs treated by IFN_-γ increased in a dose-dependent manner. There was a 61.5% inhibition by anti-CD86 monoclonal antibody and a 32.5% inhibition by anti-CD80 monoclonal antibody. These data indicate that the CD80 and CD86 expression of human LCs may be differently regulated by IFN_-γ.     

Reappearance of CD1a antigenic sites after endocytosis on human Langerhans cells evidenced by immunogoldrelabeling

We show evidence of the reappearance of CD1a antigenic sites on the surface of human isolated Langerhans cells after internalization of CD1a antigen/CD1a monoclonal antibody (BL6) complexes. The internalization was visualized by immunogoldlabeling, and the reappearance of CD1a binding sites was shown by immunogoldrelabeling. The relabeling was distinguished from the labeling either by using two sizes of gold granules (15 and 5 nm) or by quantitative estimation with one size of gold granules, before and after the relabeling. This reappearance of sites is cycloheximide insensitive, and is evidenced, even if the transfer of gold particles to lysosomes is blocked by the monensin. These results suggest that the reexpression of CD1a antigens is due to antigens stored in the cytoplasm or to recycling of internalized sites. Some immunolabeled Birbeck granules were observed in continuity with the plasma membrane, which demonstrates their membrane origin and their involvement in the endocytosis process. However, the weak labeling of these organelles makes us believe that they are not specialized CD1a endocytosis structures.     

Effects of solar-simulated radiation dose fractionation on CD1a+ Langerhans cells and CD11b+ macrophages in human skin

BACKGROUND: There are few human studies investigating the immunosuppressive effects of exposure to solar-simulated radiation (SSR) and its relationship with sunburn/erythema, and few comparative data on the importance of SSR exposure regimens. OBJECTIVES: To evaluate whether SSR-induced erythema is a reliable end-point for assessing damage to antigen-presenting cells (APCs) in human skin. METHODS: We compared the relationship between SSR-induced erythema and alterations in epidermal CD1a+ Langerhans cells (LCs) and CD11b+ macrophages in human volunteers after single exposures to 0, 0.5, 1, 2 or 3 minimal erythema doses (MED). We also investigated whether SSR exposure leads to an accumulation or accommodation of the same end-points by comparing the effects of a relatively low cumulative SSR dose (3 MED) given in varying daily dose fractions (4 x 0.75 MED, 2 x 1.5 MED and 1 x 3 MED). RESULTS: Single SSR exposures induced a dose-dependent increase in erythema. CD1a+ LCs remaining in the irradiated epidermis showed a dose-dependent increase in cell size and altered morphology. Significant depletion of CD1a+ LCs and presence of CD11b+ macrophages only occurred in sites irradiated with 2 MED and 3 MED. Dose fractionation had no effect on the final erythemal response but the 4 x 0.75 MED and 1 x 3 MED protocols were better tolerated than 2 x 1.5 MED for alterations in CD1a+ LC and CD11b+ cell numbers. In contrast, dose fractionation protected against alterations in CD1a+ LC morphology or cell size. CONCLUSIONS: We found that erythema is a poor indicator of alterations in epidermal APCs and that dose fractionation is an important parameter in the immunological effects of ultraviolet radiation.     

CD1a molecules traffic through the early recycling endosomal pathway in human Langerhans cells

In this work, we studied the localization and traffic of CD1a molecules in human epidermal Langerhans cells and the ability of these cells to stimulate CD1a-restricted T cell clones. We found that CD1a was spontaneously internalized into freshly isolated Langerhans cells, where it was rapidly distributed to the early/sorting endosomes and then to the early/recycling endosomes. In the latter compartments, CD1a colocalized with Rab11, a small GTPase known to be involved in the recycling of transmembrane proteins from early endosomes to the cell surface. In the steady state, intracellular CD1a was mainly located in Rab11+ recycling endosomal compartments. When endocytosis was blocked, intracellular CD1a moved rapidly from the early/recycling endosomes to the cell surface where it accumulated. The resultant increase in the cell surface expression of CD1a enhanced the capacity of Langerhans cells to stimulate a CD1a-restricted T cell clone. These findings are consistent with a dynamic exchange of CD1a between recycling compartments and the plasma membrane and suggest that the antigen-presenting function of CD1a depends on its traffic through the early/recycling endosomal pathway.     

Photohapten TCSA painting plus UVA irradiation of murine skin augments the expression of MHC class II molecules and CD86 on Langerhans cells

Hapten painting of skin is known to augment the expression of major histocompatibility complex (MHC) class II, CD54, and CD86 on Langerhans cells. We investigated whether painting with 3,3',4',5-tetrachlorosalicylanilide (TCSA), the representative photohapten, and subsequent irradiation with ultraviolet A (UVA) alter the expression of these surface molecules on epidermal Langerhans cells (LC). BALB/c mice were painted with 5 microl of 0.1% TCSA on the earlobes and irradiated with 16 J/cm2 (at 365 nm) of UVA. Epidermal cells were prepared from these earlobes 24 h later, and the levels of MHC class II, CD54, CD80, and CD86 on these cells were analyzed by flow cytometry. As compared with untreated earlobes, the levels of MHC class II and CD86 on LC were markedly augmented and those of CD54 and CD80 were slightly elevated in earlobes treated with TCSA/UVA. Since neither TCSA painting nor UVA exposure alone enhanced the expression, both treatments were essential for enhancement. A dot plot analysis showed the presence of subpopulations of LC expressing MHC class II and CD86 at high levels. The percentage of these highly expressing LC was increased with increasing concentrations of TCSA and doses of UVA up to 1% and 24 J/cm2, respectively. In addition, keratinocyte expression of CD54 was also augmented by TCSA plus UVA. These results suggest that photohaptens, with following UVA exposure, augment the expression of immunologically functional molecules on LC as do ordinary haptens, leading to effective sensitization and elicitation of contact photoallergy.     

Functional CD86 (B7-2/B70) is predominantly expressed on Langerhans cells in atopic dermatitis

Recently, we reported the functional expression of CD86 on cultured human Langerhans cells derived from normal epidermis. In the present study, we investigated the expression and function of co-stimulatory molecules in the pathogenesis of atopic dermatitis. In immunohistochemical analysis, CD80 and/or CD86 were detected on dendritic-shaped cells not only in the epidermis but also in the dermis in the inflammatory lesions of atopic dermatitis (n = 12). CD80 was expressed in only five cases (42%), while CD86 was expressed in all cases (100%). These molecules were not detected in normal control subjects (n = 8). In non-lesional skin of atopic dermatitis (n = 4). CD86 but not CD80 was detected in one case. CD86 was preferentially induced on dendritic-shaped cells in positive patch test sites to Dermatophagoides pteronyssinus or house dust allergen in atopic dermatitis (n = 4). The CD80- or CD86-positive cells were confirmed as Langerhans cells by double immunostaining using anti-CD1a monoclonal antibody. Neither CD86 over that CD80 was detected n keratinocytes. Similar results of the stronger expression of CD86 over that of CD80 were obtained from psoriasis vulgaris (n = 11) and from contact dermatitis (n=7), although CD86 was expressed only in 57% of the contact dermatitis cases. The percentage of Langerhans cells positive for CD86 was higher than for CD80, i.e. 48% compared with 9%, respectively, in the epidermis of lesional skin of atopic dermatitis (n=8). The expression rate of these molecules on Langerhans cells increased in the dermis. To investigate the function of co-stimulatory molecules on Langerhans cells in atopic dermatitis, we conducted an inhibition test with antibodies. Anti-CD86 monoclonal antibody almost completely nhibited T-cell proliferation stimulated with crude extract of D. pteronyssinus in the presence of epidermal cells as antigen-presenting cells, whereas anti-CD80 monoclonal antibody produced less of an inhibitory effect. These data indicate that CD86 expressed on Langerhans cells may play an important part in the pathogenesis of atopic dermatitis.for Investigative Dermatology. Washington, DC (1–5 May 1996).     

Simultaneous colloidal gold immunoelectronmicroscopy labeling of CD1a, HLA-DR, and CD4 surface antigens of human epidermal Langerhans cells

The simultaneous demonstration of three surface antigens of Langerhans cells (LC) within LC-enriched fresh epidermal cell suspensions from normal human skin was achieved, by means of a triple immunogold (IG) staining, using commercially available monoclonal antibodies (moAb) and immunoreagents, in a simple pre-embedding immunoelectronmicroscopy (IEM) procedure. As a result, suspended LC were triple-stained as follows: gold particles of 40 nm revealed the CD1 a antigen; gold particles of 20 nm revealed the HLA-DR antigen; and gold particles of 5 nm revealed the CD4 antigen. All the observed epidermal Birbeck granule-bearing LC were triple IG stained, thus simultaneously expressing the three surface differentiation antigens, which are therefore different from but coexisting with each other. The present investigation assesses the constant simultaneous expression by Birbeck granules bearing LC of not only CD1a and HLA-DR antigens, but also CD4 antigen. The occurrence is therefore excluded of both CD1a-positive HLA-DR-negative LC subpopulation and CD4-negative LC subpopulation, presumably due to the different sensitivity of the various procedures performed. The hypothetical occurrence of CD4-positive, CD1a-, and/or HLA-DR-negative LC subpopulations is ruled out. This study reaffirms indeed the high specificity and sensitivity of the IG-IEM method for a precise detection of the cell surface antigens of LC, and states the suitability of the IG labeling even for accurate multiple IEM stainings of LC.     

Epitopes for CD1a, CD1b, and CD1c antigens are differentially mapped on Langerhans cells, dermal dendritic cells, keratinocytes, and basement membrane zone in human skin.

BACKGROUND: CD1 antigens are classified serologically into at least three groups, CD1a, CD1b, and CD1c, and many kinds of monoclonal antibodies are available for each subgroup of CD1 antigens. CD1a, CD1b, and CD1c antigens have been shown to be selectively and differentially expressed on epidermal Langerhans cells and dermal dendritic cells in normal human skin. OBJECTIVE: The objective was to further delineate the localization of epitopes of CD1 antigens in human skin. METHODS: We examined the immunoreactivity of 14 different CD1 antibodies (seven CD1a, five CD1b, and two CD1c antibodies) with the immunoperoxidase technique. We also studied the reactivity of NU-T2 (CD1b) antibody by immunogold electron microscopy. RESULTS: The epitopes for CD1a, CD1b, and CD1c antigens were differentially mapped on epidermal Langerhans cells, dermal dendritic cells, keratinocytes, the luminal portion of eccrine gland ducts, and the basement membrane zone in human skin. CONCLUSION: These CD1 antibodies may be useful to analyze the phenotypic alteration of immune and nonimmune cells in various skin diseases.     

Adhesion molecules CD11a, CD18, and ICAM-1 on human epidermal Langerhans cells serve a functional role in the activation of alloreactive T cells.

Binding of antigen-presenting cells (APC) to T cells via adhesion molecules is thought to deliver accessory signals that are required for efficient T-cell activation. To determine whether Langerhans cells (LC) express relevant adhesion molecules on their surfaces, we employed two-color immunofluorescence. Human epidermal cells (EC), Ficoll-enriched for LC (greater than 10%), were incubated with monoclonal antibodies (MoAb) specific for the adhesion molecules CD11a (LFA-1 alpha), CD18 (LFA-1 beta), or ICAM-1; staining was evaluated by fluorescence microscopy. After 12 h of culture only HLA-DR+ cells (LC) expressed CD11a, CD18, and ICAM-1. As a test for the functional relevance of such adhesion molecule expression, we examined the capacity of the above MoAb to block LC stimulation of alloreactive T cells: EC were co-cultured with allogeneic peripheral blood mononuclear leukocytes (PBML) for 5 d in the presence or absence of MoAb; proliferation was measured by [3H]-thymidine uptake. MoAb against CD11a, CD18, or ICAM-1 reduced the allostimulatory capacity of LC by greater than 70%; combinations of these MoAb reduced proliferation even more (90%). We conclude that interaction of adhesion molecules on LC with ligands on T cells is required for optimal allo-antigen-dependent T-cell activation, perhaps by delivering accessory signals.     

A potential role for CD1a molecules on human epidermal Langerhans cells in allogeneic T-cell activation.

The structural similarities of CD1a molecules to major histocompatibility complex (MHC) class I antigens, as well as their expression on epidermal antigen-presenting cells suggest that CD1a molecules might be involved in the cutaneous immune response. In the present study, we investigated the effect of different anti-CD1a monoclonal antibodies (BL6, DMC1, and Na1/34) on T cell proliferation induced by allogeneic epidermal cells in vitro. A significant inhibition of the mixed skin cell-lymphocyte reaction was obtained with BL6 and DMC1 monoclonal antibodies (MoAb), which recognize the same epitope on CD1a molecule. The observed inhibition could not be related to a steric hindrance of MHC class II molecules, because Na1/34 MoAb, which reacts with another epitope on CD1a molecule, had no significant effect. BL6 and DMC1 MoAb interfered with an early event of T-cell activation, as shown by a time-course study. In the presence of these MoAb, the addition of exogenous interleukin 2 did not restore T-cell proliferation. Furthermore, the inhibitory effect of anti-CD1a MoAb was not mediated by a suppressor factor released by Langerhans cells (LC). These present data suggest that CD1a molecule may have an important function in self peptide presentation by human Langerhans cells.     

Epitope mapping of CD1a, CD1b, and CD1c antigens in human skin: differential localization on Langerhans cells, keratinocytes, and basement membrane zone.

CD1 antigens are classified into at least three groups, CD1a, CD1b, and CD1c. In order to delineate the localization of epitopes of CD1 antigens in human skin, we examined the immunoreactivity of fourteen different CD1 antibodies (seven CD1a, five CD1b, and two CD1c antibodies). The epitopes for CD1a, CD1b, and CD1c are differentially localized on epidermal Langerhans cells, dermal dendritic cells, keratinocytes, the luminal portion of eccrine gland ducts, and the basement membrane zone in normal human skin.     

Epidermal Langerhans cells efficiently mediate CD1a-dependent presentation of microbial lipid antigens to T cells

Langerhans cells are a critical component of skin immunity, capable of capturing protein antigens in the epidermis and presenting them to specific T cells in the context of major histocompatibility complex class II molecules. Recently, a major histocompatibility complex independent pathway of lipid antigen presentation has been identified and is mediated by molecules of the CD1 family (CD1a, CD1b, CD1c, and CD1d). Because Langerhans cells are professional antigen-presenting cells and express CD1a molecules prominently, we hypothesized that Langerhans cells might play a role in T cell responses directed against not only peptide antigens but also lipid antigens. Here, we show that freshly isolated immature Langerhans cells as well as mature Langerhans cells that have migrated from the epidermis are efficient in presenting foreign microbial lipid antigens to specific T cells whereas dermal dendritic cells express much less CD1a molecules and function inefficiently. Further, we found that Langerhans cells migrating from epidermal sheets that were exposed to microbial lipid antigens expressed lipid-antigen-loaded CD1a molecules on the cell surface, resulting in activation of specific T cells. These results underscore an outstanding ability of Langerhans cells to mediate CD1a-dependent lipid antigen presentation. Thus, Langerhans-cell-mediated skin immunity may involve T cell recognition of both peptide and lipid antigens.     

The interaction between Langerhans cells and CD4+ T cells.

The human skin is increasingly exposed to haptens and environmental protein antigens. Because Langerhans cells represent the outermost network of MHC class II+ antigen presenting cells in mammalians, we investigated their interaction with CD4+ T cells. Hapten-modified Langerhans cells induced proliferation and IL-2 production in naive resting CD4+ T cells. T cells activated in this manner and subsequently cultured with IL-2 mediated contact sensitivity in vivo and produced IL-2 but no IL-4 upon restimulation in vitro. Thus they corresponded to Th1 cells. Repeated stimulation with Langerhans cells induced a modulation of the lymphokine pattern: IL-2- and IL-4-producing Th0-like cells were identified after 3 to 4 rounds of restimulation; after > 5 rounds, Th2-like cells with an IL-4+IL-2- pattern and the capacity for inducing IgE synthesis in B cells was identified. Th2 cells were also recently found to mediate inflammatory tissue lesions containing a cellular infiltrate. This demonstrates that Langerhans cells may activate resting CD4+ T cells, Th1-, Th0- and Th2-like cells. It further shows that Langerhans cells may promote the differentiation of postthymic CD4+ T cells into subsets with distinct immune functions: Th1 cells which have the potential to mediate inflammatory reactions such as allergic contact sensitivity and Th2 cells which may be responsible for abnormalities associated with atopic dermatitis, such as elevated IgE and inflammatory skin lesions containing a cellular infiltrate.