Maturational steps of bone marrow-derived dendritic murine epidermal cells. Phenotypic and functional studies on Langerhans cells and Thy-1+ dendritic epidermal cells in the perinatal period

The adult murine epidermis harbors two separate CD45+ bone marrow (BM)-derived dendritic cell systems, i.e., Ia+, ADPase+, Thy-1-, CD3- Langerhans cells (LC) and Ia-, ADPase-, Thy-1+, CD3+ dendritic epidermal T cells (DETC). To clarify whether the maturation of these cells from their ill-defined precursors is already accomplished before their entry into the epidermis or, alternatively, whether a specific epidermal milieu is required for the expression of their antigenic determinants, we studied the ontogeny of CD45+ epidermal cells (EC). In the fetal life, there exists a considerable number of CD45+, Ia-, ADPase+ dendritic epidermal cells. When cultured, these cells become Ia+ and, in parallel, acquire the potential of stimulating allogeneic T cell proliferation. These results imply that CD45+, Ia-, ADPase+ fetal dendritic epidermal cells are immature LC precursors and suggest that the epidermis plays a decisive role in LC maturation. The day 17 fetal epidermis also contains a small population of CD45+, Thy-1+, ADPase-, CD3- round cells. Over the course of 2 to 3 wk, they are slowly replaced by an ever increasing number of round and, finally, dendritic CD45+, Thy-1+, CD3+ EC. Thus, CD45+, Thy-1+, ADPase-, CD3- fetal EC may either be DETC precursors or, alternatively, may represent a distinctive cell system of unknown maturation potential. According to this latter theory, these cells would be eventually outnumbered by newly immigrating CD45+, Thy-1+, CD3+ T cells--the actual DETC.     

Thy-1+ epidermal cells proliferate in response to concanavalin A and interleukin 2

Mouse epidermal cells (EC) are composed of at least two phenotypically discrete populations of cells that in epidermal sheets have a dendritic morphology: Ia+ Langerhans cells (LC) and dendritic, bone marrow-derived, Ia- cells that express Thy-1 antigen (Thy-1+ dEC). Thy-1+ dEC lack other typical T cell markers such as L3T4, Lyt-1, and Lyt-2; however they do express Ly-5 and asialo GM1 in common with NK cells and certain other leukocytes. To investigate the functional capabilities of Thy-1+ dEC in vitro, cell suspensions prepared from trypsin-disaggregated sheets of mouse body wall epidermis were first enriched to 8 to 20% Ia+ and 20 to 40% Thy-1+ cells by centrifugation over Isolymph and then were cultured for 2 to 10 days with Concanavalin A (Con A) and/or partially purified rat IL 2. Con A-induced proliferation of EC was readily seen, with the maximal response occurring at a Con A concentration of 2.5 micrograms/ml on day 5 of culture. Con A responses were significantly enhanced by the continuous presence of 1 microgram/ml indomethacin. Responses both in the presence and absence of Con A were significantly enhanced by the addition of 5 to 10 U/ml of partially purified rat IL 2; proliferation in cultures stimulated by both Con A and IL 2 continued to increase throughout the 10-day culture period. Culture of fluorescence-activated cell sorter (FACS)-separated EC suspensions revealed that Thy-1-depleted EC and irradiated Thy-1+ EC failed to proliferate in response to Con A and IL 2, whereas unirradiated purified Thy-1+ EC gave enhanced Con A- and IL 2-induced responses compared with the unseparated population. Finally, to distinguish between the proliferation of small numbers of mature peripheral T cells and that of Thy-1+ dEC, antibody and complement-depletion studies were conducted with an unusual monoclonal anti-Thy-1 reagent, 20-10-5S, and with the anti-T cell reagents, anti-L3T4 and anti-Lyt-2. Thy-1+ dEC, but not LC, express the 20-10-5S determinant; furthermore, in CBA (Thy-1.2) mice 20-10-5S reacts with Thy-1+ dEC, thymocytes, and peripheral T cells, whereas in AKR/J (Thy-1.1) mice, it reacts only with Thy-1+ dEC and thymocytes and not with peripheral T cells. Pretreatment of AKR/J EC with 20-10-5S and complement abolished the capacity of such cells to respond to Con A and to IL 2.(ABSTRACT TRUNCATED AT 400 WORDS)     

Induction and regulation of contact hypersensitivity by resident, bone marrow-derived, dendritic epidermal cells: Langerhans cells and Thy-1+ epidermal cells

Circumstantial evidence suggests strongly that epidermal Langerhans cells (LC) alone among epidermal cells (EC) are responsible for generating an immunogenic signal for contact hypersensitivity (CH) after epicutaneous application of hapten. However, data obtained from previous studies performed with intact skin or isolated EC do not address the immunogenic capacity of a second dendritic, bone marrow-derived population of cells that resides within the epidermis, Thy-1+ epidermal cells. To identify the cellular source(s) of the antigenic signals emerging from the epidermis, purified preparations of LC, Thy-1+ cells, and keratinocytes were prepared from CBA/J mouse skin. Each cell type was derivatized in vitro with TNBS and inoculated via various routes into syngeneic mice that were assayed for the induction of CH and specific unresponsiveness. IA+ LC, when derivatized with hapten and inoculated into mice, induced CH without evidence of down-regulation regardless of the route of immunization. Derivatized Thy-1+ EC did not deliver a positive signal for CH. Rather, Thy-1+ EC possessed the capacity to initiate down-regulation of the CH response when they were delivered i.v. We conclude that all cellular elements necessary for the induction and regulation of CH after epicutaneous application of hapten to skin reside within the epidermis. The resident, dendritic, bone marrow-derived populations within the epidermis have the capacity to determine the outcome of an epicutaneous antigenic encounter.     

Interleukin 2 receptors on cultured murine epidermal Langerhans cells

Rat monoclonal antibodies 3C7 and 7D4 detect two distinct functional regions of the murine interleukin 2 (IL 2) receptor. When studying the emergence kinetics of IL 2 receptors in mixed epidermal cell (EC)-lymphocyte cultures by using 3C7 and 7D4 in an indirect immunofluorescence assay, we regularly encountered a distinctive membrane fluorescence not only on lymphocytes, but also on a subpopulation of cells exhibiting a dendritic morphology. Reasoning that these 3C7/7D4-reactive dendritic cells might represent a subpopulation of epidermal dendritic cells, we studied mouse EC for the presence of 3C7/7D4- reactive cells. Although 3C7/7D4 reactivity was never detected on freshly isolated EC or on epidermal sheets, a small number of 3C7/7D4+ cells was encountered after 24 to 48 hr of culture. These cells exhibited a dendritic shape, expressed Ia antigens, lacked Thy-1 antigens, and displayed the ultrastructural features of Langerhans cells (LC) with the notable exception of Birbeck granules. Although after 24 hr, only 20% of Ia+ EC were 3C7/7D4+, the vast majority of LC displayed 3C7/7D4 binding sites after 4 to 5 days of culture. Preincubation of cultured LC-enriched EC with recombinant human IL 2 prevented subsequent 3C7-but not 7D4-binding to these cells. Western blot analysis of 7D4-reactive material of detergent extracts from LC-enriched EC revealed three bands in the same m.w. range as reported for CTLL cells. These results demonstrate that cultured LC express IL 2 receptors and may bear important implications for a better understanding of growth regulation, differentiation, and immunologic functions of LC.     

Density of epidermal Langerhans cells in psoriasis patients treated with an aromatic retinoid (RO 10-9359). An immunoperoxidase study using anti-T6 and anti-Ia monoclonal antibodies

Immunocytochemical techniques using antibodies to the specific T6 and Ia (Major Histocompatibility Complex, class II, human HLA-Dr) antigens were used to determine the densities of epidermal Langerhans cells (LC) in psoriasis patients treated with the aromatic retinoid RO 10-9359. Fourteen patients were treated with the aromatic retinoid and were skin biopsied before, during and after therapy. Two psoriasis patients receiving PUVA (systemic 8-methoxypsoralen + UVA irradiation) were included in the study. The results showed an increase in LC numbers during aromatic retinoid administration, which coincided with an improvement in the clinical severity of the lesions. At the end of retinoid administration the LC numbers were similar to those found in the initial psoriatic plaques. The density of Ia+ LC, in comparison with T6+ LC in the epidermis of psoriatic plaques were significantly different. Dendritic and non-dendritic Ia+ cells were also observed in the dermis of the plaques. Unlike aromatic retinoid treated patients, PUVA treated patients showed a decrease of both T6+ and Ia+ epidermal LC by the middle of therapy, a total absence of immunoreaction by the end of therapy, and a return to normal skin values a few weeks after treatment. This immunocytochemical study helps in distinguishing between dendritic and other possible Ia-expressing cells from the infiltrate that may penetrate the epithelium. These results do not conclusively demonstrate the role of LC in the pathogenesis of psoriasis. Other factors, such as the interrelationship with other immune response cell types and alterations in the lymphokine cascade may be important.     

On the extraordinary capacity of allogeneic epidermal Langerhans cells to prime cytotoxic T cells in vivo

We have examined the relative alloimmunogenicity of monodisperse epidermal Langerhans cells (LC), Thy-1+ dendritic epidermal cells, and keratinocytes prepared from the skins of mice, using appropriate fluorescent-tagged mAb and flow cytometry. Graded doses of each cell type were inoculated i.v. and/or s.c. into allogeneic recipients that were selected on the basis of their degree of immunogenetic disparity with the donors of the epidermal cell (EC) inocula. From 4 to 6 wk later the spleens or draining lymph nodes of recipient mice were assayed for specific priming of cytotoxic T cells. LC proved to be extremely powerful immunogens. As few as 10 MHC-disparate EC primed allospecific T cells of mice that received i.v. or s.c. injected cells. By contrast, at least 10,000 keratinocytes were required to prime appropriate recipients, and then only when these class II MHC-negative cells were injected s.c. Thy-1 dendritic epidermal cells failed to sensitize by any route in the doses employed. With the use of appropriate donor/recipient strain combinations, it was determined that LC can effectively prime cytotoxic T cells specific for diverse types of alloantigens, including determinants encoded by class I and class II MHC genes, as well as minor histocompatibility genes. The results of these in vivo studies confirm that, among EC, the primary alloimmunogenic stimulus resides among LC, and support the hypothesis that LC play a major role in the immunogenicity of skin allografts.     

T cell receptor gamma delta expression of Thy-1+ dendritic epidermal cells--an update

Thy-1+ dendritic epidermal cells (Thy-1+DEC) are present in the murine epidermis. They are morphologically dendritic and express Thy-1, CD3 and asialoGM1, but not CD4 or CD8. T cell receptor (TCR) of Thy-1+DEC is TCR gamma delta. Allison et al and Tonegawa et al recently found that TCR of Thy-1+DEC is V gamma 5 J gamma C gamma -V delta 1D2J2C delta and has no junctional diversity. This TCR gamma delta of Thy-1+DEC is identical to TCR expressed on the earliest fetal thymocytes. It is distinct from that of other epithelial associated lymphocytes or other thymocytes. The ligand of Thy-1+DEC is not known, although TCR gamma delta of adult type could recognize allogenic major histocompatibility complex(MHC) class I or class II and mycobacterium antigen, especially heat shock protein. The TCR of Thy-1+DEC may not be the homing receptor to epidermis. The further studies are needed to elucidate the ligands or functions of Thy-1+DEC.     

Lack of dendritic Thy-1+ epidermal cells in mice with severe combined immunodeficiency disease

C.B-17 scid (severe combined immunodeficiency disease) mice were used to evaluate the relationship of dendritic Thy-1+ epidermal cells (EC) to T lymphocytes (deficient in scid) and to NK cells (replete in scid). Epidermis from scid mice was deficient in dendritic Thy-1+ cells as determined by immunofluorescent staining of epidermal whole mounts. Similarly, epidermal cell suspensions from scid mice failed to proliferate in response to Con A, as compared with epidermal cell suspensions from C.B-17 control mice. Transplantation of normal bone marrow into scid mice reconstituted morphologically identifiable dendritic Thy-1+ EC in whole mounts, as well as Con A responsiveness of EC suspensions, thus indicating that the deficiency in dendritic Thy-1+ EC in scid mice is at the precursor level. These studies demonstrate that Thy-1+ EC are more closely related to T lymphocytes than to NK cells.     

Purification and identification of murine epidermal dendritic cells: flow cytometry and immunogold labeling

We report on application of flow cytometric and immunogold labeling techniques to purify and identify two types of murine epidermal dendritic cells: Langerhans cells (LC) and Thy-1-positive dendritic epidermal cells (Thy 1+-dEC). After density centrifugation of epidermal cell (EC) suspensions through Ficoll gradients. IA-positive LC and Thy 1+-dEC are labeled with monoclonal antibodies (fluorescein-conjugated anti-IAd for LC and anti-Thy 1.2-biotin, followed by avidin-phycoerythrin, for Thy 1+-dEC). The fluorescence-activated cell sorter (FACS) is then used to obtain 95-98% pure populations of these dendritic cells with a yield of 2-4 X 10(6) cells and a viability of 80-90%. A post-fixation, pre-embedding immunogold labeling technique using 15 nm and 40 nm colloidal gold particles is employed to identify LC and Thy 1+-dEC, respectively, to confirm the purity of the sorting and to estimate the number of IA antigenic sites per LC. With transmission electron microscopy, ultrastructural morphology of sorted LC is preserved; however, Birbeck granules are markedly diminished compared to the pre-sorted population of LC. In contrast, characteristic dense-core granules are readily visualized in sorted Thy 1+-dEC. Purification of epidermal dendritic cells by flow cytometry may be a useful technique to employ in functional studies of epidermal dendritic cells.     

Tumor antigen presentation by murine epidermal cells

The ability of epidermal Langerhans cells to present Ag for CD4-dependent immunity is well documented, and it has been hypothesized that Langerhans cells participate in the generation of immunity against incipient epidermal neoplasms by presentation of tumor-associated Ag in situ. This study examined the ability of murine epidermal cells (EC) to present tumor-associated Ag for the induction of in vivo antitumor immunity. Murine epidermal cells were deleted of Thy-1-bearing cells, cultured in 50 U/ml granulocyte-macrophage-CSF for 14 to 18 h, and pulsed with tumor fragments (TF) derived from S1509a-fibrosarcoma cells. These TF-pulsed EC were injected s.c. into syngeneic recipients at weekly intervals for a total of three immunizations and challenged with viable S1509a tumor cells 1 wk after the last immunization. Control animals received TF-pulsed allogeneic EC or EC treated identically but not pulsed with TF. EC that were pulsed with tumor cell fragments were able to induce protective immunity to tumor growth in vivo and to immunize for a significant delayed-type hypersensitivity response to injected tumor cells. The induction of antitumor immunity with TF-pulsed EC was genetically restricted, and culture of EC in granulocyte-macrophage-CSF was required for development of significant immunity. Furthermore, deletion of I-A+ cells by antibody and complement-mediated lysis eliminated the generation of immunity. Thus, I-A+ epidermal cells are capable of presenting S1509a tumor Ag for the generation of protective antitumor immunity in vivo.     

Antigen-presenting activity of draining lymph node cells from mice painted with a contact allergen during ultraviolet carcinogenesis.

The induction of skin cancers in mice by chronic UV irradiation is accompanied by a decrease in the numbers of Ia+ and Thy-1+ dendritic cells in the epidermis early in the course of UV irradiation. Subsequently, the number of Ia+ cells, but not Thy-1+ cells, increases until the time of tumor development. To assess the functional significance of these changes in cutaneous immune cells, and to help define the role these cells may play in immune surveillance against skin cancers, we tested the afferent immunologic capability of the skin during the development of UV-B radiation-induced skin cancers. Afferent immune function was measured by testing the Ag-presenting capacity of draining lymph node (DLN) cells from mice sensitized epicutaneously with dinitrofluorobenzene. A reduced contact hypersensitivity response was induced in mice immunized with DLN cells from UV-irradiated mice that had been sensitized with hapten on UV-irradiated skin. This decreased reactivity was present during the entire latent period of tumor development. However, in tumor-bearing mice, the DLN cells from UV-irradiated, sensitized animals exhibited normal Ag-presenting activity. DLN cells from UV-irradiated mice sensitized on ventral, unirradiated skin exhibited normal Ag-presenting activity. The lowest amount of Ag-presenting activity in the draining lymph nodes of UV-irradiated mice correlated temporally with the lowest number of Ia+, adenosine triphosphatase+ dendritic epidermal cells in the UV-irradiated skin. At least during the early part of the tumor latent period, an increase in the number of these cells was paralleled by an increase in the Ag-presenting activity of the DLN cells. In contrast, the number of Thy-1+ dendritic epidermal cells in UV-irradiated skin did not correlate with the Ag-presenting activity. Thus, the decrease in the number of identifiable epidermal Langerhans cells early in the course of chronic UV irradiation correlated with a decrease in Ag-presenting activity after sensitization through the UV-irradiated skin. These studies demonstrate that the afferent arm of the cutaneous immune response is impaired in the site of tumor development throughout the latent period of UV carcinogenesis.     

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.     

Enhancement by various cytokines or 2-beta-mercaptoethanol of Ia antigen expression on Langerhans cells in skin from normal aged and young mice. Effect of cyclosporine A

The number of Ia+ Langerhans cells (LC) in skin from aged (16- to 18-mo old) BALB/c mice is approximately 40% lower than in skin from young (2- to 3-mo old) mice. Overnight incubation at 37 degrees C with a variety of cytokines, including IL-1, IL-2, IL-3, IL-4, IL-6, TNF-alpha, IFN-gamma, and granulocyte/macrophage-CSF, causes a significant increase in the Ia expression on LC and raises the number of Ia+ cells by at least 300/mm2 in skin from both young and old mice. At 1 to 5 x 10(-5) M, 2-ME has a similar effect. The percentage increment in Ia+ cells is much higher for skin from aged mice than from young mice, particularly with IL-3, which appears to reconstitute the number of Ia+ LC in skin from aged mice to that of IL-3 exposed skin from young mice. Under the incubation conditions of our experiments, neither keratinocytes nor Thy-1+ dendritic cells acquire Ia Ag. Addition of 10 micrograms/ml cyclosporine A to the medium abolishes the effect of 2-ME and of all of the cytokines except IL-2 and IL-6. These results demonstrate the presence of a significant population of Ia- LC in the epidermis of both young and aged mice. It is suggested that epidermal production of cytokines may be of importance in the maintenance of constitutive Ia expression on LC. The possible interaction between keratinocytes and LC and the effect of aging on this process are discussed.     

Loss of epidermal integrity by T cell-mediated attack induces long term local resistance to subsequent attack. II. Thymus dependency in the induction of the resistance

Our previous study showed that in cutaneous graft-vs-host disease (GVHD) induced by intradermal injection of autoreactive T cells the epidermal structures spontaneously recovered from the destruction became resistant to the subsequent attempts to induce the cutaneous GVHD and that the resistance correlated well with a 30-fold increase in the number of Thy-1+ epidermal cells (Thy-1+EC). We show that the resistance to the cutaneous GVHD was never induced in athymic nude mice and adult thymectomy lethal radiation and bone marrow reconstitution (ATXBM) mice under the same conditions, indicating that the induction of the resistance is dependent on the presence of thymus. A great increase in the number of Thy-1+EC was similarly observed in the epidermis of the athymic nude and ATXBM mice that spontaneously recovered from the cutaneous GVHD and that remained susceptible to the induction of the cutaneous GVHD. However, the results with B10Thy-1.1----B6 radiation chimeras clearly demonstrate that the vast majority of the increased Thy-1+EC found in the "susceptible" epidermis of the ATXBM mice were of donor bone marrow origin and there was no increase in the number of host-derived Thy-1+EC, whereas in the "resistant" epidermis of the XBM mice both Thy-1+EC populations were equally increased. The overall results indicate that the expansion of Thy-1+EC that mature in the thymus is crucial to the induction of the resistance, although the migration of bone marrow-derived Thy-1+EC precursors to the epidermis occurs quite independently of the presence of thymus.     

Role of Thy-1+ and Ia+ cells in ovarian function

Cryostat sections of anovulatory ovaries from persistent estrous rats following a single postnatal dose of testosterone and from persistent diestrous rats following long-term postnatal estradiol treatment were investigated. The indirect immunoperoxidase technique was used to localize ovarian Thy-1 and Ia glycoproteins, as well as several other cell surface markers, and the results were compared with those obtained in normal ovaries of cycling females. Folliculogenesis in persistent estrous rats proceeded up to cystic antral follicles and was associated with the occurrence of Thy-1+ stromal cells under follicular basal lamina. In contrast to normal ovaries, Thy-1+ material did not invade the basal layers of granulosa cells. There was also no association of Ia+ cells with follicular basal lamina, but Ia+ cells were usually found associated with some thecal vessels. In persistent diestrous rats folliculogenesis was significantly retarded in both advanced antrum formation and thecal development. Thy-1+ cells were usually present in theca. No Thy-1+ material was found among basal layers of granulosa cells and the depletion of thecal Ia+ cells was almost complete. We suggest that normal follicular development may be dependent on the correct effects of Thy-1+ and Ia+ cells in addition to appropriate gonadotropin and steroid stimulation. On the other hand, anovulatory syndromes following postnatal androgen or estrogen treatment might be induced by temporary direct ovarian effects disturbing the establishment of the normal relationship between follicular structures and the immune system.     

Langerhans cells that migrate to skin after intravenous infusion regulate the induction of contact hypersensitivity

Intravenous infusion of hapten-derivatized epidermal cells (EC) in syngeneic mice leads to two competing signals for contact hypersensitivity (CH), a dominant effector signal attributable to Langerhans cells (LC) and a suppressor signal from Thy-1+ EC. In vitro exposure of LC to low dose ultraviolet B (UVB) radiation before hapten-derivatization and infusion not only results in the abrogation of their effector signal but also causes the down-regulation of subsequent CH responses. To delineate the relevance of i.v. immunization to the study of CH and of LC as the immunologic targets of low dose UVB radiation, we examined the migratory and immunogenic properties of EC after i.v. infusion. Unsorted EC migrated from blood to skin and lymphoid tissues, reaching steady state distributions at 16 h after infusion. No significant differences were observed between the trafficking of EC in syngeneic and allogeneic transfers. LC localized preferentially to skin, whereas Thy-1+ EC trafficked to skin, the thymus, mesenteric lymph nodes, and spleen. The pattern of trafficking of unirradiated and low dose UVB-irradiated LC were identical, suggesting that low dose UVB radiation had little effect on LC migration. Finally, skin graft experiments demonstrated i.v. infused, hapten-derivatized LC that migrate to skin to retain their capacity to induce CH, a property that was converted by in vitro pretreatment with low dose UVB radiation into down-regulation. These findings confirm the relevance and utility of the i.v. immunization model in the study of CH and the influence of low dose UVB on this immune response. Our data also provide a basis for investigating the role of disparate trafficking patterns in generating effector and suppressor signals when hapten-derivatized EC are employed for CH.     

Migration of Langerhans cells and gammadelta dendritic cells from UV-B-irradiated sheep skin

Depletion of dendritic cells from UV-B-irradiated sheep skin was investigated by monitoring migration of these cells towards regional lymph nodes. By creating and cannulating pseudoafferent lymphatic vessels draining a defined region of skin, migrating cells were collected and enumerated throughout the response to UV-B irradiation. In the present study, the effects of exposing sheep flank skin to UV-B radiation clearly demonstrated a dose-dependent increase in the migration of Langerhans cells (LC) from the UV-B-exposed area to the draining lymph node. The range of UV-B doses assessed in this study included 2.7 kJ/m2, a suberythemal dose; 8 kJ/m2, 1 minimal erythemal dose (MED); 20.1 kJ/m2; 40.2 kJ/m2; and 80.4 kJ/m2, 10 MED. The LC were the cells most sensitive to UV-B treatment, with exposure to 8 kJ/m2 or greater reproducibly causing a significant increase in migration. Migration of gammadelta+ dendritic cells (gammadelta+ DC) from irradiated skin was also triggered by exposure to UV-B radiation, but dose dependency was not evident within the range of UV-B doses examined. This, in conjunction with the lack of any consistent correlation between either the timing or magnitude of migration peaks of these two cell types, suggests that different mechanisms govern the egress of LC and gammadelta+ DC from the skin. It is concluded that the depression of normal immune function in the skin after exposure to erythemal doses of UV-B radiation is associated with changes in the migration patterns of epidermal dendritic cells to local lymph nodes.     

Enrichment of epidermal Langerhans cells by immunoadsorption to Staphylococcus aureus cells

In addition to keratinocytes and melanocytes, the mammalian epidermis harbors the so-called Langerhans cells (LC)2 as a third cell population, which is thought to participate in immune reactions involving the epidermis (1, 2). LC are dendritic cells located above the basal cell layer, have a characteristic ultrastructural appearance (3), and originate from a bone marrow precursor (4, 5). They lack membrane-incorporated surface immunoglobulin and sheep red blood cell receptors, but are the only epidermal cells (EC) that bear receptors for the Fc portion of IgG (Fc-IgG) and for C3 and express Ia antigens (1, 2). Because LC constitute only 3 to 5% of all EC, enrichment procedures are important for functional studies. Moderate enrichment of LC to 18 to 35% by separation of Fc-IgG rosetting EC on density gradients was sufficient to show the critical role of LC in EC-induced T cell proliferation (6). More powerful isolation procedures are needed, however, for more exacting analysis of LC functions, such as their role in immune induction, their secretory capacities including production of EC-derived thymocyte-activating factor (7, 8) and prostaglandins, immune endocytosis, the role of LC granules, etc. Methods hitherto available for enriching LC beyond 60% (9, 10) are time consuming and of low yield and viability, and thus are of limited practical value. In this report we describe a simple and efficient procedure to obtain viable LC suspensions of high purity based on the use of monolayers of protein A-bearing Staphylococcus aureus cells as a solid-phase immunoadsorbent (11).     

Low dose ultraviolet B-irradiated Langerhans cells preferentially activate CD4+ cells of the T helper 2 subset

UVB radiation distorts the Ag-presenting function of epidermal Langerhans cells (LC); this has been shown for the presentation of soluble Ag to primed T cells in vitro and for the initiation of delayed-type hypersensitivity in vivo, such as contact hypersensitivity (CH). Previous work has also demonstrated UVB-induced suppression of CH to be mediated ultimately by T cells. Two subsets of CD4+ Th cells, Th1 and Th2, have been identified, based on their cytokine production and functional activities. In particular, Th1 mediate delayed-type hypersensitivity, whereas Th2 do not. To investigate whether the perturbation of LC function induced by UVB radiation leads to a differential activation of these subsets of CD4+ cells, we examined the capacity of unirradiated and irradiated (200 J/m2) APC from adult BALB/c mice to present keyhole limpet hemocyanin to Ag-specific, H2d-restricted Th1 and Th2 cell lines. Four sources of APC were utilized: epidermal cells (EC), flow microfluorometry-purified Ia+ EC (LC), flow microfluorometry-purified Ia- EC, and splenic adherent cells (SAC). Unirradiated EC, LC, and SAC, but not Ia-EC, presented keyhole limpet hemocyanin to both Th1 and Th2. Irradiated EC and LC lost their ability to stimulate Th1, but retained fully their capacity to stimulate Th2. On the other hand, irradiated SAC were unable to induce proliferation of either Th1 or Th2. These findings indicate that suppression of CH mediated by UVB-irradiated LC may result from an alteration of the ratio and/or activity of Th1 and Th2 cells normally generated during the induction of such responses.