H1 and H2 histamine receptors are absent on Langerhans cells and present on dermal dendritic cells

Human monocyte-derived dendritic cells (MoDC) have both histamine H1 and H2 receptors and can induce CD86 expression by histamine. Nevertheless, it has not been reported whether human epidermal Langerhans cells (LC) have histamine receptors or not. In this study, using RT-PCR, we investigated the expression of H1 and H2 receptor mRNA on DC with the features of LC (LC-like DC) that were generated in vitro from peripheral blood monocytes, LC derived from CD34+ hematopoietic progenitor cells, and LC obtained from human epidermis. We compared the histamine-induced CD86 expression among these cells. In contrast to MoDC, LC and LC-like DC did not express H1 or H2 receptors. In addition, they could not augment the CD86 expression by histamine. Interestingly, when transforming growth factor-beta1 (TGF-beta1) was added to the culture of MoDC, the expression of H1 and H2 receptors and the histamine-induced CD86 expression were abrogated in a concentration-dependent fashion. Finally, in the assessment of the cell surface expression of histamine receptors using fluorescence-labeled histamine, histamine could bind to MoDC and dermal dendritic cells obtained from the skin, whereas there was no specific binding of histamine to LC-like DC or LC obtained from the skin. These data suggest that LC do not express either H1 or H2 receptors, mainly because of the effect of TGF-beta1. This made a striking contrast with the expression of the functional H1 and H2 receptors on MoDC and dermal dendritic cells.     

Human skin dendritic cells can be targeted in situ by intradermal injection of antibodies against lectin receptors

Skin dendritic cells (DC) express C‐type lectin receptors for the recognition of pathogens. Langerhans cells (LC) express the receptor Langerin/CD207, whereas DEC‐205/CD205 is mainly expressed by dermal DC, but can also be detected at low levels on LC. In this study, we tested an ex vivo approach for targeting DC in situ with monoclonal antibodies (mAb) against Langerin and DEC‐205. The targeting mAb was injected intradermally into human skin biopsies or added to the medium during skin explant culture. Corresponding to the expression patterns of these lectin receptors on skin DC, Langerin mAb was detected merely in LC in the epidermis and DEC‐205 mainly in dermal DC in human skin explants, regardless of the application route. Migratory skin DC bound and carried targeting mAb from skin explants according to their lectin receptor expression profiles. In contrast to the very selective transport of Langerin mAb by LC, DEC‐205 mAb was more widely distributed on all CD1a⁺ skin DC subsets but almost absent in CD14⁺ dermal DC. As effective vaccination requires the addition of adjuvant, we co‐administered the toll‐like receptor (TLR)‐3 ligand poly I:C with the mAb. This adjuvant enhanced binding of DEC‐205 mAb to all skin DC subsets, whereas Langerin targeting efficacy remained unchanged. Our findings demonstrate that LC can be preferentially targeted by Langerin mAb. In contrast, DEC‐205 mAb can be bound by all CD1a⁺ skin DC subsets. The efficacy of DEC‐205 mAb targeting strategy can be boosted by addition of poly I:C underlining the potential of this combination for immunotherapeutical interventions.     

Thy-1 antigen-bearing dendritic cells in murine epidermis are derived from bone marrow precursors

Thy-1 antigen is expressed on a dendritic subpopulation of cells in murine epidermis. Numbering between 200 and 500/mm2 surface area in abdominal skin, they are distinct from the dendritic Langerhans cells (LCs) and melanocytes. Since immigrant lymphoid cells as well as constitutive cells in various organs have been demonstrated to be Thy-1+, their origin and function are not certain. To assess these issues, two experimental protocols were established. First, grafts of whole skin from AKR mice were placed orthotopically on (AKD2)F1 recipients. Immigration of recipient-derived cells into graft epidermis was assessed histologically by fluorescence microscopy employing monoclonal anti-Thy-1.2 and anti-I-Ad antibodies. Second, bone marrow chimeras were established in AKR recipients after lethal irradiation and reconstitution with cells from (AKD2)F1 donors. In the first protocol, dendritic I-Ad+ LCs of donor origin infiltrated each graft to normal densities within 2 weeks. Thy-1.2+ cells also immigrated into the same grafts, but at much slower rates. In the second protocol, bone marrow-derived Thy-1.2+ cells populated normal skin epidermis slowly over several months, with densities reaching 70/mm2. We conclude that some, if not all, Thy-1+ cells in normal murine epidermis are derived from bone marrow precursors, that their infiltration rates differ substantially from those of LCs, and that those factors which govern immigration rates into adult skin derive from the skin itself rather than from the systemic availability of their precursors. We suggest that the function of Thy-1+ epidermal cells will therefore reside among those usually ascribed to recirculating hematogenous cells, including the possibility that they may down-regulate immunizing signals that emerge from skin.     

"Dermal dendritic cells" comprise two distinct populations: CD1+ dendritic cells and CD209+ macrophages

A key cell type of the resident skin immune system is the dendritic cell (DC), which in normal skin is located in two distinct microanatomical compartments: Langerhans cells (LCs), mainly in the epidermis, and dermal DCs (DDCs), in the dermis. Here, the lineage of DDCs was investigated using monoclonal antibodies and immunohistology. We provide evidence that "DDC" comprise at least two major phenotypic populations of dendritic-appearing cells, immature DC expressing CD1, CD11c and CD208; and macrophages expressing CD209, CD206, CD163, and CD68. These data suggest that dermal dendritic-appearing macrophages comprise a novel part of the innate immune response in the resident skin immune system.     

Langerhans cells and lymph node dendritic cells express the tight junction component claudin-1

Claudin-1 is a critical structural component of tight junctions that have an important role in adhesive properties, barrier function, and paracellular transport of epithelia and other nonhematopoietic tissues. We found claudin-1 in murine CD207+ Langerhans cells (LC) residing in epidermis. Claudin-1 was not detected in other skin dendritic cells (DC). LC expressed claudin-1 in steady state and inflamed skin. Claudin-1 was demonstrated further in lymph node LC under steady state and inflammatory conditions, including after direct tracking with tetramethylrhodamine-isothiocyanate (TRITC). All subsets of skin draining lymph node DC defined by CD205, CD11b, CD11c, and CD8, including a presumably blood-borne lymph node resident CD8+CD207+ LC population, were claudin-1+. TRITC tracking demonstrated claudin-1 in CD207- skin migrant DC in the lymph node, suggesting upregulation of this molecule during migration or once arrived in the lymph node. Claudin-1 expression in CD207+ cells was confirmed at the protein and mRNA levels. Transforming growth factor-beta, a factor critical for the induction of LC in vitro and in vivo, stimulated the accumulation of claudin-1 mRNA and protein when added to bone marrow cells cultured with GM-CSF and IL-4. Claudin-1 may thus have an important function in adhesion and/or migration of LC.     

Distinctive dendritic cell subsets expressing factor XIIIa, CD1a, CD1b and CD1c in mycosis fungoides and psoriasis

The papillary dermis of psoriasis and mycosis fungoides (MF) lesions is characterized by prominent collections of cells with dendritic morphology. Immunophenotypically distinct populations of cutaneous dendritic cells have been identified as CD1a+, FXIIIa-Langerhans cells (LC) and CD1a-, FXIIIa+ dermal dendritic cells (DDC). In this study, antibodies against the human GDI cluster of antigens (i.e. CD1a, CD1b and CD1c) and the DDC) marker (FXIIIa) were used to further characterize the subsets of dendritic cells in normal skin as compared to neonatal foreskin, psoriasis and MF by both immunoperoxidase and double immunofluorescence techniques. Normal skin and foreskin epidermis and dermis contained few CD1b+ or CD1c+ cells along with normal numbers of CD1a+ LC and FXIIIa+ DDC. Both MF and psoriasis were characterized by CD1a+ cells in the epidermis and dermis. FXIIIa+ cells were greatly expanded in the upper dermis of MF lesions and to a lesser degree in psoriasis as has been previously described by our group. MF contained significantly increased epidermal and dermal CD1b+ (15.7/5 high power fields [HPF] and 59.7/5 HPF respectively) and CD1c+ dendritic cells (33.8/5 HPF and 95.9/5 HPF respectively), while in psoriasis these cells were not statistically different from normal skin. Double immunofluorescence studies revealed that some (<25%) FXIIIa+ cells co-expressed CD1b and CD1c in MF>psoriasis> foreskin, while FXIIIa+ DDC never co-expressed CD1a. Thus, in contrast to normal skin in which epidermal or dermal dendritic cells rarely express CD1b and CD1c antigens, these members of the CD1 family are upregulated on both LC and DDC in benign and malignant inflammatory states. Upregulation of CD1b and CD1c on MF epidermal and dermal dendritic cells, as compared to psoriasis, foreskin and normal skin, may be useful in the immunophenotypic recognition of MF, as well as in helping to understand its immunobiology.     

Epidermal Langerhans cells--a target for HTLV-III/LAV infection

Langerhans cells (LC) are bone marrow-derived, Ia+, CD1+, CD4+, ATPase+ dendritic antigen-presenting cells within the human epidermis. Since the CD4 molecule has been implicated as a receptor structure for HTLV-III/LAV (human T-cell leukemia virus/lymphadenopathy-associated virus), we asked whether LC from HTLV-III/LAV-seropositive individuals display signs of HTLV-III/LAV infection. In skin biopsies from 7/40 HTLV-III/LAV-infected persons (1 asymptomatic carrier, 2 patients with acquired immunodeficiency syndrome (AIDS)-related complex and 4 patients with AIDS), LC were the only epidermal cells to react with a monoclonal antibody specific for the HTLV-III core protein p17. A varying percentage of p17+ LC were morphologically altered with blunt dendrites and poorly demarcated cellular contours. In one of these biopsies, the presence of LC-associated viral particles characteristic of HTLV-III/LAV as well as cytopathic changes in approximately one-third of the LC population were demonstrated by electron microscopy. These results strongly suggest that LC may harbor HTLV-III/LAV. The infection of LC with this retrovirus may have deleterious consequences for the immunologic functions of this cell system and may thus contribute to both the acquisition of immunodeficiency and the infectious and neoplastic complications of AIDS.     

Immunophenotypic analysis of normal human dendritic cells isolated from epidermis and dermis

Background The skin immune system comprises two types of dendritic cells, i.e. CD1a-positive Langerhans cells in the epidermis and CD36-positive dendritic macrophages in the dermis. Dendritic cells can migrate from skin explants into a culture medium.
Methods We have examined the morphology and immunophenotype of the dendritic cells migrating from epidermal and dermal sheets in vitro. The epidermis and dermis of keratomes of normal human skin were separated with dispase and cultured for 72 h. At this time, the non-adherent cells in the medium were removed, enriched on a metrizamide or Lymphoprep gradient, counted, prepared by cytospin, and labeled for CD1a, CD36, and HLADr.
Results Cells migrating from the epidermis and dermis show many thin projections or a few veils from the cell surface. Approximately four times more cells migrate from epidermal than dermal sheets from the same keratome.
Conclusions Using methods to separate the epidermis from the dermis, both CD1a-positive Langerhans cells and CD36-positive dendritic macrophages can be obtained from both tissues, although in different numbers.     

系统性红斑狼疮患者CD1a、CD68、HLA-DR等的研究

目的 研究系统性红斑狼疮(SLE)患者外观正常及病变皮肤中朗格汉斯细胞(LC)一些重要表面标志的变化。方法 应用CD1a、CD68和HLA-DR等单克隆抗体和ABC免疫组化技术对9例SLE患者外观正常和皮损部位的组织进行了免疫表型检测。结果 ①SLE皮损中LC的数量减少,且其形态与表面标志亦有变化;②SLE病损处的角质形成细胞(KC)强弱不等地表达HLA-DR抗原,个别病例的外观正常皮肤KC也可局灶性表达HLA-DR抗原;③SLE外观正常皮肤或皮损的表皮中均未见细胞间粘附分子1和CD4阳性LC,仅在真皮的浸润细胞中见到较多的阳性细胞;④发现在SLE外观正常皮肤和皮损表皮内出现两类CD68阳性的树枝状细胞;在SLE皮损的浸润细胞中CD68阳性树枝状细胞大量增加;⑤细纤维状CD68阳性物质呈网状围绕基底部的KC,这些细纤维状阳性物质有些与表皮树枝状细胞相连,有些则没有明显的关系。结论 SLE外观正常和病变皮肤中LC一些重要表面标志的变化有所不同。外观正常皮肤和皮损表皮内出现两类树枝状细胞,一类可能为LC,而另一类则来源不清;在SLE皮损的浸润细胞中这些CD68阳性树枝状细胞大量增加,表皮内存在CD68阳性纤维状染色,其意义尚需进一步研究。     

The tolerogenic molecule CD95-L is expressed on the plasma membrane of human activated, but not resting, Langerhans' cells

Although dendritic cells (DC) are well known for their immunogenic capacities, they may even induce peripheral T-cell tolerance, and such a tolerogenic potential can be exerted in mouse through the expression on the DC plasma membrane of the CD95-ligand (CD95-L) molecule, which is able to trigger apoptosis of CD95-expressing antigen-specific T cells. We therefore asked whether epidermal DC, namely Langerhans' cells (LC), either resting (i.e. within the epidermis, 'in situ') or activated (i.e. suspended from the epidermis) or both, could express the CD95-L molecule on the plasma membrane. For such a purpose, two colloidal gold-immunoelectron microscopy (IEM) double-step procedures were carried out: an 'in situ' method, able to investigate resting LC, was performed on ultrathin frozen sections obtained by ultracryomicrotomy (UCMT) of normal skin biopsies; a pre-embedding (P-E) method, able to investigate suspended LC, was performed on epidermal cells (EC) suspended from normal skin specimens. In UCMT/IEM sections, resting LC showed gold particles within the cytoplasm but very rarely within organelles and never along the plasma membrane: resting LC are therefore capable of synthesizing CD95-L but not of expressing it in a functional location, thus autoreactive phenomena against CD95-expressing EC being avoided in normal epidermis. On the other hand, in P-E/IEM preparations, suspended LC showed several gold particles along the plasma membrane: activated LC are therefore capable of expressing CD95-L in a functional location, thus bearing the potential to exert tolerogenic capabilities against CD95-expressing T cells, e.g. to prevent inflammatory/autoimmune cutaneous disorders and/or favor the resolution thereof.     

Leishmaniasis,contact hypersensitivity and graft‐versus‐host disease: understanding the role of dendritic cell subsets in balancing skin immunity and tolerance

Please cite this paper as: Leishmaniasis, contact hypersensitivity and graft‐versus‐host disease: understanding the role of dendritic cell subsets in balancing skin immunity and tolerance. Experimental Dermatology 2010; 19 : 760–771. Abstract: Dendritic cells (DC) are key elements of the immune system. In peripheral tissues, they function as sentinels taking up and processing antigens. After migration to the draining lymph nodes, the DC either present antigenic peptides by themselves or transfer them to lymph node–resident DC. The skin is the primary interface between the body and the environment and host’s various DC subsets, including dermal DC (dDC) and Langerhans cells (LC). Because of their anatomical position in the epidermis, LC are believed to be responsible for induction of adaptive cutaneous immune responses. The functions of LC and dDC in the skin immune system in vivo are manifold, and it is still discussed controversially whether the differentiation of T‐cell subtypes (e.g. effector T cells and regulatory T cells) may be initiated by distinct DC subtypes. As skin DC are able to promote or downmodulate immune responses, we chose different skin diseases (cutaneous leishmaniasis, contact hypersensitivity, UV radiation‐induced suppression, and graft‐versus‐host disease) to describe the biological interactions between different DC subtypes and T cells that lead to the development of efficient or unwanted immune responses. A detailed knowledge about the immune modulatory capacity of different cutaneous DC subsets might be helpful to specifically target these cells through the skin during therapeutic interventions.     

Distribution of CD1a-positive cells in psoriatic skin during the evolution of the lesions

Normal skin and psoriatic lesions from 35 patients were investigated immunohistochemically with regard to the CD1a+ cell population (Langerhans' cells and indeterminate cells) in the epidermis as well as in the dermal infiltrate. In the normal-appearing skin, we found the regularly typical pattern of CD1a+ dendritic cells in suprabasal position, but in lesional skin of chronic psoriasis the CD1a+ cells were scattered in the acanthotic epidermis. In initial lesions, CD1a+ cells represent up to 50-60% of the infiltrating cells of the dermal compartment, in several cases being preferentially localized in the upper part of the papillar dermis close up to the epidermal CD1a+ cells in basal position, whereas in chronic psoriasis they represent less than 10%. These results suggest that in psoriasis vulgaris, CD1a+ cells actively migrate between the epidermis and the dermal vessels.     

Spleen dendritic cells exhibit altered morphology and increased allostimulatory capacity after short-term culture.

Ia-bearing dendritic cells (DC) are a class of bone marrow-derived antigen-presenting cells that appear to possess an increased capacity to stimulate resting T lymphocytes. DC from different tissues share several morphologic, phenotypic and functional attributes. For example, freshly isolated DC from spleen resemble phenotypically and functionally freshly isolated Langerhans cells (LC) from epidermis; in addition, during short-term culture both DC and LC undergo several parallel changes including modifications affecting phenotype, capacity to present protein antigens, and ability to route surface Ia molecules into intracellular acidic compartments (J Immunol 1990: 145: 2820-2826). In the present study we show, using immunoelectron microscopy with anti-Ia and anti-33D1 monoclonal antibodies, freshly isolated DC in suspension to have a smooth cell surface with few and short cytoplasmic projections. By contrast, cultured DC display conspicuous bulbous cytoplasmic protrusions. In addition, spleen DC following culture for 24-48 hours exhibit an increased ability to stimulated allogeneic T lymphocytes in the primary mixed leukocyte reaction. These changes, similar to those described for freshly isolated and cultured LC respectively, further substantiate the close relationship between DC and LC.     

Human 6-sulfo LacNAc (slan) dendritic cells are a major population of dermal dendritic cells in steady state and inflammation

Background. The immune system of the skin has a network of resident dendritic cells (DCs) consisting of epidermal Langerhans cells and various subsets of dermal DCs. We recently reported on a new population of dermal DCs, called slan (6‐sulfoLacNAc+) DCs, which have a potent capacity to stimulate Th17/Th1 T‐cell responses. Aim. To understand the characteristics of slanDCs as a new population of dermal DCs in the context of other DC populations in healthy and psoriatic skin. Methods. We immunofluorescently stained skin samples from healthy controls and from patients with psoriasis. Results. Staining healthy skin for DCs showed that slanDCs (CD1a? CD1c? CD11c? CD14? CD163?) were present at a similar frequency to that of CD1c+ CD11c+ CD1a+ CD14? CD163? dermal DCs, which have previously been regarded as the major population of resident DCs. In psoriatic skin, the frequency of slanDCs and CD1c+ DCs was doubled, and the slanDCs expressed CD11c. In‐depth analysis of DCs in psoriatic skin by four‐colour immunofluorescence analysis showed that the pool of CD11c+ cells could be further subdivided into CD11c+ CD14+ CD163? DCs and CD11c+ CD163+ CD14+ macrophages. Conclusion. SlanDCs, initially described as large population of proinflammatory DCs in blood, are a novel and major part of the resident dermal myeloid DC system in both healthy and inflamed skin.     

Research in practice: Different dendritic cell types in skin with various functions – important implications for intradermal vaccines

It was long believed that epidermal Langerhans cells (LC) are responsible for the initiation of cellular immunity. Only recently it has been shown that in skin alone 5 different subtypes of dendritic cells (DC) can be identified. Among these, LC, but also two Langerin‐expressing dermal DC populations and two more Langerin‐negative DC subtypes exist. Novel findings in the model disease leishmaniasis, as well as evidence from research in contact hypersensitivity, have revealed that activation of LC in skin leads to induction of regulatory, immunosuppressive T cells, whereas the other skin DC subtypes stimulate effector T cells. Thus, when producing vaccines designed for intradermal use, it would seem advisable to attempt to activate dermal DC subtypes while avoiding activation of epidermal LC.     

iC3b arrests monocytic cell differentiation into CD1c-expressing dendritic cell precursors: a mechanism for transiently decreased dendritic cells in vivo after human skin injury by ultraviolet B

Our previous data indicated that C3, its bioactive product iC3b, and the iC3b ligand CD11b are critical for ultraviolet-induced immunosuppression. We thus hypothesized that iC3b is an important skin-based factor regulating CD11b+ monocytic cell function in the acute post-ultraviolet period. Although monocytic cell migration peaked at 1-3 d after ultraviolet exposure of skin, dermal CD1c dendritic cells underwent a rapid and prolonged depletion that did not recover until day 7. Because ultraviolet-induced iC3b deposits are reciprocally maximal on day 3, but fade by day 7, we next hypothesized that iC3b can be responsible for the delay in differentiation into dendritic cells of monocytic cells migrating into ultraviolet-exposed skin. Analysis of dermal cells derived from keratome biopsies suggested that iC3b exposure could inhibit the development of CD1c+ dermal cells. To model newly immigrating blood monocytes entering ultraviolet-exposed, iC3b-containing dermis, purified monocytes from human blood were induced with granulocyte-macrophage colony stimulating factor to generate a population of dendritic cell precursors expressing CD1c. Incubation with iC3b markedly inhibited the appearance of CD1c+ cells (p<0.05) and induced CD1c-CD14+ cells. This inhibition was reversed by coincubation with an anti-CD11b antibody that blocks the iC3b binding site. Other functions associated with dendritic cell maturation were also inhibited by iC3b, such as interleukin-12p70 production as well as CD80 and CD40 expression. Restimulation of monocytes for DC maturation revealed that iC3b induced a temporary inhibition of DC differentiation. Thus, a human skin response in which iC3b is transiently (3-7 d) generated in dermis, such as ultraviolet, can arrest monocytic skin-infiltrating cells from undergoing dendritic cell precursor differentiation.     

Fc epsilon R11/CD23 receptor distribution in patch test reactions to aeroallergens in atopic dermatitis.

There is increasing evidence that exposure to organic allergens may induce or exacerbate lesional skin in patients with atopic dermatitis. In this study, patients with atopic dermatitis were patch tested to 11 common organic allergens and to control chambers containing 0.4% phenol and 50% glycerin in 0.9% saline. In biopsies from positive patch test reactions, patch test control skin, lesional eczematous and non-lesional skin from atopic individuals, and normal skin from non-atopic volunteers, the presence and distribution of macrophages (RFD7+), dendritic cells (RFD1+), and Langerhans cells, and the expression of the low-affinity receptor for IgE (CD23) were investigated. In patch test reactions and lesional skin samples, inflammatory infiltrates of diffusely distributed macrophages (RFD7+), dendritic cells (RFD1+), T lymphocytes (RFTmix+), and Langerhans cells (CD1+) were seen, the latter being present in both the epidermis and the dermis. The numbers of Langerhans cells were reduced in the epidermis and increased in the dermis in patch test reactions and lesional skin compared to their controls. Double staining revealed a change in the distribution of CD23 antigen. In patch test control and non-lesional biopsies many macrophages and only a few Langerhans cells within the dermal infiltrates expressed this antigen. In patch test reaction and lesional skin samples, however, the proportion of CD23+ dermal Langerhans cells had increased compared to macrophages. Furthermore, in these latter samples an increased proportion of dermal CD1+ cells expressed the dendritic cell (RFD1+) marker. These results show that following antigen challenge there are marked similarities between the phenotype of the cellular infiltrate in patch test reaction and lesional skin biopsies, and also demonstrate a changing distribution of CD23 on antigen-presenting cells.     

T-cell receptor-gamma/delta bearing lymphocytes in normal and inflammatory human skin

Murine dendritic epidermal T cells (DETC) were recently reported to express T-cell receptor (TCR)-gamma/delta chains. In a search for the human equivalent of these cells, we tested normal and lesional skin with MoAb which react with the TCR-gamma/delta heterodimer. We performed indirect immunofluorescence (IF) on epidermal sheets, and alkaline-phosphatase-anti-alkaline-phosphatase complex (APAAP) on epidermal cell smears. Frozen skin sections from normal skin and various cutaneous lymphocyte infiltrates were also studied. A few CD3+ T lymphocytes were consistently found in normal epidermis. Most of these cells appeared to be TCR-alpha/beta +, and some CD4+ or CD8+. On epidermal sheets and cell smears, only a very small TCR-gamma/delta + cell population was visualized (less than 0.1% of the total). On normal skin sections, we observed 0 to 3 gamma/delta + cells per section. When present, they were often located in the epidermal basal layer, and were round or dendritic. Double immunolabeling revealed that gamma/delta + cells differed from CD1+ Langerhans cells, and that they had a similar phenotypic pattern as gamma/delta + peripheral lymphocytes (PBL): CD2+, CD3+, CD4-, and CD8-. Immunostaining from various inflammatory skin lesions showed that the dermal infiltrates included CD3+ T lymphocytes but virtually no gamma/delta + cells. Only a few gamma/delta + cells were found in some end-evolutive infiltrates. Taken together, these results strongly suggest that normal human epidermis occasionally harbors TCR-gamma/delta complex bearing lymphocytes, which constitute a small fraction of the CD3+ cutaneous T lymphocytes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Self‐renewal capacity of human epidermal Langerhans cells: observations made on a composite tissue allograft

Abstract: Epidermal Langerhans cells (LC) are dendritic, antigen‐presenting cells residing within mammalian epidermis and mucosal epithelia. When massively depleted, they are replaced by cells of bone‐marrow origin. However, their renewal within normal skin under steady‐state conditions is not precisely known. We observed that epidermal LC within a human hand allograft remain stable in the long term (10 years) and are not replaced by cells of recipient’s origin; furthermore, we observed a Langerhans cell in mitosis within the epidermis 8 years postgraft. These results show that under almost physiological conditions, human LC renew in the epidermis by local mitoses of preexisting cells.     

Accessory and adhesion molecules expressed on murine epidermal Langerhans cells and the modulation by cytokines.

Langerhans cells (LC) are MHC class II (Ia)-positive dendritic cells that act as an antigen-presenting cells for T cell-dependent immune responses. LC originate from cells in bone marrow and migrate into the epidermis through blood vessels. LC also migrate from the epidermis to regional lymph nodes after antigen stimulation where they present antigens to T cells. These are the essential features of LC. The morphological and functional properties of LC are modulated by external stimuli or various cytokines. In this review we focus on the accessory and adhesion molecules on LC and describe how these molecules are modulated by cytokines. We also describe the molecules participating in the migration of LC into and from the epidermis. Moreover, we introduce our data obtained from purified murine epidermal LC and from the transgenic mice overexpressing several cytokines in the epidermis.