Immature Langerhans Cells Research Articles

IL-4 supports the generation of a dendritic cell subset from murine bone marrow with altered endocytosis capacity

Dendritic cells (DC) of myeloid origin can be generated from mouse bone marrow (BM) using granulocyte macrophage-colony stimulating factor (GM-CSF). Immature major histocompatibility complex (MHC) II(low) DC are known to bear a high endocytosis capacity, in contrast to DC precursors and mature DC. Now we found that a subset of MHC II(low) DC in BM-DC cultures is unable to exert mannose receptor-mediated endocytosis of fluorescein isothiocyanate (FITC)-dextran (DX) and resembles immature Langerhans cells (LC). The FITC-DX endocytosis activity of LC-like cells occurs at an earlier stage of development, where the surface MHC II expression is absent or very weak. This LC-like subset expresses higher levels of E-cadherin but lower amounts of the markers Gr-1, scavenger receptor 2F8, and CD11b, when compared with the highly endocytic DC subset. The latter myeloid DC resemble monocyte-derived DC (MoDC). The sorted LC-like population develops completely and exclusively into mature MHC IIhigh DC, and the MoDC-like cells remain immature MHC II(low) DC or develop into adherent MHC IIneg macrophages or mature into MHC IIhigh DC. The development of LC-like cells is promoted by interleukin-4. Thus, we show here that the simultaneous development of LC-like and MoDC-like DC subsets occurs in standard bulk cultures with GM-CSF, suggesting the existence of two different precursors for LC and MoDC in BM.

PSC-RANTES blocks R5 human immunodeficiency virus infection of Langerhans cells isolated from individuals with a variety of CCR5 diplotypes.

Topical microbicides that effectively block interactions between CCR5(+) immature Langerhans cells (LC) residing within genital epithelia and R5 human immunodeficiency virus (HIV) may decrease sexual transmission of HIV. Here, we investigated the ability of synthetic RANTES analogues (AOP-, NNY-, and PSC-RANTES) to block R5 HIV infection of human immature LC by using a skin explant model. In initial experiments using activated peripheral blood mononuclear cells, each analogue compound demonstrated marked antiviral activity against two R5 HIV isolates. Next, we found that 20-min preincubation of skin explants with each RANTES analogue blocked R5 HIV infection of LC in a dose-dependent manner (1 to 100 nM) and that PSC-RANTES was the most potent of these compounds. Similarly, preincubation of LC with each analogue was able to block LC-mediated infection of cocultured CD4(+) T cells. Competition experiments between primary R5 and X4 HIV isolates showed blocking of R5 HIV by PSC-RANTES and no evidence of increased propagation of X4 HIV, data that are consistent with the specificity of PSC-RANTES for CCR5 and the CCR5(+) CXCR4(-) phenotype of immature LC. Finally, when CCR5 genetic polymorphism data were integrated with results from the in vitro LC infection studies, PSC-RANTES was found to be equally effective in inhibiting R5 HIV in LC isolated from individuals with CCR5 diplotypes known to be associated with low, intermediate, and high cell surface levels of CCR5. In summary, PSC-RANTES is a potent inhibitor of R5 HIV infection in immature LC, suggesting that it may be useful as a topical microbicide to block sexual transmission of HIV.

Langerhans’ cell count and HLA class II profile in cervical intraepithelial neoplasia in the presence or absence of HIV infection

Objectives: The progression of immunosuppression in human immunodeficiency virus (HIV)+ women has been correlated with elevated incidence of squamous intraepithelial lesions (SIL), probably indicating the role of local immune milieu. In this study, we analysed S100, and HLA class II molecule expression in cervical biopsies according to HIV status, to the severity of SIL and to human papillomavirus (HPV) type. Methods: Biopsies from 34 HIV+ and 44 HIV− patients with normal cervix or low- or high-grade SIL were studied. Langerhans’ cells (LC) (S100), HLA class II and HLA-DQ molecules were evaluated by immunohistochemistry. HPV detection was performed using polymerase chain reaction (PCR). For statistical analysis Mann–Whitney ( P≤0.05) and Spearman test were used. Results: Epithelial S100 and HLA class II density were significantly increased with the severity of lesion ( P=0.032; P=0.005). Epithelial S100 + increased in HPV+ ( P=0.038), and HLA class II density decreased in HPV 16+ ( P=0.035) or 18+ ( P<0.0001) samples. HIV infection was associated with increased stromal S100 + ( P=0.0005) and decreased HLA class II densities ( P=0.0001). Decreased stromal S100 + was observed in women with CD4<500 cells/μl ( P=0.050). Among HIV+ patients with SIL, the lowest S100 and epithelial HLA class II densities were detected in women with CD4<200 cells/μl ( P=0.045). Conclusions: After the establishment of AIDS, increased numbers of immature LCs and a reduction in HLA class II occurred, possibly turning the cervical milieu more favourable to HPV persistence. HPV 16 and 18 infections may interfere with the antigen presenting activity, possibly as an evasion mechanism.

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.

CD1a and CD1c cell sorting yields a homogeneous population of immature human Langerhans cells

There is increasing evidence that ex vivo generated Langerhans cells (LCs) cannot fully substitute for their physiological counterparts in normal epidermis when studying the immunobiology of this prototype of a tissue-residing immature dendritic cell (DC). Here, we present CD1-based magnetic-activated cell-sorting (MACS) protocols for the effective isolation of human epidermal LCs. CD1c selection yielded a homogeneous population of pure and viable HLA-DR +/CD1a + DCs, with the ultrastructural features, surface antigen expression and cytokine profile, characteristic of epidermis-resident immature LCs. The immature state and functional integrity were established by allogeneic mixed lymphocyte reactions showing a weak stimulatory capacity of freshly isolated cells and upregulation upon stimulation. Characterizing the cells in more detail, we could demonstrate for the first time that normal human LCs express CXCR4, CD40 ligand (CD40L), and Fas and Fas ligand (FasL). The observed constitutive transcription of TGF-β suggests that the viability and immature state of epidermal LCs are maintained not only by the TGF-β production from the microenvironment, but also in an autocrine or paracrine manner. LPS and IFN-ω stimulated the expression of the inflammatory cytokines TNF-α and IL-1β, and there was secretion of IL-12p70 after CD40 ligation. Remarkably, the CD1-sorted LCs showed no loss of their Birbeck granules and CD1a expression upon culturing and no spontaneous phenotypic and functional maturation into potent antigen-presenting cells (APCs). We conclude that human epidermal LCs obtained by the CD1c cell-sorting protocol are optimal candidates with which to elucidate the properties and capabilities of immature cells and to develop immunotherapeutic vaccines.

Susceptibility of immature and mature Langerhans cell-type dendritic cells to infection and immunomodulation by human cytomegalovirus.

Human cytomegalovirus (CMV) infection initiates in mucosal epithelia and disseminates via leukocytes throughout the body. Langerhans cells (LCs), the immature dendritic cells (DCs) that reside in epithelial tissues, are among the first cells to encounter virus and may play important roles in the immune response, as well as in pathogenesis as hosts for viral replication and as vehicles for dissemination. Here, we demonstrate that CD34(+) progenitor cell-derived LC-type DCs exhibit a differentiation state-dependent susceptibility to CMV infection. In contrast to the small percentage (3 to 4%) of the immature LCs that supported infection, a high percentage (48 to 74%) of mature, LC-derived DCs were susceptible to infection with endotheliotropic strains (TB40/E or VHL/E) of CMV. These cells were much less susceptible to viral strains AD169varATCC, TownevarRIT(3), and Toledo. When exposed to endotheliotropic strains, viral gene expression (IE1/IE2 and other viral gene products) and viral replication proceeded efficiently in LC-derived mature DCs (mDCs). Productive infection was associated with downmodulation of cell surface CD83, CD1a, CD80, CD86, ICAM-1, major histocompatibility complex (MHC) class I, and MHC class II on these cells. In addition, the T-cell proliferative response to allogeneic LC-derived mDCs was attenuated when CMV-infected cultures were used as stimulators. This investigation revealed important characteristics of the interaction between CMV and the LC lineage of DCs, suggesting that LC-derived mDCs are important to viral pathogenesis and immunity through their increased susceptibility to virus replication and virus-mediated immune escape.

TNF-alpha induces the generation of Langerin/(CD207)+ immature Langerhans-type dendritic cells from both CD14-CD1a and CD14+CD1a- precursors derived from CD34+ cord blood cells.

CD34+ cell-derived hematopoietic precursors amplified with FLT3-ligand, thrombopoietin and stem cell factor became, after a 6-day induction with GM-CSF, IL-4 and TGF-beta1, HLA-DR+, CD1a+, CD83-, CD86-, CD80- cells. A fraction of them expressed Langerin, Lag, and E-cadherin, resembling epidermal Langerhans cells (LC). TNF-alpha added for the last 3 days only marginally induced CD83 expression, but strikingly increased the proportion of immature Langerin+CD83- LC. Langerin+CD83+ and Langerin+CD83- cells were functionally distinct, the former internalizing less efficiently Langerin than the latter. Both CD1a-CD14- and CD1a-CD14+ cells sorted from FLT3-ligand, thrombopoietin and stem cell factor cultures responded to TNF-alpha by an increase of Langerin+ cells. Thus, TNF-alpha rescued LC precursors irrespective of their commitment to the monocytic lineage. When added to GM-CSF, IL-4 and TGF-beta1 containing-cultures, LPS or IL-1beta also induced significant numbers of Langerin+CD83- immature cells displaying a low allostimulatory activity, while CD40-ligand largely promoted highly allostimulatory Langerin-CD83+ cells. Altogether, these data show that in contrast to CD40-ligand, which induced LC maturation even in presence of TGF-beta1, nonspecific proinflammatory factors such as TNF-alpha, IL-1 or LPS, essentially induced immature LC generation, and little cell activation in the presence of TGF-beta1.

Macrophage Colony-stimulating Factor in Cooperation with Transforming Growth Factor-β1 Induces the Differentiation of CD34+ Hematopoietic Progenitor Cells Into Langerhans Cells Under Serum-free Conditions Without Granulocyte-macrophage Colony-stimulating Factor

Macrophage colony-stimulating factor has not been considered as a factor responsible for dendritic cell or Langerhans cell development from hematopoietic progenitor cells. In this study, we examined whether macrophage colony-stimulating factor could be used instead of granulocyte-macrophage colony-stimulating factor for the in vitro development of Langerhans cells from hematopoietic progenitor cells. We replaced granulocyte-macrophage colony-stimulating factor with macrophage colony-stimulating factor from a serum-free culture containing granulocyte-macrophage colony-stimulating factor, stem cell factor, Flt3 ligand, tumor necrosis factor-alpha, and transforming growth factor-beta1. This serum-free culture medium containing macrophage colony-stimulating factor, but not granulocyte-macrophage colony-stimulating factor (macrophage colony-stimulating factor culture), could induce CD1a+ Birbeck granule+ Langerin+ E-cadherin+ factor-like XIIIa Langerhans cells. As a control, the culture of hematopoietic progenitor cells in this culture medium depleted of macrophage colony-stimulating factor or transforming growth factor-beta1 resulted in far fewer or null CD1a+ cells, respectively. Macrophage colony-stimulating factor increased the number of CD1a+ cells in a concentration-dependent fashion. These macrophage colony-stimulating factor-induced Langerhans cells were different from granulocyte-macrophage colony-stimulating factor-induced Langerhans cells in their decreased expression of CD11c and their immature phenotype. The decreased expression of CD11c, however, was recovered by culturing them with granulocyte-macrophage colony-stimulating factor, while they acquired a mature phenotype qby granulocyte-macrophage colony-stimulating factor, tumor necrosis factor-alpha, interleukin-1alpha, or lipo-polysaccharide. Macrophage colony-stimulating factor-induced Langerhans cells could stimulate allogeneic T cells. Interestingly, we could keep the growth and immature phenotypes of macrophage colony-stimulating factor-induced Langerhans cells for at least 28 d of culture. These studies demonstrated that macrophage colony-stimulating factor in cooperation with transforming growth factor-beta1 could induce Langerhans cell development from hematopoietic progenitor cells in vitro without granulocyte-macrophage colony-stimulating factor, which suggests the possibility that macrophage colony-stimulating factor plays a part in the Langerhans cell development in vivo. In addition, the culture using macrophage colony-stimulating factor presents a novel culture system to enable a large-scale and long-term culture of immature Langerhans cells.

Technique for obtaining highly enriched, quiescent immature Langerhans cells suitable for ex vivo assays

Epidermis and surface epithelium-dendritic cells comprise of immature cells termed Langerhans cells (LCs), which express characteristically the Birbeck granules, along with surface markers such as CD1a. These cells can capture a pathogen and then migrate and differentiate to a more mature stage. During this maturation process, dentritic cells express surface markers differentially. In physio-pathological models of infection where LCs are involved, it is critically important to ensure that the LCs tested in vitro are still immature and are not artefactually matured-dentritic cells. For experimental purposes, LCs were isolated from skin epidermis obtained from patients undergoing plastic surgery. This work thus aimed at collecting fresh LCs ex vivo and at testing the cells for phenotypic and functional characteristics of the immature stage. After mechanic disruption of the epidermis and proceeding for single cell suspension obtaining, two methods for purification were tested in parallel: (a) a positive immuno-magnetic separation by anti-CD1a-coated beads and (b) a purely mechanic purification system based on a three-step Ficoll floatation process. Both systems were equally efficient in terms of purification and yield. By using flow cytometry phenotyping, we have demonstrated that the use of magnetic beads led to some degree of maturation of CD1a + LCs, contrary to the repeated Ficoll floatation. This work calls attention for the use of certain monoclonal antibodies such as anti-CD1a to purify immature dendritic cells as they pre-activate these cells. Pre-activation would render a number of assays on the early events of LC physiology invalid, contrary to the purification of fresh skin epidermis LCs by means of a repeated Ficoll floatation.

Accumulation of Immature Langerhans Cells in Human Lymph Nodes Draining Chronically Inflamed Skin

The coordinated migration and maturation of dendritic cells (DCs) such as intraepithelial Langerhans cells (LCs) is considered critical for T cell priming in response to inflammation in the periphery. However, little is known about the role of inflammatory mediators for LC maturation and recruitment to lymph nodes in vivo. Here we show in human dermatopathic lymphadenitis (DL), which features an expanded population of LCs in one draining lymph node associated with inflammatory lesions in its tributary skin area, that the Langerin/CD207+ LCs constitute a predominant population of immature DCs, which express CD1a, and CD68, but not CD83, CD86, and DC–lysosomal-associated membrane protein (LAMP)/CD208. Using LC-type cells generated in vitro in the presence of transforming growth factor (TGF)-β1, we further found that tumor necrosis factor (TNF)-α, as a prototype proinflammatory factor, and a variety of inflammatory stimuli and bacterial products, increase Langerin expression and Langerin dependent Birbeck granules formation in cell which nevertheless lack costimulatory molecules, DC–LAMP/CD208 and potent T cell stimulatory activity but express CCR7 and respond to the lymph node homing chemokines CCL19 and CCL21. This indicates that LC migration and maturation can be independently regulated events. We suggest that during DL, inflammatory stimuli in the skin increase the migration of LCs to the lymph node but without associated maturation. Immature LCs might regulate immune responses during chronic inflammation.

Influence of the mucosal epithelium microenvironment on Langerhans cells: implications for the development of squamous intraepithelial lesions of the cervix.

We have addressed the notion that the initiation and progression of human papillomavirus associated cancer of the uterine cervix are associated with alterations of Langerhans cells (LC) within the mucosal squamous epithelium. Since the transformation zone (TZ) of the cervix is the site where the majority of squamous intraepithelial lesions (SIL) are initiated, in contrast to the exocervix, we decided to investigate the influence of the local microenvironment within the TZ on the function and density of LC. We show that the TZ is associated with a significant reduction in the density of immature LC (CD1a/LAG) compared to the exocervix. In contrast, the development of SILs is attributed with a relative increased density of immature LC, compared to the TZ. Furthermore, we show that this variability in LC density is correlated with a differential expression of TNFalpha and MIP3alpha within the micro-environment of the TZ and SILs. Both TZ and SIL epithelium-derived LC, in the presence of allogeneic PBMC, induced lower levels of proliferation and IL2 production and higher levels of the immunosuppressive cytokine IL10 in comparison to the exocervix. Nevertheless, the epithelium-derived LC in SILs exhibits a reduction in their functional activity, relative to the TZ. Together our studies suggest that the immunosurveillance within the epithelium of the TZ may be intrinsically perturbed due to the altered expression of chemokines/cytokines and the concomitant diminished density of LC. Furthermore, following HPV infection and the development of SILs, the function of LC may be further incapacitated by viral associated mechanisms.

Mature dendritic cells infiltrate the T cell-rich region of oral mucosa in chronic periodontitis: in situ, in vivo, and in vitro studies.

Previous studies have analyzed the lymphoid and myeloid foci within the gingival mucosa in health and chronic periodontitis (CP); however, the principal APCs responsible for the formation and organizational structure of these foci in CP have not been defined. We show that in human CP tissues, CD1a(+) immature Langerhans cells predominantly infiltrate the gingival epithelium, whereas CD83(+) mature dendritic cells (DCs) specifically infiltrate the CD4(+) lymphoid-rich lamina propria. In vivo evidence shows that exacerbation of CP results in increased levels of proinflammatory cytokines that mediate DC activation/maturation, but also of counterregulatory cytokines that may prevent a Th-polarized response. Consistently, in vitro-generated monocyte-derived DCs pulsed with Porphyromonas gingivalis strain 381 or its LPS undergo maturation, up-regulate accessory molecules, and release proinflammatory (IL-1beta, PGE(2)) and Th (IL-10, IL-12) cytokines. Interestingly, the IL-10:IL-12 ratio elicited from P. gingivalis-pulsed DCs was 3-fold higher than that from Escherichia coli-pulsed DCs. This may account for the significantly (p < 0.05) lower proliferation of autologous CD4(+) T cells and reduced release of IFN-gamma elicited by P. gingivalis-pulsed DCs. Taken together, these findings suggest a previously unreported mechanism for the pathophysiology of CP, involving the activation and in situ maturation of DCs by the oral pathogen P. gingivalis, leading to release of counterregulatory cytokines and the formation of T cell-DC foci.

Extraction of human Langerhans cells: a method for isolation of epidermis-resident dendritic cells

Langerhans cells (LCs) are immature dendritic cells in the epidermis that play a central role in T-lymphocyte mediated skin immunity. Upon activation with antigenic stimuli, they differentiate drastically into mature dendritic cells while migrating from the epidermis to regional lymph nodes. Thus, in order to study biological details of immature LCs, it is crucial to isolate epidermis-resident, immature LCs without dermal dendritic cell contamination. Methods for extracting LCs from human skin as well as in vitro derivation of LC-like cells from hematopoietic progenitor cells have been described previously, but the cell preparations can potentially contain a significant number of dendritic cells that are not identical to epidermal LCs. Here, we describe a technique by which purely epidermis-resident LCs are extracted from human skin. Following digestion of human skin with dispase, the epidermis was separated mechanically without any attached dermal component. The trypsinized epidermal cells were then fractionated by centrifugation with a discontinuous density gradient composed of bovine albumin and sodium metrizoate. The LC-enriched preparation thus obtained contained 80% to >90% CD1a +, E-cadherin + cells that expressed Birbeck granules and the Lag protein. Consistent with their being at an immature stage, the freshly isolated LCs lacked the expression of CD83, a marker for mature dendritic cells. The purified LCs were able to activate allogeneic T cells, indicating that the cells retained T-cell stimulation ability even after extraction. Thus, the present work offers an opportunity for precise in vitro studies of epidermal LCs.

A combination of MIP-3α and TGF-β1 is required for the attraction of human Langerhans precursor cells through a dermal-epidermal barrier

Signals regulating the traffic of Langerhans cell precursors from blood to the epidermis are not yet fully understood. The observations that TGF-beta1 is of unique importance in Langerhans cells (LC) ontogeny and that macrophage inflammatory protein-3alpha (MIP-3alpha) is able to attract LC within the epidermis, prompted us to study the effect of MIP-3alpha and TGF-beta1 on the migration of LC precursors. The migratory capacity of immature dendritic cells (DC) was assessed using a reconstituted basement membrane assay (Matrigel), mimicking the prerequisite passage through the dermal-epidermal basement membrane on the way into the epidermis. DC differentiated from cord blood CD34 cells in the presence of GM-CSF plus TNF-alpha were subjected to migration using modified Boyden chambers. Day-6 DC progenitors migrated in a dose-dependent fashion in response to MIP-3alpha, and CD1alpha+ LC precursors responded preferentially to the chemokine. Immature DC did not respond strongly to TGF-beta1 alone in migration assays, but up to 68% of the cells migrated in response to MIP-3alpha plus TGF-beta1. Among them, at least 50% expressed CD1a and E-cadherin and can be considered LC precursors. The allostimulatory function of these cells was significantly more potent than that which migrated in response to MIP-3alpha alone. Our results show that a significant proportion of immature DC is able to migrate through a dermal-epidermal basement membrane equivalent. In the presence of TGF-beta1, the DC which respond to MIP-3alpha have the phenotype and the functional capacity of epidermal LC. Our findings underline the role of MIP-3alpha and TGF-beta1 in attraction and localization of immature LC within the epidermis under normal conditions.

Ex vivo HIV-1 infection of human immature langerhans cells within epithelial tissue explants: a novel model for sexual transmission of HIV-1

Ex vivo HIV-1 infection of human immature langerhans cells within epithelial tissue explants: a novel model for sexual transmission of HIV-1

Low levels of productive HIV infection in Langerhans cell-like dendritic cells differentiated in the presence of TGF-beta1 and increased viral replication with CD40 ligand-induced maturation.

Langerhans cells (LC) represent dendritic cells (DC) within mucosal epithelium that are purported initial targets for HIV following sexual exposure to virus. Here, morphologic, phenotypic, functional and HIV infection experiments were performed using monocyte-derived DC cultured in the presence of GM-CSF, IL-4 and TGF-beta1 (G4T-DC), GM-CSF and IL-4 (G4-DC), and G4T-DC incubated for an additional 3 days with CD40 ligand (CD40L-DC). G4T-DC, which demonstrated characteristics of immature LC, could be productively infected by either R5- or X4-HIV strains. Infection levels, however, were markedly lower than those observed in immature G4-DC. Surprisingly, CD40L-DC, which demonstrated features of mature LC, could be productively infected with HIV at higher levels than immature G4T-DC. Productive HIV infection in these three DC populations correlated positively with cell surface expression of CD4, CCR5 and CXCR4. We suggest that low levels of HIV infection in LC-like G4T-DC indicate an inefficient mechanism by which HIV can initially infect individuals, perhaps explaining the relative difficulty in becoming infected during sexual exposure to virus. In addition, enhanced HIV infection in LC-like G4T-DC following CD40L treatment suggests a mechanism by which inflammatory CD40L(+) T cells, if present in mucosal tissue, could lead to increased HIV transmission rates.

Prevention of Autoimmunity by Induction of Cutaneous Tolerance

Autoimmune gastritis develops in 20–60% of BALB/c mice following thymectomy at 3 days after birth (3dnTx). Previously we identified the gastric H+/K+ ATPase as the causative autoantigen and mapped the immunoreactive T cell epitope to a carboxyl-terminal peptide on the gastric H+/K+ ATPase β subunit. Here we show that autoimmune gastritis can be suppressed by immunizing 3dnTx mice through neonatal skin with the β subunit peptide, in combination with the contact sensitizer TNCB. When spleen cells were transferred from suppressed mice to nude mice a proportion of recipient mice developed gastritis. These results indicate that pathogenic T cells were still present in the 3dnTx mice but the absence of gastritis indicates that their activity can be regulated following induction of cutaneous tolerance by immunizing through neonatal skin. We propose that cutaneous tolerance is induced through mediation of immature Langerhans cells in neonatal skin and that this tolerance prevented the autoreactivity of pathogenic T cells. This procedure will have implications for strategies to suppress autoimmunity.

Candidate microbicides block HIV-1 infection of human immature Langerhans cells within epithelial tissue explants.

Initial biologic events that underlie sexual transmission of HIV-1 are poorly understood. To model these events, we exposed human immature Langerhans cells (LCs) within epithelial tissue explants to two primary and two laboratory-adapted HIV-1 isolates. We detected HIV-1(Ba-L) infection in single LCs that spontaneously emigrated from explants by flow cytometry (median of infected LCs = 0.52%, range = 0.08-4.77%). HIV-1-infected LCs downregulated surface CD4 and CD83, whereas MHC class II, CD80, and CD86 were unchanged. For all HIV-1 strains tested, emigrated LCs were critical in establishing high levels of infection (0.1-1 microg HIV-1 p24 per milliliter) in cocultured autologous or allogeneic T cells. HIV-1(Ba-L) (an R5 HIV-1 strain) more efficiently infected LC-T cell cocultures when compared with HIV-1(IIIB) (an X4 HIV-1 strain). Interestingly, pretreatment of explants with either aminooxypentane-RANTES (regulated upon activation, normal T cell expressed and secreted) or cellulose acetate phthalate (potential microbicides) blocked HIV-1 infection of LCs and subsequent T cell infection in a dose-dependent manner. In summary, we document HIV-1 infection in single LCs after exposure to virus within epithelial tissue, demonstrate that relatively low numbers of these cells are capable of inducing high levels of infection in cocultured T cells, and provide a useful explant model for testing of agents designed to block sexual transmission of HIV-1.

Role of graft interleukin-10 expression in the tolerogenicity of neonatal skin allografts.

Allografts of skin from neonatal donors survive longer than those from adult donors and can induce tolerance in mice that are treated with short-term immunosuppression. Neonatal (< or =24 hr old) epidermal cells (EPC) secrete high levels of interleukin-(IL) 10 and include abundant class II- immature Langerhans cells (LC). In this study, the role of IL-10 in the tolerogenicity of neonatal skin grafts was examined. After a preliminary experiment established that tolerogenesis by neonatal grafts could be supported by monoclonal antilymphocyte antibodies, B10.A(5R) recipients were immunosuppressed with anti-CD4 plus anti-CD8 (days 0, +2) and adult C57B1/6 bone marrow cells (day +7). Recipients were grafted with adult or neonatal C57B1/6 skin from wild-type or IL-10 deficient ("knockout" donors). EPC from wild-type and knockout neonatal skin were compared by flow cytometry, before and after 48 hr culture, to adult cells in terms of class II and costimulatory molecule expression. Grafts from knockout neonates survived longer than those from adult donors (median survival, MST=81 vs. 61 days), but not as long as those from wild-type neonates (MST=100 days; P<0.05). As with normal neonatal EPC, neonatal knockout EPC expressed little class II antigen. Both types of neonatal EPC acquired class II in culture, and up-regulated CD80 and CD86 in an adult pattern, but failed to up-regulate class II antigen to the high level seen among cultured adult cells. The tolerogenicity of neonatal skin grafts derives in part from natural expression of IL-10 by the graft. Another possible contribution to tolerogenicity may be the inability of neonatal antigen presenting cells to up-regulate class II fully. Low expression of class II by neonatal cells is not attributable to epidermal IL-10 secretion.

TGF-β1 Prevents the Noncognate Maturation of Human Dendritic Langerhans Cells

Abstract TGF-β1 is critical for differentiation of epithelial-associated dendritic Langerhans cells (LC). In accordance with the characteristics of in vivo LC, we show that LC obtained from human monocytes in vitro in the presence of TGF-β1 1) express almost exclusively intracellular class II Ags, low CD80, and no CD83 and CD86 Ags and 2) down-regulate TNF-RI (p55) and do not produce IL-10 after stimulation, in contrast to dermal dendritic cells and monocyte-derived dendritic cells. Surprisingly, while LC exhibit E-cadherin down-regulation upon exposure to TNF-α and IL-1, TGF-β1 prevents the final LC maturation in response to TNF-α, IL-1, and LPS with respect to Class II CD80, CD86, and CD83 Ag expression, loss of FITC-dextran uptake, production of IL-12, and Ag presentation. In sharp contrast, CD40 ligand cognate signal induces full maturation of LC and is not inhibited by TGF-β1. The presence of emigrated immature LCs in human reactive skin-draining lymph nodes provides in vivo evidence that LC migration and final maturation may be differentially regulated. Therefore, due to the effects of TGF-β1, inflammatory stimuli may not be sufficient to induce full maturation of LC, thus avoiding potentially harmful immune responses. We conclude that TGF-β1 appears to be responsible for both the acquisition of LC phenotype, cytokine production pattern, and prevention of noncognate maturation.