Characteristics and functions of murine cutaneous dendritic cells: a synopsis of recent developments.

Cutaneous accessory cells include dendritic cells (DCs) and macrophages. Heterogeneity, plasticity, and responsiveness to local environmental cues are hallmarks of both types of cells. Until recently, results of studies of cells that had been extracted from tissues or propagated in vitro provided the foundation for most conceptual frameworks. The availability of a variety of spontaneously occurring and genetically engineered mice has facilitated in vivo studies that have provided new insights into the developmental and functional aspects of DCs in skin and other tissues. In several instances, results of these in vivo studies have been very surprising. Existing paradigms have been modified or debunked, and new hypotheses have been generated. We can anticipate that detailed understanding of the biology of individual cutaneous accessory cells and their relationships with each other will continue to accumulate as these types of studies are actively pursued.

The role of interleukin (IL)-10 in the persistence of Leishmania major in the skin after healing and the therapeutic potential of anti-IL-10 receptor antibody for sterile cure.

Some pathogens (e.g., Mycobacterium tuberculosis, Toxoplasma gondii, Leishmania spp) have been shown to persist in their host after clinical cure, establishing the risk of disease reactivation. We analyzed the conditions necessary for the long term maintenance of Leishmania major in genetically resistant C57BL/6 mice after spontaneous healing of their dermal lesions. Interleukin (IL)-10 was found to play an essential role in parasite persistence as sterile cure was achieved in IL-10-deficient and IL-4/IL-10 double-deficient mice. The requirement for IL-10 in establishing latency associated with natural infection was confirmed in IL-10-deficient mice challenged by bite of infected sand flies. The host-parasite equilibrium was maintained by CD4+ and CD8+ T cells which were each able to release IL-10 or interferon (IFN)-gamma, and were found to accumulate in chronic sites of infection, including the skin and draining lymph node. A high frequency of the dermal CD4+ T cells released both IL-10 and IFN-gamma. Wild-type mice treated transiently during the chronic phase with anti-IL-10 receptor antibodies achieved sterile cure, suggesting a novel therapeutic approach to eliminate latency, infection reservoirs, and the risk of reactivation disease.

Multistep navigation of Langerhans/dendritic cells in and out of the skin.

Langerhans cells (LCs) are specialized antigen-presenting cells that reside in the epidermis as sentinels of the immune system. LCs constantly monitor the epidermal microenvironment by taking up antigen and processing it into fragments that can be recognized by cells of the adaptive immune response. Because of their unique migratory ability, LCs can transport antigen from the epidermis to regional lymph nodes, where they can initiate systemic immune responses. The mechanisms of LC trafficking thus seem to be of particular relevance for the induction and maintenance of cutaneous immunity. LCs or their putative precursors express surface molecules that allow them to home to skin and localize in the epidermis for prolonged periods of time. Tissue injury, microbial infection, and other perturbants of epidermal homeostasis (eg, contact allergens) provide danger signals, leading to a local production of proinflammatory cytokines that induce LC mobilization to the lymphoid tissue. At the same time, signals are generated that recruit LC precursors into the skin to maintain the epidermal LC population. Distinct pairs of chemokines and their receptors control the migration from blood to epidermis and from there to the regional lymphatics. In addition, trafficking is controlled at the level of cell adhesion, where LCs downregulate some adhesion molecules to exit the epidermis and upregulate others to migrate across the extracellular matrix and home to T-cell areas of regional lymphoid tissue. The improved understanding of mechanisms that regulate LC trafficking might offer new opportunities for therapeutic interventions to suppress, stimulate, or deviate cutaneous immune responses.

Generation of langerhans cell-like dendritic cells from murine fetal skin.

The dendritic cell (DC) lineage is comprised of bone marrow-derived cells that are present in small numbers in nonlymphoid as well as lymphoid tissues (1). Nonlymphoid DC, such as epidermal Langerhans cells (LC), display an immature phenotype, i.e., they are capable of acquiring and processing antigen, but express only low levels of MHC antigen and costimulatory molecules and do not effectively initiate primary immune responses. In contrast, interdigitating DC in lymphoid tissue display a mature phenotype, i.e., they have limited phagocytic and antigen-processing capacity, but express high levels of MHC antigen and costimulatory molecules and are very effective stimulators of naive T cells (2). The conceptual link between nonlymphoid and lymphoid organ DC was provided by Schuler et al. several years ago when they demonstrated that epidermal LC cultured in GM-CSF-containing media for several days matured into cells with phenotypic and functional characteristics of interdigitating DC (3). The transformation of immature epidermal LC into mature DC in vitro mimics what occurs in vivo during the migration of epidermal LC to regional lymph nodes. This model has been widely used for studies of LC/DC function.

Skin dendritic cells in murine cutaneous leishmaniasis.

Studies of the immunopathogenesis of Leishmania major-induced murine cutaneous leishmaniasis provide a framework for understanding the evolution of L. major infection of skin in humans and the foundation for rationale vaccine design. Experiments in which infection is initiated with "suprap hysiologic" numbers of parasites clearly identify Th-derived type I cytokines as essential participants in macrophage activation and macrophage nitric oxide production as prerequisite for parasite control. Dendritic cells, rather than macrophages, appear to be responsible for L. major-specific Th priming in these studies. Recent studies of murine cutaneous leishmaniasis in a model system in which infection is initiated with lower, more physiologic numbers of parasites confirm many of the important findings obtained in "high dose" inoculation models, but important differences have been noted. The low dose inoculation model should ultimately provide insights into mechanisms that are responsible for dendritic cell recruitment into leishmania lesions, mechanisms that facilitate parasite acquisition by skin dendritic cells and cellular interactions that eventuate in T cell priming and lesion involution.

Leishmania major-infected murine langerhans cell-like dendritic cells from susceptible mice release IL-12 after infection and vaccinate against experimental cutaneous Leishmaniasis.

Leishmania major-infected C57BL / 6 skin-dendritic cells (DC) are activated and release cytokines (including IL-12 p70), and likely initiate protective Th1 immunity in vivo (von Stebut, E. et al., J. Exp. Med. 188: 1547 - 1552). To characterize differences in DC function in mice that are genetically susceptible (BALB / c) and resistant (C57BL / 6) to cutaneous leishmaniasis, we analyzed the effects of L. major on Langerhans cell-like, fetal skin-derived DC (FSDDC) from both strains. BALB / c- and C57BL / 6-FSDDC ingested similar numbers of amastigotes, but did not ingest metacyclic promastigotes. Like C57BL / 6-FSDDC, infection of BALB / c-FSDDC led to up-regulation of MHC class I and II antigens, CD40, CD54, and CD86 within 18 h. L. major-induced BALB / c DC activation also led to the release of TNF-alpha, IL-6 and IL-12 p40 into 18-h supernatants. Infected BALB / c- and C57BL / 6-DC both released small amounts of IL-12 p70 within 72 h. Additional stimulation with IFN-gamma and / or anti-CD40 induced the release of more IL-12 p70 from infected BALB / c-DC than C57BL / 6-DC. Co-culture of control or infected BALB / c- and C57BL / 6-DC with naive syngeneic CD4(+) T cells and soluble anti-CD3 resulted in mixed, IFN-gamma-predominant responses after restimulation with immobilized anti-CD3. Finally, syngeneic L. major-infected DC effectively vaccinated BALB / c mice against cutaneous leishmaniasis. Genetic susceptibility to L. major that results from induction of Th2 predominant immune responses after infection does not appear to reflect failure of skin DC to internalize or respond to parasites, or the inability of BALB / c T cells to mount a Th1 response to DC-associated Leishmania antigens.

Immunostimulatory oligodeoxynucleotides promote protective immunity and provide systemic therapy for leishmaniasis via IL-12- and IFN-gamma-dependent mechanisms.

Resistance to murine leishmaniasis correlates with development of a CD4(+) T helper 1 (Th1)-predominant immune response. To determine whether immunostimulatory CpG-containing oligodeoxynucleotides (CpG-ODN), known to promote a Th1 immune response, could provide protection from Leishmania infection, CpG-ODN and freeze-thawed (F/T) Leishmania major were coinjected intradermally into susceptible BALB/c mice. A Leishmania-specific Th1-predominant immune response was induced, and 40% of animals were protected from subsequent challenge with infectious organisms, with 0% protection of animals injected with F/T Leishmania organisms and PBS, F/T organisms and control ODN, or F/T organisms alone. More striking protection (65-95%) was seen in mice first infected with intact Leishmania organisms and then injected with CpG-ODN, either at the site of infection or at a remote site. To determine whether the therapeutic protection provided by CpG-ODN depended on IL-12 and IFN-gamma production, both IFN-gamma-deficient BALB/c mice and BALB/c mice treated with neutralizing anti-IL-12 mAb were first inoculated with Leishmania and then treated with either CpG-ODN, ODN, or PBS. None of these IFN-gamma-deficient mice survived (0/20, 0/20, and 0/20 respectively). Furthermore, neutralization of IL-12 completely abolished the therapeutic protection provided by CpG-ODN (0/20 mice surviving). We conclude that immunostimulatory DNA sequences likely exert systemic effects via IL-12 and IFN-gamma-dependent mechanisms and hold considerable promise as both vaccine adjuvants and potential therapeutic agents in the prevention and treatment of leishmaniasis.

Bacterial DNA and CpG-containing oligodeoxynucleotides activate cutaneous dendritic cells and induce IL-12 production: implications for the augmentation of Th1 responses.

BACKGROUND: Unmethylated CpG sequences in bacterial DNA act as adjuvants selectively inducing Th1 predominant immune responses during genetic vaccination or when used in conjunction with protein Ag. The precise mechanism of this adjuvant effect is unknown. Because dendritic cells (DC) are thought to be crucially involved in T cell priming and Th1/Th2 education during vaccination via skin, we characterized the effects of bacterial DNA and CpG-containing oligodeoxynucleotides (CpG ODN) on cutaneous DC. METHODS AND RESULTS: Stimulation with CpG ODN 1826 (6 micrograms/ml) induced activation of immature Langerhans cell (LC)-like DC as determined by an increased expression of MHC class II and costimulatory molecules, loss of E-cadherin-mediated adhesion and increased ability to stimulate allogeneic T cells. Composition-matched control ODN 1911 lacking CpG sequences at equal concentrations was without effect. In comparison to LPS and ODN 1911, CpG ODN 1826 selectively stimulated DC to release large amounts of IL-12 (p40) and little IL-6 or TNF-alpha within 18 h and detectable levels of IL-12 p70 within 72 h. Stimulation with Escherichia coli DNA, but not calf thymus DNA, similarly induced DC maturation and IL-12 p40 production. Injection of CpG ODN into murine dermis induced enhanced expression of MHC class II and CD86 by LC in the overlying epidermis and intracytoplasmic IL-12 p40 accumulation in a subpopulation of activated LC. CONCLUSION: Bacterial DNA and CpG ODN stimulate DC in vitro and in vivo and may preferentially elicit Th1-predominant immune responses because they can activate and mobilize DC, inducing them to produce IL-12.

Characterization of E-cadherin-containing junctions involving skin-derived dendritic cells.

Adherens junctions are sites of contact between epithelial cells in which adhesion is mediated by homophilic interactions of classical cadherins that are linked to the cytoskeleton via catenins. E-cadherin constitutes the major adhesion molecule in adherens junctions of keratinocytes (KC) and mediates the binding of Langerhans cells to KC in vitro. To characterize structures responsible for E-cadherin-mediated binding of Langerhans cells, we utilized Langerhans cells-like fetal skin-derived dendritic cells (FSDDC) capable of E-cadherin-mediated adhesion. Confocal microscopy of FSDDC aggregates demonstrated colocalization of E-cadherin and catenins to areas of cell-cell contact. Immunoprecipitation confirmed a physical association of E-cadherin with intracellular catenins (alpha-, beta-, gamma-catenin/plakoglobin and p120CAs). Transmission electron microscopy of FSDDC aggregates revealed structures with features of adherens junctions in areas of cell-cell contact, and post-embedding immunoelectron microscopy localized beta-catenin to these regions. To characterize junctions that accounted for the adhesion of Langerhans cells-like dendritic cells and KC, disaggregated FSDDC were cocultured with primary murine KC. Transmission electron microscopy analysis of cocultures demonstrated FSDDC-KC contacts that were analogous to those seen in FSDDC aggregates. Confocal microscopy demonstrated focal accumulations of E-cadherin and colocalization of beta-catenin in areas of contact between KC and immature (Langerhans cell-like) dendritic cells, but not in areas of contact between KC and mature (lymph node dendritic cell-like) dendritic cells. E-cadherin in Langerhans cells appears to be localized in structures that resemble adherens junctions formed by nonpolarized epithelial cells. Loss of ability to form or maintain these structures after the induction of Langerhans cells activation/ maturation likely results in the attenuation of Langerhans cells-KC adhesion that precedes Langerhans cells emigration from the epidermis.

Epidermal Langerhans cells: from neurons to nature's adjuvants.

Once obscure cells of interest to only a few dermatologists, LCs have become perhaps the best studied of all the nonlymphoid DCs. Seminal studies carried out by Steinman and co-workers over a number of years have demonstrated that interdigitating DCs are required for the priming of naive T cells in vivo and that LCs (and presumably other DCs) are precursors of interdigitating DCs. These observations have sparked an explosion of research activity directed toward increasing our understanding of the biology of LCs and other DCs and exploiting their unique functional properties for the prevention and treatment of disease. This chapter represents an attempt to provide an introduction to this exciting field. We have briefly reviewed the history of LC research, summarized a number of important concepts in LC/DC biology, and highlighted the involvement of LCs in several diseases or pathophysiologic conditions. We have emphasized recent studies of DC-based immunotherapy and the roles that LCs/DCs play in genetic vaccination because we believe that LC/DC research will have an impact on patient care in these areas. The past few years have been a period of rapid progress in basic research in LC/DC biology, and many important discoveries have been made. We hope that the next decade will be a period in which applied LC/DC research is just as exciting.

Uptake of Leishmania major amastigotes results in activation and interleukin 12 release from murine skin-derived dendritic cells: implications for the initiation of anti-Leishmania immunity.

Epidermal Langerhans cells (LC) are immature dendritic cells (DC) located in close proximity to the site of inoculation of infectious Leishmania major metacyclic promastigotes by sand flies. Using LC-like DC expanded from C57BL/6 fetal skin, we characterized interactions involving several developmental stages of Leishmania and DC. We confirmed that L. major amastigotes, but not promastigotes, efficiently entered LC-like DC. Parasite internalization was associated with activation manifested by upregulation of major histocompatibility complex (MHC) class I and II surface antigens, increased expression of costimulatory molecules (CD40, CD54, CD80, and CD86), and interleukin (IL)-12 p40 release within 18 h. L. major-induced IL-12 p70 release by DC required interferon gamma and prolonged (72 h) incubation. In contrast, infection of inflammatory macrophages (Mphi) with amastigotes or promastigotes did not lead to significant changes in surface antigen expression or cytokine production. These results suggest that skin Mphi and DC are infected sequentially in cutaneous leishmaniasis and that they play distinct roles in the inflammatory and immune response initiated by L. major. Mphi capture organisms near the site of inoculation early in the course of infection after establishment of cellular immunity, and kill amastigotes but probably do not actively participate in T cell priming. In contrast, skin DC are induced to express increased amounts of MHC antigens and costimulatory molecules and to release cytokines (including IL-12 p70) by exposure to L. major amastigotes that ultimately accumulate in lesional tissue, and thus very likely initiate protective T helper cell type 1 immunity.

Genetic immunization with glycoprotein 63 cDNA results in a helper T cell type 1 immune response and protection in a murine model of leishmaniasis.

Genetic immunization is a promising gene therapy approach for the prevention and treatment of infectious disease. Plasmid DNA expressing genes of pathogens is directly introduced into host cells and specific cell-mediated and/or humoral immune responses are elicited against the encoded protein. Leishmaniasis is a significant world-wide health problem for which no vaccine exists. In susceptible animals, such as BALB/c mice, protection from leishmaniasis requires induction of a Thl immune response. In this study, cell-mediated immunity to Leishmania major (L. major) was induced by injecting BALB/c mice intradermally with plasmid DNA expressing the conserved L. major cell surface glycoprotein gp63 (gp63-pcDNA-3). CD4 T lymphocytes from gp63-pcDNA-3-immunized mice proliferated and produced IFN-gamma (but not IL-4) when stimulated in vitro with freeze-thawed parasites, consistent with a Th1 immune response. In contrast, lymphocyte proliferation in animals immunized with freeze-thawed parasites was associated with IL-4 (but not IFN-gamma) production, suggesting a nonprotective Th2 response. Challenge studies revealed that gp63-pcDNA-3 vaccination protected 30% of susceptible mice (21 of 70) from Leishmania infection while neither gp63 protein (0 of 20) nor freeze-thawed parasite vaccines (0 of 50) were efficacious. Dendritic cells derived from skin of gp63-pcDNA-3-injected mice also immunized naive recipients and protected them from leishmaniasis. We conclude that gp63-pcDNA-3 genetic vaccination results in a CD4-dependent Th1 immune response that correlates with protection from disease, and suggest that skin-derived dendritic cells are involved in priming this response.

Activation of cutaneous dendritic cells by CpG-containing oligodeoxynucleotides: a role for dendritic cells in the augmentation of Th1 responses by immunostimulatory DNA.

Genetic vaccination depends at least in part on the adjuvant properties of plasmids, properties that have been ascribed to unmethylated CpG dinucleotides in bacterial DNA. Because dendritic cells (DC) participate in the T cell priming that occurs during genetic vaccination, we reasoned that CpG-containing DNA might activate DC. Thus, we assessed the effects of CpG oligodeoxynucleotides (CpG ODN) on Langerhans cell (LC)-like murine fetal skin-derived DC (FSDDC) in vitro and on LC in vivo. Treatment with CpG ODN as well as LPS induced FSDDC maturation, manifested by decreased E-cadherin-mediated adhesion, up-regulation of MHC class II and costimulator molecule expression, and acquisition of enhanced accessory cell activity. In contrast to LPS, CpG ODN stimulated FSDDC to produce large amounts of IL-12 but only small amounts of IL-6 and TNF-alpha. Injection of CpG ODN into murine dermis also led to enhanced expression of MHC class II and CD86 Ag by LC in overlying epidermis and intracytoplasmic IL-12 accumulation in a subpopulation of activated LC. We conclude that immunostimulatory CpG ODN stimulate DC in vitro and in vivo. Bacterial DNA-based vaccines may preferentially elicit Th1-predominant immune responses because they activate and mobilize DC and induce them to produce large amounts of IL-12.

Characterization of Wnt gene expression in murine skin: possible involvement of epidermis-derived Wnt-4 in cutaneous epithelial-mesenchymal interactions.

Wnt glycoproteins mediate short range intracellular communication that facilitates morphogenesis and, in some settings, promotes tumor formation. Although the involvement of the Drosophila homolog wingless in ectodermal patterning is well established, the role that Wnt genes play in mammalian skin biology is not defined. We detected Wnt-4 and Wnt-10b mRNA in adult murine epidermis using degenerate primers and reverse transcriptase PCR, and confirmed expression by RNase protection. Normal murine keratinocytes and a melanocyte cell line (melan-A) propagated in vitro also contained Wnt-4 mRNA, whereas dermal fibroblasts and Langerhans cell-like dendritic cells did not. Because Wnt-4 mRNA was more abundant than Wnt-10b mRNA in epidermis and Wnt-10b trancripts were not detected in cells propagated in vitro, additional studies emphasized Wnt-4 exclusively. Wnt-4 mRNA levels were increased in cultured keratinocytes as they approached confluence and were strikingly downregulated by mitogenic growth factors. Although Wnt-4 mRNA levels were not modulated during calcium-induced keratinocyte differentiation in vitro, assessment of Wnt-4 transcripts in keratinocyte cell lines suggested that loss of Wnt-4 gene expression was associated with a less differentiated, more malignant, phenotype. Despite this, epidermal abnormalities were not identified in newborn Wnt-4 null (-/-) skin, or in full-thickness -/- skin that was engrafted to nude or athymic mice and allowed to mature for as long as 3 months. However, histologic examination of newborn Wnt-4 null skin did reveal fibroplasia involving the dermis with increased accumulation of type I collagen fibrils. These results indicate that several Wnt genes are expressed in adult murine epidermis and suggest that Wnt-4 proteins may be involved in epidermal-dermal interactions in mammalian skin.

T cell development in mice lacking all T cell receptor zeta family members (Zeta, eta, and FcepsilonRIgamma).

The zeta family includes zeta, eta, and FcepsilonRIgamma (Fcgamma). Dimers of the zeta family proteins function as signal transducing subunits of the T cell antigen receptor (TCR), the pre-TCR, and a subset of Fc receptors. In mice lacking zeta/eta chains, T cell development is impaired, yet low numbers of CD4+ and CD8+ T cells develop. This finding suggests either that pre-TCR and TCR complexes lacking a zeta family dimer can promote T cell maturation, or that in the absence of zeta/eta, Fcgamma serves as a subunit in TCR complexes. To elucidate the role of zeta family dimers in T cell development, we generated mice lacking expression of all of these proteins and compared their phenotype to mice lacking only zeta/eta or Fcgamma. The data reveal that surface complexes that are expressed in the absence of zeta family dimers are capable of transducing signals required for alpha/beta-T cell development. Strikingly, T cells generated in both zeta/eta-/- and zeta/eta-/--Fcgamma-/- mice exhibit a memory phenotype and elaborate interferon gamma. Finally, examination of different T cell populations reveals that zeta/eta and Fcgamma have distinct expression patterns that correlate with their thymus dependency. A possible function for the differential expression of zeta family proteins may be to impart distinctive signaling properties to TCR complexes expressed on specific T cell populations.

Regulation of E-cadherin-mediated adhesion in Langerhans cell-like dendritic cells by inflammatory mediators that mobilize Langerhans cells in vivo.

Adhesion of Langerhans cells (LC) to keratinocytes is mediated by E-cadherin. IL-1, TNF-alpha, and LPS mobilize LC from epidermis and presumably attenuate LC-keratinocyte adhesion. To determine whether these mediators modulated LC E-cadherin-dependent adhesion directly, we characterized their effects on LC-like dendritic cells expanded from murine fetal skin (FSDDC). FSDDC were propagated from day 16 C57BL/6 fetal skin and isolated as aggregates (FSDDC-A) in which homophilic adhesion was mediated by E-cadherin. IL-1, TNF-alpha, and LPS induced dissociation of FSDDC-A that began within 4 to 8 h and was complete within 20 h. Anti-IL-1RI mAb inhibited disaggregation caused by IL-1alpha and IL-1beta, but not that induced by TNF-alpha or LPS. Anti-TNF-alpha mAb inhibited the effect of TNF-alpha and LPS, but not that caused by IL-1alpha or IL-1beta. Flow cytometry of FSDDC-A revealed that IL-1, TNF-alpha, and LPS induced increased expression of MHC class II, CD40, and CD86 and decreased E-cadherin expression that was temporally related to dissociation of aggregates. IL-1 and TNF-alpha caused a rapid reduction in FSDDC E-cadherin mRNA levels that preceded the decrease in E-cadherin surface expression. These results demonstrate that cytokines that induce LC emigration in vivo act directly on LC-like cells in vitro, reduce E-cadherin mRNA levels, down-regulate E-cadherin surface expression, and induce a loss of E-cadherin-mediated adhesion.

E-cadherin-mediated adhesion involving Langerhans cell-like dendritic cells expanded from murine fetal skin.

Langerhans cells (LC), the epidermal contingent of the dendritic cell (DC) lineage, migrate from skin to regional lymph nodes to initiate primary immune responses against Ag encountered in skin. Because E-cadherin mediates LC-keratinocyte adhesion, E-cadherin expression and/or function must be modulated during LC migration. To facilitate studies of LC/DC cadherin biology, we defined culture conditions that allowed expansion of LC-like cells from fetal murine skin. Fetal skin-derived dendritic cells (FSDDC) were propagated from C57BL/6 day 16 fetal skin in GM-CSF- and CSF-1-supplemented media. After 14 days, aggregates of E-cadherin+ FSDDC (FSDDC-A) that resembled freshly-obtained LC with regard to phenotype and function were isolated. Nonadherent FSDDC (FSDDC-NA) with dendritic morphology, surface phenotype identical to that of interdigitating DC and potent allostimulatory capacity were released from FSDDC-A with continued incubation. A survey of cytokine mRNAs expressed by FSDDC revealed that FSDDC-A expressed predominantly TNF-alpha, TGF-beta1, and MIF mRNA. In contrast, FSDDC-NA exhibited de novo expression of IL-1beta, IL-12 (p40), increased levels of TNF-alpha and decreased MIF mRNA. Neutralizing anti-E-cadherin mAb dissociated FSDDC-A into single cells, whereas functionally inactive anti-E-cadherin mAb and mAb reactive with other adhesion molecules did not, demonstrating that adhesion within FSDDC-A was E-cadherin-mediated. FSDDC-A also preferentially adhered to E-cadherin-transfected fibroblasts. Spontaneous dissociation of FSDDC-A was accompanied by a reduction in cell surface E-cadherin expression. The availability of large numbers of cells with characteristics of LC in situ that spontaneously mature into interdigitating DC will permit detailed studies of LC/DC cadherin biology and LC/DC differentiation.

A role for TGFbeta1 in langerhans cell biology. Further characterization of the epidermal Langerhans cell defect in TGFbeta1 null mice.

Previous studies of TGFbeta1 null (-/-) mice indicated that the epidermis was devoid of Langerhans cells (LC) and that the LC deficiency was not secondary to the inflammation that is the dominant feature of the -/- phenotype (Borkowski, T.A., J.J. Letterio, A.G. Farr, and M.C. Udey. 1996. J. Exp. Med. 184:2417-2422). Herein, we demonstrate that dendritic cells could be expanded from the bone marrow of -/- mice and littermate controls. Bone marrow from -/- mice also gave rise to LC after transfer into lethally irradiated recipients. Thus, the LC defect in TGFbeta1 null mice does not result from an absolute deficiency in bone marrow precursors, and paracrine TGFbeta1 production is sufficient for LC development. Several approaches were used to assess the suitability of -/- skin for LC localization. A survey revealed that although a number of cytokine mRNAs were expressed de novo, mRNAs encoding proinflammatory cytokines known to mobilize LC from epidermis (IL-1 and TNFalpha) were not strikingly overrepresented in -/- skin. In addition, bone marrow-derived LC populated full-thickness TGFbeta1 null skin after engraftment onto BALB/c nu/nu recipients. Finally, the skin of transgenic mice expressing a truncated loricrin promoter-driven dominant-negative TGFbeta type II receptor contained normal numbers of LC. Because TGFbeta1 signaling in these mice is disrupted only in keratinocytes and the keratinocyte hyperproliferative component of the TGFbeta1 -/- phenotype is reproduced, these results strongly suggest that the LC defect in TGFbeta1 null mice is not due to an epidermal abnormality but reflects a requirement of murine LC (or their precursors) for TGFbeta1.