The Thy-1-bearing cell of murine epidermis. A distinctive leukocyte perhaps related to natural killer cells

Epicutaneous Administration of 17β-Estradiol Induces Langerhans Cells Depletion

BACKGROUND

Langerhans cells (LC) number and function in mouse vaginal mucosa are affected by 17β-estradiol (E₂) application; nonetheless, its effect on epidermal LC has not been studied. The purpose of this study was to evaluate the effect of topical administration of E₂ on the number, phenotype, and migratory ability of LC in mouse skin.

METHODS

Ears of adult CD1 male mice were topically treated once with several doses. Immunohistochemical staining for CD207 and TUNEL staining were performed. LC migration to lymph nodes and the effect on the expression of costimulatory molecules on cultured dendritic cells (DC) were also evaluated.

RESULTS

E₂ decreased the number of CD207+ LC in a dose-dependent manner. One hour after treatment, 1 and 10 µg/mL E₂ significantly reduced the LC number by 21% and 26%, respectively, after two hours, the reduction was 23% and 41%, respectively. After 48 hours, LC recovered, and after 96 hours of treatment, the CD207+/MHCII+ DC numbers were increased in regional lymph nodes. However, CD86 and CD40 molecules were expressed at lower levels than in positive control. The TUNEL assay did not show apoptotic cells. Furthermore, in cultured DC, E₂ promoted a decrease in CD40 and CD86 expression and an increase in CD273, CD274, MHCII, and CCR7.

CONCLUSIONS

The topical administration of E₂ induced a transitory local diminution of LC population and a tolerogenic phenotype. This decrease in epidermal LC suggests that E₂ may affect skin immune responses, inducing an inhibitory response, which should be considered when prescribing topical E₂ medications.

Epidermal T Cell Dendrites Serve as Conduits for Bidirectional Trafficking of Granular Cargo

Dendritic epidermal T cells (DETCs) represent a prototypical lineage of intraepithelial γδ T cells that participate in the maintenance of body barrier homeostasis. Unlike classical T cells, DETCs do not recirculate and they remain persistently activated through their T cell receptors (TCR) at steady state, i.e., in absence of infection or tissue wounding. The steady state TCR signals sustain the formation of immunological synapse-like phosphotyrosine-rich aggregates located on projections (PALPs) which act to anchor and polarize DETC’s long cellular projections toward the apical epidermis while the cell bodies reside in the basal layers. The PALPs are known to contain pre-synaptic accumulations of TCR-containing and lysosomal granules, but how this cargo accumulates there remains unclear. Here, we combined anti-Vγ5 TCR, cholera toxin subunit B (CTB), and LysoTracker (LT)-based intravital labeling of intracellular granules, with high resolution dynamic microscopy and fluorescence recovery after photobleaching (FRAP) to characterize the steady state composition and transport of DETC granules in steady state epidermis. Intradermal fluorescent Vγ5 antibody decorated DETCs without causing cellular depletion, dendrite mobilization or rounding up and became slowly internalized over 48 h into intracellular granules that, after 6 days, colocalized with LAMP-1 and less so with LT or early endosomal antigen-1. Intradermal CTB was likewise internalized predominantly by DETCs in epidermis, labeling a partly overlapping set of largely LAMP-1⁺ intracellular granules. These as well as LT-labeled granules readily moved into newly forming dendrites and accumulated at the apical endings. FRAP and spatiotemporal tracking showed that the inside tubular lengths of DETC cellular projections supported dynamic trafficking of lysosomal cargo toward and away from the PALPs, including internalized TCR and lipid raft component ganglioside GM1 (labeled with CTB). By contrast, the rate of GM1 granules transport through comparable dendrites of non-DETCs was twice slower. Our observations suggest that DETCs use chronic TCR activation to establish a polarized conduit system for long-range trans-epithelial transport aimed to accumulate mature lysosomes at the barrier-forming apical epidermis. The biological strategy behind the steady state lysosome polarization by DETCs remains to be uncovered.

Lymph node homing of T cells and dendritic cells via afferent lymphatics

The continuous migration of immune cells is of utmost importance for the induction of both protective immunity as well as immunological tolerance. However, relatively little is known about the molecular cues that regulate the entry of immune cells from peripheral, nonlymphoid tissues into afferent lymph vessels and, in particular, their subsequent transmigration from afferent lymphatics into the parenchyma of draining lymph nodes (LNs). Here, we review the requirements for T cells and dendritic cells (DCs) to enter initial afferent lymph vessels of the skin. We discuss how these cells subsequently gain access to the paracortex of draining lymph nodes; a location that allows for efficient interaction between both cell populations, providing the right environment for the induction of immunity as well as tolerance.

Adjuvanted influenza vaccine administered intradermally elicits robust long-term immune responses that confer protection from lethal challenge

Background

The respiratory illnesses caused by influenza virus can be dramatically reduced by vaccination. The current trivalent inactivated influenza vaccine is effective in eliciting systemic virus-specific antibodies sufficient to control viral replication. However, influenza protection generated after parenteral immunization could be improved by the induction of mucosal immune responses.

Methodology/Principal Findings

Transcutaneous immunization, a non-invasive vaccine delivery method, was used to investigate the quality, duration and effectiveness of the immune responses induced in the presence of inactivated influenza virus co-administered with retinoic acid or oleic acid. We observed an increased migration of dendritic cells to the draining lymph nodes after dermal vaccination. Here we demonstrate that this route of vaccine delivery in combination with certain immunomodulators can induce potent immune responses that result in long-term protective immunity. Additionally, mice vaccinated with inactivated virus in combination with retinoic acid show an enhanced sIgA antibody response, increased number of antibody secreting cells in the mucosal tissues, and protection from a higher influenza lethal dose.

Conclusions/Significance

The present study demonstrates that transdermal administration of inactivated virus in combination with immunomodulators stimulates dendritic cell migration, results in long-lived systemic and mucosal responses that confer effective protective immunity.

Transdermal immunization with low-pressure-gene-gun mediated chitosan-based DNA vaccines against Japanese encephalitis virus

DNA vaccine is a milestone in contemporary vaccine development. It has considerably offset many shortcomings in conventional vaccines. Although DNA vaccines applied through 'traditional' high-pressure gene guns generally elicit high titers of protective immunity, such a practice however requires enormous investment in daunting instruments that often discourage vaccines due to an inevitable pain-eliciting effect. In this study, we exploited a less expensive yet low-pressure-gene-gun that can alleviate such phobia of pain. DNA vaccines were prepared by using the associative feature of cationic chitosan and anionic DNAs. The optimized N/P ratio is 3. The formulized complex sizes to nano-scale. The vaccine complexes were tested in C3H/HeN mice. The expression of GFP reporter gene was observable and traceable in epidermis and spleen over 3 days. The expressions of GFP and the activation of dendritic cells (DCs) were evident and co-localized in hair follicles and epidermis. C3H/HeN mice immunized with the developed chitosan-JEV DNA vaccines can elicit desired JEV specific antibodies, whereby the mice maintained high survival rates against 50xLD(50) JEV challenge. The low-pressure-gene-gun mediated chitosan-based JEV DNA vaccines have proven to be convenient and efficacious, thereby with high capacity in deployment for future prophylaxis against JEV outbreaks.

Expression of langerin/CD207 reveals dendritic cell heterogeneity between inbred mouse strains

Langerin/CD207 is expressed by a subset of dendritic cells (DC), the epithelial Langerhans cells. However, langerin is also detected among lymphoid tissue DC. Here, we describe striking differences in langerin-expressing cells between inbred mouse strains. While langerin+ cells are observed in comparable numbers and with comparable phenotypes in the epidermis, two distinct DC subsets bear langerin in peripheral, skin-draining lymph nodes of BALB/c mice (CD11c(high) CD8alpha(high) and CD11c(low) CD8alpha(low)), whereas only the latter subset is present in C57BL/6 mice. The CD11c(high) subset is detected in mesenteric lymph nodes and spleen of BALB/c mice, but is virtually absent from C57BL/6 mice. Similar differences are observed in other mouse strains. CD11c(low) langerin+ cells represent skin-derived Langerhans cells, as demonstrated by their high expression of DEC-205/CD205, maturation markers, and recruitment to skin-draining lymph nodes upon imiquimod-induced inflammation. It will be of interest to determine the role of lymphoid tissue-resident compared to skin-derived langerin+ DC.

Transcutaneous immunization with inactivated influenza virus induces protective immune responses

The recent outbreaks of highly pathogenic avian influenza in Asia and spread of the disease worldwide highlight the need to redefine conventional immunization approaches and establish effective mass vaccination strategies to face global pandemics. Transcutaneous immunization (TCI) is a novel route for vaccination, which uses the topical application of vaccine antigens on the skin. In this study, we investigated the potential of TCI using inactivated whole influenza virus. We found that TCI with whole inactivated influenza virus induced influenza virus-specific antibodies with hemagglutination inhibition and neutralizing activities as well as cellular immune responses, even without an adjuvant, and conferred protective immunity to virus challenge. Co-administration with cholera toxin (CT), a potent adjuvant for TCI, significantly enhanced immune responses against the influenza virus antigen. To enhance penetration of the skin barrier to the particulate influenza viral antigens, we tested the effects of the potential penetration enhancers/immunomodulators oleic acid (OA) and retinoic acid (RA). Pretreatment of mouse skin with OA elicited increased levels of influenza virus-specific binding and neutralizing antibodies to levels equivalent to those induced by intranasal immunization with inactivated influenza virus. OA and RA treatments differentially affected the pattern of cytokine production upon stimulation with influenza viral antigen and provided enhanced protection. These results reveal a promising perspective for the application of transcutaneous immunization to prevent influenza epidemics as well as a range of other infectious diseases.

Mouse lymphoid tissue contains distinct subsets of langerin/CD207 dendritic cells, only one of which represents epidermal-derived Langerhans cells

Langerin/CD207 is a C-type lectin associated with formation of Birbeck granules (BG) in Langerhans cells (LC). Here, we describe a monoclonal antibody (mAb 205C1) recognizing the extracellular domain of mouse langerin. Cell-surface langerin was detected in all epidermal LC, which presented a uniform phenotype. Two subpopulations of langerin+ cells were identified in peripheral lymph nodes (LN). One population (subset 1) was CD11c(low/+)/CD8alpha(-/low)/CD11b+/CD40+/CD86+. The other population (subset 2) was CD11c(high)/CD8alpha+/CD11b(low), and lacked CD40 and CD86. Only subset 1 was fluorescein 5-isothiocyanate (FITC+) following painting onto epidermis, and the appearance of such FITC+ cells in draining LN was inhibited by pertussis toxin. Mesenteric LN, spleen, and thymus contained only a single population of langerin+ DC, corresponding to peripheral LN subset 2. Unexpectedly, BG were absent from spleen CD8alpha+ DC despite expression of langerin, and these organelles were not induced by mAb 205C1. Collectively, we demonstrate that two langerin+ DC populations (subsets 1 and 2) co-exist in mouse lymphoid tissue. Subset 1 unequivocally identifies epidermal LC-derived DC. The distribution of subset 2 indicates a non-LC origin of these langerin+ cells. These findings should facilitate our understanding of the role played by langerin in lymphoid organ DC subsets.

Disruption of the langerin/CD207 gene abolishes Birbeck granules without a marked loss of Langerhans cell function

Langerin is a C-type lectin expressed by a subset of dendritic leukocytes, the Langerhans cells (LC). Langerin is a cell surface receptor that induces the formation of an LC-specific organelle, the Birbeck granule (BG). We generated a langerin(-/-) mouse on a C57BL/6 background which did not display any macroscopic aberrant development. In the absence of langerin, LC were detected in normal numbers in the epidermis but the cells lacked BG. LC of langerin(-/-) mice did not present other phenotypic alterations compared to wild-type littermates. Functionally, the langerin(-/-) LC were able to capture antigen, to migrate towards skin draining lymph nodes, and to undergo phenotypic maturation. In addition, langerin(-/-) mice were not impaired in their capacity to process native OVA protein for I-A(b)-restricted presentation to CD4(+) T lymphocytes or for H-2K(b)-restricted cross-presentation to CD8(+) T lymphocytes. langerin(-/-) mice inoculated with mannosylated or skin-tropic microorganisms did not display an altered pathogen susceptibility. Finally, chemical mutagenesis resulted in a similar rate of skin tumor development in langerin(-/-) and wild-type mice. Overall, our data indicate that langerin and BG are dispensable for a number of LC functions. The langerin(-/-) C57BL/6 mouse should be a valuable model for further functional exploration of langerin and the role of BG.

The role of dendritic cell C-type lectin receptors in HIV pathogenesis

Dendritic cells play a major role in HIV pathogenesis. Epithelial dendritic cells appear to be one of the first cells infected after sexual transmission and transfer of the virus to CD4 lymphocytes, simultaneously activating these cells to produce high levels of HIV replication. Such transfer may occur locally in inflamed mucosa or after dendritic cells have matured and migrated to local lymph nodes. Therefore, the mechanism of binding, internalization, infection and transfer of HIV to CD4 lymphocytes is of great interest. Recently, the role of the C-type lectin DC-SIGN as a dendritic cell receptor for HIV has been intensively studied with in vitro monocyte-derived dendritic cells. However, it is clear that other C-type lectin receptors such as Langerin on Langerhan cells and mannose receptor on dermal dendritic cells are at least equally important for gp120 binding on epithelial dendritic cells. C-type lectin receptors play a role in virus transfer to T cells, either via de novo infection ("cis transfer") or without infection ("in trans" or transinfection). Both these processes are important in vitro, and both may have a role in vivo, although the low-level infection of immature dendritic cells may be more important as it leads to R5 HIV strain selection and persistence of virus within dendritic cells for at least 24 h, sufficient for these cells to transit to lymph nodes. The exact details of these processes are currently the subject of intense study.

CD4 is expressed by epidermal Langerhans' cells predominantly as covalent dimers

Langerhans' cells (LC) of skin are CD4 expressing, dendritic, antigen-presenting cells, that are essential for activation of primary immune responses and are productively infected by HIV. We have shown previously that lymphocytes and monocytes express CD4 both as monomers and covalently linked homodimers. In those cells the 55-kDa monomer structure predominates. LC in un-fractionated human epidermal cell (EC) suspension also expresses both forms of CD4, but in EC the dimer form is predominant. Because isolation of LC into single cell suspension by trypsin, as is routinely used for LC isolation, degrades CD4, a systematic study for an alternate procedure for LC isolation was performed. Thus it was found that collagenase blend F treatment can efficiently release LC into suspension, under conditions of only minimal degradation of control soluble recombinant CD4 or CEM-T4 or THP-1 cell CD4, or importantly of LC surface CD4. SDS-PAGE immunoblotting of purified LC extracted from EC by collagenase confirmed CD4 structure as predominantly 110-kDa dimers, with only minimal 55-kDa monomers. The suitability of LC prepared thus for functional studies was demonstrated with binding of functional ligand HIV gp120. It remains to be determined, however, why tissue embedded LC express mainly CD4 dimers, but single-celled blood lymphocytes and monocytes mainly monomers.

A close-up view of migrating Langerhans cells in the skin

Langerhans cells of the epidermis and dermal dendritic cells screen the skin for invading antigens. They initiate primary immune responses after migrating from sites of antigen uptake to lymphoid organs. The skin is a feasible model to study the morphology and regulation of dendritic cell migration. We therefore used murine skin explant cultures for tracking the pathways of dendritic cell migration by electron microscopy. Several novel observations are reported. (i) In 48 h cultures of epidermal sheets numerous Langerhans cells migrated out between keratinocytes extending long and thin cytoplasmic processes ("veils"). (ii) Langerhans cells in transition from epidermis to dermis were observed by transmission electron microscopy. Where Langerhans cells penetrated the basement membrane, the lamina densa was focally absent. (iii) This was highlighted by scanning electron microscopy, which presented the basement membrane as a tightly packed and dense network of fibrils. (iv) Scanning electron microscopy of the dermis revealed dendritic cells extending their cytoplasmic processes and clinging to collagen fibrils. (v) Entry of dendritic cells into dermal lymphatics was observed by transmission electron microscopy. It occurred by transmigration through intercellular spaces of adjacent endothelial cells. Entry through wide gaps between endothelial cells also seemed to take place. (vi) Dendritic cells inside the afferent lymphatics frequently carried material such as melanosomes and apoptotic bodies. These observations visualize the cumbersome pathway that dendritic cells have to take when they generate immunity.

A poxvirus protein that binds to and inactivates IL-18, and inhibits NK cell response

IL-18 induces IFN-gamma and NK cell cytotoxicity, making it a logical target for viral antagonism of host defense. We demonstrate that the ectromelia poxvirus p13 protein, bearing homology to the mammalian IL-18 binding protein, binds IL-18, and inhibits its activity in vitro. Binding of IL-18 to the viral p13 protein was compared with binding to the cellular IL-18R. The dissociation constant of p13 for murine IL-18 is 5 nM, compared with 0.2 nM for the cellular receptor heterodimer. Mice infected with a p13 deletion mutant of ectromelia virus had elevated cytotoxicity for YAC-1 tumor cell targets compared with control animals. Additionally, the p13 deletion mutant virus exhibited decreased levels of infectivity. Our data suggest that inactivation of IL-18, and subsequent impairment of NK cell cytotoxicity, may be one mechanism by which ectromelia evades the host immune response.

ATPase and MHC class II molecules co-expression in Rana pipiens dendritic cells

Mammalian Langerhans cells are antigen-presenting cells located in different epithelia. These cells have a characteristic ultrastructural pattern, present a plasmatic membrane ATPase activity and constitutively express class II molecules of the major histocompatibility complex. ATPase-positive dendritic cells that are morphologically similar to Langerhans cells have also been found in amphibian epidermis. In order to demonstrate that ATPase-positive dendritic cells of amphibian epidermis express class II molecules and are present in other stratified epithelia, histochemical and immunohistochemical as well as ultrastructural analysis were performed. ATPase-positive dendritic cells and class II-positive dendritic cells were observed in epidermis, nictitant membrane and cornea. In epidermis the number of ATPase-positive dendritic cells was 656+/-186/mm2 while class II-positive dendritic cells was 119+/-45/mm2. Some ATPase-positive dendritic cells showed co-expression of class II molecules. These results suggest the existence of dendritic cell subsets in amphibians as is clearly demonstrated in mammals.

Reduction in number and morphologic alterations of Langerhans cells after UVB radiation in vivo are accompanied by an influx of monocytoid cells into the epidermis

Acute, low-dose ultraviolet B (UVB) radiation impairs contact hypersensitivity induction in mice by a mechanism due at least in part to Langerhans cells alterations. To better define the effects of UVB on Langerhans cells, we have compared the action of this agent on the skin of intact mice and in skin explants incubated in vitro up to 24 h. Using immunofluorescence, we detected a reduction in the length of the dendrites of Langerhans cells and a significant reduction in the number of Ia-positive Langerhans cells per unit area within 2 h of UVB; these changes reversed within 24 h in vivo, but not in vitro. By electron microscopy, the number of dendritic cells per 100 basal keratinocytes increased in vivo, but decreased in vitro by 2 h after UVB, a discordance that was significant. On the contrary, the number of dendrite profiles per dendritic cell body decreased significantly 2 h after UVB, both in vivo and in vitro. Many epidermal dendritic cells, 2 h after UVB in vivo, were deficient in cytoplasmic organelles, whereas the few cells that remained after UVB in vitro retained their Birbeck granules, and displayed many, dilated cytoplasmic vesicles. We interpret these data to mean that low doses of UVB radiation destroy the functional and morphologic integrity of epidermal Langerhans cells, and that these cells are rapidly replaced by precursor cells that mature in situ into normal-appearing Langerhans cells.

Entry into afferent lymphatics and maturation in situ of migrating murine cutaneous dendritic cells

An important property of dendritic cells (DC), which contributes crucially to their strong immunogenic function, is their capacity to migrate from sites of antigen capture to the draining lymphoid organs. Here we studied in detail the migratory pathway and the differentiation of DC during migration in a skin organ culture model and, for comparison, in the conventional contact hypersensitivity system. We report several observations on the capacity of cutaneous DC to migrate in mouse ear skin. (i) Upon application of contact allergens in vivo the density of Langerhans cells in epidermal sheets decreased, as determined by immunostaining for major histocompatibility complex class II, ADPase, F4/80, CD11b, CD32, NLDC-145/DEC-205, and the cytoskeleton protein vimentin. Evaluation was performed by computer assisted morphometry. (ii) Chemically related nonsensitizing or tolerizing compounds left the density of Langerhans cells unchanged. (iii) Immunohistochemical double-staining of dermal sheets from skin organ cultures for major histocompatibility complex class II and CD54 excluded blood vessels as a cutaneous pathway of DC migration. (iv) Electron microscopy of organ cultures revealed dermal accumulations of DC (including Birbeck granule containing Langerhans cells) within typical lymphatic vessels. (v) Populations of migrating DC in organ cultures upregulated markers of maturity (the antigen recognized by monoclonal antibody 2A1, CD86), but retained indicators of immaturity (invariant chain, residual antigen processing function). These data provide additional evidence that during both the induction of contact hypersensitivity and in skin organ culture, Langerhans cells physically leave the epidermis. Both Langerhans cells and dermal DC enter lymphatic vessels. DC mature while they migrate through the skin.

Production of murine monoclonal antibodies to guinea pig leukocytes and immunohistochemistry of guinea pig skin exposed to Schistosoma mansoni

Using histochemical ATPase-staining of the guinea pig epidermal sheet, we have demonstrated remarkable accumulations of ATPase-positive cells after exposure to attenuated Schistosoma mansoni cercariae. To characterize further the cells accumulating in the skin after exposure to S. mansoni, we produced a panel of monoclonal antibodies (MAb) to guinea pig leukocytes. These were immunohistochemically classified into 15 types and included MAb to the major histocompatibility complex (MHC) Class I and Class II molecules, shared antigens of all lymph node cells or between lymph node cells and Langerhans' cells (LC), T cells and macrophages (M phi), and M phi including the large Tingible body M phi in the secondary follicle. Varied MAb to M phi, including commercially available MAb (MR-1), were negative with ATPase- and MHC Class II-positive cells accumulated in the skin exposed to S. mansoni. Three MAb (HUSM-30 and 46, and commercially available MSgp2) detected an identical staining profile of accumulated cells with epidermal LC, but two MAb (HUSM-12 and 42) positively stained accumulated cells but not resident LC. These results indicate that the cells accumulated in the guinea pig skin within a few days after exposure to attenuated cercariae of S. mansoni are closest to LC, not to Mø, and may be blood-borne LC/dendritic cells.

Sequence analysis of rat integrin alpha E1 and alpha E2 subunits: tissue expression reveals phenotypic similarities between intraepithelial lymphocytes and dendritic cells in lymph

The integrin alpha OX-62 subunit is defined by the OX-62 monoclonal antibody that was raised against rat dendritic cells in lymph (veiled cells) and shows properties similar to those of human alpha E2 that is predominantly expressed on intraepithelial lymphocytes. To clone alpha OX-62, rat probes generated using primers specific for the human alpha E sequence were used to screen rat T cell cDNA libraries. cDNA clones encoding two similar but not identical alpha subunits that are closely related to but distinct from human alpha E were isolated. alpha E1 is predicted to be the rat homolog of mouse alpha M290 and alpha E2 corresponds to rat alpha OX-62. Immunofluorescence analysis revealed that mouse alpha E1 and rat alpha E2 are expressed in dendritic epidermal T cells in the skin, intraepithelial lymphocytes in the small intestine and in cells with a dendritic morphology present at sites where gamma delta T cells occur in lymphoid organs. Unexpectedly, alpha E2 is co-expressed with intracellular CD3-delta and a 33-kDa CD3 chain but not the T cell receptor in veiled cells. These findings suggest that veiled cells may be derived from a lymphoid precursor. Furthermore, veiled cells show phenotypic similarities to intraepithelial lymphocytes.

Rat pancreatic islet and skin xenograft survival in CD4 and CD8 knockout mice

The relative contributions of the CD4+ and CD8+ T cell subpopulations in xenotransplant rejection were studied using CD4 and CD8 knockout (KO) mice. Wistar Furth (WF, RT1a) rat pancreatic islet or skin xenografts were transplanted into either CD4 or CD8 KO recipients and compared to wild-type controls. Long-term survival of WF islet xenografts was observed in the CD4 KO mice (MST, >66+/-8 days) whereas CD8 KO mice rejected their islet xenografts within 8 days, similar to controls (MST, 7+/-0.2 days). In contrast, WF skin xenografts were rejected in both CD4 and CD8 KO recipients within 8 days. CD4 KO recipients which maintained xenoislets >90 days posttransplant rejected WF skin grafts within 9 days, without rejecting their original islet xenografts. These results suggest that CD4+ cells are essential for mediating islet xenograft rejection. These data also suggest that the absence of either CD4+ or CD8+ T cells is not sufficient to prevent rejection of skin xenografts.

Physiology and pathophysiology of dendritic cells

Dendritic cells are antigen-presenting cells derived from the hematopoietic stem cell. The dendritic cell family includes Langerhans' cells (CD1a-positive dendritic cells of the skin), and antigen-presenting cells that are found in the lymphoreticular system and throughout the organ parenchyme. Dendritic cells play a key role in both the primary and secondary immune responses. Several studies indicate that these cells participate in antitumor immunity, tumor surveillance, graft-versus-host disease, and in the pathogenesis of clinical syndromes of unknown origin or those induced by viruses, such as the human immunodeficiency virus. Different disorders are characterized by an abnormal proliferation and accumulation of dendritic cells; for example, the Langerhans' histiocytes, which accumulate in Langerhans' cell histiocytosis. In this review the immunophenotypic, morphological, and functional characteristics of the dendritic cell family is described. The clinical and laboratory studies suggesting a unique role for these cells in various syndromes and diseases are reviewed. The Langerhans' cell histiocytoses and the malignant disorders associated with transformation of cells belonging to the dendritic cell family, are discussed.

An immunocytochemical study of MHC class I expression on human Langerhans cells and melanocytes

Classical MHC class I glycoproteins (HLA-A, B, and C) present endogenous cytosolic peptide antigen fragments to CD8-positive T-cells. CD8-positive T-cell recognition and destruction of virus-infected cells are dependent on adequate cellular MHC class I expression. Constitutive MHC class I expression is ubiquitous, but known to be deficient on specific differentiated cell types which include hepatocytes, neurones, chondrocytes and myocytes. Although enabling assessment of MHC class I expression on individual cells, limitations of immunocytochemistry were encountered with this assessment on Langerhans cells and melanocytes. These dispersed intraepidermal cells were obscured by adjacent keratinocytes in sections immunostained for MHC class I glycoproteins. Initiatives designed to resolve the issue have included immunoelectron microscopy, cell culture techniques, and animal bone marrow chimera models. Despite the elegance of these techniques, the issue of MHC class I expression on Langerhans cells and melanocytes remains unresolved. In this immunocytochemical study, an alternative strategy was based upon the recognized deficiency of epithelial MHC class I expression within pilosebaceous adnexal units. Langerhans cells and melanocytes were therefore studied within this microenvironment of deficient MHC class I expression, using monomorphic and polymorphic MHC markers. Langerhans cells and melanocytes were demonstrated within pilosebaceous units of scalp skin by immunocytochemistry. Differentiation markers OKT6 (CD1a) and TMH1 defined Langerhans cells and melanocytes, respectively. Monomorphic MHC markers W6/32 and TAL IB5 defined invariant epitopes of HLA class I and II, respectively. Polymorphic MHC class I markers defined the HLA-Bw4 and HLA-Bw6 supertypic determinants. Constitutive MHC class I expression was shown to be deficient on Langerhans cells and melanocytes.

Isolation and characterization of high endothelial cell lines derived from mouse lymph nodes

Two long-term cultured cell lines were established from BALB/c mouse axillary and cervical lymph nodes that exhibited a combination of functional, morphological, and phenotypic characteristics consistent only with high endothelial venule cells. Spleen lymphocytes selectively bound and migrated across the cell lines. On Matrigel, these cell lines formed tubules with lumens, a characteristic unique to endothelial cells. Morphologically the cells were 20-30 microns in diameter and exhibited contact inhibition. The cells were not myeloid in origin because they lacked sodium fluoride-inhibitable nonspecific esterase activity, myeloperoxidase activity, and F4/80 antigen. The cell line phenotypes were compared to high endothelial venule (HEV) cells in tissue sections. HEV cells in lymph node tissue sections expressed endoglin, PECAM-1, ICAM-1, VCAM-1, laminin, fibronectin, collagen IV, H2Kd, MECA 79, MECA 325, and vWF. The cell lines expressed endoglin, VCAM-1, fibronectin, and H2Kd. The cell line derived from cervical lymph nodes also expressed laminin and H2Dd. Neither cell line expressed collagen IV, IAd, ICAM-1, ICAM-2, dendritic cell antigen, or PECAM-1. They also did not express MECA antigens or intracellular vWF, consistent with reports of many cultured endothelial cells. To further substantiate cell ine identification, antiserum generated against the cell lines bound specifically to HEV cells in frozen lymph node tissue sections and to both of the lymph node-derived cell lines but not control cell lines. Thus, the lymph node derived-cell lines expressed molecules found on HEV cells in vivo and most importantly retained the functions of tubule formation, lymphocyte adhesion, and promotion of lymphocyte migration.

In vitro analysis of the phenotypical and functional properties of the 4F7+ cutaneous accessory dendritic cell

The monoclonal antibody 4F7 detects a molecule on dermal and epidermal Ia+ dendritic cells (DCs), and some of these cells are Birbeck granule-containing cells. Here we report on the phenotypical and functional characteristics of these cells which were highly enriched by 4F7-labelled immunomagnetic beads. The ultrastructural, immunocytochemical and cytochemical analyses of these preparations showed cells with the typical characteristics of DCs. The cells were found to express the DC marker NLDC145, but not 33D1. The C3bi receptor and marker F4/80 were only expressed by epidermal 4F7+ cells. The capacity of freshly isolated 4F7+ epidermal and dermal DCs to activate allogeneic T cells in a mixed leukocyte reaction was similar to the capacity of freshly isolated Langerhans cells. After culture, the epidermal cells showed a 4-5-fold increase in stimulation, whereas no difference was observed in the 4F7+ dermal DCs. We conclude that this new antibody recognizes a function-associated molecule on cutaneous DCs which are phenotypically and functionally related to Langerhans cells. The 4F7+ DCs may be precursors of epidermal Langerhans cells.

Migration of murine epidermal Langerhans cells to regional lymph nodes: engagement of major histocompatibility complex class II antigens induces migration of Langerhans cells

Langerhans cells are resident dendritic cells in the epidermis. Once they are loaded with epicutaneously-delivered antigens, they leave the epidermis and migrate to the regional lymph nodes where they initiate primary T cell responses as antigen-presenting cells. However, the stimulus that initiates such migration remains unknown. Because major histocompatibility complex class II (Ia) antigens on B lymphocytes or monocytic cells have been shown to function as signal transducers, we evaluated the effect of the engagement of Ia antigens on the migration of murine epidermal Langerhans cells. The intradermal injection of an anti-Ia monoclonal antibody (mAb) reduced the density of Langerhans cells in epidermis and produced a dose- and time-dependent increase in the frequency of cells reactive with NLDC145 (Langerhans cell- and dendritic cell-specific mAb) within the regional lymph nodes. Injection of a control mAb had no effect. The NLDC145+ cells that were induced to accumulate in the regional lymph nodes were Ia+, large dendritic cells, some of which were positive for both NLDC145 and F4/80, a phenotype corresponding to that of murine epidermal Langerhans cells. Thus, the engagement of Ia antigens on Langerhans cells by mAb induces the migration of Langerhans cells from the epidermis to the regional lymph nodes. Analysis of these changes in Langerhans cells in vitro may help to reveal the biochemical sequence of events involved in the activation and differentiation of Langerhans cells.

Ia antigens are expressed on ATPase-positive dendritic cells in chicken epidermis

Langerhans cells (LC) are antigen-presenting dendritic cells located in mammalian epidermis and in other stratified epithelia. We recently demonstrated the presence of Langerhans-like cells in the epidermis of the chicken using ultrastructural histochemistry for adenosine triphosphatase (ATPase). The aim of the present study was to test whether ATPase-positive dendritic cells also express class II histocompatibility molecules (Ia antigens) encoded by the major histocompatibility complex (MHC), using a double staining technique, in separated chicken epidermal sheets. We concluded that the epidermal dendritic cells observed are the LC of the chicken, based on their morphology and spatial distribution, but mainly on the complete overlap for ATPase reaction and Ia antigen expression, these being reliable markers for the identification of mammalian LC.

T-cell receptor diversity in dendritic epidermal T cells in the rat

The rat epidermis contains a population of dendritic CD3+ cells. For a better characterization of these cells and to investigate their relationship to epidermal lymphocytes of other species, we stained rat epidermal sheets using a variety of monoclonal antibodies against rat leukocyte differentiation antigens in an indirect immunofluorescence procedure. Additionally, we attempted to define their T-cell receptor (TCR) isotype at both the nucleic acid and protein level. Results obtained showed that the majority of the CD3+ dendritic epidermal cells are CD45+, CD2+, TCR alpha beta-, major histocompatibility complex class II-, Thy-1-, asialo GM1-, CD4-, CD5-, and CD8- lymphocytes. We further observed that, in contrast to the mouse system, the rat epidermis additionally harbors a small but distinctive portion of dendritic CD3+ cells that exhibit reactivity with an anti-pan TCR alpha beta monoclonal antibody. Our further finding that rat epidermal cells enriched for CD3+ lymphocytes express full-length C delta mRNA suggests that the vast majority of rat epidermal T cells carry surface-bound TCR gamma delta moieties. On the basis of these findings, one may speculate that the indigenous T-cell population of the epidermis is not necessarily programmed to uniformly express monomorphic TCR gamma delta molecules but, to effectively fulfill its role in host defense, is capable of adaptation to the specific challenges encountered by a given species.

Interaction of cutaneous stromal cells and gamma/delta T cell receptor (TcR)-positive cells. I. V gamma 5-gamma/delta TcR+ T cells migrating from organ-cultured murine skin proliferate by co-culture with cutaneous stromal cells in the presence of interleukin-2

It has been reported that Thy-1+CD3+CD4-CD8- cells as well as Langerhans cells migrate from organ-cultured murine skin into culture medium. We examined whether these Thy-1+ populations of migrating cells were derived from Thy-1+ dendritic epidermal T cells (Thy-1+ DEC) and found that they were Thy-1+CD3+CD4-CD8-gamma/delta TcR+ (gamma delta+T) cells but did not express V gamma 5TcR, which was used by a vast majority of Thy-1+ DEC. Recently, a unique interaction between stromal cells and lymphohemopoietic progenitors has been reported in bone marrow and thymus. In this study, we established fibroblastoid cutaneous stromal cell (CSC) lines and clones from murine skin and examined the interaction between CSC and gamma delta+T cells. When these gamma delta+T cells were co-cultured with CSC, a marked proliferation of small lymphoid cells was observed only in the presence of interleukin (IL)-2. Neither CSC alone nor IL-2 alone could induce a similar proliferation. Flow cytometry revealed that they were Thy-1+CD3+CD4-CD8-gamma/delta TcR+ but V gamma 5TcR-. Analysis of the major segments of their TcR by polymerase chain reaction demonstrated that V gamma 1, V gamma 2, V gamma 4 and all of the V delta chains from V delta 1 to V delta 7 were used without any predominant pattern. These data indicate the possible presence of gamma/delta+T cells other than V gamma 5TcR+Thy-1+ DEC in the murine skin and the unique capacity of the CSC to support the growth of these migrating gamma/delta+ T cells. The nomenclature of murine T cell receptor gamma chain is according to Reilly et al. (Nature 1986. 321:878). The relationship between the different nomenclature systems is summarized in Takagi et al. (J. Immunol. 1989. 141:2112).

Identification of macrophages and dendritic cells in the osteopetrotic (op/op) mouse

We used a panel of monoclonal antibodies and immunocytochemistry to identify macrophages and dendritic cells in mice that are deficient in macrophage colony stimulating factor (M-CSF or CSF-1) because of the recessive osteopetrotic (op/op) mutation. Prior work had shown that osteopetrosis is associated with a lack of osteoclasts, phagocytic cells required for remodelling in bone. Additional macrophage populations proved to be very M-CSF dependent. op/op mice had few and sometimes no peritoneal cavity phagocytes, splenic marginal zone metallophils, and lymph node subcapsular sinus macrophages. Other populations, however, reached substantial levels in the absence of M-CSF, including phagocytes in the thymic cortex, splenic red pulp, lymph node medulla, intestinal lamina propria, liver (Kupffer cells), lung (alveolar macrophages) and brain (microglia). Dendritic cells, which are specialized accessory cells for T-dependent immune responses and tolerance, were readily identified in skin and in the T-dependent regions of spleen, lymph node and Peyer's patch. The identification of dendritic cells utilized antibodies to MHC class II products and four different antigens that are primarily expressed by these accessory cells. Our findings indicate that only a few macrophage populations are critically dependent upon M-CSF in vivo. With respect to dendritic cells, the data are consistent with prior in vitro work where it was noted that GM-CSF but not M-CSF supported dendritic cell viability, function and growth.

Up-regulation of alpha 4 integrin on activated Langerhans cells: analysis of adhesion molecules on Langerhans cells relating to their migration from skin to draining lymph nodes

After hapten application, epidermal Langerhans cells migrate into the regional lymph nodes through dermal lymphatics. Recently, we have demonstrated that some of them take the phenotypic and functional characteristics similar to those of in vitro cultured Langerhans cells, before disappearing from the epidermis. To analyze the mechanisms underlying the migration of Langerhans cells, we studied the expression of several adhesion molecules on freshly isolated LC and cultured LC. Pgp-1 (CD44), intercellular adhesion molecule 1, and alpha 4 integrin were strongly expressed on cultured Langerhans cells. Among them, only alpha 4 integrin was strongly up-regulated by cultured Langerhans cells, because its expression by freshly isolated Langerhans cells was very weak. This up-regulation of alpha 4 integrin was also observed on in vivo activated Langerhans cells in the epidermis and draining lymph nodes after hapten application. These data suggest a possible role played by VLA-4 in the migration of Langerhans cells from the epidermis into the regional lymph nodes after hapten application.

Murine Thy-1+ dendritic epidermal T cell lines express granule-associated perforin and a family of granzyme molecules

Two T cell receptor gamma/delta + murine dendritic epidermal T cell (DETC) lines with cytotoxic potential towards various tumor cell lines are shown to express perforin and granzyme A both at the mRNA and protein levels. Furthermore, mRNA transcripts for granzyme B and at least one of the other granzymes D, E, F and G are detected in amounts equivalent to a murine IL-2-dependent alpha/beta + cytotoxic T lymphocyte cell line. Hemolytic granules containing serine-esterase (granzyme A) activity are isolated from a DETC line. Thus, cytolytically-active Thy-1+ DETC lines contain the granule-associated pore-forming protein, perforin, and at least one member of each of the three subgroups of granzyme serine esterases (granzyme A, B and D/E/F/G). These data support the proposed role of gamma/delta + DETC in immune surveillance, possibly exerting cytolytic functions against virus- or parasite-infected, transformed or stressed cells.

Development of gamma delta T-cell subsets from fetal hematopoietic stem cells

Hematopoietic stem cells (HSC) were isolated from mouse fetus, and their developmental potential was compared with adult HSC. Donor-derived V gamma 3+T cells were detected in fetal thymic lobes, repopulated in vitro with fetal liver HSC, but not in those with adult bone marrow HSC. Single clonogenic fetal HSC gave rise to thymic progeny that include V gamma 3+, other gamma delta+, and alpha beta+ T cells. No V gamma 3+ T cells were detected in adult thymus injected intrathymically with either fetal or adult HSC. These results support a hypothesis that only fetal HSC have the capacity to differentiate into V gamma 3+ T cells in the fetal thymic microenvironment, and that the developmental potential of HSC may change during ontogeny.

Lymphocytes with a CD4+ CD8- CD3- phenotype are effectors of experimental cutaneous graft-versus-host disease

Graft-versus-host disease (GVHD) is known to cause profound dysregulation of the immune system, although its effector mechanisms are poorly understood. We now describe an effector lymphocyte of unusual phenotype in the skin of mice with GVHD. This cell is of donor origin and expresses several T-cell surface proteins including Thy-1, CD2, and CD4 but does not express CD8, CD3, NK1.1, or macrophage antigens. Mononuclear cells of this phenotype are the predominant lymphocyte in the epidermis of mice with GVHD 3 weeks after transplant but are not detected in transplanted mice without GVHD. Isolation and transfer of these lymphocytes into secondary recipients causes epidermal damage characteristic of GVHD. These data demonstrate that CD4+ CD8- CD3- lymphocytes are an important effector population that can be amplified outside the thymus and that can mediate target organ damage of GVHD.

Induction, specificity and elimination of asialo-GM1+ graft-versus-host effector cells of donor origin

In previous studies we demonstrated that an induced asialo-GM1 positive (ASGM1+) cell of donor origin that exerts natural killer cell-like activity (NK activity+) plays a crucial role in the development of graft-versus-host (GVH)-associated tissue damage and severe immunosuppression. This study examined whether the ASGM1+ (NK activity+) GVH effector cells were activated by non-specific signals or whether these cells were triggered by specific alloantigens and displayed antigenic specificity. C57B1/6 (B6) donor mice were treated with either B6 x AF1 (B6AF1) lymphoid cells and anti-asialo GM1 antibodies (anti-ASGM1) to induce and eliminate specifically activated B6-anti-B6AF1 ASGM1+ (NK activity+) cells or with polyinosinic: polycytidylic acid (poly I:C), and anti-ASGM1 to eliminate non-specifically activated ASGM1+ (NK activity+) cells. Donor spleen and lymph node cells depleted of the specific allo-induced ASGM1+ NK reactive cells showed near normal numbers of L3T4+ and Lyt-2+ cells and retained T- and B-cell functions as measured by mitogen responses (to PHA, Con A and LPS), mixed lymphocyte responses (MLR) (to B6AF1) and the generation of cytotoxic T cells (CTL) (to B6AF1 blasts). Anti-ASGM1 treatment almost completely abrogated NK activity in all donor inocula. GVH reactions were induced by injecting treated donor cells into B6AF1, B6 x C3HejF1 (B6C3HF1) and B6 x SJLF1 (B6SJLF1) hybrids and monitored by splenomegaly, suppression of T-cell mitogen responses and the development of histopathological lesions in the thymus, liver and pancreas. Cells from donors depleted of non-specifically (poly I:C) induced ASGM1+ cells induced severe histological lesions, marked immunosuppression and splenomegaly in all three F1 hybrid combinations. When the donor cells were depleted of specifically induced (B6-anti-B6AF1) ASGM1+ cells and injected into the three F1 combinations they induced splenomegaly in all three but caused severe tissue injury and intense immunosuppression only in B6C3HF1 and B6SJLF1 mice and not in B6AF1 mice. Genetic analysis suggests that the H-2D (or a closely related) region of the H-2 complex plays an important role in the activation of the specific GVH effector cells. These results suggest that the cell(s) responsible for splenomegaly are different from the ones that cause severe GVH-associated tissue damage and immunosuppression although there may be cells and/or lymphokines common to both processes.(ABSTRACT TRUNCATED AT 400 WORDS)

Murine epidermal gamma/delta T cells express Fc gamma receptor II encoded by the Fc gamma R alpha gene

Short-term bulk cultures and some long-term clones and lines of murine T cell receptor (TcR) gamma/delta-bearing epidermal T cells (dEC) were found to express an Fc gamma receptor II (Fc gamma RII), as revealed by reactivity with the monoclonal antibody 2.4G2. Northern blot analysis showed that the Fc gamma RII expressed on dEC is encoded solely by the Fc gamma R alpha gene. While all the various cultured dEC cell populations analyzed exhibit lectin-dependent cellular cytotoxicity, only those which expressed Fc gamma R alpha were also capable of mediating antibody-dependent cellular cytotoxicity (ADCC). These results in combination with the previous demonstration of Fc gamma R alpha on mouse natural killer cells support an essential role for Fc gamma R alpha in ADCC and extend an analogy with surface CD16 (Fc gamma RIII) expression and ADCC in human natural killer cells and peripheral TcR gamma/delta T cells.

Class II major histocompatibility complex molecules of murine dendritic cells: synthesis, sialylation of invariant chain, and antigen processing capacity are down-regulated upon culture

Dendritic cells (DCs), such as Langerhans cells (LCs) of the epidermis and the DCs of lymphoid organs such as spleen, are potent antigen presenting cells. DCs express high levels of major histocompatibility complex (MHC) class II molecules, but, partly because of the low numbers of primary DCs in any tissue, there has been no detailed study of the biochemistry of their class II molecules. This information may be needed to help explain recent findings that DCs process native protein antigens when freshly isolated from epidermis and spleen. Processing ceases during culture, yet a strong accessory function for activating resting T cells develops. We studied immunoprecipitates of DC class II and invariant chain (Ii) molecules by two-dimensional gel electrophoresis. We found that (i) freshly isolated LCs synthesize large amounts of class II and Ii polypeptides; (ii) Ii molecules that are known to be involved in antigen processing display an unusually large number of sialic acids in fresh LCs; (iii) with culture, class II and Ii synthesis decreases dramatically and has virtually ceased at 3 days; and (iv) the turnover of class II in pulse/chase experiments is slow, being undetectable over a 12- to 32-hr culture period, whereas the turnover of Ii is rapid. We conclude that MHC class II molecules of DCs do not seem to be qualitatively unique. However, the regulation of class II and Ii expression is distinctive in that biosynthesis proceeds vigorously for a short period of time and the newly synthesized class II remains stably on the cell surface, whereas Ii turns over rapidly. This may enable DCs to process and retain antigens in the peripheral tissues such as skin and migrate to the lymphoid organs to activate T cells there.

Characterization of cutaneous infiltrates in MRL/lpr mice monitored from onset to the full development of lupus erythematosus-like skin lesions

The skin is a primary site injured in lupus erythematosus (LE), but it is still controversial whether the injury is due to cells of the mononuclear infiltrate and which immunocompetent cells play the major role in the development of cutaneous LE. To better characterize the role of immunocompetent cells, we performed an immunohistochemical examination of these cells in LE-like skin lesions in MRL/Mp-lpr/lpr (MRL/lpr) mice. Skin lesions in 60 female MRL/lpr mice were monitored from onset to full development. Skin specimens from each stage were stained for epidermal Ia+ Langerhans cells (Ia(+)-LC), for Thy-1+ dendritic epidermal cells (Thy-1+DEC), and for the phenotype of the mononuclear cell infiltrates. The numbers of Ia(+)-LC and Thy-1+DEC were decreased markedly in the skin lesions at the later stage. However, the numbers of Ia(+)-LC were increased significantly in the central portion of lesions at an early stage and in the peripheral portion of lesions later. L3T4+ cells were predominant, and the L3T4/Lyt-2 ratio was high in dermal infiltrates at an early stage. With advancing stage, the L3T4/Lyt-2 ratio gradually decreased in dermal infiltrates, whereas the Thy-1.2/Lyt-2 ratio in lymph nodes was reversed. L3T4+ cells were especially predominant in dermal infiltrates under the epidermis with increased numbers of Ia(+)-LC. This immunohistochemical analysis of a mouse model of cutaneous LE revealed changes in immunocompetent cell populations with the evolution of skin lesions, and we conclude that Ia(+)-LC and Thy-1+DEC, as well as L3T4+ and Lyt-2+ cells, may play pathogenic roles in the development of skin lesions.

The role of fetal epithelial tissues in the maturation/differentiation of bone marrow-derived precursors into dendritic epidermal T cells (DETC) of the mouse

Our attempts to clarify the contribution of the thymic vs. the cutaneous microenvironment in the maturation of dendritic epidermal T cell (DETC) precursors into DETC gave diverse results. In one series of experiments, we found that i.v. injection of fetal thymocytes (containing a TCR V gamma 3-expressing subpopulation), but not of adult thymocytes (containing no TCR V gamma 3+ cells) results in the appearance of CD3/TCR V gamma 3+ dendritic epidermal cells (=DETC). In other experiments, we have obtained evidence that transplantation of day 16 fetal skin onto a Thy-1-disparate recipient results in the appearance of donor-type DETC. Our further observation that the transplanted skin contains CD45+/Thy-1+/CD3- lymphocytes, but no mature T cells, therefore implies that fetal skin can provide stimuli promoting the expression of CD3/TCR genes in immature (CD3-) DETC precursors. It remains to be seen whether both or only one of these maturational pathways are (is) followed under physiological conditions.

Thymus-independent generation of Thy-1+ epidermal cells from a pool of Thy-1- bone marrow precursors

Thy-1+ dendritic epidermal cells (Thy-1+ DEC) and immature thymocytes share several phenotypic features: CD45+, Thy-1+, asialo-GM1+, CD3+, CD4-, and CD8-. In view of this similarity, it has been suggested that the epidermis may be a site of either post-thymic or extra-thymic T-cell development. In order to address this issue, we used C3H/He/Han (Thy-1.2)----AKR/Ola (Thy-1.1) radiation bone marrow chimeras. Animals were first either thymectomized or sham-thymectomized, then lethally irradiated (750R) and, finally, reconstituted with allogeneic bone marrow cells previously depleted of Thy-1-bearing cells. Six weeks after bone marrow transplantation, spleens and lymph nodes of sham-treated animals, but not of thymectomized animals, contained large numbers of CD3+ donor-type Thy-1+ cells. The epidermis of both thymectomized and sham-treated animals contained not only many recipient-type CD3+, Thy-1+ DEC, but also small numbers of CD3-, donor-type Thy-1+ cells. After 4 months, the frequency of donor cells had greatly increased, but they still lacked CD3 antigens. Most of the donor cells had a rounded shape, but some exhibited a dendritic configuration. These results demonstrate that Thy-1- bone marrow-derived precursors of Thy-1+ DEC can migrate to the epidermis without thymic influence and yet acquire Thy-1 antigens during their journey. Although donor-type Thy-1+ epidermal cells failed to mature into CD3+ dendritic epidermal cells, the experimental model used in this study may be a versatile tool for studying the influence of thymic and extrathymic epithelia on T-cell maturation.

Migration and maturation of Langerhans cells in skin transplants and explants

The behavior of Langerhans cells (LC) has been examined after skin transplantation and in an organ culture system. Within 24 h (and even within 4 h of culture), LC in epidermal sheets from allografts, isografts, and explants dramatically increased in size and expression of major histocompatibility complex class II molecules, and their numbers were markedly decreased. Using a new procedure, dermal sheets were then examined. By 24 h, cells resembling LC were found close to the epidermal-dermal junction, and by 3 d, they formed cords in dermal lymphatics before leaving the skin. In organ culture, the cells continued to migrate spontaneously into the medium. These observations establish a direct route for migration of LC from the epidermis into the dermis and then out of the skin. These processes are apparently induced by a local inflammatory response, and are independent of host-derived mediators. The phenotype of migratory cells was then examined by two-color immunocytochemistry and FACS analysis. The majority of migratory leukocytes were Ia+ LC, the remainder comprised Thy-1+, CD3+, CD4-, CD8- presumptive T cell receptor gamma/delta+ dendritic epidermal cells, which clustered with the LC, and a small population of adherent Ia-, FcRII+, CD11a/18+ macrophages. In contrast to the cells remaining within the epidermis of grafted skin at 1 d, the migratory cells were heterogeneous in phenotype, particularly with respect to F4/80, FcRII, and interleukin 2 receptor alpha expression, which are useful markers to follow phenotypic maturation of LC. Moreover, cells isolated from the epidermis of grafts at 1 d were more immunostimulatory in the allogeneic mixed leukocyte reaction and oxidative mitogenesis than LC isolated from normal skin, though less potent than spleen cells. The day 1 migratory cells were considerably more immunostimulatory than spleen cells, and day 3-5 migratory cells even more so, suggesting that functional maturation continues in culture. Thus, maturation of LC commences in the epidermis and continues during migration, but the cells do not need to be fully mature in phenotype or function before they leave the skin. In vivo, the migration of epidermal LC via the dermis into lymphatics and then to the draining nodes, where they have been shown previously to home to T areas, would provide a powerful stimulus for graft rejection.

A developmental switch in thymic lymphocyte maturation potential occurs at the level of hematopoietic stem cells

Hematopoietic stem cells (HSCs) isolated from mouse fetal liver, like adult HSCs, are Thy-1lo Lin- Sca-1+. Donor-derived V gamma 3+ T cells were detected in fetal thymic lobes repopulated in vitro with fetal liver HSCs, but not in those with adult bone marrow HSCs. Single clonogenic fetal HSCs gave rise to thymic progeny that include V gamma 3+, other gamma delta+, and alpha beta+ T cells. No V gamma 3+ T cells were detected in adult thymus injected intrathymically with either fetal or adult HSCs. These results support the hypothesis that only fetal HSCs have the capacity to differentiate into V gamma 3+ T cells in the fetal thymic microenvironment and that the developmental potential of HSCs may change during ontogeny.

TCR gamma/delta+ dendritic epidermal T cells as constituents of skin-associated lymphoid tissue

The epidermis of all strains of normal mice is populated by two distinct dendritic, bone marrow-derived cells: Langerhans cells and CD4-CD8- Thy-1+ dendritic epidermal T cells (DETC). The overwhelming majority of DETC are an unusually homogeneous population of thymic-dependent cells which express CD3-associated T-cell antigen receptors (TCRs) of the gamma/delta type, thereby distinguishing them from conventional CD4+CD8- or CD4-CD8+ T cells expressing CD3-associated alpha/beta TCR. Most DETC are ontogenetically primitive, derived from early fetal thymocytes with a preferential, but poorly understood tropism for the epidermis. Like the TCR on other populations of gamma/delta cells, which preferentially populate other epithelia such as in the gut and lung, the TCR on most DETC selectively utilize particular variable (V) gene segments (i.e., V gamma 3 and V delta 1 for DETC vs V gamma 5 and V delta 4 or V delta 6 for intestinal intraepithelial lymphocytes). However, unlike other gamma/delta populations whose TCR junctional regions exhibit marked heterogeneity, DETC junctional diversity is extremely limited. This lack of TCR heterogeneity among DETC suggests they recognize a narrow range of physiologic ligands (antigens) and that this recognition is restricted not by conventional polymorphic class-I or class-II MHC molecules, but rather by relatively nonpolymorphic self MHC-like molecules of the class Ib MHC type [e.g., Qa, TL, and CD1 (T6)]. Additional studies are required to clarify precisely what DETC recognize, their relevant biological functions, as well as their relationship(s) to the gamma/delta cells recently identified in human skin.

Effect of genetically determined immunodeficiency on epidermal dendritic cell populations in C57BL/6J mice

Mice homozygous for three different recessive mutations known to cause pleiotropic defects in the immune system and in the skin were used to evaluate the relationship between the classical immune system and dendritic epidermal cell populations. Numbers of Langerhans cells (LCs) and Thy-1+ dendritic cells (Thy-1+DEC) were determined using indirect immunofluorescence microscopy of epidermal whole mounts taken from viable motheaten (mev), nude (nu), and rhino (rhhr) mice. All mutants were maintained on the C57BL/6J strain background and were compared with their respective littermate normal controls. Viable motheaten mice had normal numbers of LCs at 1 month of age. However, by 8 weeks of age, LC density had decreased threefold. Nude and rhino mice had normal numbers of LCs at all ages tested. There was no significant effect of the viable motheaten mutation on numbers of Thy-1+DEC. Although nude mice showed normal numbers of Thy-1+ DEC at 1 month of age, these athymic mice had a threefold decrease in numbers of such cells by 6 months. In contrast to the reduced numbers of Thy-1+DEC seen in nude mice, rhino mice showed a four- to fivefold increase in the numbers of these epidermal cells at all ages tested. These findings suggest new mouse models for investigating the development, regulation, and biological properties of epidermal dendritic cell populations.

The surface of dendritic cells in the mouse as studied with monoclonal antibodies

A family of dendritic cells has been identified in situ and in vitro by microscopy and immunolabeling. The members of this family include the dendritic cells isolated from lymphoid organs, Langerhans cells [LC] of the epidermis, veiled cells in afferent lymph, and interdigitating cells [IDC] in the T-cell areas. Some common features to all members of the family are high levels of MHC class II antigens, a lack of most B and T cell markers, and an absence or low levels of macrophage/granulocyte antigens. This review summarizes the markers of mouse dendritic cells as assessed by a panel of monoclonal antibodies, and stresses a few recent findings. 1) In spleen, there are two populations of dendritic cells. More than 75% of isolated cells are 33D1+, NLDC145-, and J11d-, while the remainder have the reciprocal phenotype and thus share the NLDC145 antigen of IDC. Thymic dendritic cells, released by collagenase digestion, and epidermal LC also are 33D1-, NLDC145+, J11d+. 2) When epidermal LC are placed in culture, there are changes in cell function and phenotype. There is a decrease in Fc gamma receptors and the F4/80 macrophage antigen, an increase in class I and II MHC products and p55 IL-2 receptors, and persistence of the NLDC145 IDC antigen. The cultured LC thereby resembles the IDC. 3) A new antibody N418 shows that dendritic cells express the p150/90 member of the leukocyte beta 2 integrin family. Immunolabeling of tissue sections of spleen indicates that N418+ dendritic cells not only are present in the periarterial sheaths, the location of IDC, but also in "nests" at the periphery of the T area where 33D1 has been found. The peripheral collections interrupt the marginal zone of macrophages that separates white and red pulp, and places the dendritic cells in the path of T cells as they move through the white pulp. Therefore the members of the dendritic cell family have important markers in common, as well as differences that are associated with state of immunologic function and location.

In situ infiltration of natural killer-like cells induced by intradermal injection of the nucleic acid fraction from BCG

Intradermal injection of MY-1, a nucleic acid fraction extracted from Mycobacterium bovis strain BCG, induced in situ infiltration of mononuclear cells, most of which were asialo GM1 (GA1)-positive as determined by immunofluorescence microscopy. The infiltration occurred with as little as 1 microgram of MY-1 and lasted for a week. Double immunofluorescence microscopy revealed that the infiltrating GA1-positive cells were all positive for Ly-5, and partially positive for Thy-1.2, but negative for Mac-1, Ia, mu-chain, Lyt-1, Lyt-2, L3T4, and Fc receptor II. They contained neither peroxidase nor nonspecific esterase. The infiltrating cells thus markedly resembled natural killer (NK) cells in their cytochemical characteristics and surface markers. DNase and RNase destroyed the GA1-positive cell-inducing activity of MY-1. These results indicate that the nucleic acid components of MY-1 are responsible for this effect.

Cultured human Langerhans cells resemble lymphoid dendritic cells in phenotype and function

Freshly isolated murine epidermal Langerhans cells (LC) are weak stimulators of resting T cells. Upon culture their phenotype changes, their stimulatory activity increases significantly, and they come to resemble lymphoid dendritic cells. Resident murine LC, therefore, might represent a reservoir of immature dendritic cells. We have now used enzyme cytochemistry, a panel of some 80 monoclonal antibodies, and immunofluorescence microscopy or two-color flow cytometry, as well as transmission electron microscopy, to analyse the phenotype and morphology of human LC before and after 2-4 d of bulk epidermal cell culture. In addition, LC were enriched from bulk epidermal cell cultures, and their stimulatory capacity was tested in the allogeneic mixed leukocyte reaction and the oxidative mitogenesis assay. Cultured human LC resembled human lymphoid dendritic cells in morphology, phenotype, and function. Specifically, LC became non-adherent upon culture and developed sheet-like processes (so-called "veils"), decreased their surface ATP/ADP'ase activity, and lost nonspecific esterase activity. As in the mouse, surface expression of MHC class I and II antigens increased significantly, and FcII receptors were significantly reduced. Markers that are expressed by dendritic cells (like CD40) appeared on LC following culture. Cultured human LC were potent T-cell stimulators. Our findings support the view that resident human LC, like murine LC, represent immature precursors of lymphoid dendritic cells in skin-draining lymph nodes.

Dendritic cells in contact sensitivity

Bone-marrow-derived DC, passing through the skin or residing there as LC, acquire antigen following epicutaneous exposure to contact sensitizer. They move as veiled cells in the afferent lymphatics and migrate to draining lymph nodes, where they become interdigitating cells of the paracortex. Here they initiate T-cell responses; the cytotoxic T cells and antibody formation which develop may be able to target on DC as well as other antigen-bearing cells, so producing feed-back mechanisms to switch off immune responses. Additional features include a systemic effect which leads to movement of DC without antigen into lymph nodes. What are the signals leading to this movement and what is its significance? There is evidence for synergy between directly haptenated DC and DC not directly acquiring antigen. How does this occur and how important is this effect in ensuring the potency of DC in presenting contact sensitizer to T cells? What is the importance of antigen processing by LC? Finally, dendriform cells which may be of T-cell origin are also present in the skin. What is their role in modulating the development of contact sensitivity?

Murine epidermal Langerhans cells express significant amounts of class I major histocompatibility complex antigens

Epidermal Langerhans cells (LC) are leukocytes that express major histocompatibility complex (MHC) class II antigens and function as antigen-presenting and accessory cells. Caughman et al. [Caughman, S. W., Sharrow, S. O., Shimada, S., Stephany, D., Mizuochi, T., Rosenberg, A. S., Katz, S. I. & Singer, A. (1986) Proc. Natl. Acad. Sci. USA 83, 7438-7442] reported that LC are deficient in surface expression of MHC class I antigens, implying a specialization of these cells to class II-restricted antigen presentation. To readdress this obviously important issue, we have studied murine epidermal sheets prepared from B6 X BALB/c----B6 bone marrow chimeras 5 months after irradiation and bone marrow reconstitution. This enabled us to distinguish class I of LC from that of surrounding keratinocytes. When sheets were analyzed by immunofluorescence microscopy with monoclonal antibodies specific for donor class I antigens, donor-derived LC but not LC of recipient origin were stained. Appropriate controls for antibody isotype and MHC haplotype were negative. LC in epidermal cell suspensions, prepared from normal BALB/c and BALB/cBy mice (MHC haplotype d), were analyzed by flow cytometry as well as immunofluorescence microscopy. LC were stained by monoclonal antibodies to class I antigens of haplotype d, but not by isotype-matched control antibodies to class I antigens of haplotype k. We also found that LC were virtually depleted from epidermal cell suspensions by treatment with monoclonal antibodies to class I antigens of haplotype d and complement but not by treatment with control monoclonal antibodies and complement. Our data, therefore, show that LC express MHC class I molecules on their surface.