Blood-derived dermal langerin+ dendritic cells survey the skin in the steady state.

Langerin is a C-type lectin receptor that recognizes glycosylated patterns on pathogens. Langerin is used to identify human and mouse epidermal Langerhans cells (LCs), as well as migratory LCs in the dermis and the skin draining lymph nodes (DLNs). Using a mouse model that allows conditional ablation of langerin(+) cells in vivo, together with congenic bone marrow chimeras and parabiotic mice as tools to differentiate LC- and blood-derived dendritic cells (DCs), we have revisited the origin of langerin(+) DCs in the skin DLNs. Our results show that in contrast to the current view, langerin(+)CD8(-) DCs in the skin DLNs do not derive exclusively from migratory LCs, but also include blood-borne langerin(+) DCs that transit through the dermis before reaching the DLN. The recruitment of circulating langerin(+) DCs to the skin is dependent on endothelial selectins and CCR2, whereas their recruitment to the skin DLNs requires CCR7 and is independent of CD62L. We also show that circulating langerin(+) DCs patrol the dermis in the steady state and migrate to the skin DLNs charged with skin antigens. We propose that this is an important and previously unappreciated element of immunosurveillance that needs to be taken into account in the design of novel vaccine strategies.

Langerin expressing cells promote skin immune responses under defined conditions.

There are conflicting data in the literature regarding the role of epidermal Langerhans cells (LC) in promoting skin immune responses. On one hand, LC can be extremely potent APCs in vitro, and are thought to be involved in contact hypersensitivity (CHS). On the other hand, it seems counterintuitive that a cell type continually exposed to pathogens at the organism\'s barrier surfaces should readily trigger potent T cell responses. Indeed, LC depletion in one model led to enhanced contact hypersensitivity, suggesting they play a negative regulatory role. However, apparently similar LC depletion models did not show enhanced CHS, and in one case showed reduced CHS. In this study we found that acute depletion of mouse LC reduced CHS, but the timing of toxin administration was critical: toxin administration 3 days before priming did not impair CHS, whereas toxin administration 1 day before priming did. We also show that LC elimination reduced the T cell response to epicutaneous immunization with OVA protein Ag. However, this reduction was only observed when OVA was applied on the flank skin, and not on the ear. Additionally, peptide immunization was not blocked by depletion, regardless of the site. Finally we show that conditions which eliminate epidermal LC but spare other Langerin(+) DC do not impair the epicutaneous immunization response to OVA. Overall, our results reconcile previous conflicting data in the literature, and suggest that Langerin(+) cells do promote T cell responses to skin Ags, but only under defined conditions.

Priming of CD8+ and CD4+ T Cells in Experimental Leishmaniasis Is Initiated by Different Dendritic Cell Subtypes

The biological role of Langerin(+) dendritic cells (DCs) such as Langerhans cells and a subset of dermal DCs (dDCs) in adaptive immunity against cutaneous pathogens remains enigmatic. Thus, we analyzed the impact of Langerin(+) DCs in adaptive T cell-mediated immunity toward Leishmania major parasites in a Lang-DTR mouse model that allows conditional diphtheria toxin (DT)-induced ablation of The biological role of Langerin+ dendritic cells (DCs) such as Langerhans cells and a subset of dermal DCs (dDCs) in adaptive immunity against cutaneous pathogens remains enigmatic. Thus, we analyzed the impact of Langerin+ DCs in adaptive T cell-mediated immunity toward Leishmania major parasites in a Lang-DTR mouse model that allows conditional diphtheria toxin (DT)-induced ablation of Langerin+ DCs in vivo. For the first time, infection experiments with DT-treated Lang-DTR mice revealed that proliferation of L. major-specific CD8+ T cells is significantly reduced during the early phase of the immune response following depletion of Langerin+ DCs. Consequently, the total number of activated CD8+ T cells within the draining lymph node and at the site of infection is diminished. Furthermore, we show that the impaired CD8+ T cell response is due to the absence of Langerin+ dDCs and not Langerhans cells. Nevertheless, the CD4+ T cell response is not altered and the infection is cleared as effectively in DT-treated Lang-DTR mice as in control mice. This clearly demonstrates that Langerin+ DCs are, in general, dispensable for an efficient adaptive immune response against L. major parasites. Thus, we propose a novel concept that, in the experimental model of leishmaniasis, priming of CD4+ T cells is mediated by Langerin− dDCs, whereas Langerin+ dDCs are involved in early priming of CD8+ T cells.

Langerhans cell (LC) proliferation mediates neonatal development, homeostasis, and inflammation-associated expansion of the epidermal LC network.

Most tissues develop from stem cells and precursors that undergo differentiation as their proliferative potential decreases. Mature differentiated cells rarely proliferate and are replaced at the end of their life by new cells derived from precursors. Langerhans cells (LCs) of the epidermis, although of myeloid origin, were shown to renew in tissues independently from the bone marrow, suggesting the existence of a dermal or epidermal progenitor. We investigated the mechanisms involved in LC development and homeostasis. We observed that a single wave of LC precursors was recruited in the epidermis of mice around embryonic day 18 and acquired a dendritic morphology, major histocompatibility complex II, CD11c, and langerin expression immediately after birth. Langerin+ cells then undergo a massive burst of proliferation between postnatal day 2 (P2) and P7, expanding their numbers by 10–20-fold. After the first week of life, we observed low-level proliferation of langerin+ cells within the epidermis. However, in a mouse model of atopic dermatitis (AD), a keratinocyte signal triggered increased epidermal LC proliferation. Similar findings were observed in epidermis from human patients with AD. Therefore, proliferation of differentiated resident cells represents an alternative pathway for development in the newborn, homeostasis, and expansion in adults of selected myeloid cell populations such as LCs. This mechanism may be relevant in locations where leukocyte trafficking is limited.

Langerin(+) Dermal Dendritic Cells Are Critical for CD8(+) T Cell Activation and IgH gamma-1 Class Switching in Response to Gene Gun Vaccines

The C-type lectin langerin/CD207 was originally discovered as a specific marker for epidermal Langerhans cells (LC). Recently, additional and distinct subsets of langerin(+) dendritic cells (DC) have been identified in lymph nodes and peripheral tissues of mice. Although the role of LC for immune activation or modulation is now being discussed controversially, other langerin(+) DC appear crucial for protective immunity in a growing set of infection and vaccination models. In knock-in mice that express the human diphtheria toxin receptor under control of the langerin promoter, injection of diphtheria toxin ablates LC for several weeks whereas other langerin(+) DC subsets are replenished within just a few days. Thus, by careful timing of diphtheria toxin injections selective states of deficiency in either LC only or all langerin(+) cells can be established. Taking advantage of this system, we found that, unlike selective LC deficiency, ablation of all langerin(+) DC abrogated the activation of IFN-gamma producing and cytolytic CD8(+) T cells after gene gun vaccination. Moreover, we identified migratory langerin(+) dermal DC as the subset that directly activated CD8(+) T cells in lymph nodes. Langerin(+) DC were also critical for IgG1 but not IgG2a Ab induction, suggesting differential polarization of CD4(+) T helper cells by langerin(+) or langerin-negative DC, respectively. In contrast, protein vaccines administered with various adjuvants induced IgG1 independently of langerin(+) DC. Taken together, these findings reflect a highly specialized division of labor between different DC subsets both with respect to Ag encounter as well as downstream processes of immune activation. The Journal of Immunology, 2011, 186: 1377-1383.

Skin langerin+ dendritic cells transport intradermally injected anti-DEC-205 antibodies but are not essential for subsequent cytotoxic CD8+ T cell responses

Incorporation of Ags by dendritic cells (DCs) increases when Ags are targeted to endocytic receptors by mAbs. We have previously demonstrated in the mouse that mAbs against C-type lectins administered intradermally are taken up by epidermal Langerhans cells (LCs), dermal Langerin(neg) DCs, and dermal Langerin(+) DCs in situ. However, the relative contribution of these skin DC subsets to the induction of immune responses after Ag targeting has not been addressed in vivo. We show in this study that murine epidermal LCs and dermal DCs transport intradermally injected mAbs against the lectin receptor DEC-205/CD205 in vivo. Skin DCs targeted in situ with mAbs migrated through lymphatic vessels in steady state and inflammation. In the skin-draining lymph nodes, targeting mAbs were found in resident CD8a(+) DCs and in migrating skin DCs. More than 70% of targeted DCs expressed Langerin, including dermal Langerin(+) DCs and LCs. Numbers of targeted skin DCs in the nodes increased 2-3-fold when skin was topically inflamed by the TLR7 agonist imiquimod. Complete removal of the site where OVA-coupled anti-DEC-205 had been injected decreased endogenous cytotoxic responses against OVA peptide-loaded target cells by 40-50%. Surprisingly, selective ablation of all Langerin(+) skin DCs in Langerin-DTR knock-in mice did not affect such responses independently of the adjuvant chosen. Thus, in cutaneous immunization strategies where Ag is targeted to DCs, Langerin(+) skin DCs play a major role in transport of anti-DEC-205 mAb, although Langerin(neg) dermal DCs and CD8a(+) DCs are sufficient to subsequent CD8(+) T cell responses.

Insights into Langerhans cell function from Langerhans cell ablation models

Langerhans cells (LC) are the principal dendritic cell (DC) population in the epidermis of the skin. Owing to their prominent position at the environmental barrier, LC have long been considered to be prototypic sentinel DC. More recently, the precise role of LC in the initiation and control of cutaneous immune responses has become debatable. To elucidate their contribution to immune regulation in the skin, our laboratories have generated genetically modified mice in which LC can be followed in situ by expression of enhanced green fluorescent protein and can be either inducibly or constitutively depleted in vivo. This review highlights the similarities and differences between these mouse models, discusses the discovery and functional significance of Langerin(+) dermal DC, and examines some recent data that help to shed light on LC function.

Development of an ex vivo human skin model for intradermal vaccination : tissue viability and Langerhans cell behaviour

The presence of resident Langerhans cells (LCs) in the epidermis makes the skin an attractive target for DNA vaccination. However, reliable animal models for cutaneous vaccination studies are limited. We demonstrate an ex vivo human skin model for cutaneous DNA vaccination which can potentially bridge the gap between pre-clinical in vivo animal models and clinical studies. Cutaneous transgene expression was utilised to demonstrate epidermal tissue viability in culture. LC response to the culture environment was monitored by immunohistochemistry. Full-thickness and split-thickness skin remained genetically viable in culture for at least 72 h in both phosphate-buffered saline (PBS) and full organ culture medium (OCM). The epidermis of explants cultured in OCM remained morphologically intact throughout the culture duration. LCs in full-thickness skin exhibited a delayed response (reduction in cell number and increase in cell size) to the culture conditions compared with split-thickness skin, whose response was immediate. In conclusion, excised human skin can be cultured for a minimum of 72 h for analysis of gene expression and immune cell activation. However, the use of split-thickness skin for vaccine formulation studies may not be appropriate because of the nature of the activation. Full-thickness skin explants are a more suitable model to assess cutaneous vaccination ex vivo.

High frequency of immature dendritic cells and altered in situ production of interleukin-4 and tumor necrosis factor-alpha in lung cancer

Introduction Antigen-presenting cells, like dendritic cells (DCs) and macrophages, play a significant role in the induction of an immune response and an imbalance in the proportion of macrophages, immature and mature DCs within the tumor could affect significantly the immune response to cancer. DCs and macrophages can differentiate from monocytes, depending on the milieu, where cytokines, like interleukin (IL)-4 and granulocyte-macrophage colony-stimulating factor (GM-CSF) induce DC differentiation and tumor necrosis factor (TNF)-alpha induce DC maturation. Thus, the aim of this work was to analyze by immunohistochemistry the presence of DCs (S100+ or CD1a+), macrophages (CD68+), IL-4 and TNF-alpha within the microenvironment of primary lung carcinomas. Results Higher frequencies of both immature DCs and macrophages were detected in the tumor-affected lung, when compared to the non-affected lung. Also, TNF-alpha-positive cells were more frequent, while IL-4-positive cells were less frequent in neoplastic tissues. This decreased frequency of mature DCs within the tumor was further confirmed by the lower frequency of CD14-CD80+ cells in cell suspensions obtained from the same lung tissues analyzed by flow cytometry. Conclusion These data are discussed and interpreted as the result of an environment that does not oppose monocyte differentiation into DCs, but that could impair DC maturation, thus affecting the induction of effective immune responses against the tumor.

Papilomavírus humano (HPV) e células de Langerhans em carcinoma epidermóide oral

The Human Papillomavirus (HPV) has been strongly implicated on development of some cases of oral squamous cell carcinoma (OSCC). However, the immunological system somehow reacts against the presence of this virus. Among the cells involved on such mechanism of defense detaches the Langerhans cells (LC), which are responsible for processing and presenting antigens. The purpose of this study was to evaluate the immunohistochemical reactivity for Langerhans cells between HPV positive and HPV negative OSCC, as well as, the relation of the immunoreactivity for this cells and the histological grading of malignancy proposed by Bryne (1998) and modified by Miranda (2002). Additionally, HPV infection was evaluated in relation to sex, age, lesion localization and histological grading of malignancy. In the total, 27 cases of OSSC were evaluated, 09 of them HPV positive and 18 HPV negative. Anti S-100 antibody was utilized for the immunohistochemical labelling, followed by the counting of LCs in 5 highpower fields (400x). No statistically significant difference was verified between the variables sex, age, lesion localization, histological grading of malignancy and HPV presence in OSSC. There was neither association between the immunohistochemical labeling for LCs (S-100+) and HPV infection nor correlation between the quantity of LCs labeled and the histological grading of malignancy of OSSC. The results suggest that despite the absence of statistically significant difference, the presence of HPV in such cases of OSCC can alter the immunological system, particularly the Langerhans cells

Modulação imunológica in vitro de células de Langerhans e macrófagos por drogas utilizadas no manejo de reações hansênicas

As células de Langerhans (CLs) estão localizadas na epiderme e desempenham um papel chave na indução da resposta imune e da tolerância imunológica. Os macrófagos são células fagocíticas que atuam como primeira linha de defesa do organismo, e que estão envolvidos na formação de granulomas em pacientes com hanseníase. A imunopatogenia da resposta celular nos estados reacionais ainda é pouco estudada, porém, diversas evidências sugerem que as drogas prednisona, talidomida, ciclosporina e amitriptilina, utilizadas no controle das reações hansênicas, exercem seus efeitos pela modulação das funções de diferentes células imunocompetentes. O objetivo do presente estudo foi analisar a ação in vitro das drogas prednisona, talidomida, ciclosporina e amitriptilina sobre a produção de citocinas por CLs e macrófagos de camundongos BALB/c. As CLs foram isoladas, purificadas e cultivadas a partir da epiderme pela técnica de “panning” e os macrófagos foram isolados da cavidade peritoneal de camundongos BALB/c. Após 36 h de tratamento com as drogas, os níveis de TNF-, IL-12 e IL-10 foram medidos por ELISA. Prednisona, talidomida, ciclosporina e amitriptilina inibiram os níveis de TNF- produzidos pelas CLs, em ambas as concentrações, no entanto, não foi detectada alteração significativa na produção de IL-12. A produção de TNF- e de IL-12 por macrófagos peritoneais também foi diminuída após o tratamento, porém os níveis de IL-10 não foram modificados por nenhuma das drogas testadas. Nossos resultados mostram que estas drogas podem modular a resposta imune através da regulação das citocinas pró-inflamatórias TNF- e IL-12 por CLs purificadas da epiderme e por macrófagos peritoneais, indicando que as citocinas constituem importante alvo de drogas usadas no tratamento dos estados reacionais.

Análise morfológica das células de Langerhans purificadas da epiderme de camundongo Balb/c, após interação in vitro com Leishania (Viannia) brasiliensis e Leishamania (Leishmania) amazonensis

Células de Langerhans (CL) são células apresentadoras de antígenos, MHC classe II positivas, que constituem 2 a 3% de todas as células da epiderme, e que têm demonstrado serem estimuladoras de uma resposta vigorosa de linfócitos T contra Leishmania major. A leishmanionse cutânea do Novo Mundo é causada por diferentes espécies, apresentando formas clínicas diversas variando de leishmaniose cutânea difusa anérgica. Utilizando a técnica de "panning", CL da epiderme de comundongos BALB/c foram purificadas para em torno de 95% de pureza (pCL) em relação à outras células da epiderme. As CL recentemente isoladas apresentaram dentritos pequenos e delicados e os clássicos grânulos de Birbeck. Tem sido sugerido que os parasitos do subgênero Viannia e Leishmania, que são geneticamente bastante distintos, podem ter respostas espécie-específicas na resposta imune celular. Neste estudo, pCL e L. (V.) brasilienses ou L. (L.) amazonensis foram cultivadas e a morfologia das CL foi analizada após 12 ou 36 h de cultura. Utilizando a coloração de Giemsa e a microscopia eletrônica de varredura, alterações morfológicas diferentes foram detectadas nas CL após 12 h de cultivo nas duas culturas, CL e L. (V.) brasiliensis ou CL e L. (L.) amazonensis. Depois da interação com L. (V.) brasiliensis as CL tornaram-se mais dentríticas, que eram mais curtos quando comparados às CL cultivadas isoladamente. Em contraste, após a interação com L. (L.) amazonensis, as CL tornaram-se arredondadas com algumas células mostrando alguns dendritos. Além disto, verificou-se um contato íntimo entre o flagelo das prostigota com as CL, mas sem observar a fagocitose das leishmanias após 12 ou 36 h de cultivo, o que é diferente dos relatos da literatura com CL e L. major. Estes resultados sugerem que a resposta imune primária das CL contra as diferentes espécies de leishamania podem ser distintas de acordo com a espécie envolvida no processo de interação.

Leishmania (L.) amazonensis inibe a maturação e a função ativadora das células de Langerhans da pele tratadas com TNF-α e anti-CD40 in vitro

Leishmania amazonensis é um dos principais agentes etiológicos em um amplo espectro de formas clínicas da Leishmaniose Tegumentar Americana. De modo geral, a resistência frente às leishmanioses decorre do desenvolvimento de uma resposta imune celular eficiente, porém muitos estudos têm demonstrado que citocinas específicas ou combinações de citocinas podem ser fatores de resistência ou suscetibilidade à infecção por L. amazonensis. Estudos recentes sugerem a participação das células de Langerhans (LCs) nas resposta anti-Leishmania, porém os mecanismos envolvidos durante esta interação são ainda pouco estudados. Objetivos: Estudar o papel do TNF-α e anti-CD40 nas interações in vitro entre as LCs e L. amazonensis, observando o perfil de citocinas produzidas e a expressão de moléculas de superfície, bem como verificar a capacidade destas células em ativar a produção de IFN-γ e IL-4 por células do linfonodo. Metodologia: As LCs foram isoladas da epiderme de camundongos BALB/c e incubadas com promastigotas de L. amazonensis, TNF-α e/ou anti- CD40. Após 24h, as LCs foram co-cultivadas com células obtidas de linfonodos por 72h. As citocinas IL-6, IL-12, IFN-γ e IL-4 foram dosadas por ensaio imunoenzimático (ELISA) e as moléculas de superfície foram analisadas por citometria de fluxo. Resultados: Os níveis de IL- 6 e IL-12p70 produzidos pela LCs foram significativamente reduzidos após interação com L. amazonensis, mesmo após o tratamento das LCs com TNF-α ou anti-CD40. Em relação às moléculas de superfície, não houve diferença na expressão de CD207 em nenhum dos grupos, porém a presença de L. amazonensis promoveu uma redução significativa na expressão de CD40 nas LCs tratadas com TNF-α ou anti-CD40, e aumentou a expressão de CD86 em todos os grupos. Na presença de L. amazonensis, as células do linfonodo apresentaram uma produção diminuída de IFN-γ e não houve alteração na produção de IL-4. Quando cocultivadas com LCs estimuladas previamente com L. amazonensis, a produção de IFN-γ também foi reduzida, mesmo na presença dos estímulos TNF-α e/ou anti-CD40. Não foram observadas alterações significativas na produção de IL-4 pelas células do linfonodo cocultivadas nas mesmas condições experimentais. Conclusão: L. (L.) amazonensis exerce um efeito imunomodulador sobre a resposta imune mediada por LCs, inibindo a produção de IL-6 e IL-12p70 e expressão de CD40, além de impedir a ativação da produção de IFN-γ por células do linfonodo co-cultivadas com LCs, mesmo após tratamento com TNF-α e anticorpo anti-CD40.

Imunopatogenia da interação entre acrófagos e/ou células de Langerhans e Lacazia loboi

A lobomicose é uma infecção subcutânea crônica, granulomatosa, causada pela implantação traumática do fungo Lacazia loboi nos tecidos cutâneo e subcutâneo. Ocorre predominantemente na região Amazônica e atinge qualquer grupo populacional. Histologicamente, observa-se reação inflamatória crônica caracterizada por intensa histiocitose e fibroplasia, abundante número de macrófagos, células gigantes multinucleadas do tipo corpo estranho e presença de considerável número de células leveduriformes. Os macrófagos são células fagocíticas que participam do reconhecimento e da resposta a patógenos através da fagocitose, da apresentação de antígenos aos linfócitos T e da produção de citocinas. As células de Langerhans (LC) são um grupo de Células dendríticas (CD) derivadas da medula óssea situadas principalmente em uma camada suprabasal da epiderme. Estudos envolvendo a interação fungo-hospedeiro na doença de Jorge Lobo são escassos. Assim, Este estudo é um passo importante para o melhor entendimento da biologia e patogenia do L. loboi, e para o estudo da imunopatologia da interação patógeno versus hospedeiro desta doença emergente e pouco conhecida. O objetivo do presente trabalho foi analisar a interação in vitro entre macrófagos peritoneais não ativados e/ou LC, isolados de camundongos BALB/c, com L. loboi recém-isolado de pacientes com doença de Jorge Lobo, bem como determinar os índices de infecção, fagocitose e fusão, e medir a produção das citocinas TNF-α, IL-4, IL-6, IL-10 e IL-12. Os resultados demonstraram que L. loboi é fagocitado por macrófagos, mas não por LC. O índice de infecção na interação entre macrófagos e L. loboi foi semelhante à interação entre macrófagos, LC e L. loboi em todos os tempos analisados. A média do número de fungos por macrófago também foi praticamente igual entre as interações e ao longo do tempo, variando de 1,2 a 1,6 fungos/macrófagos. Não houve a formação de células gigantes em macrófagos cultivados ou LC cultivadas isoladamente e em nenhum dos co-cultivos. Não houve diferença significante na produção de IL-4, IL-2 e IL-10 nas interações estudadas. Os níveis de TNF-α diminuem ao longo do tempo na interação entre macrófagos e L. loboi, enquanto a adição de LC induz aumento da produção de TNF-α, principalmente após 48 horas. LC modulam negativamente a produção de IL-6 por macrófagos e L. loboi também inibem essa produção por macrófagos isoladamente ou em co-cultivo com LC. L. loboi estimulam significativamente a produção de IL-12 por macrófagos co-cultivados com LC, mas não em LC ou macrófagos isoladamente.

Leishmania (V.) braziliensis and L. (L.) amazonensis promote differential expression of dendritic cells and cellular immune response in murine model

The expression of Langerhans cell (LC) and dermal dendritic cell (dDC) as well as T CD4+ and CD8+ immune responses was evaluated in the skin of BALB/c mice experimentally infected by L. (L.) amazonensis (La) and L. (V.) braziliensis (Lb). At 4th and 8th weeks post infection (PI), skin biopsies were collected to determine the parasite load and CD207+, CD11c+, CD4+, CD8+, iNOS+ cellular densities. Cytokine (IFN-?, IL-4 and IL-10) profiles were also analysed in draining lymph node. At 4th week, the densities of CD207+ and CD11c+ were higher in the La infection, while in the Lb infection, these markers revealed a significant increase at 8th week. At 4th week, CD4+ and CD8+ were higher in the La infection, but at 8th week, there was a substantial increase in both markers in the Lb infection. iNOS+ was higher in the Lb infection at 4th and 8th weeks. In contrast, the parasite load was higher in the La infection at 4th and 8th weeks. The concentration of IFN-? was higher in the Lb infection, but IL-4 and IL-10 were higher in the La infection at 4th and 8th weeks. These results confirm the role of the Leishmania species in the BALB/c mice disease characterized by differences in the expression of dendritic cells and cellular immune response.