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2015
Mairhofer David G, Ortner Daniela, Tripp Christoph H, Schaffenrath Sandra, Fleming Viktor, Heger Lukas, Komenda Kerstin, Reider Daniela, Dudziak Diana, Chen Suzie, Becker Jürgen C, Flacher Vincent, Stoitzner Patrizia
Impaired gp100-Specific CD8(+) Ŧ-Cell Responses in the Presence of Myeloid-Derived Suppressor Cells in a Spontaneous Mouse Melanoma Model Article de journal
Dans: The Journal of Investigative Dermatology, vol. 135, no. 11, p. 2785–2793, 2015, ISSN: 1523-1747.
Résumé | Liens | BibTeX | Étiquettes: Analysis of Variance, Animal, Animals, Antigen, cancer, CARCINOGENESIS, CD8-Positive T-Lymphocytes, Cell Proliferation, Cultured, DERMATOLOGY, development, disease, Disease Models, Experimental, GLYCOPROTEIN, gp100 Melanoma Antigen, Growth, Human, Humans, Immunity, Immunologic, IN VITRO, Inbred C57BL, iNOS, Leukocytes, LYMPH, LYMPH NODE, Lymph Nodes, Lymphocyte Activation, MELANOCYTES, Melanoma, Mice, mouse, murine, NITRIC OXIDE, nitric oxide synthase, Phenotype, Proliferation, Random Allocation, Receptor, Regulatory, RESPONSES, Skin, SUBSETS, Suppressor Factors, T CELLS, T-CELLS, T-Lymphocytes, Team-Mueller, Transforming Growth Factor beta, transgenic, tumor, Tumor Cells, tumor immunity
@article{mairhofer_impaired_2015,
title = {Impaired gp100-Specific CD8(+) Ŧ-Cell Responses in the Presence of Myeloid-Derived Suppressor Cells in a Spontaneous Mouse Melanoma Model},
author = {David G Mairhofer and Daniela Ortner and Christoph H Tripp and Sandra Schaffenrath and Viktor Fleming and Lukas Heger and Kerstin Komenda and Daniela Reider and Diana Dudziak and Suzie Chen and Jürgen C Becker and Vincent Flacher and Patrizia Stoitzner},
doi = {10.1038/jid.2015.241},
issn = {1523-1747},
year = {2015},
date = {2015-11-01},
journal = {The Journal of Investigative Dermatology},
volume = {135},
number = {11},
pages = {2785--2793},
abstract = {Murine tumor models that closely reflect human diseases are important tools to investigate carcinogenesis and tumor immunity. The transgenic (tg) mouse strain tg(Grm1)EPv develops spontaneous melanoma due to ectopic overexpression of the metabotropic glutamate receptor 1 (Grm1) in melanocytes. In the present study, we characterized the immune status and functional properties of immune cells in tumor-bearing mice. Melanoma development was accompanied by a reduction in the percentages of CD4(+) T cells including regulatory T cells (Tregs) in CD45(+) leukocytes present in tumor tissue and draining lymph nodes (LNs). In contrast, the percentages of CD8(+) T cells were unchanged, and these cells showed an activated phenotype in tumor mice. Endogenous melanoma-associated antigen glycoprotein 100 (gp100)-specific CD8(+) T cells were not deleted during tumor development, as revealed by pentamer staining in the skin and draining LNs. They, however, were unresponsive to ex vivo gp100-peptide stimulation in late-stage tumor mice. Interestingly, immunosuppressive myeloid-derived suppressor cells (MDSCs) were recruited to tumor tissue with a preferential accumulation of granulocytic MDSC (grMDSCs) over monocytic MDSC (moMDSCs). Both subsets produced Arginase-1, inducible nitric oxide synthase (iNOS), and transforming growth factor-β and suppressed T-cell proliferation in vitro. In this work, we describe the immune status of a spontaneous melanoma mouse model that provides an interesting tool to develop future immunotherapeutical strategies.},
keywords = {Analysis of Variance, Animal, Animals, Antigen, cancer, CARCINOGENESIS, CD8-Positive T-Lymphocytes, Cell Proliferation, Cultured, DERMATOLOGY, development, disease, Disease Models, Experimental, GLYCOPROTEIN, gp100 Melanoma Antigen, Growth, Human, Humans, Immunity, Immunologic, IN VITRO, Inbred C57BL, iNOS, Leukocytes, LYMPH, LYMPH NODE, Lymph Nodes, Lymphocyte Activation, MELANOCYTES, Melanoma, Mice, mouse, murine, NITRIC OXIDE, nitric oxide synthase, Phenotype, Proliferation, Random Allocation, Receptor, Regulatory, RESPONSES, Skin, SUBSETS, Suppressor Factors, T CELLS, T-CELLS, T-Lymphocytes, Team-Mueller, Transforming Growth Factor beta, transgenic, tumor, Tumor Cells, tumor immunity},
pubstate = {published},
tppubtype = {article}
}
Murine tumor models that closely reflect human diseases are important tools to investigate carcinogenesis and tumor immunity. The transgenic (tg) mouse strain tg(Grm1)EPv develops spontaneous melanoma due to ectopic overexpression of the metabotropic glutamate receptor 1 (Grm1) in melanocytes. In the present study, we characterized the immune status and functional properties of immune cells in tumor-bearing mice. Melanoma development was accompanied by a reduction in the percentages of CD4(+) T cells including regulatory T cells (Tregs) in CD45(+) leukocytes present in tumor tissue and draining lymph nodes (LNs). In contrast, the percentages of CD8(+) T cells were unchanged, and these cells showed an activated phenotype in tumor mice. Endogenous melanoma-associated antigen glycoprotein 100 (gp100)-specific CD8(+) T cells were not deleted during tumor development, as revealed by pentamer staining in the skin and draining LNs. They, however, were unresponsive to ex vivo gp100-peptide stimulation in late-stage tumor mice. Interestingly, immunosuppressive myeloid-derived suppressor cells (MDSCs) were recruited to tumor tissue with a preferential accumulation of granulocytic MDSC (grMDSCs) over monocytic MDSC (moMDSCs). Both subsets produced Arginase-1, inducible nitric oxide synthase (iNOS), and transforming growth factor-β and suppressed T-cell proliferation in vitro. In this work, we describe the immune status of a spontaneous melanoma mouse model that provides an interesting tool to develop future immunotherapeutical strategies.
2014
Flacher Vincent, Tripp Christoph H, Mairhofer David G, Steinman Ralph M, Stoitzner Patrizia, Idoyaga Juliana, Romani Nikolaus
Murine Langerin+ dermal dendritic cells prime CD8+ Ŧ cells while Langerhans cells induce cross-tolerance Article de journal
Dans: EMBO molecular medicine, vol. 6, no. 9, p. 1191–1204, 2014, ISSN: 1757-4684.
Résumé | Liens | BibTeX | Étiquettes: agonists, Animals, Antibodies, antibody, Antigen, Antigen Presentation, Antigens, C-Type, C-type lectin, cancer, CD70, CD8-Positive T-Lymphocytes, CD8+ T cells, CD8+ T‐cell responses, Cellular, CROSS-PRESENTATION, Cross-Priming, Cytotoxicity, Dendritic Cells, DERMAL DENDRITIC CELLS, DERMATOLOGY, disease, imiquimod, Immunization, IMMUNOGENICITY, Immunologic Memory, Immunological, Immunology, In vivo, Inbred C57BL, INDUCTION, Intradermal, Langerhans Cells, LECTIN, Lectins, Mannose-Binding Lectins, Maturation, Mice, Models, murine, OVALBUMIN, physiology, priming, RESPONSES, Skin, Surface, T CELLS, T-CELLS, Team-Mueller, tolerance, Vaccination, vaccine, Vaccines
@article{flacher_murine_2014,
title = {Murine Langerin+ dermal dendritic cells prime CD8+ Ŧ cells while Langerhans cells induce cross-tolerance},
author = {Vincent Flacher and Christoph H Tripp and David G Mairhofer and Ralph M Steinman and Patrizia Stoitzner and Juliana Idoyaga and Nikolaus Romani},
doi = {10.15252/emmm.201303283},
issn = {1757-4684},
year = {2014},
date = {2014-09-01},
journal = {EMBO molecular medicine},
volume = {6},
number = {9},
pages = {1191--1204},
abstract = {Skin dendritic cells (DCs) control the immunogenicity of cutaneously administered vaccines. Antigens targeted to DCs via the C-type lectin Langerin/CD207 are cross-presented to CD8(+) T cells in vivo. We investigated the relative roles of Langerhans cells (LCs) and Langerin(+) dermal DCs (dDCs) in different vaccination settings. Poly(I:C) and anti-CD40 agonist antibody promoted cytotoxic responses upon intradermal immunization with ovalbumin (OVA)-coupled anti-Langerin antibodies (Langerin/OVA). This correlated with CD70 upregulation in Langerin(+) dDCs, but not LCs. In chimeric mice where Langerin targeting was restricted to dDCs, CD8(+) T-cell memory was enhanced. Conversely, providing Langerin/OVA exclusively to LCs failed to prime cytotoxicity, despite initial antigen cross-presentation to CD8(+) T cells. Langerin/OVA combined with imiquimod could not prime CD8(+) T cells and resulted in poor cytotoxicity in subsequent responses. This tolerance induction required targeting and maturation of LCs. Altogether, Langerin(+) dDCs prime long-lasting cytotoxic responses, while cross-presentation by LCs negatively influences CD8(+) T-cell priming. Moreover, this highlights that DCs exposed to TLR agonists can still induce tolerance and supports the existence of qualitatively different DC maturation programs.},
keywords = {agonists, Animals, Antibodies, antibody, Antigen, Antigen Presentation, Antigens, C-Type, C-type lectin, cancer, CD70, CD8-Positive T-Lymphocytes, CD8+ T cells, CD8+ T‐cell responses, Cellular, CROSS-PRESENTATION, Cross-Priming, Cytotoxicity, Dendritic Cells, DERMAL DENDRITIC CELLS, DERMATOLOGY, disease, imiquimod, Immunization, IMMUNOGENICITY, Immunologic Memory, Immunological, Immunology, In vivo, Inbred C57BL, INDUCTION, Intradermal, Langerhans Cells, LECTIN, Lectins, Mannose-Binding Lectins, Maturation, Mice, Models, murine, OVALBUMIN, physiology, priming, RESPONSES, Skin, Surface, T CELLS, T-CELLS, Team-Mueller, tolerance, Vaccination, vaccine, Vaccines},
pubstate = {published},
tppubtype = {article}
}
Skin dendritic cells (DCs) control the immunogenicity of cutaneously administered vaccines. Antigens targeted to DCs via the C-type lectin Langerin/CD207 are cross-presented to CD8(+) T cells in vivo. We investigated the relative roles of Langerhans cells (LCs) and Langerin(+) dermal DCs (dDCs) in different vaccination settings. Poly(I:C) and anti-CD40 agonist antibody promoted cytotoxic responses upon intradermal immunization with ovalbumin (OVA)-coupled anti-Langerin antibodies (Langerin/OVA). This correlated with CD70 upregulation in Langerin(+) dDCs, but not LCs. In chimeric mice where Langerin targeting was restricted to dDCs, CD8(+) T-cell memory was enhanced. Conversely, providing Langerin/OVA exclusively to LCs failed to prime cytotoxicity, despite initial antigen cross-presentation to CD8(+) T cells. Langerin/OVA combined with imiquimod could not prime CD8(+) T cells and resulted in poor cytotoxicity in subsequent responses. This tolerance induction required targeting and maturation of LCs. Altogether, Langerin(+) dDCs prime long-lasting cytotoxic responses, while cross-presentation by LCs negatively influences CD8(+) T-cell priming. Moreover, this highlights that DCs exposed to TLR agonists can still induce tolerance and supports the existence of qualitatively different DC maturation programs.
Voisin Benjamin, Mairhofer David Gabriel, Chen Suzie, Stoitzner Patrizia, Mueller Christopher George, Flacher Vincent
Anatomical distribution analysis reveals lack of Langerin+ dermal dendritic cells in footpads and tail of C57BL/6 mice Article de journal
Dans: Experimental Dermatology, vol. 23, no. 5, p. 354–356, 2014, ISSN: 1600-0625.
Résumé | Liens | BibTeX | Étiquettes: Analysis, Animals, Antigen, Antigens, C-Type, CD, CD11c Antigen, Cell Adhesion Molecules, Dendritic Cells, DERMAL DENDRITIC CELLS, Epithelial Cell Adhesion Molecule, footpad skin, function, Hindlimb, immunopathology, Inbred BALB C, Inbred C57BL, Inbred CBA, inflammation, Integrin alpha Chains, Langerhans Cells, Lectins, Letter, Leukocyte Common Antigens, LYMPH, LYMPH NODE, Lymph Nodes, Mannose-Binding Lectins, Mice, mouse, Neoplasm, Skin, skin-draining lymph nodes, Surface, T CELLS, T-CELLS, Tail, tail skin, Team-Mueller
@article{voisin_anatomical_2014,
title = {Anatomical distribution analysis reveals lack of Langerin+ dermal dendritic cells in footpads and tail of C57BL/6 mice},
author = {Benjamin Voisin and David Gabriel Mairhofer and Suzie Chen and Patrizia Stoitzner and Christopher George Mueller and Vincent Flacher},
doi = {10.1111/exd.12373},
issn = {1600-0625},
year = {2014},
date = {2014-01-01},
journal = {Experimental Dermatology},
volume = {23},
number = {5},
pages = {354--356},
abstract = {Epidermal Langerhans cells (LCs) and dermal dendritic cells (dDCs) capture cutaneous antigens and present them to T-cells in lymph nodes (LNs). The function of LCs and Langerin+ dDCs was extensively studied in the mouse, but their anatomical repartition is unknown. Here, we found LCs in back skin, footpads and tail skin of C57BL/6, BALB/c, 129/Sv and CBA/J mice. Langerin+ dDCs were readily observed in back skin of all strains, but only in footpads and tail of BALB/c and CBA/J mice. Similarly, while LCs were equally present in all LNs and strains, Langerin+ dDCs were found in popliteal LNs (draining footpads) only in BALB/c and CBA/J mice. The sciatic LNs, which we identified as the major tail-draining lymphoid organ, were devoid of Langerin+ dDCs in all strains. Thus, functionally different DCs reside in different skin areas, with variations among mouse strains, implying a potential impact on the cutaneous immune reaction.},
keywords = {Analysis, Animals, Antigen, Antigens, C-Type, CD, CD11c Antigen, Cell Adhesion Molecules, Dendritic Cells, DERMAL DENDRITIC CELLS, Epithelial Cell Adhesion Molecule, footpad skin, function, Hindlimb, immunopathology, Inbred BALB C, Inbred C57BL, Inbred CBA, inflammation, Integrin alpha Chains, Langerhans Cells, Lectins, Letter, Leukocyte Common Antigens, LYMPH, LYMPH NODE, Lymph Nodes, Mannose-Binding Lectins, Mice, mouse, Neoplasm, Skin, skin-draining lymph nodes, Surface, T CELLS, T-CELLS, Tail, tail skin, Team-Mueller},
pubstate = {published},
tppubtype = {article}
}
Epidermal Langerhans cells (LCs) and dermal dendritic cells (dDCs) capture cutaneous antigens and present them to T-cells in lymph nodes (LNs). The function of LCs and Langerin+ dDCs was extensively studied in the mouse, but their anatomical repartition is unknown. Here, we found LCs in back skin, footpads and tail skin of C57BL/6, BALB/c, 129/Sv and CBA/J mice. Langerin+ dDCs were readily observed in back skin of all strains, but only in footpads and tail of BALB/c and CBA/J mice. Similarly, while LCs were equally present in all LNs and strains, Langerin+ dDCs were found in popliteal LNs (draining footpads) only in BALB/c and CBA/J mice. The sciatic LNs, which we identified as the major tail-draining lymphoid organ, were devoid of Langerin+ dDCs in all strains. Thus, functionally different DCs reside in different skin areas, with variations among mouse strains, implying a potential impact on the cutaneous immune reaction.
2012
Flacher V, Tripp C H, Haid B, Kissenpfennig A, Malissen B, Stoitzner P, Idoyaga J, Romani N
Skin langerin+ dendritic cells transport intradermally injected anti-DEC-205 antibodies but are not essential for subsequent cytotoxic CD8+ Ŧ cell responses Article de journal
Dans: Journal of Immunology, vol. 188, no. 1550-6606 (Electronic), p. 2146–2155, 2012.
Résumé | BibTeX | Étiquettes: administration & dosage, Animals, Antibodies, antibody, Antigen, Antigens, Biosynthesis, C-Type, C-type lectin, CD, Cell Surface, Comparative Study, Cytotoxic, Dendritic Cells, DERMATOLOGY, Gene Knock-In Techniques, Genetics, imiquimod, immune response, IMMUNE-RESPONSES, Immunization, Immunology, in situ, In vivo, Inbred BALB C, Inbred C57BL, INDUCTION, inflammation, Inflammation Mediators, Injections, Intradermal, knock-in, Langerhans Cells, LECTIN, Lectins, LYMPH, LYMPH NODE, Lymph Nodes, LYMPHATIC VESSEL, Lymphatic Vessels, mAb, Mannose-Binding Lectins, MEDIATOR, metabolism, Mice, Minor Histocompatibility Antigens, mouse, murine, Organ Culture Techniques, Ovum, pathology, physiology, Protein, Protein Transport, Rats, Receptor, Receptors, RESPONSES, Skin, SUBSETS, Surface, T-Lymphocytes, target, Team-Mueller, TLR7, transgenic
@article{flacher_skin_2012,
title = {Skin langerin+ dendritic cells transport intradermally injected anti-DEC-205 antibodies but are not essential for subsequent cytotoxic CD8+ Ŧ cell responses},
author = {V Flacher and C H Tripp and B Haid and A Kissenpfennig and B Malissen and P Stoitzner and J Idoyaga and N Romani},
year = {2012},
date = {2012-03-01},
journal = {Journal of Immunology},
volume = {188},
number = {1550-6606 (Electronic)},
pages = {2146--2155},
abstract = {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 CD8alpha(+) 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 CD8alpha(+) DCs are sufficient to subsequent CD8(+) T cell responses},
keywords = {administration & dosage, Animals, Antibodies, antibody, Antigen, Antigens, Biosynthesis, C-Type, C-type lectin, CD, Cell Surface, Comparative Study, Cytotoxic, Dendritic Cells, DERMATOLOGY, Gene Knock-In Techniques, Genetics, imiquimod, immune response, IMMUNE-RESPONSES, Immunization, Immunology, in situ, In vivo, Inbred BALB C, Inbred C57BL, INDUCTION, inflammation, Inflammation Mediators, Injections, Intradermal, knock-in, Langerhans Cells, LECTIN, Lectins, LYMPH, LYMPH NODE, Lymph Nodes, LYMPHATIC VESSEL, Lymphatic Vessels, mAb, Mannose-Binding Lectins, MEDIATOR, metabolism, Mice, Minor Histocompatibility Antigens, mouse, murine, Organ Culture Techniques, Ovum, pathology, physiology, Protein, Protein Transport, Rats, Receptor, Receptors, RESPONSES, Skin, SUBSETS, Surface, T-Lymphocytes, target, Team-Mueller, TLR7, transgenic},
pubstate = {published},
tppubtype = {article}
}
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 CD8alpha(+) 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 CD8alpha(+) DCs are sufficient to subsequent CD8(+) T cell responses
Schickel Jean-Nicolas, Pasquali Jean-Louis, Soley Anne, Knapp Anne-Marie, Decossas Marion, Kern Aurélie, Fauny Jean-Daniel, Marcellin Luc, Korganow Anne-Sophie, Martin Thierry, Soulas-Sprauel Pauline
Carabin deficiency in B cells increases BCR-TLR9 costimulation-induced autoimmunity Article de journal
Dans: EMBO molecular medicine, vol. 4, no. 12, p. 1261–1275, 2012, ISSN: 1757-4684.
Résumé | Liens | BibTeX | Étiquettes: Adaptor Proteins, Animals, Antigen, Autoimmunity, B-Cell, B-Lymphocytes, Carrier Proteins, Cohort Studies, DNA, Humans, I2CT, Imagerie, Inbred NZB, Inbred Strains, Mice, Phosphorylation, Prospective Studies, Receptors, Signal Transducing, Toll-Like Receptor 9, Transfection
@article{schickel_carabin_2012,
title = {Carabin deficiency in B cells increases BCR-TLR9 costimulation-induced autoimmunity},
author = {Jean-Nicolas Schickel and Jean-Louis Pasquali and Anne Soley and Anne-Marie Knapp and Marion Decossas and Aurélie Kern and Jean-Daniel Fauny and Luc Marcellin and Anne-Sophie Korganow and Thierry Martin and Pauline Soulas-Sprauel},
doi = {10.1002/emmm.201201595},
issn = {1757-4684},
year = {2012},
date = {2012-01-01},
journal = {EMBO molecular medicine},
volume = {4},
number = {12},
pages = {1261--1275},
abstract = {The mechanisms behind flares of human autoimmune diseases in general, and of systemic lupus in particular, are poorly understood. The present scenario proposes that predisposing gene defects favour clinical flares under the influence of external stimuli. Here, we show that Carabin is low in B cells of (NZB × NZW) F1 mice (murine SLE model) long before the disease onset, and is low in B cells of lupus patients during the inactive phases of the disease. Using knock-out and B-cell-conditional knock-out murine models, we identify Carabin as a new negative regulator of B-cell function, whose deficiency in B cells speeds up early B-cell responses and makes the mice more susceptible to anti-dsDNA production and renal lupus flare after stimulation with a Toll-like Receptor 9 agonist, CpG-DNA. Finally, in vitro analysis of NFκB activation and Erk phosphorylation in TLR9- and B-cell receptor (BCR)-stimulated Carabin-deficient B cells strongly suggests how the internal defect synergizes with the external stimulus and proposes Carabin as a natural inhibitor of the potentially dangerous crosstalk between BCR and TLR9 pathways in self-reactive B cells.},
keywords = {Adaptor Proteins, Animals, Antigen, Autoimmunity, B-Cell, B-Lymphocytes, Carrier Proteins, Cohort Studies, DNA, Humans, I2CT, Imagerie, Inbred NZB, Inbred Strains, Mice, Phosphorylation, Prospective Studies, Receptors, Signal Transducing, Toll-Like Receptor 9, Transfection},
pubstate = {published},
tppubtype = {article}
}
The mechanisms behind flares of human autoimmune diseases in general, and of systemic lupus in particular, are poorly understood. The present scenario proposes that predisposing gene defects favour clinical flares under the influence of external stimuli. Here, we show that Carabin is low in B cells of (NZB × NZW) F1 mice (murine SLE model) long before the disease onset, and is low in B cells of lupus patients during the inactive phases of the disease. Using knock-out and B-cell-conditional knock-out murine models, we identify Carabin as a new negative regulator of B-cell function, whose deficiency in B cells speeds up early B-cell responses and makes the mice more susceptible to anti-dsDNA production and renal lupus flare after stimulation with a Toll-like Receptor 9 agonist, CpG-DNA. Finally, in vitro analysis of NFκB activation and Erk phosphorylation in TLR9- and B-cell receptor (BCR)-stimulated Carabin-deficient B cells strongly suggests how the internal defect synergizes with the external stimulus and proposes Carabin as a natural inhibitor of the potentially dangerous crosstalk between BCR and TLR9 pathways in self-reactive B cells.
Romani N, Flacher V, Tripp C H, Sparber F, Ebner S, Stoitzner P
Targeting skin dendritic cells to improve intradermal vaccination Article de journal
Dans: Current Topics in Microbiology and Immunology, vol. 351, p. 113–138, 2012, ISSN: 0070-217X.
Résumé | Liens | BibTeX | Étiquettes: Adaptive Immunity, administration & dosage, Analysis, Animals, Antibodies, antibody, Antigen, ANTIGEN PRESENTING CELLS, Antigen-Presenting Cells, Antigens, B CELLS, B-Lymphocytes, Bacterial Infections, Biosynthesis, C-Type, CD, CD14, CD1a, Cell Lineage, cytokine, Cytokines, cytology, Cytotoxic, Dendritic Cells, DERMATOLOGY, DERMIS, Drug Delivery Systems, Expression, Human, Humans, Immunity, Immunology, INDUCTION, Injections, Innate, Intradermal, Langerhans Cells, LECTIN, Lectins, Lymphocyte Activation, Lymphocytes, Mannose-Binding Lectins, methods, Mice, mouse, Muscle, prevention & control, PRODUCTION, Protein, review, Skin, SUBSETS, T-Lymphocytes, Team-Mueller, tolerance, Vaccination, vaccine, Vaccines, Virus Diseases
@article{romani_targeting_2012,
title = {Targeting skin dendritic cells to improve intradermal vaccination},
author = {N Romani and V Flacher and C H Tripp and F Sparber and S Ebner and P Stoitzner},
doi = {10.1007/82_2010_118},
issn = {0070-217X},
year = {2012},
date = {2012-01-01},
journal = {Current Topics in Microbiology and Immunology},
volume = {351},
pages = {113--138},
abstract = {Vaccinations in medicine are typically administered into the muscle beneath the skin or into the subcutaneous fat. As a consequence, the vaccine is immunologically processed by antigen-presenting cells of the skin or the muscle. Recent evidence suggests that the clinically seldom used intradermal route is effective and possibly even superior to the conventional subcutaneous or intramuscular route. Several types of professional antigen-presenting cells inhabit the healthy skin. Epidermal Langerhans cells (CD207/langerin(+)), dermal langerin(neg), and dermal langerin(+) dendritic cells (DC) have been described, the latter subset so far only in mouse skin. In human skin langerin(neg) dermal DC can be further classified based on their reciprocal expression of CD1a and CD14. The relative contributions of these subsets to the generation of immunity or tolerance are still unclear. Yet, specializations of these different populations have become apparent. Langerhans cells in human skin appear to be specialized for induction of cytotoxic T lymphocytes; human CD14(+) dermal DC can promote antibody production by B cells. It is currently attempted to rationally devise and improve vaccines by harnessing such specific properties of skin DC. This could be achieved by specifically targeting functionally diverse skin DC subsets. We discuss here advances in our knowledge on the immunological properties of skin DC and strategies to significantly improve the outcome of vaccinations by applying this knowledge.},
keywords = {Adaptive Immunity, administration & dosage, Analysis, Animals, Antibodies, antibody, Antigen, ANTIGEN PRESENTING CELLS, Antigen-Presenting Cells, Antigens, B CELLS, B-Lymphocytes, Bacterial Infections, Biosynthesis, C-Type, CD, CD14, CD1a, Cell Lineage, cytokine, Cytokines, cytology, Cytotoxic, Dendritic Cells, DERMATOLOGY, DERMIS, Drug Delivery Systems, Expression, Human, Humans, Immunity, Immunology, INDUCTION, Injections, Innate, Intradermal, Langerhans Cells, LECTIN, Lectins, Lymphocyte Activation, Lymphocytes, Mannose-Binding Lectins, methods, Mice, mouse, Muscle, prevention & control, PRODUCTION, Protein, review, Skin, SUBSETS, T-Lymphocytes, Team-Mueller, tolerance, Vaccination, vaccine, Vaccines, Virus Diseases},
pubstate = {published},
tppubtype = {article}
}
Vaccinations in medicine are typically administered into the muscle beneath the skin or into the subcutaneous fat. As a consequence, the vaccine is immunologically processed by antigen-presenting cells of the skin or the muscle. Recent evidence suggests that the clinically seldom used intradermal route is effective and possibly even superior to the conventional subcutaneous or intramuscular route. Several types of professional antigen-presenting cells inhabit the healthy skin. Epidermal Langerhans cells (CD207/langerin(+)), dermal langerin(neg), and dermal langerin(+) dendritic cells (DC) have been described, the latter subset so far only in mouse skin. In human skin langerin(neg) dermal DC can be further classified based on their reciprocal expression of CD1a and CD14. The relative contributions of these subsets to the generation of immunity or tolerance are still unclear. Yet, specializations of these different populations have become apparent. Langerhans cells in human skin appear to be specialized for induction of cytotoxic T lymphocytes; human CD14(+) dermal DC can promote antibody production by B cells. It is currently attempted to rationally devise and improve vaccines by harnessing such specific properties of skin DC. This could be achieved by specifically targeting functionally diverse skin DC subsets. We discuss here advances in our knowledge on the immunological properties of skin DC and strategies to significantly improve the outcome of vaccinations by applying this knowledge.
2011
Banchet-Cadeddu Aline, Hénon Eric, Dauchez Manuel, Renault Jean-Hugues, Monneaux Fanny, Haudrechy Arnaud
The stimulating adventure of KRN 7000 Article de journal
Dans: Organic & Biomolecular Chemistry, vol. 9, no. 9, p. 3080–3104, 2011, ISSN: 1477-0539.
Résumé | Liens | BibTeX | Étiquettes: Adjuvants, Animals, Antigen, Antigens, CD1d, Galactosylceramides, Helper-Inducer, Humans, I2CT, Immunologic, Monneaux, Receptors, T-Cell, T-Lymphocytes, Team-Dumortier
@article{banchet-cadeddu_stimulating_2011,
title = {The stimulating adventure of KRN 7000},
author = {Aline Banchet-Cadeddu and Eric Hénon and Manuel Dauchez and Jean-Hugues Renault and Fanny Monneaux and Arnaud Haudrechy},
doi = {10.1039/c0ob00975j},
issn = {1477-0539},
year = {2011},
date = {2011-01-01},
journal = {Organic & Biomolecular Chemistry},
volume = {9},
number = {9},
pages = {3080--3104},
abstract = {Associated with the CD1d protein, KRN 7000, a potent synthetic α-galactosylceramide, is known to activate the invariant NKT immune cells. This stimulation then leads to the production of different cytokines modulating a T(H)1/T(H)2 immune response balance involved in protection against several pathologies such as autoimmune diseases and cancers. Various efforts have been made toward the synthesis of simple and more functionalized analogues in order to selectively induce T(H)1 or T(H)2-type cytokine production. Since the discovery of KRN 7000, structure-activity relationships, crystallographic and modelling studies have pointed to the potential of several GalCer analogues in term of selective bioactivity, and have highlighted interesting elements in order to better understand the recognition and activation mechanisms of immune iNKT cells. By presenting an up-to-date library of analogues, collecting recent breakthroughs done in crystallography and molecular modelling, and relating them to the available biological results, we hope that this review will highlight and help the scientific community in their KRN research.},
keywords = {Adjuvants, Animals, Antigen, Antigens, CD1d, Galactosylceramides, Helper-Inducer, Humans, I2CT, Immunologic, Monneaux, Receptors, T-Cell, T-Lymphocytes, Team-Dumortier},
pubstate = {published},
tppubtype = {article}
}
Associated with the CD1d protein, KRN 7000, a potent synthetic α-galactosylceramide, is known to activate the invariant NKT immune cells. This stimulation then leads to the production of different cytokines modulating a T(H)1/T(H)2 immune response balance involved in protection against several pathologies such as autoimmune diseases and cancers. Various efforts have been made toward the synthesis of simple and more functionalized analogues in order to selectively induce T(H)1 or T(H)2-type cytokine production. Since the discovery of KRN 7000, structure-activity relationships, crystallographic and modelling studies have pointed to the potential of several GalCer analogues in term of selective bioactivity, and have highlighted interesting elements in order to better understand the recognition and activation mechanisms of immune iNKT cells. By presenting an up-to-date library of analogues, collecting recent breakthroughs done in crystallography and molecular modelling, and relating them to the available biological results, we hope that this review will highlight and help the scientific community in their KRN research.
Canard B, Vachon H, Fontaine T, Pin J J, Paul S, Genin C, Mueller C G
Generation of anti-DC-SIGN monoclonal antibodies capable of blocking HIV-1 gp120 binding and reactive on formalin-fixed tissue Article de journal
Dans: Immunol.Lett., vol. 135, no. 1879-0542 (Electronic), p. 165–172, 2011.
Résumé | BibTeX | Étiquettes: Adhesion, adhesion molecules, Animals, Antibodies, antibody, Antigen, Antigens, Blocking, C-Type, C-type lectin, CD, Cell Adhesion, Cell Adhesion Molecules, Cell Surface, Chemistry, clones, Dendritic Cells, DERMIS, Differentiation, Fixatives, Formaldehyde, formalin-fixed tissue, Genetics, GLYCOPROTEIN, GP120, HeLa Cells, HIV, HIV Envelope Protein gp120, HIV-1, Human, Humans, hybridoma, ICAM-3, immunodeficiency, Immunology, Inbred BALB C, infection, LECTIN, Lectins, Macrophage, Macrophages, Mice, Monoclonal, monoclonal antibody, MONOCLONAL-ANTIBODY, Monocytes, Murine-Derived, Myelomonocytic, Nih 3T3 Cells, Paraffin Embedding, pathogenicity, Protein, Receptor, Receptors, recognition, Skin, Team-Mueller, virus
@article{canard_generation_2011,
title = {Generation of anti-DC-SIGN monoclonal antibodies capable of blocking HIV-1 gp120 binding and reactive on formalin-fixed tissue},
author = {B Canard and H Vachon and T Fontaine and J J Pin and S Paul and C Genin and C G Mueller},
year = {2011},
date = {2011-01-01},
journal = {Immunol.Lett.},
volume = {135},
number = {1879-0542 (Electronic)},
pages = {165--172},
abstract = {DC-SIGN is a C-type lectin of recognized importance in immunology and in the pathogenicity human pathogens. Monoclonal antibodies directed against DC-SIGN have been generated, but their systemic characterization for interfering with binding of the HIV-1 glycoprotein 120 has often been omitted. Moreover, so far, no anti-DC-SIGN monoclonal antibody has been described that recognizes its antigen after formalin fixation and paraffin embedding. In this study, we have generated new anti-DC-SIGN monoclonal antibodies using HeLa cells stably expressing DC-SIGN as immunogen. We have obtained 11 hybridoma clones producing antibodies that recognized DC-SIGN on monocyte-derived dendritic cells and on dermal-type macrophages. Seven monoclonal antibodies displayed a capacity to interfere with DC-SIGN binding to HIV-1 gp120. One recognized DC-SIGN on formalin-fixed dendritic cells and macrophages. Using this antibody we have obtained specific labelling of DC-SIGN and colocalisation with the dermal macrophage marker CD163 on human skin. The described monoclonal anti-human DC-SIGN antibodies will be of use to the scientific community to address fundamental immunology issues, in particular concerning macrophages and dendritic cells, and help elucidate infection events of pathogen targeting DC-SIGN as recognition receptor},
keywords = {Adhesion, adhesion molecules, Animals, Antibodies, antibody, Antigen, Antigens, Blocking, C-Type, C-type lectin, CD, Cell Adhesion, Cell Adhesion Molecules, Cell Surface, Chemistry, clones, Dendritic Cells, DERMIS, Differentiation, Fixatives, Formaldehyde, formalin-fixed tissue, Genetics, GLYCOPROTEIN, GP120, HeLa Cells, HIV, HIV Envelope Protein gp120, HIV-1, Human, Humans, hybridoma, ICAM-3, immunodeficiency, Immunology, Inbred BALB C, infection, LECTIN, Lectins, Macrophage, Macrophages, Mice, Monoclonal, monoclonal antibody, MONOCLONAL-ANTIBODY, Monocytes, Murine-Derived, Myelomonocytic, Nih 3T3 Cells, Paraffin Embedding, pathogenicity, Protein, Receptor, Receptors, recognition, Skin, Team-Mueller, virus},
pubstate = {published},
tppubtype = {article}
}
DC-SIGN is a C-type lectin of recognized importance in immunology and in the pathogenicity human pathogens. Monoclonal antibodies directed against DC-SIGN have been generated, but their systemic characterization for interfering with binding of the HIV-1 glycoprotein 120 has often been omitted. Moreover, so far, no anti-DC-SIGN monoclonal antibody has been described that recognizes its antigen after formalin fixation and paraffin embedding. In this study, we have generated new anti-DC-SIGN monoclonal antibodies using HeLa cells stably expressing DC-SIGN as immunogen. We have obtained 11 hybridoma clones producing antibodies that recognized DC-SIGN on monocyte-derived dendritic cells and on dermal-type macrophages. Seven monoclonal antibodies displayed a capacity to interfere with DC-SIGN binding to HIV-1 gp120. One recognized DC-SIGN on formalin-fixed dendritic cells and macrophages. Using this antibody we have obtained specific labelling of DC-SIGN and colocalisation with the dermal macrophage marker CD163 on human skin. The described monoclonal anti-human DC-SIGN antibodies will be of use to the scientific community to address fundamental immunology issues, in particular concerning macrophages and dendritic cells, and help elucidate infection events of pathogen targeting DC-SIGN as recognition receptor
2010
Noordegraaf Madelon, Flacher Vincent, Stoitzner Patrizia, Clausen Björn E
Functional redundancy of Langerhans cells and Langerin+ dermal dendritic cells in contact hypersensitivity Article de journal
Dans: The Journal of Investigative Dermatology, vol. 130, no. 12, p. 2752–2759, 2010, ISSN: 1523-1747.
Résumé | Liens | BibTeX | Étiquettes: Animal, Animals, Antigen, Antigens, C-Type, CHS, contact, CONTACT HYPERSENSITIVITY, Dendritic Cells, DEPLETION, DERMAL DENDRITIC CELLS, Dermatitis, DERMIS, Diphtheria Toxin, Disease Models, Epidermis, function, Gene Knock-In Techniques, Genetics, Growth, HAPTEN, Haptens, Heparin-binding EGF-like Growth Factor, Hypersensitivity, Immunology, Inbred C57BL, INDUCTION, Intercellular Signaling Peptides and Proteins, LACKING, Langerhans Cells, LECTIN, Lectins, LYMPH, LYMPH NODE, Lymph Nodes, Mannose-Binding Lectins, metabolism, Mice, mouse, Mutant Strains, Organ Culture Techniques, pathology, Peptides, Poisons, Protein, Proteins, RESPONSES, signaling, Skin, Surface, Team-Mueller, Toxicity
@article{noordegraaf_functional_2010,
title = {Functional redundancy of Langerhans cells and Langerin+ dermal dendritic cells in contact hypersensitivity},
author = {Madelon Noordegraaf and Vincent Flacher and Patrizia Stoitzner and Björn E Clausen},
doi = {10.1038/jid.2010.223},
issn = {1523-1747},
year = {2010},
date = {2010-12-01},
journal = {The Journal of Investigative Dermatology},
volume = {130},
number = {12},
pages = {2752--2759},
abstract = {The relative roles of Langerhans cells (LC), dermal dendritic cells (DC), and, in particular, the recently discovered Langerin(+) dermal DC subset in the induction and control of contact hypersensitivity (CHS) responses remain controversial. Using an inducible mouse model, in which LC and other Langerin(+) DC can be depleted by injection of diphtheria toxin, we previously reported impaired transport of topically applied antigen to draining lymph nodes and reduced CHS in the absence of all Langerin(+) skin DC. In this study, we demonstrate that mice with a selective depletion of LC exhibit attenuated CHS only upon sensitization with a low hapten dose but not with a high hapten dose. In contrast, when painting a higher concentration of hapten onto the skin, which leads to increased antigen dissemination into the dermis, CHS is still diminished in mice lacking all Langerin(+) skin DC. Taken together, these data suggest that the magnitude of a CHS reaction depends on the number of skin DC, which have access to the hapten, rather than on the presence or absence of a particular skin DC population. LC and (Langerin(+)) dermal DC thus seem to have a redundant function in regulating CHS.},
keywords = {Animal, Animals, Antigen, Antigens, C-Type, CHS, contact, CONTACT HYPERSENSITIVITY, Dendritic Cells, DEPLETION, DERMAL DENDRITIC CELLS, Dermatitis, DERMIS, Diphtheria Toxin, Disease Models, Epidermis, function, Gene Knock-In Techniques, Genetics, Growth, HAPTEN, Haptens, Heparin-binding EGF-like Growth Factor, Hypersensitivity, Immunology, Inbred C57BL, INDUCTION, Intercellular Signaling Peptides and Proteins, LACKING, Langerhans Cells, LECTIN, Lectins, LYMPH, LYMPH NODE, Lymph Nodes, Mannose-Binding Lectins, metabolism, Mice, mouse, Mutant Strains, Organ Culture Techniques, pathology, Peptides, Poisons, Protein, Proteins, RESPONSES, signaling, Skin, Surface, Team-Mueller, Toxicity},
pubstate = {published},
tppubtype = {article}
}
The relative roles of Langerhans cells (LC), dermal dendritic cells (DC), and, in particular, the recently discovered Langerin(+) dermal DC subset in the induction and control of contact hypersensitivity (CHS) responses remain controversial. Using an inducible mouse model, in which LC and other Langerin(+) DC can be depleted by injection of diphtheria toxin, we previously reported impaired transport of topically applied antigen to draining lymph nodes and reduced CHS in the absence of all Langerin(+) skin DC. In this study, we demonstrate that mice with a selective depletion of LC exhibit attenuated CHS only upon sensitization with a low hapten dose but not with a high hapten dose. In contrast, when painting a higher concentration of hapten onto the skin, which leads to increased antigen dissemination into the dermis, CHS is still diminished in mice lacking all Langerin(+) skin DC. Taken together, these data suggest that the magnitude of a CHS reaction depends on the number of skin DC, which have access to the hapten, rather than on the presence or absence of a particular skin DC population. LC and (Langerin(+)) dermal DC thus seem to have a redundant function in regulating CHS.
Flacher Vincent, Tripp Christoph H, Stoitzner Patrizia, Haid Bernhard, Ebner Susanne, Frari Barbara Del, Koch Franz, Park Chae Gyu, Steinman Ralph M, Idoyaga Juliana, Romani Nikolaus
Epidermal Langerhans cells rapidly capture and present antigens from C-type lectin-targeting antibodies deposited in the dermis Article de journal
Dans: The Journal of Investigative Dermatology, vol. 130, no. 3, p. 755–762, 2010, ISSN: 1523-1747.
Résumé | Liens | BibTeX | Étiquettes: Animals, Antibodies, antibody, Antigen, Antigen Presentation, ANTIGEN PRESENTING CELLS, Antigen-Presenting Cells, Antigens, BASEMENT MEMBRANE, C-Type, C-type lectin, CD103, CD8+ T cells, Cell Division, Cell Movement, Cells, Culture, Cultured, cytology, Dendritic Cells, DERMATOLOGY, DERMIS, Epidermal Cells, Epidermis, function, Human, Humans, Immunology, in situ, IN VITRO, In vivo, Inbred BALB C, Inbred C57BL, Injections, Intradermal, Langerhans Cells, LECTIN, Lectins, mAb, Mannose-Binding Lectins, Membrane, Mice, Monoclonal, mouse, murine, Pharmacology, Proliferation, Protein, Receptor, Skin, Surface, T CELLS, T-CELLS, T-Lymphocytes, Team-Mueller, Vaccination, vaccine, Vaccines
@article{flacher_epidermal_2010,
title = {Epidermal Langerhans cells rapidly capture and present antigens from C-type lectin-targeting antibodies deposited in the dermis},
author = {Vincent Flacher and Christoph H Tripp and Patrizia Stoitzner and Bernhard Haid and Susanne Ebner and Barbara Del Frari and Franz Koch and Chae Gyu Park and Ralph M Steinman and Juliana Idoyaga and Nikolaus Romani},
doi = {10.1038/jid.2009.343},
issn = {1523-1747},
year = {2010},
date = {2010-03-01},
journal = {The Journal of Investigative Dermatology},
volume = {130},
number = {3},
pages = {755--762},
abstract = {Antigen-presenting cells can capture antigens that are deposited in the skin, including vaccines given subcutaneously. These include different dendritic cells (DCs) such as epidermal Langerhans cells (LCs), dermal DCs, and dermal langerin+ DCs. To evaluate access of dermal antigens to skin DCs, we used mAb to two C-type lectin endocytic receptors, DEC-205/CD205 and langerin/CD207. When applied to murine and human skin explant cultures, these mAbs were efficiently taken up by epidermal LCs. In addition, anti-DEC-205 targeted langerin+ CD103+ and langerin- CD103- mouse dermal DCs. Unexpectedly, intradermal injection of either mAb, but not isotype control, resulted in strong and rapid labeling of LCs in situ, implying that large molecules can diffuse through the basement membrane into the epidermis. Epidermal LCs targeted in vivo by ovalbumin-coupled anti-DEC-205 potently presented antigen to CD4+ and CD8+ T cells in vitro. However, to our surprise, LCs targeted through langerin were unable to trigger T-cell proliferation. Thus, epidermal LCs have a major function in uptake of lectin-binding antibodies under standard vaccination conditions.},
keywords = {Animals, Antibodies, antibody, Antigen, Antigen Presentation, ANTIGEN PRESENTING CELLS, Antigen-Presenting Cells, Antigens, BASEMENT MEMBRANE, C-Type, C-type lectin, CD103, CD8+ T cells, Cell Division, Cell Movement, Cells, Culture, Cultured, cytology, Dendritic Cells, DERMATOLOGY, DERMIS, Epidermal Cells, Epidermis, function, Human, Humans, Immunology, in situ, IN VITRO, In vivo, Inbred BALB C, Inbred C57BL, Injections, Intradermal, Langerhans Cells, LECTIN, Lectins, mAb, Mannose-Binding Lectins, Membrane, Mice, Monoclonal, mouse, murine, Pharmacology, Proliferation, Protein, Receptor, Skin, Surface, T CELLS, T-CELLS, T-Lymphocytes, Team-Mueller, Vaccination, vaccine, Vaccines},
pubstate = {published},
tppubtype = {article}
}
Antigen-presenting cells can capture antigens that are deposited in the skin, including vaccines given subcutaneously. These include different dendritic cells (DCs) such as epidermal Langerhans cells (LCs), dermal DCs, and dermal langerin+ DCs. To evaluate access of dermal antigens to skin DCs, we used mAb to two C-type lectin endocytic receptors, DEC-205/CD205 and langerin/CD207. When applied to murine and human skin explant cultures, these mAbs were efficiently taken up by epidermal LCs. In addition, anti-DEC-205 targeted langerin+ CD103+ and langerin- CD103- mouse dermal DCs. Unexpectedly, intradermal injection of either mAb, but not isotype control, resulted in strong and rapid labeling of LCs in situ, implying that large molecules can diffuse through the basement membrane into the epidermis. Epidermal LCs targeted in vivo by ovalbumin-coupled anti-DEC-205 potently presented antigen to CD4+ and CD8+ T cells in vitro. However, to our surprise, LCs targeted through langerin were unable to trigger T-cell proliferation. Thus, epidermal LCs have a major function in uptake of lectin-binding antibodies under standard vaccination conditions.
Romani Nikolaus, Thurnher Martin, Idoyaga Juliana, Steinman Ralph M, Flacher Vincent
Targeting of antigens to skin dendritic cells: possibilities to enhance vaccine efficacy Article de journal
Dans: Immunology and Cell Biology, vol. 88, no. 4, p. 424–430, 2010, ISSN: 1440-1711.
Résumé | Liens | BibTeX | Étiquettes: Animals, Antibodies, antibody, Antigen, ANTIGEN PRESENTING CELLS, Antigen-Presenting Cells, Antigens, C-Type, CD, CD14, CD1a, CROSS-PRESENTATION, Dendritic Cells, DERMATOLOGY, Expression, Human, Humans, Immunity, Immunotherapy, INDUCTION, Intradermal, Langerhans Cells, Lectins, Lymphocytes, Mannose-Binding Lectins, mouse, Receptor, Skin, SUBSETS, T-Lymphocytes, Team-Mueller, tolerance, Vaccination, vaccine, Vaccines
@article{romani_targeting_2010,
title = {Targeting of antigens to skin dendritic cells: possibilities to enhance vaccine efficacy},
author = {Nikolaus Romani and Martin Thurnher and Juliana Idoyaga and Ralph M Steinman and Vincent Flacher},
doi = {10.1038/icb.2010.39},
issn = {1440-1711},
year = {2010},
date = {2010-01-01},
journal = {Immunology and Cell Biology},
volume = {88},
number = {4},
pages = {424--430},
abstract = {Vaccinations in medicine are commonly administered through the skin. Therefore, the vaccine is immunologically processed by antigen-presenting cells of the skin. There is recent evidence that the clinically less often used intradermal route is effective; in cases even superior to the conventional subcutaneous or intramuscular route. Professional antigen-presenting cells of the skin comprise epidermal Langerhans cells (CD207/langerin(+)), dermal langerin(-) and dermal langerin(+) dendritic cells (DCs). In human skin, langerin(-) dermal DCs can be further subdivided on the basis of their reciprocal CD1a and CD14 expression. The relative contributions of these subsets to the generation of immunity or tolerance are still unclear. Langerhans cells in human skin seem to be specialized for induction of cytotoxic T lymphocytes. Likewise, mouse Langerhans cells are capable of cross-presentation and of protecting against experimental tumours. It is desirable to harness these properties for immunotherapy. A promising strategy to dramatically improve the outcome of vaccinations is 'antigen targeting'. Thereby, the vaccine is delivered directly and selectively to defined types of skin DCs. Targeting is achieved by means of coupling antigen to antibodies that recognize cell surface receptors on DCs. This approach is being widely explored. Little is known, however, about the events that take place in the skin and the DCs subsets involved therein. This topic will be discussed in this article.},
keywords = {Animals, Antibodies, antibody, Antigen, ANTIGEN PRESENTING CELLS, Antigen-Presenting Cells, Antigens, C-Type, CD, CD14, CD1a, CROSS-PRESENTATION, Dendritic Cells, DERMATOLOGY, Expression, Human, Humans, Immunity, Immunotherapy, INDUCTION, Intradermal, Langerhans Cells, Lectins, Lymphocytes, Mannose-Binding Lectins, mouse, Receptor, Skin, SUBSETS, T-Lymphocytes, Team-Mueller, tolerance, Vaccination, vaccine, Vaccines},
pubstate = {published},
tppubtype = {article}
}
Vaccinations in medicine are commonly administered through the skin. Therefore, the vaccine is immunologically processed by antigen-presenting cells of the skin. There is recent evidence that the clinically less often used intradermal route is effective; in cases even superior to the conventional subcutaneous or intramuscular route. Professional antigen-presenting cells of the skin comprise epidermal Langerhans cells (CD207/langerin(+)), dermal langerin(-) and dermal langerin(+) dendritic cells (DCs). In human skin, langerin(-) dermal DCs can be further subdivided on the basis of their reciprocal CD1a and CD14 expression. The relative contributions of these subsets to the generation of immunity or tolerance are still unclear. Langerhans cells in human skin seem to be specialized for induction of cytotoxic T lymphocytes. Likewise, mouse Langerhans cells are capable of cross-presentation and of protecting against experimental tumours. It is desirable to harness these properties for immunotherapy. A promising strategy to dramatically improve the outcome of vaccinations is 'antigen targeting'. Thereby, the vaccine is delivered directly and selectively to defined types of skin DCs. Targeting is achieved by means of coupling antigen to antibodies that recognize cell surface receptors on DCs. This approach is being widely explored. Little is known, however, about the events that take place in the skin and the DCs subsets involved therein. This topic will be discussed in this article.
2009
Flacher Vincent, Sparber Florian, Tripp Christoph H, Romani Nikolaus, Stoitzner Patrizia
Targeting of epidermal Langerhans cells with antigenic proteins: attempts to harness their properties for immunotherapy Article de journal
Dans: Cancer immunology, immunotherapy: CII, vol. 58, no. 7, p. 1137–1147, 2009, ISSN: 1432-0851.
Résumé | Liens | BibTeX | Étiquettes: Active, Animals, Antibodies, antibody, Antigen, Antigens, BLOOD, C-Type, cancer, CD, CD4-Positive T-Lymphocytes, CD4+ T cells, CD8-Positive T-Lymphocytes, CD8+ T cells, Dendritic Cells, DERMATOLOGY, DERMIS, Epidermis, Growth, Human, Humans, immune response, IMMUNE-RESPONSES, Immunization, Immunology, Immunotherapy, in situ, In vivo, Inbred BALB C, Inbred C57BL, INDUCTION, Langerhans Cells, LECTIN, Lectins, LYMPH, LYMPH NODE, Lymph Nodes, Major Histocompatibility Complex, Mannose-Binding Lectins, metabolism, methods, MHC class I, MHC class I molecules, Mice, Neoplasm, Neoplasms, OVALBUMIN, Patients, PROGENITORS, Protein, Proteins, RESPONSES, review, Skin, T CELLS, T-CELLS, Team-Mueller, therapy, tumor
@article{flacher_targeting_2009,
title = {Targeting of epidermal Langerhans cells with antigenic proteins: attempts to harness their properties for immunotherapy},
author = {Vincent Flacher and Florian Sparber and Christoph H Tripp and Nikolaus Romani and Patrizia Stoitzner},
doi = {10.1007/s00262-008-0563-9},
issn = {1432-0851},
year = {2009},
date = {2009-07-01},
journal = {Cancer immunology, immunotherapy: CII},
volume = {58},
number = {7},
pages = {1137--1147},
abstract = {Langerhans cells, a subset of skin dendritic cells in the epidermis, survey peripheral tissue for invading pathogens. In recent functional studies it was proven that Langerhans cells can present exogenous antigen not merely on major histocompatibility complexes (MHC)-class II molecules to CD4+ T cells, but also on MHC-class I molecules to CD8+ T cells. Immune responses against topically applied antigen could be measured in skin-draining lymph nodes. Skin barrier disruption or co-application of adjuvants was required for maximal induction of T cell responses. Cytotoxic T cells induced by topically applied antigen inhibited tumor growth in vivo, thus underlining the potential of Langerhans cells for immunotherapy. Here we review recent work and report novel observations relating to the potential use of Langerhans cells for immunotherapy. We investigated the potential of epicutaneous immunization strategies in which resident skin dendritic cells are loaded with tumor antigen in situ. This contrasts with current clinical approaches, where dendritic cells generated from progenitors in blood are loaded with tumor antigen ex vivo before injection into cancer patients. In the current study, we applied either fluorescently labeled protein antigen or targeting antibodies against DEC-205/CD205 and langerin/CD207 topically onto barrier-disrupted skin and examined antigen capture and transport by Langerhans cells. Protein antigen could be detected in Langerhans cells in situ, and they were the main skin dendritic cell subset transporting antigen during emigration from skin explants. Potent in vivo proliferative responses of CD4+ and CD8+ T cells were measured after epicutaneous immunization with low amounts of protein antigen. Targeting antibodies were mainly transported by langerin+ migratory dendritic cells of which the majority represented migratory Langerhans cells and a smaller subset the new langerin+ dermal dendritic cell population located in the upper dermis. The preferential capture of topically applied antigen by Langerhans cells and their ability to induce potent CD4+ and CD8+ T cell responses emphasizes their potential for epicutaneous immunization strategies.},
keywords = {Active, Animals, Antibodies, antibody, Antigen, Antigens, BLOOD, C-Type, cancer, CD, CD4-Positive T-Lymphocytes, CD4+ T cells, CD8-Positive T-Lymphocytes, CD8+ T cells, Dendritic Cells, DERMATOLOGY, DERMIS, Epidermis, Growth, Human, Humans, immune response, IMMUNE-RESPONSES, Immunization, Immunology, Immunotherapy, in situ, In vivo, Inbred BALB C, Inbred C57BL, INDUCTION, Langerhans Cells, LECTIN, Lectins, LYMPH, LYMPH NODE, Lymph Nodes, Major Histocompatibility Complex, Mannose-Binding Lectins, metabolism, methods, MHC class I, MHC class I molecules, Mice, Neoplasm, Neoplasms, OVALBUMIN, Patients, PROGENITORS, Protein, Proteins, RESPONSES, review, Skin, T CELLS, T-CELLS, Team-Mueller, therapy, tumor},
pubstate = {published},
tppubtype = {article}
}
Langerhans cells, a subset of skin dendritic cells in the epidermis, survey peripheral tissue for invading pathogens. In recent functional studies it was proven that Langerhans cells can present exogenous antigen not merely on major histocompatibility complexes (MHC)-class II molecules to CD4+ T cells, but also on MHC-class I molecules to CD8+ T cells. Immune responses against topically applied antigen could be measured in skin-draining lymph nodes. Skin barrier disruption or co-application of adjuvants was required for maximal induction of T cell responses. Cytotoxic T cells induced by topically applied antigen inhibited tumor growth in vivo, thus underlining the potential of Langerhans cells for immunotherapy. Here we review recent work and report novel observations relating to the potential use of Langerhans cells for immunotherapy. We investigated the potential of epicutaneous immunization strategies in which resident skin dendritic cells are loaded with tumor antigen in situ. This contrasts with current clinical approaches, where dendritic cells generated from progenitors in blood are loaded with tumor antigen ex vivo before injection into cancer patients. In the current study, we applied either fluorescently labeled protein antigen or targeting antibodies against DEC-205/CD205 and langerin/CD207 topically onto barrier-disrupted skin and examined antigen capture and transport by Langerhans cells. Protein antigen could be detected in Langerhans cells in situ, and they were the main skin dendritic cell subset transporting antigen during emigration from skin explants. Potent in vivo proliferative responses of CD4+ and CD8+ T cells were measured after epicutaneous immunization with low amounts of protein antigen. Targeting antibodies were mainly transported by langerin+ migratory dendritic cells of which the majority represented migratory Langerhans cells and a smaller subset the new langerin+ dermal dendritic cell population located in the upper dermis. The preferential capture of topically applied antigen by Langerhans cells and their ability to induce potent CD4+ and CD8+ T cell responses emphasizes their potential for epicutaneous immunization strategies.
2008
Flacher Vincent, Douillard Patrice, Aït-Yahia Smina, Stoitzner Patrizia, Clair-Moninot Valérie, Romani Nikolaus, Saeland Sem
Expression of langerin/CD207 reveals dendritic cell heterogeneity between inbred mouse strains Article de journal
Dans: Immunology, vol. 123, no. 3, p. 339–347, 2008, ISSN: 1365-2567.
Résumé | Liens | BibTeX | Étiquettes: Animals, Antigen, Antigens, C-Type, CD, Cell Surface, Dendritic Cells, DERMATOLOGY, Epidermis, Expression, Immunology, Immunophenotyping, Inbred Strains, inflammation, Langerhans Cells, LECTIN, Lectins, LYMPH, LYMPH NODE, Lymph Nodes, Lymphoid Tissue, Mannose-Binding Lectins, Maturation, metabolism, Mice, Minor Histocompatibility Antigens, mouse, Phenotype, Protein, Receptor, Receptors, Species Specificity, SPLEEN, SUBSETS, Surface, Team-Mueller
@article{flacher_expression_2008,
title = {Expression of langerin/CD207 reveals dendritic cell heterogeneity between inbred mouse strains},
author = {Vincent Flacher and Patrice Douillard and Smina Aït-Yahia and Patrizia Stoitzner and Valérie Clair-Moninot and Nikolaus Romani and Sem Saeland},
doi = {10.1111/j.1365-2567.2007.02785.x},
issn = {1365-2567},
year = {2008},
date = {2008-03-01},
journal = {Immunology},
volume = {123},
number = {3},
pages = {339--347},
abstract = {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.},
keywords = {Animals, Antigen, Antigens, C-Type, CD, Cell Surface, Dendritic Cells, DERMATOLOGY, Epidermis, Expression, Immunology, Immunophenotyping, Inbred Strains, inflammation, Langerhans Cells, LECTIN, Lectins, LYMPH, LYMPH NODE, Lymph Nodes, Lymphoid Tissue, Mannose-Binding Lectins, Maturation, metabolism, Mice, Minor Histocompatibility Antigens, mouse, Phenotype, Protein, Receptor, Receptors, Species Specificity, SPLEEN, SUBSETS, Surface, Team-Mueller},
pubstate = {published},
tppubtype = {article}
}
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.
2007
Mueller C G, Boix C, Kwan W H, Daussy C, Fournier E, Fridman W H, Molina T J
Critical role of monocytes to support normal B cell and diffuse large B cell lymphoma survival and proliferation Article de journal
Dans: Journal of Leukocyte Biology, vol. 82, no. 0741-5400 (Print), p. 567–575, 2007.
Résumé | BibTeX | Étiquettes: Activation, Antigen, Antigens, B CELL ACTIVATION, B CELLS, B-Cell, B-Cell Activation Factor Receptor, B-Lymphocytes, Biological, BLOOD, CC, CD14, CD40, Cell Division, Cell Proliferation, Cell Survival, Chemokine CCL5, chemokines, Coculture, cytology, Dendritic Cells, Differentiation, Diffuse, Enzyme-Linked Immunosorbent Assay, Flow Cytometry, Human, Humans, IL-2, Immunoenzyme Techniques, Interleukin-2, Large B-Cell, Lymph Nodes, LYMPHOMA, metabolism, monocyte, Monocytes, Myeloid Cells, pathology, Proliferation, Protein, Receptor, Reverse Transcriptase Polymerase Chain Reaction, survival, Team-Mueller, tumor, Tumor Markers
@article{mueller_critical_2007,
title = {Critical role of monocytes to support normal B cell and diffuse large B cell lymphoma survival and proliferation},
author = {C G Mueller and C Boix and W H Kwan and C Daussy and E Fournier and W H Fridman and T J Molina},
year = {2007},
date = {2007-01-01},
journal = {Journal of Leukocyte Biology},
volume = {82},
number = {0741-5400 (Print)},
pages = {567--575},
abstract = {Large B cell lymphomas can comprise numerous CD14+ cells in the tumor stroma, which raises the question of whether monocytes can support B cell survival and proliferation. We show that the coculture of monocytes with B cells from peripheral blood or from diffuse large B cell lymphoma enabled prolonged B cell survival. Under these conditions, diffuse large lymphoma B cells proliferated, and addition of B cell-activating factor of the TNF family (BAFF) and IL-2 enhanced cell division. Monocytes and dendritic cells (DC) had similar antiapoptotic activity on healthy B cells but displayed differences with respect to B cell proliferation. Monocytes and cord blood-derived CD14+ cells promoted B cell proliferation in the presence of an anti-CD40 stimulus, whereas DC supported B cell proliferation when activated through the BCR. DC and CD14+ cells were able to induce plasmocyte differentiation. When B cells were activated via the BCR or CD40, they released the leukocyte attractant CCL5, and this chemokine is one of the main chemokines expressed in diffuse large B cell lymphoma. The data support the notion that large B cell lymphoma recruit monocytes via CCL5 to support B cell survival and proliferation},
keywords = {Activation, Antigen, Antigens, B CELL ACTIVATION, B CELLS, B-Cell, B-Cell Activation Factor Receptor, B-Lymphocytes, Biological, BLOOD, CC, CD14, CD40, Cell Division, Cell Proliferation, Cell Survival, Chemokine CCL5, chemokines, Coculture, cytology, Dendritic Cells, Differentiation, Diffuse, Enzyme-Linked Immunosorbent Assay, Flow Cytometry, Human, Humans, IL-2, Immunoenzyme Techniques, Interleukin-2, Large B-Cell, Lymph Nodes, LYMPHOMA, metabolism, monocyte, Monocytes, Myeloid Cells, pathology, Proliferation, Protein, Receptor, Reverse Transcriptase Polymerase Chain Reaction, survival, Team-Mueller, tumor, Tumor Markers},
pubstate = {published},
tppubtype = {article}
}
Large B cell lymphomas can comprise numerous CD14+ cells in the tumor stroma, which raises the question of whether monocytes can support B cell survival and proliferation. We show that the coculture of monocytes with B cells from peripheral blood or from diffuse large B cell lymphoma enabled prolonged B cell survival. Under these conditions, diffuse large lymphoma B cells proliferated, and addition of B cell-activating factor of the TNF family (BAFF) and IL-2 enhanced cell division. Monocytes and dendritic cells (DC) had similar antiapoptotic activity on healthy B cells but displayed differences with respect to B cell proliferation. Monocytes and cord blood-derived CD14+ cells promoted B cell proliferation in the presence of an anti-CD40 stimulus, whereas DC supported B cell proliferation when activated through the BCR. DC and CD14+ cells were able to induce plasmocyte differentiation. When B cells were activated via the BCR or CD40, they released the leukocyte attractant CCL5, and this chemokine is one of the main chemokines expressed in diffuse large B cell lymphoma. The data support the notion that large B cell lymphoma recruit monocytes via CCL5 to support B cell survival and proliferation
2006
Marmey B, Boix C, Barbaroux J B, Dieu-Nosjean M C, Diebold J, Audouin J, Fridman W H, Mueller C G, Molina T J
CD14 and CD169 expression in human lymph nodes and spleen: specific expansion of CD14+C Article de journal
Dans: Hum.Pathol., vol. 37, no. 0046-8177 (Print), p. 68–77, 2006.
Résumé | BibTeX | Étiquettes: Adhesion, Antigen, Antigens, B-Cell, Biological, CD14, Cell Differentiation, CELL SEPARATION, Dendritic Cells, Differentiation, Diffuse, Direct, Expression, Flow Cytometry, Fluorescent Antibody Technique, Gene, GLYCOPROTEIN, Glycoproteins, granulocyte/macrophage-colony, Human, Humans, Immunoenzyme Techniques, Immunohistochemistry, Immunologic, Large B-Cell, leukemia, LYMPH, LYMPH NODE, Lymph Nodes, Lymphadenitis, Lymphoid Tissue, LYMPHOMA, Macrophage, Macrophages, Membrane, Membrane Glycoproteins, metabolism, Monocytes, pathology, Phagocytosis, Receptor, Receptors, SIALOADHESIN, SPLEEN, Team-Mueller, tumor, Tumor Markers
@article{marmey_cd14_2006,
title = {CD14 and CD169 expression in human lymph nodes and spleen: specific expansion of CD14+C},
author = {B Marmey and C Boix and J B Barbaroux and M C Dieu-Nosjean and J Diebold and J Audouin and W H Fridman and C G Mueller and T J Molina},
year = {2006},
date = {2006-01-01},
journal = {Hum.Pathol.},
volume = {37},
number = {0046-8177 (Print)},
pages = {68--77},
abstract = {The mononuclear phagocyte system of human lymphoid tissue comprises macrophages and dendritic cells (DCs). The heterogeneity of the non-DC mononuclear phagocyte population in human lymphoid tissue has been little addressed. Here, we studied the expression of 2 monocyte-derived markers, CD14 and CD169 (sialoadhesin), in reactive human lymphoid tissue as well as in a series of 51 B-cell lymphomas by immunohistochemistry on paraffin-embedded tissue. We confirmed that lymph node sinusoidal monocyte-derived cells were the only population staining for CD169. Although most sinusoidal histiocytes also expressed CD14, monocyte-derived cells with phagocytosis such as erythrophagocytosis, anthracosis, or tingible bodies macrophage lacked CD14 and CD169. Among B-cell lymphomas, splenic marginal zone lymphoma was the only one associated with an expansion of the CD14(+)CD169(+) cells in the cords. With respect to nodal B-cell lymphomas, CD14(+) cells were rare among B-chronic lymphocytic leukemia, follicular lymphoma (FL), mantle cell lymphoma (MCL). However, strikingly, we found a strong expansion of CD14(+)CD169(-) cells in numerous diffuse large B-cell lymphomas (DLBCLs), except in cases associated with numerous mitoses, apoptotic bodies, and tingible bodies macrophages. When cultivated in granulocyte/macrophage colony stimulating factor/interleukin 4, DLBCL purified CD14(+) cells differentiate into plasmacytoid cells, expressing DC-specific intercellular adhesion molecule 3-grabbing nonintegrin, suggesting dendritic cell differentiation potential. Our observation fits well with the lymph node and host response cluster signatures described in the gene profiling signatures of DLBCL. However, the role of this CD14(+) population that may constitute a microenvironment-related marker of this subgroup of DLBCL remains to be determined},
keywords = {Adhesion, Antigen, Antigens, B-Cell, Biological, CD14, Cell Differentiation, CELL SEPARATION, Dendritic Cells, Differentiation, Diffuse, Direct, Expression, Flow Cytometry, Fluorescent Antibody Technique, Gene, GLYCOPROTEIN, Glycoproteins, granulocyte/macrophage-colony, Human, Humans, Immunoenzyme Techniques, Immunohistochemistry, Immunologic, Large B-Cell, leukemia, LYMPH, LYMPH NODE, Lymph Nodes, Lymphadenitis, Lymphoid Tissue, LYMPHOMA, Macrophage, Macrophages, Membrane, Membrane Glycoproteins, metabolism, Monocytes, pathology, Phagocytosis, Receptor, Receptors, SIALOADHESIN, SPLEEN, Team-Mueller, tumor, Tumor Markers},
pubstate = {published},
tppubtype = {article}
}
The mononuclear phagocyte system of human lymphoid tissue comprises macrophages and dendritic cells (DCs). The heterogeneity of the non-DC mononuclear phagocyte population in human lymphoid tissue has been little addressed. Here, we studied the expression of 2 monocyte-derived markers, CD14 and CD169 (sialoadhesin), in reactive human lymphoid tissue as well as in a series of 51 B-cell lymphomas by immunohistochemistry on paraffin-embedded tissue. We confirmed that lymph node sinusoidal monocyte-derived cells were the only population staining for CD169. Although most sinusoidal histiocytes also expressed CD14, monocyte-derived cells with phagocytosis such as erythrophagocytosis, anthracosis, or tingible bodies macrophage lacked CD14 and CD169. Among B-cell lymphomas, splenic marginal zone lymphoma was the only one associated with an expansion of the CD14(+)CD169(+) cells in the cords. With respect to nodal B-cell lymphomas, CD14(+) cells were rare among B-chronic lymphocytic leukemia, follicular lymphoma (FL), mantle cell lymphoma (MCL). However, strikingly, we found a strong expansion of CD14(+)CD169(-) cells in numerous diffuse large B-cell lymphomas (DLBCLs), except in cases associated with numerous mitoses, apoptotic bodies, and tingible bodies macrophages. When cultivated in granulocyte/macrophage colony stimulating factor/interleukin 4, DLBCL purified CD14(+) cells differentiate into plasmacytoid cells, expressing DC-specific intercellular adhesion molecule 3-grabbing nonintegrin, suggesting dendritic cell differentiation potential. Our observation fits well with the lymph node and host response cluster signatures described in the gene profiling signatures of DLBCL. However, the role of this CD14(+) population that may constitute a microenvironment-related marker of this subgroup of DLBCL remains to be determined
2005
Dumortier Hélène, van Mierlo Geertje J D, Egan Deirdre, van Ewijk Willem, Toes René E M, Offringa Rienk, Melief Cornelis J M
Dans: Journal of Immunology (Baltimore, Md.: 1950), vol. 175, no. 2, p. 855–863, 2005, ISSN: 0022-1767.
Résumé | Liens | BibTeX | Étiquettes: Adenovirus E1A Proteins, Animals, Antigen, Antigen Presentation, CD8-Positive T-Lymphocytes, Cell Differentiation, Cell Line, Cell Movement, Clonal Deletion, Cytotoxic, Cytotoxicity, Dendritic Cells, Down-Regulation, Dumortier, Epitopes, Female, I2CT, Immunologic, Immunologic Memory, Inbred C57BL, Lipopolysaccharides, Lymphocyte Activation, Mice, Myeloid Cells, Receptors, Regulatory, T-Cell, T-Lymphocyte, T-Lymphocytes, Team-Dumortier, transgenic
@article{dumortier_antigen_2005,
title = {Antigen presentation by an immature myeloid dendritic cell line does not cause CTL deletion in vivo, but generates CD8+ central memory-like Ŧ cells that can be rescued for full effector function},
author = {Hélène Dumortier and Geertje J D van Mierlo and Deirdre Egan and Willem van Ewijk and René E M Toes and Rienk Offringa and Cornelis J M Melief},
doi = {10.4049/jimmunol.175.2.855},
issn = {0022-1767},
year = {2005},
date = {2005-01-01},
journal = {Journal of Immunology (Baltimore, Md.: 1950)},
volume = {175},
number = {2},
pages = {855--863},
abstract = {Immature dendritic cells (DC), in contrast to their mature counterparts, are incapable of mobilizing a CD8+ CTL response, and, instead, have been reported to induce CTL tolerance. We directly addressed the impact of immature vs mature DC on CTL responses by infusing adenovirus peptide-loaded DC (of the D1 cell line) into mice that had received adenovirus-specific naive TCR-transgenic CD8+ T cells. Whereas i.v. injection of mature DC triggered vigorous CTL expansion, immature DC elicited little proliferation involving only a minority of the TCR-transgenic CTL. Even though the latter CTL developed effector functions, including cytolytic activity and proinflammatory cytokine secretion, these cells differed significantly from CTL primed by mature DC in that they did not exhibit down-regulation of CD62L and CCR7, receptors involved in trapping of T cells in the lymphoid organs. Interestingly, adoptive transfer of CTL effector cells harvested after priming by either mature or immature DC into naive recipient mice, followed by exposure to adenovirus, yielded quantitatively and qualitatively indistinguishable CTL memory responses. Therefore, in vivo priming of naive CD8+ T cells by immature DC, although failing to induce a full-blown, systemic CTL response, resulted in the formation of central memory-like T cells that were able to expand and produce IFN-gamma upon secondary antigenic stimulation.},
keywords = {Adenovirus E1A Proteins, Animals, Antigen, Antigen Presentation, CD8-Positive T-Lymphocytes, Cell Differentiation, Cell Line, Cell Movement, Clonal Deletion, Cytotoxic, Cytotoxicity, Dendritic Cells, Down-Regulation, Dumortier, Epitopes, Female, I2CT, Immunologic, Immunologic Memory, Inbred C57BL, Lipopolysaccharides, Lymphocyte Activation, Mice, Myeloid Cells, Receptors, Regulatory, T-Cell, T-Lymphocyte, T-Lymphocytes, Team-Dumortier, transgenic},
pubstate = {published},
tppubtype = {article}
}
Immature dendritic cells (DC), in contrast to their mature counterparts, are incapable of mobilizing a CD8+ CTL response, and, instead, have been reported to induce CTL tolerance. We directly addressed the impact of immature vs mature DC on CTL responses by infusing adenovirus peptide-loaded DC (of the D1 cell line) into mice that had received adenovirus-specific naive TCR-transgenic CD8+ T cells. Whereas i.v. injection of mature DC triggered vigorous CTL expansion, immature DC elicited little proliferation involving only a minority of the TCR-transgenic CTL. Even though the latter CTL developed effector functions, including cytolytic activity and proinflammatory cytokine secretion, these cells differed significantly from CTL primed by mature DC in that they did not exhibit down-regulation of CD62L and CCR7, receptors involved in trapping of T cells in the lymphoid organs. Interestingly, adoptive transfer of CTL effector cells harvested after priming by either mature or immature DC into naive recipient mice, followed by exposure to adenovirus, yielded quantitatively and qualitatively indistinguishable CTL memory responses. Therefore, in vivo priming of naive CD8+ T cells by immature DC, although failing to induce a full-blown, systemic CTL response, resulted in the formation of central memory-like T cells that were able to expand and produce IFN-gamma upon secondary antigenic stimulation.
2002
Cremer I, Dieu-Nosjean M C, Mar�chal S, Dezutter-Dambuyant C, Goddard S, Adams D, Winter N, Menetrier-Caux C, Saut�s-Fridman C, Fridman W H, Mueller C G F
Long-lived immature dendritic cells mediated by TRANCE-RANK interaction Article de journal
Dans: Blood, vol. 100, no. 10, p. 3646–3655, 2002.
Résumé | BibTeX | Étiquettes: Activation, Antigen, CD40, CD40 Ligand, CHEMOTAXIS, Cytokines, Dendritic Cells, Epidermis, Expression, Homeostasis, Human, IMMATURE, l, ligand, lipopolysaccharide, Longevity, LPS, LYMPH, LYMPH NODE, Lymph Nodes, M-CSF, Macrophage, Macrophages, Maturation, naive, Necrosis, NF-kappaB, PROGENITOR CELLS, rank, Receptor, survival, T CELL ACTIVATION, T CELLS, Team-Mueller, TRANCE, tumor, viability
@article{cremer_long-lived_2002,
title = {Long-lived immature dendritic cells mediated by TRANCE-RANK interaction},
author = {I Cremer and M C Dieu-Nosjean and S Mar�chal and C Dezutter-Dambuyant and S Goddard and D Adams and N Winter and C Menetrier-Caux and C Saut�s-Fridman and W H Fridman and C G F Mueller},
year = {2002},
date = {2002-01-01},
journal = {Blood},
volume = {100},
number = {10},
pages = {3646--3655},
abstract = {Immature dendritic cells (DCs) reside in Interstitial tissues (Int-DC) or in the epidermis, where they capture antigen and, thereafter, mature and migrate to draining lymph nodes (LNs), where they present processed antigen to T cells. We have Identified Int-DCs that express both TRANCE (tumor necrosis factor-related activation-induced cytokine) and RANK (receptor activator of NF-kappaB) and have generated these cells from CD34(+) human progenitor cells using macrophage colony-stimulating factor (M-CSF). These CD34(+)-derived Int-DCs, which are related to macrophages, are long-lived, but addition of soluble RANK leads to significant reduction of cell viability and BcI-2 expression. This suggests that constitutive TRANCE-RANK interaction is responsible for CD34(+)-derived Int-DC longevity. Conversely, CD1a(+) DCs express only RANK and are short-lived. However, they can be rescued from cell death either by recombinant soluble TRANCE or by CD34(+)-derived Int-DCs. CD34(+)-derived Int-DCs mature in response to lipopolysaccharide (LPS) plus CD40 ligand (L) and become capable of CCL21/CCL19-mediated chemotaxis and naive T-cell activation. Upon maturation, they lose TRANCE, making them, like CD1a(+) DCs, dependent on exogenous TRANCE for survival. These findings provide evidence that TRANCE and RANK play important roles in the homeostasis of DCs. (C) 2002 by The American Society of Hematology},
keywords = {Activation, Antigen, CD40, CD40 Ligand, CHEMOTAXIS, Cytokines, Dendritic Cells, Epidermis, Expression, Homeostasis, Human, IMMATURE, l, ligand, lipopolysaccharide, Longevity, LPS, LYMPH, LYMPH NODE, Lymph Nodes, M-CSF, Macrophage, Macrophages, Maturation, naive, Necrosis, NF-kappaB, PROGENITOR CELLS, rank, Receptor, survival, T CELL ACTIVATION, T CELLS, Team-Mueller, TRANCE, tumor, viability},
pubstate = {published},
tppubtype = {article}
}
Immature dendritic cells (DCs) reside in Interstitial tissues (Int-DC) or in the epidermis, where they capture antigen and, thereafter, mature and migrate to draining lymph nodes (LNs), where they present processed antigen to T cells. We have Identified Int-DCs that express both TRANCE (tumor necrosis factor-related activation-induced cytokine) and RANK (receptor activator of NF-kappaB) and have generated these cells from CD34(+) human progenitor cells using macrophage colony-stimulating factor (M-CSF). These CD34(+)-derived Int-DCs, which are related to macrophages, are long-lived, but addition of soluble RANK leads to significant reduction of cell viability and BcI-2 expression. This suggests that constitutive TRANCE-RANK interaction is responsible for CD34(+)-derived Int-DC longevity. Conversely, CD1a(+) DCs express only RANK and are short-lived. However, they can be rescued from cell death either by recombinant soluble TRANCE or by CD34(+)-derived Int-DCs. CD34(+)-derived Int-DCs mature in response to lipopolysaccharide (LPS) plus CD40 ligand (L) and become capable of CCL21/CCL19-mediated chemotaxis and naive T-cell activation. Upon maturation, they lose TRANCE, making them, like CD1a(+) DCs, dependent on exogenous TRANCE for survival. These findings provide evidence that TRANCE and RANK play important roles in the homeostasis of DCs. (C) 2002 by The American Society of Hematology
2000
Casimir J R, Iterbeke K, Nest W Van Den, Trescol-Biémont M C, Dumortier H, Muller S, Gerlier D, Rabourdin-Combe C, Tourwé D, Paris J
Conformational restriction of the Tyr53 side-chain in the decapeptide HE Article de journal
Dans: The Journal of Peptide Research: Official Journal of the American Peptide Society, vol. 56, no. 6, p. 398–408, 2000, ISSN: 1397-002X.
Résumé | Liens | BibTeX | Étiquettes: Amino Acid Sequence, Animals, Antigen, Antigen-Presenting Cells, B-Lymphocytes, Chemical, Chickens, Dumortier, I2CT, Major Histocompatibility Complex, Mice, Models, Molecular Sequence Data, Muramidase, Peptide Biosynthesis, Peptides, Phenylalanine, Protein Binding, Protein Conformation, Receptors, T-Cell, Team-Dumortier, Temperature, Tyrosine
@article{casimir_conformational_2000,
title = {Conformational restriction of the Tyr53 side-chain in the decapeptide HE},
author = {J R Casimir and K Iterbeke and W Van Den Nest and M C Trescol-Biémont and H Dumortier and S Muller and D Gerlier and C Rabourdin-Combe and D Tourwé and J Paris},
doi = {10.1034/j.1399-3011.2000.00777.x},
issn = {1397-002X},
year = {2000},
date = {2000-12-01},
journal = {The Journal of Peptide Research: Official Journal of the American Peptide Society},
volume = {56},
number = {6},
pages = {398--408},
abstract = {A series of conformationally restricted analogs of the hen egg lysozyme (HEL) decapeptide 52-61 in which the conformationally flexible Tyr53 residue was replaced by several more constrained tyrosine and phenylalanine analogs was prepared. Among these tyrosine and phenylalanine analogs were 1,2,3,4-tetrahydro-7-hydroxyisoquinoline-3-carboxylic acid (Htc), 1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid (Tic), 4-amino- 1,2,4,5-tetrahydro-8-hydroxy-2-benzazepine-3-one (Hba), 4-amino-1,2,4,5-tetrahydro-2-benzazepine-3-one (Aba), 2-amino-6-hydroxytetralin-2-carboxylic acid (Hat) and 2-amino-5-hydroxyindan-2-carboxylic acid (Hai) in which the rotations around Calpha-Cbeta and Cbeta-Cgamma were restricted because of cyclization of the side-chain to the backbone. Synthesis of Pht-Hba-Gly-OH using a modification of the Flynn and de Laszlo procedure is described. Analogs of beta-methyltyrosine (beta-MeTyr) in which the side-chains were biased to particular side-chain torsional angles because of substitution at the beta-hydrogens were also prepared. These analogs of HEL[52-61] peptide were tested for their ability to bind to the major histocompatibility complex class II I-Ak molecule and to be recognized in this context by two T-cell hybridomas, specific for the parent peptide HEL[52-61]. The data showed that the conformation and also the configuration of the Tyr53 residue influenced both the binding of the peptide to I-Ak and the recognition of the peptide/I-Ak complex by a T-cell receptor.},
keywords = {Amino Acid Sequence, Animals, Antigen, Antigen-Presenting Cells, B-Lymphocytes, Chemical, Chickens, Dumortier, I2CT, Major Histocompatibility Complex, Mice, Models, Molecular Sequence Data, Muramidase, Peptide Biosynthesis, Peptides, Phenylalanine, Protein Binding, Protein Conformation, Receptors, T-Cell, Team-Dumortier, Temperature, Tyrosine},
pubstate = {published},
tppubtype = {article}
}
A series of conformationally restricted analogs of the hen egg lysozyme (HEL) decapeptide 52-61 in which the conformationally flexible Tyr53 residue was replaced by several more constrained tyrosine and phenylalanine analogs was prepared. Among these tyrosine and phenylalanine analogs were 1,2,3,4-tetrahydro-7-hydroxyisoquinoline-3-carboxylic acid (Htc), 1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid (Tic), 4-amino- 1,2,4,5-tetrahydro-8-hydroxy-2-benzazepine-3-one (Hba), 4-amino-1,2,4,5-tetrahydro-2-benzazepine-3-one (Aba), 2-amino-6-hydroxytetralin-2-carboxylic acid (Hat) and 2-amino-5-hydroxyindan-2-carboxylic acid (Hai) in which the rotations around Calpha-Cbeta and Cbeta-Cgamma were restricted because of cyclization of the side-chain to the backbone. Synthesis of Pht-Hba-Gly-OH using a modification of the Flynn and de Laszlo procedure is described. Analogs of beta-methyltyrosine (beta-MeTyr) in which the side-chains were biased to particular side-chain torsional angles because of substitution at the beta-hydrogens were also prepared. These analogs of HEL[52-61] peptide were tested for their ability to bind to the major histocompatibility complex class II I-Ak molecule and to be recognized in this context by two T-cell hybridomas, specific for the parent peptide HEL[52-61]. The data showed that the conformation and also the configuration of the Tyr53 residue influenced both the binding of the peptide to I-Ak and the recognition of the peptide/I-Ak complex by a T-cell receptor.
1997
Mézière C, Viguier M, Dumortier H, Lo-Man R, Leclerc C, Guillet J G, Briand J P, Muller S
In vivo Ŧ helper cell response to retro-inverso peptidomimetics Article de journal
Dans: Journal of Immunology (Baltimore, Md.: 1950), vol. 159, no. 7, p. 3230–3237, 1997, ISSN: 0022-1767.
Résumé | BibTeX | Étiquettes: Amino Acid Sequence, Animals, Antibodies, Antigen, Capsid, Capsid Proteins, Dumortier, Female, Helper-Inducer, Histocompatibility Antigens Class II, I2CT, Immunoglobulin Allotypes, Immunoglobulin G, Inbred BALB C, Injections, Intraperitoneal, Lymphocyte Activation, Mice, Molecular Sequence Data, Peptide Fragments, Poliovirus, Protein Binding, Receptors, T-Cell, T-Lymphocytes, Team-Dumortier, Viral
@article{meziere_vivo_1997,
title = {In vivo Ŧ helper cell response to retro-inverso peptidomimetics},
author = {C Mézière and M Viguier and H Dumortier and R Lo-Man and C Leclerc and J G Guillet and J P Briand and S Muller},
issn = {0022-1767},
year = {1997},
date = {1997-10-01},
journal = {Journal of Immunology (Baltimore, Md.: 1950)},
volume = {159},