Your search keyword '"Mary J van Helden"' showing total 20 results

1. 1160 Phosphonate-antibody-drug conjugates: a novel immunostimulatory class of ADCs driving inside-out activation of Vγ9Vδ2 T cells leading to selective tumor cell killing

Author

Lilian Driessen-Engels, Roel J Arends, Désirée Damming, Wendela A Kappers, Gijs Verheijden, Mary J van Helden, Ronald C Elgersma, Daphne WJ van Kuppeveld, Dennis Waalboer, Ellen WH Santegoeds-Lenssen, Inge Leenders, Karin de Laat-Arts, Marc CBC Paradé, Menno Winkel, Anja Scholzen, Daniëlle EJW van Wijk, Diels van den Dobbelsteen, Genny Filiciotto, Laura Assink, Myrthe Rouwette, Panagiota I Spantidea, Timo K van den Berg, Wim HA Dokter, and Miranda MC van der Lee

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Published

2023

2. BYON4228 is a pan-allelic antagonistic SIRPα antibody that potentiates destruction of antibody-opsonized tumor cells and lacks binding to SIRPγ on T cells

Author

Timo K van den Berg, Hugo Olsman, Hanke L Matlung, Katka Franke, Imke Lodewijks, Lilian Driessen-Engels, Mary J van Helden, Seline A Zwarthoff, Roel J Arends, Inge M J Reinieren-Beeren, Marc C B C Paradé, Karin de Laat-Arts, Désirée Damming, Ellen W H Santegoeds-Lenssen, Daphne W J van Kuppeveld, Ellen Mattaar-Hepp, Marloes E M Stokman, Benny de Wit, Dirk H R F Glaudemans, Daniëlle E J W van Wijk, Lonnie Joosten-Stoffels, Jan Schouten, Paul J Boersema, Monique van der Vleuten, Jorien W H Sanderink, Wendela A Kappers, Diels van den Dobbelsteen, Marco Timmers, Ruud Ubink, Gerard J A Rouwendal, Gijs Verheijden, Miranda M C van der Lee, and Wim H A Dokter

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Background Preclinical studies have firmly established the CD47-signal-regulatory protein (SIRP)α axis as a myeloid immune checkpoint in cancer, and this is corroborated by available evidence from the first clinical studies with CD47 blockers. However, CD47 is ubiquitously expressed and mediates functional interactions with other ligands as well, and therefore targeting of the primarily myeloid cell-restricted inhibitory immunoreceptor SIRPα may represent a better strategy.Method We generated BYON4228, a novel SIRPα-directed antibody. An extensive preclinical characterization was performed, including direct comparisons to previously reported anti-SIRPα antibodies.Results BYON4228 is an antibody directed against SIRPα that recognizes both allelic variants of SIRPα in the human population, thereby maximizing its potential clinical applicability. Notably, BYON4228 does not recognize the closely related T-cell expressed SIRPγ that mediates interactions with CD47 as well, which are known to be instrumental in T-cell extravasation and activation. BYON4228 binds to the N-terminal Ig-like domain of SIRPα and its epitope largely overlaps with the CD47-binding site. BYON4228 blocks binding of CD47 to SIRPα and inhibits signaling through the CD47-SIRPα axis. Functional studies show that BYON4228 potentiates macrophage-mediated and neutrophil-mediated killing of hematologic and solid cancer cells in vitro in the presence of a variety of tumor-targeting antibodies, including trastuzumab, rituximab, daratumumab and cetuximab. The silenced Fc region of BYON4228 precludes immune cell-mediated elimination of SIRPα-positive myeloid cells, implying anticipated preservation of myeloid immune effector cells in patients. The unique profile of BYON4228 clearly distinguishes it from previously reported antibodies representative of agents in clinical development, which either lack recognition of one of the two SIRPα polymorphic variants (HEFLB), or cross-react with SIRPγ and inhibit CD47-SIRPγ interactions (SIRPAB-11-K322A, 1H9), and/or have functional Fc regions thereby displaying myeloid cell depletion activity (SIRPAB-11-K322A). In vivo, BYON4228 increases the antitumor activity of rituximab in a B-cell Raji xenograft model in human SIRPαBIT transgenic mice. Finally, BYON4228 shows a favorable safety profile in cynomolgus monkeys.Conclusions Collectively, this defines BYON4228 as a preclinically highly differentiating pan-allelic SIRPα antibody without T-cell SIRPγ recognition that promotes the destruction of antibody-opsonized cancer cells. Clinical studies are planned to start in 2023.

Published

2023

3. Role of NKp46+ natural killer cells in house dust mite‐driven asthma

Author

Eline Haspeslagh, Mary J van Helden, Kim Deswarte, Sofie De Prijck, Justine van Moorleghem, Louis Boon, Hamida Hammad, Eric Vivier, and Bart N Lambrecht

Subjects

allergic asthma, house dust mite, NK cells, NKG2D, NKp46, Medicine (General), R5-920, Genetics, QH426-470

Abstract

Abstract House dust mite (HDM)‐allergic asthma is driven by T helper 2 (Th2) lymphocytes, but also innate immune cells control key aspects of the disease. The precise function of innate natural killer (NK) cells during the initiation and propagation of asthma has been very confusing, in part because different, not entirely specific, strategies were used to target these cells. We show that HDM inhalation rapidly led to the accumulation of NK cells in the lung‐draining lymph nodes and of activated CD69+ NK cells in the bronchoalveolar lumen. However, genetically engineered Ncr1‐DTA or Ncr1‐DTR mice that constitutively or temporarily lack NK cells, still developed all key features of acute or chronic HDM‐driven asthma, such as bronchial hyperreactivity, Th2 cytokine production, eosinophilia, mucus overproduction, and Th2‐dependent immunoglobulin serum titers. The same results were obtained by administration of conventional NK1.1 or asialo‐GM1 NK cell‐depleting antibodies, antibody‐mediated blocking of the NKG2D receptor, or genetic NKG2D deficiency. Thus, although NK cells accumulate in allergen‐challenged lungs, our findings comprehensively demonstrate that these cells are not required for HDM‐driven asthma in the mouse.

Published

2018

4. Epitope mapping and kinetics of CD4 T cell immunity to pneumonia virus of mice in the C57BL/6 strain

Author

Lana Vandersarren, Cedric Bosteels, Manon Vanheerswynghels, James J. Moon, Andrew J. Easton, Gert Van Isterdael, Sophie Janssens, Bart N. Lambrecht, and Mary J. van Helden

Subjects

Medicine, Science

Abstract

Abstract Pneumonia virus of mice (PVM) infection has been widely used as a rodent model to study the closely related human respiratory syncytial virus (hRSV). While T cells are indispensable for viral clearance, they also contribute to immunopathology. To gain more insight into mechanistic details, novel tools are needed that allow to study virus-specific T cells in C57BL/6 mice as the majority of transgenic mice are only available on this background. While PVM-specific CD8 T cell epitopes were recently described, so far no PVM-specific CD4 T cell epitopes have been identified within the C57BL/6 strain. Therefore, we set out to map H2-IAb-restricted epitopes along the PVM proteome. By means of in silico prediction and subsequent functional validation, we were able to identify a MHCII-restricted CD4 T cell epitope, corresponding to amino acids 37–47 in the PVM matrix protein (M37–47). Using this newly identified MHCII-restricted M37–47 epitope and a previously described MHCI-restricted N339–347 epitope, we generated peptide-loaded MHCII and MHCI tetramers and characterized the dynamics of virus-specific CD4 and CD8 T cell responses in vivo. The findings of this study can provide a basis for detailed investigation of T cell-mediated immune responses to PVM in a variety of genetically modified C57BL/6 mice.

Published

2017

5. BYON4228 is a pan-allelic antagonistic SIRPα antibody that potentiates destruction of antibody-opsonized tumor cells and lacks binding to SIRPγon T cells

Author

Mary J van Helden, Seline A Zwarthoff, Roel J Arends, Inge M J Reinieren-Beeren, Marc C B C Paradé, Lilian Driessen-Engels, Karin de Laat-Arts, Désirée Damming, Ellen W H Santegoeds-Lenssen, Daphne W J van Kuppeveld, Imke Lodewijks, Hugo Olsman, Hanke L Matlung, Katka Franke, Ellen Mattaar-Hepp, Marloes E M Stokman, Benny de Wit, Dirk H R F Glaudemans, Daniëlle E J W van Wijk, Lonnie Joosten-Stoffels, Jan Schouten, Paul J Boersema, Monique van der Vleuten, Jorien W H Sanderink, Wendela A Kappers, Diels van den Dobbelsteen, Marco Timmers, Ruud Ubink, Gerard J A Rouwendal, Gijs Verheijden, Miranda M C van der Lee, Wim H A Dokter, and Timo K van den Berg

Subjects

Pharmacology, Cancer Research, Oncology, Immunology, Molecular Medicine, Immunology and Allergy

Abstract

BackgroundPreclinical studies have firmly established the CD47-signal-regulatory protein (SIRP)α axis as a myeloid immune checkpoint in cancer, and this is corroborated by available evidence from the first clinical studies with CD47 blockers. However, CD47 is ubiquitously expressed and mediates functional interactions with other ligands as well, and therefore targeting of the primarily myeloid cell-restricted inhibitory immunoreceptor SIRPα may represent a better strategy.MethodWe generated BYON4228, a novel SIRPα-directed antibody. An extensive preclinical characterization was performed, including direct comparisons to previously reported anti-SIRPα antibodies.ResultsBYON4228 is an antibody directed against SIRPα that recognizes both allelic variants of SIRPα in the human population, thereby maximizing its potential clinical applicability. Notably, BYON4228 does not recognize the closely related T-cell expressed SIRPγ that mediates interactions with CD47 as well, which are known to be instrumental in T-cell extravasation and activation. BYON4228 binds to the N-terminal Ig-like domain of SIRPα and its epitope largely overlaps with the CD47-binding site. BYON4228 blocks binding of CD47 to SIRPα and inhibits signaling through the CD47-SIRPα axis. Functional studies show that BYON4228 potentiates macrophage-mediated and neutrophil-mediated killing of hematologic and solid cancer cells in vitro in the presence of a variety of tumor-targeting antibodies, including trastuzumab, rituximab, daratumumab and cetuximab. The silenced Fc region of BYON4228 precludes immune cell-mediated elimination of SIRPα-positive myeloid cells, implying anticipated preservation of myeloid immune effector cells in patients. The unique profile of BYON4228 clearly distinguishes it from previously reported antibodies representative of agents in clinical development, which either lack recognition of one of the two SIRPα polymorphic variants (HEFLB), or cross-react with SIRPγ and inhibit CD47-SIRPγ interactions (SIRPAB-11-K322A, 1H9), and/or have functional Fc regions thereby displaying myeloid cell depletion activity (SIRPAB-11-K322A). In vivo, BYON4228 increases the antitumor activity of rituximab in a B-cell Raji xenograft model in human SIRPαBITtransgenic mice. Finally, BYON4228 shows a favorable safety profile in cynomolgus monkeys.ConclusionsCollectively, this defines BYON4228 as a preclinically highly differentiating pan-allelic SIRPα antibody without T-cell SIRPγ recognition that promotes the destruction of antibody-opsonized cancer cells. Clinical studies are planned to start in 2023.

Published

2023

6. Mouse Models of Asthma

Author

Bart N. Lambrecht, Nincy Debeuf, Mary J. van Helden, Eline Haspeslagh, and Hamida Hammad

Subjects

0301 basic medicine, Ovalbumin, Immunoglobulin E, medicine.disease_cause, Mice, 03 medical and health sciences, Th2 Cells, Allergen, immune system diseases, Eosinophilia, medicine, Animals, Humans, Sensitization, Asthma, House dust mite, Metaplasia, biology, medicine.diagnostic_test, business.industry, Pyroglyphidae, General Medicine, respiratory system, Flow Cytometry, medicine.disease, biology.organism_classification, respiratory tract diseases, Disease Models, Animal, 030104 developmental biology, Bronchoalveolar lavage, medicine.anatomical_structure, Acute Disease, Immunology, biology.protein, Alum Compounds, Cytokines, Goblet Cells, medicine.symptom, business, Bronchoalveolar Lavage Fluid

Abstract

Allergic asthma is a chronic inflammatory disease of the conducting airways characterized by the presence of allergen-specific IgE, Th2 cytokine production, eosinophilic airway inflammation, bronchial hyperreactivity, mucus overproduction, and structural changes in the airways. Investigators have tried to mimic these features of human allergic asthma in murine models. Whereas the surrogate allergen ovalbumin has been extremely valuable for unravelling underlying mechanisms of the disease, murine asthma models depend nowadays on naturally occurring allergens, such as house dust mite (HDM), cockroach, and Alternaria alternata. Here we describe a physiologically relevant model of acute allergic asthma based on sensitization and challenge with HDM extracts, and compare it with the ovalbumin/alum-induced asthma model. Moreover, we propose a detailed readout of the asthma phenotype, determining the degree of eosinophilia in bronchoalveolar lavage fluids by flow cytometry, visualizing goblet cell metaplasia, and measuring Th cytokine production by lung-draining mediastinal lymph node cells restimulated with HDM. © 2016 by John Wiley & Sons, Inc.

Published

2016

7. Inflammatory Type 2 cDCs Acquire Features of cDC1s and Macrophages to Orchestrate Immunity to Respiratory Virus Infection

Author

Martin Guilliams, Sofie De Prijck, David L. Williams, Cedric Bosteels, Franca Ronchese, Katrijn Neyt, Bart N. Lambrecht, Yvan Saeys, Charlotte L. Scott, Manon Lesage, Hamida Hammad, Niels Vandamme, Liesbet Martens, Manon Vanheerswynghels, Mary J. van Helden, Victor Bosteels, Dorine Sichien, Els Louagie, Johannes U Mayer, Shiau-Choot Tang, Nincy Debeuf, and Pulmonary Medicine

Subjects

0301 basic medicine, Cell Plasticity, Fc receptor, Receptors, Fc, Monocytes, IRF8, 0302 clinical medicine, T-Lymphocyte Subsets, Immunology and Allergy, Gene Regulatory Networks, Receptor, transcription factor, CD64, Antigen Presentation, biology, type 1 interferon, Research Highlight, 3. Good health, Infectious Diseases, Organ Specificity, Virus Diseases, 030220 oncology & carcinogenesis, Interferon Type I, monocyte, Disease Susceptibility, dendritic cell, Immunology, virus, Respirovirus Infections, Article, Immunophenotyping, convalescent serum, 03 medical and health sciences, Antigen, Immunity, Humans, Inflammation, Gene Expression Profiling, Macrophages, Dendritic Cells, 030104 developmental biology, Gene Expression Regulation, inf-cDC2, biology.protein, Biomarkers, CD8, Transcription Factors, IRF4

Abstract

Summary The phenotypic and functional dichotomy between IRF8+ type 1 and IRF4+ type 2 conventional dendritic cells (cDC1s and cDC2s, respectively) is well accepted; it is unknown how robust this dichotomy is under inflammatory conditions, when additionally monocyte-derived cells (MCs) become competent antigen-presenting cells (APCs). Using single-cell technologies in models of respiratory viral infection, we found that lung cDC2s acquired expression of the Fc receptor CD64 shared with MCs and of IRF8 shared with cDC1s. These inflammatory cDC2s (inf-cDC2s) were superior in inducing CD4+ T helper (Th) cell polarization while simultaneously presenting antigen to CD8+ T cells. When carefully separated from inf-cDC2s, MCs lacked APC function. Inf-cDC2s matured in response to cell-intrinsic Toll-like receptor and type 1 interferon receptor signaling, upregulated an IRF8-dependent maturation module, and acquired antigens via convalescent serum and Fc receptors. Because hybrid inf-cDC2s are easily confused with monocyte-derived cells, their existence could explain why APC functions have been attributed to MCs., Graphical Abstract, Highlights • Type I interferon drives differentiation of inf-cDC2s that closely resemble MCs • Inf-cDC2s prime CD4+ and CD8+ T cells, whereas MCs lack APC function • Inf-cDC2s internalize antibody-complexed antigen via Fc receptors • IRF8 controls maturation gene module in inf-cDC2s, The dichotomy between type 1 and 2 conventional DCs under steady-state conditions is well defined. Bosteels et al. demonstrate that, upon inflammation, cDC2s acquire a hybrid inf-cDC2 phenotype, sharing phenotype, gene expression, and function with cDC1s and monocyte-derived cells, to optimally boost CD4 and CD8 immunity via Fc receptors.

Published

2020

8. The ubiquitin-editing enzyme A20 controls NK cell homeostasis through regulation of mTOR activity and TNF

Author

Farzaneh Fayazpour, Louis Boon, Manon Vanheerswynghels, Kim Deswarte, Arne Martens, Simon Tavernier, Jessica Vetters, Nozomi Takahashi, Justine Van Moorleghem, Sophie Janssens, Geert van Loo, Sigrid Wahlen, Sofie De Prijck, Peter Vandenabeele, Karl Vergote, Eric Vivier, Bart N. Lambrecht, Mary J. van Helden, Unit of Immunoregulation and Mucosal Immunology [Ghent, Belgium], VIB Inflammation Research Center [Ghent, Belgium], Université de Strasbourg (UNISTRA), Groupe d'études orientales, slaves et néo-helléniques (GEO), Universiteit Gent = Ghent University (UGENT), Bioceros BV, Centre d'Immunologie de Marseille - Luminy (CIML), Aix Marseille Université (AMU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), VIB-UGent Center for Inflammation Research [Gand, Belgique] (IRC), VIB [Belgium], Department of Respiratory Medicine, Imperial College London, ER Stress and Inflammation [Ghent, Belgium], VIB Center for Inflammation Research [Ghent, Belgium], Erasmus MC other, Pulmonary Medicine, Universiteit Gent = Ghent University [Belgium] (UGENT), and Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Aix Marseille Université (AMU)

Subjects

0301 basic medicine, PROTECTS CELLS, Programmed cell death, Cell Survival, Immunology, Cell, B-CELL, Regulator, BCL-2, MATURATION, Mice, 03 medical and health sciences, NATURAL-KILLER-CELLS, 0302 clinical medicine, Ubiquitin, immune system diseases, Lymphopenia, hemic and lymphatic diseases, medicine, Medicine and Health Sciences, KINASE, Animals, Homeostasis, Immunology and Allergy, HEMATOPOIETIC STEM-CELLS, Research Articles, Tumor Necrosis Factor alpha-Induced Protein 3, PI3K/AKT/mTOR pathway, biology, Tumor Necrosis Factor-alpha, Chemistry, TOR Serine-Threonine Kinases, Brief Definitive Report, Biology and Life Sciences, Phenotype, 3. Good health, Cell biology, Killer Cells, Natural, 030104 developmental biology, medicine.anatomical_structure, biology.protein, T-CELLS, SURVIVAL, [SDV.IMM]Life Sciences [q-bio]/Immunology, Tumor necrosis factor alpha, OVEREXPRESSION, 030215 immunology

Abstract

The study of Vetters et al. identifies the ubiquitin-modifying enzyme A20 as a critical regulator of mTOR. Loss of A20 unleashes mTOR activity and induces NK cell death, underscoring the need for a tightly controlled mTOR pathway for proper NK cell homeostasis., The ubiquitin-editing enzyme A20 is a well-known regulator of immune cell function and homeostasis. In addition, A20 protects cells from death in an ill-defined manner. While most studies focus on its role in the TNF-receptor complex, we here identify a novel component in the A20-mediated decision between life and death. Loss of A20 in NK cells led to spontaneous NK cell death and severe NK cell lymphopenia. The few remaining NK cells showed an immature, hyperactivated phenotype, hallmarked by the basal release of cytokines and cytotoxic molecules. NK-A20−/− cells were hypersensitive to TNF-induced cell death and could be rescued, at least partially, by a combined deficiency with TNF. Unexpectedly, rapamycin, a well-established inhibitor of mTOR, also strongly protected NK-A20−/− cells from death, and further studies revealed that A20 restricts mTOR activation in NK cells. This study therefore maps A20 as a crucial regulator of mTOR signaling and underscores the need for a tightly balanced mTOR pathway in NK cell homeostasis.

Published

2019

9. Epitope mapping and kinetics of CD4 T cell immunity to pneumonia virus of mice in the C57BL/6 strain

Author

Mary J. van Helden, Andrew J. Easton, Sophie Janssens, Bart N. Lambrecht, Lana Vandersarren, James J. Moon, Cedric Bosteels, Gert Van Isterdael, and Manon Vanheerswynghels

Subjects

CD4-Positive T-Lymphocytes, 0301 basic medicine, Genetically modified mouse, Science, In silico, Pneumonia, Viral, PATHOGENESIS, RESPIRATORY SYNCYTIAL VIRUS, Epitopes, T-Lymphocyte, CD8-Positive T-Lymphocytes, Biology, DENDRITIC CELLS, SEQUENCE, Article, DISEASE, Epitope, Virus, Mice, 03 medical and health sciences, Immune system, parasitic diseases, Medicine and Health Sciences, Animals, Cytotoxic T cell, PEPTIDE, Amino Acid Sequence, Cells, Cultured, Immunity, Cellular, Multidisciplinary, Viral matrix protein, MEMORY, Histocompatibility Antigens Class II, GLYCOPROTEIN, Biology and Life Sciences, PNEUMOVIRUS INFECTION, Virology, 3. Good health, Mice, Inbred C57BL, ATTACHMENT, Kinetics, 030104 developmental biology, Epitope mapping, Murine pneumonia virus, Medicine, Female, Epitope Mapping, RESPONSES

Abstract

Pneumonia virus of mice (PVM) infection has been widely used as a rodent model to study the closely related human respiratory syncytial virus (hRSV). While T cells are indispensable for viral clearance, they also contribute to immunopathology. To gain more insight into mechanistic details, novel tools are needed that allow to study virus-specific T cells in C57BL/6 mice as the majority of transgenic mice are only available on this background. While PVM-specific CD8 T cell epitopes were recently described, so far no PVM-specific CD4 T cell epitopes have been identified within the C57BL/6 strain. Therefore, we set out to map H2-IAb-restricted epitopes along the PVM proteome. By means of in silico prediction and subsequent functional validation, we were able to identify a MHCII-restricted CD4 T cell epitope, corresponding to amino acids 37–47 in the PVM matrix protein (M37–47). Using this newly identified MHCII-restricted M37–47 epitope and a previously described MHCI-restricted N339–347 epitope, we generated peptide-loaded MHCII and MHCI tetramers and characterized the dynamics of virus-specific CD4 and CD8 T cell responses in vivo. The findings of this study can provide a basis for detailed investigation of T cell-mediated immune responses to PVM in a variety of genetically modified C57BL/6 mice.

Published

2017

10. Cellular and molecular synergy in AS01-adjuvanted vaccines results in an early IFNγ gamma response promoting vaccine immunogenicity

Author

Patricia Bourguignon, Catherine Collignon, Stanislas Goriely, Age K. Smilde, Sandra Morel, Bart N. Lambrecht, Caroline Hervé, Iain Welsby, Margherita Coccia, Mary J. van Helden, Arnaud M. Didierlaurent, Sophie Detienne, Robert A. van den Berg, Sheetij Dutta, Nathalie Garçon, Christopher J. Genito, Robbert van der Most, Aurélie Chalon, Katrijn Van Deun, David Franco, Norman C. Waters, Department of Methodology and Statistics, Didierlaurent, Arnaud, and Biosystems Data Analysis (SILS, FNWI)

Subjects

lcsh:Immunologic diseases. Allergy, 0301 basic medicine, Herpes Zoster Vaccine, medicine.medical_treatment, Immunology, Monophosphoryl Lipid A, lcsh:RC254-282, DENDRITIC CELLS, 03 medical and health sciences, HOST-DEFENSE, Immune system, Medicine and Health Sciences, medicine, IMMUNE-RESPONSE, Pharmacology (medical), PROTECTION, Author Correction, Lymph node, Pharmacology, LYMPH-NODES, business.industry, Biology and Life Sciences, Sciences bio-médicales et agricoles, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, medicine.disease, Virology, MICE, FALCIPARUM CIRCUMSPOROZOITE PROTEIN, 030104 developmental biology, Infectious Diseases, medicine.anatomical_structure, T-CELLS, TLR4, lcsh:RC581-607, NK CELLS, INFLUENZA VACCINATION, business, Adjuvant, CD8, Malaria

Abstract

Combining immunostimulants in adjuvants can improve the quality of the immune response to vaccines. Here, we report a unique mechanism of molecular and cellular synergy between a TLR4 ligand, 3-O-desacyl-4’-monophosphoryl lipid A (MPL), and a saponin, QS-21, the constituents of the Adjuvant System AS01. AS01 is part of the malaria and herpes zoster vaccine candidates that have demonstrated efficacy in phase III studies. Hours after injection of AS01-adjuvanted vaccine, resident cells, such as NK cells and CD8+ T cells, release IFNγ in the lymph node draining the injection site. This effect results from MPL and QS-21 synergy and is controlled by macrophages, IL-12 and IL-18. Depletion strategies showed that this early IFNγ production was essential for the activation of dendritic cells and the development of Th1 immunity by AS01-adjuvanted vaccine. A similar activation was observed in the lymph node of AS01-injected macaques as well as in the blood of individuals receiving the malaria RTS,S vaccine. This mechanism, previously described for infections, illustrates how adjuvants trigger naturally occurring pathways to improve the efficacy of vaccines.

Published

2017

11. Pre-existing virus-specific CD8+ T-cells provide protection against pneumovirus-induced disease in mice

Author

Claire J. P. Boog, Peter J.S. van Kooten, Andrew J. Easton, Alice J. A. M. Sijts, Andrea Gröne, Dietmar M. W. Zaiss, Cornelis P. J. Bekker, Mary J. van Helden, David J. Topham, and Dirk H. Busch

Subjects

BM-DC, bone marrow derived DC, CD8-Positive T-Lymphocytes, Epitope, Mice, DC, dendritic cell, 0302 clinical medicine, DCp, peptide-loaded DC, Cytotoxic T cell, Pneunomia virus of mice, p.i., post infection, Mice, Inbred BALB C, 0303 health sciences, Pneumovirus, i.p., intraperitoneal, Adoptive Transfer, Respiratory Syncytial Viruses, SEM, standard error of mean, 3. Good health, Killer Cells, Natural, FI, formalin inactivated, hRSV, human respiratory syncytial virus, MLN, mediastinal lymph node, Pneumoviruses, Infectious Diseases, Molecular Medicine, Female, BAL, bronchoalveolar lavage, NK, natural killer, Murine pneumonia virus, Biology, Article, Virus, Interferon-gamma, 03 medical and health sciences, i.v., intravenous, Immunology and Microbiology(all), parasitic diseases, Animals, Pneumovirus Infections, NK cell, 030304 developmental biology, QR355, ID, infectious dose, General Veterinary, General Immunology and Microbiology, NS, nonstructural, Influenza A Virus, H3N2 Subtype, Public Health, Environmental and Occupational Health, EID, egg ID, i.n., intranasal, pfu, plaque forming units, Dendritic cell, veterinary(all), Virology, Immunology, Pneumovirus vaccine, Interleukin-4, PVM, pneunomia virus of mice, CD8+ T-cell, BALF, BAL fluid, Immunologic Memory, Vaccine, CD8, 030215 immunology

Abstract

Highlights ► NK cells and CD8+ T-cells expand relatively late following pneumovirus infection. ► Memory CD8+ T-cells support type 1 skewing of pneumovirus-specific responses. ► Memory CD8+ T-cells prevent pneumovirus-induced immunopathology. ► CD8+ T-cell targeted immunization protects against pneumovirus-induced disease., Pneumoviruses such as pneumonia virus of mice (PVM), bovine respiratory syncytial virus (bRSV) or human (h)RSV are closely related pneumoviruses that cause severe respiratory disease in their respective hosts. It is well-known that T-cell responses are essential in pneumovirus clearance, but pneumovirus-specific T-cell responses also are important mediators of severe immunopathology. In this study we determined whether memory- or pre-existing, transferred virus-specific CD8+ T-cells provide protection against PVM-induced disease. We show that during infection with a sublethal dose of PVM, both natural killer (NK) cells and CD8+ T-cells expand relatively late. Induction of CD8+ T-cell memory against a single CD8+ T-cell epitope, by dendritic cell (DC)-peptide immunization, leads to partial protection against PVM challenge and prevents Th2 differentiation of PVM-induced CD4 T-cells. In addition, adoptively transferred PVM-specific CD8+ T-cells, covering the entire PVM-specific CD8+ T-cell repertoire, provide partial protection from PVM-induced disease. From these data we infer that antigen-specific memory CD8+ T-cells offer significant protection to PVM-induced disease. Thus, CD8+ T-cells, despite being a major cause of PVM-associated pathology during primary infection, may offer promising targets of a protective pneumovirus vaccine.

Published

2012

12. The Bone Marrow Functions as the Central Site of Proliferation for Long-Lived NK Cells

Author

Claire J. P. Boog, Dietmar M. W. Zaiss, Natascha de Graaf, David J. Topham, Alice J. A. M. Sijts, and Mary J. van Helden

Subjects

Adoptive cell transfer, Cell Survival, Immunology, Cell, Bone Marrow Cells, Spleen, Biology, Article, Mice, Mice, Congenic, Interleukin 21, Orthomyxoviridae Infections, NK-92, medicine, Animals, Immunology and Allergy, Cytotoxic T cell, Cell Proliferation, Cell growth, Adoptive Transfer, Liver Transplantation, Killer Cells, Natural, Mice, Inbred C57BL, medicine.anatomical_structure, Influenza A virus, Bone marrow, Lung Transplantation

Abstract

NK cells play an important role in the early defense against invading pathogens. Although it is well established that infection leads to a substantial, local increase in NK cell numbers, little is known about the mechanisms that trigger their proliferation and migration. In this study, we investigated the dynamics of NK cell responses after intranasal respiratory virus infection. We show that NK cell numbers increased in the airways after influenza virus infection but find no evidence of proliferation either at the site of infection or in the draining lymph nodes. Instead, we find that the bone marrow (BM) is the primary site of proliferation of both immature and mature NK cells during infection. Using an adoptive transfer model, we demonstrate that peripheral, long-lived and phenotypically mature NK cells migrate back to the BM and proliferate there, both homeostatically and in response to infection. Thus, the BM is not only a site of NK cell development but also an important site for proliferation of long-lived mature NK cells.

Published

2012

13. Author Correction: Cellular and molecular synergy in AS01-adjuvanted vaccines results in an early IFNγ response promoting vaccine immunogenicity

Author

Katrijn Van Deun, David Franco, Stanislas Goriely, Catherine Collignon, Christopher J. Genito, Arnaud Didierlaurent, Margherita Coccia, Sheetij Dutta, Norman C. Waters, Age K. Smilde, Mary J. van Helden, Patricia Bourguignon, Caroline Hervé, Sandra Morel, Bart N. Lambrecht, Sophie Detienne, Robbert van der Most, Robert A. van den Berg, Aurélie Chalon, Nathalie Garçon, and Iain Welsby

Subjects

Pharmacology, lcsh:Immunologic diseases. Allergy, business.industry, Published Erratum, Immunology, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Virology, lcsh:RC254-282, Article, Infectious Diseases, Vaccine Immunogenicity, Medicine, Pharmacology (medical), business, lcsh:RC581-607

Abstract

Combining immunostimulants in adjuvants can improve the quality of the immune response to vaccines. Here, we report a unique mechanism of molecular and cellular synergy between a TLR4 ligand, 3-O-desacyl-4’-monophosphoryl lipid A (MPL), and a saponin, QS-21, the constituents of the Adjuvant System AS01. AS01 is part of the malaria and herpes zoster vaccine candidates that have demonstrated efficacy in phase III studies. Hours after injection of AS01-adjuvanted vaccine, resident cells, such as NK cells and CD8+ T cells, release IFNγ in the lymph node draining the injection site. This effect results from MPL and QS-21 synergy and is controlled by macrophages, IL-12 and IL-18. Depletion strategies showed that this early IFNγ production was essential for the activation of dendritic cells and the development of Th1 immunity by AS01-adjuvanted vaccine. A similar activation was observed in the lymph node of AS01-injected macaques as well as in the blood of individuals receiving the malaria RTS,S vaccine. This mechanism, previously described for infections, illustrates how adjuvants trigger naturally occurring pathways to improve the efficacy of vaccines., Adjuvants: Vaccine components working in synergy to improve beneficial effects of vaccination A mechanism is revealed by which vaccine components co-operate to stimulate the immune system and improve vaccine efficacy. Some vaccines are formulated with adjuvants—compounds that induce a greater immune response to the vaccine and help to elicit greater protection against future infections. Arnaud Didierlaurent and his team of researchers at GSK Vaccines, Belgium, demonstrate that the two immunostimulants in the adjuvant AS01, used in several recently developed vaccines, works in tandem to trigger the activation of important immune system moderators. The synergistic effect of the immunostimulants modulate specific immune cells at the site of the vaccination to better prepare the body against future infection. Studies such as this allow us to better understand how vaccines work and lay the foundation for more informed research into future vaccine development.

Published

2018

14. Dendritic Cells and Type 2 Inflammation

Author

Hamida Hammad, Mary J. van Helden, and Bart N. Lambrecht

Subjects

House dust mite, Innate immune system, biology, Follicular dendritic cells, Antigen, Immunology, medicine, Pattern recognition receptor, Priming (immunology), Inflammation, medicine.symptom, Antigen-presenting cell, biology.organism_classification

Abstract

CD4 Th2 lymfocytes producing IL-4, IL-5 and IL-13 are common controllers of type 2 immunity. They respond to allergens and helminthes only when antigen is presented by professional antigen presenting cells like dendritic cells. Dendritic cells express many pattern recognition receptors that can be triggered by type 2 antigens, leading to direct DC activation and Th2 polarization. Alternatively, type 2 stimuli can first trigger barrier epithelial cells that subsequently activate the DCs via release of TSLP, IL-33 and IL-25. It is clear now that also other innate immune cells involved in type 2 immunity such as basophils and ILC2s help DCs to polarize CD4 T cells towards the Th2 direction. In addition to the roles of DCs in priming CD4 Th2 responses, they also control recall responses of memory CD4 Th2 cells to allergens, identifying these cells as important targets for intervention in allergic inflammatory diseases like asthma, dermatitis and rhinitis.

Published

2016

15. Terminal NK cell maturation is controlled by concerted actions of T-bet and Zeb2 and is essential for melanoma rejection

Author

Fabrice Faure, Niels Vandamme, Simon de Bernard, Anne-Laure Mathieu, Julie Chaix, Katia Mayol, Danny Huylebroeck, Sophie Degouve, Laurent Buffat, Eve Seuntjens, Thierry Walzer, Mary J. van Helden, Steven Goossens, Bart N. Lambrecht, Natalie Farla, Philippe Mangeot, Emilie Debien, Antoine Marçais, Andrea Conidi, Sébastien Viel, Jody J. Haigh, Geert Berx, Cécile Daussy, VIB-UGent Center for Inflammation Research [Gand, Belgique] (IRC), VIB [Belgium], Réponse immunitaire innée dans les maladies infectieuses et auto-immunes – Innate immunity in infectious and autoimmune diseases, Centre International de Recherche en Infectiologie (CIRI), École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Université Jean Monnet - Saint-Étienne (UJM)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Université Jean Monnet - Saint-Étienne (UJM)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Laboratory of Molecular Biology (CELGEN), Catholic University of Leuven - Katholieke Universiteit Leuven (KU Leuven), Department of Cell Biology [Rotterdam, Pays-Bas], Erasmus University Medical Center [Rotterdam] (Erasmus MC), Department of Pulmonary Medicine [Rotterdam, The Netherlands], Centre d'Immunologie de Marseille - Luminy (CIML), Aix Marseille Université (AMU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Contrôle traductionnel des ARNm eucaryotes et viraux – Translational control of Eukaryotic and Viral RNAs, AltraBio [Lyon], Australian Centre for Blood Diseases [Victoria, Australia], Cell biology, Pulmonary Medicine, Centre International de Recherche en Infectiologie - UMR (CIRI), École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), and Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Aix Marseille Université (AMU)

Subjects

HOMEOSTASIS, genetic structures, Melanoma, Experimental, Gene Expression, Cell Maturation, Inbred C57BL, MOUSE, CD49b, Transgenic, DISEASE, Interleukin 21, Mice, 0302 clinical medicine, Bone Marrow, Immunology and Allergy, Killer Cells, Melanoma, Cells, Cultured, IN-VIVO, Research Articles, Mice, Knockout, 0303 health sciences, Tumor, Cultured, Reverse Transcriptase Polymerase Chain Reaction, Janus kinase 3, hemic and immune systems, Flow Cytometry, 3. Good health, Cell biology, Killer Cells, Natural, [SDV.MP.VIR]Life Sciences [q-bio]/Microbiology and Parasitology/Virology, Interleukin 12, Natural, Cytokines, [SDV.IMM]Life Sciences [q-bio]/Immunology, EXPRESSION, Cell Survival, PROTEINS, Knockout, Cells, Immunology, Mice, Transgenic, chemical and pharmacologic phenomena, Biology, News, Insights, Cell Line, 03 medical and health sciences, Experimental, Cell Line, Tumor, Humans, Animals, TRAFFICKING, 030304 developmental biology, Zinc Finger E-box Binding Homeobox 2, Homeodomain Proteins, Lymphokine-activated killer cell, RECEPTOR, Brief Definitive Report, Biology and Life Sciences, Cell Biology, [SDV.MP.BAC]Life Sciences [q-bio]/Microbiology and Parasitology/Bacteriology, Mice, Inbred C57BL, Repressor Proteins, MICE, Cell culture, Ectopic expression, T-Box Domain Proteins, 030215 immunology

Abstract

The transcription factor Zeb2 cooperates with T-bet to control NK cell maturation, viability, and exit from the bone marrow and is essential for rejection of melanoma lung metastasis., Natural killer (NK) cell maturation is a tightly controlled process that endows NK cells with functional competence and the capacity to recognize target cells. Here, we found that the transcription factor (TF) Zeb2 was the most highly induced TF during NK cell maturation. Zeb2 is known to control epithelial to mesenchymal transition, but its role in immune cells is mostly undefined. Targeted deletion of Zeb2 resulted in impaired NK cell maturation, survival, and exit from the bone marrow. NK cell function was preserved, but mice lacking Zeb2 in NK cells were more susceptible to B16 melanoma lung metastases. Reciprocally, ectopic expression of Zeb2 resulted in a higher frequency of mature NK cells in all organs. Moreover, the immature phenotype of Zeb2−/− NK cells closely resembled that of Tbx21−/− NK cells. This was caused by both a dependence of Zeb2 expression on T-bet and a probable cooperation of these factors in gene regulation. Transgenic expression of Zeb2 in Tbx21−/− NK cells partially restored a normal maturation, establishing that timely induction of Zeb2 by T-bet is an essential event during NK cell differentiation. Finally, this novel transcriptional cascade could also operate in human as T-bet and Zeb2 are similarly regulated in mouse and human NK cells.

Published

2015

16. FlowSOM: Using self-organizing maps for visualization and interpretation of cytometry data

Author

Sofie Van Gassen, Mary J. van Helden, Britt Callebaut, Bart N. Lambrecht, Yvan Saeys, Piet Demeester, and Tom Dhaene

Subjects

Self-organizing map, Histology, Lymphoma, B-Cell, Computer science, Graft vs Host Disease, computer.software_genre, Bioinformatics, Pathology and Forensic Medicine, Bioconductor, Cluster Analysis, Humans, Mass cytometry, Cluster analysis, Hematopoietic Stem Cell Transplantation, Computational Biology, Cell Biology, Flow Cytometry, Visualization, Exploratory data analysis, Identification (information), Scatter plot, Data mining, computer, Algorithms, Biomarkers, West Nile Fever

Abstract

The number of markers measured in both flow and mass cytometry keeps increasing steadily. Although this provides a wealth of information, it becomes infeasible to analyze these datasets manually. When using 2D scatter plots, the number of possible plots increases exponentially with the number of markers and therefore, relevant information that is present in the data might be missed. In this article, we introduce a new visualization technique, called FlowSOM, which analyzes Flow or mass cytometry data using a Self-Organizing Map. Using a two-level clustering and star charts, our algorithm helps to obtain a clear overview of how all markers are behaving on all cells, and to detect subsets that might be missed otherwise. R code is available at https://github.com/SofieVG/FlowSOM and will be made available at Bioconductor.

Published

2015

17. Contributors

Author

Valérie Abadie, Clara Abraham, David H. Adams, William W. Agace, Jennifer Alexander-Brett, Omar Alkhairy, Ines Ambite, Deborah J. Anderson, David Artis, Robert L. Atmar, Laetitia Aymeric, Claus Bachert, Jantine E. Bakema, Kristi Baker, Kenneth W. Beagley, A.D. Befus, Mats Bemark, M. Cecilia Berin, Margot Berings, Jay A. Berzofsky, Martin Bilej, Nabanita Biswas, Richard S. Blumberg, John Bienenstock, Dimitrios Bogdanos, Monica Boirivant, Kobporn Boonnak, Ken R. Bracke, Per Brandtzaeg, Jonathan Braun, Marie-Agnès Bringer, Andrew J. Broadbent, Richard Bronson, Guy G. Brusselle, Judith N. Bulmer, J.E. Butler, Paul A. Cardenas, John J. Cebra, Marina Cella, Andrea Cerutti, Stephen J. Challacombe, Kuldeep Chattha, Hilde Cheroutre, Tsutomu Chiba, Alejo Chorny, John D. Clements, Marco Colonna, William O.C. Cookson, Lynette B. Corbeil, Blaise Corthésy, Allan W. Cripps, Koen van Crombruggen, Andre Pires da Cunha, Susanna Cunningham-Rundles, Roy Curtiss, Arlette Darfeuille-Michaud, Wouter J. de Jonge, Livija Deban, Timothy L. Denning, James P. Di Santo, Andreas Diefenbach, Victor J. DiRita, Jordan Downey, Ming-Qing Du, Karen L. Edelblum, Marjolein van Egmond, H.-J. Epple, Sidonia Fagarasan, John V. Fahey, Michael J. Ferris, Stefan Fichtner-Feigl, Paul L. Fidel, Melanie Flach, Richard Flavell, Howard B. Fleit, Genoveffa Franchini, Lucy C. Freytag, Anja Fuchs, kohtaro Fujihashi, Ivan J. Fuss, Nicola Gagliani, Marta Rodriguez Garcia, Wendy S. Garrett, M. Eric Gershwin, Philippe Gevaert, Maree Gleeson, Gabriela Godaly, Randall M. Goldblum, Naina Gour, Mayda Gursel, George Hajishengallis, Hamida Hammad, Lennart Hammarström, Arno Hänninen, Lars Å. Hanson, Adrian Hayday, Ronit Herzog, Douglas C. Hodgins, Stephen T. Holgate, Jan Holmgren, Michael J. Holtzman, Edward W. Hook, Samuel Huber, Julia L. Hurwitz, Juraj Ivanyi, Akiko Iwasaki, Bana Jabri, Susan Jackson, Jonathan Jacobs, Sirpa Jalkanen, Edward N. Janoff, Ann E. Jerse, Mangalakumari Jeyanathan, Bruce A. Julian, Imre Kacskovics, Charlotte S. Kaetzel, Charu Kaushic, Brian L. Kelsall, Sarah Kessans, Rebecca Kesselring, Mogens Kilian, Hiroshi Kiyono, Dennis M. Klinman, Marina Korotkova, Mitchell Kronenberg, Olga Krysko, Yuichi Kurono, Miloslav Kverka, Bart N. Lambrecht, Michael E. Lamm, Olivier Lantz, Gendie E. Lash, E.C. Lavelle, Leo Lefrancois, Patrick S.C. Leung, Myron M. Levine, David J. Lim, John Lippolis, Nancy A. Louis, Andrew D. Luster, Nataliya Lutay, Nils Lycke, Andrew J. Macpherson, Nicholas J. Mantis, Harold Marcotte, David H. Martin, Hugh S. Mason, Helen M. Massa, Nobuyuki Matoba, Lloyd Mayer, Craig L. Maynard, M. Juliana McElrath, C. McEntee, Jerry R. McGhee, Michael A. McGuckin, Jiri Mestecky, Zamaneh Mikhak, Robert D. Miller, Zina Moldoveanu, Paul C. Montgomery, Tsafrir Mor, Markus F. Neurath, Katrijn Neyt, Lindsay K. Nicholson, Jan Novak, Stella Nowicki, D.T. O’Hagan, Nancy L. O’Sullivan, Pearay Ogra, Carlos Orihuela, André J. Ouellette, Robert L. Owen, Oliver Pabst, Charles A. Parkos, Viviana Parreño, Mickey V. Patel, Claudina Perez-Novo, Darren J. Perkins, Calman Prussin, Jeffrey Pudney, Sukanya Raghavan, Pascal Rainard, Sasirekha Ramani, Troy D. Randall, Milan Raska, Gourapura J. Renukaradhya, Maria Rescigno, Kenneth L. Rosenthal, Marc E. Rothenberg, Frank M. Ruemmele, Michael W. Russell, Linda J. Saif, Irene Salinas, Marko Salmi, Henri Salmon, Hugh A. Sampson, Philippe Sansonetti, T. Schneider, Nicolas Serafini, Dolly Sharma, Zheng Shen, Hai Ning Shi, Penelope J. Shirlaw, Sourima B. Shivhare, Phillip D. Smith, Patrick M. Smith, Daniel J. Smith, Lesley E. Smythies, Jo Spencer, Warren Strober, Kanta Subbarao, Catharina Svanborg, Ann-Mari Svennerholm, Martin A. Taubman, Esbjörn Telemo, Martin H. Thornhill, David J. Thornton, Eva Thuenemann, Helena Tlaskalova-Hogenova, Debra Tristram, Palak Trivedi, Elaine Tuomanen, Jaroslav Turanek, Jerrold R. Turner, Brian J. Underdown, Mary J. van Helden, Ronald S. Veazey, Elena F. Verdu, Anastasia Vlasova, Harissios Vliagoftis, Stefanie N. Vogel, W. Allan Walker, Xiaolei Wang, Tomohiro Watanabe, Casey T. Weaver, Howard L. Weiner, Jerry M. Wells, Ting Wen, Judith Whittum-Hudson, Jeffrey A. Whitsett, Ifor R. Williams, Marsha Wills-Karp, Charles R. Wira, Jenny M. Woof, Andrew C. Wotherspoon, Zhou Xing, Huanbin Xu, Colby Zaph, Sebastian Zeissig, and M. Zeitz

Published

2015

18. The Mucosal Immune Response to Respiratory Viruses

Author

Katrijn Neyt, Mary J. van Helden, and Bart N. Lambrecht

Subjects

Innate immune system, Immune system, biology, viruses, Innate lymphoid cell, Immunology, biology.protein, Respiratory virus, Cytotoxic T cell, Antibody, Acquired immune system, Virology, Virus

Abstract

Because of its air-exchange function, the lung is continuously exposed to foreign particles such as microbes. Viral infections such as influenza A virus, respiratory syncytial virus, human metapneumovirus, and rhinovirus are common and the lung is a very vulnerable organ that needs to preserve gas exchange during antiviral defense. To recognize these threats and at the same time maintain tissue homeostasis, the lung is equipped with an elaborate network of innate and adaptive immune cells. The innate mucosal immune response to respiratory viruses is made up of natural killer cells and B cells producing low-affinity natural antibodies. Dendritic cells are the sentinels of the immune system linking sensing by ancient innate immune system receptors to activation of adaptive immunity to respiratory viruses. These cells also induce the polarization of virus-specific CD4 and CD8 T cell responses, necessary for viral clearance. Memory responses to viral antigens are found in the CD4 and CD8 compartment of T cells, and these cells often home back to the lung mucosa to become tissue-resident memory cells, which produce copious amounts of cytokines upon renewed viral encounter. Following respiratory viral infection, there frequently is induction of tertiary lymphoid organs such as bronchus-associated lymphoid tissues that similarly play important roles in maintaining antiviral immunity.

Published

2015

19. Dendritic cells in asthma

Author

Bart N. Lambrecht, Mary J. van Helden, and Pulmonary Medicine

Subjects

House dust mite, biology, business.industry, Immunology, Innate lymphoid cell, Allergic asthma, Epithelial Cells, Dendritic Cells, Allergens, medicine.disease, biology.organism_classification, Asthma, Heterogeneous population, Immune system, Th2 Cells, Antigen, medicine, Immunology and Allergy, Animals, Humans, business, Antigen-presenting cell, Lung

Abstract

The lungs are constantly exposed to antigens, most of which are non-pathogenic and do not require the induction of an immune response. Dendritic cells (DCs) are situated at the basolateral site of the lungs and continuously scan the environment to detect the presence of pathogens and subsequently initiate an immune response. They are a heterogeneous population of antigen-presenting cells that exert specific functions. Compelling evidence is now provided that DCs are both sufficient and necessary to induce allergic responses against several inhaled harmless allergens. How various DC subsets exactly contribute to the induction of allergic asthma is currently a subject of intense investigation. We here review the current progress in this field.

Published

2014

20. Induction of humoral and cellular immune responses by antigen-expressing immunostimulatory liposomes

Author

Mary J. van Helden, Neda Rafiei Tabataei, Marijn Schouten, Alice J. A. M. Sijts, Volkert de Bot, Anna L. de Goede, Anastasia Lanzi, Enrico Mastrobattista, Guus F. Rimmelzwaan, Maryam Amidi, Rob A. Gruters, Pharmacy, Cardiothoracic Surgery, and Virology

Subjects

T-Lymphocytes, Pharmaceutical Science, Lymphocyte Activation, Epitope, DNA vaccination, Mice, Immune system, Antigen, SDG 3 - Good Health and Well-being, Adjuvants, Immunologic, Vaccines, DNA, Animals, Antigens, Luciferases, Liposome, Immunity, Cellular, biology, Transfection, beta-Galactosidase, Molecular biology, Immunity, Humoral, Mice, Inbred C57BL, CTL, Liposomes, biology.protein, Female, Antibody, Plasmids

Abstract

Recently we have shown that liposomes can be used as artificial microbes for the production and delivery of DNA-encoded antigens. These so-called antigen-expressing immunostimulatory liposomes (AnExILs) were superior in inducing antigen-specific antibodies compared to conventional liposomal protein or DNA vaccines when tested in mice after i.m. immunization. In this study, we investigated the capacity of AnExILs to induce T-cell responses. By using a plasmid vector encoding a model antigen under control of both the prokaryotic T7 and the eukaryotic CMV promoter we hypothesized that antigen production could lead to CTL activation via two distinct routes: i. production of antigens inside the AnExILs with subsequent cross-presentation after processing by APCs and ii. endogenous production of antigens after AnExIL-mediated transfection of the pDNA. Although we were not able to demonstrate transfection-mediated expression of luc-NP in mice, i.m. injection of AnExILs producing luc-NP resulted in T-cell responses against the encoded NP epitope, as determined by tetramer staining. T-cell responses were comparable to the responses obtained after i.m. injection of naked pDNA. In order to find out whether CTL activation was caused by cross-presentation of the exogenous antigens produced inside AnExILs or by endogenous antigen production from transfection with the same pDNA source a second study was initiated in which the contribution of each of these effects could be separately determined. These results demonstrate that the observed T-cell responses were not exclusively caused by cross-presentation of the AnExIL-produced antigens alone, but were rather a combination of dose-dependent antigen cross-presentation and low levels of endogenous antigen production. (c) 2012 Elsevier B. V. All rights reserved.

Published

2012