Your search keyword '"Immo, Prinz"' showing total 185 results

1. Supplementary Figures and Tables from Broad Cytotoxic Targeting of Acute Myeloid Leukemia by Polyclonal Delta One T Cells

Author

Bruno Silva-Santos, David Vermijlen, Sarina Ravens, Haakan Norell, Immo Prinz, Ton N. Schumacher, Julie Déchanet-Merville, Maria Gomes da Silva, Tânia Carvalho, Daniel V. Correia, Paola Tieppo, Francisco Caiado, André E. Simões, and Biagio Di Lorenzo

Abstract

Supplementary Figures 1-5 and tables 1-3

Published

2023

2. Data from Broad Cytotoxic Targeting of Acute Myeloid Leukemia by Polyclonal Delta One T Cells

Author

Bruno Silva-Santos, David Vermijlen, Sarina Ravens, Haakan Norell, Immo Prinz, Ton N. Schumacher, Julie Déchanet-Merville, Maria Gomes da Silva, Tânia Carvalho, Daniel V. Correia, Paola Tieppo, Francisco Caiado, André E. Simões, and Biagio Di Lorenzo

Abstract

Acute myeloid leukemia (AML) remains a clinical challenge due to frequent chemotherapy resistance and deadly relapses. We are exploring the immunotherapeutic potential of peripheral blood Vδ1+ T cells, which associate with improved long-term survival of stem-cell transplant recipients but have not yet been applied as adoptive cell therapy. Using our clinical-grade protocol for expansion and differentiation of “Delta One T” (DOT) cells, we found DOT cells to be highly cytotoxic against AML primary samples and cell lines, including cells selected for resistance to standard chemotherapy. Unlike chemotherapy, DOT-cell targeting did not select for outgrowth of specific AML lineages, suggesting a broad recognition domain, an outcome that was consistent with the polyclonality of the DOT-cell T-cell receptor (TCR) repertoire. However, AML reactivity was only slightly impaired upon Vδ1+ TCR antibody blockade, whereas it was strongly dependent on expression of the NKp30 ligand, B7-H6. In contrast, DOT cells did not show reactivity against normal leukocytes, including CD33+ or CD123+ myeloid cells. Adoptive transfer of DOT cells in vivo reduced AML load in the blood and target organs of multiple human AML xenograft models and significantly prolonged host survival without detectable toxicity, thus providing proof-of-concept for DOT-cell application in AML treatment.

Published

2023

3. OMIP‐084: 28‐color full spectrum flow cytometry panel for the comprehensive analysis of human γδ T cells

Author

Joana Barros‐Martins, Elena Bruni, Alina Suzann Fichtner, Markus Cornberg, and Immo Prinz

Subjects

Histology, CD28 Antigens, NK Cell Lectin-Like Receptor Subfamily K, T-Lymphocyte Subsets, Programmed Cell Death 1 Receptor, Humans, Receptors, Antigen, T-Cell, gamma-delta, Receptors, Chemokine, Cell Biology, Flow Cytometry, Pathology and Forensic Medicine

Abstract

Using full spectrum flow cytometry, we designed a 28-color panel for the analysis of markers known to be associated with the γδ T cell immune response. This panel allows the classification of γδ T cell subsets via specific V gene usage (Vγ9, Vδ1, Vδ2, and Vδ3) of their T cell receptor (TCR) and according to their functional differentiation. Phenotypical surface receptors to distinguish different stages of cell maturation included CD45RA, CD27, CD28, CD127, CD57, and CD16; chemokine receptors CXCR6, CCR5, CCR6, and CX3CR1; NK-associated markers NKG2A, NKG2D, CD56, and CD161, checkpoint-inhibitor PD-1, and activating receptors CD38 and CD25. T cell lineage markers for the analysis of αβ T cells (CD4 and CD8) and MAIT cells (Vα7.2) were also included. This optimized multicolor panel allows a comprehensive immune-profiling of all main human γδ T cell subsets and is suitable for longitudinal or exploratory analysis of γδ T cell development and γδ T cell dynamics in clinical cohorts.

Published

2022

4. Transcriptional and Clonal Characterization of Cytotoxic T Cells in Crescentic Glomerulonephritis

Author

Anne Mueller, Yu Zhao, Hakan Cicek, Hans-Joachim Paust, Amirrtavarshni Sivayoganathan, Alexandra Linke, Claudia Wegscheid, Thorsten Wiech, Tobias B. Huber, Catherine Meyer-Schwesinger, Stefan Bonn, Immo Prinz, Ulf Panzer, Gisa Tiegs, Christian F. Krebs, and Katrin Neumann

Subjects

Nephrology, General Medicine

Published

2023

5. Adult thymus-derived cMaf+RORγt+γδ T cells lack Scart2 chromatin accessibility and do not reach periphery

Author

Tao Yang, Joana Barros-Martins, Anika Janssen, Ziqing Wang, Ximena León-Lara, Siegfried Weiss, Immo Prinz, Reinhold Förster, and Sarina Ravens

Abstract

T cell receptor (TCR) Vγ4+expressing γδT cells can be divided into IFN-γ and IL-17-producing effector T cell subsets. A bias towards γδ17 effector fate decisions is observed during early ontogeny. In contrast, the existence of Vγ4+γδ17 cells derived from adult thymus is still controversial. In the present work, we used a mouse model where T cells are exclusive generated within an adult thymus. Additionally, we employed single-cell chromatin state analysis from thymocytes of normal mice. A small, but considerable population of immatureCd24+Gzma+Vγ4 cells was found that exhibit molecular programs of γδ17 cells. These adult thymus-derived immatureCd24a+cMaf+Vγ4 cells secrete small amounts of IL-17A and IL-17F. Interestingly, do not reach the periphery under steady-state conditions. Furthermore,de novogenerated γδ17-like cells from adult thymus lack transcriptional activity of the Scart2 encoding gene, suggesting that Scart2 is a distinct trait of fetal γδT cell precursors. Together, this study provides valuable insights into developmental traits of Vγ4 cells during adulthood and raises the question on signals suppressing the full maturation and/or thymic export of γδ17-like cells within the adult thymus.HighlightsTranscriptional and epigenetic profiling identifies developmental plasticity ofGzma+Cd24a+Vγ4 cells in adult thymus.Thymic c-Maf+and RORγt+Vγ4 T cells can be generated during adulthood, but do not reach the periphery under steady-state conditions.Innate CD44highCD45RBnegγδ17 cells are completely absent upon induction of T cell development during adulthood.Scart2 expression might be a key molecule to track developmental traits of fetal-derived γδ17 cell precursors.

Published

2023

6. IL-17 Signaling in Keratinocytes Orchestrates the Defense against Staphylococcus aureus Skin Infection

Author

Sonja Moos, Tommy Regen, Florian Wanke, Yizhu Tian, Lucas T. Arendholz, Judith Hauptmann, André P. Heinen, Lisa Bleul, Katharina Bier, Khalifa El Malki, Christoph Reinhardt, Immo Prinz, Andreas Diefenbach, Christiane Wolz, Birgit Schittek, Ari Waisman, and Florian C. Kurschus

Subjects

Cell Biology, Dermatology, Molecular Biology, Biochemistry

Published

2023

7. The role of CXCR6+γδ T cells in chronic hepatitis B virus (HBV) infection

Author

Katja Steppich, Roni Souleiman, Elena Bruni, XimenaLeon Lara, Immo Prinz, Anke Kraft, and Markus Cornberg

Published

2023

8. Adult Thymus-Derived cMaf RORγt γδ T Cells Lack Scart2 Chromatin Accessibility and Do Not Reach Periphery

Author

Tao Yang, Joana Barros-Martins, Anika Janssen, Ziqing Wang, Ximena Leon-Lara, Siegfried Weiss, Immo Prinz, Reinhold Förster, and Sarina Ravens

Published

2023

9. Interleukin-23 receptor expressing γδ T cells locally promote early atherosclerotic lesion formation and plaque necrosis in mice

Author

Jesus Gil-Pulido, Núria Amézaga, Ivana Jorgacevic, Helga D Manthey, Melanie Rösch, Theresa Brand, Peter Cidlinsky, Sarah Schäfer, Andreas Beilhack, Antoine-Emmanuel Saliba, Kristina Lorenz, Louis Boon, Immo Prinz, Ari Waisman, Thomas Korn, Clément Cochain, and Alma Zernecke

Subjects

Mice, Knockout, Physiology, Granulocyte-Macrophage Colony-Stimulating Factor, Receptors, Interleukin, Atherosclerosis, Plaque, Atherosclerotic, Mice, Inbred C57BL, Mice, Disease Models, Animal, Necrosis, Receptors, LDL, Physiology (medical), Animals, Th17 Cells, Cardiology and Cardiovascular Medicine

Abstract

Aims Atherosclerosis is a chronic inflammatory disease of the vessel wall controlled by local and systemic immune responses. The role of interleukin-23 receptor (IL-23R), expressed in adaptive immune cells (mainly T-helper 17 cells) and γδ T cells, in atherosclerosis is only incompletely understood. Here, we investigated the vascular cell types expressing IL-23R and addressed the function of IL-23R and γδ T cells in atherosclerosis. Methods and results IL-23R+ cells were frequently found in the aortic root in contrast to the aorta in low-density lipoprotein receptor deficient IL-23R reporter mice (Ldlr−/−Il23rgfp/+), and mostly identified as γδ T cells that express IL-17 and GM-CSF. scRNA-seq confirmed γδ T cells as the main cell type expressing Il23r and Il17a in the aorta. Ldlr−/−Il23rgfp/gfp mice deficient in IL-23R showed a loss of IL-23R+ cells in the vasculature, and had reduced atherosclerotic lesion formation in the aortic root compared to Ldlr−/− controls after 6 weeks of high-fat diet feeding. In contrast, Ldlr−/−Tcrδ−/− mice lacking all γδ T cells displayed unaltered early atherosclerotic lesion formation compared to Ldlr−/− mice. In both HFD-fed Ldlr−/−Il23rgfp/gfp and Ldlr−/−Tcrδ−/− mice a reduction in the plaque necrotic core area was noted as well as an expansion of splenic regulatory T cells. In vitro, exposure of bone marrow-derived macrophages to both IL-17A and GM-CSF induced cell necrosis, and necroptotic RIP3K and MLKL expression, as well as inflammatory mediators. Conclusions IL-23R+ γδ T cells are predominantly found in the aortic root rather than the aorta and promote early atherosclerotic lesion formation, plaque necrosis, and inflammation at this site. Targeting IL-23R may thus be explored as a therapeutic approach to mitigate atherosclerotic lesion development.

Published

2021

10. γδ T Cells Differentially Regulate Bone Loss in Periodontitis Models

Author

Asaf Wilensky, Y. Jaber, A. Leibovich, O Barel, Khaled Zubeidat, Yuval Aizenbud, Luba Eli-Berchoer, Immo Prinz, O. Heyman, Yaara Tabib, Y. Horev, Avi-Hai Hovav, and Yasmin Saba

Subjects

T-Lymphocytes, Population, Alveolar Bone Loss, Biology, Mice, Immune system, medicine, Animals, Oral mucosa, Periodontitis, education, General Dentistry, Porphyromonas gingivalis, Dental alveolus, education.field_of_study, Innate immune system, medicine.disease, biology.organism_classification, Mice, Inbred C57BL, Bone Diseases, Metabolic, Disease Models, Animal, medicine.anatomical_structure, Immunology, Homeostasis

Abstract

γδ T cells are nonclassical T lymphocytes representing the major T-cell population at epithelial barriers. In the gingiva, γδ T cells are enriched in epithelial regions adjacent to the biofilm and are considered to regulate local immunity to maintain host-biofilm homeostatic interactions. This delicate balance is often disrupted resulting in the development of periodontitis. Previous studies in mice lacking γδ T cells from birth ( Tcrd-/-mice) examined the impact of these cells on ligature-induced periodontitis. Data obtained from those studies proposed either a protective effect or no impact to γδ T cells in this setting. Here, we addressed the role of γδ T cells in periodontitis using the recently developed Tcrd-GDL mice, enabling temporal ablation of γδ T cells. Specifically, the impact of γδ T cells during periodontitis was examined in 2 modalities: the ligature model and the oral infection model in which the pathogen Porphyromonas gingivalis was administrated via successive oral gavages. Ablation of γδ T cells during ligature-induced periodontitis had no impact on innate immune cell recruitment to the ligated gingiva. In addition, the number of osteoclasts and subsequent alveolar bone loss were unaffected. However, γδ T cells play a pathologic role during P. gingivalis infection, and their absence prevented alveolar bone loss. Further analysis revealed that γδ T cells were responsible for the recruitment of neutrophils and monocytes to the gingiva following the exposure to P. gingivalis. γδ T-cell ablation also downregulated osteoclastogenesis and dysregulated long-term immune responses in the gingiva. Collectively, this study demonstrates that whereas γδ T cells are dispensable to periodontitis induced by the ligature model, they play a deleterious role in the oral infection model by facilitating pathogen-induced bone-destructive immune responses. On a broader aspect, this study highlights the complex immunopathologic mechanisms involved in periodontal bone loss.

Published

2021

11. Kidney-resident innate-like memory γδ T cells control chronic

Author

Tabea, Bertram, Daniel, Reimers, Niels C, Lory, Constantin, Schmidt, Joanna, Schmid, Lisa, C Heinig, Peter, Bradtke, Guido, Rattay, Stephanie, Zielinski, Malte, Hellmig, Patricia, Bartsch, Holger, Rohde, Sarah, Nuñez, Mariana V, Rosemblatt, Maria Rosa, Bono, Nicola, Gagliani, Inga, Sandrock, Ulf, Panzer, Christian F, Krebs, Catherine, Meyer-Schwesinger, Immo, Prinz, and Hans-Willi, Mittrücker

Subjects

Mice, Inbred C57BL, Mice, Staphylococcus aureus, Reinfection, Interleukin-17, Animals, Receptors, Antigen, T-Cell, gamma-delta, Persistent Infection, Staphylococcal Infections, Kidney

Abstract

γδ T cells are involved in the control of

Published

2022

12. Kidney-resident innate-like memory γδ T cells control chronic Staphylococcus aureus infection of mice

Author

Tabea Bertram, Daniel Reimers, Niels C. Lory, Constantin Schmidt, Joanna Schmid, Lisa C. Heinig, Peter Bradtke, Guido Rattay, Stephanie Zielinski, Malte Hellmig, Patricia Bartsch, Holger Rohde, Sarah Nuñez, Mariana V. Rosemblatt, Maria Rosa Bono, Nicola Gagliani, Inga Sandrock, Ulf Panzer, Christian F. Krebs, Catherine Meyer-Schwesinger, Immo Prinz, and Hans-Willi Mittrücker

Subjects

Multidisciplinary

Abstract

γδ T cells are involved in the control of Staphylococcus aureus infection, but their importance in protection compared to other T cells is unclear. We used a mouse model of systemic S. aureus infection associated with high bacterial load and persistence in the kidney. Infection caused fulminant accumulation of γδ T cells in the kidney. Renal γδ T cells acquired tissue residency and were maintained in high numbers during chronic infection. At day 7, up to 50% of renal γδ T cells produced IL-17A in situ and a large fraction of renal γδ T cells remained IL-17A + during chronic infection. Controlled depletion revealed that γδ T cells restricted renal S. aureus replication in the acute infection and provided protection during chronic renal infection and upon reinfection. Our results demonstrate that kidney-resident γδ T cells are nonredundant in limiting local S. aureus growth during chronic infection and provide enhanced protection against reinfection.

Published

2022

13. New insights on murine γδ T cells from single-cell multi-omics

Author

Likai, Tan, Daniel, Inácio, Immo, Prinz, and Bruno, Silva-Santos

Subjects

Mice, Multidisciplinary, T-Lymphocytes, Animals, Receptors, Antigen, T-Cell, gamma-delta, Multiomics

Published

2022

14. αβ T cells replacing dermal and epidermal γδ T cells inTcrd−/−mice express an MHC‐independent TCR repertoire

Author

Christoph Binz, Immo Prinz, Anja Bubke, and Inga Sandrock

Subjects

education.field_of_study, Epidermis (botany), Immunology, Population, T-cell receptor, Double negative, hemic and immune systems, chemical and pharmacologic phenomena, Biology, Major histocompatibility complex, Phenotype, Cell biology, medicine.anatomical_structure, Dermis, biology.protein, medicine, Immunology and Allergy, education, CD8

Abstract

The epidermis of mouse skin is usually populated by dendritic epidermal T cells (γδDETC) expressing an invariant Vγ5Vδ1+ TCR. In Tcrd-/- mice, skin-resident γδDETC are replaced by αβDETC carrying polyclonal αβ TCRs. Although they exhibit a dendritic morphology, αβDETC were reported to be less functional than genuine γδDETC, likely because their TCR is unable to interact with the original TCR ligands of γδDETC. However, the TCR repertoire of those replacement DETC in Tcrd-/- mice might provide clues for understanding the development and selection of canonical γδDETC. Here, we compare the phenotype and TCR repertoires of wild-type and Tcrd-/- mouse skin T cells. Our data reveal that αβDETC are CD4/CD8 double negative and express an MHC-independent TCR repertoire. Furthermore, we identify a second MHC-independent population of CD103hi CD4/ CD8 double-negative αβ T cells in the dermis of Tcrd-/- mice.

Published

2021

15. Interleukin-23 instructs protective multifunctional CD4 T cell responses after immunization with the Mycobacterium tuberculosis subunit vaccine H1 DDA/TDB independently of interleukin-17A

Author

Thomas Lindenstrøm, Christoph Hölscher, Jasmin Rousseau, Immo Prinz, Hanna Erdmann, Johanna Volz, Jochen Behrends, Alexandra Hölscher, and Kristina Ritter

Subjects

business.industry, Vaccination, T cells, Interleukin, Mice, Immune system, Immunization, Immunity, Drug Discovery, Immunology, Interleukin 23, Molecular Medicine, Medicine, Tuberculosis, Cytokines, Tumor necrosis factor alpha, Original Article, Interleukin 17, business, Genetics (clinical)

Abstract

Interleukin (IL)-17A-producing T helper (Th)17 cells are increasingly being acknowledged to be associated with protective immunity toMycobacterium tuberculosis(Mtb). Subunit vaccines potently promote protective immune responses against Mtb infection that correlate with an expansion of IL-23-dependent Th17 cells. Previous studies revealed that after vaccination, IL-23 is required for protection against challenge with Mtb but the underlying IL-23-dependent—and possibly IL-17A-mediated—mechanisms remain elusive. Therefore, we here analyzed the early outcome of Mtb infection in C57BL/6, IL-23p19-deficient (−/−), and IL-17A−/−mice after vaccination with the subunit vaccine H1-DDA/TDB to investigate the role of the IL-23-Th17 immune axis for the instruction of vaccine-induced protection. While in IL-23p19−/−mice the protective effect was reduced, protection after vaccination was maintained in IL-17A−/−animals for the course of infection of 6 weeks, indicating that after vaccination with H1-DDA/TDB early protection against Mtb is—although dependent on IL-23—not mediated by IL-17A. In contrast, IL-17A deficiency appears to have an impact on maintaining long-term protection. In fact, IL-23 instructed the vaccine-induced memory immunity in the lung, in particular the sustained expansion of tumor necrosis factor (TNF)+IL-2+multifunctional T cells, independently of IL-17A. Altogether, a targeted induction of IL-23 during vaccination against Mtb might improve the magnitude and quality of vaccine-induced memory immune responses.Key messagesAfter subunit Mtb vaccination with H1-DDA/TDB, IL-23 but not IL-17A contributes to vaccine-induced early protection against infection with Mtb.IL-17F does not compensate for IL-17A deficiency in terms of H1-DDA/TDB-induced protection against Mtb infection.IL 23 promotes the H1-DDA/TDB-induced accumulation of effector memory T cells independently of IL 17A.IL-23 arbitrates the induction of H1-specific IFN-γ−TNF+IL-2+double-positive multifunctional CD4 T cells after subunit Mtb vaccination in an IL-17A-independent manner.Graphical abstract

Published

2021

16. Systematic pattern analyses of Vδ2+ TCRs reveal that shared 'public' Vδ2+ γδ T cell clones are a consequence of rearrangement bias and a higher expansion status

Author

Lihua Deng, Anna Harms, Sarina Ravens, Immo Prinz, and Likai Tan

Subjects

Immunology, Immunology and Allergy

Abstract

BackgroundVγ9Vδ2+T cells are a major innate T cell subset in human peripheral blood. Their Vδ2+VDJ-rearrangements are short and simple in the fetal thymus and gradually increase in diversity and CDR3 length along with development. So-called “public” versions of Vδ2+TCRs are shared among individuals of all ages. However, it is unclear whether such frequently occurring “public” Vγ9Vδ2+T cell clones are derived from the fetal thymus and whether they are fitter to proliferate and persist than infrequent “private” clones.MethodsShared “public” Vδ2+TCRs were identified from Vδ2+TCR-repertoires collected from 89 individuals, including newborns (cord blood), infants, and adults (peripheral blood). Distance matrices of Vδ2+CDR3 were generated by TCRdist3 and then embedded into a UMAP for visualizing the heterogeneity of Vδ2+TCRs.ResultsVδ2+CDR3 distance matrix embedded by UMAP revealed that the heterogeneity of Vδ2+TCRs is primarily determined by the J-usage and CDR3aa length, while age or publicity-specific motifs were not found. The most prevalent public Vδ2+TCRs showed germline-like rearrangement with low N-insertions. Age-related features were also identified. Public Vδ2+TRDJ1TCRs from cord blood showed higher N-insertions and longer CDR3 lengths. Synonymous codons resulting from VDJ rearrangement also contribute to the generation of public Vδ2+TCRs. Each public TCR was always produced by multiple different transcripts, even with different D gene usage, and the publicity of Vδ2+TCRs was positively associated with expansion status.ConclusionTo conclude, the heterogeneity of Vδ2+TCRs is mainly determined byTRDJ-usage and the length of CDR3aa sequences. Public Vδ2+TCRs result from germline-like rearrangement and synonymous codons, associated with a higher expansion status.

Published

2022

17. Healthy-like CD4+ Regulatory and CD4+ Conventional T-Cell Receptor Repertoires Predict Protection from GVHD Following Donor Lymphocyte Infusion

Author

Jessica Schneider, Leonie Kuhlmann, Yankai Xiao, Solaiman Raha, Günter Bernhardt, Michael Stadler, Felicitas Thol, Michael Heuser, Matthias Eder, Arnold Ganser, Sarina Ravens, Reinhold Förster, Immo Prinz, Christian Koenecke, and Christian R. Schultze-Florey

Subjects

Inorganic Chemistry, Organic Chemistry, General Medicine, Physical and Theoretical Chemistry, donor lymphocyte infusion, immunotherapy, graft-versus-host disease, allogeneic hematopoietic stem-cell transplantation, Treg cells, TRB sequencing, TCR repertoire, Molecular Biology, Spectroscopy, Catalysis, Computer Science Applications

Abstract

Donor lymphocyte infusion (DLI) can (re-)induce durable remission in relapsing patients after allogeneic hematopoietic stem-cell transplantation (alloHSCT). However, DLI harbors the risk of increased non-relapse mortality due to the co-occurrence of graft-versus-host disease (GVHD). GVHD onset may be caused or accompanied by changes in the clonal T-cell receptor (TCR) repertoire. To investigate this, we analyzed T cells in a cohort of 21 patients receiving DLI after alloHSCT. We performed deep T-cell receptor β (TRB) sequencing of sorted CD4+CD25+CD127low regulatory T cells (Treg cells) and CD4+ conventional T cells (Tcon cells) in order to track longitudinal changes in the TCR repertoire. GVHD following DLI was associated with less diverse but clonally expanded CD4+CD25+CD127low Treg and CD4+ Tcon TCR repertoires, while patients without GVHD exhibited healthy-like repertoire properties. Moreover, the diversification of the repertoires upon GVHD treatment was linked to steroid-sensitive GVHD, whereas decreased diversity was observed in steroid-refractory GVHD. Finally, the unbiased sample analysis revealed that the healthy-like attributes of the CD4+CD25+CD127low Treg TCR repertoire were associated with reduced GVHD incidence. In conclusion, CD4+CD25+CD127low Treg and CD4+ Tcon TRB repertoire dynamics may provide a helpful real-time tool to improve the diagnosis and monitoring of treatment in GVHD following DLI.

Published

2022

18. High-Dose Mycobacterium tuberculosis H37rv Infection in IL-17A- and IL-17A/F-Deficient Mice

Author

Kristina Ritter, Jochen Behrends, Dominik Rückerl, Alexandra Hölscher, Johanna Volz, Immo Prinz, and Christoph Hölscher

Subjects

tuberculosis, rodent, cytokines, IL-17A, IL-17F, neutrophils, General Medicine

Abstract

During experimental tuberculosis (TB), interleukin (IL)-17A appears to be involved in the formation of lung granulomas, possibly through the attraction of neutrophils to the sites of infection. However, the protective impact of cytokine appears to depend on the degree of its induction. Hence, robust production of IL-17A in mice infected with the hypervirulent isolate Mycobacterium tuberculosis (Mtb) HN878 mediates protection, while the cytokine is dispensable for protective immune responses against low-dose infection with the less virulent strain H37rv. Here, we show that after experimental infection with high doses of Mtb H37rv, IL-17A-deficient (−/−) mice exhibited high susceptibility to the infection, which was mediated by the strong accumulation of neutrophils in the infected lung tissue. Accordingly, we observed nearly unrestricted bacterial replication within the neutrophils, indicating that they may serve as a survival niche for Mtb. By use of IL-17A/IL-17F-double-deficient mice, we demonstrated that the susceptibility in the absence of IL-17A is mediated by a compensatory expression of IL-17F, which, however, appeared not to be dependent on neutrophils. Together, our results illustrate the compensatory potential of the Th17-secreted cytokines IL-17A and IL-17F in the context of experimental TB and once again emphasize the detrimental effect of excessive neutrophil infiltration in response to Mtb.

Published

2022

19. Cross-Reactive T Cell Response Exists in Chronic Lymphocytic Choriomeningitis Virus Infection upon Pichinde Virus Challenge

Author

Jasmin Mischke, Sebastian Klein, Austin Seamann, Immo Prinz, Liisa Selin, Dario Ghersi, Markus Cornberg, and Anke R.M. Kraft

Subjects

Mice, Inbred C57BL, Mice, Infectious Diseases, Virology, Receptors, Antigen, T-Cell, heterologous immunity, LCMV, PICV, virus-specific T cells, cross-reactive T cells, sequential infection, chronic infection, Animals, Lymphocytic choriomeningitis virus, Arenaviridae Infections, Lymphocytic Choriomeningitis, CD8-Positive T-Lymphocytes, Pichinde virus

Abstract

Immunological memory to a previously encountered pathogen can influence the outcome of a sequential infection, which is called heterologous immunity. Lymphocytic choriomeningitis virus (LCMV) immune mice develop a NP205-specific T cell response that is cross-reactive to Pichinde virus infection (PICV). So far, limited data are available if cross-reactive T cell responses appear also during chronic infections with exhausted T cell responses. Exhaustion in chronic viral infections can be treated with checkpoint inhibitors, which might affect heterologous outcomes unexpectedly. The aim of this study was to investigate the cross-reactive immune response in chronic LCMV clone 13 (LCMVcl13) infection during primary PICV infection at phenotypic, functional, and T cell receptor (TCR) level. Moreover, the influence of checkpoint inhibitor therapy with αPD-L1 was investigated. Cross-reactive NP205-specific responses were present and functional in the chronic environment. Additionally, chronically infected mice were also protected from PICV mediated weight loss compared to naive PICV mice. An altered phenotype of NP205-specific T cells was detectable, but no major differences in the clonality and diversity of their TCR repertoire were observed. Checkpoint inhibitor treatment with αPD-L1 did alter chronic LCMV infection but had no major effect on heterologous immunity to PICV. Our study demonstrated that cross-reactive CD8+ T cells also exist in the setting of chronic infection, indicating a clinically relevant role of cross-reactive T cells in chronic infections.

Published

2022

20. Healthy-like CD4

Author

Jessica, Schneider, Leonie, Kuhlmann, Yankai, Xiao, Solaiman, Raha, Günter, Bernhardt, Michael, Stadler, Felicitas, Thol, Michael, Heuser, Matthias, Eder, Arnold, Ganser, Sarina, Ravens, Reinhold, Förster, Immo, Prinz, Christian, Koenecke, and Christian R, Schultze-Florey

Subjects

Lymphocyte Transfusion, Receptors, Antigen, T-Cell, alpha-beta, Hematopoietic Stem Cell Transplantation, Graft vs Host Disease, Humans, T-Lymphocytes, Regulatory

Abstract

Donor lymphocyte infusion (DLI) can (re-)induce durable remission in relapsing patients after allogeneic hematopoietic stem-cell transplantation (alloHSCT). However, DLI harbors the risk of increased non-relapse mortality due to the co-occurrence of graft-versus-host disease (GVHD). GVHD onset may be caused or accompanied by changes in the clonal T-cell receptor (TCR) repertoire. To investigate this, we analyzed T cells in a cohort of 21 patients receiving DLI after alloHSCT. We performed deep T-cell receptor β (

Published

2022

21. Intrahepatic CD69

Author

Elena, Bruni, Matteo Maria, Cimino, Matteo, Donadon, Roberta, Carriero, Sara, Terzoli, Rocco, Piazza, Sarina, Ravens, Immo, Prinz, Valentina, Cazzetta, Paolo, Marzano, Paolo, Kunderfranco, Clelia, Peano, Cristiana, Soldani, Barbara, Franceschini, Federico Simone, Colombo, Cecilia, Garlanda, Alberto, Mantovani, Guido, Torzilli, Joanna, Mikulak, and Domenico, Mavilio

Subjects

Lymphocytes, Tumor-Infiltrating, T-Lymphocyte Subsets, Tumor Microenvironment, Humans, Receptors, Antigen, T-Cell, gamma-delta, Immunotherapy, Colorectal Neoplasms

Abstract

More than 50% of all patients with colorectal cancer (CRC) develop liver metastases (CLM), a clinical condition characterized by poor prognosis and lack of reliable prognostic markers. Vδ1 cells are a subset of tissue-resident gamma delta (γδ) T lymphocytes endowed with a broad array of antitumor functions and showing a natural high tropism for the liver. However, little is known about their impact in the clinical outcomes of CLM.We isolated human γδ T cells from peripheral blood (PB) and peritumoral (PT) tissue of 93 patients undergone surgical procedures to remove CLM. The phenotype of freshly purified γδ T cells was assessed by multiparametric flow cytometry, the transcriptional profiles by single cell RNA-sequencing, the functional annotations by Gene Ontology enrichment analyses and the clonotype by γδ T cell receptor (TCR)-sequencing.The microenvironment of CLM is characterized by a heterogeneous immune infiltrate comprising different subsets of γδ tumor-infiltrating lymphocytes (TILs) able to egress the liver and re-circulate in PB. Vδ1 T cells represent the largest population of γδ TILs within the PT compartment of CLM that is greatly enriched in Vδ1 T effector (TThe enrichment of tissue-resident CD69

Published

2022

22. Antigen-specific γδ T cells contribute to cytomegalovirus control after stem cell transplantation

Author

Immo Prinz and Christian Koenecke

Subjects

Immunology, Immunology and Allergy

Published

2023

23. Individual Epitope-Specific CD8+ T Cell Immune Responses Are Shaped Differently during Chronic Viral Infection

Author

Sebastian Klein, Jasmin Mischke, Finn Beruldsen, Immo Prinz, Dinler A. Antunes, Markus Cornberg, and Anke R. M. Kraft

Subjects

Microbiology (medical), Infectious Diseases, General Immunology and Microbiology, Immunology and Allergy, CD8+ T cells, T cell receptor repertoire, chronic viral infection, checkpoint inhibitor therapy, lymphocytic choriomeningitis virus, Molecular Biology

Abstract

A hallmark in chronic viral infections are exhausted antigen-specific CD8+ T cell responses and the inability of the immune system to eliminate the virus. Currently, there is limited information on the variability of epitope-specific T cell exhaustion within one immune response and the relevance to the T cell receptor (TCR) repertoire. The aim of this study was a comprehensive analysis and comparison of three lymphocytic choriomeningitis virus (LCMV) epitope-specific CD8+ T cell responses (NP396, GP33 and NP205) in a chronic setting with immune intervention, e.g., immune checkpoint inhibitor (ICI) therapy, in regard to the TCR repertoire. These responses, though measured within the same mice, were individual and independent from each other. The massively exhausted NP396-specific CD8+ T cells revealed a significantly reduced TCR repertoire diversity, whereas less-exhausted GP33-specific CD8+ T cell responses were rather unaffected by chronicity in regard to their TCR repertoire diversity. NP205-specific CD8+ T cell responses showed a very special TCR repertoire with a prominent public motif of TCR clonotypes that was present in all NP205-specific responses, which separated this from NP396- and GP33-specific responses. Additionally, we showed that TCR repertoire shifts induced by ICI therapy are heterogeneous on the epitope level, by revealing profound effects in NP396-, less severe and opposed effects in NP205-, and minor effects in GP33-specific responses. Overall, our data revealed individual epitope-specific responses within one viral response that are differently affected by exhaustion and ICI therapy. These individual shapings of epitope-specific T cell responses and their TCR repertoires in an LCMV mouse model indicates important implications for focusing on epitope-specific responses in future evaluations for therapeutic approaches, e.g., for chronic hepatitis virus infections in humans.

Published

2023

24. Systematic pattern analyses of Vδ2

Author

Lihua, Deng, Anna, Harms, Sarina, Ravens, Immo, Prinz, and Likai, Tan

Subjects

Adult, T-Lymphocyte Subsets, Infant, Newborn, Infant, Humans, Receptors, Antigen, T-Cell, gamma-delta, Thymus Gland, Intraepithelial Lymphocytes, Clone Cells

Abstract

Vγ9Vδ2Shared "public" Vδ2Vδ2To conclude, the heterogeneity of Vδ2

Published

2022

25. High-Dose

Author

Kristina, Ritter, Jochen, Behrends, Dominik, Rückerl, Alexandra, Hölscher, Johanna, Volz, Immo, Prinz, and Christoph, Hölscher

Subjects

Mice, Inbred C57BL, Mice, Knockout, Mice, Interleukin-17, Animals, Cytokines, Tuberculosis, Mycobacterium tuberculosis

Abstract

During experimental tuberculosis (TB), interleukin (IL)-17A appears to be involved in the formation of lung granulomas, possibly through the attraction of neutrophils to the sites of infection. However, the protective impact of cytokine appears to depend on the degree of its induction. Hence, robust production of IL-17A in mice infected with the hypervirulent isolate

Published

2022

26. IL-17A–producing γδT cells promote muscle regeneration in a microbiota-dependent manner

Author

Alexander O. Mann, Bola S. Hanna, Andrés R. Muñoz-Rojas, Inga Sandrock, Immo Prinz, Christophe Benoist, and Diane Mathis

Subjects

Mice, Inbred C57BL, Mice, Microbiota, Muscles, T-Lymphocytes, Interleukin-17, Immunology, Animals, Regeneration, Immunology and Allergy, Receptors, Antigen, T-Cell, gamma-delta, Muscle Development

Abstract

Subsequent to acute injury, skeletal muscle undergoes a stereotypic regenerative process that reestablishes homeostasis. Various types of innate and adaptive immunocytes exert positive or negative influences at specific stages along the course of muscle regeneration. We describe an unanticipated role for γδT cells in promoting healthy tissue recovery after injection of cardiotoxin into murine hindlimb muscle. Within a few days of injury, IL-17A–producing γδT cells displaying primarily Vγ6+ antigen receptors accumulated at the wound site. Punctual ablation experiments showed that these cells boosted early inflammatory events, notably recruitment of neutrophils; fostered the proliferation of muscle stem and progenitor cells; and thereby promoted tissue regeneration. Supplementation of mice harboring low numbers of IL-17A+ γδT cells with recombinant IL-17A largely reversed their inflammatory and reparative defects. Unexpectedly, the accumulation and influences of γδT cells in this experimental context were microbiota dependent, unveiling an orthogonal perspective on the treatment of skeletal muscle pathologies such as catastrophic wounds, wasting, muscular dystrophies, and myositides.

Published

2022

27. Ligand recognition by the γδ TCR and discrimination between homeostasis and stress conditions

Author

Malte Deseke and Immo Prinz

Subjects

Immunology, gamma-delta TCR, chemical and pharmacologic phenomena, Context (language use), Review Article, Mhc antigens, Major histocompatibility complex, Models, Biological, Antigen, Stress, Physiological, Animals, Homeostasis, Humans, Immunology and Allergy, T-cell receptor, Antigens, biology, ligands, Receptors, Antigen, T-Cell, gamma-delta, hemic and immune systems, Antigen recognition, antigen recognition, Infectious Diseases, biology.protein, Stress conditions, Gammadelta T cells, Neuroscience

Abstract

T lymphocytes comprise cells expressing either an αβ or a γδ TCR. The riddle how αβ TCRs are triggered by specific peptides presented in the context of MHC was elucidated some time ago. In contrast, the mechanisms that underlie antigen recognition by γδ TCRs are still baffling the scientific community. It is clear that activation of γδ TCRs does not necessarily depend on MHC antigen presentation. To date, diverse and largely host-cell-derived molecules have been identified as cognate antigens for the γδ TCR. However, for most γδ TCRs, the activating ligand is still unknown and many open questions with regard to physiological relevance and generalizable concepts remain. Especially the question of how γδ T cells can distinguish homeostatic from stress conditions via their TCR remains largely unresolved. Recent discoveries in the field might have paved the way towards a better understanding of antigen recognition by the γδ TCR and have made it conceivable to revise the current knowledge and contextualize the new findings.

Published

2020

28. IL‐17 regulates DC migration to the peribronchial LNs and allergen presentation in experimental allergic asthma

Author

Jelena Skuljec, Ruth Grychtol, Anika Habener, Adan Chari Jirmo, David S. DeLuca, Mandy Busse, Oliver D. Breiholz, Kathleen Dalüge, Immo Prinz, Gesine Hansen, and Christine Happle

Subjects

0301 basic medicine, Allergy, T cell, Immunology, Bronchi, Inflammation, Immunoglobulin E, Mice, 03 medical and health sciences, 0302 clinical medicine, Cell Movement, medicine, Animals, Immunology and Allergy, Eosinophilia, Mice, Knockout, Antigen Presentation, CD40, biology, Interleukin-17, hemic and immune systems, Dendritic Cells, T helper cell, Allergens, respiratory system, medicine.disease, Asthma, respiratory tract diseases, 030104 developmental biology, medicine.anatomical_structure, biology.protein, Lymph Nodes, Interleukin 17, medicine.symptom, 030215 immunology

Abstract

IL-17 is associated with different phenotypes of asthma, however, it is not fully elucidated how it influences induction and maintenance of asthma and allergy. In order to determine the role of IL-17 in development of allergic asthma, we used IL-17A/F double KO (IL-17A/F KO) and WT mice with or without neutralization of IL-17 in an experimental allergic asthma model and analyzed airway hyperresponsiveness, lung inflammation, T helper cell polarization, and DCs influx and activation. We report that the absence of IL-17 reduced influx of DCs into lungs and lung draining LNs. Compared to WT mice, IL-17A/F KO mice or WT mice after neutralization of IL-17A showed reduced airway hyperresponsiveness, eosinophilia, mucus hypersecretion, and IgE levels. DCs from draining LNs of allergen-challenged IL-17A/F KO mice showed a reduction in expression of migratory and costimulatory molecules CCR7, CCR2, MHC-II, and CD40 compared to WT DCs. Moreover, in vivo stimulation of adoptively transferred antigen-specific cells was attenuated in lung-draining LNs in the absence of IL-17. Thus, we report that IL-17 enhances airway DC activation, migration, and function. Consequently, lack of IL-17 leads to reduced antigen-specific T cell priming and impaired development of experimental allergic asthma.

Published

2020

29. Three Layers of Intestinal γδ T Cells Talk Different Languages With the Microbiota

Author

Francesca Rampoldi and Immo Prinz

Subjects

Mice, Microbiota, Immunology, Immunology and Allergy, Animals, Humans, Receptors, Antigen, T-Cell, gamma-delta, Lymphocytes, Intestinal Mucosa, Intraepithelial Lymphocytes, Immunity, Innate, Language

Abstract

The mucosal surfaces of our body are the main contact site where the immune system encounters non-self molecules from food-derived antigens, pathogens, and symbiotic bacteria. γδ T cells are one of the most abundant populations in the gut. Firstly, they include intestinal intraepithelial lymphocytes, which screen and maintain the intestinal barrier integrity in close contact with the epithelium. A second layer of intestinal γδ T cells is found among lamina propria lymphocytes (LPL)s. These γδ LPLs are able to produce IL-17 and likely have functional overlap with local Th17 cells and innate lymphoid cells. In addition, a third population of γδ T cells resides within the Peyer´s patches, where it is probably involved in antigen presentation and supports the mucosal humoral immunity. Current obstacles in understanding γδ T cells in the gut include the lack of information on cognate ligands of the γδ TCR and an incomplete understanding of their physiological role. In this review, we summarize and discuss what is known about different subpopulations of γδ T cells in the murine and human gut and we discuss their interactions with the gut microbiota in the context of homeostasis and pathogenic infections.

Published

2022

30. PD-1/CTLA-4 blockade leads to expansion of CD8+PD-1int TILs and results in tumor remission in experimental liver cancer

Author

Sandra Bufe, Artur Zimmermann, Sarina Ravens, Immo Prinz, Laura Elisa Buitrago-Molina, Robert Geffers, Norman Woller, Florian Kühnel, Steven R. Talbot, Fatih Noyan, Michael Peter Manns, Heiner Wedemeyer, Matthias Hardtke-Wolenski, Elmar Jaeckel, and Ana C. Davalos-Misslitz

Subjects

Oncology, Hepatology, Medizin

Abstract

Background: Checkpoint inhibitors act on exhausted CD8+ T cells and restore their effector function in chronic infections and cancer. The underlying mechanisms of action appear to differ between different types of cancer and are not yet fully understood. Methods: Here, we established a new orthotopic HCC model to study the effects of checkpoint blockade on exhausted CD8+ tumor-infiltrating lymphocytes (TILs). The tumors expressed endogenous levels of HA, which allowed the study of tumor-specific T cells Results: The induced tumors developed an immune-resistant TME in which few T cells were found. The few recovered CD8+ TILs were mostly terminally exhausted and expressed high levels of PD-1. PD-1/CTLA-4 blockade resulted in a strong increase in the number of CD8+ TILs expressing intermediate amounts of PD-1, also called progenitor-exhausted CD8+ TILs, while terminally exhausted CD8+ TILs were almost absent in the tumors of treated mice. Although transferred naïve tumor-specific T cells did not expand in the tumors of untreated mice, they expanded strongly after treatment and generated progenitor-exhausted but not terminally exhausted CD8+ TILs. Unexpectedly, although progenitor-exhausted CD8+ TILs mediated the anti-tumor response after treatment with minimal changes in their transcriptional profile. Conclusion: In our model, few doses of checkpoint inhibitors during the priming of transferred CD8+ tumor-specific T cells were sufficient to induce tumor remission. PD-1/CTLA-4 blockade neither reinvigorated the effector function of CD8+PD-1high TILs nor changed the functionality of CD8+PD-1int TILs. Therefore, PD-1/CTLA-4 blockade has an ameliorative effect the expansion of recently primed CD8+ T cells while preventing their development into CD8+PD-1high TILs in the TME. This finding could have important implications for future T cell therapies.

Published

2022

31. A monoclonal Trd chain supports the development of the complete set of functional γδ T cell lineages

Author

Anne M. Hahn, Lisa Vogg, Stefanie Brey, Andrea Schneider, Simon Schäfer, Ralph Palmisano, Anna Pavlova, Inga Sandrock, Likai Tan, Alina S. Fichtner, Immo Prinz, Sarina Ravens, and Thomas H. Winkler

Subjects

General Biochemistry, Genetics and Molecular Biology

Published

2023

32. IL-17A-producing CD8+T cells promote PDAC via induction of inflammatory cancer-associated fibroblasts

Author

Felix Simon Ruben Picard, Veronika Lutz, Anna Brichkina, Felix Neuhaus, Teresa Ruckenbrod, Anna Hupfer, Hartmann Raifer, Matthias Klein, Tobias Bopp, Petra Ina Pfefferle, Rajkumar Savai, Immo Prinz, Ari Waisman, Sonja Moos, Hyun-Dong Chang, Stefan Heinrich, Detlef K Bartsch, Malte Buchholz, Shiv Singh, Mengyu Tu, Lukas Klein, Christian Bauer, Robert Liefke, Andreas Burchert, Ho-Ryun Chung, Philipp Mayer, Thomas M Gress, Matthias Lauth, Matthias Gaida, and Magdalena Huber

Subjects

Gastroenterology

Abstract

ObjectivePancreatic ductal adenocarcinoma (PDAC) is characterised by an abundant desmoplastic stroma composed of cancer-associated fibroblasts (CAF) and interspersed immune cells. A non-canonical CD8+T-cell subpopulation producing IL-17A (Tc17) promotes autoimmunity and has been identified in tumours. Here, we evaluated the Tc17 role in PDAC.DesignInfiltration of Tc17 cells in PDAC tissue was correlated with patient overall survival and tumour stage. Wild-type (WT) orIl17ra-/-quiescent pancreatic stellate cells (qPSC) were exposed to conditional media obtained from Tc17 cells (Tc17-CM); moreover, co-culture of Tc17-CM-induced inflammatory (i)CAF (Tc17-iCAF) with tumour cells was performed. IL-17A/F-, IL-17RA-, RAG1-deficient andFoxn1nu/numice were used to study the Tc17 role in subcutaneous and orthotopic PDAC mouse models.ResultsIncreased abundance of Tc17 cells highly correlated with reduced survival and advanced tumour stage in PDAC. Tc17-CM induced iCAF differentiation as assessed by the expression of iCAF-associated genes via synergism of IL-17A and TNF. Accordingly, IL-17RA controlled the responsiveness of qPSC to Tc17-CM. Pancreatic tumour cells co-cultured with Tc17-iCAF displayed enhanced proliferation and increased expression of genes implicated in proliferation, metabolism and protection from apoptosis. Tc17-iCAF accelerated growth of mouse and human tumours inRag1-/-andFoxn1nu/numice, respectively. Finally,Il17ra-expressed by fibroblasts was required for Tc17-driven tumour growth in vivo.ConclusionsWe identified Tc17 as a novel protumourigenic CD8+T-cell subtype in PDAC, which accelerated tumour growth via IL-17RA-dependent stroma modification. We described a crosstalk between three cell types, Tc17, fibroblasts and tumour cells, promoting PDAC progression, which resulted in poor prognosis for patients.

Published

2023

33. A CMV-induced adaptive human Vδ1+ γδ T cell clone recognizes HLA-DR

Author

Malte Deseke, Francesca Rampoldi, Inga Sandrock, Eva Borst, Heike Böning, George Liam Ssebyatika, Carina Jürgens, Nina Plückebaum, Maleen Beck, Ahmed Hassan, Likai Tan, Abdi Demera, Anika Janssen, Peter Steinberger, Christian Koenecke, Abel Viejo-Borbolla, Martin Messerle, Thomas Krey, and Immo Prinz

Subjects

T-Lymphocyte Subsets, Immunology, Cytomegalovirus Infections, Immunology and Allergy, Humans, Receptors, Antigen, T-Cell, gamma-delta, HLA-DR Antigens, Intraepithelial Lymphocytes, Clone Cells

Abstract

The innate and adaptive roles of γδ T cells and their clonal γδ T cell receptors (TCRs) in immune responses are still unclear. Recent studies of γδ TCR repertoire dynamics showed massive expansion of individual Vδ1+ γδ T cell clones during viral infection. To judge whether such expansion is random or actually represents TCR-dependent adaptive immune responses, information about their cognate TCR ligands is required. Here, we used CRISPR/Cas9-mediated screening to identify HLA-DRA, RFXAP, RFX5, and CIITA as required for target cell recognition of a CMV-induced Vγ3Vδ1+ TCR, and further characterization revealed a direct interaction of this Vδ1+ TCR with the MHC II complex HLA-DR. Since MHC II is strongly upregulated by interferon-γ, these results suggest an inflammation-induced MHC-dependent immune response of γδ T cells.

Published

2021

34. IL-4-Producing Vγ1+/Vδ6+ γδ T Cells Sustain Germinal Center Reactions in Peyer’s Patches of Mice

Author

Anneke Wilharm, Anna-Lena Juergens, Leon Ullrich, Yvonne Lueder, Joana Barros-Martins, Inga Sandrock, Koichi Ikuta, Immo Prinz, Anika Janssen, Gwendolyn E. Patzer, Anja Bubke, Abdi Demera, and Francesca Rampoldi

Subjects

Salmonella typhimurium, T cell, First line, Immunology, education, Stimulation, Biology, Lymphocyte Activation, γδ T cells, Lymphocyte Depletion, Peyer's Patches, Immune system, medicine, Animals, Immunology and Allergy, Vγ1+ T cells, Intestinal Mucosa, Immunity, Mucosal, Intraepithelial Lymphocytes, Cells, Cultured, Interleukin 4, health care economics and organizations, Original Research, Cell Proliferation, Mice, Knockout, B-Lymphocytes, T-cell receptor, IL-4, Germinal center, Cell Differentiation, Receptors, Antigen, T-Cell, gamma-delta, RC581-607, Immunoglobulin Class Switching, Small intestine, Immunoglobulin A, Cell biology, Disease Models, Animal, Phenotype, medicine.anatomical_structure, germinal center, Salmonella Infections, Interleukin-4, Peyer’s patches, Immunologic diseases. Allergy, IgA, Signal Transduction

Abstract

The mucosal immune system is the first line of defense against pathogens. Germinal centers (GCs) in the Peyer’s patches (PPs) of the small intestine are constantly generated through stimulation of the microbiota. In this study, we investigated the role of γδ T cells in the GC reactions in PPs. Most γδ T cells in PPs localized in the GCs and expressed a TCR composed of Vγ1 and Vδ6 chains. By using mice with partial and total γδ T cell deficiencies, we found that Vγ1+/Vδ6+T cells can produce high amounts of IL-4, which drives the proliferation of GC B cells as well as the switch of GC B cells towards IgA. Therefore, we conclude that γδ T cells play a role in sustaining gut homeostasis and symbiosisviasupporting the GC reactions in PPs.

Published

2021

35. Lymphatic migration of unconventional T cells promotes site-specific immunity in distinct lymph nodes

Author

Marco A. Ataide, Konrad Knöpper, Paulina Cruz de Casas, Milas Ugur, Sarah Eickhoff, Mangge Zou, Haroon Shaikh, Apurwa Trivedi, Anika Grafen, Tao Yang, Immo Prinz, Knut Ohlsen, Mercedes Gomez de Agüero, Andreas Beilhack, Jochen Huehn, Mauro Gaya, Antoine-Emmanuel Saliba, Georg Gasteiger, Wolfgang Kastenmüller, Centre d'Immunologie de Marseille - Luminy (CIML), and Aix Marseille Université (AMU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Mice, Inbred C57BL, Disease Models, Animal, Mice, Infectious Diseases, T-Lymphocytes, [SDV]Life Sciences [q-bio], Immunology, Immunity, Receptors, Antigen, T-Cell, Animals, Immunology and Allergy, Mice, Transgenic, Lymph Nodes

Abstract

Lymphatic transport of molecules and migration of myeloid cells to lymph nodes (LNs) continuously inform lymphocytes on changes in drained tissues. Here, using LN transplantation, single-cell RNA-seq, spectral flow cytometry, and a transgenic mouse model for photolabeling, we showed that tissue-derived unconventional T cells (UTCs) migrate via the lymphatic route to locally draining LNs. As each tissue harbored a distinct spectrum of UTCs with locally adapted differentiation states and distinct T cell receptor repertoires, every draining LN was thus populated by a distinctive tissue-determined mix of these lymphocytes. By making use of single UTC lineage-deficient mouse models, we found that UTCs functionally cooperated in interconnected units and generated and shaped characteristic innate and adaptive immune responses that differed between LNs that drained distinct tissues. Lymphatic migration of UTCs is, therefore, a key determinant of site-specific immunity initiated in distinct LNs with potential implications for vaccination strategies and immunotherapeutic approaches.

Published

2022

36. Inflammation triggers ILC3 patrolling of the intestinal barrier

Author

Angélique Jarade, Zacarias Garcia, Solenne Marie, Abdi Demera, Immo Prinz, Philippe Bousso, James P. Di Santo, and Nicolas Serafini

Subjects

Inflammation, Immunology, Immunology and Allergy, Cytokines, Humans, Lymphocytes, Intestinal Mucosa, Ligands, Immunity, Innate

Abstract

An orchestrated cellular network, including adaptive lymphocytes and group 3 innate lymphoid cells (ILC3s), maintains intestinal barrier integrity and homeostasis. T cells can monitor environmental insults through constitutive circulation, scanning tissues and forming immunological contacts, a process named immunosurveillance. In contrast, the dynamics of intestinal ILC3s are unknown. Using intravital imaging, we observed that villus ILC3s were largely immotile at steady state but acquired migratory ‘patrolling’ attributes and enhanced cytokine expression in response to inflammation. We showed that T cells, the chemokine CCL25 and bacterial ligands regulated intestinal ILC3 behavior and that loss of patrolling behavior by interleukin-22 (IL-22)-producing ILC3s altered the intestinal barrier through increased epithelial cell death. Collectively, we identified notable differences between the behavior of ILC3s and T cells, with a prominent adaptation of intestinal ILC3s toward mucosal immunosurveillance after inflammation.

Published

2021

37. Interleukin-10 Improves Stroke Outcome by Controlling the Detrimental Interleukin-17A Response

Author

Marius Piepke, Bettina H. Clausen, Peter Ludewig, Jonas H. Vienhues, Tanja Bedke, Ehsan Javidi, Björn Rissiek, Larissa Jank, Leonie Brockmann, Inga Sandrock, Karoline Degenhardt, Immo Prinz, Richard A. Flavell, Yasushi Kobayashi, Thomas Renne, Christian Gerloff, Samuel Huber, Tim Magnus, and Mathias Gelderblom

Abstract

Background: Lymphocytes have dichotomous functions in ischemic stroke. Regulatory T cells are protective, while IL-17A from innate lymphocytes promotes the infarcts growth. With recent advances of T cell-subtype specific transgenic mouse models it now has become possible to study the complex interplay of T cell subpopulations in ischemic stroke.Methods: In a murine model of experimental stroke we analyzed the effects of IL-10 on the functional outcome for up to 14 days post-ischemia and defined the source of IL-10 in ischemic brains based on immunohistochemistry, flow cytometry, and bone marrow chimeric mice. We used neutralizing IL-17A antibodies, intrathecal IL-10 injections, and transgenic mouse models which harbor a deletion of the IL-10R on distinct T cell subpopulations to further explore the interplay between IL-10 and IL-17A pathways in the ischemic brain. Results: We demonstrate that IL-10 deficient mice exhibit significantly increased infarct sizes on days three and seven and enlarged brain atrophy and impaired neurological outcome on day fourteen following tMCAO. In ischemic brains IL-10 producing immune cells included regulatory T cells, macrophages, and microglia. Neutralization of IL-17A following stroke reversed the worse outcome in IL-10 deficient mice and intracerebral treatment with recombinant IL-10 revealed that IL-10 controlled IL-17A positive lymphocytes in ischemic brains. Importantly, IL-10 acted differentially on αβ and γδ T cells. IL-17A producing CD4+ αβ T cells were directly controlled via their IL-10-receptor (IL-10R), whereas IL-10 by itself had no direct effect on the IL-17A production in γδ T cells. The control of the IL-17A production in γδ T cells depended on an intact IL10R signaling in regulatory T cells (Tregs). Conclusions: Taken together, our data indicate a key function of IL-10 in restricting the detrimental IL-17A-signaling in stroke and further supports that IL-17A is a therapeutic opportunity for stroke treatment.

Published

2021

38. The Detrimental Role of Regulatory T Cells in Nonalcoholic Steatohepatitis

Author

Fatih Noyan, Martin Hapke, Maren Lieber, Katharina Luise Hupa-Breier, Christian Koenecke, Ana Clara Marques Davalos-Misslitz, Heiner Wedemeyer, Jerome Schlue, Michael P. Manns, Laura Elisa Buitrago-Molina, Solaiman Raha, Elmar Jaeckel, Matthias Hardtke-Wolenski, Christine S. Falk, Janine Dywicki, and Immo Prinz

Subjects

Nonalcoholic steatohepatitis, Metabolic inflammation, CD3 Complex, Medizin, chemical and pharmacologic phenomena, RC799-869, Biology, Adaptive Immunity, Diet, High-Fat, digestive system, T-Lymphocytes, Regulatory, Non-alcoholic Fatty Liver Disease, medicine, Macrophage, Animals, Immunologic Factors, Aspartate Aminotransferases, Alanine aminotransferase, Inflammation, Mice, Inbred BALB C, Innate immune system, Hepatology, nutritional and metabolic diseases, Alanine Transaminase, Original Articles, Diseases of the digestive system. Gastroenterology, medicine.disease, Acquired immune system, Adoptive Transfer, digestive system diseases, Disease Models, Animal, Immunology, Disease Progression, Original Article, Steatosis, Diet, Carbohydrate Loading

Abstract

Nonalcoholic steatohepatitis (NASH) is induced by steatosis and metabolic inflammation. While involvement of the innate immune response has been shown, the role of the adaptive immune response in NASH remains controversial. Likewise, the role of regulatory T cells (Treg) in NASH remains unclear although initial clinical trials aim to target these regulatory responses. High-fat high-carbohydrate (HF-HC) diet feeding of NASH-resistant BALB/c mice as well as the corresponding recombination activating 1 (Rag)-deficient strain was used to induce NASH and to study the role of the adaptive immune response. HF-HC diet feeding induced strong activation of intrahepatic T cells in BALB/c mice, suggesting an antigen-driven effect. In contrast, the effects of the absence of the adaptive immune response was notable. NASH in BALB/c Rag1−/− mice was substantially worsened and accompanied by a sharp increase of M1-like macrophage numbers. Furthermore, we found an increase in intrahepatic Treg numbers in NASH, but either adoptive Treg transfer or anti-cluster of differentiation (CD)3 therapy unexpectedly increased steatosis and the alanine aminotransferase level without otherwise affecting NASH. Conclusion: Although intrahepatic T cells were activated and marginally clonally expanded in NASH, these effects were counterbalanced by increased Treg numbers. The ablation of adaptive immunity in murine NASH led to marked aggravation of NASH, suggesting that Tregs are not regulators of metabolic inflammation but rather enhance it. OA Förderung 2022

Published

2021

39. Broad Cytotoxic Targeting of Acute Myeloid Leukemia by Polyclonal Delta One T Cells

Author

David Vermijlen, Bruno Silva-Santos, Biagio Di Lorenzo, Paola Tieppo, Maria Gomes da Silva, Immo Prinz, Tânia Carvalho, Sarina Ravens, Daniel V. Correia, André E. Simões, Francisco Caiado, T.N. Schumacher, Haakan Norell, Julie Déchanet-Merville, Composantes innées de la réponse immunitaire et différenciation (CIRID), Université Bordeaux Segalen - Bordeaux 2-Centre National de la Recherche Scientifique (CNRS), Institute for Immunology, Hannover Medical School [Hannover] (MHH), 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), Instituto de Medicina Molecular, Universidade de Lisboa (ULISBOA), and Universidade de Lisboa = University of Lisbon (ULISBOA)

Subjects

Cytotoxicity, Immunologic, Male, 0301 basic medicine, Cancer Research, Adoptive cell transfer, Myeloid, medicine.medical_treatment, Immunology, CD33, [SDV.CAN]Life Sciences [q-bio]/Cancer, Mice, SCID, Immunotherapy, Adoptive, Cell therapy, 03 medical and health sciences, 0302 clinical medicine, Mice, Inbred NOD, hemic and lymphatic diseases, medicine, Animals, Humans, Cytotoxic T cell, ComputingMilieux_MISCELLANEOUS, business.industry, Myeloid leukemia, Généralités, [SDV.MHEP.HEM]Life Sciences [q-bio]/Human health and pathology/Hematology, Immunotherapy, medicine.disease, 3. Good health, Leukemia, Myeloid, Acute, Leukemia, 030104 developmental biology, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Cancer research, [SDV.IMM]Life Sciences [q-bio]/Immunology, Female, business, T-Lymphocytes, Cytotoxic

Abstract

Acute myeloid leukemia (AML) remains a clinical challenge due to frequent chemotherapy resistance and deadly relapses. We are exploring the immunotherapeutic potential of peripheral blood Vd1 þ T cells, which associate with improved long-term survival of stem-cell transplant recipients but have not yet been applied as adoptive cell therapy. Using our clinical-grade protocol for expansion and differentiation of "Delta One T" (DOT) cells, we found DOT cells to be highly cytotoxic against AML primary samples and cell lines, including cells selected for resistance to standard chemotherapy. Unlike chemotherapy, DOT-cell targeting did not select for outgrowth of specific AML lineages, suggesting a broad recognition domain, an outcome that was consistent with the polyclonality of the DOT-cell T-cell receptor (TCR) repertoire. However, AML reactivity was only slightly impaired upon Vd1 þ TCR antibody blockade, whereas it was strongly dependent on expression of the NKp30 ligand, B7-H6. In contrast, DOT cells did not show reactivity against normal leukocytes, including CD33 þ or CD123 þ myeloid cells. Adoptive transfer of DOT cells in vivo reduced AML load in the blood and target organs of multiple human AML xenograft models and significantly prolonged host survival without detectable toxicity, thus providing proof-of-concept for DOT-cell application in AML treatment., SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2019

40. Styk1 is specifically expressed in NK1.1 + lymphocytes including NK, γδ T, and iNKT cells in mice, but is dispensable for their ontogeny and function

Author

Inga Sandrock, Abdi Demera, Ronald Naumann, Immo Prinz, Thierry Walzer, Anneke Wilharm, and Marie Marotel

Subjects

Kinase, Transgene, Immunology, Cell, Biology, Natural killer T cell, Receptor tyrosine kinase, Cell biology, medicine.anatomical_structure, biology.protein, medicine, Immunology and Allergy, STYK1, Receptor, Ex vivo

Abstract

Innate T cells, NK cells, and innate-like lymphocytes (ILCs) share transcriptional signatures that translate into overlapping developmental and functional programs. A prominent example for genes that are highly expressed in NK cells but not in ILCs is serine-threonine-tyrosine kinase 1 (Styk1 encoded by Styk1). We found Styk1 to be specifically expressed in lymphocytes positive for Killer cell lectin-like receptor subfamily B, member 1, also known as CD161 or NK1.1, i.e. in NK cell, αβ iNKT, and γδ NKT cell lineages. To investigate the role of Styk1 in the development and function of NK1.1+ innate T-cell subsets, we generated and analyzed a novel Styk1null mutant mouse line. Furthermore, we validated Styk1 expression in γδ NKT cells and in thymic, but not in peripheral invariant αβ iNKT cells through ex vivo analysis of a concomitantly generated transgenic Styk1 reporter mouse line. Despite the very specific expression of Styk1 in NK cells, γδ NKT cells, and thymic αβ iNKT, its absence did not alter homeostasis and function of these lineages. Thus, Styk1 expression is specific for NK cells and selected NK-like innate T-cell subsets, but dispensable for their development and function.

Published

2019

41. Guidelines for the use of flow cytometry and cell sorting in immunological studies (second edition)

Author

Lara Gibellini, Sussan Nourshargh, Susanna Cardell, Wlodzimierz Maslinski, Mar Felipo-Benavent, Florian Mair, Hans-Martin Jäck, Lilly Lopez, Klaus Warnatz, John Trowsdale, Diana Ordonez, Marcus Eich, William Hwang, Anne Cooke, Dirk Mielenz, Alberto Orfao, Winfried F. Pickl, Vladimir Benes, Alice Yue, T. Vincent Shankey, Maria Tsoumakidou, Virginia Litwin, Gelo Victoriano Dela Cruz, Andrea Cavani, Sara De Biasi, Larissa Nogueira Almeida, Jonathan J M Landry, Claudia Haftmann, Charlotte Esser, Ana Cumano, Anneke Wilharm, Francesco Dieli, Rudi Beyaert, Alessio Mazzoni, Burkhard Ludewig, Carlo Pucillo, Dirk H. Busch, Joe Trotter, Stipan Jonjić, Marc Veldhoen, Josef Spidlen, Aja M. Rieger, Dieter Adam, Srijit Khan, Todd A. Fehniger, Giuseppe Matarese, Maximilien Evrard, Christian Maueröder, Steffen Schmitt, Kristin A. Hogquist, Barry Moran, Raghavendra Palankar, Markus Feuerer, S Schmid, Susann Rahmig, Amy E. Lovett-Racke, James V. Watson, Megan K. Levings, Susanne Melzer, Dinko Pavlinic, Christopher M. Harpur, Christina Stehle, A. Graham Pockley, Toshinori Nakayama, Attila Tárnok, Juhao Yang, Michael Lohoff, Paulo Vieira, Francisco Sala-de-Oyanguren, Christian Kurts, Anastasia Gangaev, Alfonso Blanco, Hans Scherer, Regine J. Dress, Bruno Silva-Santos, Kiyoshi Takeda, Bimba F. Hoyer, Ilenia Cammarata, Daryl Grummitt, Isabel Panse, Günnur Deniz, Bianka Baying, Friederike Ebner, Esther Schimisky, Leo Hansmann, Thomas Kamradt, Edwin van der Pol, Daniel Scott-Algara, Anna Iannone, Giorgia Alvisi, Sebastian R. Schulz, Francesco Liotta, Irmgard Förster, Beatriz Jávega, Hans-Peter Rahn, Caetano Reis e Sousa, Livius Penter, Xuetao Cao, David P. Sester, Keisuke Goda, Peter Wurst, Iain B. McInnes, Ricardo T. Gazzinelli, Federica Piancone, Gerald Willimsky, Yotam Raz, Pärt Peterson, Wolfgang Fritzsche, Yvonne Samstag, Martin Büscher, Thomas Schüler, Susanne Hartmann, Robert J. Wilkinson, Anna E. S. Brooks, Steven L. C. Ketelaars, Catherine Sautès-Fridman, Anna Rubartelli, Petra Bacher, Katja Kobow, Marco A. Cassatella, Andrea Hauser, Henrik E. Mei, Kilian Schober, Silvia Della Bella, Graham Anderson, Michael D. Ward, Garth Cameron, Sebastian Lunemann, Katharina Kriegsmann, Katarzyna M. Sitnik, Brice Gaudilliere, Chantip Dang-Heine, Marcello Pinti, Paul Klenerman, Frank A. Schildberg, Joana Barros-Martins, Laura G. Rico, Hanlin Zhang, Christian Münz, Thomas Dörner, Jakob Zimmermann, Andrea M. Cooper, Jonni S. Moore, Andreas Diefenbach, Yanling Liu, Wolfgang Bauer, Tobit Steinmetz, Katharina Pracht, Leonard Tan, Peter K. Jani, Alan M. Stall, Petra Hoffmann, Christine S. Falk, Jasmin Knopf, Simon Fillatreau, Hans-Dieter Volk, Luis E. Muñoz, David L. Haviland, William W. Agace, Jonathan Rebhahn, Ljiljana Cvetkovic, Mohamed Trebak, Jordi Petriz, Mario Clerici, Diether J. Recktenwald, Anders Ståhlberg, Tristan Holland, Helen M. McGuire, Sa A. Wang, Christian Kukat, Thomas Kroneis, Laura Cook, Wan Ting Kong, Xin M. Wang, Britta Engelhardt, Pierre Coulie, Genny Del Zotto, Sally A. Quataert, Kata Filkor, Gabriele Multhoff, Bartek Rajwa, Federica Calzetti, Hans Minderman, Cosima T. Baldari, Jens Geginat, Hervé Luche, Gert Van Isterdael, Linda Schadt, Sophia Urbanczyk, Giovanna Borsellino, Liping Yu, Dale I. Godfrey, Achille Anselmo, Rachael C. Walker, Andreas Grützkau, David W. Hedley, Birgit Sawitzki, Silvia Piconese, Maria Yazdanbakhsh, Burkhard Becher, Ramon Bellmas Sanz, Michael Delacher, Hyun-Dong Chang, Immanuel Andrä, Hans-Gustaf Ljunggren, José-Enrique O'Connor, Ahad Khalilnezhad, Sharon Sanderson, Federico Colombo, Götz R. A. Ehrhardt, Inga Sandrock, Enrico Lugli, Christian Bogdan, James B. Wing, Susann Müller, Tomohiro Kurosaki, Derek Davies, Ester B. M. Remmerswaal, Kylie M. Quinn, Christopher A. Hunter, Andreas Radbruch, Timothy P. Bushnell, Anna Erdei, Sabine Adam-Klages, Pascale Eede, Van Duc Dang, Rieke Winkelmann, Thomas Korn, Gemma A. Foulds, Dirk Baumjohann, Matthias Schiemann, Manfred Kopf, Jan Kisielow, Lisa Richter, Jochen Huehn, Gloria Martrus, Alexander Scheffold, Jessica G. Borger, Sidonia B G Eckle, John Bellamy Foster, Anna Katharina Simon, Alicia Wong, Mübeccel Akdis, Gisa Tiegs, Toralf Kaiser, James McCluskey, Anna Vittoria Mattioli, Aaron J. Marshall, Hui-Fern Koay, Eva Orlowski-Oliver, Anja E. Hauser, J. Paul Robinson, Jay K. Kolls, Luca Battistini, Mairi McGrath, Jane L. Grogan, Natalio Garbi, Timothy Tree, Kingston H. G. Mills, Stefan H. E. Kaufmann, Wolfgang Schuh, Ryan R. Brinkman, Tim R. Mosmann, Vincenzo Barnaba, Andreas Dolf, Lorenzo Cosmi, Bo Huang, Andreia C. Lino, Baerbel Keller, René A. W. van Lier, Alexandra J. Corbett, Paul S. Frenette, Pleun Hombrink, Helena Radbruch, Sofie Van Gassen, Olivier Lantz, Lorenzo Moretta, Désirée Kunkel, Kirsten A. Ward-Hartstonge, Armin Saalmüller, Leslie Y. T. Leung, Salvador Vento-Asturias, Paola Lanuti, Alicia Martínez-Romero, Sarah Warth, Zhiyong Poon, Diana Dudziak, Andrea Cossarizza, Kovit Pattanapanyasat, Konrad von Volkmann, Jessica P. Houston, Agnès Lehuen, Andrew Filby, Pratip K. Chattopadhyay, Stefano Casola, Annika Wiedemann, Hannes Stockinger, Jürgen Ruland, Arturo Zychlinsky, Claudia Waskow, Katrin Neumann, Ari Waisman, Lucienne Chatenoud, Sudipto Bari, Kamran Ghoreschi, David W. Galbraith, Yvan Saeys, Hamida Hammad, Andrea Gori, Miguel López-Botet, Gabriel Núñez, Sabine Ivison, Michael Hundemer, Dorothea Reimer, Mark C. Dessing, Günter J. Hämmerling, Rudolf A. Manz, Tomas Kalina, Jonas Hahn, Holden T. Maecker, Hendy Kristyanto, Martin S. Davey, Henning Ulrich, Michael L. Dustin, Takashi Saito, Yousuke Takahama, Milena Nasi, Johanna Huber, Jürgen Wienands, Paolo Dellabona, Andreas Schlitzer, Michael D. Leipold, Kerstin H. Mair, Christian Peth, Immo Prinz, Chiara Romagnani, José M. González-Navajas, Josephine Schlosser, Marina Saresella, Matthias Edinger, Dirk Brenner, Nicole Baumgarth, Rikard Holmdahl, Fang-Ping Huang, Guadalupe Herrera, Malte Paulsen, Gergely Toldi, Luka Cicin-Sain, Reiner Schulte, Christina E. Zielinski, Thomas Winkler, Christoph Goettlinger, Philip E. Boulais, Jennie H M Yang, Antonio Celada, Heike Kunze-Schumacher, Julia Tornack, Florian Ingelfinger, Jenny Mjösberg, Andy Riddell, Leonie Wegener, Thomas Höfer, Christoph Hess, James P. Di Santo, Anna E. Oja, J. Kühne, Willem van de Veen, Mary Bebawy, Alberto Mantovani, Bart Everts, Giovanna Lombardi, Laura Maggi, Anouk von Borstel, Pia Kvistborg, Elisabetta Traggiai, A Ochel, Nima Aghaeepour, Charles-Antoine Dutertre, Matthieu Allez, Thomas Höllt, Wenjun Ouyang, Regina Stark, Maries van den Broek, Shimon Sakaguchi, Paul K. Wallace, Silvano Sozzani, Francesca LaRosa, Annette Oxenius, Malgorzata J. Podolska, Ivana Marventano, Wilhelm Gerner, Oliver F. Wirz, Britta Frehse, Gevitha Ravichandran, Martin Herrmann, Carl S. Goodyear, Gary Warnes, Helen Ferry, Stefan Frischbutter, Tim R. Radstake, Salomé LeibundGut-Landmann, Yi Zhao, Axel Schulz, Angela Santoni, Pablo Engel, Daniela C. Hernández, Andreas Acs, Cristiano Scottà, Francesco Annunziato, Thomas Weisenburger, Wolfgang Beisker, Sue Chow, Fritz Melchers, Daniel E. Speiser, Immanuel Kwok, Florent Ginhoux, Dominic A. Boardman, Natalie Stanley, Carsten Watzl, Marie Follo, Erik Lubberts, Andreas Krueger, Susanne Ziegler, Göran K. Hansson, David Voehringer, Antonia Niedobitek, Eleni Christakou, Lai Guan Ng, Sabine Baumgart, Nicholas A Gherardin, Antonio Cosma, Orla Maguire, Jolene Bradford, Daniel Schraivogel, Linda Quatrini, Stephen D. Miller, Rheumatology, Università degli Studi di Modena e Reggio Emilia (UNIMORE), Deutsches Rheuma-ForschungsZentrum (DRFZ), Deutsches Rheuma-ForschungsZentrum, Swiss Institute of Allergy and Asthma Research (SIAF), Universität Zürich [Zürich] = University of Zurich (UZH), Institut de Recherche Saint-Louis - Hématologie Immunologie Oncologie (Département de recherche de l’UFR de médecine, ex- Institut Universitaire Hématologie-IUH) (IRSL), Université de Paris (UP), Ecotaxie, microenvironnement et développement lymphocytaire (EMily (UMR_S_1160 / U1160)), Institut National de la Santé et de la Recherche Médicale (INSERM)-Université de Paris (UP), Department of Internal Medicine, Università degli Studi di Firenze = University of Florence [Firenze] (UNIFI)-DENOTHE Center, Institute of Clinical Molecular Biology, Kiel University, Department of Life Sciences [Siena, Italy], Università degli Studi di Siena = University of Siena (UNISI), Institut Pasteur, Fondation Cenci Bolognetti - Istituto Pasteur Italia, Fondazione Cenci Bolognetti, Réseau International des Instituts Pasteur (RIIP), Dulbecco Telethon Institute/Department of Biology, Caprotec Bioanalytics GmbH, International Occultation Timing Association European Section (IOTA ES), International Occultation Timing Association European Section, European Molecular Biology Laboratory [Heidelberg] (EMBL), VIB-UGent Center for Inflammation Research [Gand, Belgique] (IRC), VIB [Belgium], Fondazione Santa Lucia (IRCCS), Department of Immunology, Chinese Academy of Medical Sciences, FIRC Institute of Molecular Oncology Foundation, IFOM, Istituto FIRC di Oncologia Molecolare (IFOM), Institut Necker Enfants-Malades (INEM - UM 111 (UMR 8253 / U1151)), Université Paris Descartes - Paris 5 (UPD5)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Department of Physiopatology and Transplantation, University of Milan (DEPT), University of Milan, Monash University [Clayton], Institut des Maladies Emergentes et des Thérapies Innovantes (IMETI), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay, Institute of Cellular Pathology, Université Catholique de Louvain = Catholic University of Louvain (UCL), Lymphopoïèse (Lymphopoïèse (UMR_1223 / U1223 / U-Pasteur_4)), Institut Pasteur [Paris]-Université Paris Diderot - Paris 7 (UPD7)-Institut National de la Santé et de la Recherche Médicale (INSERM), Experimental Immunology Unit, Dept. of Oncology, DIBIT San Raffaele Scientific Institute, Immunité Innée - Innate Immunity, Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut Pasteur [Paris], Charité - UniversitätsMedizin = Charité - University Hospital [Berlin], Department of Biopharmacy [Bruxelles, Belgium] (Institute for Medical Immunology IMI), Université libre de Bruxelles (ULB), Charité Hospital, Humboldt-Universität zu Berlin, Agency for science, technology and research [Singapore] (A*STAR), Laboratory of Molecular Immunology and the Howard Hughes Institute, Rockefeller University [New York], Kennedy Institute of Rheumatology [Oxford, UK], Imperial College London, Theodor Kocher Institute, University of Bern, Leibniz Research Institute for Environmental Medicine [Düsseldorf, Germany] ( IUF), Université Lumière - Lyon 2 (UL2), Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Université de Paris (UP), University of Edinburgh, Integrative Biology Program [Milano], Istituto Nazionale Genetica Molecolare [Milano] (INGM), Singapore Immunology Network (SIgN), Biomedical Sciences Institute (BMSI), Universitat de Barcelona (UB), Rheumatologie, Cell Biology, Department of medicine [Stockholm], Karolinska Institutet [Stockholm]-Karolinska University Hospital [Stockholm], Department for Internal Medicine 3, Institute for Clinical Immunology, Friedrich-Alexander Universität Erlangen-Nürnberg (FAU), Delft University of Technology (TU Delft), Medical Inflammation Research, Karolinska Institutet [Stockholm], Department of Photonics Engineering [Lyngby], Technical University of Denmark [Lyngby] (DTU), Dpt of Experimental Immunology [Braunschweig], Helmholtz Centre for Infection Research (HZI), Department of Internal Medicine V, Universität Heidelberg [Heidelberg], Department of Histology and Embryology, University of Rijeka, Freiburg University Medical Center, Nuffield Dept of Clinical Medicine, University of Oxford [Oxford]-NIHR Biomedical Research Centre, Institute of Integrative Biology, Molecular Biomedicine, Berlin Institute of Health (BIH), Laboratory for Lymphocyte Differentiation, RIKEN Research Center, Institutes of Molecular Medicine and Experimental Immunology, University of Bonn, Immunité et cancer (U932), Institut Curie [Paris]-Institut National de la Santé et de la Recherche Médicale (INSERM), Institut Cochin (IC UM3 (UMR 8104 / U1016)), Department of Surgery [Vancouver, BC, Canada] (Child and Family Research Institute), University of British Columbia (UBC)-Child and Family Research Institute [Vancouver, BC, Canada], College of Food Science and Technology [Shangai], Shanghai Ocean University, Institute for Medical Microbiology and Hygiene, University of Marburg, King‘s College London, Erasmus University Medical Center [Rotterdam] (Erasmus MC), Centre d'Immunophénomique (CIPHE), Aix Marseille Université (AMU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Brustzentrum Kantonsspital St. Gallen, Immunotechnology Section, Vaccine Research Center, National Institutes of Health [Bethesda] (NIH)-National Institute of Allergy and Infectious Diseases, Heinrich Pette Institute [Hamburg], Università degli Studi di Firenze = University of Florence [Firenze] (UNIFI), Department of Immunology and Cell Biology, Mario Negri Institute, Laboratory of Molecular Medicine and Biotechnology, Don C. Gnocchi ONLUS Foundation, Institute of Translational Medicine, Klinik für Dermatologie, Venerologie und Allergologie, School of Biochemistry and Immunology, Department of Medicine Huddinge, Karolinska Institutet [Stockholm]-Karolinska University Hospital [Stockholm]-Lipid Laboratory, Università di Genova, Dipartimento di Medicina Sperimentale, Department of Environmental Microbiology, Helmholtz Zentrum für Umweltforschung = Helmholtz Centre for Environmental Research (UFZ), Department of Radiation Oncology [Munich], Ludwig-Maximilians-Universität München (LMU), Centre de Recherche Publique- Santé, Université du Luxembourg (Uni.lu), William Harvey Research Institute, Barts and the London Medical School, University of Michigan [Ann Arbor], University of Michigan System, Centro de Investigacion del Cancer (CSIC), Universitario de Salamanca, Molecular Pathology [Tartu, Estonia], University of Tartu, Hannover Medical School [Hannover] (MHH), Centre d'Immunologie de Marseille - Luminy (CIML), Monash Biomedicine Discovery Institute, Cytometry Laboratories and School of Veterinary Medicine, Purdue University [West Lafayette], Data Mining and Modelling for Biomedicine [Ghent, Belgium], VIB Center for Inflammation Research [Ghent, Belgium], Laboratory for Cell Signaling, RIKEN Research Center for Allergy and Immunology, RIKEN Research Center for Allergy and Immunology, Osaka University [Osaka], Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome], Centre de Recherche des Cordeliers (CRC (UMR_S_1138 / U1138)), École pratique des hautes études (EPHE), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Sorbonne Université (SU)-Université de Paris (UP), Institute of Medical Immunology [Berlin, Germany], FACS and Array Core Facility, Johannes Gutenberg - Universität Mainz (JGU), Otto-von-Guericke University [Magdeburg] (OVGU), SUPA School of Physics and Astronomy [University of St Andrews], University of St Andrews [Scotland]-Scottish Universities Physics Alliance (SUPA), Biologie Cellulaire des Lymphocytes - Lymphocyte Cell Biology, Institut Pasteur [Paris]-Institut National de la Santé et de la Recherche Médicale (INSERM), General Pathology and Immunology (GPI), University of Brescia, Université de Lausanne (UNIL), Terry Fox Laboratory, BC Cancer Agency (BCCRC)-British Columbia Cancer Agency Research Centre, Department of Molecular Immunology, Medizinische Universität Wien = Medical University of Vienna, Dept. Pediatric Cardiology, Universität Leipzig [Leipzig], Universitaetsklinikum Hamburg-Eppendorf = University Medical Center Hamburg-Eppendorf [Hamburg] (UKE), Center for Cardiovascular Sciences, Albany Medical College, Dept Pathol, Div Immunol, University of Cambridge [UK] (CAM), Department of Information Technology [Gent], Universiteit Gent, Department of Plant Systems Biology, Department of Plant Biotechnology and Genetics, Universiteit Gent = Ghent University [Belgium] (UGENT), Division of Molecular Immunology, Institute for Immunology, Department of Geological Sciences, University of Oregon [Eugene], Centers for Disease Control and Prevention [Atlanta] (CDC), Centers for Disease Control and Prevention, University of Colorado [Colorado Springs] (UCCS), FACS laboratory, Cancer Research, London, Cancer Research UK, Regeneration in Hematopoiesis and Animal Models of Hematopoiesis, Faculty of Medicine, Dresden University of Technology, Barbara Davis Center for Childhood Diabetes (BDC), University of Colorado Anschutz [Aurora], School of Computer and Electronic Information [Guangxi University], Guangxi University [Nanning], School of Materials Science and Engineering, Nanyang Technological University [Singapour], Max Planck Institute for Infection Biology (MPIIB), Max-Planck-Gesellschaft, Work in the laboratory of Dieter Adam is supported by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation)—Projektnummer 125440785 – SFB 877, Project B2.Petra Hoffmann, Andrea Hauser, and Matthias Edinger thank BD Biosciences®, San José, CA, USA, and SKAN AG, Bale, Switzerland for fruitful cooperation during the development, construction, and installation of the GMP‐compliant cell sorting equipment and the Bavarian Immune Therapy Network (BayImmuNet) for financial support.Edwin van der Pol and Paola Lanuti acknowledge Aleksandra Gąsecka M.D. for excellent experimental support and Dr. Rienk Nieuwland for textual suggestions. This work was supported by the Netherlands Organisation for Scientific Research – Domain Applied and Engineering Sciences (NWO‐TTW), research program VENI 15924.Jessica G Borger, Kylie M Quinn, Mairi McGrath, and Regina Stark thank Francesco Siracusa and Patrick Maschmeyer for providing data.Larissa Nogueira Almeida was supported by DFG research grant MA 2273/14‐1. Rudolf A. Manz was supported by the Excellence Cluster 'Inflammation at Interfaces' (EXC 306/2).Susanne Hartmann and Friederike Ebner were supported by the German Research Foundation (GRK 2046).Hans Minderman was supported by NIH R50CA211108.This work was funded by the Deutsche Forschungsgemeinschaft through the grant TRR130 (project P11 and C03) to Thomas H. Winkler.Ramon Bellmàs Sanz, Jenny Kühne, and Christine S. Falk thank Jana Keil and Kerstin Daemen for excellent technical support. The work was funded by the Germany Research Foundation CRC738/B3 (CSF).The work by the Mei laboratory was supported by German Research Foundation Grant ME 3644/5‐1 and TRR130 TP24, the German Rheumatism Research Centre Berlin, European Union Innovative Medicines Initiative ‐ Joint Undertaking ‐ RTCure Grant Agreement 777357, the Else Kröner‐Fresenius‐Foundation, German Federal Ministry of Education and Research e:Med sysINFLAME Program Grant 01ZX1306B and KMU‐innovativ 'InnoCyt', and the Leibniz Science Campus for Chronic Inflammation (http://www.chronische-entzuendung.org).Axel Ronald Schulz, Antonio Cosma, Sabine Baumgart, Brice Gaudilliere, Helen M. McGuire, and Henrik E. Mei thank Michael D. Leipold for critically reading the manuscript.Christian Kukat acknowledges support from the ISAC SRL Emerging Leaders program.John Trowsdale received funding from the European Research Council under the European Union's Horizon 2020 research and innovation program (Grant Agreement 695551)., European Project: 7728036(1978), Università degli Studi di Modena e Reggio Emilia = University of Modena and Reggio Emilia (UNIMORE), Université Paris Cité (UPCité), Institut National de la Santé et de la Recherche Médicale (INSERM)-Université Paris Cité (UPCité), Università degli Studi di Firenze = University of Florence (UniFI)-DENOTHE Center, Università degli Studi di Milano = University of Milan (UNIMI), Institut Pasteur [Paris] (IP)-Université Paris Diderot - Paris 7 (UPD7)-Institut National de la Santé et de la Recherche Médicale (INSERM), Institut Pasteur [Paris] (IP)-Institut National de la Santé et de la Recherche Médicale (INSERM), Humboldt University Of Berlin, Leibniz Research Institute for Environmental Medicine [Düsseldorf, Germany] (IUF), Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité), Danmarks Tekniske Universitet = Technical University of Denmark (DTU), Universität Heidelberg [Heidelberg] = Heidelberg University, Universitäts Klinikum Freiburg = University Medical Center Freiburg (Uniklinik), University of Oxford-NIHR Biomedical Research Centre, Universität Bonn = University of Bonn, Università degli Studi di Firenze = University of Florence (UniFI), Università degli studi di Genova = University of Genoa (UniGe), Universidad de Salamanca, Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome] (UNIROMA), École Pratique des Hautes Études (EPHE), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Sorbonne Université (SU)-Université Paris Cité (UPCité), Johannes Gutenberg - Universität Mainz = Johannes Gutenberg University (JGU), Otto-von-Guericke-Universität Magdeburg = Otto-von-Guericke University [Magdeburg] (OVGU), Université de Lausanne = University of Lausanne (UNIL), Universität Leipzig, Universiteit Gent = Ghent University (UGENT), HZI,Helmholtz-Zentrum für Infektionsforschung GmbH, Inhoffenstr. 7,38124 Braunschweig, Germany., Cossarizza, A., Chang, H. -D., Radbruch, A., Acs, A., Adam, D., Adam-Klages, S., Agace, W. W., Aghaeepour, N., Akdis, M., Allez, M., Almeida, L. N., Alvisi, G., Anderson, G., Andra, I., Annunziato, F., Anselmo, A., Bacher, P., Baldari, C. T., Bari, S., Barnaba, V., Barros-Martins, J., Battistini, L., Bauer, W., Baumgart, S., Baumgarth, N., Baumjohann, D., Baying, B., Bebawy, M., Becher, B., Beisker, W., Benes, V., Beyaert, R., Blanco, A., Boardman, D. A., Bogdan, C., Borger, J. G., Borsellino, G., Boulais, P. E., Bradford, J. A., Brenner, D., Brinkman, R. R., Brooks, A. E. S., Busch, D. H., Buscher, M., Bushnell, T. P., Calzetti, F., Cameron, G., Cammarata, I., Cao, X., Cardell, S. L., Casola, S., Cassatella, M. A., Cavani, A., Celada, A., Chatenoud, L., Chattopadhyay, P. K., Chow, S., Christakou, E., Cicin-Sain, L., Clerici, M., Colombo, F. S., Cook, L., Cooke, A., Cooper, A. M., Corbett, A. J., Cosma, A., Cosmi, L., Coulie, P. G., Cumano, A., Cvetkovic, L., Dang, V. D., Dang-Heine, C., Davey, M. S., Davies, D., De Biasi, S., Del Zotto, G., Dela Cruz, G. V., Delacher, M., Della Bella, S., Dellabona, P., Deniz, G., Dessing, M., Di Santo, J. P., Diefenbach, A., Dieli, F., Dolf, A., Dorner, T., Dress, R. J., Dudziak, D., Dustin, M., Dutertre, C. -A., Ebner, F., Eckle, S. B. G., Edinger, M., Eede, P., Ehrhardt, G. R. A., Eich, M., Engel, P., Engelhardt, B., Erdei, A., Esser, C., Everts, B., Evrard, M., Falk, C. S., Fehniger, T. A., Felipo-Benavent, M., Ferry, H., Feuerer, M., Filby, A., Filkor, K., Fillatreau, S., Follo, M., Forster, I., Foster, J., Foulds, G. A., Frehse, B., Frenette, P. S., Frischbutter, S., Fritzsche, W., Galbraith, D. W., Gangaev, A., Garbi, N., Gaudilliere, B., Gazzinelli, R. T., Geginat, J., Gerner, W., Gherardin, N. A., Ghoreschi, K., Gibellini, L., Ginhoux, F., Goda, K., Godfrey, D. I., Goettlinger, C., Gonzalez-Navajas, J. M., Goodyear, C. S., Gori, A., Grogan, J. L., Grummitt, D., Grutzkau, A., Haftmann, C., Hahn, J., Hammad, H., Hammerling, G., Hansmann, L., Hansson, G., Harpur, C. M., Hartmann, S., Hauser, A., Hauser, A. E., Haviland, D. L., Hedley, D., Hernandez, D. C., Herrera, G., Herrmann, M., Hess, C., Hofer, T., Hoffmann, P., Hogquist, K., Holland, T., Hollt, T., Holmdahl, R., Hombrink, P., Houston, J. P., Hoyer, B. F., Huang, B., Huang, F. -P., Huber, J. E., Huehn, J., Hundemer, M., Hunter, C. A., Hwang, W. Y. K., Iannone, A., Ingelfinger, F., Ivison, S. M., Jack, H. -M., Jani, P. K., Javega, B., Jonjic, S., Kaiser, T., Kalina, T., Kamradt, T., Kaufmann, S. H. E., Keller, B., Ketelaars, S. L. C., Khalilnezhad, A., Khan, S., Kisielow, J., Klenerman, P., Knopf, J., Koay, H. -F., Kobow, K., Kolls, J. K., Kong, W. T., Kopf, M., Korn, T., Kriegsmann, K., Kristyanto, H., Kroneis, T., Krueger, A., Kuhne, J., Kukat, C., Kunkel, D., Kunze-Schumacher, H., Kurosaki, T., Kurts, C., Kvistborg, P., Kwok, I., Landry, J., Lantz, O., Lanuti, P., Larosa, F., Lehuen, A., LeibundGut-Landmann, S., Leipold, M. D., Leung, L. Y. T., Levings, M. K., Lino, A. C., Liotta, F., Litwin, V., Liu, Y., Ljunggren, H. -G., Lohoff, M., Lombardi, G., Lopez, L., Lopez-Botet, M., Lovett-Racke, A. E., Lubberts, E., Luche, H., Ludewig, B., Lugli, E., Lunemann, S., Maecker, H. T., Maggi, L., Maguire, O., Mair, F., Mair, K. H., Mantovani, A., Manz, R. A., Marshall, A. J., Martinez-Romero, A., Martrus, G., Marventano, I., Maslinski, W., Matarese, G., Mattioli, A. V., Maueroder, C., Mazzoni, A., Mccluskey, J., Mcgrath, M., Mcguire, H. M., Mcinnes, I. B., Mei, H. E., Melchers, F., Melzer, S., Mielenz, D., Miller, S. D., Mills, K. H. G., Minderman, H., Mjosberg, J., Moore, J., Moran, B., Moretta, L., Mosmann, T. R., Muller, S., Multhoff, G., Munoz, L. E., Munz, C., Nakayama, T., Nasi, M., Neumann, K., Ng, L. G., Niedobitek, A., Nourshargh, S., Nunez, G., O'Connor, J. -E., Ochel, A., Oja, A., Ordonez, D., Orfao, A., Orlowski-Oliver, E., Ouyang, W., Oxenius, A., Palankar, R., Panse, I., Pattanapanyasat, K., Paulsen, M., Pavlinic, D., Penter, L., Peterson, P., Peth, C., Petriz, J., Piancone, F., Pickl, W. F., Piconese, S., Pinti, M., Pockley, A. G., Podolska, M. J., Poon, Z., Pracht, K., Prinz, I., Pucillo, C. E. M., Quataert, S. A., Quatrini, L., Quinn, K. M., Radbruch, H., Radstake, T. R. D. J., Rahmig, S., Rahn, H. -P., Rajwa, B., Ravichandran, G., Raz, Y., Rebhahn, J. A., Recktenwald, D., Reimer, D., Reis e Sousa, C., Remmerswaal, E. B. M., Richter, L., Rico, L. G., Riddell, A., Rieger, A. M., Robinson, J. P., Romagnani, C., Rubartelli, A., Ruland, J., Saalmuller, A., Saeys, Y., Saito, T., Sakaguchi, S., Sala-de-Oyanguren, F., Samstag, Y., Sanderson, S., Sandrock, I., Santoni, A., Sanz, R. B., Saresella, M., Sautes-Fridman, C., Sawitzki, B., Schadt, L., Scheffold, A., Scherer, H. U., Schiemann, M., Schildberg, F. A., Schimisky, E., Schlitzer, A., Schlosser, J., Schmid, S., Schmitt, S., Schober, K., Schraivogel, D., Schuh, W., Schuler, T., Schulte, R., Schulz, A. R., Schulz, S. R., Scotta, C., Scott-Algara, D., Sester, D. P., Shankey, T. V., Silva-Santos, B., Simon, A. K., Sitnik, K. M., Sozzani, S., Speiser, D. E., Spidlen, J., Stahlberg, A., Stall, A. M., Stanley, N., Stark, R., Stehle, C., Steinmetz, T., Stockinger, H., Takahama, Y., Takeda, K., Tan, L., Tarnok, A., Tiegs, G., Toldi, G., Tornack, J., Traggiai, E., Trebak, M., Tree, T. I. M., Trotter, J., Trowsdale, J., Tsoumakidou, M., Ulrich, H., Urbanczyk, S., van de Veen, W., van den Broek, M., van der Pol, E., Van Gassen, S., Van Isterdael, G., van Lier, R. A. W., Veldhoen, M., Vento-Asturias, S., Vieira, P., Voehringer, D., Volk, H. -D., von Borstel, A., von Volkmann, K., Waisman, A., Walker, R. V., Wallace, P. K., Wang, S. A., Wang, X. M., Ward, M. D., Ward-Hartstonge, K. A., Warnatz, K., Warnes, G., Warth, S., Waskow, C., Watson, J. V., Watzl, C., Wegener, L., Weisenburger, T., Wiedemann, A., Wienands, J., Wilharm, A., Wilkinson, R. J., Willimsky, G., Wing, J. B., Winkelmann, R., Winkler, T. H., Wirz, O. F., Wong, A., Wurst, P., Yang, J. H. M., Yang, J., Yazdanbakhsh, M., Yu, L., Yue, A., Zhang, H., Zhao, Y., Ziegler, S. M., Zielinski, C., Zimmermann, J., Zychlinsky, A., UCL - SSS/DDUV - Institut de Duve, UCL - SSS/DDUV/GECE - Génétique cellulaire, Netherlands Organization for Scientific Research, German Research Foundation, European Commission, European Research Council, Repositório da Universidade de Lisboa, CCA - Imaging and biomarkers, Experimental Immunology, AII - Infectious diseases, AII - Inflammatory diseases, Biomedical Engineering and Physics, ACS - Atherosclerosis & ischemic syndromes, and Landsteiner Laboratory

Subjects

0301 basic medicine, Consensus, Immunology, Consensu, Cell Separation, Biology, Article, Flow cytometry, 03 medical and health sciences, 0302 clinical medicine, Guidelines, Allergy and Immunology, medicine, Cell separation, Immunology and Allergy, Humans, guidelines, flow cytometry, immunology, medicine.diagnostic_test, BIOMEDICINE AND HEALTHCARE. Basic Medical Sciences, Cell sorting, Flow Cytometry, Cell selection, Data science, 3. Good health, 030104 developmental biology, Phenotype, [SDV.IMM]Life Sciences [q-bio]/Immunology, BIOMEDICINA I ZDRAVSTVO. Temeljne medicinske znanosti, 030215 immunology, Human

Abstract

All authors: Andrea Cossarizza Hyun‐Dong Chang Andreas Radbruch Andreas Acs Dieter Adam Sabine Adam‐Klages William W. Agace Nima Aghaeepour Mübeccel Akdis Matthieu Allez Larissa Nogueira Almeida Giorgia Alvisi Graham Anderson Immanuel Andrä Francesco Annunziato Achille Anselmo Petra Bacher Cosima T. Baldari Sudipto Bari Vincenzo Barnaba Joana Barros‐Martins Luca Battistini Wolfgang Bauer Sabine Baumgart Nicole Baumgarth Dirk Baumjohann Bianka Baying Mary Bebawy Burkhard Becher Wolfgang Beisker Vladimir Benes Rudi Beyaert Alfonso Blanco Dominic A. Boardman Christian Bogdan Jessica G. Borger Giovanna Borsellino Philip E. Boulais Jolene A. Bradford Dirk Brenner Ryan R. Brinkman Anna E. S. Brooks Dirk H. Busch Martin Büscher Timothy P. Bushnell Federica Calzetti Garth Cameron Ilenia Cammarata Xuetao Cao Susanna L. Cardell Stefano Casola Marco A. Cassatella Andrea Cavani Antonio Celada Lucienne Chatenoud Pratip K. Chattopadhyay Sue Chow Eleni Christakou Luka Čičin‐Šain Mario Clerici Federico S. Colombo Laura Cook Anne Cooke Andrea M. Cooper Alexandra J. Corbett Antonio Cosma Lorenzo Cosmi Pierre G. Coulie Ana Cumano Ljiljana Cvetkovic Van Duc Dang Chantip Dang‐Heine Martin S. Davey Derek Davies Sara De Biasi Genny Del Zotto Gelo Victoriano Dela Cruz Michael Delacher Silvia Della Bella Paolo Dellabona Günnur Deniz Mark Dessing James P. Di Santo Andreas Diefenbach Francesco Dieli Andreas Dolf Thomas Dörner Regine J. Dress Diana Dudziak Michael Dustin Charles‐Antoine Dutertre Friederike Ebner Sidonia B. G. Eckle Matthias Edinger Pascale Eede Götz R.A. Ehrhardt Marcus Eich Pablo Engel Britta Engelhardt Anna Erdei Charlotte Esser Bart Everts Maximilien Evrard Christine S. Falk Todd A. Fehniger Mar Felipo‐Benavent Helen Ferry Markus Feuerer Andrew Filby Kata Filkor Simon Fillatreau Marie Follo Irmgard Förster John Foster Gemma A. Foulds Britta Frehse Paul S. Frenette Stefan Frischbutter Wolfgang Fritzsche David W. Galbraith Anastasia Gangaev Natalio Garbi Brice Gaudilliere Ricardo T. Gazzinelli Jens Geginat Wilhelm Gerner Nicholas A. Gherardin Kamran Ghoreschi Lara Gibellini Florent Ginhoux Keisuke Goda Dale I. Godfrey Christoph Goettlinger Jose M. González‐Navajas Carl S. Goodyear Andrea Gori Jane L. Grogan Daryl Grummitt Andreas Grützkau Claudia Haftmann Jonas Hahn Hamida Hammad Günter Hämmerling Leo Hansmann Goran Hansson Christopher M. Harpur Susanne Hartmann Andrea Hauser Anja E. Hauser David L. Haviland David Hedley Daniela C. Hernández Guadalupe Herrera Martin Herrmann Christoph Hess Thomas Höfer Petra Hoffmann Kristin Hogquist Tristan Holland Thomas Höllt Rikard Holmdahl Pleun Hombrink Jessica P. Houston Bimba F. Hoyer Bo Huang Fang‐Ping Huang Johanna E. Huber Jochen Huehn Michael Hundemer Christopher A. Hunter William Y. K. Hwang Anna Iannone Florian Ingelfinger Sabine M Ivison Hans‐Martin Jäck Peter K. Jani Beatriz Jávega Stipan Jonjic Toralf Kaiser Tomas Kalina Thomas Kamradt Stefan H. E. Kaufmann Baerbel Keller Steven L. C. Ketelaars Ahad Khalilnezhad Srijit Khan Jan Kisielow Paul Klenerman Jasmin Knopf Hui‐Fern Koay Katja Kobow Jay K. Kolls Wan Ting Kong Manfred Kopf Thomas Korn Katharina Kriegsmann Hendy Kristyanto Thomas Kroneis Andreas Krueger Jenny Kühne Christian Kukat Désirée Kunkel Heike Kunze‐Schumacher Tomohiro Kurosaki Christian Kurts Pia Kvistborg Immanuel Kwok Jonathan Landry Olivier Lantz Paola Lanuti Francesca LaRosa Agnès Lehuen Salomé LeibundGut‐Landmann Michael D. Leipold Leslie Y.T. Leung Megan K. Levings Andreia C. Lino Francesco Liotta Virginia Litwin Yanling Liu Hans‐Gustaf Ljunggren Michael Lohoff Giovanna Lombardi Lilly Lopez Miguel López‐Botet Amy E. Lovett‐Racke Erik Lubberts Herve Luche Burkhard Ludewig Enrico Lugli Sebastian Lunemann Holden T. Maecker Laura Maggi Orla Maguire Florian Mair Kerstin H. Mair Alberto Mantovani Rudolf A. Manz Aaron J. Marshall Alicia Martínez‐Romero Glòria Martrus Ivana Marventano Wlodzimierz Maslinski Giuseppe Matarese Anna Vittoria Mattioli Christian Maueröder Alessio Mazzoni James McCluskey Mairi McGrath Helen M. McGuire Iain B. McInnes Henrik E. Mei Fritz Melchers Susanne Melzer Dirk Mielenz Stephen D. Miller Kingston H.G. Mills Hans Minderman Jenny Mjösberg Jonni Moore Barry Moran Lorenzo Moretta Tim R. Mosmann Susann Müller Gabriele Multhoff Luis Enrique Muñoz Christian Münz Toshinori Nakayama Milena Nasi Katrin Neumann Lai Guan Ng Antonia Niedobitek Sussan Nourshargh Gabriel Núñez José‐Enrique O'Connor Aaron Ochel Anna Oja Diana Ordonez Alberto Orfao Eva Orlowski‐Oliver Wenjun Ouyang Annette Oxenius Raghavendra Palankar Isabel Panse Kovit Pattanapanyasat Malte Paulsen Dinko Pavlinic Livius Penter Pärt Peterson Christian Peth Jordi Petriz Federica Piancone Winfried F. Pickl Silvia Piconese Marcello Pinti A. Graham Pockley Malgorzata Justyna Podolska Zhiyong Poon Katharina Pracht Immo Prinz Carlo E. M. Pucillo Sally A. Quataert Linda Quatrini Kylie M. Quinn Helena Radbruch Tim R. D. J. Radstake Susann Rahmig Hans‐Peter Rahn Bartek Rajwa Gevitha Ravichandran Yotam Raz Jonathan A. Rebhahn Diether Recktenwald Dorothea Reimer Caetano Reis e Sousa Ester B.M. Remmerswaal Lisa Richter Laura G. Rico Andy Riddell Aja M. Rieger J. Paul Robinson Chiara Romagnani Anna Rubartelli Jürgen Ruland Armin Saalmüller Yvan Saeys Takashi Saito Shimon Sakaguchi Francisco Sala‐de‐Oyanguren Yvonne Samstag Sharon Sanderson Inga Sandrock Angela Santoni Ramon Bellmàs Sanz Marina Saresella Catherine Sautes‐Fridman Birgit Sawitzki Linda Schadt Alexander Scheffold Hans U. Scherer Matthias Schiemann Frank A. Schildberg Esther Schimisky Andreas Schlitzer Josephine Schlosser Stephan Schmid Steffen Schmitt Kilian Schober Daniel Schraivogel Wolfgang Schuh Thomas Schüler Reiner Schulte Axel Ronald Schulz Sebastian R. Schulz Cristiano Scottá Daniel Scott‐Algara David P. Sester T. Vincent Shankey Bruno Silva‐Santos Anna Katharina Simon Katarzyna M. Sitnik Silvano Sozzani Daniel E. Speiser Josef Spidlen Anders Stahlberg Alan M. Stall Natalie Stanley Regina Stark Christina Stehle Tobit Steinmetz Hannes Stockinger Yousuke Takahama Kiyoshi Takeda Leonard Tan Attila Tárnok Gisa Tiegs Gergely Toldi Julia Tornack Elisabetta Traggiai Mohamed Trebak Timothy I.M. Tree Joe Trotter John Trowsdale Maria Tsoumakidou Henning Ulrich Sophia Urbanczyk Willem van de Veen Maries van den Broek Edwin van der Pol Sofie Van Gassen Gert Van Isterdael René A.W. van Lier Marc Veldhoen Salvador Vento‐Asturias Paulo Vieira David Voehringer Hans‐Dieter Volk Anouk von Borstel Konrad von Volkmann Ari Waisman Rachael V. Walker Paul K. Wallace Sa A. Wang Xin M. Wang Michael D. Ward Kirsten A Ward‐Hartstonge Klaus Warnatz Gary Warnes Sarah Warth Claudia Waskow James V. Watson Carsten Watzl Leonie Wegener Thomas Weisenburger Annika Wiedemann Jürgen Wienands Anneke Wilharm Robert John Wilkinson Gerald Willimsky James B. Wing Rieke Winkelmann Thomas H. Winkler Oliver F. Wirz Alicia Wong Peter Wurst Jennie H. M. Yang Juhao Yang Maria Yazdanbakhsh Liping Yu Alice Yue Hanlin Zhang Yi Zhao Susanne Maria Ziegler Christina Zielinski Jakob Zimmermann Arturo Zychlinsky., These guidelines are a consensus work of a considerable number of members of the immunology and flow cytometry community. They provide the theory and key practical aspects of flow cytometry enabling immunologists to avoid the common errors that often undermine immunological data. Notably, there are comprehensive sections of all major immune cell types with helpful Tables detailing phenotypes in murine and human cells. The latest flow cytometry techniques and applications are also described, featuring examples of the data that can be generated and, importantly, how the data can be analysed. Furthermore, there are sections detailing tips, tricks and pitfalls to avoid, all written and peer‐reviewed by leading experts in the field, making this an essential research companion., This work was supported by the Netherlands Organisation for Scientific Research – Domain Applied and Engineering Sciences (NWO-TTW), research program VENI 15924. This work was funded by the Deutsche Forschungsgemeinschaft. European Union Innovative Medicines Initiative - Joint Undertaking - RTCure Grant Agreement 777357 and innovation program (Grant Agreement 695551).

Published

2019

42. Interleukin-10 improves stroke outcome by controlling the detrimental Interleukin-17A response

Author

Leonie Brockmann, Tim Magnus, Mathias Gelderblom, Jonas H. Vienhues, Tanja Bedke, Marius Piepke, Richard A. Flavell, Immo Prinz, Karoline Degenhardt, Samuel Huber, Yasushi Kobayashi, Alina Jander, Ehsan Javidi, Bettina Hjelm Clausen, Thomas Renné, Christian Gerloff, Inga Sandrock, Björn Rissiek, Ines Sophie Schädlich, Vanessa Roth, Larissa Jank, and Peter Ludewig

Subjects

Genetically modified mouse, CD4-Positive T-Lymphocytes, T cell, Immunology, T cells, Inflammation, Mice, Transgenic, T-Lymphocytes, Regulatory, Cellular and Molecular Neuroscience, Mice, Immune system, Ischemia, Medicine, Animals, Receptors, Interleukin-10, RC346-429, Stroke, Injections, Spinal, Ischemic Stroke, Microglia, business.industry, Research, General Neuroscience, Interleukin-17, Infarction, Middle Cerebral Artery, medicine.disease, Antibodies, Neutralizing, Immunohistochemistry, Interleukin-10, Mice, Inbred C57BL, Interleukin 10, medicine.anatomical_structure, Treatment Outcome, Neurology, Neurology. Diseases of the nervous system, Interleukin 17, medicine.symptom, business

Abstract

Background: Lymphocytes have dichotomous functions in ischemic stroke. Regulatory T cells are protective, while IL-17A from innate lymphocytes promotes the infarct growth. With recent advances of T cell-subtype specifc transgenic mouse models it now has become possible to study the complex interplay of T cell subpopulations in ischemic stroke.Methods: In a murine model of experimental stroke we analyzed the efects of IL-10 on the functional outcome for up to 14 days post-ischemia and defned the source of IL-10 in ischemic brains based on immunohistochemistry, fow cytometry, and bone-marrow chimeric mice. We used neutralizing IL-17A antibodies, intrathecal IL-10 injections, and transgenic mouse models which harbor a deletion of the IL-10R on distinct T cell subpopulations to further explore the interplay between IL-10 and IL-17A pathways in the ischemic brain.Results: We demonstrate that IL-10 defcient mice exhibit signifcantly increased infarct sizes on days 3 and 7 and enlarged brain atrophy and impaired neurological outcome on day 14 following tMCAO. In ischemic brains IL-10 producing immune cells included regulatory T cells, macrophages, and microglia. Neutralization of IL-17A following stroke reversed the worse outcome in IL-10 defcient mice and intracerebral treatment with recombinant IL-10 revealed that IL-10 controlled IL-17A positive lymphocytes in ischemic brains. Importantly, IL-10 acted diferentially on αβ and γδ T cells. IL-17A producing CD4+ αβ T cells were directly controlled via their IL-10-receptor (IL-10R), whereas IL-10 by itself had no direct efect on the IL-17A production in γδ T cells. The control of the IL-17A production in γδ T cells depended on an intact IL10R signaling in regulatory T cells (Tregs).Conclusions: Taken together, our data indicate a key function of IL-10 in restricting the detrimental IL-17A-signaling in stroke and further supports that IL-17A is a therapeutic opportunity for stroke treatment. Background: Lymphocytes have dichotomous functions in ischemic stroke. Regulatory T cells are protective, while IL-17A from innate lymphocytes promotes the infarct growth. With recent advances of T cell-subtype specific transgenic mouse models it now has become possible to study the complex interplay of T cell subpopulations in ischemic stroke. Methods: In a murine model of experimental stroke we analyzed the effects of IL-10 on the functional outcome for up to 14 days post-ischemia and defined the source of IL-10 in ischemic brains based on immunohistochemistry, flow cytometry, and bone-marrow chimeric mice. We used neutralizing IL-17A antibodies, intrathecal IL-10 injections, and transgenic mouse models which harbor a deletion of the IL-10R on distinct T cell subpopulations to further explore the interplay between IL-10 and IL-17A pathways in the ischemic brain. Results: We demonstrate that IL-10 deficient mice exhibit significantly increased infarct sizes on days 3 and 7 and enlarged brain atrophy and impaired neurological outcome on day 14 following tMCAO. In ischemic brains IL-10 producing immune cells included regulatory T cells, macrophages, and microglia. Neutralization of IL-17A following stroke reversed the worse outcome in IL-10 deficient mice and intracerebral treatment with recombinant IL-10 revealed that IL-10 controlled IL-17A positive lymphocytes in ischemic brains. Importantly, IL-10 acted differentially on αβ and γδ T cells. IL-17A producing CD4 + αβ T cells were directly controlled via their IL-10-receptor (IL-10R), whereas IL-10 by itself had no direct effect on the IL-17A production in γδ T cells. The control of the IL-17A production in γδ T cells depended on an intact IL10R signaling in regulatory T cells (Tregs). Conclusions: Taken together, our data indicate a key function of IL-10 in restricting the detrimental IL-17A-signaling in stroke and further supports that IL-17A is a therapeutic opportunity for stroke treatment.

Published

2021

43. αβ T cells replacing dermal and epidermal γδ T cells in Tcrd

Author

Christoph, Binz, Anja, Bubke, Inga, Sandrock, and Immo, Prinz

Subjects

Mice, Knockout, Mice, Epidermal Cells, T-Lymphocyte Subsets, Receptors, Antigen, T-Cell, alpha-beta, Animals, Receptors, Antigen, T-Cell, gamma-delta, Dendritic Cells, Epidermis

Abstract

The epidermis of mouse skin is usually populated by dendritic epidermal T cells (γδDETC) expressing an invariant Vγ5Vδ1

Published

2021

44. Author response for 'αβ T cells replacing dermal and epidermal γδ T cells in Tcrd −/− mice express an MHC‐independent TCR repertoire'

Author

Anja Bubke, Immo Prinz, Christoph Binz, and Inga Sandrock

Subjects

biology.protein, Biology, Tcr repertoire, Major histocompatibility complex, Cell biology

Published

2021

45. γδ T cells license immature B cells to produce a broad range of polyreactive antibodies

Author

Francesca Rampoldi, Elisa Donato, Leon Ullrich, Malte Deseke, Anika Janssen, Abdi Demera, Inga Sandrock, Anja Bubke, Anna-Lena Juergens, Maxine Swallow, Tim Sparwasser, Christine Falk, Likai Tan, Andreas Trumpp, and Immo Prinz

Subjects

Mice, Inbred C57BL, B-Lymphocytes, Mice, Precursor Cells, B-Lymphoid, T-Lymphocytes, Animals, Humans, Receptors, Antigen, T-Cell, gamma-delta, General Biochemistry, Genetics and Molecular Biology, Antibodies

Abstract

Immature autoreactive B cells are present in all healthy individuals, but it is unclear which signals are required for their maturation into antibody-producing cells. Inducible depletion of γδ T cells show that direct interaction between γδ T cells and immature B cells in the spleen support an "innate" transition to mature B cells with a broad range of antigen specificities. IL-4 production of γδ T cells and cell-to-cell contact via CD30L support B cell maturation and induce genes of the unfolded protein response and mTORC1 signaling. Eight days after in vivo depletion of γδ T cells, increased numbers of B cells are already stuck in the transitional phase and express increased levels of IgD and CD21. Absence of γδ T cells leads also to reduced levels of serum anti-nuclear autoantibodies, making γδ T cells an attractive target to treat autoimmunity.

Published

2021

46. Interleukin-17 is disease promoting in early stages and protective in late stages of experimental periodontitis

Author

Anneke Wilharm, Christoph Binz, Inga Sandrock, Francesca Rampoldi, Stefan Lienenklaus, Eva Blank, Andreas Winkel, Abdi Demera, Avi-Hai Hovav, Meike Stiesch, and Immo Prinz

Subjects

Inflammation, Mice, Multidisciplinary, Interleukin-17, Alveolar Bone Loss, Gingiva, Animals, Cytokines, Periodontitis

Abstract

Periodontitis is one of the most common infectious diseases in humans. It is characterized by a chronic inflammation of the tooth-supporting tissue that results in bone loss. However, the role and source of the pro-inflammatory cytokine interleukin-17 (IL-17) and of the cells producing it locally in the gingiva is still controversial. Th17 αβ T cells, CD4+ exFoxP3+ αβ T cells, or IL-17-producing γδ T cells (γδ17 cells) seem to be decisive cellular players in periodontal inflammation. To address these issues in an experimental model for periodontitis, we employed genetic mouse models deficient for either γδ T cells or IL-17 cytokines and assessed the bone loss during experimental periodontal inflammation by stereomicroscopic, histological, and μCT-analysis. Furthermore, we performed flow-cytometric analyses and qPCR-analyses of the gingival tissue. We found no γδ T cell- or IL-17-dependent change in bone loss after four weeks of periodontitis. Apart from that, our data are complementary with earlier studies, which suggested IL-17-dependent aggravation of bone loss in early periodontitis, but a rather bone-protective role for IL-17 in late stages of experimental periodontitis with respect to the osteoclastogenicity defined by the RANKL/OPG ratio.

Published

2021

47. A fetal wave of human type 3 effector gamma delta cells with restricted TCR diversity persists into adulthood

Author

Reinhold Förster, Bowen Zhang, Alina Borchers, Ulf Panzer, Constantin von Kaisenberg, Christian Koenecke, Christian Schultze-Florey, Immo Prinz, Anja Bubke, Elena Bruni, Yang Li, Alina Suzann Fichtner, Xiaojing Chu, Inga Sandrock, Likai Tan, Ansgar Schulz, Sarina Ravens, Ivan Odak, Michael Jarek, and Christian Krebs

Subjects

0301 basic medicine, Adult, Male, SUBSETS, T cell, Immunology, C-C chemokine receptor type 6, UNIQUE, Biology, Lymphocyte Activation, PHENOTYPE, Fetal Development, 03 medical and health sciences, 0302 clinical medicine, RAR-related orphan receptor gamma, T-Lymphocyte Subsets, MAPS, medicine, Humans, RNA-Seq, Intraepithelial Lymphocytes, Cells, Cultured, Effector, T-cell receptor, Cell Differentiation, Receptors, Antigen, T-Cell, gamma-delta, General Medicine, EXPANSION, Fetal Blood, Phenotype, Embryonic stem cell, Cell biology, KLRB1, 030104 developmental biology, medicine.anatomical_structure, DIFFERENTIATION, T-CELLS, VISUALIZATION, Female, Single-Cell Analysis, REQUIREMENTS, 030215 immunology, EXPRESS

Abstract

Accumulating evidence suggests that the mouse embryonic thymus produces distinct waves of innate effector gamma delta T cells. However, it is unclear whether this process occurs similarly in humans and whether it comprises a dedicated subset of innate-like type 3 effector gamma delta T cells. Here, we present a protocol for high-throughput sequencing of TRG and TRD pairs that comprise the clonal gamma delta TCR. In combination with single-cell RNA sequencing, multiparameter flow cytometry, and TCR sequencing, we reveal a high heterogeneity of gamma delta T cells sorted from neonatal and adult blood that correlated with TCR usage. Immature gamma delta T cell clusters displayed mixed and diverse TCRs, but effector cell types segregated according to the expression of either highly expanded individual V delta 1(+) TCRs or moderately expanded semi-invariant V gamma 9V delta 2(+) TCRs. The V gamma 9V delta 2(+) T cells shared expression of genes that mark innate-like T cells, including ZBTB16 (encoding PLZF), KLRB1, and KLRC1, but consisted of distinct clusters with unrelated V gamma 9V delta 2(+) TCR clones characterized either by TBX21, FCGR3A, and cytotoxicity-associated gene expression (type 1) or by CCR6, RORC, IL23R, and DPP4 expression (type 3). Effector gamma delta T cells with type 1 and type 3 innate T cell signatures were detected in a public dataset of early embryonic thymus organogenesis. Together, this study suggests that functionally distinct waves of human innate-like effector gamma delta T cells with semi-invariant V gamma 9V delta 2(+) TCR develop in the early fetal thymus and persist into adulthood.

Published

2021

48. Lack of gamma delta T cells ameliorates inflammatory response after acute intestinal ischemia reperfusion in mice

Author

Omid Madadi-Sanjani, Benno M. Ure, Tawan Imvised, Xiaoyan Feng, Christian Klemann, Yi Yu, Faikah Gueler, Immo Prinz, Dominik Funken, and J. F. Kuebler

Subjects

Male, medicine.medical_treatment, Science, Gene Expression, Paediatric research, Article, Flow cytometry, Mice, Immunity, Gene expression, medicine, Animals, Intraepithelial Lymphocytes, Inflammation, Mice, Knockout, Kidney, Multidisciplinary, Lung, medicine.diagnostic_test, business.industry, urogenital system, medicine.disease, Acute Intestinal Ischemia, Intestines, Mice, Inbred C57BL, Experimental models of disease, Disease Models, Animal, Cytokine, medicine.anatomical_structure, Neutrophil Infiltration, Reperfusion Injury, Immunology, Medicine, Chemokines, business, Infiltration (medical)

Abstract

T-cells have been demonstrated to modulate ischemia–reperfusion injury (IRI) in the kidney, lung, liver, and intestine. Whereas most T-cell subpopulations contribute primarily to the antigen-specific effector and memory phases of immunity, γδ-T-cells combine adaptive features with rapid, innate-like responses that can place them in the initiation phase of immune reactions. Therefore, we aimed to clarify the role of γδ-T-cells in intestinal IRI. Adult wild-type (WT) and γδ-T-cell-deficient mice were subjected to acute intestinal IRI. Gene expression of pro-inflammatory cytokines and influx of leukocyte subpopulations in the gut were assessed by qPCR and flow cytometry. Serum transaminases were measured as an indicator of distant organ IRI. Intestinal IRI led to increased influx of neutrophils, pro-inflammatory cytokine expression and LDH/ALT/AST elevation. Selective deficiency of γδ-T-cells significantly decreased pro-inflammatory cytokine levels and neutrophil infiltration in the gut following IRI compared to controls. Furthermore, γδ-T-cell deficiency resulted in decreased LDH and transaminases levels in sera, indicating amelioration of distant organ injury. Increasing evidence demonstrates a key role of T-cell subpopulations in IRI. We demonstrate that γδ-T-cell deficiency ameliorated pro-inflammatory cytokine production, neutrophil recruitment and distant organ injury. Thus, γδ-T-cells may be considered as mediators contributing to the inflammatory response in the acute phase of intestinal IRI.

Published

2021

49. γδT Cells Are Essential for Orthodontic Tooth Movement

Author

Omer Fleissig, Stella Chaushu, Sharon Wald, O Barel, Yasmin Saba, Immo Prinz, Inga Sandrock, Avi-Hai Hovav, Noam Koren, A Leibowitz, Yuval Aizenbud, Dror Aizenbud, Anneke Wilharm, O. Heyman, Y Tal, and Khaled Zubeidat

Subjects

Innate immune system, Tooth Movement Techniques, Chemistry, Periodontal Ligament, Monocyte, Interleukin, Osteoclasts, CD8-Positive T-Lymphocytes, Bone resorption, Resorption, Cell biology, Mice, medicine.anatomical_structure, stomatognathic system, Osteogenesis, medicine, Periodontal fiber, Animals, General Dentistry, Dental alveolus, CD8

Abstract

Sustained mechanical forces applied to tissue are known to shape local immunity. In the oral mucosa, mechanical stress, either naturally induced by masticatory forces or externally via mechanical loading during orthodontic tooth movement (OTM), is translated, in part, by T cells to alveolar bone resorption. Nevertheless, despite being considered critical for OTM, depletion of CD4+ and CD8+ T cells is reported to have no impact on tooth movement, thus questioning the function of αβT cells in OTM-associated bone resorption. To further address the role of T cells in OTM, we first characterized the leukocytes residing in the periodontal ligament (PDL), the tissue of interest during OTM, and compared it to the neighboring gingiva. Unlike the gingiva, monocytes and neutrophils represent the major leukocytes of the PDL. These myeloid cells were also the main leukocytes in the PDL of germ-free mice, although at lower levels than SPF mice. T lymphocytes were more enriched in the gingiva than the PDL, yet in both tissues, the relative fraction of the γδT cells was higher than the αβ T cells. We thus sought to examine the role of γδT cells in OTM. γδT cells residing in the PDL were mainly Vγ6+ and produced interleukin (IL)–17A but not interferon-γ. Using Tcrd-GDL mice allowing conditional ablation of γδT cells in vivo, we demonstrate that OTM was greatly diminished in the absence of γδT cells. Further analysis revealed that ablation of γδT cells decreased early IL-17A expression, monocyte and neutrophil recruitment, and the expression of the osteoclastogenic molecule receptor activator of nuclear factor–κβ ligand. This, eventually, resulted in reduced numbers of osteoclasts in the pressure site during OTM. Collectively, our data suggest that γδT cells are essential in OTM for translating orthodontic mechanical forces to bone resorption, required for relocating the tooth in the alveolar bone.

Published

2021

50. γδ intraepithelial lymphocytes facilitate pathological epithelial cell shedding via CD103-mediated granzyme release

Author

Madeleine D. Hu, Natasha B. Golovchenko, Thomas J. Kelly, Jonathan Agos, Matthew R. Zeglinski, Edward M. Bonder, Inga Sandrock, Immo Prinz, David J. Granville, Alastair J.M. Watson, and Karen L. Edelblum

Subjects

biology, Cell, T-cell receptor, hemic and immune systems, chemical and pharmacologic phenomena, medicine.anatomical_structure, Granzyme, Intestinal mucosa, Perforin, Immunology, medicine, biology.protein, Extracellular, Intraepithelial lymphocyte, Receptor

Abstract

SummaryExcessive shedding of enterocytes into the intestinal lumen is observed in inflammatory bowel disease and is correlated with disease relapse. However, the mechanisms underlying this phenomenon remain unclear. Intraepithelial lymphocytes (IEL) expressing the γδ T-cell receptor (TCR) provide surveillance of the intestinal mucosa at steady-state, which is regulated, in part, by CD103. Intravital microscopy of lipopolysaccharide (LPS)-treated mice revealed that γδ IELs make extended contact with shedding enterocytes. These prolonged interactions require CD103 engagement by E-cadherin, as CD103 blockade significantly reduces LPS-induced shedding. Furthermore, we find that granzymes A and B, but not perforin, are required for cell shedding, and that these granzymes are released by γδ IELs both constitutively and following CD103/E-cadherin ligation. These findings indicate that extracellular granzyme facilitates shedding, likely through cleavage of extracellular matrix proteins. Our results uncover a previously unrecognized role for γδ IELs in facilitating pathological cell shedding in a CD103- and granzyme-dependent manner.

Published

2021