Your search keyword '"Brockmann, Leonie"' showing total 41 results

1. Investigating the complexity of the double distance problems

Author

Braga, Marília D. V., Brockmann, Leonie R., Klerx, Katharina, and Stoye, Jens

Published

2024

2. Investigating the complexity of the double distance problems

Author

Braga, Marilia D. V., Brockmann, Leonie R., Klerx, Katharina, and Stoye, Jens

Subjects

Computer Science - Data Structures and Algorithms

Abstract

Two genomes over the same set of gene families form a canonical pair when each of them has exactly one gene from each family. Different distances of canonical genomes can be derived from a structure called breakpoint graph, which represents the relation between the two given genomes as a collection of cycles of even length and paths. Then, the breakpoint distance is equal to n - (c_2 + p_0/2), where n is the number of genes, c_2 is the number of cycles of length 2 and p_0 is the number of paths of length 0. Similarly, when the considered rearrangements are those modeled by the double-cut-and-join (DCJ) operation, the rearrangement distance is n - (c + p_e/2), where c is the total number of cycles and p_e is the total number of even paths. The distance formulation is a basic unit for several other combinatorial problems related to genome evolution and ancestral reconstruction, such as median or double distance. Interestingly, both median and double distance problems can be solved in polynomial time for the breakpoint distance, while they are NP-hard for the rearrangement distance. One way of exploring the complexity space between these two extremes is to consider the {\sigma}_k distance, defined to be n - [c_2 + c_4 + ... + c_k + (p_0 + p_2 + ... +p_k)/2], and increasingly investigate the complexities of median and double distance for the {\sigma}_4 distance, then the {\sigma}_6 distance, and so on. While for the median much effort was done in our and in other research groups but no progress was obtained even for the {\sigma}_4 distance, for solving the double distance under {\sigma}_4 and {\sigma}_6 distances we could devise linear time algorithms, which we present here., Comment: 24 pages, 26 figures

Published

2023

3. IL-10 dampens antitumor immunity and promotes liver metastasis via PD-L1 induction

Author

Shiri, Ahmad Mustafa, Zhang, Tao, Bedke, Tanja, Zazara, Dimitra E., Zhao, Lilan, Lücke, Jöran, Sabihi, Morsal, Fazio, Antonella, Zhang, Siwen, Tauriello, Daniele V.F., Batlle, Eduard, Steglich, Babett, Kempski, Jan, Agalioti, Theodora, Nawrocki, Mikołaj, Xu, Yang, Riecken, Kristoffer, Liebold, Imke, Brockmann, Leonie, Konczalla, Leonie, Bosurgi, Lidia, Mercanoglu, Baris, Seeger, Philipp, Küsters, Natalie, Lykoudis, Panagis M., Heumann, Asmus, Arck, Petra C., Fehse, Boris, Busch, Philipp, Grotelüschen, Rainer, Mann, Oliver, Izbicki, Jakob R., Hackert, Thilo, Flavell, Richard A., Gagliani, Nicola, Giannou, Anastasios D., and Huber, Samuel

Published

2024

4. On the Class of Double Distance Problems

Author

Braga, Marília D. V., Brockmann, Leonie R., Klerx, Katharina, Stoye, Jens, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Jahn, Katharina, editor, and Vinař, Tomáš, editor

Published

2023

5. Intestinal microbiota-specific Th17 cells possess regulatory properties and suppress effector T cells via c-MAF and IL-10

Author

Brockmann, Leonie, Tran, Alexander, Huang, Yiming, Edwards, Madeline, Ronda, Carlotta, Wang, Harris H., and Ivanov, Ivaylo I.

Published

2023

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

Author

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

Published

2021

7. Probiotic-guided CAR-T cells for solid tumor targeting

Author

Vincent, Rosa L., primary, Gurbatri, Candice R., additional, Li, Fangda, additional, Vardoshvili, Ana, additional, Coker, Courtney, additional, Im, Jongwon, additional, Ballister, Edward R., additional, Rouanne, Mathieu, additional, Savage, Thomas, additional, de los Santos-Alexis, Kenia, additional, Redenti, Andrew, additional, Brockmann, Leonie, additional, Komaranchath, Meghna, additional, Arpaia, Nicholas, additional, and Danino, Tal, additional

Published

2023

8. TGF-β signaling in Th17 cells promotes IL-22 production and colitis-associated colon cancer

Author

Perez, Laura Garcia, Kempski, Jan, McGee, Heather M., Pelzcar, Penelope, Agalioti, Theodora, Giannou, Anastasios, Konczalla, Leonie, Brockmann, Leonie, Wahib, Ramez, Xu, Hao, Vesely, Maria Carolina Amezcua, Soukou, Shiwa, Steglich, Babett, Bedke, Tanja, Manthey, Carolin, Seiz, Oliver, Diercks, Björn-Philipp, Gnafakis, Stylianos, Guse, Andreas H., Perez, Daniel, Izbicki, Jakob R., Gagliani, Nicola, Flavell, Richard A., and Huber, Samuel

Published

2020

9. Publisher Correction: TGF-β signaling in Th17 cells promotes IL-22 production and colitis-associated colon cancer

Author

Perez, Laura Garcia, Kempski, Jan, McGee, Heather M., Pelzcar, Penelope, Agalioti, Theodora, Giannou, Anastasios, Konczalla, Leonie, Brockmann, Leonie, Wahib, Ramez, Xu, Hao, Vesely, Maria Carolina Amezcua, Soukou, Shiwa, Steglich, Babett, Bedke, Tanja, Manthey, Carolin, Seiz, Oliver, Diercks, Björn-Philipp, Gnafakis, Stylianos, Guse, Andreas H., Perez, Daniel, Izbicki, Jakob R., Gagliani, Nicola, Flavell, Richard A., and Huber, Samuel

Published

2020

10. A pathogenic role for T cell-derived IL-22BP in inflammatory bowel disease

Author

Pelczar, Penelope, Witkowski, Mario, Perez, Laura Garcia, Kempski, Jan, Hammel, Anna G., Brockmann, Leonie, Kleinschmidt, Dörte, Wende, Sandra, Haueis, Cathleen, Bedke, Tanja, Witkowski, Marco, Krasemann, Susanne, Steurer, Stefan, Booth, Carmen J., Busch, Philipp, König, Alexandra, Rauch, Ursula, Benten, Daniel, Izbicki, Jakob R., Rösch, Thomas, Lohse, Ansgar W., Strowig, Till, Gagliani, Nicola, Flavell, Richard A., and Huber, Samuel

Published

2016

11. Tissue resident iNKT17 cells facilitate cancer cell extravasation in liver metastasis via interleukin-22

Author

Giannou, Anastasios D., primary, Kempski, Jan, additional, Shiri, Ahmad Mustafa, additional, Lücke, Jöran, additional, Zhang, Tao, additional, Zhao, Lilan, additional, Zazara, Dimitra E., additional, Cortesi, Filippo, additional, Riecken, Kristoffer, additional, Amezcua Vesely, Maria Carolina, additional, Low, Jun Siong, additional, Xu, Hao, additional, Kaffe, Eleanna, additional, Garcia-Perez, Laura, additional, Agalioti, Theodora, additional, Yamada, Yoshito, additional, Jungraithmayr, Wolfgang, additional, Zigmond, Ehud, additional, Karstens, Karl-Frederick, additional, Steglich, Babett, additional, Wagner, Jonas, additional, Konczalla, Leonie, additional, Carambia, Antonella, additional, Schulze, Kornelius, additional, von Felden, Johann, additional, May, Peter, additional, Briukhovetska, Daria, additional, Bedke, Tanja, additional, Brockmann, Leonie, additional, Starzonek, Sarah, additional, Lange, Tobias, additional, Koch, Claudia, additional, Riethdorf, Sabine, additional, Pelczar, Penelope, additional, Böttcher, Marius, additional, Sabihi, Morsal, additional, Huber, Francis J., additional, Reeh, Matthias, additional, Grass, Julia Kristin, additional, Wahib, Ramez, additional, Seese, Hannes, additional, Stüben, Björn-Ole, additional, Fard-Aghaie, Mohammad, additional, Duprée, Anna, additional, Scognamiglio, Pasquale, additional, Plitzko, Gabriel, additional, Meiners, Jan, additional, Soukou, Shiwa, additional, Wittek, Agnes, additional, Manthey, Caroline, additional, Maroulis, Ioannis C., additional, Arck, Petra C., additional, Perez, Daniel, additional, Gao, Bin, additional, Zarogiannis, Sotirios G., additional, Strowig, Till, additional, Pasqualini, Renata, additional, Arap, Wadih, additional, Gosálvez, Javier Suárez, additional, Kobold, Sebastian, additional, Prinz, Immo, additional, Guse, Andreas H., additional, Tachezy, Michael, additional, Ghadban, Tarik, additional, Heumann, Asmus, additional, Li, Jun, additional, Melling, Nathaniel, additional, Mann, Oliver, additional, Izbicki, Jakob R., additional, Pantel, Klaus, additional, Schumacher, Udo, additional, Lohse, Ansgar W., additional, Flavell, Richard A., additional, Gagliani, Nicola, additional, and Huber, Samuel, additional

Published

2023

12. A Critical Role of the IL-22–IL-22 Binding Protein Axis in Hepatocellular Carcinoma

Author

Giannou, Anastasios D., primary, Lücke, Jöran, additional, Kleinschmidt, Dörte, additional, Shiri, Ahmad Mustafa, additional, Steglich, Babett, additional, Nawrocki, Mikolaj, additional, Zhang, Tao, additional, Zazara, Dimitra E., additional, Kempski, Jan, additional, Zhao, Lilan, additional, Giannou, Olympia, additional, Agalioti, Theodora, additional, Brockmann, Leonie, additional, Bertram, Franziska, additional, Sabihi, Morsal, additional, Böttcher, Marius, additional, Ewald, Florian, additional, Schulze, Kornelius, additional, von Felden, Johann, additional, Machicote, Andres, additional, Maroulis, Ioannis C., additional, Arck, Petra C., additional, Graß, Julia-Kristin, additional, Mercanoglu, Baris, additional, Reeh, Matthias, additional, Wolter, Stefan, additional, Tachezy, Michael, additional, Seese, Hannes, additional, Theodorakopoulou, Myrto, additional, Lykoudis, Panagis M., additional, Heumann, Asmus, additional, Uzunoglu, Faik G., additional, Ghadban, Tarik, additional, Mann, Oliver, additional, Izbicki, Jakob R., additional, Li, Jun, additional, Duprée, Anna, additional, Melling, Nathaniel, additional, Gagliani, Nicola, additional, and Huber, Samuel, additional

Published

2022

13. CD4+ T-cell-derived IL-10 promotes CNS inflammation in mice by sustaining effector T cell survival

Author

Yogev, Nir, Bedke, Tanja, Kobayashi, Yasushi, Brockmann, Leonie, Lukas, Dominika, Regen, Tommy, Croxford, Andrew L, Nikolav, Alexei, Hövelmeyer, Nadine, von Stebut, Esther, Prinz, Marco, Ubeda, Carles, Maloy, Kevin J., Gagliani, Nicola, Flavell, Richard A, Waisman, Ari, and Huber, Samuel

Abstract

Interleukin (IL)-10 is considered a prototypical anti-inflammatory cytokine, significantly contributing to the maintenance and reestablishment of immune homeostasis. Accordingly, it has been shown in the intestine that IL-10 produced by Tregs can act on effector T cells, thereby limiting inflammation. Herein, we investigate whether this role also applies to IL-10 produced by T cells during central nervous system (CNS) inflammation. During neuroinflammation, both CNS-resident and -infiltrating cells produce IL-10; yet, as IL-10 has a pleotropic function, the exact contribution of the different cellular sources is not fully understood. We find that T-cell-derived IL-10, but not other relevant IL-10 sources, can promote inflammation in experimental autoimmune encephalomyelitis. Furthermore, in the CNS, T-cell-derived IL-10 acts on effector T cells, promoting their survival and thereby enhancing inflammation and CNS autoimmunity. Our data indicate a pro-inflammatory role of T-cell-derived IL-10 in the CNS.

Published

2022

14. A Linear Time Algorithm for an Extended Version of the Breakpoint Double Distance

Author

Brockmann, Leonie R., Klerx, Katharina, Stoye, Jens, Brockmann, Leonie R., Klerx, Katharina, and Stoye, Jens

Published

2022

15. TH17 cells transdifferentiate into regulatory T cells during resolution of inflammation

Author

Gagliani, Nicola, Vesely, Maria Carolina Amezcua, Iseppon, Andrea, Brockmann, Leonie, Xu, Hao, Palm, Noah W., de Zoete, Marcel R., Licona-Limon, Paula, Paiva, Ricardo S., Ching, Travers, Weaver, Casey, Zi, Xiaoyuan, Pan, Xinghua, Fan, Rong, Garmire, Lana X., Cotton, Matthew J., Drier, Yotam, Bernstein, Bradley, Geginat, Jens, Stockinger, Brigitta, Esplugues, Enric, Huber, Samuel, and Flavell, Richard A.

Subjects

T cells -- Physiological aspects, Inflammation -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Inflammation is a beneficial host response to infection but can contribute to inflammatory disease if unregulated. The TH17 lineage of T helper (Th) cells can cause severe human inflammatory diseases. These cells exhibit both instability (they can cease to express their signature cytokine, IL-17A) (1) and plasticity (they can start expressing cytokines typical of other lineages) (1,2) upon in vitro re-stimulation. However, technical limitations have prevented the transcriptional profiling of pre- and post-conversion TH17 cells ex vivo during immune responses. Thus, it is unknown whether TH17 cell plasticity merely reflects change in expression of a few cytokines, or if TH17 cells physiologically undergo global genetic reprogramming driving their conversion from one T helper cell type to another, a process known as transdifferentiation (3,4). Furthermore, although TH17 cell instability/plasticity has been associated with pathogenicity (1,2,5), it is unknown whether this could present a therapeutic opportunity, whereby formerly pathogenic TH17 cells could adopt an anti-inflammatory fate. Here we used two new fate-mapping mouse models to track TH17 cells during immune responses to show that [CD4.sup.+] T cells that formerly expressed IL-17A go on to acquire an antiinflammatory phenotype. The transdifferentiation of TH17 into regulatory T cells was illustrated by a change in their signature transcriptional profile and the acquisition of potent regulatory capacity. Comparisons of the transcriptional profiles of pre- and post-conversion TH17 cells also revealed a role for canonical TGF-β signalling and consequently for the aryl hydrocarbon receptor (AhR) in conversion. Thus, TH17 cells transdifferentiate into regulatory cells, and contribute to the resolution of inflammation. Our data suggest that TH17 cell instability and plasticity is a therapeutic opportunity for inflammatory diseases., TH17 cells are characterized by secretion of IL-17A, expression of chemokine receptor CCR6 and transcriptional factor RORγt (6). Their pathogenicity is limited by [Foxp3.sup.+] [T.sub.Reg] and T regulatory type 1 [...]

Published

2015

16. A Linear Time Algorithm for an Extended Version of the Breakpoint Double Distance

Author

Dias Vieira Braga, Marília, Brockmann, Leonie Ruth, Klerx, Katharina, Stoye, Jens, Boucher, Christina, and Rahmann, Sven

Subjects

genome rearrangement, breakpoint distance, Comparative genomics, double distance, double-cut-and-join (DCJ) distance, Applied computing → Bioinformatics

Abstract

Two genomes over the same set of gene families form a canonical pair when each of them has exactly one gene from each family. A genome is circular when it contains only circular chromosomes. Different distances of canonical circular genomes can be derived from a structure called breakpoint graph, which represents the relation between the two given genomes as a collection of cycles of even length. Then, the breakpoint distance is equal to n-c_2, where n is the number of genes and c_2 is the number of cycles of length 2. Similarly, when the considered rearrangements are those modeled by the double-cut-and-join (DCJ) operation, the rearrangement distance is n-c, where c is the total number of cycles. The distance problem is a basic unit for several other combinatorial problems related to genome evolution and ancestral reconstruction, such as median or double distance. Interestingly, both median and double distance problems can be solved in polynomial time for the breakpoint distance, while they are NP-hard for the rearrangement distance. One way of exploring the complexity space between these two extremes is to consider a σ_k distance, defined to be n-(c_2+c_4+…+c_k), and increasingly investigate the complexities of median and double distance for the σ₄ distance, then the σ₆ distance, and so on. While for the median much effort was done in our and in other research groups but no progress was obtained even for the σ₄ distance, for solving the double distance under σ₄ and σ₆ distances we could devise linear time algorithms, which we present here., LIPIcs, Vol. 242, 22nd International Workshop on Algorithms in Bioinformatics (WABI 2022), pages 13:1-13:16

Published

2022

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

Author

Cossarizza, Andrea, primary, Chang, Hyun‐Dong, additional, Radbruch, Andreas, additional, Abrignani, Sergio, additional, Addo, Richard, additional, Akdis, Mübeccel, additional, Andrä, Immanuel, additional, Andreata, Francesco, additional, Annunziato, Francesco, additional, Arranz, Eduardo, additional, Bacher, Petra, additional, Bari, Sudipto, additional, Barnaba, Vincenzo, additional, Barros‐Martins, Joana, additional, Baumjohann, Dirk, additional, Beccaria, Cristian G., additional, Bernardo, David, additional, Boardman, Dominic A., additional, Borger, Jessica, additional, Böttcher, Chotima, additional, Brockmann, Leonie, additional, Burns, Marie, additional, Busch, Dirk H., additional, Cameron, Garth, additional, Cammarata, Ilenia, additional, Cassotta, Antonino, additional, Chang, Yinshui, additional, Chirdo, Fernando Gabriel, additional, Christakou, Eleni, additional, Čičin‐Šain, Luka, additional, Cook, Laura, additional, Corbett, Alexandra J., additional, Cornelis, Rebecca, additional, Cosmi, Lorenzo, additional, Davey, Martin S., additional, De Biasi, Sara, additional, De Simone, Gabriele, additional, del Zotto, Genny, additional, Delacher, Michael, additional, Di Rosa, Francesca, additional, Di Santo, James, additional, Diefenbach, Andreas, additional, Dong, Jun, additional, Dörner, Thomas, additional, Dress, Regine J., additional, Dutertre, Charles‐Antoine, additional, Eckle, Sidonia B. G., additional, Eede, Pascale, additional, Evrard, Maximilien, additional, Falk, Christine S., additional, Feuerer, Markus, additional, Fillatreau, Simon, additional, Fiz‐Lopez, Aida, additional, Follo, Marie, additional, Foulds, Gemma A., additional, Fröbel, Julia, additional, Gagliani, Nicola, additional, Galletti, Giovanni, additional, Gangaev, Anastasia, additional, Garbi, Natalio, additional, Garrote, José Antonio, additional, Geginat, Jens, additional, Gherardin, Nicholas A., additional, Gibellini, Lara, additional, Ginhoux, Florent, additional, Godfrey, Dale I., additional, Gruarin, Paola, additional, Haftmann, Claudia, additional, Hansmann, Leo, additional, Harpur, Christopher M., additional, Hayday, Adrian C., additional, Heine, Guido, additional, Hernández, Daniela Carolina, additional, Herrmann, Martin, additional, Hoelsken, Oliver, additional, Huang, Qing, additional, Huber, Samuel, additional, Huber, Johanna E., additional, Huehn, Jochen, additional, Hundemer, Michael, additional, Hwang, William Y. K., additional, Iannacone, Matteo, additional, Ivison, Sabine M., additional, Jäck, Hans‐Martin, additional, Jani, Peter K., additional, Keller, Baerbel, additional, Kessler, Nina, additional, Ketelaars, Steven, additional, Knop, Laura, additional, Knopf, Jasmin, additional, Koay, Hui‐Fern, additional, Kobow, Katja, additional, Kriegsmann, Katharina, additional, Kristyanto, H., additional, Krueger, Andreas, additional, Kuehne, Jenny F., additional, Kunze‐Schumacher, Heike, additional, Kvistborg, Pia, additional, Kwok, Immanuel, additional, Latorre, Daniela, additional, Lenz, Daniel, additional, Levings, Megan K., additional, Lino, Andreia C., additional, Liotta, Francesco, additional, Long, Heather M., additional, Lugli, Enrico, additional, MacDonald, Katherine N., additional, Maggi, Laura, additional, Maini, Mala K., additional, Mair, Florian, additional, Manta, Calin, additional, Manz, Rudolf Armin, additional, Mashreghi, Mir‐Farzin, additional, Mazzoni, Alessio, additional, McCluskey, James, additional, Mei, Henrik E., additional, Melchers, Fritz, additional, Melzer, Susanne, additional, Mielenz, Dirk, additional, Monin, Leticia, additional, Moretta, Lorenzo, additional, Multhoff, Gabriele, additional, Muñoz, Luis Enrique, additional, Muñoz‐Ruiz, Miguel, additional, Muscate, Franziska, additional, Natalini, Ambra, additional, Neumann, Katrin, additional, Ng, Lai Guan, additional, Niedobitek, Antonia, additional, Niemz, Jana, additional, Almeida, Larissa Nogueira, additional, Notarbartolo, Samuele, additional, Ostendorf, Lennard, additional, Pallett, Laura J., additional, Patel, Amit A., additional, Percin, Gulce Itir, additional, Peruzzi, Giovanna, additional, Pinti, Marcello, additional, Pockley, A. Graham, additional, Pracht, Katharina, additional, Prinz, Immo, additional, Pujol‐Autonell, Irma, additional, Pulvirenti, Nadia, additional, Quatrini, Linda, additional, Quinn, Kylie M., additional, Radbruch, Helena, additional, Rhys, Hefin, additional, Rodrigo, Maria B., additional, Romagnani, Chiara, additional, Saggau, Carina, additional, Sakaguchi, Shimon, additional, Sallusto, Federica, additional, Sanderink, Lieke, additional, Sandrock, Inga, additional, Schauer, Christine, additional, Scheffold, Alexander, additional, Scherer, Hans U., additional, Schiemann, Matthias, additional, Schildberg, Frank A., additional, Schober, Kilian, additional, Schoen, Janina, additional, Schuh, Wolfgang, additional, Schüler, Thomas, additional, Schulz, Axel R., additional, Schulz, Sebastian, additional, Schulze, Julia, additional, Simonetti, Sonia, additional, Singh, Jeeshan, additional, Sitnik, Katarzyna M., additional, Stark, Regina, additional, Starossom, Sarah, additional, Stehle, Christina, additional, Szelinski, Franziska, additional, Tan, Leonard, additional, Tarnok, Attila, additional, Tornack, Julia, additional, Tree, Timothy I. M., additional, van Beek, Jasper J. P., additional, van de Veen, Willem, additional, van Gisbergen, Klaas, additional, Vasco, Chiara, additional, Verheyden, Nikita A., additional, von Borstel, Anouk, additional, Ward‐Hartstonge, Kirsten A., additional, Warnatz, Klaus, additional, Waskow, Claudia, additional, Wiedemann, Annika, additional, Wilharm, Anneke, additional, Wing, James, additional, Wirz, Oliver, additional, Wittner, Jens, additional, Yang, Jennie H. M., additional, and Yang, Juhao, additional

Published

2021

18. Coexpression of CD49b and LAG-3 identifies human and mouse T regulatory type 1 cells

Author

Gagliani, Nicola, Magnani, Chiara F., Huber, Samuel, Gianolini, Monica E., Pala, Mauro, Licona-Limon, Paula, Guo, Binggege, Herbert, De'Broski R., Bulfone, Alessandro, Trentini, Filippo, Serio, Clelia Di, Bacchetta, Rosa, Andreani, Marco, Brockmann, Leonie, Gregori, Silvia, Flavell, Richard A., and Roncarolo, Maria-Grazia

Subjects

T cells -- Receptors -- Physiological aspects -- Genetic aspects -- Research, Gene expression -- Physiological aspects -- Research, Antigen receptors, T cell -- Physiological aspects -- Genetic aspects -- Research, Biological sciences, Health

Abstract

[D4.sup.+] type 1 T regulatory (Tr1) cells are induced in the periphery and have a pivotal role in promoting and maintaining tolerance. The absence of surface markers that uniquely identify [...]

Published

2013

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

Author

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

Published

2021

20. Additional file 1 of Interleukin-10 improves stroke outcome by controlling the detrimental Interleukin-17A response

Author

Piepke, Marius, Clausen, Bettina H., Ludewig, Peter, Vienhues, Jonas H., Bedke, Tanja, Javidi, Ehsan, Rissiek, Bj��rn, Jank, Larissa, Brockmann, Leonie, Sandrock, Inga, Degenhardt, Karoline, Jander, Alina, Roth, Vanessa, Sch��dlich, Ines S., Prinz, Immo, Flavell, Richard A., Kobayashi, Yasushi, Renn��, Thomas, Gerloff, Christian, Huber, Samuel, Magnus, Tim, and Gelderblom, Mathias

Abstract

Additional file 1: Figure S1. Il10���/��� mice exhibit worsened neurological scores compared to WT littermate controls, whereas mortality did not differ between groups. (A) Bederson score and survival rate; (B) 14 days after tMCAO in WT control and Il10���/��� mice. Figure S2. Generation of bone-marrow chimeric mice and characterization of post-ischemic IL-10 producers. (A) Generation of bone-marrow chimeras. (B) Representative FACS plots of peripheral blood of bone-marrow chimeras after sacrifice. (C) Flow cytometric analysis of IL-10 produced by B cells, NK cells, CD8+, and CD4+ T cells after sham surgery and 3, 7, and 14 days after stroke in FIR-tiger mice. (D) Expression of Tr1 cell markers CD49b and Lag-3 on CD4+ T cells in spleen and CNS 3 days after tMCAO in FIR-tiger mice. Figure S3. IL-10 deficiency leads to an activation of the IL-17A axis and IL-17A positive ���� T cellls co-express PD-1 in the post ischemic brain. (A) Flow cytometric analysis of the number of infiltrating IL-17A+ CD4+ and ���� T cells isolated from ischemic hemispheres of WT controls and Il10���/��� mice 7 days after tMCAO. (B) Relative gene expression of Cxcl1 and Mmp3 in ischemic hemispheres of WT and Il10���/��� mice 3 days after tMCAO. (C) Flow cytometric analysis of IL-17 production and PD-1 co-expression by ���� T cells in cervical lymph nodes and the CNS 3 days after stroke.

Published

2021

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

Author

Rolf M. Schwiete Foundation, Associazione Italiana per la Ricerca sul Cancro, German Research Foundation, National Institutes of Health (US), European Commission, Cossarizza, Andrea, Chang, Hyun‐Dong, Radbruch, Andreas, Abrignani, Sergio, Addo, Richard, Akdis, Mübeccel, Andrä, Immanuel, Andreata, Francesco, Annunziato, Francesco, Arranz, Eduardo, Bacher, Petra, Knop, Laura, Knopf, Jasmin, Koay, Hui-Fern, Kobow, Katja, Kriegsmann, Katharina, Kristyanto, H., Krueger, Andreas, Kuehne, Jenny F., Kunze-Schumacher, Heike, Maini, Mala K., Verheyden, Nikita A., Kvistborg, Pia, Kwok, Immanuel, Latorre, Daniela, Mair, Florian, Bari, Sudipto, Manta, Calin, Armin Manz, Rudolf, Mashreghi, Mir-Farzin, Mazzoni, Alessio, McCluskey, James, Borstel, Anouk von, Mei, Henrik E., Melchers, Fritz, Melzer, Susanne, Mielenz, Dirk, Monin, Leticia, Barnaba, Vincenzo, Moretta, Lorenzo, Multhoff, Gabriele, Muñoz, Luis Enrique, Muñoz-Ruiz, Miguel, Ward-Hartstonge, Kirsten A., Muscate, Franziska, Natalini, Ambra, Neumann, Katrin, Guan N., Lai, Niedobitek, Antonia, Niemz, Jana, Barros-Martins, Joana, Nogueira Almeida, Larissa, Notarbartolo, Samuele, Ostendorf, Lennard, Warnatz, Klaus, Pallett, Laura J., Patel, Amit A., Itir Percin, Gulce, Peruzzi, Giovanna, Pinti, Marcello, Pockley, A. Graham, Pracht, Katharina, Baumjohann, Dirk, Prinz, Immo, Pujol-Autonell, Irma, Waskow, Claudia, Pulvirenti, Nadia, Quatrini, Linda, Quinn, Kylie M., Radbruch, Helena, Rhys, Hefin, Rodrigo, Maria B., Romagnani, Chiara, Saggau, Carina, Beccaria, Cristian G., Sakaguchi, Shimon, Wiedemann, Annika, Sallusto, Federica, Sanderink, Lieke, Sandrock, Inga, Schauer, Christine, Scheffold, Alexander, Scherer, Hans U., Schiemann, Matthias, Schildberg, Frank A., Schober, Kilian, Bernardo, David, Wilharm, Anneke, Schoen, Janina, Schuh, Wolfgang, Schüler, Thomas, Schulz, Axel R., Schulz, Sebastian, Schulze, Julia, Simonetti, Sonia, Singh, Jeeshan, Sitnik, Katarzyna M., Stark, Regina, Wing, James, Boardman, Dominic A., Starossom, Sarah, Stehle, Christina, Szelinski, Franziska, Tan, Leonard, Tarnok, Attila, Tornack, Julia, Tree, Timothy I. M., Van Beek, Jasper J. P., Veen, Willem van de, Wirz, Oliver, Gisbergen, Klaas van, Borger, Jessica, Vasco, Chiara, Böttcher, Chotima, Lenz, Daniel, Wittner, Jens, Yang, Jennie H. M., Yang, Juhao, Brockmann, Leonie, Burns, Marie, Busch, Dirk H., Cameron, Garth, Cammarata, Ilenia, Cassotta, Antonino, Chang, Yinshui, Levings, Megan K., Chirdo, Fernando G., Christakou, Eleni, Cicin-Sain, Luka, Cook, Laura, Corbett, Alexandra J., Cornelis, Rebecca, Cosmi, Lorenzo, Davey, Martin S., Biasi, Sara De, Simone, Gabriele De, Lino, Andreia C., Zotto, Genny del, Delacher, Michael, Rosa, Francesca Di, Santo, James Di, Diefenbach, Andreas, Dong, Jun, Dörner, Thomas, Dress, Regine J., Dutertre, Charles-Antoine, Eckle, Sidonia B. G., Liotta, Francesco, Eede, Pascale, Evrard, Maximilien, Falk, Christine S., Feuerer, Markus, Fillatreau, Simon, Fiz-López, Aida, Follo, Marie, Foulds, Gemma A., Fröbel, Julia, Gagliani, Nicola, Long, Heather M., Galletti, Giovanni, Gangaev, Anastasia, Garbi, Natalio, Garrote, José Antonio, Geginat, Jens, Gherardin, Nicholas A., Gibellini, Lara, Ginhoux, Florent, Godfrey, Dale I., Gruarin, Paola, Lugli, Enrico, Haftmann, Claudia, Hansmann, Leo, Harpur, Christopher M., Hayday, Adrian C., Heine, Guido, Hernández, Daniela Carolina, Herrmann, Martin, Hoelsken, Oliver, Huang, Qing, Huber, Samuel, MacDonald, Katherine N., Huber, Johanna E., Huehn, Jochen, Hundemer, Michael, Hwang, William Y. K., Iannacone, Matteo, Ivison, Sabine M., Jäck, Hans-Martin, Jani, Peter K., Keller, Baerbel, Kessler, Nina, Maggi, Laura, Ketelaars, Steven, Rolf M. Schwiete Foundation, Associazione Italiana per la Ricerca sul Cancro, German Research Foundation, National Institutes of Health (US), European Commission, Cossarizza, Andrea, Chang, Hyun‐Dong, Radbruch, Andreas, Abrignani, Sergio, Addo, Richard, Akdis, Mübeccel, Andrä, Immanuel, Andreata, Francesco, Annunziato, Francesco, Arranz, Eduardo, Bacher, Petra, Knop, Laura, Knopf, Jasmin, Koay, Hui-Fern, Kobow, Katja, Kriegsmann, Katharina, Kristyanto, H., Krueger, Andreas, Kuehne, Jenny F., Kunze-Schumacher, Heike, Maini, Mala K., Verheyden, Nikita A., Kvistborg, Pia, Kwok, Immanuel, Latorre, Daniela, Mair, Florian, Bari, Sudipto, Manta, Calin, Armin Manz, Rudolf, Mashreghi, Mir-Farzin, Mazzoni, Alessio, McCluskey, James, Borstel, Anouk von, Mei, Henrik E., Melchers, Fritz, Melzer, Susanne, Mielenz, Dirk, Monin, Leticia, Barnaba, Vincenzo, Moretta, Lorenzo, Multhoff, Gabriele, Muñoz, Luis Enrique, Muñoz-Ruiz, Miguel, Ward-Hartstonge, Kirsten A., Muscate, Franziska, Natalini, Ambra, Neumann, Katrin, Guan N., Lai, Niedobitek, Antonia, Niemz, Jana, Barros-Martins, Joana, Nogueira Almeida, Larissa, Notarbartolo, Samuele, Ostendorf, Lennard, Warnatz, Klaus, Pallett, Laura J., Patel, Amit A., Itir Percin, Gulce, Peruzzi, Giovanna, Pinti, Marcello, Pockley, A. Graham, Pracht, Katharina, Baumjohann, Dirk, Prinz, Immo, Pujol-Autonell, Irma, Waskow, Claudia, Pulvirenti, Nadia, Quatrini, Linda, Quinn, Kylie M., Radbruch, Helena, Rhys, Hefin, Rodrigo, Maria B., Romagnani, Chiara, Saggau, Carina, Beccaria, Cristian G., Sakaguchi, Shimon, Wiedemann, Annika, Sallusto, Federica, Sanderink, Lieke, Sandrock, Inga, Schauer, Christine, Scheffold, Alexander, Scherer, Hans U., Schiemann, Matthias, Schildberg, Frank A., Schober, Kilian, Bernardo, David, Wilharm, Anneke, Schoen, Janina, Schuh, Wolfgang, Schüler, Thomas, Schulz, Axel R., Schulz, Sebastian, Schulze, Julia, Simonetti, Sonia, Singh, Jeeshan, Sitnik, Katarzyna M., Stark, Regina, Wing, James, Boardman, Dominic A., Starossom, Sarah, Stehle, Christina, Szelinski, Franziska, Tan, Leonard, Tarnok, Attila, Tornack, Julia, Tree, Timothy I. M., Van Beek, Jasper J. P., Veen, Willem van de, Wirz, Oliver, Gisbergen, Klaas van, Borger, Jessica, Vasco, Chiara, Böttcher, Chotima, Lenz, Daniel, Wittner, Jens, Yang, Jennie H. M., Yang, Juhao, Brockmann, Leonie, Burns, Marie, Busch, Dirk H., Cameron, Garth, Cammarata, Ilenia, Cassotta, Antonino, Chang, Yinshui, Levings, Megan K., Chirdo, Fernando G., Christakou, Eleni, Cicin-Sain, Luka, Cook, Laura, Corbett, Alexandra J., Cornelis, Rebecca, Cosmi, Lorenzo, Davey, Martin S., Biasi, Sara De, Simone, Gabriele De, Lino, Andreia C., Zotto, Genny del, Delacher, Michael, Rosa, Francesca Di, Santo, James Di, Diefenbach, Andreas, Dong, Jun, Dörner, Thomas, Dress, Regine J., Dutertre, Charles-Antoine, Eckle, Sidonia B. G., Liotta, Francesco, Eede, Pascale, Evrard, Maximilien, Falk, Christine S., Feuerer, Markus, Fillatreau, Simon, Fiz-López, Aida, Follo, Marie, Foulds, Gemma A., Fröbel, Julia, Gagliani, Nicola, Long, Heather M., Galletti, Giovanni, Gangaev, Anastasia, Garbi, Natalio, Garrote, José Antonio, Geginat, Jens, Gherardin, Nicholas A., Gibellini, Lara, Ginhoux, Florent, Godfrey, Dale I., Gruarin, Paola, Lugli, Enrico, Haftmann, Claudia, Hansmann, Leo, Harpur, Christopher M., Hayday, Adrian C., Heine, Guido, Hernández, Daniela Carolina, Herrmann, Martin, Hoelsken, Oliver, Huang, Qing, Huber, Samuel, MacDonald, Katherine N., Huber, Johanna E., Huehn, Jochen, Hundemer, Michael, Hwang, William Y. K., Iannacone, Matteo, Ivison, Sabine M., Jäck, Hans-Martin, Jani, Peter K., Keller, Baerbel, Kessler, Nina, Maggi, Laura, and Ketelaars, Steven

Abstract

The third edition of Flow Cytometry Guidelines provides the key aspects to consider when performing flow cytometry experiments and includes comprehensive sections describing phenotypes and functional assays of all major human and murine immune cell subsets. Notably, the Guidelines contain helpful tables highlighting phenotypes and key differences between human and murine cells. Another useful feature of this edition is the flow cytometry analysis of clinical samples with examples of flow cytometry applications in the context of autoimmune diseases, cancers as well as acute and chronic infectious diseases. Furthermore, there are sections detailing tips, tricks and pitfalls to avoid. All sections are written and peer-reviewed by leading flow cytometry experts and immunologists, making this edition an essential and state-of-the-art handbook for basic and clinical researchers.

Published

2021

22. IL22BP Mediates the Antitumor Effects of Lymphotoxin Against Colorectal Tumors in Mice and Humans

Author

Kempski, Jan, primary, Giannou, Anastasios D., additional, Riecken, Kristoffer, additional, Zhao, Lilan, additional, Steglich, Babett, additional, Lücke, Jöran, additional, Garcia-Perez, Laura, additional, Karstens, Karl-Frederick, additional, Wöstemeier, Anna, additional, Nawrocki, Mikolaj, additional, Pelczar, Penelope, additional, Witkowski, Mario, additional, Nilsson, Sven, additional, Konczalla, Leonie, additional, Shiri, Ahmad Mustafa, additional, Kempska, Joanna, additional, Wahib, Ramez, additional, Brockmann, Leonie, additional, Huber, Philipp, additional, Gnirck, Ann-Christin, additional, Turner, Jan-Eric, additional, Zazara, Dimitra E., additional, Arck, Petra C., additional, Stein, Alexander, additional, Simon, Ronald, additional, Daubmann, Anne, additional, Meiners, Jan, additional, Perez, Daniel, additional, Strowig, Till, additional, Koni, Pandelakis, additional, Kruglov, Andrey A., additional, Sauter, Guido, additional, Izbicki, Jakob R., additional, Guse, Andreas H., additional, Rösch, Thomas, additional, Lohse, Ansgar W., additional, Flavell, Richard A., additional, Gagliani, Nicola, additional, and Huber, Samuel, additional

Published

2020

23. Molecular and functional heterogeneity of IL-10-producing CD4+ T cells

Author

Brockmann, Leonie, primary, Soukou, Shiwa, additional, Steglich, Babett, additional, Czarnewski, Paulo, additional, Zhao, Lilan, additional, Wende, Sandra, additional, Bedke, Tanja, additional, Ergen, Can, additional, Manthey, Carolin, additional, Agalioti, Theodora, additional, Geffken, Maria, additional, Seiz, Oliver, additional, Parigi, Sara M., additional, Sorini, Chiara, additional, Geginat, Jens, additional, Fujio, Keishi, additional, Jacobs, Thomas, additional, Roesch, Thomas, additional, Izbicki, Jacob R., additional, Lohse, Ansgar W., additional, Flavell, Richard A., additional, Krebs, Christian, additional, Gustafsson, Jan-Ake, additional, Antonson, Per, additional, Roncarolo, Maria Grazia, additional, Villablanca, Eduardo J., additional, Gagliani, Nicola, additional, and Huber, Samuel, additional

Published

2018

24. Flt3 ligand expands bona fide innate lymphoid cell precursors in vivo

Author

Parigi, Sara M., Czarnewski, Paulo, Das, Srustidhar, Steeg, Christiane, Brockmann, Leonie, Fernandez-Gaitero, Sara, Yman, Victor, Forkel, Marianne, Höög, Charlotte, Mjösberg, Jenny, Westerberg, Lisa, Färnert, Anna, Huber, Samuel, Jacobs, Thomas, Villablanca, Eduardo J., Parigi, Sara M., Czarnewski, Paulo, Das, Srustidhar, Steeg, Christiane, Brockmann, Leonie, Fernandez-Gaitero, Sara, Yman, Victor, Forkel, Marianne, Höög, Charlotte, Mjösberg, Jenny, Westerberg, Lisa, Färnert, Anna, Huber, Samuel, Jacobs, Thomas, and Villablanca, Eduardo J.

Abstract

A common helper-like innate lymphoid precursor (CHILP) restricted to the innate lymphoid cells (ILC) lineage has been recently characterized. While specific requirements of transcription factors for CHILPs development has been partially described, their ability to sense cytokines and react to peripheral inflammation remains unaddressed. Here, we found that systemic increase in Flt3L levels correlated with the expansion of Lineage (Lin)(neg)alpha 4 beta 7(+) precursors in the adult murine bone marrow. Expanded Lin(neg)alpha 4 beta 7(+) precursors were bona fide CHILPs as seen by their ability to differentiate into all helper ILCs subsets but cNK in vivo. Interestingly, Flt3L-expanded CHILPs transferred into lymphopenic mice preferentially reconstituted the small intestine. While we did not observe changes in serum Flt3L during DSS-induced colitis in mice or plasma from inflammatory bowel disease (IBD) patients, elevated Flt3L levels were detected in acute malaria patients. Interestingly, while CHILP numbers were stable during the course of DSS-induced colitis, they expanded following increased serum Flt3L levels in malaria-infected mice, hence suggesting a role of the Flt3L-ILC axis in malaria. Collectively, our results indicate that Flt3L expands CHILPs in the bone marrow, which might be associated with specific inflammatory conditions., Funding Agencies|Swedish Research Council VR grant [K2015-68X-22765-01-6]; FORMAS [2016-00830]; Wallenberg Academy Fellow (WAF) program

Published

2018

25. Flt3 ligand expands bona fide innate lymphoid cell precursors in vivo

Author

Parigi, Sara M., primary, Czarnewski, Paulo, additional, Das, Srustidhar, additional, Steeg, Christiane, additional, Brockmann, Leonie, additional, Fernandez-Gaitero, Sara, additional, Yman, Victor, additional, Forkel, Marianne, additional, Höög, Charlotte, additional, Mjösberg, Jenny, additional, Westerberg, Lisa, additional, Färnert, Anna, additional, Huber, Samuel, additional, Jacobs, Thomas, additional, and Villablanca, Eduardo J., additional

Published

2018

26. Role of IL-10 Receptor Signaling in the Function of CD4+ T-Regulatory Type 1 cells: T-Cell Therapy in Patients with Inflammatory Bowel Disease

Author

Soukou, Shiwa, primary, Brockmann, Leonie, additional, Bedke, Tanja, additional, Gagliani, Nicola, additional, Flavell, Richard A., additional, and Huber, Samuel, additional

Published

2018

27. TH17 Cell and Epithelial Cell Crosstalk during Inflammatory Bowel Disease and Carcinogenesis

Author

Kempski, Jan, primary, Brockmann, Leonie, additional, Gagliani, Nicola, additional, and Huber, Samuel, additional

Published

2017

28. Regulation of TH17 Cells and Associated Cytokines in Wound Healing, Tissue Regeneration, and Carcinogenesis

Author

Brockmann, Leonie, primary, Giannou, Anastasios, additional, Gagliani, Nicola, additional, and Huber, Samuel, additional

Published

2017

29. IL-10 Receptor Signaling Is Essential for TR1 Cell Function In Vivo

Author

Brockmann, Leonie, primary, Gagliani, Nicola, additional, Steglich, Babett, additional, Giannou, Anastasios D., additional, Kempski, Jan, additional, Pelczar, Penelope, additional, Geffken, Maria, additional, Mfarrej, Bechara, additional, Huber, Francis, additional, Herkel, Johannes, additional, Wan, Yisong Y., additional, Esplugues, Enric, additional, Battaglia, Manuela, additional, Krebs, Christian F., additional, Flavell, Richard A., additional, and Huber, Samuel, additional

Published

2017

30. Th17 cells transdifferentiate into regulatory T cells during resolution of inflammation

Author

LS Infectiebiologie (Bacteriologie), I&I SIB2, Infection & Immunity, Gagliani, Nicola, Vesely, Maria Carolina Amezcua, Iseppon, Andrea, Brockmann, Leonie, Xu, Hao, Palm, Noah W, de Zoete, Marcel R, Licona-Limón, Paula, Paiva, Ricardo S, Ching, Travers, Weaver, Casey, Zi, Xiaoyuan, Pan, Xinghua, Fan, Rong, Garmire, Lana X, Cotton, Matthew J, Drier, Yotam, Bernstein, Bradley, Geginat, Jens, Stockinger, Brigitta, Esplugues, Enric, Huber, Samuel, Flavell, Richard A, LS Infectiebiologie (Bacteriologie), I&I SIB2, Infection & Immunity, Gagliani, Nicola, Vesely, Maria Carolina Amezcua, Iseppon, Andrea, Brockmann, Leonie, Xu, Hao, Palm, Noah W, de Zoete, Marcel R, Licona-Limón, Paula, Paiva, Ricardo S, Ching, Travers, Weaver, Casey, Zi, Xiaoyuan, Pan, Xinghua, Fan, Rong, Garmire, Lana X, Cotton, Matthew J, Drier, Yotam, Bernstein, Bradley, Geginat, Jens, Stockinger, Brigitta, Esplugues, Enric, Huber, Samuel, and Flavell, Richard A

Published

2015

31. TH17 Cell and Epithelial Cell Crosstalk during Inflammatory Bowel Disease and Carcinogenesis.

Author

Kempski, Jan, Brockmann, Leonie, Gagliani, Nicola, and Huber, Samuel

Subjects

INFLAMMATORY bowel diseases, COLON cancer, T cells

Abstract

The intestine is colonized by hundreds of different species of commensal bacteria, viruses, and fungi. Therefore, the intestinal immune system is constantly being challenged by foreign antigens. The immune system, the commensal microbiota, and the intestinal epithelial surface have to maintain a tight balance to guarantee defense against potential pathogens and to prevent chronic inflammatory conditions at the same time. Failure of these mechanisms can lead to a vicious cycle in which a perpet- ual tissue damage/repair process results in a pathological reorganization of the normal mucosal surface. This dysregulation of the intestine is considered to be one of the underlying causes for both inflammatory bowel disease (IBD) and colorectal cancer. TH17 cells have been associated with immune-mediated diseases, such as IBD, since their discovery in 2005. Upon mucosal damage, these cells are induced by a combination of different cytokines, such as IL-6, TGF-β, and IL-1β. TH17 cells are crucial players in the defense against extracellular pathogens and have various mechanisms to fulfill their function. They can activate and attract phagocytic cells. Additionally, TH17 cells can induce the release of anti-microbial peptides from non-immune cells, such as epithelial cells. The flip side of the coin is the strong potential of TH17 cells to be pro-inflammatory and promote pathogenicity. TH17 cells have been linked to both mucosal regeneration and inflammation. In turn, these cells and their cytokines emerged as potential therapeutic targets both for inflammatory diseases and cancer. This review will summarize the current knowledge regarding the TH17 cell-enterocyte crosstalk and give an overview of its clinical implications. [ABSTRACT FROM AUTHOR]

Published

2017

32. Regulation of TH17 Cells and Associated Cytokines in Wound Healing, Tissue Regeneration, and Carcinogenesis.

Author

Brockmann, Leonie, Giannou, Anastasios D., Gagliani, Nicola, and Huber, Samuel

Subjects

*CYTOKINES, *T cells, *WOUND healing, *CARCINOGENESIS, *PATHOGENIC microorganisms, *TUMOR necrosis factors

Abstract

Wound healing is a crucial process which protects our body against permanent damage and invasive infectious agents. Upon tissue damage, inflammation is an early event which is orchestrated by a multitude of innate and adaptive immune cell subsets including TH17 cells. TH17 cells and TH17 cell associated cytokines can impact wound healing positively by clearing pathogens and modulating mucosal surfaces and epithelial cells. Injury of the gut mucosa can cause fast expansion of TH17 cells and their induction from naïve T cells through Interleukin (IL)-6, TGF-β, and IL-1β signaling. TH17 cells produce various cytokines, such as tumor necrosis factor (TNF)-α, IL-17, and IL-22, which can promote cell survival and proliferation and thus tissue regeneration in several organs including the skin, the intestine, and the liver. However, TH17 cells are also potentially pathogenic if not tightly controlled. Failure of these control mechanisms can result in chronic inflammatory conditions, such as Inflammatory Bowel Disease (IBD), and can ultimately promote carcinogenesis. Therefore, there are several mechanisms which control TH17 cells. One control mechanism is the regulation of TH17 cells via regulatory T cells and IL-10. This mechanism is especially important in the intestine to terminate immune responses and maintain homeostasis. Furthermore, TH17 cells have the potential to convert from a pro-inflammatory phenotype to an anti-inflammatory phenotype by changing their cytokine profile and acquiring IL-10 production, thereby limiting their own pathological potential. Finally, IL-22, a signature cytokine of TH17 cells, can be controlled by an endogenous soluble inhibitory receptor, Interleukin 22 binding protein (IL-22BP). During tissue injury, the production of IL-22 by TH17 cells is upregulated in order to promote tissue regeneration. To limit the regenerative program, which could promote carcinogenesis, IL-22BP is upregulated during the later phase of regeneration in order to terminate the effects of IL-22. This delicate balance secures the beneficial effects of IL-22 and prevents its potential pathogenicity. An important future goal is to understand the precise mechanisms underlying the regulation of TH17 cells during inflammation, wound healing, and carcinogenesis in order to design targeted therapies for a variety of diseases including infections, cancer, and immune mediated inflammatory disease. [ABSTRACT FROM AUTHOR]

Published

2017

33. IL-10 Receptor Signaling Is Essential for TR1 Cell Function In Vivo.

Author

Brockmann, Leonie, Gagliani, Nicola, Steglich, Babett, Giannou, Anastasios D., Kempski, Jan, Pelczar, Penelope, Geffken, Maria, Mfarrej, Bechara, Huber, Francis, Herkel, Johannes, Wan, Yisong Y., Esplugues, Enric, Battaglia, Manuela, Krebs, Christian F., Flavell, Richard A., and Huber, Samuel

Subjects

*CELL physiology, *HOMEOSTASIS, *CYTOKINES, *LABORATORY mice, *T cells, *THERAPEUTICS

Abstract

IL-10 is essential to maintain intestinal homeostasis. CD4+ T regulatory type 1 (TR1) cells produce large amounts of this cytokine and are therefore currently being examined in clinical trials as T cell therapy in patients with inflammatory bowel disease. However, factors and molecular signals sustaining TR1 cell regulatory activity still need to be identified to optimize the efficiency and ensure the safety of these trials. We investigated the role of IL-10 signaling in mature TR1 cells in vivo. Double IL-10eGFP Foxp3mRFP reporter mice and transgenic mice with impairment in IL-10 receptor signaling were used to test the activity of TR1 cells in a murine inflammatory bowel disease model, a model that resembles the trials performed in humans. The molecular signaling was elucidated in vitro. Finally, we used human TR1 cells, currently employed for cell therapy, to confirm our results. We found that murine TR1 cells expressed functional IL-10Ra. TR1 cells with impaired IL-10 receptor signaling lost their regulatory activity in vivo. TR1 cells required IL-10 receptor signaling to activate p38 MAPK, thereby sustaining IL-10 production, which ultimately mediated their suppressive activity. Finally, we confirmed these data using human TR1 cells. In conclusion, TR1 cell regulatory activity is dependent on IL-10 receptor signaling. These data suggest that to optimize TR1 cell-based therapy, IL-10 receptor expression has to be taken into consideration. [ABSTRACT FROM AUTHOR]

Published

2017

34. Erratum: Corrigendum: Coexpression of CD49b and LAG-3 identifies human and mouse T regulatory type 1 cells

Author

Gagliani, Nicola, primary, Magnani, Chiara F, additional, Huber, Samuel, additional, Gianolini, Monica E, additional, Pala, Mauro, additional, Licona-Limon, Paula, additional, Guo, Binggege, additional, Herbert, De'Broski R, additional, Bulfone, Alessandro, additional, Trentini, Filippo, additional, Di Serio, Clelia, additional, Bacchetta, Rosa, additional, Andreani, Marco, additional, Brockmann, Leonie, additional, Gregori, Silvia, additional, Flavell, Richard A, additional, and Roncarolo, Maria-Grazia, additional

Published

2014

35. CD4+T-cell-derived IL-10 promotes CNS inflammation in mice by sustaining effector T cell survival

Author

Yogev, Nir, Bedke, Tanja, Kobayashi, Yasushi, Brockmann, Leonie, Lukas, Dominika, Regen, Tommy, Croxford, Andrew L., Nikolav, Alexei, Hövelmeyer, Nadine, von Stebut, Esther, Prinz, Marco, Ubeda, Carles, Maloy, Kevin J., Gagliani, Nicola, Flavell, Richard A., Waisman, Ari, and Huber, Samuel

Abstract

Interleukin (IL)-10 is considered a prototypical anti-inflammatory cytokine, significantly contributing to the maintenance and reestablishment of immune homeostasis. Accordingly, it has been shown in the intestine that IL-10 produced by Tregs can act on effector T cells, thereby limiting inflammation. Herein, we investigate whether this role also applies to IL-10 produced by T cells during central nervous system (CNS) inflammation. During neuroinflammation, both CNS-resident and -infiltrating cells produce IL-10; yet, as IL-10 has a pleotropic function, the exact contribution of the different cellular sources is not fully understood. We find that T-cell-derived IL-10, but not other relevant IL-10 sources, can promote inflammation in experimental autoimmune encephalomyelitis. Furthermore, in the CNS, T-cell-derived IL-10 acts on effector T cells, promoting their survival and thereby enhancing inflammation and CNS autoimmunity. Our data indicate a pro-inflammatory role of T-cell-derived IL-10 in the CNS.

Published

2022

36. Molecular and functional heterogeneity of IL-10-producing CD4+ T cells.

Author

Brockmann, Leonie, Soukou, Shiwa, Steglich, Babett, Czarnewski, Paulo, Zhao, Lilan, Wende, Sandra, Bedke, Tanja, Ergen, Can, Manthey, Carolin, Agalioti, Theodora, Geffken, Maria, Seiz, Oliver, Parigi, Sara M., Sorini, Chiara, Geginat, Jens, Fujio, Keishi, Jacobs, Thomas, Roesch, Thomas, Izbicki, Jacob R., and Lohse, Ansgar W.

Abstract

IL-10 is a prototypical anti-inflammatory cytokine, which is fundamental to the maintenance of immune homeostasis, especially in the intestine. There is an assumption that cells producing IL-10 have an immunoregulatory function. However, here we report that IL-10-producing CD4+ T cells are phenotypically and functionally heterogeneous. By combining single cell transcriptome and functional analyses, we identified a subpopulation of IL-10-producing Foxp3neg CD4+ T cells that displays regulatory activity unlike other IL-10-producing CD4+ T cells, which are unexpectedly pro-inflammatory. The combinatorial expression of co-inhibitory receptors is sufficient to discriminate IL-10-producing CD4+ T cells with regulatory function from others and to identify them across different tissues and disease models in mice and humans. These regulatory IL-10-producing Foxp3neg CD4+ T cells have a unique transcriptional program, which goes beyond the regulation of IL-10 expression. Finally, we found that patients with Inflammatory Bowel Disease demonstrate a deficiency in this specific regulatory T-cell subpopulation. Tr1 cells are considered an immunosuppressive CD4 T cell population producing IL-10. Here the authors show that IL-10 is insufficient for Tr1 immunosuppression, define surface markers and transcriptional program of the immunosuppressive subset within Tr1, and reveal its deficiency in patients with IBD. [ABSTRACT FROM AUTHOR]

Published

2018

37. Corrigendum: Coexpression of CD49b and LAG-3 identifies human and mouse T regulatory type 1 cells.

Author

Gagliani, Nicola, Magnani, Chiara F, Huber, Samuel, Gianolini, Monica E, Pala, Mauro, Licona-Limon, Paula, Guo, Binggege, Herbert, De'Broski R, Bulfone, Alessandro, Trentini, Filippo, Di Serio, Clelia, Bacchetta, Rosa, Andreani, Marco, Brockmann, Leonie, Gregori, Silvia, Flavell, Richard A, and Roncarolo, Maria-Grazia

Subjects

JOURNALISTIC errors, HUMAN T cells

Abstract

A correction to the article "Coexpression of CD49b and LAG-3 identifies human and mouse T regulatory type 1 cells" that was published in the 2013 issue is presented.

Published

2014

38. CD4 + T-cell-derived IL-10 promotes CNS inflammation in mice by sustaining effector T cell survival.

Author

Yogev N, Bedke T, Kobayashi Y, Brockmann L, Lukas D, Regen T, Croxford AL, Nikolav A, Hövelmeyer N, von Stebut E, Prinz M, Ubeda C, Maloy KJ, Gagliani N, Flavell RA, Waisman A, and Huber S

Subjects

Animals, CD4-Positive T-Lymphocytes, Cell Survival, Central Nervous System, Inflammation, Mice, Interleukin-10 physiology, T-Lymphocytes

Abstract

Interleukin (IL)-10 is considered a prototypical anti-inflammatory cytokine, significantly contributing to the maintenance and reestablishment of immune homeostasis. Accordingly, it has been shown in the intestine that IL-10 produced by Tregs can act on effector T cells, thereby limiting inflammation. Herein, we investigate whether this role also applies to IL-10 produced by T cells during central nervous system (CNS) inflammation. During neuroinflammation, both CNS-resident and -infiltrating cells produce IL-10; yet, as IL-10 has a pleotropic function, the exact contribution of the different cellular sources is not fully understood. We find that T-cell-derived IL-10, but not other relevant IL-10 sources, can promote inflammation in experimental autoimmune encephalomyelitis. Furthermore, in the CNS, T-cell-derived IL-10 acts on effector T cells, promoting their survival and thereby enhancing inflammation and CNS autoimmunity. Our data indicate a pro-inflammatory role of T-cell-derived IL-10 in the CNS., Competing Interests: Declaration of interests The authors declare no conflicts of interest., (Copyright © 2022 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2022

39. Molecular and functional heterogeneity of IL-10-producing CD4 + T cells.

Author

Brockmann L, Soukou S, Steglich B, Czarnewski P, Zhao L, Wende S, Bedke T, Ergen C, Manthey C, Agalioti T, Geffken M, Seiz O, Parigi SM, Sorini C, Geginat J, Fujio K, Jacobs T, Roesch T, Izbicki JR, Lohse AW, Flavell RA, Krebs C, Gustafsson JA, Antonson P, Roncarolo MG, Villablanca EJ, Gagliani N, and Huber S

Subjects

Animals, Humans, Mice, Inbred C57BL, Single-Cell Analysis, Transcriptome, CD4-Positive T-Lymphocytes metabolism, Inflammatory Bowel Diseases immunology, Interleukin-10 metabolism

Abstract

IL-10 is a prototypical anti-inflammatory cytokine, which is fundamental to the maintenance of immune homeostasis, especially in the intestine. There is an assumption that cells producing IL-10 have an immunoregulatory function. However, here we report that IL-10-producing CD4 + T cells are phenotypically and functionally heterogeneous. By combining single cell transcriptome and functional analyses, we identified a subpopulation of IL-10-producing Foxp3 neg CD4 + T cells that displays regulatory activity unlike other IL-10-producing CD4 + T cells, which are unexpectedly pro-inflammatory. The combinatorial expression of co-inhibitory receptors is sufficient to discriminate IL-10-producing CD4 + T cells with regulatory function from others and to identify them across different tissues and disease models in mice and humans. These regulatory IL-10-producing Foxp3 neg CD4 + T cells have a unique transcriptional program, which goes beyond the regulation of IL-10 expression. Finally, we found that patients with Inflammatory Bowel Disease demonstrate a deficiency in this specific regulatory T-cell subpopulation.

Published

2018

40. T H 17 Cell and Epithelial Cell Crosstalk during Inflammatory Bowel Disease and Carcinogenesis.

Author

Kempski J, Brockmann L, Gagliani N, and Huber S

Abstract

The intestine is colonized by hundreds of different species of commensal bacteria, viruses, and fungi. Therefore, the intestinal immune system is constantly being challenged by foreign antigens. The immune system, the commensal microbiota, and the intestinal epithelial surface have to maintain a tight balance to guarantee defense against potential pathogens and to prevent chronic inflammatory conditions at the same time. Failure of these mechanisms can lead to a vicious cycle in which a perpetual tissue damage/repair process results in a pathological reorganization of the normal mucosal surface. This dysregulation of the intestine is considered to be one of the underlying causes for both inflammatory bowel disease (IBD) and colorectal cancer. T H 17 cells have been associated with immune-mediated diseases, such as IBD, since their discovery in 2005. Upon mucosal damage, these cells are induced by a combination of different cytokines, such as IL-6, TGF-β, and IL-1β. T H 17 cells are crucial players in the defense against extracellular pathogens and have various mechanisms to fulfill their function. They can activate and attract phagocytic cells. Additionally, T H 17 cells can induce the release of anti-microbial peptides from non-immune cells, such as epithelial cells. The flip side of the coin is the strong potential of T H 17 cells to be pro-inflammatory and promote pathogenicity. T H 17 cells have been linked to both mucosal regeneration and inflammation. In turn, these cells and their cytokines emerged as potential therapeutic targets both for inflammatory diseases and cancer. This review will summarize the current knowledge regarding the T H 17 cell-enterocyte crosstalk and give an overview of its clinical implications.

Published

2017

41. Regulation of T H 17 Cells and Associated Cytokines in Wound Healing, Tissue Regeneration, and Carcinogenesis.

Author

Brockmann L, Giannou AD, Gagliani N, and Huber S

Subjects

Adaptive Immunity, Animals, Cell Proliferation, Cell Survival, Cytokines immunology, Humans, Immunity, Innate, Inflammation immunology, Inflammatory Bowel Diseases immunology, Mice, Carcinogenesis immunology, Th17 Cells immunology, Wound Healing immunology

Abstract

Wound healing is a crucial process which protects our body against permanent damage and invasive infectious agents. Upon tissue damage, inflammation is an early event which is orchestrated by a multitude of innate and adaptive immune cell subsets including T H 17 cells. T H 17 cells and T H 17 cell associated cytokines can impact wound healing positively by clearing pathogens and modulating mucosal surfaces and epithelial cells. Injury of the gut mucosa can cause fast expansion of T H 17 cells and their induction from naïve T cells through Interleukin (IL)-6, TGF-β, and IL-1β signaling. T H 17 cells produce various cytokines, such as tumor necrosis factor (TNF)-α, IL-17, and IL-22, which can promote cell survival and proliferation and thus tissue regeneration in several organs including the skin, the intestine, and the liver. However, T H 17 cells are also potentially pathogenic if not tightly controlled. Failure of these control mechanisms can result in chronic inflammatory conditions, such as Inflammatory Bowel Disease (IBD), and can ultimately promote carcinogenesis. Therefore, there are several mechanisms which control T H 17 cells. One control mechanism is the regulation of T H 17 cells via regulatory T cells and IL-10. This mechanism is especially important in the intestine to terminate immune responses and maintain homeostasis. Furthermore, T H 17 cells have the potential to convert from a pro-inflammatory phenotype to an anti-inflammatory phenotype by changing their cytokine profile and acquiring IL-10 production, thereby limiting their own pathological potential. Finally, IL-22, a signature cytokine of T H 17 cells, can be controlled by an endogenous soluble inhibitory receptor, Interleukin 22 binding protein (IL-22BP). During tissue injury, the production of IL-22 by T H 17 cells is upregulated in order to promote tissue regeneration. To limit the regenerative program, which could promote carcinogenesis, IL-22BP is upregulated during the later phase of regeneration in order to terminate the effects of IL-22. This delicate balance secures the beneficial effects of IL-22 and prevents its potential pathogenicity. An important future goal is to understand the precise mechanisms underlying the regulation of T H 17 cells during inflammation, wound healing, and carcinogenesis in order to design targeted therapies for a variety of diseases including infections, cancer, and immune mediated inflammatory disease.

Published

2017