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7. Immune tolerance against infused FVIII in hemophilia A is mediated by PD-L1+ Tregs

Author

Becker-Gotot, J, Meissner, M, Kotov, V, Jurado-Mestre, B, Maione, A, Pannek, A, Albert, T, Flores, C, Schildberg, FA, Gleeson, PA, Reipert, BM, Oldenburg, J, Kurts, C, Becker-Gotot, J, Meissner, M, Kotov, V, Jurado-Mestre, B, Maione, A, Pannek, A, Albert, T, Flores, C, Schildberg, FA, Gleeson, PA, Reipert, BM, Oldenburg, J, and Kurts, C

Abstract

A major complication of hemophilia A therapy is the development of alloantibodies (inhibitors) that neutralize intravenously administered coagulation factor VIII (FVIII). Immune tolerance induction therapy (ITI) by repetitive FVIII injection can eradicate inhibitors, and thereby reduce morbidity and treatment costs. However, ITI success is difficult to predict and the underlying immunological mechanisms are unknown. Here, we demonstrated that immune tolerance against FVIII under nonhemophilic conditions was maintained by programmed death (PD) ligand 1-expressing (PD-L1-expressing) regulatory T cells (Tregs) that ligated PD-1 on FVIII-specific B cells, causing them to undergo apoptosis. FVIII-deficient mice injected with FVIII lacked such Tregs and developed inhibitors. Using an ITI mouse model, we found that repetitive FVIII injection induced FVIII-specific PD-L1+ Tregs and reengaged removal of inhibitor-forming B cells. We also demonstrated the existence of FVIII-specific Tregs in humans and showed that such Tregs upregulated PD-L1 in patients with hemophilia after successful ITI. Simultaneously, FVIII-specific B cells upregulated PD-1 and became killable by Tregs. In summary, we showed that PD-1-mediated B cell tolerance against FVIII operated in healthy individuals and in patients with hemophilia A without inhibitors, and that ITI reengaged this mechanism. These findings may impact monitoring of ITI success and treatment of patients with hemophilia A.

Published
2022

8. Monocyte-derived macrophages aggravate pulmonary vasculitis via cGAS/STING/IFN-mediated nucleic acid sensing (vol 219, e0220759, 2022)

Author

Kessler, N, Viehmann, SF, Krollmann, C, Mai, K, Kirschner, KM, Luksch, H, Kotagiri, P, Boehner, AMC, Huugen, D, de Oliveira Mann, CC, Otten, S, Weiss, SAI, Zillinger, T, Dobrikova, K, Jenne, DE, Behrendt, R, Ablasser, A, Bartok, E, Hartmann, G, Hopfner, K-P, Lyons, PA, Boor, P, Roesen-Wolff, A, Teichmann, LL, Heeringa, P, Kurts, C, Garbi, N, Kessler, N, Viehmann, SF, Krollmann, C, Mai, K, Kirschner, KM, Luksch, H, Kotagiri, P, Boehner, AMC, Huugen, D, de Oliveira Mann, CC, Otten, S, Weiss, SAI, Zillinger, T, Dobrikova, K, Jenne, DE, Behrendt, R, Ablasser, A, Bartok, E, Hartmann, G, Hopfner, K-P, Lyons, PA, Boor, P, Roesen-Wolff, A, Teichmann, LL, Heeringa, P, Kurts, C, and Garbi, N

Published
2022

9. Gastrointestinaler »field effect«: Folge immunologischer Prozesse im Darm?

Author

Koscielny, A., Engel, D., Börner, T., Kurts, C., Kalff, J. C., Bruch, H. P., editor, Büchler, M. W., editor, Buhr, H. J., editor, Hohenberger, W., editor, Klar, E., editor, Kremer, B., editor, Post, S., editor, Schilling, M., editor, Schumpelick, V., editor, Siewert, J. R., editor, Thiede, A., editor, Becker, H., editor, Bittner, R., editor, Függer, R., editor, Köckerling, F., editor, Saeger, H. D., editor, Zornig, C., editor, Hölscher, A., editor, Izbicki, J. R., editor, Junginger, T., editor, Senninger, N., editor, Allgayer, H., editor, Broll, R., editor, Bruns, C. J., editor, Fries, H., editor, Kalthoff, H., editor, Schackert, H. K., editor, Ertel, W., editor, Faist, E., editor, Holzheimer, R. G., editor, Holzmann, B., editor, Schade, U. F., editor, Vollmar, B., editor, Brückner, U. B., editor, Heidecke, C. D., editor, Menger, M. D., editor, Neugebauer, E., editor, Spiegel, H. U., editor, Biemer, E., editor, Germann, G., editor, Haas, N., editor, Machens, H. G., editor, Stark, G. B., editor, Steinau, H. U., editor, Haverich, A., editor, Heberer, M., editor, Rogiers, X., editor, Jauch, K. W., editor, Roth, H., editor, von Schweinitz, D., editor, Waag, K. L., editor, Altendorf-Hofmann, A., editor, Celik, I., editor, Lehnert, T., editor, Lorenz, W., editor, Ohmann, C., editor, Bechstein, W. O., editor, Broelsch, C., editor, Hopt, U., editor, Klempnauer, J., editor, Neuhaus, P., editor, Fändrich, F., editor, Markus, B., editor, Minor, T., editor, Wonigeit, K., editor, Dralle, H., editor, Goretzki, P. E., editor, Rothmund, M., editor, Bühren, V., editor, Josten, C., editor, Muhr, G., editor, Nast-Kolb, D., editor, Stürmer, K. M., editor, Trentz, O., editor, Brunkwall, J., editor, Sandmann, W., editor, Schmitz-Rixen, T., editor, Storck, M., editor, Branscheid, D., editor, Dienemann, H., editor, Hirner, A., editor, Passlick, B., editor, Toomes, H., editor, Beyersdorf, F., editor, Hetzer, R., editor, Schäfers, H. J., editor, Zerkowski, H. R., editor, Becker, H. D., editor, Saeger, H. -D., editor, Jauch, K. -W., editor, and Bauer, H., editor

Published
2006
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11. Sodium and its manifold impact on our immune system

Author

Jobin, K., Müller, D.N., Jantsch, J., and Kurts, C.

Subjects
endocrine system, animal structures, Cardiovascular and Metabolic Diseases
Abstract

The Western diet is rich in salt, and a high salt diet (HSD) is suspected to be a risk factor for cardiovascular diseases. It is now widely accepted that an experimental HSD can stimulate components of the immune system, potentially exacerbating certain autoimmune diseases, or alternatively, improving defenses against certain infections, such as cutaneous leishmaniasis. However, recent findings show that an experimental HSD may also aggravate other infections (e.g., pyelonephritis or systemic listeriosis). Here, we discuss the modulatory effects of a HSD on the microbiota, metabolic signaling, hormonal responses, local sodium concentrations, and their effects on various immune cell types in different tissues. We describe how these factors are integrated, resulting either in immune stimulation or suppression in various tissues and disease settings.

Published
2021

13. Die mesenterialen Lymphknoten und das GALT spielen eine zentrale Rolle bei der Vermittlung des gastrointestinalen Field Effects

Author

Koscielny, Arne, Engel, D., Kurts, C., Hirner, A., Kalff, J., Bruch, H. P., editor, Büchler, M. W., editor, Buhr, H. J., editor, Hohenberger, W., editor, Klar, E., editor, Post, S., editor, Schilling, M., editor, Schumpelick, V., editor, Siewert, J. R., editor, Thiede, A., editor, Becker, H., editor, Bittner, R., editor, Függer, R., editor, Köckerling, F., editor, Saeger, H. D., editor, Zornig, C., editor, Hölscher, A., editor, Izbicki, J. R., editor, Jauch, K. W., editor, Senninger, N., editor, Allgayer, H., editor, Bruns, C. J., editor, Celik, I., editor, Fries, H., editor, Kalthoff, H., editor, Schackert, H. K., editor, Brückner, U. B., editor, Ertel, W., editor, Faist, E., editor, Holzheimer, R. G., editor, Holzmann, B., editor, Schade, U. F., editor, Vollmar, B., editor, Heidecke, C. D., editor, Menger, M. D., editor, Neugebauer, E., editor, Spiegel, H. U., editor, Germann, G., editor, Haas, N., editor, Langer, S., editor, Machens, H. G., editor, Stark, G. B., editor, Steinau, H. U., editor, Haverich, A., editor, Heberer, M., editor, Fitze, G., editor, Roth, H., editor, von Schweinitz, D., editor, Waag, K. L., editor, Altendorf-Hofmann, A., editor, Lehnert, T., editor, Lorenz, W., editor, Ohmann, C., editor, Bechstein, W. O., editor, Broelsch, C., editor, Hopt, U., editor, Klempnauer, J., editor, Fändrich, F., editor, Markus, B., editor, Minor, T., editor, Neuhaus, P., editor, Wonigeit, K., editor, Dralle, H., editor, Goretzki, P. E., editor, Rothmund, M., editor, Bühren, V., editor, Josten, C., editor, Muhr, G., editor, Nast-Kolb, D., editor, Stürmer, K. M., editor, Trentz, O., editor, Brunkwall, J., editor, Sandmann, W., editor, Schmitz-Rixen, T., editor, Storck, M., editor, Branscheid, D., editor, Dienemann, H., editor, Hirner, A., editor, Passlick, B., editor, Toomes, H., editor, Beyersdorf, F., editor, Hetzer, R., editor, Schäfers, H. J., editor, Steinsträßer, L., editor, Vogt, P., editor, Arbogast, R., editor, and Bauer, H., editor

Published
2008
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14. Pathogen-induced tissue-resident memory TH17 (TRM17) cells amplify autoimmune kidney disease.

Author

Huber T.B., Franzenburg S., Koch-Nolte F., Turner J.-E., Riedel J.-H., Huber S., Gagliani N., Wiech T., Rohde H., Bono M.R., Bonn S., Panzer U., Mittrucker H.-W., Krebs C.F., Reimers D., Zhao Y., Paust H.-J., Bartsch P., Nunez S., Rosemblatt M.V., Hellmig M., Kilian C., Borchers A., Enk L.U.B., Zinke M., Becker M., Schmid J., Klinge S., Wong M.N., Puelles V.G., Schmidt C., Bertram T., Stumpf N., Hoxha E., Meyer-Schwesinger C., Lindenmeyer M.T., Cohen C.D., Rink M., Kurts C., Huber T.B., Franzenburg S., Koch-Nolte F., Turner J.-E., Riedel J.-H., Huber S., Gagliani N., Wiech T., Rohde H., Bono M.R., Bonn S., Panzer U., Mittrucker H.-W., Krebs C.F., Reimers D., Zhao Y., Paust H.-J., Bartsch P., Nunez S., Rosemblatt M.V., Hellmig M., Kilian C., Borchers A., Enk L.U.B., Zinke M., Becker M., Schmid J., Klinge S., Wong M.N., Puelles V.G., Schmidt C., Bertram T., Stumpf N., Hoxha E., Meyer-Schwesinger C., Lindenmeyer M.T., Cohen C.D., Rink M., and Kurts C.

Abstract

Although it is well established that microbial infections predispose to autoimmune diseases, the underlying mechanisms remain poorly understood. After infection, tissue-resident memory T (TRM) cells persist in peripheral organs and provide immune protection against reinfection. However, whether TRM cells participate in responses unrelated to the primary infection, such as autoimmune inflammation, is unknown. By using high-dimensional single-cell analysis, we identified CD4+ TRM cells with a TH17 signature (termed TRM17 cells) in kidneys of patients with ANCA-associated glomerulonephritis. Experimental models demonstrated that renal TRM17 cells were induced by pathogens infecting the kidney, such as Staphylococcus aureus, Candida albicans, and uropathogenic Escherichia coli, and persisted after the clearance of infections. Upon induction of experimental glomerulonephritis, these kidney TRM17 cells rapidly responded to local proinflammatory cytokines by producing IL-17A and thereby exacerbate renal pathology. Thus, our data show that pathogen-induced TRM17 cells have a previously unrecognized function in aggravating autoimmune disease.Copyright © 2020 American Association for the Advancement of Science. All rights reserved.

Published
2020

22. T Cell Tolerance and Autoimmunity

Author

Miller, J. F. A. P., primary, Heath, W. R., additional, Allison, J., additional, Morahan, G., additional, Hoffmann, M., additional, Kurts, C., additional, and Kosaka, H., additional

Published
2007
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24. Novel 3D analysis using optical tissue clearing documents the evolution of murine rapidly progressive glomerulonephritis.

Author

Moeller M.J., Floege J., Kramann R., Kurts C., Bertram J.F., Spehr M., Nikolic-Paterson D.J., Puelles V.G., Fleck D., Ortz L., Papadouri S., Strieder T., Bohner A.M.C., van der Wolde J.W., Vogt M., Saritas T., Kuppe C., Fuss A., Menzel S., Klinkhammer B.M., Muller-Newen G., Heymann F., Decker L., Braun F., Kretz O., Huber T.B., Susaki E.A., Ueda H.R., Boor P., Moeller M.J., Floege J., Kramann R., Kurts C., Bertram J.F., Spehr M., Nikolic-Paterson D.J., Puelles V.G., Fleck D., Ortz L., Papadouri S., Strieder T., Bohner A.M.C., van der Wolde J.W., Vogt M., Saritas T., Kuppe C., Fuss A., Menzel S., Klinkhammer B.M., Muller-Newen G., Heymann F., Decker L., Braun F., Kretz O., Huber T.B., Susaki E.A., Ueda H.R., and Boor P.

Abstract

Recent developments in optical tissue clearing have been difficult to apply for the morphometric analysis of organs with high cellular content and small functional structures, such as the kidney. Here, we establish combinations of genetic and immuno-labelling for single cell identification, tissue clearing and subsequent de-clarification for histoimmunopathology and transmission electron microscopy. Using advanced light microscopy and computational analyses, we investigated a murine model of crescentic nephritis, an inflammatory kidney disease typified by immune-mediated damage to glomeruli leading to the formation of hypercellular lesions and the rapid loss of kidney function induced by nephrotoxic serum. Results show a graded susceptibility of the glomeruli, significant podocyte loss and capillary injury. These effects are associated with activation of parietal epithelial cells and formation of glomerular lesions that may evolve and obstruct the kidney tubule, thereby explaining the loss of kidney function. Thus, our work provides new high-throughput endpoints for the analysis of complex tissues with single-cell resolution.Copyright © 2019 International Society of Nephrology

Published
2019

25. Chronically stimulated human MAIT cells are unexpectedly potent IL-13 producers

Author

Kelly, J, Minoda, Y, Meredith, T, Cameron, G, Philipp, M-S, Pellicci, DG, Corbett, AJ, Kurts, C, Gray, DHD, Godfrey, D, Kannourakis, G, Berzins, SP, Kelly, J, Minoda, Y, Meredith, T, Cameron, G, Philipp, M-S, Pellicci, DG, Corbett, AJ, Kurts, C, Gray, DHD, Godfrey, D, Kannourakis, G, and Berzins, SP

Abstract

Mucosal-associated invariant T (MAIT) cells are unconventional T cells that recognize antigens derived from riboflavin biosynthesis. In addition to anti-microbial functions, human MAIT cells are associated with cancers, autoimmunity, allergies and inflammatory disorders, although their role is poorly understood. Activated MAIT cells are well known for their rapid release of Th1 and Th17 cytokines, but we have discovered that chronic stimulation can also lead to potent interleukin (IL)-13 expression. We used RNA-seq and qRT-PCR to demonstrate high expression of the IL-13 gene in chronically stimulated MAIT cells, and directly identify IL-13 using intracellular flow cytometry and multiplex bead analysis of MAIT cell cultures. This unexpected finding has important implications for IL-13-dependent diseases, such as colorectal cancer (CRC), that occur in mucosal areas where MAIT cells are abundant. We identify MAIT cells near CRC tumors and show that these areas and precancerous polyps express high levels of the IL-13 receptor, which promotes tumor progression and metastasis. Our data suggest that MAIT cells have a more complicated role in CRC than currently realized and that they represent a promising new target for immunotherapies where IL-13 can be a critical factor.

Published
2019

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

Author

Cossarizza, A, Chang, H-D, Radbruch, A, Acs, A, Adam, D, Adam-Klages, S, Agace, WW, Aghaeepour, N, Akdis, M, Allez, M, Almeida, LN, Alvisi, G, Anderson, G, Andrae, I, Annunziato, F, Anselmo, A, Bacher, P, Baldari, CT, 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, DA, Bogdan, C, Borger, JG, Borsellino, G, Boulais, PE, Bradford, JA, Brenner, D, Brinkman, RR, Brooks, AES, Busch, DH, Buescher, M, Bushnell, TP, Calzetti, F, Cameron, G, Cammarata, I, Cao, X, Cardell, SL, Casola, S, Cassatella, MA, Cavani, A, Celada, A, Chatenoud, L, Chattopadhyay, PK, Chow, S, Christakou, E, Cicin-Sain, L, Clerici, M, Colombo, FS, Cook, L, Cooke, A, Cooper, AM, Corbett, AJ, Cosma, A, Cosmi, L, Coulie, PG, Cumano, A, Cvetkovic, L, Dang, VD, Dang-Heine, C, Davey, MS, Davies, D, De Biasi, S, Del Zotto, G, Dela Cruz, GV, Delacher, M, Della Bella, S, Dellabona, P, Deniz, G, Dessing, M, Di Santo, JP, Diefenbach, A, Dieli, F, Dolf, A, Doerner, T, Dress, RJ, Dudziak, D, Dustin, M, Dutertre, C-A, Ebner, F, Eckle, SBG, Edinger, M, Eede, P, Ehrhardt, GRA, Eich, M, Engel, P, Engelhardt, B, Erdei, A, Esser, C, Everts, B, Evrard, M, Falk, CS, Fehniger, TA, Felipo-Benavent, M, Ferry, H, Feuerer, M, Filby, A, Filkor, K, Fillatreau, S, Follo, M, Foerster, I, Foster, J, Foulds, GA, Frehse, B, Frenette, PS, Frischbutter, S, Fritzsche, W, Galbraith, DW, Gangaev, A, Garbi, N, Gaudilliere, B, Gazzinelli, RT, Geginat, J, Gerner, W, Gherardin, NA, Ghoreschi, K, Gibellini, L, Ginhoux, F, Goda, K, Godfrey, DI, Goettlinger, C, Gonzalez-Navajas, JM, Goodyear, CS, Gori, A, Grogan, JL, Grummitt, D, Gruetzkau, A, Haftmann, C, Hahn, J, Hammad, H, Haemmerling, G, Hansmann, L, Hansson, G, Harpur, CM, Hartmann, S, Hauser, A, Hauser, AE, Haviland, DL, Hedley, D, Hernandez, DC, Herrera, G, Herrmann, M, Hess, C, Hoefer, T, Hoffmann, P, Hogquist, K, Holland, T, Hollt, T, Holmdahl, R, Hombrink, P, Houston, JP, Hoyer, BF, Huang, B, Huang, F-P, Huber, JE, Huehn, J, Hundemer, M, Hunter, CA, Hwang, WYK, Iannone, A, Ingelfinger, F, Ivison, SM, Jaeck, H-M, Jani, PK, Javega, B, Jonjic, S, Kaiser, T, Kalina, T, Kamradt, T, Kaufmann, SHE, Keller, B, Ketelaars, SLC, Khalilnezhad, A, Khan, S, Kisielow, J, Klenerman, P, Knopf, J, Koay, H-F, Kobow, K, Kolls, JK, Kong, WT, Kopf, M, Korn, T, Kriegsmann, K, Kristyanto, H, Kroneis, T, Krueger, A, Kuehne, 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, MD, Leung, LYT, Levings, MK, Lino, AC, Liotta, F, Litwin, V, Liu, Y, Ljunggren, H-G, Lohoff, M, Lombardi, G, Lopez, L, Lopez-Botet, M, Lovett-Racke, AE, Lubberts, E, Luche, H, Ludewig, B, Lugli, E, Lunemann, S, Maecker, HT, Maggi, L, Maguire, O, Mair, F, Mair, KH, Mantovani, A, Manz, RA, Marshall, AJ, Martinez-Romero, A, Martrus, G, Marventano, I, Maslinski, W, Matarese, G, Mattioli, AV, Maueroder, C, Mazzoni, A, McCluskey, J, McGrath, M, McGuire, HM, McInnes, IB, Mei, HE, Melchers, F, Melzer, S, Mielenz, D, Miller, SD, Mills, KHG, Minderman, H, Mjosberg, J, Moore, J, Moran, B, Moretta, L, Mosmann, TR, Mueller, S, Multhoff, G, Munoz, LE, Munz, C, Nakayama, T, Nasi, M, Neumann, K, Ng, LG, 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, WF, Piconese, S, Pinti, M, Pockley, AG, Podolska, MJ, Poon, Z, Pracht, K, Prinz, I, Pucillo, CEM, Quataert, SA, Quatrini, L, Quinn, KM, Radbruch, H, Radstake, TRDJ, Rahmig, S, Rahn, H-P, Rajwa, B, Ravichandran, G, Raz, Y, Rebhahn, JA, Recktenwald, D, Reimer, D, Reis e Sousa, C, Remmerswaal, EBM, Richter, L, Rico, LG, Riddell, A, Rieger, AM, Robinson, JP, Romagnani, C, Rubartelli, A, Ruland, J, Saalmueller, A, Saeys, Y, Saito, T, Sakaguchi, S, Sala-de-Oyanguren, F, Samstag, Y, Sanderson, S, Sandrock, I, Santoni, A, Sanz, RB, Saresella, M, Sautes-Fridman, C, Sawitzki, B, Schadt, L, Scheffold, A, Scherer, HU, Schiemann, M, Schildberg, FA, Schimisky, E, Schlitzer, A, Schlosser, J, Schmid, S, Schmitt, S, Schober, K, Schraivogel, D, Schuh, W, Schueler, T, Schulte, R, Schulz, AR, Schulz, SR, Scotta, C, Scott-Algara, D, Sester, DP, Shankey, TV, Silva-Santos, B, Simon, AK, Sitnik, KM, Sozzani, S, Speiser, DE, Spidlen, J, Stahlberg, A, Stall, AM, 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, TIM, 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, RAW, Veldhoen, M, Vento-Asturias, S, Vieira, P, Voehringer, D, Volk, H-D, von Borstel, A, von Volkmann, K, Waisman, A, Walker, RV, Wallace, PK, Wang, SA, Wang, XM, Ward, MD, Ward-Hartstonge, KA, Warnatz, K, Warnes, G, Warth, S, Waskow, C, Watson, JV, Watzl, C, Wegener, L, Weisenburger, T, Wiedemann, A, Wienands, J, Wilharm, A, Wilkinson, RJ, Willimsky, G, Wing, JB, Winkelmann, R, Winkler, TH, Wirz, OF, Wong, A, Wurst, P, Yang, JHM, Yang, J, Yazdanbakhsh, M, Yu, L, Yue, A, Zhang, H, Zhao, Y, Ziegler, SM, Zielinski, C, Zimmermann, J, Zychlinsky, A, Cossarizza, A, Chang, H-D, Radbruch, A, Acs, A, Adam, D, Adam-Klages, S, Agace, WW, Aghaeepour, N, Akdis, M, Allez, M, Almeida, LN, Alvisi, G, Anderson, G, Andrae, I, Annunziato, F, Anselmo, A, Bacher, P, Baldari, CT, 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, DA, Bogdan, C, Borger, JG, Borsellino, G, Boulais, PE, Bradford, JA, Brenner, D, Brinkman, RR, Brooks, AES, Busch, DH, Buescher, M, Bushnell, TP, Calzetti, F, Cameron, G, Cammarata, I, Cao, X, Cardell, SL, Casola, S, Cassatella, MA, Cavani, A, Celada, A, Chatenoud, L, Chattopadhyay, PK, Chow, S, Christakou, E, Cicin-Sain, L, Clerici, M, Colombo, FS, Cook, L, Cooke, A, Cooper, AM, Corbett, AJ, Cosma, A, Cosmi, L, Coulie, PG, Cumano, A, Cvetkovic, L, Dang, VD, Dang-Heine, C, Davey, MS, Davies, D, De Biasi, S, Del Zotto, G, Dela Cruz, GV, Delacher, M, Della Bella, S, Dellabona, P, Deniz, G, Dessing, M, Di Santo, JP, Diefenbach, A, Dieli, F, Dolf, A, Doerner, T, Dress, RJ, Dudziak, D, Dustin, M, Dutertre, C-A, Ebner, F, Eckle, SBG, Edinger, M, Eede, P, Ehrhardt, GRA, Eich, M, Engel, P, Engelhardt, B, Erdei, A, Esser, C, Everts, B, Evrard, M, Falk, CS, Fehniger, TA, Felipo-Benavent, M, Ferry, H, Feuerer, M, Filby, A, Filkor, K, Fillatreau, S, Follo, M, Foerster, I, Foster, J, Foulds, GA, Frehse, B, Frenette, PS, Frischbutter, S, Fritzsche, W, Galbraith, DW, Gangaev, A, Garbi, N, Gaudilliere, B, Gazzinelli, RT, Geginat, J, Gerner, W, Gherardin, NA, Ghoreschi, K, Gibellini, L, Ginhoux, F, Goda, K, Godfrey, DI, Goettlinger, C, Gonzalez-Navajas, JM, Goodyear, CS, Gori, A, Grogan, JL, Grummitt, D, Gruetzkau, A, Haftmann, C, Hahn, J, Hammad, H, Haemmerling, G, Hansmann, L, Hansson, G, Harpur, CM, Hartmann, S, Hauser, A, Hauser, AE, Haviland, DL, Hedley, D, Hernandez, DC, Herrera, G, Herrmann, M, Hess, C, Hoefer, T, Hoffmann, P, Hogquist, K, Holland, T, Hollt, T, Holmdahl, R, Hombrink, P, Houston, JP, Hoyer, BF, Huang, B, Huang, F-P, Huber, JE, Huehn, J, Hundemer, M, Hunter, CA, Hwang, WYK, Iannone, A, Ingelfinger, F, Ivison, SM, Jaeck, H-M, Jani, PK, Javega, B, Jonjic, S, Kaiser, T, Kalina, T, Kamradt, T, Kaufmann, SHE, Keller, B, Ketelaars, SLC, Khalilnezhad, A, Khan, S, Kisielow, J, Klenerman, P, Knopf, J, Koay, H-F, Kobow, K, Kolls, JK, Kong, WT, Kopf, M, Korn, T, Kriegsmann, K, Kristyanto, H, Kroneis, T, Krueger, A, Kuehne, 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, MD, Leung, LYT, Levings, MK, Lino, AC, Liotta, F, Litwin, V, Liu, Y, Ljunggren, H-G, Lohoff, M, Lombardi, G, Lopez, L, Lopez-Botet, M, Lovett-Racke, AE, Lubberts, E, Luche, H, Ludewig, B, Lugli, E, Lunemann, S, Maecker, HT, Maggi, L, Maguire, O, Mair, F, Mair, KH, Mantovani, A, Manz, RA, Marshall, AJ, Martinez-Romero, A, Martrus, G, Marventano, I, Maslinski, W, Matarese, G, Mattioli, AV, Maueroder, C, Mazzoni, A, McCluskey, J, McGrath, M, McGuire, HM, McInnes, IB, Mei, HE, Melchers, F, Melzer, S, Mielenz, D, Miller, SD, Mills, KHG, Minderman, H, Mjosberg, J, Moore, J, Moran, B, Moretta, L, Mosmann, TR, Mueller, S, Multhoff, G, Munoz, LE, Munz, C, Nakayama, T, Nasi, M, Neumann, K, Ng, LG, 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, WF, Piconese, S, Pinti, M, Pockley, AG, Podolska, MJ, Poon, Z, Pracht, K, Prinz, I, Pucillo, CEM, Quataert, SA, Quatrini, L, Quinn, KM, Radbruch, H, Radstake, TRDJ, Rahmig, S, Rahn, H-P, Rajwa, B, Ravichandran, G, Raz, Y, Rebhahn, JA, Recktenwald, D, Reimer, D, Reis e Sousa, C, Remmerswaal, EBM, Richter, L, Rico, LG, Riddell, A, Rieger, AM, Robinson, JP, Romagnani, C, Rubartelli, A, Ruland, J, Saalmueller, A, Saeys, Y, Saito, T, Sakaguchi, S, Sala-de-Oyanguren, F, Samstag, Y, Sanderson, S, Sandrock, I, Santoni, A, Sanz, RB, Saresella, M, Sautes-Fridman, C, Sawitzki, B, Schadt, L, Scheffold, A, Scherer, HU, Schiemann, M, Schildberg, FA, Schimisky, E, Schlitzer, A, Schlosser, J, Schmid, S, Schmitt, S, Schober, K, Schraivogel, D, Schuh, W, Schueler, T, Schulte, R, Schulz, AR, Schulz, SR, Scotta, C, Scott-Algara, D, Sester, DP, Shankey, TV, Silva-Santos, B, Simon, AK, Sitnik, KM, Sozzani, S, Speiser, DE, Spidlen, J, Stahlberg, A, Stall, AM, 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, TIM, 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, RAW, Veldhoen, M, Vento-Asturias, S, Vieira, P, Voehringer, D, Volk, H-D, von Borstel, A, von Volkmann, K, Waisman, A, Walker, RV, Wallace, PK, Wang, SA, Wang, XM, Ward, MD, Ward-Hartstonge, KA, Warnatz, K, Warnes, G, Warth, S, Waskow, C, Watson, JV, Watzl, C, Wegener, L, Weisenburger, T, Wiedemann, A, Wienands, J, Wilharm, A, Wilkinson, RJ, Willimsky, G, Wing, JB, Winkelmann, R, Winkler, TH, Wirz, OF, Wong, A, Wurst, P, Yang, JHM, Yang, J, Yazdanbakhsh, M, Yu, L, Yue, A, Zhang, H, Zhao, Y, Ziegler, SM, Zielinski, C, Zimmermann, J, and Zychlinsky, A

Abstract

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.

Published
2019

27. HIF1A and NFAT5 coordinate Na+-boosted antibacterial defense via enhanced autophagy and autolysosomal targeting

Author

Neubert, P, Weichselbaum, A, Reitinger, C, Schatz, V, Schroeder, A, Ferdinand, JR, Simon, M, Baer, A-L, Brochhausen, C, Gerlach, RG, Tomiuk, S, Hammer, K, Wagner, S, van Zandbergen, G, Binger, KJ, Mueller, DN, Kitada, K, Clatworthy, MR, Kurts, C, Titze, J, Abdullah, Z, Jantsch, J, Neubert, P, Weichselbaum, A, Reitinger, C, Schatz, V, Schroeder, A, Ferdinand, JR, Simon, M, Baer, A-L, Brochhausen, C, Gerlach, RG, Tomiuk, S, Hammer, K, Wagner, S, van Zandbergen, G, Binger, KJ, Mueller, DN, Kitada, K, Clatworthy, MR, Kurts, C, Titze, J, Abdullah, Z, and Jantsch, J

Abstract

Infection and inflammation are able to induce diet-independent Na+-accumulation without commensurate water retention in afflicted tissues, which favors the pro-inflammatory activation of mouse macrophages and augments their antibacterial and antiparasitic activity. While Na+-boosted host defense against the protozoan parasite Leishmania major is mediated by increased expression of the leishmanicidal NOS2 (nitric oxide synthase 2, inducible), the molecular mechanisms underpinning this enhanced antibacterial defense of mouse macrophages with high Na+ (HS) exposure are unknown. Here, we provide evidence that HS-increased antibacterial activity against E. coli was neither dependent on NOS2 nor on the phagocyte oxidase. In contrast, HS-augmented antibacterial defense hinged on HIF1A (hypoxia inducible factor 1, alpha subunit)-dependent increased autophagy, and NFAT5 (nuclear factor of activated T cells 5)-dependent targeting of intracellular E. coli to acidic autolysosomal compartments. Overall, these findings suggest that the autolysosomal compartment is a novel target of Na+-modulated cell autonomous innate immunity. Abbreviations: ACT: actins; AKT: AKT serine/threonine kinase 1; ATG2A: autophagy related 2A; ATG4C: autophagy related 4C, cysteine peptidase; ATG7: autophagy related 7; ATG12: autophagy related 12; BECN1: beclin 1; BMDM: bone marrow-derived macrophages; BNIP3: BCL2/adenovirus E1B interacting protein 3; CFU: colony forming units; CM-H2DCFDA: 5-(and-6)-chloromethyl-2',7'-dichlorodihydrofluorescein diacetate, acetyl ester; CTSB: cathepsin B; CYBB: cytochrome b-245 beta chain; DAPI: 4,6-diamidino-2-phenylindole; DMOG: dimethyloxallyl glycine; DPI: diphenyleneiodonium chloride; E. coli: Escherichia coli; FDR: false discovery rate; GFP: green fluorescent protein; GSEA: gene set enrichment analysis; GO: gene ontology; HIF1A: hypoxia inducible factor 1, alpha subunit; HUGO: human genome organization; HS: high salt (+ 40 mM of NaCl to standard cell culture conditio

Published
2019

30. Perforin inhibition protects from lethal endothelial damage during fulminant viral hepatitis

Author

Welz, M, Eickhoff, S, Abdullah, Z, Trebicka, J, Gartlan, KH, Spicer, JA, Demetris, AJ, Akhlaghi, H, Anton, M, Manske, K, Zehn, D, Nieswandt, B, Kurts, C, Trapani, JA, Knolle, P, Wohlleber, D, Kastenmueller, W, Welz, M, Eickhoff, S, Abdullah, Z, Trebicka, J, Gartlan, KH, Spicer, JA, Demetris, AJ, Akhlaghi, H, Anton, M, Manske, K, Zehn, D, Nieswandt, B, Kurts, C, Trapani, JA, Knolle, P, Wohlleber, D, and Kastenmueller, W

Abstract

CD8 T cells protect the liver against viral infection, but can also cause severe liver damage that may even lead to organ failure. Given the lack of mechanistic insights and specific treatment options in patients with acute fulminant hepatitis, we develop a mouse model reflecting a severe acute virus-induced CD8 T cell-mediated hepatitis. Here we show that antigen-specific CD8 T cells induce liver damage in a perforin-dependent manner, yet liver failure is not caused by effector responses targeting virus-infected hepatocytes alone. Additionally, CD8 T cell mediated elimination of cross-presenting liver sinusoidal endothelial cells causes endothelial damage that leads to a dramatically impaired sinusoidal perfusion and indirectly to hepatocyte death. With the identification of perforin-mediated killing as a critical pathophysiologic mechanism of liver failure and the protective function of a new class of perforin inhibitor, our study opens new potential therapeutic angles for fulminant viral hepatitis.

Published
2018

32. Guidelines for the use of flow cytometry and cell sorting in immunological studies

Author

Cossarizza, A. (Andrea), Chang, H.-D. (Hyun-Dong), Radbruch, A. (Andreas), Andrä, I. (Immanuel), Annunziato, F. (Francesco), Bacher, P. (Petra), Barnaba, V. (Vincenzo), Battistini, L. (Luca), Bauer, W.M. (Wolfgang M.), Baumgart, S. (Sabine), Becher, B. (Burkhard), Beisker, W. (Wolfgang), Berek, C. (Claudia), Blanco, A. (Alfonso), Borsellino, G. (Giovanna), Boulais, P.E. (Philip E.), Brinkman, R.R. (Ryan R.), Büscher, M. (Martin), Busch, D.H. (Dirk), Bushnell, T.P. (Timothy P.), Cao, X. (Xuetao), Cavani, A. (Andrea), Chattopadhyay, P.K. (Pratip K.), Cheng, Q. (Qingyu), Chow, S. (Sue), Clerici, M. (Mario), Cooke, A. (Anne), Cosma, A. (Antonio), Cosmi, L. (Lorenzo), Cumano, A. (Ana), Dang, V.D. (Van Duc), Davies, D. (Derek), De Biasi, S. (Sara), Del Zotto, G. (Genny), Della Bella, S. (Silvia), Dellabona, P. (Paolo), Deniz, G. (Gunnur), Dessing, M. (Mark), Diefenbach, A. (Andreas), Santo, J.P. (James) di, Dieli, F. (Francesco), Dolf, A. (Andreas), Donnenberg, V.S. (Vera S.), Dörner, A. (Andrea), Ehrhardt, G.R.A. (Götz R. A.), Endl, E. (Elmar), Engel, P. (Pablo), Engelhardt, B. (Britta), Esser, C. (Charlotte), Everts, B. (Bart), Falk, C.S. (Christine S.), Fehniger, T.A. (Todd A.), Filby, A. (Andrew), Fillatreau, S. (Simon), Follo, M. (Marie), Förster, I. (Irmgard), Foster, J. (John), Foulds, G.A. (Gemma A.), Frenette, P.S. (Paul S.), Galbraith, D. (David), Garbi, N. (Natalio), García-Godoy, M.D. (Maria Dolores), Ghoreschi, K. (Kamran), Gibellini, L. (Lara), Goettlinger, C. (Christoph), Goodyear, C.S. (Carl), Gori, A. (Andrea), Grogan, J.L. (Jane), Gross, M. (Mor), Grützkau, A. (Andreas), Grummitt, D. (Daryl), Hahn, J. (Jonas), Hammer, Q. (Quirin), Hauser, A.E. (Anja E.), Haviland, D.L. (David L.), Hedley, D. (David), Herrera, G. (Guadalupe), Herrmann, M. (Martin), Hiepe, F. (Falk), Holland, T. (Tristan), Hombrink, P. (Pleun), Houston, J.P. (Jessica P.), Hoyer, B.F. (Bimba F.), Huang, B. (Bo), Hunter, C.A. (Christopher A.), Iannone, A. (Anna), Jäck, H.-M. (Hans-Martin), Jávega, B. (Beatriz), Jonjic, S. (Stipan), Juelke, K. (Kerstin), Jung, S. (Steffen), Kaiser, T. (Toralf), Kalina, T. (Tomas), Keller, B. (Baerbel), Khan, S. (Srijit), Kienhöfer, D. (Deborah), Kroneis, T. (Thomas), Kunkel, D. (Désirée), Kurts, C. (Christian), Kvistborg, P. (Pia), Lannigan, J. (Joanne), Lantz, O. (Olivier), Larbi, A. (Anis), LeibundGut-Landmann, S. (Salome), Leipold, M.D. (Michael D.), Levings, M.K., Litwin, V. (Virginia), Liu, Y. (Yanling), Lohoff, M. (Michael), Lombardi, G. (Giovanna), Lopez, L. (Lilly), Lovett-Racke, A. (Amy), Lubberts, E.W. (Erik), Ludewig, B. (Burkhard), Lugli, E. (Enrico), Maecker, H.T. (Holden T.), Martrus, G. (Glòria), Matarese, G. (Giuseppe), Maueröder, C. (Christian), McGrath, M. (Mairi), McInnes, I.B. (Iain), Mei, H.E. (Henrik E.), Melchers, F. (Fritz), Melzer, S. (Susanne), Mielenz, D. (Dirk), Mills, K. (Kingston), Mjösberg, J.M. (Jenny), Moore, J. (Jonni), Moran, B. (Barry), Moretta, A. (Alessandro), Moretta, L. (Lorenzo), Mosmann, T.R. (Tim R.), Müller, S. (Susann), Müller, W. (Werner), Münz, C. (Christian), Multhoff, G. (Gabriele), Munoz, L.E. (Luis Enrique), Murphy, K.M. (Kenneth M.), Nakayama, T. (Toshinori), Nasi, M. (Milena), Neudörfl, C. (Christine), Nolan, J. (John), Nourshargh, S. (Sussan), O'Connor, J.-E. (José-Enrique), Ouyang, W. (Wenjun), Oxenius, A. (Annette), Palankar, R. (Raghav), Panse, I. (Isabel), Peterson, P. (Pärt), Peth, C. (Christian), Petriz, J. (Jordi), Philips, D. (Daisy), Pickl, W. (Winfried), Piconese, S. (Silvia), Pinti, M. (Marcello), Pockley, A.G. (A. Graham), Podolska, M.J. (Malgorzata Justyna), Pucillo, C. (Carlo), Quataert, S.A. (Sally A.), Radstake, T.R.D.J. (Timothy R. D. J.), Rajwa, B. (Bartek), Rebhahn, J.A. (Jonathan A.), Recktenwald, D. (Diether), Remmerswaal, D. (Daniëlle), Rezvani, K. (Katy), Rico, L.G. (Laura G.), Robinson, J.P. (J. Paul), Romagnani, C. (Chiara), Rubartelli, A. (Anna), Ruland, J. (Jürgen), Sakaguchi, S. (Shimon), Sala-de-Oyanguren, F. (Francisco), Samstag, Y. (Yvonne), Sanderson, S. (Sharon), Sawitzki, B. (Birgit), Scheffold, A. (Alexander), Schiemann, M. (Matthias), Schildberg, F. (Frank), Schimisky, E. (Esther), Schmid, S.A. (Stephan A), Schmitt, S. (Steffen), Schober, K. (Kilian), Schüler, T. (Thomas), Schulz, A.R. (Axel Ronald), Schumacher, T.N. (Ton), Scotta, C. (Cristiano), Shankey, T.V. (T. Vincent), Shemer, A. (Anat), Simon, A.-K. (Anna-Katharina), Spidlen, J. (Josef), Stall, A.M. (Alan M.), Stark, R. (Regina), Stehle, C. (Christina), Stein, M. (Merle), Steinmetz, T. (Tobit), Stockinger, H. (Hannes), Takahama, Y. (Yousuke), Tarnok, A. (Attila), Tian, Z. (ZhiGang), Toldi, G. (Gergely), Tornack, J. (Julia), Traggiai, E. (Elisabetta), Trotter, J. (Joe), Ulrich, H. (Henning), van der Braber, M. (Marlous), Van Lier, R.A.W. (Rene A. W.), Veldhoen, M. (Marcello), Vento-Asturias, S. (Salvador), Vieira, P. (Paulo), Voehringer, D. (David), Volk, H.D. (Hans), von Volkmann, K. (Konrad), Waisman, A. (Ari), Walker, R. (Rachael), Ward, M.D. (Michael D.), Warnatz, K. (Klaus), Warth, S. (Sarah), Watson, J.V. (James V.), Watzl, C. (Carsten), Wegener, L. (Leonie), Wiedemann, A. (Annika), Wienands, J. (Jürgen), Willimsky, G. (Gerald), Wing, J. (James), Wurst, P. (Peter), Yu, L. (Liping), Yue, A. (Alice), Zhang, Q. (Qianjun), Zhao, Y. (Yi), Ziegler, S. (Susanne), Zimmermann, J. (Jakob), Cossarizza, A. (Andrea), Chang, H.-D. (Hyun-Dong), Radbruch, A. (Andreas), Andrä, I. (Immanuel), Annunziato, F. (Francesco), Bacher, P. (Petra), Barnaba, V. (Vincenzo), Battistini, L. (Luca), Bauer, W.M. (Wolfgang M.), Baumgart, S. (Sabine), Becher, B. (Burkhard), Beisker, W. (Wolfgang), Berek, C. (Claudia), Blanco, A. (Alfonso), Borsellino, G. (Giovanna), Boulais, P.E. (Philip E.), Brinkman, R.R. (Ryan R.), Büscher, M. (Martin), Busch, D.H. (Dirk), Bushnell, T.P. (Timothy P.), Cao, X. (Xuetao), Cavani, A. (Andrea), Chattopadhyay, P.K. (Pratip K.), Cheng, Q. (Qingyu), Chow, S. (Sue), Clerici, M. (Mario), Cooke, A. (Anne), Cosma, A. (Antonio), Cosmi, L. (Lorenzo), Cumano, A. (Ana), Dang, V.D. (Van Duc), Davies, D. (Derek), De Biasi, S. (Sara), Del Zotto, G. (Genny), Della Bella, S. (Silvia), Dellabona, P. (Paolo), Deniz, G. (Gunnur), Dessing, M. (Mark), Diefenbach, A. (Andreas), Santo, J.P. (James) di, Dieli, F. (Francesco), Dolf, A. (Andreas), Donnenberg, V.S. (Vera S.), Dörner, A. (Andrea), Ehrhardt, G.R.A. (Götz R. A.), Endl, E. (Elmar), Engel, P. (Pablo), Engelhardt, B. (Britta), Esser, C. (Charlotte), Everts, B. (Bart), Falk, C.S. (Christine S.), Fehniger, T.A. (Todd A.), Filby, A. (Andrew), Fillatreau, S. (Simon), Follo, M. (Marie), Förster, I. (Irmgard), Foster, J. (John), Foulds, G.A. (Gemma A.), Frenette, P.S. (Paul S.), Galbraith, D. (David), Garbi, N. (Natalio), García-Godoy, M.D. (Maria Dolores), Ghoreschi, K. (Kamran), Gibellini, L. (Lara), Goettlinger, C. (Christoph), Goodyear, C.S. (Carl), Gori, A. (Andrea), Grogan, J.L. (Jane), Gross, M. (Mor), Grützkau, A. (Andreas), Grummitt, D. (Daryl), Hahn, J. (Jonas), Hammer, Q. (Quirin), Hauser, A.E. (Anja E.), Haviland, D.L. (David L.), Hedley, D. (David), Herrera, G. (Guadalupe), Herrmann, M. (Martin), Hiepe, F. (Falk), Holland, T. (Tristan), Hombrink, P. (Pleun), Houston, J.P. (Jessica P.), Hoyer, B.F. (Bimba F.), Huang, B. (Bo), Hunter, C.A. (Christopher A.), Iannone, A. (Anna), Jäck, H.-M. (Hans-Martin), Jávega, B. (Beatriz), Jonjic, S. (Stipan), Juelke, K. (Kerstin), Jung, S. (Steffen), Kaiser, T. (Toralf), Kalina, T. (Tomas), Keller, B. (Baerbel), Khan, S. (Srijit), Kienhöfer, D. (Deborah), Kroneis, T. (Thomas), Kunkel, D. (Désirée), Kurts, C. (Christian), Kvistborg, P. (Pia), Lannigan, J. (Joanne), Lantz, O. (Olivier), Larbi, A. (Anis), LeibundGut-Landmann, S. (Salome), Leipold, M.D. (Michael D.), Levings, M.K., Litwin, V. (Virginia), Liu, Y. (Yanling), Lohoff, M. (Michael), Lombardi, G. (Giovanna), Lopez, L. (Lilly), Lovett-Racke, A. (Amy), Lubberts, E.W. (Erik), Ludewig, B. (Burkhard), Lugli, E. (Enrico), Maecker, H.T. (Holden T.), Martrus, G. (Glòria), Matarese, G. (Giuseppe), Maueröder, C. (Christian), McGrath, M. (Mairi), McInnes, I.B. (Iain), Mei, H.E. (Henrik E.), Melchers, F. (Fritz), Melzer, S. (Susanne), Mielenz, D. (Dirk), Mills, K. (Kingston), Mjösberg, J.M. (Jenny), Moore, J. (Jonni), Moran, B. (Barry), Moretta, A. (Alessandro), Moretta, L. (Lorenzo), Mosmann, T.R. (Tim R.), Müller, S. (Susann), Müller, W. (Werner), Münz, C. (Christian), Multhoff, G. (Gabriele), Munoz, L.E. (Luis Enrique), Murphy, K.M. (Kenneth M.), Nakayama, T. (Toshinori), Nasi, M. (Milena), Neudörfl, C. (Christine), Nolan, J. (John), Nourshargh, S. (Sussan), O'Connor, J.-E. (José-Enrique), Ouyang, W. (Wenjun), Oxenius, A. (Annette), Palankar, R. (Raghav), Panse, I. (Isabel), Peterson, P. (Pärt), Peth, C. (Christian), Petriz, J. (Jordi), Philips, D. (Daisy), Pickl, W. (Winfried), Piconese, S. (Silvia), Pinti, M. (Marcello), Pockley, A.G. (A. Graham), Podolska, M.J. (Malgorzata Justyna), Pucillo, C. (Carlo), Quataert, S.A. (Sally A.), Radstake, T.R.D.J. (Timothy R. D. J.), Rajwa, B. (Bartek), Rebhahn, J.A. (Jonathan A.), Recktenwald, D. (Diether), Remmerswaal, D. (Daniëlle), Rezvani, K. (Katy), Rico, L.G. (Laura G.), Robinson, J.P. (J. Paul), Romagnani, C. (Chiara), Rubartelli, A. (Anna), Ruland, J. (Jürgen), Sakaguchi, S. (Shimon), Sala-de-Oyanguren, F. (Francisco), Samstag, Y. (Yvonne), Sanderson, S. (Sharon), Sawitzki, B. (Birgit), Scheffold, A. (Alexander), Schiemann, M. (Matthias), Schildberg, F. (Frank), Schimisky, E. (Esther), Schmid, S.A. (Stephan A), Schmitt, S. (Steffen), Schober, K. (Kilian), Schüler, T. (Thomas), Schulz, A.R. (Axel Ronald), Schumacher, T.N. (Ton), Scotta, C. (Cristiano), Shankey, T.V. (T. Vincent), Shemer, A. (Anat), Simon, A.-K. (Anna-Katharina), Spidlen, J. (Josef), Stall, A.M. (Alan M.), Stark, R. (Regina), Stehle, C. (Christina), Stein, M. (Merle), Steinmetz, T. (Tobit), Stockinger, H. (Hannes), Takahama, Y. (Yousuke), Tarnok, A. (Attila), Tian, Z. (ZhiGang), Toldi, G. (Gergely), Tornack, J. (Julia), Traggiai, E. (Elisabetta), Trotter, J. (Joe), Ulrich, H. (Henning), van der Braber, M. (Marlous), Van Lier, R.A.W. (Rene A. W.), Veldhoen, M. (Marcello), Vento-Asturias, S. (Salvador), Vieira, P. (Paulo), Voehringer, D. (David), Volk, H.D. (Hans), von Volkmann, K. (Konrad), Waisman, A. (Ari), Walker, R. (Rachael), Ward, M.D. (Michael D.), Warnatz, K. (Klaus), Warth, S. (Sarah), Watson, J.V. (James V.), Watzl, C. (Carsten), Wegener, L. (Leonie), Wiedemann, A. (Annika), Wienands, J. (Jürgen), Willimsky, G. (Gerald), Wing, J. (James), Wurst, P. (Peter), Yu, L. (Liping), Yue, A. (Alice), Zhang, Q. (Qianjun), Zhao, Y. (Yi), Ziegler, S. (Susanne), and Zimmermann, J. (Jakob)

Published
2017
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34. CCR2-abhängige Makrophagen sind die Hauptproduzenten von VEGF im Mausmodell der laserinduzierten choroidalen Neovaskularisation

Author

Alex, Anne F., Urzynicok, T.A., Engel, D., Kurts, C., and Eter, N.

Subjects
genetic structures, ddc: 610, sense organs, 610 Medical sciences, Medicine, eye diseases
Abstract

Hintergrund: In dieser Studie wurden die mononukleären Phagozyten auf ihre Rolle bei der Produktion von vascular endothelial growth factor (VEGF) im laserinduzierten Modell der choroidalen Neovaskularisation (CNV) untersucht. Die Auswirkungen auf die CNV in einem CCR2-loss-of-function-Modell wurden[for full text, please go to the a.m. URL], 175. Versammlung des Vereins Rheinisch-Westfälischer Augenärzte

Published
2013

36. Die Rolle VEGF-exprimierender mononukleärer Phagozyten im murinen Modell der Laser-induzierten choroidalen Neovaskularisation

Author

Urzynicok, TA, Alex, AF, Engel, D, Kurts, C, and Eter, N

Subjects
ddc: 610, 610 Medical sciences, Medicine
Abstract

Hintergrund: Ziel dieser Studie war, im murinen CNV-Modell zu beurteilen, ob infiltrierende oder residente Phagozyten eine Quelle für VEGF sind, und somit zu einer Neovaskularisation beitragen können. Methoden: Zur Visualisierung mononukleärer Phagozyten wurden CX3CR1-Reportermäuse[for full text, please go to the a.m. URL], 25. Jahrestagung der Retinologischen Gesellschaft

Published
2012
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40. Liver inflammation abrogates T cell mediated tolerance against particulate antigens induced by liver Kupffer cells

Author

Heymann, F, primary, Peusquens, J, additional, Ludwig-Portugall, I, additional, Kohlhepp, M, additional, Ergen, C, additional, Niemietz, P, additional, Martin, C, additional, van Roojen, N, additional, Ochando, J, additional, Randolph, G, additional, Luedde, T, additional, Ginhoux, F, additional, Kurts, C, additional, Trautwein, C, additional, and Tacke, F, additional

Published
2015
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47. Renal dendritic cells adopt a pro-inflammatory phenotype in obstructive uropathy to activate T cells but do not directly contribute to fibrosis.

Author

Kitching A.R., Ooi J.D., Coates P.T., Hickey M.J., Holdsworth S.R., Kurts C., Engel D.R., Snelgrove S.L., Kausman J.Y., Lo C., Kitching A.R., Ooi J.D., Coates P.T., Hickey M.J., Holdsworth S.R., Kurts C., Engel D.R., Snelgrove S.L., Kausman J.Y., and Lo C.

Abstract

Unilateral ureteral obstruction (UUO) is a well-characterized murine model of renal inflammation leading to fibrosis. Renal dendritic cells (DCs) constitute a significant portion of kidney leukocytes and may participate in local inflammation and have critical roles in antigen presentation. The heterogeneity in renal DC populations and surface marker overlap with monocytes/macrophages has made studying renal DCs difficult. These studies used CD11c-promoter driven reporter/depletion mice to study DCs in vivo. Studying early local inflammatory events (day 3 of UUO), in vivo multiphoton imaging of the intact kidney of CD11c reporter mice revealed more dendrite extensions and increased activity of renal DCs in real time. Phenotypic analysis suggested resident DC maturation in obstructed kidneys with increased CD11b and less F4/80 expressed. CD11bhi Gr-1+ inflammatory DCs were also present in obstructed kidneys. T-cell receptor transgenic mice revealed enhanced antigen-presenting capacity of renal DCs after UUO, with increased antigen-specific T-cell proliferation in vivo and ex vivo. However, conditional DC ablation at days 0, 2, or 4 did not attenuate fibrosis or apoptosis 7 days after UUO, and depletion at 7 days did not alter outcomes at day 14. Therefore, after UUO, renal DCs exhibit inflammatory morphological and functional characteristics and are more effective antigen-presenting cells, but they do not directly contribute to tubulointerstitial damage and fibrosis. © 2012 American Society for Investigative Pathology.

Published
2012

48. Endogenous foxp3+ T-regulatory cells suppress anti-glomerular basement membrane nephritis.

Author

Hickey M.J., Holdsworth S.R., O'Sullivan K.M., Kurts C., Kitching A.R., Ooi J.D., Snelgrove S.L., Engel D.R., Hochheiser K., Ludwig-Portugall I., Nozaki Y., Hickey M.J., Holdsworth S.R., O'Sullivan K.M., Kurts C., Kitching A.R., Ooi J.D., Snelgrove S.L., Engel D.R., Hochheiser K., Ludwig-Portugall I., and Nozaki Y.

Abstract

Foxp3+ T-regulatory cells (Tregs) may suppress pathogenic inflammation; however, although transferred Tregs lessen glomerulonephritis in mice, the role of endogenous foxp3 cells is not known. To study this, we characterized endogenous foxp3 cells in accelerated anti-glomerular basement membrane (GBM) nephritis by using foxp3 GFP reporter mice to track their responses in early and established disease. Further, diphtheria toxin was used to ablate foxp3 Tregs in foxp3 DTR mice after establishing an immune response. In this model, mice were immunized with sheep globulin in adjuvant, and sheep anti-mouse GBM globulin was injected after 4 days to initiate progressive histological and functional injury. Intrarenal leukocytic infiltrates were increased by day 3 but intrarenal foxp3 Tregs, present in interstitial and periglomerular areas, were only increased at day 7. Ablation of foxp3 Tregs after injection of anti-GBM globulin increased renal injury and systemic T-cell responses, including increased interferon-gamma and interleukin-17A (IL-17A) production, but no change in antibody titers. Compared with foxp3 Tregs isolated from naive mice, those from immunized mice produced more IL-10 and more effectively regulated CD4 foxp3 responder T cells. Thus, endogenous foxp3 Tregs infiltrate the kidney in glomerulonephritis, and deleting foxp3 cells after the induction of immune responses upregulated T-cell reactions and enhanced disease. Hence, endogenous foxp3 cells have increased suppressive capacity after immune stimuli. © 2011 International Society of Nephrology.

Published
2012

49. Major histocompatibility complex class II expression by intrinsic renal cells is required for crescentic glomerulonephritis.

Author

Kurts C., Tipping P.G., Li S., Kontgen F., Holdsworth S.R., Kurts C., Tipping P.G., Li S., Kontgen F., and Holdsworth S.R.

Abstract

The requirement for major histocompatibility complex class II (MHC II) to initiate immune renal injury was studied in a murine model of CD4+ T cell-dependent crescentic glomerulonephritis (GN). C57BL/6 (MHC II(+/+)) mice developed crescentic GN with glomerular CD4+ T cell infiltration and renal injury, in response to a nephritogenic antigen (sheep globulin) planted on their glomerular basement membrane. MHC II-deficient C57BL/6 mice (MHC II(- /-)) did not develop crescentic GN, CD4+ T cell infiltration, or injury, indicating that this form of immune glomerular injury is MHC II dependent. The requirement for MHC II expression by intrinsic renal cells was studied in chimeric mice, which expressed MHC II on bone marrow-derived cells and in the thymus, but not in the kidneys. These chimeric mice had normal T and B cell populations and MHC II expression in their spleens and lymph nodes and developed an immune response to systemically and cutaneously administered sheep globulin. However, they did not develop crescentic GN, CD4+ T cell infiltration, or renal injury in response to the sheep globulin planted in their glomeruli. These studies demonstrate that interaction of CD4+ T cells with intrinsic renal cells expressing MHC II is required for development of cell-mediated immune renal injury.

Published
2012

50. Subtotal ablation of parietal epithelial cells induces crescent formation.

Author

Sicking, E.M., Fuss, A., Uhlig, S., Jirak, P., Dijkman, H., Wetzels, J., Engel, D.R., Urzynicok, T., Heidenreich, S., Kriz, W., Kurts, C., Ostendorf, T., Floege, J., Smeets, B., Moeller, M.J., Sicking, E.M., Fuss, A., Uhlig, S., Jirak, P., Dijkman, H., Wetzels, J., Engel, D.R., Urzynicok, T., Heidenreich, S., Kriz, W., Kurts, C., Ostendorf, T., Floege, J., Smeets, B., and Moeller, M.J.

Abstract

01 april 2012, Item does not contain fulltext, Parietal epithelial cells (PECs) of the renal glomerulus contribute to the formation of both cellular crescents in rapidly progressive GN and sclerotic lesions in FSGS. Subtotal transgenic ablation of podocytes induces FSGS but the effect of specific ablation of PECs is unknown. Here, we established an inducible transgenic mouse to allow subtotal ablation of PECs. Proteinuria developed during doxycycline-induced cellular ablation but fully reversed 26 days after termination of doxycycline administration. The ablation of PECs was focal, with only 30% of glomeruli exhibiting histologic changes; however, the number of PECs was reduced up to 90% within affected glomeruli. Ultrastructural analysis revealed disruption of PEC plasma membranes with cytoplasm shedding into Bowman's space. Podocytes showed focal foot process effacement, which was the most likely cause for transient proteinuria. After >9 days of cellular ablation, the remaining PECs formed cellular extensions to cover the denuded Bowman's capsule and expressed the activation marker CD44 de novo. The induced proliferation of PECs persisted throughout the observation period, resulting in the formation of typical cellular crescents with periglomerular infiltrate, albeit without accompanying proteinuria. In summary, subtotal ablation of PECs leads the remaining PECs to react with cellular activation and proliferation, which ultimately forms cellular crescents.

Published
2012

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