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  • Systems immunology Vaeth_WueSi
Systemimmunologie Würzburg

Metabolism and Immune Cell Signaling (Vaeth Lab)

Die immunologische Toleranz ist das Gleichgewicht zwischen der Immunität gegen Infektionen und der Autoimmunität, deren Dysregulation zu schweren immunologischen Erkrankungen führen kann. Unser Labor untersucht die molekulare Regulierung von (patho-) physiologischen Immunantworten mit besonderem Schwerpunkt auf der metabolischen Programmierung von Lymphozyten. In den letzten zehn Jahren wurde deutlich, dass der "Immunstoffwechsel" nicht nur chemische Energie und Bausteine für die klonale Expansion und die Effektorfunktion von Lymphozyten liefert, sondern auch die epigenetische Programmierung von Immunzellen steuert. Ein besseres Verständnis der metabolisch-epigenetischen Regelkreise in Immunzellen verspricht daher neue therapeutische Möglichkeiten zur Behandlung immunbedingter Krankheiten wie Infektionen, Krebs oder Autoimmunität.

Im Gegensatz zu den meisten anderen Geweben sind Immunzellen nicht sessil, sondern patrouillieren und bevölkern alle Organe des Körpers. Um mit den unterschiedlichen Stoffwechselbedingungen in den verschiedenen (nicht-lymphoiden) Geweben zurechtzukommen, sind Immunzellen mit einem umfangreichen Enzymrepertoire ausgestattet. Diese Vielseitigkeit der Leukozyten und die Vorstellung, dass der zelluläre Stoffwechsel untrennbar mit dem Ergebnis komplexer Immunreaktionen verbunden ist, haben den "Immunmetabolismus" als eigenständiges und interdisziplinäres Forschungsgebiet begründet. Eine Fülle von katabolischen und anaplerotischen Reaktionen ist direkt mit der Signaltransduktion, epigenetischen Veränderungen und der Kontrolle der Genexpression verbunden. Die Wechselbeziehung zwischen zellulärem Stoffwechsel, Signalübertragung und epigenetischer Prägung bildet somit ein intrazelluläres Netzwerk, das das Schicksal und die Funktion von Immunzellen steuert.

Wir untersuchen verschiedene Aspekte dieses Netzwerks im Immunsystem, indem wir funktionelle Studien in transgenen Tiermodellen mit (einzelligen) transkriptomischen, metabolomischen und epigenetischen Analysen kombinieren. Ein besseres Verständnis darüber, wie der Stoffwechsel die komplexen Funktionen des Immunsystems steuert, wird nicht nur neue therapeutische Konzepte zur Behandlung von Entzündungs- und Autoimmunkrankheiten liefern, sondern auch dazu beitragen, die den Leukozyten innewohnende Fähigkeit zur Bekämpfung von Krankheitserregern und Krebs zu nutzen.

We showed previously that cell cycle entry and clonal expansion of virus-specific T cells is controlled by calcium signaling and transcription factors of the nuclear factor of activated T cells (NFAT) family. NFAT controls the expression of nutrient transporters and metabolic enzymes to support cellular growth and proliferation of T cells. To meet their bioenergetic demand, effector T cells rewire their metabolic machinery to aerobic glycolysis to generate ATP and building blocks for the biosynthesis of macromolecules. By contrast, memory and regulatory T cells are less glycolytic and rely, instead, on oxidative phosphorylation (OXPHOS) and fatty acid oxidation (FAO). The goal of this project is to define how calcium and NFAT signaling contributes to the specific metabolic phenotypes of different immune cell subsets. Specifially, we pursue the following goals:

  • To delineate the shared and redundant functions of store-operated calcium entry (SOCE), calcineurin signaling and NFAT-mediated gene expression
  • To define the role of different NFAT family members and their isoforms during the metabolic reprogramming of lymphocytes
  • To investigate the reciprocal regulation of SOCE and NFAT signaling by intermediary metabolites

Glucose is the universal fuel for metabolic processes in all tissues of the body. Immune cells are no exception and utilize two main transporters to utilize glucose: GLUT1 and GLUT3. In this project we focus on the glucose transporter GLUT3, because of its high expression in effector, tissue-resident and regulatory T cells. Unlike the universal hexose transporter GLUT1, GLUT3 seems dispensable for energy production and clonal expansion of T cells, but is crucial for their pathogenicity in models of autoimmunity. Metabolomic, transcriptomic and epigenetic analyses linked GLUT3-dependent glucose utilization to mitochondrial metabolism and histone acetylation. We identified ATP-citrate lyase (ACLY), which catalyzes the release of cytosolic acetyl-CoA from mitochondrial citrate, as a druggable metabolic checkpoint downstream of GLUT3 to mitigate the pathogenicity of inflammatory T cells. Our work revealed a novel GLUT3-dependent metabolic-epigenetic circuit that controls the effector function of T cells but several important questions remain:

  • What are the molecular and functional differences between the two glucose transporters in leukocytes?
  • How is glucose metabolism is spatially organized, e.g., by directed metabolic channeling or subcellular compartmentalization?
  • Is glucose transport and metabolism regulated in a cell and tissue-dependent manner?
  • Can we exploit nutrient transporters to engineer metabolically optimized (CAR) T cells to treat malignancies and other immune-related pathologies?

Mitochondria play a pivotal role in cellular metabolism by producing chemical energy in the form of ATP. The respiratory chain complexes generate a proton gradient following oxidative phosphorylation (OXPHOS) and fatty acid oxidation (FAO) at the inner mitochondrial membrane that is utilized by the ATP synthase (complex V) to generate ATP from ADP and inorganic phosphate. In addition to the ‘textbook function‘ of the mitochondria, intermediates of the tricarboxylic acid (TCA) cycle control the fate and function of immune cells by regulating signaling pathways, cellular redox balance, apoptosis and metabolic-epigenetic rewiring through posttranslational DNA and histone modifications. Thus, mitochondrial metabolism plays an eminent role in the life (and death) of leukocytes. Our lab is specifically interested to untangle the importance of mitochondria as the cellular powerhouses (i.e. the production of ATP) and their non-energetic functions, such as regulating signal transduction and their role in epigenetic reprogramming. To address these questions, we generated a series of immune cell-specific research models to investigate the following mitochondrial functions:

  • Mitochondrial phosphate handling a s a prerequisite for ATP production
  • Cardiolipins and the composition of the inner mitochondrial membrane
  • The role of mitochondria as subcellular calcium buffers
  • Mitochondrial ROS and its importance as a secondary messenger in signal transduction
  • Mitochondrial insufficiency as an accelerator of immunosenescence and aging

Using preclinical models of autoimmunity, viral infection, and myocardial infarction, we also explore the potential of mitochondrial metabolism as a novel target for the treatment of inflammatory diseases.

PUBLICATIONS

Complete publication list on Pubmed:  https://www.ncbi.nlm.nih.gov/myncbi/1pyNMxsZw4B58/bibliography/public/

 

Selected Articles

Mitochondrial dysfunction promotes the transition of precursor to terminally exhausted T cells through HIF-1α-mediated glycolytic reprogramming. Wu, H., Zhao, X., Hochrein SM, Eckstein, M., Gubert GF, Knöpper, K., Mansilla, AM, Doucet-Ladevèze, R., Schmitz, W., Ghesquière, Theurich, S., Dudek, J., Gasteiger, G., Zernecke, A., Kobold, S., Kastenmüller, W., and Vaeth, M. (2023). Nat Commun 14, 6858. 10.1038/s41467-023-42634-3

The glucose transporter GLUT3 controls T helper 17 cell responses through glycolytic-epigenetic reprogramming. Hochrein, SM, Wu, H., Eckstein, M., Arrigoni, L., Herman, JS, Schumacher, F., Gerecke, C., Rosenfeldt, M., Grün, D., Kleuser, B., Gasteiger, G., Kastenmüller, W., Ghesquiere, B., Van den Bossche, J., Abel, ED and Vaeth, M. (2022). Cell Metab 34, 516-532 e511. 10.1016/j.cmet.2022.02.015.

Genetic ablation of the mitochondrial calcium uniporter (MCU) does not impair T cell-mediated immunity in vivo. Wu, H., Brand, B., Eckstein, M., Hochrein, SM, Shumanska, M., Dudek, J., Nickel, A., Maack, C., Bogeski, I., and Vaeth, M. (2021). Front Pharmacol 12, 734078. 10.3389/ fphar.2021.734078.

BATF3 programs CD8+ T cell memory. Ataide, MA, Komander, K., Knopper, K., Peters, AE, Wu, H., Eickhoff, S., Gogishvili, T., Weber, J., Grafen, A., Kallies, A., Garbi, N., Einsele, H., Hudecek, M., Gasteiger, G., Holzel, M., Vaeth, M. and Kastenmüller, W. (2020). Nat Immunol 21, 1397-1407. 10.1038/s41590-020-0786-2.

Tissue resident and follicular Treg cell differentiation is regulated by CRAC channels. Vaeth, M., Wang, YH, Eckstein, M., Yang, J., Silverman, GJ, Lacruz, RS, Kannan, K., and Feske, S. (2019). Nat Commun 10, 1183. 10.1038/s41467-019-08959-8.

Store-operated calcium entry controls clonal expansion of T cells through metabolic reprogramming. Vaeth, M., Maus, M., Klein-Hessling, S., Freinkman, E., Yang, J., Eckstein, M., Cameron, S., Turvey, SE, Serfling, E., Berberich-Siebelt, F., Possemato R. and Feske, S. (2017a). Immunity 47, 664-679 e666. 10.1016/j. immuni.2017.09.003.

ORAI2 modulates store-operated calcium entry and T cell-mediated immunity. Vaeth, M., Yang, J., Yamashita, M., Zee, I., Eckstein, M., Knosp, C., Kaufmann, U., Karoly Jani, P., Lacruz, RS, Flockerzi, V., Kacskovics I., Prakriya M. and Feske, S. (2017b). ORAI2 modulates store-operated calcium entry and T cell-mediated immunity. Nat Commun 8, 14714. 10.1038/ncomms14714.

Store-operated calcium entry in follicular T cells con­trols humoral immune responses and autoimmunity. Vaeth, M., Eckstein, M., Shaw, PJ, Kozhaya, L., Yang, J., Berberich-Siebelt, F., Clancy, R., Unutmaz, D., and Feske, S. (2016). Immunity 44, 1350-1364. 10.1016/j. immuni.2016.04.013.

Selective NFAT targeting in T cells ameliorates GvHD while maintaining antitumor activity. Vaeth M., Bäuerlein CA, Pusch T., Findeis J., Chopra M., Mottok A., Rosenwald A., Beilhack A. and Berberich-Siebelt F. Proc Natl Acad Sci USA 112(4):1125-30. 10.1073/pnas.1409290112

Follicular regulatory T cells control humoral autoimmunity via NFAT2-regulated CXCR5 expression. Vaeth, M., Muller, G., Stauss, D., Dietz, L., Klein-Hessling, S., Serfling, E., Lipp, M., Berberich, I., and Berberich-Siebelt, F. (2014). J Exp Med 211, 545-561. 10.1084/jem.20130604.

 

Selected Review Articles

CRAC channels and calcium signaling in T cell-mediated immunity. Vaeth M, Kahlfuss S, Feske S. (2020). Trends Immunol (10):878-901. 10.1016/j.it.2020.06.012.

Calcium regulation of T cell metabolism. Wang Y, Tao A, Vaeth M, Feske S. (2020). Curr Opin Physiol 17:207-223. 10.1016/j.cophys.2020.07.016

NFAT control of immune function: New Frontiers for an Abiding Trooper. Vaeth M, Feske S. (2018) F1000 Res 2;7:260. 10.12688/f1000research.13426.1.

Ion channelopathies of the immune system. Vaeth M, Feske S. (2018) Curr Opin Immunol 52:39-50. 10.1016/j.coi.2018.03.021.

Gesunde (rot) und erschöpfte (grün) T-Zellen in der Milz einer chronisch infizierten Maus.

Die Erschöpfung von T-Zellen verhindern

Wie Zucker Entzündungen fördert

Dr. Martin Vaeth

Junior Group Leader
Telefon: +49 931 31 82491
Martin Vaeth Väth Systemimmunologie WueSi

Miriam Campillo Prados

PhD student / Väth Lab
Telefon: +49 931 31-86219
Miriam Campillo Prados WueSi Systems immunology

Stella Cavicchioli

PhD student / Väth lab
Telefon: +49 931 31-86783
Stella Cavicchioli_WueSi_Systems immunology

Miriam Eckstein

Technician / Väth Lab
Telefon: +49 931 31 82510
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Alexandra Freitag

PhD student / Väth Lab
Telefon: +49 931 31-86441
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Gabriela Gubert

PhD student / Väth Lab
Telefon: +49 931 31-88805
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Sophia Hochrein

PhD student / Väth Lab
Telefon: +49 931 31 89058
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Melina Lappe

Master student / Väth lab

Katrin Sinning

PhD student / Väth Lab
Telefon: +49 931 31-84102
Kathrin Sinning_WueSi_Systems immunology

Dr. Hao Wu

Postdoc / Väth Lab
Telefon: +49 931 31 89678
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Xiufeng Zhao

PhD student / Väth Lab
Telefon: +49 931 31 80553
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