Mechanisms of T Cell Reconstitution Following Lymphoablation in TransplantationAnd Description of a Novel Protective Role for T Cells in Epilepsy

Ayasoufi, Katayoun

07 February 2017

No description available.

Immunology

Neurobiology

Lymphoablation

T cells

Transplantation

Immunological memory

CD4 T cells

T cell reconstitution

Transplant Rejection

Sensitized transplant recipients

Epilepsy

Cortical Dysplasia

Seizures

CD200-CD200R Interaction in Tumor Immunity

Talebian, Fatemeh

20 June 2012

No description available.

Bioinformatics

Biology

Biomedical Research

Cellular Biology

Immunology

Molecular Biology

Oncology

Therapy

CD200

CD200R

B16.OVA

T cell therapy

tumor metastasis

P1CTL

agonistic CD200R antibody

immunotherapy

T cell Differentiation and Cytokine Responses in Nontuberculous Mycobacterial Infection

Claeys, Tiffany Ann

January 2021

No description available.

Biomedical Research

Immunology

Microbiology

Biology

T cells

mycobacteria

nontuberculous mycobacteria

NTM

Mycobacterium avium

mycobacterium intracellulare

cytokine

T cell differentiation

Th1

Th17

Role of Dynamic Actin Cytoskeleton Remodeling in Foxp3+ Regulatory T Cell Development and Function: Implications for Osteoclastogenesis

Dohnke, Sebastian, Moehser, Stephanie, Surnov, Alexey, Kurth, Thomas, Jessberger, Rolf, Kretschmer, Karsten, Garbe, Annette I.

11 June 2024

In T cells, processes such as migration and immunological synapse formation are accompanied by the dynamic reorganization of the actin cytoskeleton, which has been suggested to be mediated by regulators of RhoGTPases and by F-actin bundlers. SWAP-70 controls F-actin dynamics in various immune cells, but its role in T cell development and function has remained incompletely understood. CD4+ regulatory T (Treg) cells expressing the transcription factor Foxp3 employ diverse mechanisms to suppress innate and adaptive immunity, which is critical for maintaining immune homeostasis and self-tolerance. Here, we propose Swap-70 as a novel member of the Foxp3-dependent canonical Treg cell signature. We show that Swap-70-/- mice have increased numbers of Foxp3+ Treg cells with an effector/memory-like phenotype that exhibit impaired suppressor function in vitro, but maintain overall immune homeostasis in vivo. Upon formation of an immunological synapse with antigen presenting cells in vitro, cytosolic SWAP-70 protein is selectively recruited to the interface in Treg cells. In this context, Swap-70-/- Treg cells fail to downregulate CD80/CD86 on osteoclast precursor cells by trans-endocytosis and to efficiently suppress osteoclastogenesis and osteoclast function. These data provide first evidence for a crucial role of SWAP-70 in Treg cell biology and further highlight the important non-immune function of Foxp3+ Treg cells in bone homeostasis mediated through direct SWAP-70-dependent mechanisms.

info:eu-repo/classification/ddc/610

ddc:610

Mechanisms of IFN-gamma-mediated Resistance against Development of Toxoplasmic Encephalitis

Wang, Xisheng

07 March 2007

Toxoplasma gondii, an obligate intracellular protozoan parasite, establishes a latent, chronic infection by forming cysts preferentially in the brain after replication of tachyzoites in various organs during the acute stage of infection. Chronic infection with T. gondii is one of the most common parasitic diseases in humans. The immune system is required for maintaining the latency of chronic infection. Reactivation of infection can occur in immunocompromised individuals, such as AIDS patients, which results in the development of life-threatening toxoplasmic encephalitis (TE). IFN-gamma-dependent, cell mediated immune responses play an essential role in preventing the reactivation of chronic infection of T. gondii in the brain. In my dissertation study, we examined the mechanisms of IFN-gamma-mediated prevention of TE by using models of reactivation of chronic infection in BALB/c mice. This strain of mouse is genetically resistant to T. gondii infection and establishes a latent chronic infection as do immunocompetent humans, and therefore provides an excellet model for this purpose. Our laboratory previously demonstrated that both T cells and IFN-gamma-producing non-T cells are required for genetic resistance of BALB/c mice against development of TE. However, the function of T cells required for the resistance is still unclear. Therefore, in the present study, we examined whether IFN-gamma production or perforin-mediated cytotoxicity of T cells play an important role in their protective activity against TE. Immune T cells were obtained from infected IFN-gamma-knockout (IFN-g-/-), perforin-knockout (PO), and wild-type (WT) BALB/c mice, and transferred into infected, sulfadiazine-treated athymic nude mice which lack T cells but have IFN-gamma-producing non-T cells. Control nude mice that had not received any T cells developed severe TE due to reactivation of infection and died after discontinuation of sulfadiazine treatment. Animals that had received immune T cells from either PO or WT mice did not develop TE and survived. In contrast, nude mice that had received immune T cells from IFN-gamma-/- mice developed severe TE and died as early as control nude mice. T cells obtained from spleens of the animals that had received either PO or WT T cells both produced large amounts of IFN-gamma following stimulation with T. gondii antigens in vitro. In addition, the amounts of IFN-gamma mRNA expressed in the brains of PO T-cell recipients did not differ from those of WT T-cell recipients. These results indicate that IFN-gamma production, but not perforin-mediated cytotoxic activity, by T cells is required for prevention of TE in genetically resistant BALB/c mice. In our attempt to identify a T cell population(s) that produces IFN-gamma in the brain and plays an important role for prevention of TE, we analyzed T cell receptor (TCR) Vb chain usage in T cells expressing IFN-gamma in the brains of infected BALB/c mice. We found T cells bearing TCR V beta8 chain to be the most frequent IFN-g-producing population in the brains of infected animals. To examine the role of IFN-gamma production by this T cell population for prevention of TE, V beta8+ immune T cells purified from spleens of infected BALB/c and IFN-g-/- mice were transferred into infected, sulfadiazine-treated athymic nude mice. After discontinuation of sulfadiazine treatment, control nude mice that had not received any T cells and animals that had received Vb8+ T cells from IFN-g-/- mice all died due to reactivation of infection (TE). In contrast, animals that had received the cells from WT mice survived. These results indicate that IFN-gamma production by Vb8+ T cells in the absence of any other T cell population can prevent reactivation of infection. Thus, V beta8+ T cells play a crucial role in genetic resistance of BALB/c mice to TE through their production of IFN-gamma. When V beta8+ immune T cells were divided into CD4+ and CD8+ subsets, a potent protective activity was observed only in the CD8+ subset whereas a combination of both subsets provided greater protection than did the CD8+Vb8+ population alone. These results indicate that CD8+ subset of V beta8+ T cells is a major afferent limb of IFN-gamma-mediated resistance of BALB/c mice against TE, although the CD4+ subset of the T cell population works additively or synergistically with the CD8+V beta8+ population. T cells need to enter into the brains of infected mice to demonstrate their protective activity against TE. This migration is mediated, in part, by endothelial adhesion molecules. Since IFN-gamma is essential for preventing reactivation of chronic infection with this parasite in the brain, we examined whether this cytokine plays an important role in expression of lymphocyte and endothelial adhesion molecules and recruitment of T cells into the brain during chronic infection with T. gondii using IFN-g-/- and WT BALB/c mice. Although the number of cerebral vessels expressing intercellular adhesion molecule-1 (ICAM-1) and vascular cell adhesion molecule-1 (VCAM-1) increased in both WT and IFN-g-/- mice following infection, there were more VCAM-1+ vessels in brains of infected WT than infected IFN-g-/- mice; in contrast, numbers of ICAM-1+ vessels did not differ between strains. We did not detect endothelial E-selectin, P-selectin, MAdCAM-1 or PNAd in any of the brains. Significantly fewer CD8+ T cells were recruited into brains of infected IFN-g-/- than WT mice. Treatment of infected IFN-g-/- mice with recombinant IFN-gamma restored the expression of VCAM-1 on their cerebral vessels and recruitment of CD8+ T cells into their brains, confirming an importance of this cytokine for up-regulation of VCAM-1 expression and CD8+ T cell trafficking. In infected WT and IFN-g-/- animals, almost all cerebral CD8+ T cells had an effector/memory phenotype (LFA-1high, CD44high and CD62Lneg) and approximately 38% were positive for a4b1 integrin (the ligand for VCAM-1). In adoptive transfer of immune spleen cells, pre-treatment of the cells with a monoclonal antibody against a4 integrin markedly inhibited recruitment of CD8+ T cells into the brain of chronically infected wild-type mice. These results indicate that IFN-g-induced expression of endothelial VCAM-1 and its binding to a4b1 integrin on CD8+ T cells is important for recruitment of the T cells into the brain during the chronic stage of T. gondii infection. Since we found strong expression of ICAM-1 on endothelia and LFA-1 on T cells in the brains of infected mice, LFA-1/ICAM-1 interaction, in addition to a4b1 integrin/VCAM-1 interaction, may also be involved in this process. As mentioned earlier, CD8+ T cells are crucial for prevention of TE in BALB/c mice. Therefore, IFN-gamma-mediated expression of VCAM-1 and its binding to a4b1 integrin for recruitment of CD8+ T cells may play a critical role in genetic resistance of BALB/c mice to development of TE. / Ph. D.

adhesion molecules

cell infiltration

brain

Toxoplasma gondii

IFN-gamma

toxoplasmic encephalitis

T cells

T cell receptor

perforin

cytotoxicity

V beta8 T cells

Distinguishing activated T regulatory cell and T conventional cells by single-cell technologies

Reinhardt, Julia, Sharma, Virag, Stavridou, Antigoni, Lindner, Annett, Reinhardt, Susanne, Petzold, Andreas, Lesche, Mathias, Rost, Fabian, Bonifacio, Ezio, Eugster, Anne

21 May 2024

Resting conventional T cells (Tconv) can be distinguished from T regulatory cells (Treg) by the canonical markers FOXP3, CD25 and CD127. However, the expression of these proteins alters after T-cell activation leading to overlap between Tconv and Treg. The objective of this study was to distinguish resting and antigen-responsive T effector (Tconv) and Treg using single-cell technologies. CD4+ Treg and Tconv cells were stimulated with antigen and responsive and non-responsive populations processed for targeted and non-targeted single-cell RNAseq. Machine learning was used to generate a limited set of genes that could distinguish responding and non-responding Treg and Tconv cells and which was used for single-cell multiplex qPCR and to design a flow cytometry panel. Targeted scRNAseq clearly distinguished the four-cell populations. A minimal set of 27 genes was identified by machine learning algorithms to provide discrimination of the four populations at >95% accuracy. In all, 15 of the genes were validated to be differentially expressed by single-cell multiplex qPCR. Discrimination of responding Treg from responding Tconv could be achieved by a flow cytometry strategy that included staining for CD25, CD127, FOXP3, IKZF2, ITGA4, and the novel marker TRIM which was strongly expressed in Tconv and weakly expressed in both responding and non-responding Treg. A minimal set of genes was identified that discriminates responding and non-responding CD4+ Treg and Tconv cells and, which have identified TRIM as a marker to distinguish Treg by flow cytometry.

info:eu-repo/classification/ddc/610

ddc:610

Novel approaches to enhance the protective immune responses of vaccines against Porcine Reproductive and Respiratory Syndrome Virus

Cao, Qian

08 February 2018

Since late 1980s, porcine reproductive and respiratory syndrome virus (PRRSV) has emerged as the most economically important swine pathogen affecting pig industries worldwide. Vaccination is the principal means that have been used for prevention of PRRSV infection. However, the currently available vaccines for PRRSV are generally considered as not very effective. One of the major obstacles for developing an effective modified live-attenuated vaccine (MLV) with broad protection is the delayed and insufficient immune responses mounted by PRRSV, and the problem is further exacerbated by the antigenic variations of the constantly-evolving field strains of PRRSV. In order to boost the immune response induced by the MLV vaccine virus, we evaluated the immunogenicity and vaccine efficacy of recombinant PRRSV MLVs expressing porcine IL-15 or IL-18 as adjuvants. The cytokine genes were fused with a GPI modification signal so that they are anchored onto the cell surface upon infection with the recombinant MLV. Both cytokines are successfully expressed on the cell membrane of porcine alveolar macrophage (PAMs) after recombinant MLVs infection in vitro. Subsequently, pigs vaccinated with cytokine-expressing recombinant PRRSV MLVs had an improved antiviral response of cytotoxic lymphocytes including natural killer (NK) cells and T cells, characterized by increased IFN-γ secretion and/or enhanced CD107a expression. The results offer a novel strategy to incorporate cytokine genes into PRRSV genome as potent bio-active adjuvants expressed by the vaccine virus itself. Since we showed that PRRSV VR2385 down-regulated swine leukocyte antigen class I surface expression, naturally the next logical question is which viral protein is responsible for this down-regulation. To answer the question, we cloned and expressed all known PRRSV structural and non-structural proteins and examined which protein(s) is involved in SLA-I downregulation. Our results identified the newly-discovered nonstructural protein Nsp2TF of PRRSV as the main mediator in down-regulating SLA-I expression. We also demonstrated that the Nsp2TF-knockout mutant virus lost its function of negatively modulating SLA-I presentation compared to the wild-type virus. The results suggest that disruption of the Nsp2TF's ability to down-regulate SLA-I expression may improve the existing PRRSV vaccines towards a better CMI response against the virus. / PHD / Porcine reproductive and respiratory syndrome virus (PRRSV) is an important swine pathogen, causing enormous economical losses in the pork industry worldwide. However, the vaccine program is not satisfactory, with the insufficient protection against genetically divergent strains and newly emerged strains. One of the most important reasons is that PRRSV is able to suppress immune responses in the host, but the underlying mechanisms are not well known. Therefore, the first dissertation study is to investigate novel strategies of developing live-attenuated vaccines with improved efficacy against PRRSV. In this study, we successfully generated recombinant PRRSV live vaccines that are able to express immuno-activating cytokines as adjuvants. Subsequently, pigs vaccinated with cytokine-expressing PRRSVs had significantly improved anti-PRRSV immune repsonses when compared to pigs vaccinated with unmodified PRRSV. Those recombinant PRRSVs also provided cross-protection against a heterologous PRRSV challenge. The second part of disseration research is to understand the mechanism of immune modulation by PRRSV. Our results showed that one of PRRSV proteins- Nsp2TF contributes to the PRSV-induced down-regulation of swine leukocyte antigen (SLA) class I expression. Since SLA class I molecules are essential in the activation of the immune response and required for the clearance of viruses, Our study suggested that knocking-out Nsp2TF could be of great value to generate PRRSV vaccines with a better immune response.

vaccine

adjuvant

cytokine

porcine immunology

T cell and NK cells

swine leukocyte antigen class I (SLA-I)

Nsp2TF

Intra- und extrazelluläre Signale während der T-Zellaktivierung und -differenzierung

Schumann, Julia

27 November 2014

Im ersten Teil dieser Dissertation wurde der Einfluss des mitochondrialen Proteins TCAIM (T cell activation inhibitor, mitochondrial) auf die T-Zellaktivierung untersucht. Hierzu wurde eine transgene Mauslinie mit einem T-zellspezifischen knock-in (KI) von Tcaim in den Rosa26 Lokus generiert. Die Tcaim-Überexpression beeinflusste die Fission und Umverteilung von Mitochondrien und reduzierte die T-Zellrezeptor (TZR)-induzierte Bildung mitochondrialer, radikaler Sauerstoffspezies. In vitro stimulierte CD4+ Tcaim KI T-Zellen zeigten eine geringere Aktivierung, Proliferation und IL-2 Sekretion als Kontrollzellen. T-Zellen aus Tcaim KI Mäusen, die in Rag-1 knock-out Mäuse transferiert wurden, waren nicht fähig ein allogenes Haut-Transplantat abzustoßen und behielten einen naiven Phänotyp. Diese Ergebnisse zeigen, dass TCAIM als mitochondriales Protein wichtige Schritte in der Zellaktivierung und der Bildung von Gedächtnis-T-Zellen beeinflusst. Der zweite Teil der Dissertation beschäftigte sich mit dem Einfluss der CD44-Oberflächenexpression auf die Differenzierung von T-Helfer (TH)-Zellen. Eine hohe CD44-Expression unterscheidet Effektor- von naiven T-Zellen. Durch die allogene Stimulation von CD4+ T-Zellen bildeten sich drei verschiedene Populationen: CD44+, CD44++ und CD44+++. Sowohl in vitro als auch in vivo generierte alloreaktive TH17-Zellen wurden in der CD44+++ Population, TH1-Zellen hingegen in der CD44++ Population, detektiert. Es wurde beschrieben, dass sowohl eine geringe TZR- als auch eine geringe CD28-Stimulation eher die Bildung von TH17- als TH1-Zellen unterstützen. Unter genau diesen Bedingungen kann CD44 als kostimulatorisches Molekül die Signaltransduktion verstärken. Tatsächlich zeigten allogenreaktive CD44+++ TH-Zellen eine höhere ZAP-70-Phosphorylierung als CD44++ TH-Zellen. Diese Ergebnisse unterstützen die Annahme, dass CD44 durch die Verstärkung der Signaltransduktion die TH17-Differenzierung fördern kann. / Within the first part of this thesis, the influence of the mitochondrial Protein TCAIM (T cell activation inhibitor, mitochondrial) on T cell activation was investigated. Tcaim expression correlated negatively with the rejection of allografts and it is down-regulated during T cell activation. To study effects of TCAIM during T cell activation, we generated a T cell-specific mouse strain with a Tcaim knock-in (KI) targeted to the Rosa26 locus. Tcaim overexpression changed the mitochondrial morphology and reduced the T cell receptor (TCR)-induced mitochondrial reactive oxygen species production. In vitro activation of Tcaim KI CD4+ T cells resulted in a decreased activation, proliferation and cytokine release. Importantly, Rag-1 knock-out mice, reconstituted with Tcaim KI T cells, tolerated allogeneic skin grafts. Thus, by regulating TCR-induced mitochondrial distribution and ROS production, TCAIM controls important steps during T cell activation and memory formation. The second part dealt with the influence of CD44 surface expression level for T helper cell (Th cell) differentiation. By association with lymphocyte-specific protein kinase (LCK) it can enhance T cell signaling. Allogeneic stimulation of CD4+ T cells resulted in the formation of three distinguishable populations: CD44+, CD44++ and CD44+++. In vitro and in vivo generated allo-reactive TH17 cells were mainly CD44+++. This is in contrast to TH1 cells which were dominantly CD44++. Titration experiments revealed that low TCR- and co-stimulation supports TH17 rather than TH1 development. Under exactly these conditions it was reported that CD44 can act as co-stimulatory molecule and replace CD28. Indeed, CD44+++CD4+ T cells contained already more phosphorylated ZAP-70 as compared to CD44++ cells. Our results support the notion that CD44 enhances TCR signaling strength by delivering LCK, which is required to support TH17 development.

CD44

Transplantation

Mitochondrien

Th17

Th1

T-Zellaktivierung

TCAIM

CD44

Th17

Th1

T cell activation

TCAIM

Transplantation

Mitochondria

570 Biologie

32 Biologie

WF 9895

ddc:570

Immunoregulation in melanoma / role of IL-10 and TGF-beta

Wiguna, Arlina Permatasari

19 January 2015

IL-10 und TGF-beta sind immunsupprimierende Zytokine, die in verschiedenen Tumoren, u.a. im Melanom, entdeckt wurden und als Hauptursache für das Versagen der Anti-Tumorimmunantwort angesehen werden. Allerdings wurden divergente Daten auch berichtet. Um diese Diskrepanz zu erklären, wurde die Expression dieser Zytokine mittels quantitativer RT-PCR im Melanom und in Haut gesunder Individuen verglichen. Weiterhin wurde die Induktion beider Zytokine in Kokulturexperimenten mit Dendritische Zellen und T-Zellen zusammen mit Tumorzellen sowie ihr Einfluß auf das Immunsystem untersucht. Beide Zytokine sowie deren Rezeptoren wurden im Melanom exprimiert, aber im Vergleich mit gesunder Haut auf signifikant geringerem Level. Dementsprechend waren die Expressionen von IL-10-induzierbare-SOCS-3 und auch TGF-beta-induzierbare-SMAD-7 im Tumor gering und in der gesunden Haut hoch. T-Zellen, die mit einer großen Zahl an Tumorzellen kokultiviert wurden, entwickelten einen anergischen Zustand, aber ohne mit dem IL-10 oder TGF-beta Level zu korrelieren. Dendritische Zellen, die zusammen mit Tumorzellen kokultiviert wurden, wiesen eine gemischte Population an vollständig und unvollständig differenzierten iDCs auf, produzierten hohe Level IL-10 und konnten die CD4 T Zellproliferation weniger effizient induzieren. Trotzdem konnten sie zur Reifung induziert werden, wobei die Blockierung von IL-10 nicht die Fähigkeit der resultierenden, reifen DCs veränderte, CD4 T-Zellproliferation zu induzieren. DCs, deren Reifung in der Gegenwart von Tumorzellen induziert wurde, produzierten erhöhte Level an IL-10, dagegen gleiche oder verminderte Level an TGF-beta und waren effizienter in der Induktion der CD4 T-Zellproliferation. Die fehlende Korrelation von IL-10 und TGF-beta mit den Immundefiziten in situ und in vitro legt den Schluß nahe, ihre Rolle bei Krebs neu zu überdenken. / IL-10 and TGF-beta are immunosuppressive cytokines expressed in tumors including melanoma and, therefore, deemed major cause for failing anti-tumor immune responses. To re-evaluate their role, their expression was compared by quantitative RT-PCR in melanoma and skin of healthy individuals, their induction in dendritic cells and T cells co-cultured with tumor cells, and their effects on the immune cells were tested. Both cytokines as well as their receptors were expressed in melanoma at significantly lower levels than in healthy skin. Consequently, the expressions of IL-10-responsive SOCS-3 and TGF-beta-responsive Smad-7 were low in tumors but high in healthy skin. T cells co-cultured with tumor cells developed an anergic state but without increased IL-10 or TGF-beta expression. In vitro tumor-associated iDCs produced high IL-10 levels and were less efficient in inducing T cell proliferation. Nonetheless, they could be induced to mature, and blocking IL-10 did not alter the capacity of the resulting mDCs to induce T cell proliferation. mDCs co-cultured with tumor cells produced increased IL-10 but similar or decreased TGF-beta level and were more efficient in inducing T cell proliferation. The lack of correlation of IL-10 and TGF-beta with immune deficits in situ and in vitro suggests a necessity of re-evaluating their roles in cancer.

TGF-beta

IL-10

Melanom

Dendritische Zell

T-Zell

T cell

TGF-beta

IL-10

melanoma

dendritic cell

570 Biologie

32 Biologie

XH 9150

ddc:570

Induktionsbedingungen und kostimulatorische Effekte von ICOS / einem neuen T-Zellspezifischen Oberflächenantigen

Dittrich, Anna-Maria

15 January 2001

Das Ergebnis einer T-Zellmediierten Immunantwort ist von der Signalvermittlung durch kostimulatorische Moleküle abhängig. Diese kostimulatorischen Moleküle sind - neben dem spezifischen Antigen - notwendig für eine vollständige T-Zellaktivierung, die es der T-Zelle erlaubt zu proliferieren, neue Oberflächenantigene zu exprimieren und Zytokine zu sezernieren. Ohne das kostimulatorische Signal wird die T-Zelle anerg oder sogar apoptotisch, eine effektive Immunantwort ist dann nicht möglich. Die vorliegende Dissertationsschrift enthält die initiale Beschreibung eines neuen kostimulatorischen Moleküls, eine umfangreiche Charakterisierung seiner Expression in vitro, sowie seiner Funktion. Das Molekül "ICOS" (ICOS steht für inducible costimulator) ist ein T-Zellspezifisches Molekül und weist eine große Homologie zu dem Prototyp eines kostimulatorischen Moleküls, dem CD28 Molekül auf. Die Experimente, die zur Charakterisierung der Induktionsbedingungen des ICOS Moleküls durchgeführt wurden, zeigen, daß die Expression des ICOS Moleküls sehr schnell nach T-Zellaktivierung induziert wird, die Expressionsstärke innerhalb von Stunden stark heraufreguliert wird und die Expression lange (mindestens 96h) auf der T-Zelloberfläche zu detektieren ist. Ein Vergleich mit anderen aktivierungsabhängigen T-Zelloberflächenmolekülen zeigt eine ICOS-spezifische Zeitkinetik der Expression, die durch verschiedene T-Zellstimuli zu induzieren ist. Eine optimale Expression des Moleküls ist zwei-signalabhängig und durch Cyclosporin A blockierbar. Bezüglich der Funktion von ICOS wurde die Wirkung der Kostimulation via ICOS auf eine Reihe von kritischen Parametern der T-Zellaktivierung analysiert. Durch die Kostimulation mit einem ICOS-spezifischen Antikörper wird konzentrationsabhängig die T-Zellproliferation induziert, unabhängig davon, ob das ersten Signal via CD3 oder via einen löslichen Stimulus, wie PHA erfolgte. Die ICOS Kostimulation bewirkt die Hochregulation von typischen T-Zellaktivierungsantigenen und sie induziert oder verstärkt die Sekretion zahlreicher Lymphokine. Die verstärkende Wirkung auf alle diese Parameter der T-Zellaktivierung führt schließlich dazu, daß die über ICOS kostimulierten Zellen in der Lage sind T-Zellhilfe für B-Zellen zu leisten, so daß diese Immunglobuline sezernieren. Wurde versucht, die direkte Interaktion des ICOS Moleküls mit seinem potentiellen Liganden bei der T-Zellinduzierten Immunglobulinsekretion durch den mAk F44 zu blockieren, so zeigte sich kein Effekt. Bei Langzeitkostimulation via ICOS zeigte sich allerdings, daß die Kostimulation durch das ICOS Molekül auch in der Lage ist, die T-Zellaktivierung negativ zu beeinflussen: Die Langzeitstimulation via ICOS erzeugt eine deutliche Proliferationsdepression und einen Viabilitätsverlust der T-Zellen. Insgesamt lassen diese Ergebnisse den vorsichtigen Schluß zu, daß das ICOS Molekül eine wichtige Rolle an der Schnittstelle zwischen Expansion und Effektorfunktion einerseits und Depression der T-Zellen andererseits spielt. / The outcome of T-cell resonses after T-cell encounter with specific antigens is modulated by co-stimulatory signals, which are required for both lymphocyte activation and development of adaptive immunity. Here I report the initial characterization of a novel co-stimulatory molecule which enhances all basic T-cell functions and displays a unique induction and expression pattern. ICOS (for inducible co-stimulator) is a T-cellspecific activation antigen with high homology to CD28, the prototype of a co-stimulatory molecule. Analysis of induction requirements for ICOS expression revealed a two-signal dependency and cyclosporine A sensitivity. ICOS' expression kinetics are unique when compared with other early T-cell activation antigens. ICOS is induced very quickly on the T-cell surface and is rapidly upregulated following T-cell activation. The surface expression of ICOS is surprisingly prolonged - lasting at least 96 hours - considering its rapid induction kinetics. Stimulation via an ICOS-specific monoclonal antibody enhances all basic T-cell functions such as proliferation, upregulation of molecules that medicate cell-cell interaction, secretion of lymphokines and effective help for antibody secreting B-cells. Costimulation via ICOS is effective regardless of the route of action of the first signal (immobilized or soluble). Blockade of the ICOS interaction with its presumed ligand on B-cells does not inhibit immunoglobulin production by these B-cells, though. Finally long-term stimulation experiments reveal a possible negative role for ICOS in regulating T-cell responses. These results indicate that ICOS is a major regulator of the adaptive immune system determining the healthy balance of negative and positive signaling during T-cell activation and differentiation.

T-Zelle

ICOS

Kostimulation

T-Zellaktivierung

T-cell activation

ICOS

Co-stimulatory molecule

610 Medizin und Gesundheit

33 Medizin

XD 3100

ddc:610