The Role of Eosinophils in the Regulation of CD4+ T helper 2 Regulated Inflammation

MacKenzie, Jason Roderick, Jason.Mackenzie@ipaustralia.gov.au

January 2004

The eosinophil is a leukocyte whose intracellular mediators are considered to play a central role in the pathogenesis of allergic diseases, including allergic asthma, allergic rhinitis and atopic dermatitis, and which is also involved in immunological responses to parasites. Eosinophil differentiation and maturation from bone marrow progenitors is regulated by interleukin-5 (IL-5), which may be secreted by T helper 2 (Th2) T lymphocytes, and is consistently upregulated in allergic conditions. Eotaxin is a potent chemoattractant for circulating and tissue eosinophils, and the production of this chemokine promotes eosinophil infiltration and accumulation within sites of allergic inflammation.¶ Eosinophils obtained from inflammatory tissues and secretions display an altered phenotype in comparison to peripheral blood eosinophils, with increased surface expression of major histocompatibility complex (MHC) proteins and adhesion molecules (Hansel et al., 1991), and migration across the microvascular endothelium may also increase their capacity to generate an oxidative burst (Walker et al., 1993; Yamamoto et al., 2000). Eosinophils are phagocytic cells, and have been shown to present simple (no requirement for intracellular processing) and complex antigens to MHC-restricted, antigen-specific T lymphocytes (Del Pozo et al., 1992; Weller et al., 1993). Furthermore, eosinophils express the costimulatory molecules required for effective antigen presentation (Tamura et al., 1996), and ligation of costimulatory molecules on the eosinophil cell surface can induce the release of eosinophil derived cytokines (Woerly et al., 1999; Woerly et al., 2002). Therefore the eosinophil may also regulate immune responses.¶ To date, no studies have demonstrated the ability of eosinophils to modulate activated T lymphocyte function via presentation of relevant antigen in the context of MHC class II (MHC-II), concomitant with Th2 cytokine release. In the experiments described in this thesis, murine eosinophils have been observed to rapidly migrate to sites of antigen deposition within the airways mucosa of naïve mice, suggesting a potential role for this granulocyte in the primary response to inhaled antigen. However, human allergic diseases are often diagnosed after the establishment of allergic responses, and symptom development. Therefore, a murine model of allergic airways disease (AAD) was used to investigate the ability for eosinophils to participate as antigen presenting cells (APCs), and thereby modulate activated T lymphocyte function both in vitro and in vivo. Detailed histological analysis of the pulmonary draining lymph nodes following antigen challenge in sensitised mice revealed a rapid infiltration of eosinophils into this tissue, which preceded the accumulation of eosinophils in bronchoalveolar lavage fluid (BALF). This suggested that eosinophils were preferentially translocating to the draining lymph nodes following antigen challenge, and that the subsequent accumulation of these cells in the BALF was a consequence of continued antigen delivery to the lower airways.¶ Eosinophil trafficking to lymphoid tissue via the afferent lymphatics was substantiated using electron microscopy of lymph node sections and the intravenous (i.v.) transfer of fluorescently labeled eosinophils, which did not traffic to lymph nodes via the blood. During the resolution of AAD, eosinophils were noted for their persistence in the pulmonary draining lymph nodes. These observations suggested a continued modulation of T cell function by lymph node dwelling eosinophils during AAD resolution, particularly in light of recent observations for draining lymph node T cell proliferation following instillation of antigen-pulsed eosinophils into the allergic mouse lung (Shi et al., 2000).¶ To further investigate the antigen presenting capacity, eosinophils were obtained from the BALF of mice with AAD, and their surface expression of MHC class II (MHC-II) proteins and costimulatory molecules confirmed using flow cytometric analysis. The ability to acquire and process complex antigen both in vitro and in vivo was also confirmed using naturally quenching fluorescenated ovalbumin (OVA), which is degraded into fluorescent peptides by the action of intracellular proteases. Thus, eosinophil expression of the surface molecules necessary for effective antigen presentation was confirmed, as was their ability to process complex antigen. Further investigations revealed that eosinophils can present complex OVA antigen to CD4+ T lymphocytes obtained from the allergic mouse, and to in vitro derived OVA-specific Th2 cells. In the presence of exogenous antigen, eosinophils co-cultured with T lymphocytes were able to induce Th2 cytokine production, and demonstrated an ability for eosinophils to modulate T lymphocyte function in vitro.¶ The ability for eosinophils to act as antigen presenting cells in vivo was also investigated. Eosinophils obtained from the antigen-saturated lungs of OVA sensitised and challenged mice were transferred to the peritoneal cavities of naïve host mice. When subsequently challenged with aerosolised OVA, eosinophil recipients developed a pulmonary eosinophilia similar to that of OVA sensitised and challenged mice. To validate this finding, the experimental procedure was altered to accommodate the use of non-allergy derived eosinophils, which were pulsed with OVA in vitro, prior to transfer into naïve recipients. When subsequently challenged with aerosolised OVA, eosinophil recipients developed a peripheral blood and pulmonary eosinophilia, and stimulation with OVA induced IL-5 and IL-13 cytokine production from pulmonary draining lymph node cells. Notably, the AAD induced by transfer of antigen pulsed eosinophils did not induce detectable OVA-specific IgG1, which may be attributed to the lack of soluble antigen required for B cell antibody production.¶ During the course of these investigations, an OVA T cell receptor (TCR) transgenic mouse (OT-II) was procured with a view to defining the interaction between eosinophils and activated T lymphocytes (Barnden et al., 1998). Despite having specificity for the OVA323-339 peptide, an immunodominant epitope that skews naïve T cell responses towards Th2 cytokine release (Janssen et al., 2000), T lymphocytes from the OT-II mouse preferentially secreted IFN-γ in response to stimulation with either OVA peptide or OVA. These mice were further characterised in a mouse model of AAD, and found to be refractory to disease induction and progression, which may be attributed to significant IFN-γ secretion by transgenic CD4+ T lymphocytes during antigen sensitisation. Indeed, these cells were noted for their ability to attenuate pulmonary eosinophilia when transferred to OVA sensitised and challenged wild type mice, although serum OVA-specific IgG1, peripheral blood eosinophilia levels and airways response to methacholine challenge remained intact.¶ Knowledge of the biased Th1 phenotype in naïve OT-II provided a unique opportunity to investigate the fate of T lymphocytes bearing high affinity OVA-specific TCRs following neonatal antigen exposure to soluble OVA. In a previous study, subcutaneous (s.c.) administration of soluble OVA to wild type neonatal mice was suspected to have deleted OVA-specific T cells from the T cell repertoire (Hogan et al., 1998a). Using flow cytometry and TCR specific antibody, the delivery of s.c. OVA to OT-II neonates did not alter transgenic T cell populations in adult mice. Instead, it was surprising to find a skewing towards the Th2 phenotype and loss of IFN-γ secretion following OVA sensitisation and challenge in adult mice. A mechanism for this reprogramming of the transgenic T cell from the Th1 to a Th2 phenotype following OT-II neonatal exposure to soluble OVA is proposed, and further experimentation may validate this hypothesis.¶ In conclusion, eosinophils residing in the allergic lung have the capacity to interact with activated T cells, both within this tissue and the draining lymph nodes. Despite their relative inefficiency as antigen presenting cells (Mawhorter et al., 1994), eosinophils may participate en masse in the serial triggering of activated TCRs, and provide appropriate costimulatory signals that modulate T lymphocyte function. Through the elaboration of Th2 cytokines and stimulation of T cell proliferation, antigen presenting eosinophils may transiently prolong or exacerbate the symptoms of allergic diseases. Alternatively, eosinophils presenting relevant antigens may inhibit T cell activity via degranulation, and such activity has recently been observed in a parasite model (Shinkai et al., 2002). Finally, experiments in the OT-II mouse have provided valuable information to suggest that therapies designed to modulate eosinophil numbers in allergic tissues through the secretion of opposing cytokines such as IFN-γ, may be of limited benefit. The results shown here suggest that airways dysfunction remains intact despite significantly reduced pulmonary eosinophilia

Eosinophil

Antigen Presenting Cell

APC

Allergic Airways Disease

AAD

Ovalbumin

Ova-transgenic

Asthma

CD4

Lymphocyte

T helper 2

Initiation of Autoimmunity in Experimental Autoimmune Encephalomyelitis

Isaksson, Magnus

January 2012

The events that trigger an autoimmune disease remain largely unknown. To study these events animal models are necessary because symptoms of autoimmune diseases are preceded by a long asymptomatic period in humans. Experimental autoimmune encephalomyelitis (EAE) is the best characterized model for cell mediated autoimmunity and an animal model for the human disease multiple sclerosis. EAE is induced in rodents by immunization with myelin antigens (Ags) together with adjuvants. After immunization, T cells are primed in the periphery by Ag presenting cells and subsequently invade the central nervous system where they mediate parenchymal inflammation, resulting in demyelination and clinical symptoms of an ascending paralysis. It is now generally recognised that the main cell type mediating EAE is the T helper type 17 (Th17) cell. Tolerance to EAE can be attained by DNA vaccination, but how the immune response against the myelin Ags is abrogated after DNA vaccination is not known. By employing short interfering RNA technology, induction of the innate immune signalling molecule interferon (IFN) -β was found to be necessary for the protective effect of DNA vaccination in EAE. In addition, DNA vaccination inhibited subsequent autoimmune Th17 cell responses. The Toll-like receptors (TLRs) of the innate immune system have evolved to recognise conserved molecular structures on microbes and signalling through them almost exclusively converge on the molecule MyD88. Signalling via MyD88 was found to be required for induction of EAE since mice deficient in this molecule did not develop disease. Upstream signalling via TLR4 and TLR9 had tolerogenic properties. In studies of Ag presentation in EAE, two major subtypes of dendritic cells (DCs) were examined. Plasmacytoid DCs were found to have a promoting role in the induction of EAE, partly via type 1 IFNs. Myeloid DCs had a redundant role in the induction phase of EAE, neither disease severity nor encephalitogenic Th17 responses were affected by their absence during priming. These studies further demonstrate that the cells and molecules of the innate immune system exhibit a crucial role in controlling the adaptive immune system which mediates tissue damage in autoimmune diseases.

Autoimmunity

Cytokines

Dendritic cells

DNA vaccination

EAE

Innate immunity

T helper cells

Toll-like receptors

Type I interferons

Immunological Studies using Human and Canine Model Disorders / Immunologiska studier av modellsjukdomar i människa och hund

Ahlgren, Kerstin M.

January 2011

The studies presented in this thesis focus on human and canine models for autoimmune disease, with the main aim to gain new knowledge about disease mechanisms and to further evaluate the dog as a model for autoimmune disease. Autoimmune Polyendocrine Syndrome type 1 (APS-1) is a hereditary human multiorgan disease caused by mutations in the autoimmune regulator (AIRE) gene. Hallmarks of APS-1 are chronic mucocutaneous candidiasis caused by Candida albicans, together with the autoimmune endocrine disorders hypoparathyroidism and adrenocortical failure. Many human diseases have an equivalent disease in dogs. Because humans share environment, and in part life style with the dogs they provide an interesting model for further genetic studies. Immune responses to Candida albicans in APS-1 patients displayed an increased secretion of the proinflammatory cytokine IL-17A and similar results were also found in AIRE deficient mice. Anticytokine autoantibodies to IL-17A, IL-17F and IL-22 were detected in APS-1 patients, and a radioligand binding assay for measuring these autoantibodies was developed and evaluated. In the canine studies we investigated whether canine diabetes mellitus could serve as a model for human autoimmune diabetes mellitus. Furthermore, we investigated type I IFN responses in Nova Scotia duck tolling retriever dogs with a systemic autoimmune disease resembling human SLE. Four assays were used in search for signs of humoral autoimmunity in diabetic dogs. However, no evidence for a type 1 diabetes-like phenotype in dogs was found. Sera from Nova Scotia duck tolling retrievers suffering from steroid-responsive meningitis arteritis elicited an increased expression of IFN-inducible genes in the canine MDCK cell line. This suggests that these dogs have an IFN signature, as seen in human SLE.

Autoimmunity

T cell

T helper cell

B cell

Autoantibodies

Interferon

Interleukin

Dogs

APS-1

Candida albicans

fungus

Mécanismes moléculaires et cellulaires dans l’induction des réponses T helper folliculaires après vaccination cutanée / Molecular and cellular mecanisms in the induction of T follicular helper responses after cutaneous vaccination

Levin, Clément

12 December 2016

La vaccination du tissu cutané présente un fort potentiel, car elle permet le ciblage de l’antigène aux populations de cellules dendritiques uniques et spécialisées de la peau, et le recrutement de cellules inflammatoires du sang.Les cellules T helper folliculaires (TFH) jouent un rôle crucial dans l’établissement de la réponse humorale. Cependant, les interactions cellulaires et moléculaires qui gouvernent leur induction dans un contexte de vaccination restent à élucider.Mon projet de thèse a eu pour but de mieux comprendre les mécanismes d’induction des réponses TFH et humorales, par l’étude des événements précoces ayant lieu aux sites d’immunisation et d’induction de l’immunité adaptative après vaccination cutanée. L’utilisation de modèles murins nous a permis d’évaluer la contribution de différentes populations de la peau, du ganglion, et du sang dans la mise en place de ces réponses après immunisation intradermique avec un antigène particulaire présentant l’antigène modèle p24 du VIH. Cette étude a révélé un rôle crucial des cellules de Langerhans et des cellules dendritiques migratoires de la peau dans l’induction de réponses TFH et humorales.Nous avons ensuite évalué la capacité de différentes formulations d’adjuvants à polariser la réponse TFH et humorale contre un antigène de l’enveloppe du VIH à fort potentiel vaccinal. L’utilisation de l’émulsion IFA favorise l’induction des cellules TFH et induit la production d’anticorps neutralisants des souches du VIH.Ces résultats soulignent l’importance de cibler les DCs de la peau par l’utilisation de voies de vaccination pertinentes et l’utilisation d’adjuvants capables de favoriser la réponse cellulaire TFH. / Skin vaccination is of great interest, as it enables targeting of the antigen to unique and specialized dendritic cell populations of the skin, as well as recruitment of inflammatory blood cells.T follicular helper (TFH) cells play a critical role in the setting of the humoral response. However, the cellular and molecular interactions that underlie their induction after vaccination remain unknown.My thesis project aimed at understanding the immune mechanisms by which skin vaccination could favor the induction of TFH and humoral immune responses by studying the early events that take place in tissue and lymph node.Using mice models, we evaluated the relative contributions of various populations from the skin, lymph node and blood in the setting of TFH cell responses after intradermal immunization with nanoparticles coated with p24 antigen from HIV. This revealed a crucial role of Langerhans cells and skin migratory dendritic cells in the induction of TFH and germinal center responses.We then evaluated the ability of different adjuvant formulations to polarize the TFH and humoral response against a promising vaccine antigen from HIV envelope protein. Emulsifying the antigen in IFA favors the induction of TFH cells and induces the production of neutralizing antibodies able to block viral infection.This work highlights the relevance of targeting skin dendritic cells by using relevant vaccination routes and adjuvant formulation able to induce TFH cell responses.

Vaccination cutanée

Cellule T helper folliculaire

Cellule de Langerhans

Nanoparticule

VIH

Inflammation

Skin vaccination

T follicular helper cell

Langerhans cell

571.96

The Role of IkZF Factors in Mediating TH1/TFH Development and Flexibility

Bharath Krishnan Nair, Sreekumar

24 January 2020

The ability of cells within the adaptive immune system to develop into specialized subsets allow for a robust and tailored immune response in the advent of an infection or injury. Here, CD4+ T-cells are a crucial component within this system, with subsets such as TH1, TH2, TH17, TFH and TREG cells playing vital roles in propagating cell-mediated immunity. For example, TH1 cells are essential in combating intracellular pathogens such as viruses, while TFH cells communicate with B-cells to optimize antibody responses against an invading pathogen. The development (and functionality) of these subsets is ultimately dictated by the appropriate integration of extracellular cues such as cytokines with cell intrinsic transcription factors, thereby promoting the necessary gene profile. Moreover, the observation that T-helper cells could exhibit a flexible nature (i.e having shared gene profiles and effector functions) not only demonstrate the efficiency of our immune system but also how such flexibility could have unintended consequences during adverse events such as autoimmunity. An important mediator of such flexibility is cytokines. However, the complete network of factors that come together to co-ordinate cytokine mediated plasticity remain unknown. Thus, the work in this dissertation hope to delineate the factors that collaborate to regulate cytokine induced T-helper cell flexibility. As such, we see that in the presence of IL-2, the Ikaros Zinc Finger (IkZF) transcription factor Eos is upregulated in TH1 cells, with this factor playing a significant role in promoting regulatory and effector functions of TH1 cells. Moreover, we show that Eos forms a novel protein complex with STAT5 and promotes STAT5 activity in TH1 cells. However, depleting IL-2 from the micro-environment leads to the upregulation of two other members within the IkZF family, Ikaros and Aiolos. Aiolos in turn collaborate with STAT3, induces Bcl-6 expression within these cells, thus promoting these cells to exhibit characteristic features of TFH cells. The work in this dissertation hopes to advance our understanding of the regulatory mechanisms involved in cytokine mediated T-cell flexibility thereby hoping to open new avenues for the development of novel therapeutic strategies in the event of autoimmunity. / Ph. D. / T-helper (TH) cells are an important component of the immune system, as these cells aid in the fight against pathogens by secreting factors that either accentuate the inflammatory response during infection or attenuate immune responses post infection. Such effects are made possible because T-helper cells can differentiate into a variety of subsets, with each subset being an important mediator in maintaining immune homeostasis. For example, the T-helper cell subset called TH1 plays a vital role in the fight against intracellular pathogens such as viruses and certain parasites, while T-follicular helper (TFH) cells aid in the production of antibodies specific to the invading pathogen. The development of such subsets occur when cell extrinsic signals, called cytokines, lead to the activation or induction of cell intrinsic proteins called transcription factors. Interestingly, research over the years have shown that T-helper cells are highly adaptable in nature, with one subset having the ability to attain certain characteristic features of other subsets. This malleable nature of T-helper cells relies on several factors, with cytokines within the micro-environment being an important one. Although this form of flexibility is efficient and beneficial at times, it can also be detrimental, as such flexibility is known to promote certain autoimmune diseases such as multiple sclerosis, rheumatoid arthritis and type 1 diabetes. Such detrimental effects are thought to be due to cytokines within the environment. Therefore understanding how cytokines influence the flexible nature of T-helper cells is important; as controlling such flexibility (either by regulating cytokines or the transcription factors activated as a consequence) could prevent the propagation of undesired T-helper cell functions. As such, the work in this dissertation hopes to uncover how one such cytokine, termed Interleukin-2 (IL-2) mediates the flexibility between TH1 and TFH cells. The work highlighted in this dissertation broadens our understanding of how cytokines influence T-helper cell development and flexibility, and consequently allows the design of novel therapeutic strategies to combat autoimmune diseases.

CD4+ T helper 1 cell

CD4+ T follicular helper cell

interleukin-2

STAT transcription factors

IkZF transcription factors

Modeling the Interleukin 2 gene expression in activated T cells

Benary, Manuela

15 February 2016

Interleukin 2 (IL-2) ist ein Zytokin, welches in menschlichen Gedächtnis-T-Helfer-Zellen (Teff Zellen) exprimiert und sekretiert wird und damit die Immunantwort formt. Im Gegensatz dazu wird IL-2 normalerweise nicht in regulatorischen T-Zellen (Treg Zellen) exprimiert, sondern von diesen nur aufgenommen. Durch die Aktivierung des T-Zellrezeptors werden Signalkaskaden induziert, welche zur Aktivierung der Transkriptionsfaktoren AP-1, NFAT, und NF-kB führen. Diese sind entscheidend für die Genexpression von IL-2. Im Rahmen meiner Dissertation habe ich die Regulation der IL-2 Genexpression untersucht. Dabei vergleiche ich die transkriptionelle Regulation in Teff Zellen mit der Regulation in Treg Zellen. Insbesondere konnte ich zeigen, dass die endogene Konzentration der Transkriptionsfaktoren sich auf die Anzahl der IL-2 Produzenten auswirkt, aber nicht auf die Konzentration von IL-2 innerhalb einer Zelle. Deshalb untersuche ich wie sich die Konzentration der Transkriptionsfaktoren auf die Häufigkeit von IL-2 Produzenten auswirkt. Ich nutze die vorhandenen endogenen Konzentrationen und kann damit vorhersagen, dass die Zahl der IL-2 Produzenten entscheidend von der c-fos Konzentration in Teff Zellen abhängt. Mit Hilfe des entwickelten Modells kann ich voraussagen, wie der spezifische Inhibitor U0126 die Häufigkeit von IL-2 Produzenten verringert. Diese Vorhersage wurde durch Experimente belegt. Meine Modelle zeigen weiterhin, dass c-fos und NFATc2 die Häufigkeit der IL-2 Produzenten in Teff Zellen kooperativ regulieren. In Treg-Zellen zeigt meine Analyse, dass alle Transkriptionsfaktoren eine ähnliche sigmoidale Wirkung auf die Häufigkeit der IL-2-Produzenten ausüben. Im Gegensatz zu den Teff Zellen haben alle Transkriptionsfaktor eine ähnliche maximale Wirkung auf Genexpression von IL-2. Mittels eines Inhibitionsmodelles konnte ich zeigen, dass der Treg zellspezifische Transkriptionsfaktor FoxP3 allen aktivierenden Transkriptionsfaktoren entgegenwirkt. / Interleukin 2 (IL-2) is a cytokine expressed in human memory T helper cells (Teff cells) and the secretion of IL-2 shapes the immune response. In contrast, human regulatory T-cells (Treg cells) commonly do not express IL-2. The gene expression of IL-2 is induced by the activation of the T-cell receptor signaling network activating the transcription factors AP-1, NFAT, and NF-kB. These transcription factors are crucial for initiating IL-2 gene expression. Within my thesis I compare the regulation of IL-2 gene expression in Teff cells and Treg cells using experiments and modeling. I demonstrate that the transcription factor concentrations correlate with number of IL-2 producers but do not affect IL-2 concentration per cell. Thus, I investigate how the transcription factor concentration of c-fos, NFATc2, p65, and p-c-jun affects the frequency of IL-2 producing cells as a proxy for the probability of a cell to produce IL-2. Using the endogenous heterogeneity of transcription factor concentrations, I predict that the number of IL-2 producers is critically dependent on the amount of c-fos in Teff cells. I use my model to predict how perturbations of c-fos by the specific inhibitor U0126 decrease the frequency of IL-2 producers in Teff cells. This prediction was than validated by experiments. My models furthermore indicate the cooperative behavior of c-fos and NFATc2 on the level of frequency of IL-2 producers in Teff cells. In Treg cells, I show that all transcription factors exert a similar sigmoidal effect on the frequency of IL-2 producers. In contrast to the effects seen in Teff cells, all transcription factor have a similar maximal effect on the IL-2 gene expression. With an inhibitory model I explore the relation between the Treg cell-specific transcription factor FoxP3 the transcription factors c-fos, NFATc2, p65, and p-c-jun on the frequency of IL-2 producers. This model indicates that FoxP3 counteracts the activating function of NFATc2, AP-1, and also NF-kB.

Systembiologie

mathematische Modellierung

T-Helferzelle

Interleukin 2

systems biology

mathematical modelling

T helper cell

interleukin 2

570 Biowissenschaften, Biologie

32 Biologie

ddc:570

The effect of dietary n-3 polyunsaturated fatty acids on T cell subset activation-induced cell death

Switzer, Kirsten Collette

15 November 2004

Dietary n-3 polyunsaturated fatty acids (PUFA) have been shown to potently attenuate T cell-mediated inflammation, in part, by suppressing T cell activation and proliferation. Apoptosis is an important mechanism for preventing chronic inflammation by maintaining T cell homeostasis through the contraction of populations of activated T cells. We hypothesized that dietary n-3 PUFA would promote T cell apoptosis, thus, providing an additional mechanism to explain the anti-inflammatory effects. We specifically examined activation-induced cell death (AICD) since it is the form of apoptosis associated with peripheral T cell deletion involved in immunological tolerance and T cell homeostasis. Female C57BL/6 mice were fed diets containing either n-6 PUFA (control) or n-3 PUFA for 14 d. Splenic T cells were stimulated with CD3/CD28, CD3/PMA, or PMA/Ionomycin for 48 h followed by reactivation with the same stimuli for 5 h. Apoptosis was measured using Annexin V/propidium iodide and flow cytometry. Cytokine analyses revealed that n-3 PUFA enhanced AICD only in T cells expressing a Th1-like cytokine profile (high IFN, low IL-4) compared to mice fed the n-6 PUFA control diet. Dietary n-3 PUFA significantly altered the fatty acid composition of phosphatidylcholine and phosphatidylethanolamine in T cell membranes. To examine the apparently selective effect of dietary n-3 PUFA on AICD in Th1 cells, CD4+ T cells were polarized in vitro to a Th1 phenotype by culture with IL-4, IL-2, and IL-12 for 2 d, followed by culture with IL-2 and IL-12 for 3 d in the presence of diet-matched homologous mouse serum (MS) to prevent loss of cell membrane fatty acids. Following polarization and reactivation, we observed that n-3 PUFA enhanced Th1 polarization and AICD only in cells cultured in the presence of MS, but not in fetal bovine serum. The n-3 PUFA enhancement of Th1 polarization and AICD was associated with the maintenance of diet-induced changes in EPA (20:5n-3) and DHA (22:6n-3) in plasma T cell membrane lipid rafts. Overall, these results suggest that dietary n-3 PUFA enhance both the polarization and deletion of pro-inflammatory Th1 cells, possibly as a result of alterations in lipid raft fatty acid composition.

activation-induced cell death

apoptosis

docosahexaenoic acid

eicosapentaenoic acid

fish oil

lipid rafts

n-3 polyunsaturated fatty acids

T cell

T helper 1 cell

L'activation des cellules T CD8+ et T CD4+ en réponse aux auto-antigènes : du tissu lymphoïde à l'organe cible / Activation of CD8+ and CD4+ T cells in response to self-antigen : from the lymphoid tissue to the target organ

Espinosa Carrasco, Gabriel

07 October 2016

Le système immunitaire comporte différents mécanismes de tolérance périphérique permettant de contrôler la réponse des cellules T CD8+. Dans certaines conditions encore peu connues, des cellules T potentiellement auto-réactives peuvent contourner les mécanismes de tolérance et se différencier en cellules effectrices, capables d’attaquer différentes organes de l’organisme, dans un processus d’auto-réactivité. En utilisant une souris transgénique exprimant un antigène modèle dans les cellules bêta du pancréas, j’ai étudié deux processus fondamentaux impliqués dans la différenciation des cellules T CD8+ en réponse aux antigènes du soi.1) Rôle de la translocation des lipopolysaccharides (LPS) dans la rupture de la tolérance. Nous avons préalablement démontré dans le laboratoire que des protocoles de lympho-déplétions, tels l’irradiation, étaient capables d’induire une rupture de la tolérance périphérique dans les cellules T CD8+. L’irradiation provoque la translocation des LPS des bactéries commensales vers la circulation sanguine, ce qui induit une activation du système immunitaire inné. Mes données ont montré que la translocation des LPS était corrélée avec l’activation systémique des cellules dendritiques (DC) CD11c+, en particulier les DC CD8+, responsables de la cross-présentation des auto-antigènes pancréatiques dans les tissus lymphoïdes. Alors que le traitement par des antibiotiques avant l’irradiation permet de prévenir la translocation des LPS, l’activation des DC n’est que partiellement affectée, et le développement de l’auto-immunité résultant d’une rupture de la tolérance périphérique des cellules T CD8+ ne peut pas être empêchée par le traitement.2) Visualisation de la coopération entre cellules T CD4+ et CD8+ effectrices dans la destruction des cellules bêta pancréatiques in vivo. En utilisant la microscopie intra-vitale à 2-photons, j’ai pu analyser, pour la première fois, la dynamiques des cellules T CD4+ et CD8+ auto-réactives exprimant un marqueur fluorescent, lors de l’infiltration du pancréas et du développement du diabète auto-immun. J’ai mis en évidence que l’infiltration des cellules T était accompagnée d’un remodelage de la matrice extracellulaire du pancréas, permettant la migration dirigée des lymphocytes. De plus, j’ai montré que l’arrêt MHC classe II-dépendant des cellules T CD4+, dû à des interactions avec des cellules présentatrices d’antigène recrutées au site d’inflammation et impliquant dans certains cas également les cellules T CD8+, contribuait au maintien des fonctions effectrices des cellules T CD8+. / The immune system has evolved multiple mechanisms of peripheral tolerance to control CD8+ T cell responses. Under particular conditions that are not yet well understood, potentially autoreactive T cells may override tolerance and differentiate into effector cells capable of targeting the own components of the organism resulting in self-reactivity. Utilizing transgenic mice expressing a model antigen in the beta cells of the pancreas, I have studied two important processes involved in CD8+ T cells differentiation in response to self-antigens. 1) Role of lipopolysaccharides (LPS) translocation in the breakdown of CD8+ T cell tolerance. It has been previously shown in our laboratory that lymphodepleting protocols, such as total body irradiation, promote breakdown of peripheral CD8+ T cell tolerance. Irradiation induces translocation of commensal bacteria LPS, a potent innate immune system activator, into the bloodstream. My data demonstrated that LPS translocation correlated with systemic activation of CD11c+ dendritic cells (DC), in particular CD8+ DC, responsible for pancreatic self-antigen cross-presentation, in lymphoid tissue. While antibiotic treatment of mice before irradiation prevented LPS translocation, DC activation was only partially affected, and onset of autoimmunity and breakdown of CD8+ T cell tolerance could not be prevented.2) Intra-vital visualization of effector CD8+ and CD4+ T cell cooperation in beta cell destruction in the pancreas. Using two-photon microscopy, I have been able, for the first time, to simultaneously analyze dynamics of fluorescently tagged autoreactive CD8+ and CD4+ T cells as they infiltrated the pancreas and induced autoimmune diabetes. I found that T cell infiltration promoted extracellular matrix remodeling in the pancreas, which in turn served as a scaffold for T cell migration. In addition, I showed that MHC class II dependent arrest of effector CD4+ T cells, due to interactions with antigen presenting cells, occasionally also implicating CD8+ T cells, provided help to effector CD8+ T cells in maintaining their effector functions.

Tolérance immune

Auto-Immunité

Lymphocyte T CD8+

Lymphocyte T CD4+

Microscopie intra-Vitale

Immune Tolerance

Autoimmunity

CD8+ T cytotoxic cell

CD4+ T helper cell

Intra-Vital imaging

Adaptationen von T Helferlymphozyten an chronische Entzündungen

Chang, Hyun-Dong

29 March 2018

T-Helfer(Th)-Lymphozyten spielen aufgrund ihrer Expression von Zytokinen eine zentrale Rolle in der Regulation von Immunantworten. Durch die Zytokine fördern die Th-Zellen die Rekrutierung und Aktivierung von Zellen des angeborenen Immunsystems, den Immunglobulin-Klassenwechsel von B-Zellen und ihre Differenzierung zu antikörper-sezernierenden Plasmazellen. Welche Zytokine eine aktivierte Th-Zelle exprimiert hängt von instruktiven Signalen ab, die sie in der Regel von antigen-präsentierenden Signalen bekommt. Mit den instruktiven Signalen wird ein ganzes Differenzierungsprogramm in den Th-Zellen initiiert, welches am Ende zu einer epigenetischen Prägung des Effektorprogramms führt, sodass die Th-Zelle auch bei nachfolgenden Aktivierungen die gleichen Funktionen ausführt. In dieser Arbeit wurde untersucht wie diese Differenzierungsprogramme zur Pathogenese von chronischen Entzündungen beitragen und wie eine chronische Entzündung wiederum die Differenzierung der Th-Zellen beeinflusst. Des Weiteren haben wir molekulare Adaptationen identifiziert, die selektiv in chronisch aktivierten entzündungsfördernden Th Typ 1 (Th1)-Zellen hochgeregelt werden. Diese Adaptationen, wie die Expression von Twist1 und Hopx, fördern das Überleben der Th1-Zellen am Ort der Entzündung und könnten zur Perpetuation der Entzündung entscheidend beitragen. Zusammengenommen zeigen unsere Daten, dass Th-Zellen durch ihre pro-inflammatorische Prägung zwar gut gerüstet sind uns gegen Pathogene zu schützen, im Falle einer Autoreaktivität aber auch Immunpathologie und chronische Entzündungen auslösen können. Allerdings weisen unsere Arbeiten auch daraufhin, dass selektive Anpassungen der Th-Zellen an eine chronische Entzündung auch gleichzeitig Ansatzpunkte für ein therapeutisches Eingreifen bei chronisch-entzündlichen Krankheiten darstellen. / T helper (Th) lymhocytes play a central role in the regulation of immune responses. Through the expression of cytokines, Th cells orchestrate the recruitment and activation of cells of the innate immune system, and induce antibody class switch recombination in B lymphocytes and their differentiation into antibody-secreting plasma cells. Which cytokines an activated Th cell expresses is dependent on instructive signals, the Th cells receives from antigen-presenting cells. Such instructive signals initiate a differentiation program, which in the end leads to the epigenetic imprinting of the effector program, ensuring that the Th cell execute the same functions in subsequent activations. In this thesis, we investigated how such differentiation programs contribute to the pathogenesis of chronic inflammation and how chronic inflammation, in turn, affects the differentiation of the Th cells. Furthermore, we have identified molecular adaptations, which are selectively upregulated in chronically activated pro-inflammatory Th type 1 (Th1) cells. Such adaptations, like the upregulation of Twist1 and Hopx, promote the survival of Th1 cells in the inflamed tissue and could thereby contribute to the perpetuation of the inflammation. Taken together, our data show that Th cells with a pro-inflammatory imprint are well equipped to protect us against pathogens, in case of autoimmunity, however, cause immune pathology and chronic inflammation. At the same time, our work also shows that the selective adaptations of Th cells to chronic inflammation could also be promising targets for novel therapies for the treatment of chronic inflammatory diseases.

T Helferlymphozyten

chronische Entzündung

Zytokine

T-Zelldifferenzierung

T helper lymphocytes

chronic inflammation

cytokines

T cell differentiation

570 Biowissenschaften; Biologie

WF 9910

ddc:570

Dermatology for the Practicing Allergist: Tinea Pedis and Its Complications

Al Hasan, Muhannad, Fitzgerald, S. Matthew, Saoudian, Mahnaz, Krishnaswamy, Guha

29 March 2004

Tinea pedis is a chronic fungal infection of the feet, very often observed in patients who are immuno-suppressed or have diabetes mellitus. The practicing allergist may be called upon to treat this disease for various reasons. Sometimes tinea infection may be mistaken for atopic dermatitis or allergic eczema. In other patients, tinea pedis may complicate allergy and asthma and may contribute to refractory atopic disease. Patients with recurrent cellulitis may be referred to the allergist/immunologist for an immune evaluation and discovered to have tinea pedis as a predisposing factor. From a molecular standpoint, superficial fungal infections may induce a type2 T helper cell response (Th2) that can aggravate atopy. Th2 cytokines may induce eosinophil recruitment and immunoglobulin E (IgE) class switching by B cells, thereby leading to exacerbation of atopic conditions. Three groups of fungal pathogens, referred to as dermatophytes, have been shown to cause tinea pedis: Trychophyton sp, Epidermophyton sp, and Microsporum sp. The disease manifests as a pruritic, erythematous, scaly eruption on the foot and depending on its location, three variants have been described: interdigital type, moccasin type, and vesiculobullous type. Tinea pedis may be associated with recurrent cellulitis, as the fungal pathogens provide a portal for bacterial invasion of subcutaneous tissues. In some cases of refractory asthma, treatment of the associated tinea pedis infection may induce remission in airway disease. Very often, protracted topical and/or oral antifungal agents are required to treat this often frustrating and morbid disease. An evaluation for underlying immuno-suppression or diabetes may be indicated in patients with refractory disease.

allergy

antifungal agents

asthma

cellulitis

dermatitis

epidermophyton floccosum

IgE

immunity

Tinea Pedis

trichophyton mentagrophytes

trichophyton rubrum

type 2 T helper cytokines