L'immunité innée dans le diabète sucré

Simoni, Yannick

26 November 2013

Le diabète de type 1 (T1D) est une maladie auto-immune caractérisée par la destruction des cellules β du pancréas par les lymphocytes T auto-réactifs. Durant ma thèse, nous nous sommes intéressés au rôle des cellules de l'immunité innée dans le T1D à l'aide d'un modèle murin de la maladie : la souris NOD. Au contraire des cellules du système adaptatif (lymphocytes T et B), les cellules de l'immunité innée constituent la première ligne de défense de l'organisme lors d'une infection. Cette population est constituée entre autre de neutrophiles, cellules dendritiques plasmacytoïdes (pDC), macrophages, mais aussi de lymphocytes T et B non conventionnels tel que les cellules iNKT et B-1a. Précédemment, notre laboratoire a mis en lumière le rôle des lymphocytes iNKT dans le développement du T1D. Durant la première partie de ma thèse, nous avons démontré que les lymphocytes iNKT17, une sous-population des lymphocytes iNKT, ont un rôle délétère dans le T1D chez la souris NOD. Ces cellules infiltrent le pancréas et y produisent de l'IL-17, une cytokine pro-inflammatoire. Grâce à des expériences de transferts, nous avons mis en évidence que les lymphocytes iNKT17 exacerbent la maladie via la production d'IL-17. Dans la deuxième partie de ma thèse, nous nous sommes intéressés aux mécanismes qui induisent l'activation des lymphocytes T auto-réactifs. Nous avons observé chez la souris NOD, que la mort physiologique des cellules β conduit à l'activation de cellules de l'immunité innée : les neutrophiles, les lymphocytes B-1a et les pDC. La coopération entre ces cellules conduit à l'activation des pDC qui produisent de l'IFNα. Cette cytokine active les lymphocytes T auto-réactifs qui vont détruire les cellules β du pancréas. Nos résultats montrent que l'immunité innée est un acteur important dans la physiopathologie du diabète sucré.

Diabète

Diabète de type 1

Souris NOD

Lymphocytes T

NKT

MAIT

Obésité

Immunité innée

Optimisation de l'activité immunostimulatrice des lymphocytes T Natural Killer invariants : conséquences sur l'immunité anti-tumorale / Optimization of immune stimulatory activities of invariant Natural Killer T lymphocytes : consequences on anti-tumor responses

Ghinnagow, Reem

24 May 2017

Pour optimiser les stratégies vaccinales anti-tumorales, l’activation des cellules du système immunitaire inné est cruciale pour générer l’expansion des lymphocytes T spécifiques des antigènes tumoraux. Les lymphocytes T Natural Killer invariant (iNKT) représentent une famille unique de lymphocytes T innés ayant des propriétés immunomodulatrices puissantes. Ces cellules reconnaissent via leur récepteur T des antigènes glycolipidiques présentés par la molécule CD1d exprimée par les cellules présentatrices d’antigènes. L'alpha-galactosylcéramide (α-GalCer), un puissant activateur des cellules iNKT, est en développement clinique dans le cancer. Les cellules dendritiques (DCs) sont équipées pour activer les cellules iNKT and promouvoir de puissantes réponses immunitaires adaptatives. Considérant la capacité unique des DC CD8α+ à présenter de façon croisée les antigènes aux lymphocytes T CD8+, notre objectif a visé à délivrer l’α-GalCer (considéré ici comme un adjuvant) et des antigènes tumoraux aux DC CD8α+ dans le but de générer de puissantes réponses T cytotoxiques anti-tumorales. Pour cela, les antigènes ont été incorporés dans des nanoparticules de PLGA décorées à leur surface avec des anticorps anti-Clec9a, un marquer exprimé spécifiquement par les DC CD8α+. Nos résultats montrent chez la souris que la co-délivrance simultanée de l’α-GalCer et d’auto-antigènes tumoraux (Trp2 et gp100) aux DC CD8α+ promeut une forte réponse anti-tumorale dans un contexte prophylactique et thérapeutique. Nous démontrons que cet effet vaccinal est dû aux cellules iNKT (mais pas aux lymphocytes T auxiliaires) et aux lymphocytes T CD8+. L’efficacité vaccinale est corrélée à un rapport supérieur entre les lymphocytes T CD8+ spécifiques des antigènes tumoraux et les lymphocytes T CD4+ régulateurs au sein des tumeurs. Chez l’homme, la co-administration de l’α-GalCer et de l’antigène tumoral (Mélan A) aux DC BDCA3+ (les équivalents humains des DC CD8α+) induit une forte expansion des lymphocytes T CD8+ spécifiques du Mélan-A in vitro. Nos résultats montrent pour la première fois que la tolérance aux auto-antigènes tumoraux peut être levée en exploitant la fonction «helper» des cellules iNKT et mettent en évidence de nouvelles approches thérapeutiques contre le développement tumoral. / To optimize anti-tumor vaccine strategies, exploitation of cells of the innate immune system to assist the expansion of tumor antigen-specific T cells is of interest. Invariant Natural Killer T lymphocytes (iNKT) are a unique population of “innate-like” T cells endowed with potent immunomodulatory properties. These cells recognize through their T cell receptor glycolipids presented by the CD1d molecule expressed by antigen presenting cells. Alpha-galactosylceramide (α-GalCer), a potent iNKT cell activator, is in clinical development in cancer. Dendritic cells (DC) are well equipped to trigger iNKT cells activation and to promote adaptive immune responses. Regarding the unique ability of CD8α+ DCs to cross-present antigens to CD8+ T cell response, we intended to deliver α-GalCer (viewed here as an adjuvant) and tumor antigens to CD8α+ DCs with the aim to generate efficient antitumor cytotoxic T cells. To this end, antigens were incorporated in PLGA-based nanoparticles decorated with anti-Clec9a antibodies, a marker specifically expressed by CD8α+ DCs. Our results show (mouse system) that simultaneous co-delivery of α-GalCer and tumor selfantigens (Trp2 and gp100) to CD8α+ DCs promotes strong anti-tumor responses in prophylactic and therapeutic settings. We attributed the therapeutic effects of the vaccine to iNKT cells (but not to T-helper lymphocytes) and to CD8+ T lymphocytes. The efficacy was correlated with a high ratio of tumor antigen specific CD8+ T cells to CD4+ regulatory T lymphocytes infiltrating the tumor. In human, co-administration of α-GalCer and a tumor antigen (Melan A) to DC BDCA3+ (the human equivalent of CD8α+ DCs) strongly induces the expansion of Melan-A specific CD8+ T lymphocytes in vitro. Our results demonstrate that tolerance to self-antigens can be abrogated by manipulating the NKT cells’ helper functions and shed light on novel therapeutic approaches for controlling tumor development.

INKT

Cellules dendritiques

Nanoparticules

Alpha-GalCer

Lymphocte NKT

Vectorisation

CD8a+

BDCA3+

Α-GalCer

INKT cells

Invariant Natural Killer T lymphocytes

Nanoparticles

Design and Synthesis of TLR2 and TLR6 Heterodimer Ligands, a Triply Functionalized α-GalCer Derivative for Identifying Proteins Involved in Glycolipid Trafficking, and the Disaccharide of Staphylococcus aureus CP8 Towards a Self-Adjuvanting Vaccine

Mata, Sara Mayeth

01 July 2019

Toll like receptors (TLRs) are found on B cells, macrophages, monocytes, and dendritic cells, and these cells belong to the innate immune system that recognizes antigens and induces multiple cell responses through the release of cytokines. TLR1, TLR2 and TLR6 function as heterodimers, either as TLR1/TLR2 or TLR2/TLR6 to recognize lipopeptides. TLR1/2 dimer activation releases inflammatory cytokines, while TLR2/TLR6 dimer activation releases immunomodulatory cytokines. Based on the size of the binding pocket between TLR2 and TLR6, it was hypothesized that lipopeptides, such as FSL1, could be simplified while keeping overall activity. FSL1 is a lipopeptide first isolated from Mycoplasma salivarum that activates macrophages at picomolar concentrations. It is expected that synthetic lipopeptides mimicking immunostimulatory molecules such as FSL1 will allow development of better ways to stimulate or modulate the immune system. Therefore, novel synthetic TLR2/6 ligands were synthesized replacing the polylysine chain with a polyamine chain showing activation of the immune cells in a manner like FSL1. Natural killer T-cell (NKT) antigens, such as α-galactosylceramide (α-GalCer), are carried through the body by lipid transfer proteins before they interact with the NKT cells. Not all the proteins involved in glycolipid transportation have been characterized. The synthesis of an α-GalCer analogue, termed CD1d-Triceps was designed to help find additional proteins involved in glycolipid trafficking. CD1d-Triceps has three functionalities: the first is the α-GalCer structure, and the other two are on C6 of the sugar: biotin, which helps tag the molecule for its purification, and a photoactive tag that, upon UV light activation, will cross-link with neighboring proteins. Antibiotic-resistant strains of Staphylococcus aureus (SA) are a growing health problem worldwide. Serotype 5 and 8 are the most common SA pathogens. Loading the serotype 5 or 8 disaccharides onto Qβ-particles that are linked to an NKT cell activator yield a vaccine that is expected to trigger adaptive immunity to the disaccharide. Previous similar studies showed production of antibodies with high affinity against Streptococcus pyogenes oligosaccharides in a similar vaccine.

immune system

NKT cell

adjuvant

glycolipid

synthesis

organic

chemistry

immunology

trafficking

carbohydrate

TLR2

TLR6

ligand

Q-β particle

Staphylococcus A

serotype

disaccharide

vaccine

Physical Sciences and Mathematics

Úloha mutace genu LIF a relativní zastoupení NK buněk, NKT a T lymfocytů ve folikulární tekutině a krvi žen s různou anamnézou neplodnosti / The role of LIF gene mutations and the relative distribution of NK cells, NKT and T lymphocytes in follicular fluid and blood of women with different history of infertility

Křížan, Jiří

January 2011

Charles University in Prague Faculty of Natural Sciences Summary of Ph.D. thesis The role of LIF gene mutations and the relative distribution of NK cells, NKT and T lymphocytes in follicular fluid and blood of women with different history of infertility Jiří Křížan Prague 2010 1 | P a g e Doctoral degree programs in biomedicine Charles University in Prague and the Academy of Sciences of the Czech Republic Programme: Biomedicine Chairman of the Subject Board: Doc. RNDr. Vladimír Holáň, Dr.Sc. Place of study: Institute of Microbiology, v.v.i., Academy of the Czech Sciences Vídeňská 1083, 142 20 Prague 4 phone: +420 296 442 318 Autor: Mgr. Jiří Křížan Supervisor: RNDr. Petr Šíma, CSc. The dissertation can be found at Dean's Office Faculty of Charles University in Prague 2 | P a g e CONTENTS Contents 2 Summary 3 1. Introduction 5 2. Hypotheses and aims 6 3. Material and methods 7 Material: 7 Methods: 8 4. Results 10 5. Discussion 12 6. Conclusion 15 7. References 16 Bibliography of Autor: 18 1. papers in extenso (thesis background) 18 2. papers in extenso (without regard to thesis) 19 3 | P a g e SUMMARY The aim of the dissertation thesis "The role of LIF gene mutations and the relative distribution of NK cells, NKT, and T lymphocytes in follicular fluid and blood of women with different history of infertility"...

Lysosomal alpha-galactosidase A controls the generation of self lipid antigens for NKT cells

Darmoise, Alexandre F

04 March 2011

CD1 Moleküle spielen eine wichtige Rolle in der Lipidpräsentation und T-Zell-Aktivierung. CD1d fungiert als Restriktionselement für NKT-Zellen, eine T-Zell-Untergruppe, die nach Erkennung von Glykosphingolipide (GSL), IFN-gamma und IL-4 produziert. NKT Zellen steuern folglich anschliessende Immunantworten. Den meisten infektiösen Mikroorganismen mangelt es jedoch an GSL-Antigenen zur Stimulation von NKT-Zellen. Der Wirtsorganismus hat daher einen Mechanismus entwickelt, der die Aktivierung der NKT-Zellen dennoch gewährleistet. NKT-Zellen erkennen auch endogene GSL, die in dendritischen Zellen (DZ) infolge von Toll-like-Rezeptor (TLR)-Stimulation durch Pathogene produziert werden. Bislang war unklar, wie genau TLR-Aktivierung zur Produktion von Selbst-GSL-Antigenen führt. Ziel dieser Arbeit war es die Verknüpfung der beiden Prozesse aufzudecken. Diese Dissertation zeigt, dass alpha-Galaktosidase A (a-Gal A) als lysosomales Schlüsselenzym für den konstitutiven Abbau von Selbst-GSL-Antigenen in DZ fungiert. NKT-Zellen antworteten auf CD1d-restringierte Antigene, die von DZ, denen a-Gal A-Aktivität fehlte, präsentiert wurden. Ferner expandierten NKT-Zellen nach adoptiven Transfer in a-Gal A-defiziente Mäuse in Abhängigkeit von CD1d-Expression im Wirtsorganismus. Diese Arbeit zeigte auch, wie GSL-Antigene dem Abbau durch a-Gal A entkommen und für die NKT-Zell-Aktivierung bei Infektionen verfügbar werden. Unter normalen Bedingungen wurden die GSL durch a-Gal A abgebaut. TLR-vermittelte Signale führten jedoch zu Inhibierung der a-Gal A-Aktivität in DZ und resultierten somit in einer GSL-Akkumulation in den Lysosomen. Wir identifizierten einen neuen Regulationsmechanismus der NKT-Zell-Aktivierung bei Infektionen, der auf der Induktion von lysosomalen GSL-Antigenen durch TLR-vermittelte Hemmung der a-Gal A-Aktivität beruht. Diese Dissertation beantwortet fundamentale Fragen der NKT-Zell-Biologie und ebnet den Weg dieses System für therapeutische Ansätze zu nutzen. / CD1 molecules are pivotal for lipid presentation to T lymphocytes. Notably, CD1d functions as a restriction element for NKT cells, a T-cell lineage that produces IFN-gamma and IL-4 following recognition of glycosphingolipids (GSL). Consequently, NKT cells exert decisive regulatory functions on downstream immune responses. Most microbes potentially causing infection of the host lack GSL antigens to stimulate NKT cells. However, facing this challenge, the host developed a mechanism to ensure NKT-cell activation. This pathway exploits the property of NKT cells to react with self GSLs produced in dendritic cells (DCs) stimulated by pathogens through Toll-like receptors (TLR). How TLR engagement leads to production of self GSL antigens remains elusive. The aim of this study was to provide a mechanistic link between these two processes. Here, we identified alpha-galactosidase A (a-Gal A) as a key lysosomal enzyme required for constitutive degradation of self GSL antigens in DCs. Accordingly, NKT cells exposed to DCs lacking a-Gal A activity were activated in the context of CD1d-presented antigens. In addition, NKT cells underwent robust expansion upon transfer to a-Gal A-deficient mice that required CD1d expression by the host. This study further addressed the critical question as to how GSL antigens escape degradation by a-Gal A, and thus become available for presentation to NKT cells in infection. Accordingly, we found that TLR signaling targeted a-Gal A activity for negative regulation in DCs. Consequently, GSLs degraded by a-Gal A in steady-state conditions were induced in lysosomes. Based on these findings, we propose a new pathway that warrants the activation of NKT cells in infection by self GSL antigens induced through TLR-mediated inhibition of a-Gal A activity. Overall, this dissertation answers fundamental questions in the NKT field, and paves the way toward exploring this antigen presentation axis for therapeutic use.

Infektion

Antigenpräsentation

Antigenprozessierung

NKT Zelle

CD1d

Toll-like Rezeptor

Immunantwort

PAMP

Dendritische Zelle

Lipid

Enzym

alpha-Galaktosidase

Immunologie

infection

antigen presentation

antigen processing

CD1d

PAMP

immune response

NKT cell

Dendritic cell

lipid

Toll-like Receptor

enzyme

alpha-Galactosidase

Immunology

570 Biowissenschaften, Biologie

32 Biologie

WF 9895

ddc:570

In vitro test buněčné imunitní odpovědi pro diagnostiku Lymeské boreliózy / Lyme borreliosis diagnostics using in vitro cellular immune response testing

Prokopová, Tereza

January 2017

Lyme borreliosis is a multisystemic disease affecting skin, joints, heart and central nervous system. The disease is caused by spirochetes of Borrelia burgdorferi sensu lato complex. These bacteria are spread by ticks of Ixodes genus. In 2016 there were almost 4,000 newly infected individuals reported in the Czech Republic. Contemporary serological diagnostics of Lyme borreliosis is not sensitive nor specific enough and does not even correlate with the pathology of the disease in the early or late phases. For the correct diagnosis of the disease it is necessary to detect the pathogen and its genotype. For this reason we had aimed at two goals. Through the digital droplet PCR (ddPCR) method we detected Borrelia-specific DNA and its genotype. The detection limit of borrelial DNA was set on gDNA samples isolated from the tick. Detection threshold for the initial amount of 1 ng of tick gDNA is at the range of 10-17 g of specific borrelial DNA. Borrelia spp. coinfection was detected in 5 out of 12 tested samples. The most frequent type was B. garinii which was detected in 5 samples. On the basis of published sequences for virulent factors we have designed specific primers in conserved regions of the genes flanking their variable segments to be PCR amplified. Gene variability will be monitored through...

The influence of Toll-like receptors on murine invariant natural killer T cell activation

Villanueva, Alexander Ian

21 June 2013

Invariant natural killer T (iNKT) cells are a versatile subclass of T lymphocytes which recognize glycolipid antigens. iNKT cells are capable of rapidly producing a broad array of cytokines in response to stimulation; thus, they play an important role in the early regulation of a variety of immune responses. It was hypothesized that iNKT cells express functional Toll-like receptors (TLRs) and that stimulation of TLRs by their ligands modulates iNKT cells responses. In the first objective, it was revealed that upon stimulation with anti-CD3 monoclonal antibody and interferon (IFN)-α, expression of TLRs was enhanced in iNKT cells. Furthermore, stimulation of iNKT cells with TLR ligands led to a significant increase in the expression of several cytokines. In the second objective, the mechanisms behind the modulatory effects of the TLR9 ligand (CpG-ODN) on iNKT cells were determined. Altogether, these findings suggest a direct role for TLRs in iNKT cell activation. / Ontario Graduate Scholarship

immunology

NKT cells

innate immunity

Toll-like receptors

real-time PCR

ELISA

Western blot

flow cytometry

macrophage

cell lines

hybridoma

VSV

MAPK

MAPK phosphatase

DUSP1

CpG

T cells

natural killer cells

gene expression

Imunoterapie nádorů asociovaných s virem HPV16 a regulace protinádorové imunitní odpovědi / Immunotherapy of HPV16 - associated cancers and regulation of antitumour immune response

Štěpánek, Ivan

January 2013

The MHC class I status of tumour cells during immunotherapy is often underestimated. It represents one of important tumour escape mechanisms and thus can contribute to the failure of most of the cancer clinical trials that are usually based on the induction of cytotoxic T cell responses. Epigenetic changes in the promoters of genes involved in the MHC class I Ag presentation can result in decreased expression of the cell surface MHC molecules on tumour cells. Thus, epigenetic modifiers can restore an expression of the MHC class I molecules and make tumours visible to the CD8+ effector cells. Besides the epigenetic changes on the tumour cells, epigenetic modulators affect cells of the immune system such as dendritic cells (DC). Tumour cells can escape from the immune response not only by changes in the cancer cells, but also by influencing, expanding and/or activating immunoregulatory cell populations, such as regulatory T cells (Treg). This thesis focuses on the potential of the DC-based vaccines against HPV-16-associated tumours with a different MHC class I expression, on the combination of cancer immunotherapy with the treatment using epigenetic modifiers, with special attention paid to their effects on DC, and, finally, on the impacts of the anti-CD25 antibody (used for Treg elimination) on Treg and NKT...

Structure-Activity Studies of Glycosphingolipids as Antigens of Natural Killer T Cells

Goff, Randal Donald

26 July 2006

Glycosphingolipids (GSLs), composed of a polar saccharide head and a lipophilic ceramide tail, are ubiquitous components of the plasma membrane of eukaryotic cells. They serve in many regulatory capacities and have antigenic properties towards natural killer T (NKT) cells of the innate immune system. Critical to the recognition of glycosylceramides by NKT cells are antigen presenting cells (APC), such as dendritic cells, which are responsible for binding, processing, and delivery of ligands to these lymphocytes. This event is mediated by CD1d, a major histocompatibility complex-like protein expressed on the surface of APCs, which binds GSL antigens by the ceramide moiety and presents the polar group to the T cell receptors of CD1d-restricted cells. The subsequent immune response involves NKT cell proliferation and emission of numerous cytokines, such as interferon-gamma (IFN-gamma) and interleukin-4 (IL-4), resulting in the stimulation of the innate and adaptive immune systems through maturation of APCs, activation of T cells, and secretion of antibodies by B cells. To understand the structure-activity relationship between GSLs and NKT cell activity and the requirements for intracellular processing of antigens, analogs of the model compound alphaGalCer (KRN-7000) have been synthesized. These include fluorophore-appended 6”-amino-α-galactosylceramides and N-alkenoyl GSLs, such as PBS-57, a potent alphaGalCer surrogate useful in NKT cell stimulation studies. A nonantigenic beta-C-galactosylceramide has also been prepared as an inhibitor of these innate lymphocytes. To probe the potential for using NKT cells to bias the immune system between the proinflammatory TH1 response or the immunomodulatory TH2 mode, versions of alphaGalCer with shortened ceramides have been created. One of these truncated analogs, PBS-25, has successfully been cocrystallized with CD1d and the binary complex structure solved by X-ray crystallography. Synthetic glycosphingolipids derived from Novosphingobium capsulatum and Sphingomonas paucimobilis have also been made. In assays with classical Valpha14i/Valpha24i NKT cell lines, these Gram-negative bacterial antigens were recognized directly and specifically by host immune systems through CD1d-restriction, unlike GSL-deficient microbes (e.g., Salmonella typhimurium). A search for other GSL-bearing alpha-proteobacteria led to the discovery of another natural glycosphingolipid, an N-alkenoylphytosphingoid-alpha-galactoside, isolated from the outer membrane of Ehrlichia muris.

glycosphingolipid

GSL

natural killer T cell

NKT cell

alpha-galactosylceramide

ceramide

CD1d

glycolipid

Sphingomonas

Novosphingobium capsulatum

Sphingomonas paucimobilis

Ehrlichia

Ehrlichia muris

PBS-25

PBS-57

dendritic cell

DC

C-glycoside

aGalCer

KRN-7000

TH1

TH2

interferon-gamma

interleukin-4

synthesis

structure-activity relationship

Biochemistry

Chemistry