Brucella abortus RB51 vaccine: Testing its Spectrum of Protective and Curative Characteristics

Contreras Rojas, Andrea Paz

22 September 2004

Brucella abortus (BA) are gram-negative, facultative intracellular bacteria that cause abortions in cattle and debilitating illness in humans. The US is now virtually free of bovine brucellosis, but the disease is endemic in wildlife. The official brucellosis vaccine in the US is strain RB51 (RB51). It elicits protective cell-mediated immunity (CMI) against BA infections. Mycobacterium avium subspecies paratuberculosis (MAP) causes paratuberculosis in ruminants. It is a slow growing intracellular parasite that requires CMI for its control, belongs to the genus Mycobacterium, and is closely related to M. avium avium (MA). Using RB51 as a vector that induces strong protective CMI may be useful to protect against MAP if it expresses MAP protective antigens. Therefore, MAP 85A and 35kDa proteins were expressed at low levels in RB51, and the immune responses elicited by these vaccines in BALB/c mice were evaluated. Strong anti-Brucella immunity was generated, but the anti-mycobacterial response was low. To evaluate protective efficacy, a BALB/c model using MA was developed. When mice were challenged with MA, protection was obtained in some experiments but was inconsistent. This may be due to the low expression of MAP antigens in RB51. Another objective was to evaluate the effect of an ongoing Brucella-infection on the efficacy of RB51 vaccination, and whether vaccination of already infected animals could have a curative effect. Mice acutely or chronically infected with virulent BA, rapidly cleared the RB51 vaccine organisms, but there was no significant decrease in the number of virulent BA. Brucella spp. have been developed as biological weapons, but there are no vaccines to protect humans. The development of a very attenuated protective vaccine is necessary to prevent human infections, as well as to protect wildlife. To generate such a vaccine, RB51 based vaccines were irradiated to render them non-replicative, but metabolically active. We demonstrated that in general, irradiated and non-irradiated RB51 vaccines remain protective at levels similar to those elicited by the live vaccines. Therefore, irradiation of strain RB51 is an effective means of attenuating the strain without affecting its protective characteristics, and could eventually be used as a vaccine for wildlife and humans. / Ph. D.

vaccine

therapeutic

RB51

Brucella

overexpression

cytokine

curative

gamma irradiation

cell mediated immunity

recombinant

Mycobacterium

paratuberculosis

avium.

Les ligands du récepteur au CNTF dans le système immunitaire

Cognet, Isabelle

January 2006

Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.

"Cardiotrophin-like cytokine"

"Ciliary neurotrophic factor"

CNTF receptor [alpha]"

"Cytokine like factor 1"

Epstein-Barr virus induced gene 3"

Cytokine biotinylée

Cytokine de la famille IL6/12

Maladie neurodégénérative

Système immunitaire

Similarity and difference between systemic lupus erythematosus and NZB/W F1 mice by multi-omics analysis / マルチオミクス解析による全身性エリテマトーデスとNZB/W F1 マウスの類似性と相違性

大熊, 賢司

23 May 2024

京都大学 / 新制・論文博士 / 博士(医学) / 乙第13630号 / 論医博第2321号 / 新制||医||1074(附属図書館) / (主査)教授 伊藤 能永, 教授 浅野 雅秀, 教授 濵﨑 洋子 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM

Cytokine

Multi-omics

NZB/W F1 mouse

Systemic lupus erythematosus

Transcriptome

490

Regulation of human satellite cells in vitro via inflammatory cytokines and myogenic transcription factors across proliferation and differentiation

Lupi, Ryan Alexander

20 June 2019

Skeletal muscle is a primary contributor to body mass and whole-body energy metabolism. It is an adaptive tissue with the ability to fluctuate in size and mechanical properties in response to stimulus. Health conditions involving chronic elevated inflammation levels often feature metabolic inflexibility and losses in skeletal muscle mass. Mononuclear stem cells, termed satellite cells, are mitotic and serve to donate nuclei to muscle fibers to enable skeletal muscle adaptation. Despite the well-characterized nature of satellite cell activation, proliferation, and differentiation, the underlying mechanisms regulating this process is not fully understood. Recent characterization of cytokines secreted by skeletal muscle in an endocrine type fashion has led to discoveries of inflammatory cytokines influencing satellite cell function. However, how the autocrine production and secretion of these cytokines during proliferation and differentiation in humans and their correlation with myogenic transcription factors is not well understood. Our study used satellite cells cultured from the vastus lateralis of 12 male human research subjects, and ELISA analysis to measure levels of TNF-α and IL-6 across proliferation, early differentiation, and late differentiation. Additionally, mRNA levels of Pax7, MyoD, myogenin, IL-6, TNF-α, and TGF-β were assessed in satellite cells cultured from a subset of two endurance trained and two sedentary individuals from the larger group of 12 human subjects. The novelty of our study is the large number of human research subjects and simultaneous analysis of inflammatory cytokine secretion, mRNA inflammatory cytokine expression, and myogenic transcription factor mRNA expression. Results showed an 83% decrease in IL-6 protein secretion 24 hours after exposure to differentiation media (p-value <0.05) before increasing 50-fold after 7 day of exposure to differentiation media (p-value < 0.05). Myogenin and TGF-β mRNA expression levels were positively correlated (R2 = 0.5814, p-value < 0.0001). A negative correlation was found between IL-6 and MyoD (R2 = 0.2473, p – value = 0.0257). After 1 day of exposure to differentiation media, satellite cells from endurance trained subjects exhibited higher levels of TGF-β mRNA expression compared to sedentary satellite cells of sedentary subjects of the same age and levels of adiposity (p-value < 0.05). Results support a potential relationship in humans satellite cells between myogenic transcription factors and inflammatory cytokines, however, further study is necessary in order to investigate the underlying mechanisms behind the correlations. / Master of Science / Skeletal muscle is responsible for conscious, voluntary movement. In addition, the tissue is responsible for the majority of energy expenditure in the human body. Skeletal muscle is able to adapt to exercise programs through the fusion of undifferentiated stem cells – called satellite cells – in the skeletal muscle fiber. In long-term diseased conditions, the immune response involves chronic rises in inflammation and results in the loss of skeletal muscle and corresponding loss of ability to move. A shorter rise in inflammation is also linked with the positive exercise response. Our study features satellite cells harvested from muscle samples of 12 male human research participants. We were interested in evaluating the relationships between the expression and secretion of two proteins associated with inflammation and regulation of the satellite cell cycle. The two proteins of interest in our study are tumor necrosis factor alpha (TNF-α) and interleukin 6 (IL-6). We also measure the gene expression of another inflammatory protein, transforming growth factor beta (TGF-β). In order to know where the cells were in their life cycle, we measured expression of genes associated with the division (Pax7), early fusion (MyoD), and late fusion of satellite cells (myogenin). Our study found a decrease in IL-6 secretion and expression as the process of satellite cells turning into muscle fibers was initiated. Additionally, a 50-fold increase in IL-6 expression was found at day 7 compared to day 0 of the satellite cell cycle. Additionally, we found a positive correlation between TGF-β and myogenin and a negative correlation between IL-6 and MyoD. Although we found correlations between satellite cell cycle genes and inflammation genes, more research is necessary to see if there is a pathway causing this relationship.

skeletal muscle

humans

satellite cells

inflammation

inflammatory cytokine

Exercise

endurance training

Characterization of Influenza:Streptococcus pneumoniae synergistic disease and potential for disease alleviation via sphingolipid therapy

Gasser, Amanda Lynn

06 September 2013

Influenza A virus (IAV) is generally associated with the seasonal malady that causes brief respiratory illness during the winter months, known simply as "the flu." Most otherwise healthy individuals will suffer from mild fever, congestion, headaches and myalgia that are resolved within 5-7 days of onset. However, there are nearly 500,000 influenza-related deaths that occur world-wide every year. Many of these casualties and patients hospitalized with influenza also test positive for bacterial pneumonia, the most common agent being Streptococcus pneumoniae. Although all individuals are subject to this viral:bacterial synergistic disease, the young, elderly, and immunocompromised are the most susceptible. Previous studies have shown that viral infection creates a prolonged hyper-responsive pro-inflammatory state in the lungs, which increases susceptibility to secondary bacterial infection. Lethality is due to detrimental pulmonary damage from a dysregulated host inflammatory response, known as the "cytokine storm." However, the nature of dual infection has not been well-studied in the elderly demographic. Therefore, we aim to better define this disease synergy in an aged mouse model and explore potential therapeutic alternatives that could be beneficial for the aged and other vulnerable populations. Sphingolipid modulation has emerged as a potential target to ameliorate the excessive inflammation (cytokine storm) elicited by highly pathogenic influenza. There is particular emphasis on sphingosine 1-phosphate (S1P) signaling, as well as control of intracellular S1P levels via sphingosine kinases (SK). Sphingolipids are involved in a multitude of cellular processes, and are tightly regulated by their metabolizing enzymes. We hypothesize that manipulation of sphingolipid signaling and alteration of the internal sphingolipid milieu will diminish the inflammatory response elicited by IAV infection. Using fluorescence-activated cell sorting (FACS), real-time PCR and cytometric bead array (CBA) analysis, we evaluated the immunomodulatory effects of systemic sphingosine analog treatment within the lung microenvironment under homeostatic and influenza-infected conditions. FTY720 treatment caused transient, but significant lymphopenia, influx of neutrophils and efflux of macrophages in the lungs, which was enhanced during a mild influenza infectionGene expression in the lungs was generally unaltered, but protein levels showed increases in specific influenza-induced cytokines, suggesting these treatments may have post-transcriptional effects on cytokine expression. To evaluate sphingolipid modulation in specific pulmonary cell types, we next observed the effects of these compounds and sphingosine kinase (SK) inhibitors in epithelial and alveolar macrophage-like cell lines. SK inhibitors and Enigmol demonstrated anti-viral effects in A549 cells, decreasing viral loads by up to 1.5 logs. Real-time PCR and CBA analysis further demonstrated that these effects were associated with alterations in key cytokine expression, including CCL2, CCL5, CXCL10, IL-6, and IL-8. Collectively, these findings indicate that therapeutic sphingolipid modulation has the potential for creating a protective microenvironment in the lungs that could alleviate or even prevent viral:bacterial synergistic disease. / Master of Science

Influenza A virus

cytokine storm

immunomodulation

sphingosine 1-phosphate

FTY720

sphingosine kinase

Enigmol

Caractérisation d'une nouvelle cytokine composite formée de CLF et de la sous-unité p28 de l'IL-27

Guay-Giroux, Angélique

January 2007

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal.

Immunité

Syndrome de transpiration au froid

Interféron-y

Cytokine de la famille IL6/12

Cellules dendritiques

Locally Administered Particle-Anchored Cytokines Safely Enhance Cancer Immunotherapy

Niu, Liqian

16 May 2024

Cancer immunotherapy has long been proposed as a powerful approach to curing tumors, based on the natural function of the immune system in protecting its host with specificity, thus holding the potential for developing long-term memory that prevents tumor recurrence. However, the immunosuppressive feature of the tumor microenvironment prevents the patients' own immune system from functioning normally in the fight against cancer. As one of the most potent cancer immunotherapies, immunostimulatory cytokines have been shown to elicit anti-tumor immune responses in preclinical studies, but their clinical application is limited by severe immune-related adverse events upon systemic administration. None of the current delivery strategies can fully address issues of toxicities and sustainably supply cytokines over the course of a few days without compromising cytokines' structural integrity. Herein, we have developed a novel formulation to anchor potent cytokine molecules to the surface of large-sized particles (1 µm) for local cancer treatment. The cytokines are confined in tumors and have minimal systemic exposure over a few days following intratumoral injection, thereby eliciting anti-tumor immunity while avoiding the systemic toxicities caused by the circulating cytokines. Such particle-anchored cytokines can be synergistic with other immunotherapies, including immune checkpoint blockade antibodies and tumor antigens, to safely promote tumor regressions in various syngeneic tumor models and genetically engineered murine tumor models. / Doctor of Philosophy / Cancer immunotherapy is a promising method to treat cancer by harnessing the power of the body's immune system, which naturally fights off diseases and can remember and prevent diseases from returning. Unfortunately, cancers create a hostile environment that weakens the immune system's ability to combat the disease effectively. Among the treatments explored, immunostimulatory cytokines (unique proteins that boost the immune system) have shown great promise in laboratory studies for their ability to fight cancer. However, when these proteins are administered to patients, they can cause severe side effects due to their systemic dissemination throughout the body. Herein, by attaching the potent cytokines to large-sized particles (1 µm), and injecting them directly into the tumor, their cancer-fighting abilities are focused precisely where they are most needed. This targeted delivery minimizes the cytokines' presence in the rest of the body, dramatically reducing the risk of side effects associated with their systemic dissemination. This method not only shows promise on its own but also enhances the effectiveness of other cancer treatments. Our findings suggest a new, safer way to encourage the body's defense system to fight cancer more effectively.

Cancer immunotherapy

cytokine delivery

non-covalent anchoring

Fc-binding peptide

local combination therapy

Resistance Exercise and Alcohol: Combined Effects on Physiology and Performance

Levitt, Danielle E.

08 1900

Resistance exercise (RE) training is a well-known and effective method for promoting increases in muscle mass and strength. A single bout of RE induces physiological disturbances that require coordinated activation of the immune system and intramuscular signaling in order to return the tissue to homeostasis and adapt to the RE challenge. On the other hand, acute binge alcohol consumption can affect the immune response to an inflammatory challenge, intramuscular anabolic signaling, and muscle protein synthesis, and the effects of alcohol on these processes are opposite that of RE. Furthermore, individuals who report more frequent exercise also report a greater frequency of binge drinking. However, few investigations exist regarding the effects of binge alcohol consumed after a bout of RE on RE-induced physiological changes and performance recovery. Therefore, the overarching purpose of the investigations contained within this dissertation was to investigate the effect of alcohol consumed after RE on the RE-induced changes in mTOR pathway signaling, muscle protein synthesis, inflammatory capacity, strength recovery, and power recovery. Although RE increased mTOR pathway signaling and inflammatory capacity after exercise and reduced maximal strength and explosive power the day after exercise, we observed no effects of alcohol (1.09 g ethanol∙kg-1 lean body mass, designed to result in a peak blood alcohol concentration of approximately 0.12 g∙dl-1) consumed after RE on mTOR pathway signaling, 24-hour rates of muscle protein synthesis, inflammatory capacity, or strength and power recovery in resistance-trained individuals.

Binge drinking

mTOR

protein synthesis

cytokine

strength

power

Isometric exercise.

Studies on the exaggerated inflammatory response caused by streptococcus suis at systemic and central nervous system levels

Domínguez Punaro, María de la Cruz

04 1900

Streptococcus suis de type 2 est un microorganisme pathogène d’importance chez le porc. Il est la cause de différentes pathologies ayant comme caractéristique commune la méningite. C’est également un agent émergeant de zoonose : des cas cliniques humains ont récemment été rapportés en Asie. Cependant, la pathogénèse de S. suis n’est pas encore complètement élucidée. Jusqu’à présent, la réponse pro-inflammatoire initiée par S. suis n’a été étudiée qu’in vitro. L’étude du choc septique et de la méningite requiert toujours des modèles expérimentaux appropriés. Au cours de cette étude, nous avons développé un modèle in vivo d’infection chez la souris qui utilise la voie d’inoculation intra-péritonéale. Ce modèle a servi à l’étude de la réponse pro-inflammatoire associée à ce pathogène, tant au niveau systémique qu’au niveau du système nerveux central (SNC). Il nous a également permis de déterminer si la sensibilité aux infections à S. suis pouvait être influencée par des prédispositions génétiques de l’hôte. Le modèle d’infection par S. suis a été mis au point sur des souris de lignée CD1. Les résultats ont démontré une bactériémie élevée pendant les trois jours suivant l’infection. Celle-ci était accompagnée d’une libération rapide et importante de différentes cytokines pro-inflammatoires (TNF-α, IL-6, IL-12p40/p70, IFN-ɣ) et de chémokines (KC, MCP-1 and RANTES), qui ont entraîné un choc septique et la mort de 20 % des animaux. Ensuite, pour confirmer le rôle de l’inflammation sur la mortalité et pour déterminer si les caractéristiques génétiques de l’hôte pouvaient influencer la réponse inflammatoire et l’issue de la maladie, le modèle d’infection a été étendu à deux lignées murines consanguines différentes considérées comme résistante : la lignée C57BL/6 (B6), et sensible : la lignée A/J. Les résultats ont démontré une importante différence de sensibilité entre les souris A/J et les souris B6, avec un taux de mortalité atteignant 100 % à 20 h post-infection (p.i.) pour la première lignée et de seulement 16 % à 36 h p.i. pour la seconde. La quantité de bactéries dans le sang et dans les organes internes était similaire pour les deux lignées. Donc, tout comme dans la lignée CD1, la bactériémie ne semblait pas être liée à la mort des souris. La différence entre les taux de mortalité a été attribuée à un choc septique non contrôlé chez les souris A/J infectées par S. suis. Les souris A/J présentaient des taux exceptionnellement élevés de TNF-α, IL-12p40/p70, IL-1β and IFN- γ, significativement supérieurs à ceux retrouvés dans la lignée B6. Par contre, les niveaux de chémokines étaient similaires entre les lignées, ce qui suggère que leur influence est limitée dans le développement du choc septique dû à S. suis. Les souris B6 avaient une production plus élevée d’IL-10, une cytokine anti-inflammatoire, ce qui suppose que la cascade cytokinaire pro-inflammatoire était mieux contrôlée, entraînant un meilleur taux de survie. Le rôle bénéfique potentiel de l’IL-10 chez les souris infectées par S. suis a été confirmé par deux approches : d’une part en bloquant chez les souris B6 le récepteur cellulaire à l’IL-10 (IL-10R) par un anticorps monoclonal anti-IL-10R de souris et d’autre part en complémentant les souris A/J avec de l’IL-10 de souris recombinante. Les souris B6 ayant reçu le anticorps monoclonal anti-IL-10R avant d’être infectées par S. suis ont développé des signes cliniques aigus similaires à ceux observés chez les souris A/J, avec une mortalité rapide et élevée et des taux de TNF-α plus élevés que les souris infectées non traitées. Chez les souris A/J infectées par S. suis, le traitement avec l’IL-10 de souris recombinante a significativement retardé l’apparition du choc septique. Ces résultats montrent que la survie au choc septique dû à S. suis implique un contrôle très précis des mécanismes pro- et anti-inflammatoires et que la réponse anti-inflammatoire doit être activée simultanément ou très rapidement après le début de la réponse pro-inflammatoire. Grâce à ces expériences, nous avons donc fait un premier pas dans l’identification de gènes associés à la résistance envers S. suis chez l’hôte. Une des réussites les plus importantes du modèle d’infection de la souris décrit dans ce projet est le fait que les souris CD1 ayant survécu à la septicémie présentaient dès 4 jours p.i. des signes cliniques neurologiques clairs et un syndrome vestibulaire relativement similaires à ceux observés lors de méningite à S. suis chez le porc et chez l’homme. L’analyse par hybridation in situ combinée à de l’immunohistochimie des cerveaux des souris CD1 infectées a montré que la réponse inflammatoire du SNC débutait avec une augmentation significative de la transcription du Toll-like receptor (TLR)2 et du CD14 dans les microvaisseaux cérébraux et dans les plexus choroïdes, ce qui suggère que S. suis pourrait se servir de ces structures comme portes d’entrée vers le cerveau. Aussi, le NF-κB (suivi par le système rapporteur de l’activation transcriptionnelle de IκBα), le TNF-α, l’IL-1β et le MCP-1 ont été activés, principalement dans des cellules identifiées comme de la microglie et dans une moindre mesure comme des astrocytes. Cette activation a également été observée dans différentes structures du cerveau, principalement le cortex cérébral, le corps calleux, l’hippocampe, les plexus choroïdes, le thalamus, l’hypothalamus et les méninges. Partout, cette réaction pro-inflammatoire était accompagnée de zones extensives d’inflammation et de nécrose, de démyélinisation sévère et de la présence d’antigènes de S. suis dans la microglie. Nous avons mené ensuite des études in vitro pour mieux comprendre l’interaction entre S. suis et la microglie. Pour cela, nous avons infecté des cellules microgliales de souris avec la souche sauvage virulente (WT) de S. suis, ainsi qu’avec deux mutants isogéniques, un pour la capsule (CPS) et un autre pour la production d’hémolysine (suilysine). Nos résultats ont montré que la capsule était un important mécanisme de résistance à la phagocytose pour S. suis et qu’elle modulait la réponse inflammatoire, en dissimulant les composants pro-inflammatoires de la paroi bactérienne. Par contre, l’absence d’hémolysine, qui est un facteur cytotoxique potentiel, n’a pas eu d’impact majeur sur l’interaction de S. suis avec la microglie. Ces études sur les cellules microgliales ont permis de confirmer les résultats obtenus précédemment in vivo. La souche WT a induit une régulation à la hausse du TLR2 ainsi que la production de plusieurs médiateurs pro-inflammatoires, dont le TNF-α et le MCP-1. S. suis a induit la translocation du NF-kB. Cet effet était plus rapide dans les cellules stimulées par le mutant déficient en CPS, ce qui suggère que les composants de la paroi cellulaire représentent de puissants inducteurs du NF-kB. De plus, la souche S. suis WT a stimulé l’expression de la phosphotyrosine, de la PKC et de différentes cascades liées à l’enzyme mitogen-activated protein kinase (MAPK). Cependant, les cellules microgliales infectées par le mutant déficient en CPS ont montré des profils de phosphorylation plus forts et plus soutenus que celles infectées par le WT. Finalement, la capsule a aussi modulé l’expression de l’oxyde nitrique synthétase inductible (iNOS) induite par S. suis et par la production subséquente d’oxyde nitrique par la microglie. Ceci pourrait être lié in vivo à la neurotoxicité et à la vasodilatation. Nous pensons que ces résultats contribueront à une meilleure compréhension des mécanismes sous-tendant l’induction de l’inflammation par S. suis, ce qui devrait permettre, d’établir éventuellement des stratégies plus efficaces de lutte contre la septicémie et la méningite. Enfin, nous pensons que ce modèle expérimental d’infection chez la souris pourra être utilisé dans l’étude de la pathogénèse d’autres bactéries ayant le SNC pour cible. / Streptococcus suis serotype 2 is an important swine pathogen responsible for diverse infections, meningitis being its most striking feature. In addition, it is an emerging agent of zoonosis, which has gained worldwide attention due to important outbreaks in Asia. Understanding the pathogenesis of S. suis infections still represents a challenge. Up to present, the pro-inflammatory response due to S. suis has only been studied in vitro, and there is still a great need of appropriate experimental models for both septic shock and meningitis. In the present study, we successfully developed an in vivo model of S. suis infection in adult mice infected by the intraperitoneal route. This model served to investigate the pro-inflammatory events that take place at both the systemic and Central Nervous System (CNS) levels associated with this important pathogen. In addition, this model was useful to determine if susceptibility to S. suis infection may be influenced by the genetic background of the host. The mouse model of S. suis infection was standardized in CD1 mice. Results showed sustained bacteremia during the 3 days post-infection (p.i.), accompanied by a quick and substantial release of different pro-inflammatory cytokines (TNF-α, IL-6, IL-12p40/p70, IFN-ɣ) and chemokines (KC, MCP-1 and RANTES) that lead to septic shock and 20% mortality in mice. Once the hallmark of the septic phase of S. suis infection was established in CD1 mice, research continued with the objective to confirm the role of inflammation in mortality and to determine if the genetic background of the host may influence the inflammatory response toward this pathogen and the further outcome of the disease. For this, the mouse model of S. suis infection was used with two genetically different inbred mouse strains, this is, C57BL/6 (B6) and A/J mice, which are considered as the prototype of Th1-type and Th2-type mice, respectively. Results demonstrated a striking susceptibility to S. suis infection in A/J mice in comparison to B6 mice, with 100% mortality in the former mice strain at 20 h p.i., and 16 % mortality at 36 h p.i. for the latter. Very interestingly, and similarly to CD1 mice, bacteremia did not seem to be responsible for the death of mice, as both mice strains presented similar amounts of bacteria in blood and organs. Thus, it was postulated that the higher mortality in S. suis-infected A/J mice was due to uncontrolled septic shock. In fact, A/J mice presented very high levels of TNF-α, IL-12p40/p70, IL-1β and IFN-ɣ, that significantly exceeded those found in B6 mice. Remarkably, chemokine levels were similar between strains, suggesting their limited participation in the development of septic shock by S. suis. A greater survival of B6 mice was partially related to a better regulation of the pro-inflammatory cytokine cascade, as they showed a higher production of the anti-inflammatory cytokine IL-10 than A/J mice. The potential beneficial role of the IL-10 in mice infected with S. suis was confirmed using two approaches: the first, by blockage of the cell receptor of IL-10 (IL-10R) with an anti-mouse IL-10R monoclonal antibody (Mab) in B6 mice and the second by administrating recombinant mouse (rm)IL-10 (rmIL-10) to A/J mice. B6 mice that received the IL-10R MAb treatment before challenge with S. suis developed a clinical acute disease similar to that observed with A/J mice, with a striking and rapid increase in mortality and higher levels of TNF-α in comparison to those of infected mice that did not receive the treatment. Controversially, treatment with rmIL-10 significantly delayed the onset of septic shock in A/J mice infected with S. suis. These results show that survival from S. suis septic shock requires a tight regulation of pro- and anti-inflammatory mechanisms, and that the latter should be activated at the same time or soon after the onset of the pro-inflammatory response. This part of the study may represent a first step in the identification of host genes associated with resistance against S. suis. One of the most important achievements of the mouse model of infection described in this project is the development of distinct clinical signs of neurological disease in CD1 mice from 4 days p.i. Indeed, in CD1 mice that survived sepsis due to S. suis infection, clinical signs of neurological disease and vestibular syndrome, which are quite similar to those observed in clinical cases of S. suis meningitis in both pigs and humans, were observed. Studies of the brains of infected CD1 mice using in situ hybridization combined with immunocytochemistry, demonstrated that the CNS inflammatory response began with a significant increase in the transcription of Toll-like receptor (TLR)2 and CD14 initially in the brain microvasculature and choroid plexuses, suggesting that S. suis may use these structures as portals of entry to the brain. There also was activation of NF-κB (as indicated by transcriptional activation of IκBα as a reporter system) and TNF-α, IL-1β and MCP-1, mainly in cells identified as microglia and to a lesser extent in astrocytes. These signals reached different brain structures, mainly the brain cortex, corpus callosum, hippocampus, choroid plexuses, thalamus, hypothalamus and meninges. All of these pro-inflammatory events were associated with extensive areas of inflammation and necrosis, severe demyelination and presence of antigens of S. suis inside microglia. In vitro studies were conducted in order to better understand the interactions of S. suis and microglia. For this, mouse microglia were infected with a virulent wild type (WT) strain of S. suis. Two isogenic mutants deficient in capsule (CPS) or hemolysin production (suilysin, SLY) respectively, were also included for comparative purposes. The CPS was important for S. suis resistance to phagocytosis, and it also modulated the inflammatory response by hiding pro-inflammatory components from the bacterial cell wall. On the other hand, the absence of SLY, a potential cytotoxic factor, did not have a major impact on S. suis interactions with microglia. Studies with microglia helped to confirm previous findings in vivo in mice, as the WT S. suis strain induced the up-regulation of TLR2 and the production of several pro-inflammatory mediators, including TNF-α and MCP-1. As observed in mice, S. suis induced NF-kB translocation, which was more rapid for cells stimulated with the CPS-deficient mutant, suggesting that bacterial cell wall components are potent inducers of NF-kB. Moreover, WT S. suis promoted phosphotyrosine, PKC and different mitogen-activated protein kinase (MAPK) events. However, microglia infected with the CPS-deficient mutant showed overall stronger and more sustained phosphorylation profiles. Finally, the CPS also modulated S. suis-induced inducible nitrogen oxide synthase (iNOS) expression and further nitric oxide production in microglia, which could be related to neurotoxicity and vasodilatation in vivo. We are confident that our results may help to more fully understand the mechanisms underlying S. suis induction of inflammation, leading to the design of more efficient anti-inflammatory strategies for sepsis and meningitis. Finally, we believe this experimental model of infection in mice could also be useful for studying the pathogenesis of infections of the CNS, due to other bacteria.

Streptococcus suis

mouse

sepsis

meningitis

inflammation

cytokine

chemokine

microglia

TLR2

MAPK

Streptococcus suis

souris

sepsis

méningite

inflammation

cytokine

chemiokine

microglia

TLR2

MAPK

La génotoxicité des quantum dots et le rôle du stress oxydant : implications sur l'environnement et la santé humaine / Genotoxicity of quantum dots and the role of oxidative stress : implications for the environment and human health

Aye-Baratier, Mélanie

15 November 2013

Les quantum dots (QDs) sont des cristaux semi-conducteurs de dimensions nanométriques. Ils peuvent être employés comme des marqueurs photosensibles du métabolisme cellulaire et peuvent être utiles dans différents domaines notamment en médecine mais il s’est rapidement avéré nécessaire de démontrer leur innocuité avant leur utilisation à grande échelle et leur diffusion dans l’environnement. Nous proposons un projet de thèse de doctorat sur le thème : La génotoxicité des quantum dots et le rôle du stress oxydant, implications sur l’environnement et la santé humaine. Il s’organise suivant trois axes: L’étude in vitro des propriétés génotoxiques et mutagènes des QDs Les QDs induisent des lésions primaires de l’ADN sur cellules CHO-K1 par le test des comètes qui sont associées à un stress oxydant. Ils sont plus actifs après irradiation par le spectre solaire. Ils induisent des mutations chromosomiques. L’étude in vivo des propriétés génotoxiques et mutagènes des QDs Les QDs induisent une augmentation significative des lésions de l'ADN chez le rat qui varie selon l’organe considéré (foie, rein, poumon, cerveau et testicule). Ils induisent une augmentation significative et une réponse dose-dépendante des micronoyaux indiquant nettement leur pouvoir clastogène/aneugène. Aucune variation significative des variables biochimiques mesurées n’est apparue. La mise en évidence de leurs effets sur l’environnement L'exposition aux QDs et au CdCl2 a entraîné une augmentation significative des lésions de l'ADN chez E. fetida et N. diversicolor. / Quantum dots (QDs) are semiconductor nanocrystals which can be employed as sensitive biomarkers of cellular metabolism and thus show their usefulness in various fields, including medicine and it soon became necessary to prove their safety before their widespread use and their distribution in the environment. The thesis project targeted on: Genotoxicity of quantum dots and the role of oxidative stress implications for the environment and human health. This study was organized in three main parts The in vitro study of the genotoxic and mutagenic properties of QDs QDs induced primary DNA lesions in CHO-K1 cells using the comet assay and were associated with oxidative stress. We demonstrated that the QDs were more active after irradiation by the solar spectrum. We showed the ability of QDs to induce chromosomal mutations. The main mechanism was probably that of the production of free radicals. The in vivo study of the genotoxic and mutagenic properties of QDs The comet assay shows that QDs induced an overall significant increase in DNA lesions of different organs (liver, kidneys, lungs, brain and testes). However, each organ had a specific susceptibility. QDs induced a significant increase in a dose-dependent manner of micronuclei. These results clearly indicated the in vivo clastogenic / aneugenic properties of QDs. No significant variation in the measured biochemical variables. The evidence of their effects on the environment Evaluation of genotoxicity was performed on coelomocytes of E. fetida and N. diversicolor resulting in a significant increase in DNA damage.