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Papel protetor da quinase ativada por adenosina monofosfato (AMPK) na progressão e severidade da nefrite tubulointersticial experimental. / Protective role of adenosine monophosphate activated kinase (AMPK) on the progression and severity of experimental tubulointerstitial nephritis.Macêdo, Marina Barguil 12 September 2017 (has links)
Objetivamos investigar o papel da quinase ativada por adenosina monofosfato (AMPK) na doença renal crônica. Induzimos nefrite túbulo-intersticial (NTI) em camundongos C57BL/6 e LyzM-cre AMPKflox/flox através de ração com adenina, e tratamos com metformina (Met) 200 mg/kg/dia. Avaliamos ainda o efeito da Met sobre a transição epitélio-mesenquimal (TEM) em células tubulares epiteliais renais murinas (linhagem MM55.K). Os C57BL/6 tratados apresentaram preservação da função renal; maior frequência de macrófagos (MØ) M1, em detrimento dos M2; e redução de marcadores de fibrose. Os LyzM-cre AMPK-/- não diferiram dos LyzM-cre AMPK+/+ quanto à intensidade da lesão, por a molécula já se encontrar infrarregulada na NTI. Contudo, ao serem tratados com Met, os LyzM-cre AMPK+/+ evoluíram melhor do que os não tratados, o mesmo não se verificando nos LyzM-cre AMPK-/-, sugerindo que a ação da Met nos MØ é dependente de AMPK. As MM55.K, após estímulo com Met, exibiram maior captação de glicose, expressão do transportador Glut-2, ativação da glicólise, e resistência à TEM. / We aimed to investigate the role of adenosine monophosphate activated kinase (AMPK) on chronic kidney disease. We induced tubulointerstitial nephritis (TIN) in C57BL/6 and LyzM-cre AMPKflox/flox mice by feeding them adenine diet, and then treating with metformin (Met) 200 mg/kg/day. We also evaluated the effect of Met on epithelium-to-mesenchyma transition (EMT) of murine epithelial renal tubular cells (lineage MM55.K). Met-treated C57BL/6 mice presented preserved kidney function, greater frequency of M1 macrophages (MØ) compared to M2 ones, and reduced markers of fibrosis. Disease severity on LyzM-cre AMPK-/- and AMPK+/+ mice did not differ, since the molecule was already downregulated on TIN. However, by treating them with Met, LyzM-cre AMPK+/+ improved in comparison to the non-treated mice. The same did not happen with LyzM-cre AMPK-/- mice, suggesting that Met effect on MØ is AMPK-dependent. MM55.K cells, after stimulus with Met, showed increased glucose uptake, greater expression of the transporter Glut-2, activation of glycolysis, and resistance to EMT.
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The role of macrophage intracellular lipid partitioning in glucose and lipid homeostasis during obesityPetkevicius, Kasparas January 2019 (has links)
Obesity-associated metabolic disorders are amongst the most prevalent causes of death worldwide. Understanding how obesity leads to the development of the Metabolic Syndrome (MetS) and cardiovascular disease (CVD) will enable the development of novel therapies that dissociate obesity from its cardiometabolic complications. Our laboratory views the functional capacity of white adipose tissue (WAT), the organ designed for safe lipid storage, as a key factor in the development of MetS and CVD. At a genetically-defined stage of the aberrant WAT expansion that occurs during obesity, adipocytes undergo a functional failure, resulting in an impaired control of serum free fatty acid (FFA) concentration. In such setting, FFAs and their metabolic derivatives accumulate in other organs, where they cause lipotoxicity, leading to the development of insulin resistance and CVD. We therefore aim to understand the pathophysiological mechanisms that induce adipocyte dysfunction. The past two decades of research have established the immune system as an important regulator of WAT function. The number of adipose tissue macrophages (ATMs), the most abundant immune cell type in WAT, increases during obesity, resulting in WAT inflammation. Multiple genetic and pharmacological intervention studies of murine models of obesity have assigned a causal link between ATM pro-inflammatory activation and WAT dysfunction. However, while the propagation of inflammation in ATMs during obesity has been extensively studied, factors triggering ATM inflammatory activation are less clear. Recently, our lab has observed lipid accumulation in the ATMs isolated from obese mice. Lipid-laden ATMs were pro-inflammatory, leading us to hypothesise that aberrant lipid build-up in macrophages triggers WAT inflammation during obesity. This thesis expands on the initial findings from our lab and describes two novel mechanisms that potentially contribute to lipid-induced inflammatory activation of ATMs. In chapter 3, the role of de novo phosphatidylcholine (PC) synthesis pathway during lipotoxicity in macrophages is addressed. The first part of the chapter demonstrates that lipotoxic environment increased de novo PC synthesis rate in bone marrow-derived macrophages (BMDMs) and ATMs, and that loss of rate-limiting enzyme in de novo PC synthesis pathway, CTP:phosphocholine cytidylyltransferase a (CCTa) diminished saturated FFA-induced inflammation in BMDMs. In the second part, I show that macrophage-specific CCTa deletion did not impact on the development of WAT inflammation or systemic insulin resistance, but had a minor benefitial effect on hepatic gene transcription during obesity. Chapter 4 develops on recent observations of interactions between sympathetic nerves and macrophages in WAT. In the first part of the chapter, I demonstrate that stimulating B2-adrenergic receptor (B2AR), the main receptor for sympathetic neurotransmitter norepinephrine in macrophages, enhanced intracellular triglyceride storage by up-regulating diacylglycerol O-acyltransferase 1 (Dgat1) gene expression in BMDMs. The second part of the chapter shows that macrophage-specific B2AR deletion did not modulate systemic glucose and lipid metabolism during obesity, but mice lacking B2ARs in macrophages demonstrated augmented hepatic glucose production on a chow diet. Furthermore, systemic B2AR blockade or macrophage-specific B2AR deletion in mice did not affect the thermogenic response to cold exposure. Chapter 5 includes the characterisation of B2AR stimulation-induced changes to the global cellular proteome of BMDMs, and a subsequent validation of the role of candidate transcription factors in regulating B2AR agonism-induced gene expression in BMDMs.
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Régulation immunométabolique du macrophage : potentiel anti-inflammatoire des ligands du CD36 dans le traitement de la dégénérescence maculaire liée à l’âgeMellal, Katia 05 1900 (has links)
La dégénérescence maculaire liée à l’âge (DMLA), une maladie neurodégénérative de la rétine, est considérée comme la principale cause de perte de vision chez les personnes âgées. Le CD36 est un récepteur éboueur (scavenger) exprimé à la surface des phagocytes mononucléés et de l’épithélium pigmentaire rétinien (EPR), qui agit également comme corécepteur de l’hétérodimère des récepteurs de type Toll-like (TLR) 2/6 dans l’induction de l’inflammation. Dans la DMLA, l’activation du CD36 favorise l’internalisation des lipides oxydés par les cellules de l’EPR, le recrutement et l’accumulation des phagocytes mononucléés (microglie, monocytes/macrophages), ainsi que l’induction de la réponse inflammatoire au niveau sous-rétinien. L’identification du CD36 comme récepteur de peptides synthétiques de la famille des sécrétines de l’hormone de croissance (GHRPs) par notre laboratoire, nous a conduit au développement de ligands plus sélectifs pour ce récepteur, qui ont été étudiés dans le contexte des maladies inflammatoires chroniques liées aux macrophages telle que l’athérosclérose. Étant donné les similitudes observées entre la pathologie de l’athérosclérose et de la DMLA, nous avons émis l’hypothèse selon laquelle les azapeptides, comme ligands du CD36, auraient des effets protecteurs contre la DMLA en modulant la réponse inflammatoire. Ainsi, l’objectif général de ce projet de doctorat était d’évaluer les effets anti-inflammatoires et immunomodulateurs des azapeptides, comme ligands du CD36, et d’élucider leurs mécanismes d’action au niveau des macrophages ainsi que dans des modèles murins de DMLA.
Le premier objectif spécifique de cette thèse était de déterminer l’effet de l’azapeptide MPE-001 dans la modulation de la réponse inflammatoire cellulaire médiée par le TLR2 et les voies de signalisation associées. Pour ce faire, des macrophages péritonéaux de souris C57BL/6 ou déficientes en Cd36 (Cd36-/-) ont été stimulés avec des agonistes du TLR2. Le traitement avec le MPE-001 a induit une diminution significative de la production de cytokines pro-inflammatoires, tels que le TNFa, l’IL-6, l’IL-12 et l’IL-1b et la chimiokine CCL2, de même qu’une inhibition des voies de signalisation nuclear factor kB (NFkB), c-Jun N-terminal kinase (JNK) et P38. Ce premier objectif nous a permis de mettre en évidence les effets anti-inflammatoires du MPE-001 et son mécanisme d’action, en modulant la réponse inflammatoire médiée par l’hétérodimère TLR2/6.
Afin de déterminer les effets du MPE-001 sur la modulation de la réponse inflammatoire chez un modèle murin de DMLA, les souris C57BL/6, Cd36-/-, Cx3Cr1-/- et Cx3Cr1-/-/Cd36-/- ont été soumises à un stress photo-oxydatif induit par la lumière bleue pendant 5 jours. Une journée après le début de l’illumination, les souris ont reçu une injection s.c. de MPE-001 répétée pendant 7 jours. Le modèle murin de Cx3Cr1-/- est connue pour exacerber la réponse inflammatoire et induire l’accumulation de phagocytes mononucléés, plus particulièrement les microglies dans la rétine. Les montages à plat des coupes des yeux prélevés ont montré que le traitement au MPE-001 a engendré une diminution importante de 60% de l’accumulation de phagocytes mononucléés dans l’espace sous-rétinien, de même qu’une diminution des marqueurs inflammatoires (iNOS, IL-12), ainsi que la préservation de l’intégrité et de la fonction des photorécepteurs. Ce deuxième objectif nous a permis de démontrer les effets in vivo du MPE-001, en entraînant une diminution de l’accumulation de phagocytes mononucléés sous-rétiniens et la préservation des photorécepteurs.
Étant donné les effets inhibiteurs du MPE-001 sur la sécrétion d’IL-1b, notre troisième objectif était d’investiguer l’effet du MPE-001 sur la régulation de l’inflammasome au niveau des macrophages. Nous avons montré que le MPE-001 entraînait une diminution de la réponse inflammatoire en inhibant la sécrétion d’IL-1b au niveau des macrophages, tout en diminuant l’expression de nucleotide-binding domain leucin-rich repeat and pyrin-containing receptor 3 (NLRP3) et de la caspase-1. Ce troisième objectif nous a permis de montrer que le MPE-001 a modulé le profil inflammatoire des macrophages en atténuant l’inflammasome NLRP3.
Étant donné que le phénotype des macrophages est régulé par leur métabolisme, notre 4e et dernier objectif était de déterminer si les effets anti-inflammatoires du MPE-001 pouvaient influencer la polarisation des macrophages. Pour ce faire, nous avons utilisé un modèle de bone marrow-derived macrophages (BMDM) induits en phénotype pro-inflammatoire M1 ou anti-inflammatoire M2. Bien que le MPE-001 n’ait eu aucune influence sur les marqueurs de surfaces phénotypiques, nous avons montré que ce dernier induisait un changement métabolique des macrophages pro-inflammatoires M1, en inhibant la glycolyse et en favorisant la phosphorylation oxydative, de façon dépendante du récepteur nucléaire peroxisome proliferator-activated receptor-γ (PPAR-γ).
En conclusion, les travaux de cette thèse ont montré que l’azapeptide MPE-001 possède de puissants effets anti-inflammatoires et immunomodulateurs au niveau des macrophages dans un contexte d’inflammation rétinienne, pouvant constituer une nouvelle approche thérapeutique prometteuse pour le traitement de la DMLA. / Age-related macular degeneration (AMD), a neurodegenerative disease of the retina, is considered to be the main cause of vision loss in the elderly. CD36 is a scavenger receptor expressed on the surface of mononuclear phagocytes and retinal pigment epithelium (RPE), which also acts as a co-receptor for the Toll-like receptor (TLR)-2/6 heterodimer in the induction of inflammation. In AMD, CD36 activation promotes the internalization of oxidized lipids by RPE cells, the recruitment and accumulation of mononuclear phagocytes (microglia, monocytes / macrophages), as well as the induction of the inflammatory response at the subretinal level. The identification of CD36 as a receptor for synthetic peptides of the growth hormone releasing-peptides (GHRP) by our laboratory, led us to the development of more selective ligands for this receptor, which have been studied in the context of chronic inflammatory diseases related to macrophages such as atherosclerosis. Given the similarities observed between the pathology of atherosclerosis and AMD, we hypothesized that azapeptides, as CD36 ligands, protect against AMD by modulating the inflammatory response. Thus, the general objective of this doctoral project was to characterize the anti-inflammatory and immunomodulatory effects of azapeptides, as CD36 ligands, and to elucidate their mechanisms of action on macrophages as well as in murine models of AMD.
The first specific objective of this thesis was to determine the effect of the azapeptide MPE-001 in the modulation of the cellular TLR2-mediated inflammatory response and the associated signaling pathways. To do so, peritoneal macrophages from C57BL/6 or Cd36-deficient (Cd36-/-) mice were stimulated with TLR2 agonists. Treatment with MPE-001 induced a significant decrease in the production of pro-inflammatory cytokines, such as TNFa, IL-6, IL-12 and IL-1b and the chemokine CCL2, as well as inhibition of the nuclear factor k B (NF kB), N-terminal c-Jun kinase (JNK) and P38 signaling pathways. This first objective allows us to highlight the anti-inflammatory effects of MPE-001 and its mechanism of action, by modulating the inflammatory response mediated by the TLR2/6 heterodimer.
In order to determine the effects of MPE-001 on the modulation of the inflammatory response in a mouse model of AMD, the murine models C57BL/6, Cd36-/-, Cx3Cr1-/- and Cx3xr1-/-/Cd36-/- were subjected to photo-oxidative stress induced by blue light for 5 days. One day after the start of illumination, the mice received a repeated s.c. injection of MPE-001 for 7 days. The mouse model of Cx3Cr1-/- is known to exacerbate the inflammatory response and induce the accumulation of mononuclear phagocytes, more specifically microglia, in the retina. Flat mounts from collected eyes showed that MPE-001 treatment caused a significant 60% decrease in the accumulation of mononuclear phagocytes in the subretinal space, as well as a reduction in inflammatory markers (iNOS, IL-12), with the preservation of photoreceptor integrity and function. This second objective allows us to demonstrate the in vivo effects of MPE-001, leading to a decrease in the accumulation of sub-retinal mononuclear phagocytes and the preservation of photoreceptors.
Given the inhibitory effects of MPE-001 on IL-1b secretion, our third objective was to investigate the effect of MPE-001 on inflammasome regulation in macrophages. We have shown that MPE-001 decreases the inflammatory response by inhibiting the secretion of IL-1b in macrophages, while decreasing the expression of nucleotide-binding domain leucin-rich repeat and pyrin-containing receptor 3 (NLRP3) and caspase-1. This third objective allows us to show that MPE-001 modulates the inflammatory profile of macrophages by attenuating the NLRP3 inflammasome.
Since macrophage phenotypes are regulated by their metabolism, our fourth and final objective was to determine whether the anti-inflammatory effects of MPE-001 could influence the polarization of macrophages. To do so, we used a bone marrow-derived macrophages (BMDM) model induced to pro-inflammatory M1 or anti-inflammatory M2 phenotype. Although MPE-001 had no influence on phenotypic markers, we have shown that the latter induces a metabolic shift of the pro-inflammatory M1 macrophages, by inhibiting glycolysis and promoting oxidative phosphorylation of macrophages, in a peroxisome proliferator-activated receptor-γ (PPAR-g)-dependent manner.
In conclusion, the work conducted in this thesis showed that the azapeptide MPE-001 has powerful anti-inflammatory and immunomodulatory effects on macrophages in a context of retinal inflammation, which could constitute a promising new therapeutic approach for the treatment of AMD.
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Molecular Mechanisms of Immunometabolic Dysfunction in Multiple SclerosisTänzer, Aline 19 September 2019 (has links)
Multiple Sklerose (MS) ist eine chronische neuro-degenerative Erkrankung des zentralen Nervensystems, die durch auto-immun-bedingte Prozesse charakterisiert ist. T Zellen wurden als wesentliche pro-inflammatorische Mediatoren mit der Pathogenese der MS assoziiert. In gesunden Individuen passen Immunzellen ihren Metabolismus, wie die mitochondriale Atmung und Glykolyse, ihrer jeweiligen Funktion und ihrem inflammatorischen Phänotyp an. Im Krankheitsverlauf der MS ist die Bedeutung der metabolischen Anpassung und der damit verbundenen pro-inflammatorischen Mechanismen von T Zell-Subpopulationen noch nicht eindringlich erforscht. Um dieser Fragestellung nachzugehen wurden Relapsing Remitting MS (schubförmig, RRMS) Patienten und sorgfältig aufeinander abgestimmte gesunde Kontrollprobanden als Teil der Studie Depression und Immunfuktion bei MS rekrutiert (n=62). Den Patienten und gesunden Kontrollprobanden wurde Nüchternblut entnommen, woraus periphäre mononukleäre Blutzellen (PBMC) aufgearbeitet wurden, um anschließend CD4+ und CD8+ T Zellen zu isolieren. Die erzielten Ergebnisse zeigten CD4+ T Zell-spezifische Verringerungen der mitochondrialen Atmung und glykolytischen Aktivität in der MS Patienten Kohorte im Vergleich zur Kohorte der gesunden Kontrollprobanden. Darüberhinaus wurden, zusätzlich zu den umfangreichen phänotypischen Charakterisierungen der PBMCs via Durchflußzytometrie, erhöhte Werte des mitochondrialen Membranproteins CPT1a in CD4+ T Zell-Subpopulationen in der MS Patienten Kohorte detektiert. Die Analyse der CD4+ CD25- CD127+ konventionellen T Zell- Subpopulation ergab leicht erniedrigte Werte von IL7-Rα in MS Patienten. Genexpressionsanalysen, die mit pro-inflammatorischen und metabolischen Genen assoziiert sind, ergaben keine Veränderungen in den T Zell-Subpopulationen der MS Patienten. Die in dieser Studie erzielten Ergebnisse weisen auf Funktionsstörungen bei der metabolischen Anpassung in T-Zell-Subpopulationen bei MS Patienten hin und helfen, den Beitrag des Immunmetabolismus bei der Pathogenese der MS Erkrankung besser zu verstehen. / Multiple Sclerosis (MS) is a chronic neurodegenerative disease of the central nervous system characterized by autoimmune-mediated mechanisms. T cells have been associated as central pro-inflammatory mediators in MS pathogenesis. In healthy individuals, immune cells adapt metabolic programs like mitochondrial respiration and glycolysis based on their function and inflammatory phenotype. However, the relevance of metabolic reprogramming and associated pro-inflammatory mechanisms in T cell subpopulations in MS disease is not well understood yet. To address this question, Relapsing Remitting MS (RRMS) patients and meticulously matched healthy control (HC) participants were recruited as part of the clinical study Depression and Immune Function in MS (n=62). Blood samples, after a period of fasting, were collected and CD4+ and CD8+ T cells isolated from peripheral blood mononuclear cells (PBMC). The results obtained demonstrated decreased mitochondrial and glycolytic activity specific to CD4+ T cells in the MS patient cohort compared to the HC participant cohort. Furthermore, increased CPT1a mitochondrial membrane protein levels were detected in CD4+ T cell subpopulations in the MS patient cohort as assessed in comprehensive flow cytometry PBMC phenotype investigations. The analysis of the CD4+ CD25- CD127+ conventional T cell subpopulation moreover revealed a trend of decreased IL7-Rα expression levels in MS patients. Gene expression measurements of pro-inflammatory and metabolic genes did not reveal alterations in MS patients’ T cell subpopulations. The results obtained in this study allude to dysfunctions in metabolic reprogramming in T cell subpopulations in MS patients and help to better understand the contribution of immunometabolism in the pathogenesis of MS disease.
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IMMUNOTHERAPY OF SOLID TUMORS WITH IMMUNOMETABOLICALLY-RETARGETED NATURAL KILLER CELLSAndrea M Chambers (10283939) 06 April 2021 (has links)
<div>Cancer is responsible for the second highest cause of death in the United States, and lung cancer accounts for 13% of new cancer diagnoses, with the highest rate of cancer death at 24%. Almost 85% of these cases represent non-small cell lung cancer (NSCLC), which includes lung adenocarcinoma, the most common NSCLC subtype. Traditional cancer treatments often only temporarily stop the spread of the disease, but immunotherapies, which are becoming a standard of care, are much more promising. Natural killer (NK) cells are powerful effectors of innate immunity, and genetically engineered NK cells as immunotherapies have had encouraging clinical responses in the treatment of various cancers. However, more progress is needed for solid tumor treatment, especially for lung adenocarcinoma. The activation of cancer-associated ectoenzymes, CD39 and CD73 catalyze the phosphorylation of ATP to AMP to produce extracellular adenosine (ADO), which is a highly immunosuppressive mechanism contributing to the pathogenesis of solid tumors. Understanding adenosine effects on NK cells will help develop more robust immunotherapeutic treatments to improve cytotoxicity against solid tumors. Here, we established that tumor microenvironment ADO results in impaired metabolic and anti-tumor functions of cytokine-primed NK cells. Specifically, peripheral blood-derived NK cells stimulated with IL-2, IL-15, or a combination of IL-12 and IL-15 showed suppressed anti-tumor immunity due to ADO. This was observed by the downregulation of activation receptor expression, cytotoxicity inhibition, impairment of metabolic activity, and alterations in gene expression. To target ADO-producing CD73 on cancer cells, we redirected NK cells by fusing CD73 ScFv with intracellular and transmembrane regions of NK cell specific signaling components derived from FCyRIIIa (CD16). Engineered NK cells were shown to be cytotoxic against lung adenocarcinoma <i>in vitro</i> and impede tumor growth in a lung adenocarcinoma mouse model <i>in vivo</i>. Engineered cells also had higher levels of degranulation and cytokine release, as well as more infiltration into tumors and longer survival time in mice. In summary, the microenvironment of solid tumors is highly immunosupressive, and redirecting NK cell function using a NK-specific anti-CD73 targeting construct will help to promote anti-tumor immunity and</div><div>inhibit cancer growth for a potentially powerful new immunotherapy against solid tumors.</div>
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