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Monocytes-macrophages in liver injury and regenerationMoore, Joanna Kirsty January 2016 (has links)
Chronic Liver Disease (CLD) and Acute Liver Failure (ALF) are serious medical syndromes. Current therapeutic options consist of managing complications, and liver transplant. Even if liver transplantation is thought to be suitable for CLD or ALF patients, there are not enough organs available and thus increasingly more deaths occur on the transplant waiting list. Therefore, there is a pressing need to develop additional therapies. This thesis firstly systematically reviews trials in autologous cell therapies as possible treatments for patients with cirrhosis. The published literature is imperfect and the difference in trial design means it has not been possible to conduct a meta-analysis. Regardless of these shortcomings, cell therapy is a potentially positive prospect. In ALF and CLD monocyte-macrophages have diverse roles within the liver. Monocyte and immune cell changes in ALF are investigated and it is demonstrated for the first time that patients with paracetamol induced ALF have a significantly altered blood compartment and that these changes correlate with patient outcome. It is possible that these results may help stratify which patients may spontaneously survive and which patients may require an emergency liver transplant. Furthermore, modulation of these changes may improve outcomes for patients. The thesis also examines monocyte-macrophages in cirrhotic patients and demonstrates the feasibility of differentiating cirrhotic patients’ monocytes into functional macrophages, comparable to healthy volunteers in a Good Manufacturing Practice (GMP) environment. A first in-man trial using macrophages infused to patients with cirrhosis as a potential new treatment is also detailed. Finally, this thesis outlines developmental work for cell therapy in patients with cirrhosis in the multi-centre REALISTIC trial. Patients were randomly assigned to receive; standard medical care, Granulocyte Stimulating Factor (GCSF) injections alone or GCSF combined with repeated stem cell infusion.
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Role of DNA methyltransferase 3a (Dnmt3a) in the adaptation of atherogenesis key players to proatherogenic environment. / Rôle de l'ADN méthyltransférase 3a (Dnmt3a) dans l'adaptation des joueurs clés de l'athérogenèse à l'environnement proathérogèneNabulsi, Maisa 30 September 2016 (has links)
L’ADN méthyltransférase 3a (DNMT3A) relie environnement et phénotype par la méthylation des dinucléotides CpG, qu’on les trouve en particulier dans les régions promotrices des gènes. Hypométhylation de ces CpG est associée à l’activation de la transcription, qui permet le contrôle de l'expression génique dans des états physiologiques et pathologiques. La plupart de nos connaissances sur l’implication de Dnmt3a en pathologie concernent le cancer, quelques données montrent sa contribution à d’autres pathologies. L’athérosclérose est la maladie cardiovasculaire la plus fréquente. Plusieurs facteurs de risque contribuant à son apparition, sont liés à L’environnement. En particulier, les dyslipidémies, largement influencées par le régime alimentaire. Par ailleurs, d’abondantes données décrivent la contribution des cellules inflammatoires à la physiopathologie de cette maladie. Jusqu'à présent, un nombre croissant de données suggère un rôle de la méthylation de l’ADN dans l'athérosclérose, mais à ce jour, le rôle de Dnmt3a dans la régulation du cholestérol et le développement initial des plaques n'a pas été étudié.Nos résultats suggèrent que l’inactivation de Dnmt3a dans les monocytes/macrophages ne modifie pas le développement initial des plaques d’athérome et n’a pas d’influence sur la polarisation des macrophages in vitro. En parallèle, nous avons démontré que l’inactivation de Dnmt3a dans les hépatocytes conduit à une différence significative de cholestérolémie plasmatique qui n’est pas liée à une dérégulation des gènes majeurs impliqués dans le métabolisme du cholestérol. En revanche, nous avons mis en évidence une activation des réponses inflammatoires. / DNA methyltransferase 3a (DNMT3A) links environment to phenotypes via catalysis of CpG dinucleotides, notably found in genes promoter regions, methylation and whose hypomethylation is associated with gene transcriptional activation thus enabling the control of gene expression in physiologic and pathologic states. Most of our knowledge about its’ role in disease occurrence are based on articles demonstrating its’ implication in human cancers. Limited data from mouse studies illustrates its’ contribution to certain pathologies. Atherosclerosis constitutes the single most important contributor to the growing burden of cardiovascular disease. Risk factors contribute to disease occurrence, where most are related to environmental influences, notably Dyslipidaemia, a key initiator of atherosclerosis. Abundant data link hypercholesterolemia to atherogenesis, on the other hand, contribution of inflammatory mechanisms that couple dyslipidaemia to atheroma formation has been also appreciated. So far, a growing number of data suggests a role of Dnmt3a in atherosclerosis but to date, its role in cholesterol regulation and early plaque formation has not been clearly elucidated. Our results suggested that deletion of Dnmt3a in monocyte/macrophages does not affect the formation of early atherosclerostic plaque nor does it impact the polarization of macrophages in vitro. In parallel, we have also demonstrated that the deletion of Dnmt3a in hepatocytes leads to significant elevation in TC levels. We were not able to relate this elevation to dysregulation of major genes involved in Cholesterol regulation. On the other hand, we noticed activation of hepatic inflammatory responses.
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Influence of Peripheral Immune-Derived EphA4 on Microglial Dynamics Following Traumatic Brain InjuryMills, Jatia 30 July 2024 (has links)
Traumatic brain injury (TBI) elicits an immediate neuroinflammatory response that involves resident glia and infiltrating peripheral immune cells that coordinate tissue damage and functional deficits. The activation of resident microglial has been associated with a change in their morphology from a branched-like ramified cell to an ameboid state. This activation is thought to initiate a pro-inflammatory response leading to the release of neurotoxic, immune chemoattractant, and antigen-presenting signals. Subsequently, peripheral-derived immune cells (PICs), such as neutrophils and monocytes, travel to the site of injury and help coordinate this response. However, little is known regarding whether PICs influence the progressive activation state of microglia in the acute and chronic phases of injury. Overactivation of microglia can lead to neuroinflammation-mediated tissue damage and death or dysfunction of healthy neurons. Therefore, understanding how microenvironmental cues may regulate the microglial response may aid in strategies to retool their activation state in the brain. EphA4 receptor tyrosine kinase has been identified as a potential cell-to-cell contact protein on PICs that could be involved in the inflammatory changes following TBI. While microglial activation changes have been described in TBI models, the mechanistic role of infiltrating peripheral-derived immune cell (PIC) recruitment on microglial fate and function is not well understood. The purpose of my project is to gain a better understating of the temporospatial influence that EphA4-expressing PICs, specifically monocyte/macrophages, have on microglial proliferation, survival, activation phenotype, and debris clean-up using bone marrow GFP chimeric mice and the cortical contusion injury TBI model. / Doctor of Philosophy / Traumatic brain injury (TBI) triggers an immediate response from the brain's immune system, involving both local glial cells and immune cells from outside the brain. These cells work together to mediate the initial injury but, in some cases, cause development of a secondary injury. Microglia, the brain's resident immune cell, change their shape and behavior when activated by a TBI, becoming more aggressive and releasing inflammatory proteins. At the same time, immune cells from the bloodstream, like neutrophils and monocytes, rush to the injury site to assist. Yet, it's unclear how these immune cells affect microglia over time during the injury's acute and chronic phases. If microglia become too active, they can cause further damage to brain tissue and harm healthy neurons. Therefore, understanding the signals that control microglial activity could help us develop therapies to manage brain inflammation. One protein of interest in this process is the EphA4 receptor found on immune cells, which might play a crucial role in inflammation following TBI. While we know that microglia change post-TBI, we don't fully understand how the recruitment of immune cells from outside the brain affects them. My research aims to clarify how EphA4-expressing immune cells, especially monocytes/macrophages, influence microglia in terms of growth, behavior, and their ability to mediate a TBI.
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T-bet-Mediated Tim-3 Expression Dampens Monocyte Function During Chronic Hepatitis C Virus InfectionYi, Wenjing, Zhang, Peixin, Liang, Yan, Zhou, Yun, Shen, Huanjun, Fan, Chao, Moorman, Jonathan P., Yao, Zhi, Jia, Zhansheng, Zhang, Ying 01 March 2017 (has links)
Hepatitis C virus (HCV) induces a high rate of chronic infection via dysregulation of host immunity. We have previously shown that T-cell immunoglobulin and mucin domain protein-3 (Tim-3) is up-regulated on monocyte/macrophages (M/Mφ) during chronic HCV infection; little is known, however, about the transcription factor that controls its expression in these cells. In this study, we investigated the role of transcription factor, T-box expressed in T cells (T-bet), in Tim-3 expression in M/Mφ in the setting of HCV infection. We demonstrate that T-bet is constitutively expressed in resting CD14+ M/Mφ in the peripheral blood. M/Mφ from chronically HCV-infected individuals exhibit a significant increase in T-bet expression that positively correlates with an increased level of Tim-3 expression. Up-regulation of T-bet is also observed in CD14+ M/Mφ incubated with HCV+ Huh7.5 cells, as well as in primary M/Mφ or monocytic THP-1 cells exposed to HCV core protein in vitro, which is reversible by blocking HCV core/gC1qR interactions. Moreover, the HCV core-induced up-regulation of T-bet and Tim-3 expression in M/Mφ can be abrogated by incubating the cells with SP600125 – an inhibitor for the c-Jun N-terminal kinase (JNK) signalling pathway. Importantly, silencing T-bet gene expression decreases Tim-3 expression and enhances interleukin-12 secretion as well as signal transducer and activator of transcription 1 phosphorylation. These data suggest that T-bet, induced by the HCV core/gC1qR interaction, enhances Tim-3 expression via the JNK pathway, leading to dampened M/Mφ function during HCV infection. These findings reveal a novel mechanism for Tim-3 regulation via T-bet during HCV infection, providing new targets to combat this global epidemic viral disease.
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