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The structure, function and specificity of the Rhodobacter sphaeroides membrane-associated chemotaxis arrayAllen, James Robert January 2014 (has links)
Bacterial chemotaxis is the movement of bacteria towards or away from chemical stimuli in the surrounding media. Bacteria respond to chemotactic signals through chemoreceptors which bind specific ligands and transduce signals through a modified two-component system. Typical chemoreceptors bind a ligand in the periplasm and signal across the inner membrane to the cytoplasmic chemosensory array through the inner membrane. Bacterial chemoreceptors must integrate multiple signals within an array of different receptor homologues to a single output. Chemoreceptors act cooperatively to allow a rapid signal spread across the array and large signal gain. Chemoreceptors adapt to a signal by chemical modification of their cytoplasmic domains in order respond across a wide range of effector concentrations. How bacterial chemoreceptors transduce signals through the inner membrane, integrate multiple effector responses, signal cooperatively and adapt to result in a single output signal is not currently fully known. In Rhodobacter sphaeroides, additional complexity arises from the presence of multiple homologues of various chemotactic components, notably the array scaffold protein CheW. Decoding this signalling mechanism and heterogeneity involved in this system is important in decoding the action of a biological system, with implications for biotechnology and synthetic biology. This study used the two model systems Escherichia coli and R. sphaeroides to analyse the mechanism of signalling through bacterial chemoreceptors. Rational design of activity-shifting chemoreceptor mutations was undertaken and these variants were analysed in phenotypic and fluorescence localisation studies. Molecular-dynamics simulations showed an increase in flexibility of chemoreceptors corresponds to a decrease in kinase output activity, which was determined by the computational tracking of bacteria free-swimming in media. Fluorescence recovery after photobleaching was used to show that this increase in flexibility results in a decrease in binding of receptors to their array scaffold proteins. A two-hybrid screen also suggested that inter-receptor affinity is also likely to decrease. These results show that signalling through chemoreceptors is likely through a mechanism involving the selective flexibility of chemoreceptor cytoplasmic domains. Analysis of R. sphaeroides chemoreceptors and CheW scaffold proteins in E. coli showed that it should be possible to design, from the bottom-up, a functional bacterial chemotaxis system in order to analyse individual protein specificity. Expression of R. sphaeroides MCPs in this E. coli system show the reconstitution of a chemotactic array, but not one capable of signalling specifically to proposed attractants. Results gained from this system suggest the R. sphaeroides CheW proteins are not homologous and their differential binding affinities may allow array activity 'fine-tuning'.
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Influence of Lck abundance on thymic selection, peripheral T cell activation and the formation of T cell memoryStockner, Kaija January 2014 (has links)
Selection of the T cell repertoire in the thymus is governed by the need to create a repertoire of peripheral T cells that can respond to any foreign antigen in the context of self-major histocompatibility complex (MHC), while enforcing central tolerance to self-antigens. Perturbations in signalling molecules, that reduce the affinity of thymic selection, can lead to the production of a peripheral repertoire with increased autoimmunity, as has been shown for mutations in the Zap-70 kinase. Upstream of Zap-70 is Lck, the most proximal tyrosine kinase required for T cell receptor (TCR) triggering upon TCR engagement by peptide:MHC. In order to study how Lck influences T cell activation, a transgenic mouse model (LckVA), in which Lck is expressed constitutively from a T cell specific transgene and mice have very low expression of Lck (~5% of WT) in both the thymus and periphery, was used. It has been shown that Lck is critical for successful T cell development, yet the results of this thesis show that even 5% of WT levels of Lck are sufficient for selection of thymic T cells on both polyclonal and F5 TCR transgenic backgrounds. Previous studies utilising mice expressing an inducible Lck transgene, which also had reduced Lck expression in the periphery, showed Lck to be critical in determining the activation threshold of T cells. In contrast, peripheral T cells in LckVA mice had similar activation thresholds to wild type T cells, as measured by in vitro upregulation of early activation markers. Further analysis of LckVA peripheral T cells revealed differential influences of low expression of Lck on downstream signalling pathways upon TCR engagement. For example, ERK signalling was impaired, while calcium flux and proliferation were enhanced in LckVA T cells. Finally, LckVA T cells were altered in their ability to differentiate, showing enhanced production of cytokines and retaining the capacity to form memory cells.
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Investigating the heterogeneity of leukaemia kinase networks and the impact of the microenvironment on leukaemic cell signallingDokal, Arran D. January 2018 (has links)
The tumour microenvironment plays a key role in tumour progression. In this thesis acute myeloid leukaemia (AML) was used as a model system to investigate the interplay between stromal and cancer cells. AML is a heterogeneous clonal disorder of haematopoietic undifferentiated progenitor cells or 'blast cells', which accumulate in the bone marrow and lead to the reduced output of crucial haematopoietic elements. Due to its heterogeneity (at least in part), treatment of the disease has not witnessed great innovation in the past 30 years. The bone marrow microenvironment (BMM) has a key role in the haematological malignancies contributing to the survival of leukaemic blasts. Relapse in AML occurs because of residual disease and evidence suggests that this resistance is facilitated through leukaemic cells ability to reside in BMM niches. To understand the precise role of the BMM in AML progression and therefore target any supportive mechanisms requires knowledge of how AML cells communicate with their microenvironment. In the work presented in this thesis I undertook a multi-proteomic approach that utilised liquid chromatography tandem mass spectrometry (LC-MS/MS) to assess the interplay between AML and BMM cell signalling. This thesis shows the results of a secretomic analysis of stromal cell lines, which identified a previously uncharacterized panel of six stromal secreted proteins (BMP-1, CSF-1, CTGF, HGF, S100-A4 and S100-A11) that support primary AML cell survival and proliferation in culture. Comparison of AML cell signalling (using global phosphoproteomic methods) following treatment with the newly identified growth factors revealed that these signalling proteins elicit multi-nodular activation of signalling networks with known anti-apoptotic activity. Consistent with the cell signalling proteomics data, cell viability studies as a function of pharmacological kinase inhibitor treatment determined that the sensitivity of AML to targeted kinase inhibitors was modulated by the supportive stromal conditioned media. To investigate heterotypic signalling between cell populations, AML/stromal cell co-cultures were designed, tested and optimised. These studies identified additional activated pathways in AML cells that were only present when AML cells had physical interaction with stroma. Complementary analysis of the stromal cells which had been first cultured with AML cells revealed that despite heterogeneity there is an emerging stromal phospho-proteomic signature that is different in BMM independent AML cells vs BMM interactive AML cells. Collectively these findings evidence the influence that the BMM can have on AML signalling. Although evidence for the influence of BMM in modulating AML resistance to standard chemotherapy exists, this study highlights specific BMM components that contribute to the ability of AML cells to circumvent current treatments based on kinase targeted drugs. These observations have implications for designing future therapies for AML.
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Inflammasome signalling during Salmonella Typhimurium infectionde Almeida Pereira, Milton César January 2018 (has links)
The innate immune system is the first line of defence against infection. It is comprised of physicochemical barriers and a variety of cell types including macrophages and dendritic cells. Pathogens express specific pathogen associated molecular patterns (PAMP) which are recognised by pattern recognition receptors (PRR) on macrophages to initiate an innate immune response. Gram-negative bacteria such as Salmonella enterica serovar Typhimurium express a range of bacterial PAMPs recognised by Toll-like receptors (TLRs) including lipopolysaccharides (LPS) recognised by TLR-4 and lipoproteins by TLR-2. The activation of TLRs results in activation of nuclear factor κB (NF-κB) to drive transcription of mRNA coding for pro-inflammatory proteins such as tumor necrosis factor α (TNF-α) and pro-interleukin (IL) 1β. Myeloid cells also possess intracellular PRRs including the nucleotide-binding domain and leucine-rich repeat (NLR) family. NLR family CARD domain- containing protein 4 (NLRC4) and NLR family pyrin domain-containing protein 3 (NLRP3) are the main NLRs engaged in recognising S. Typhimurium infection, leading to formation of the inflammasome. The inflammasome is a macromolecular complex assembled in the cytoplasm, and usually contains a NLR, the structural protein apoptosis-associated speck-like protein containing a CARD (ASC) and effector enzymes such as cysteine-dependent aspartate-directed protease (caspase) -1 and caspase-8. This structure is responsible for processing the cytokines pro- IL-1β and pro-IL-18 to their mature form and is involved in triggering a pro-inflammatory process of cell death termed pyroptosis. The formation of the inflammasome therefore results in cell death and secretion of proinflammatory cytokines which play important roles in controlling infections. Inflammasome activity must be tightly coordinated, as its dysregulation is associated with a variety of auto-inflammatory and auto-immune diseases. The signalling events leading to inflammasome assembly are poorly understood and the molecules involved in fine-tuning its activity are only beginning to be discovered. The aim of this thesis was to discover new molecules involved in inflammasome activation and/or in keeping its activity in check. To achieve this goal, I performed S. Typhimurium infection assays in primary bone marrow derived macrophages (BMDM) derived from C57BL/6 mice wild type (WT) and compared the resulting cellular viability, intracellular bacteria counts and IL-1β production to that of BMDMs derived from C57BL/6 mice lacking proteins involved with, or suspected to be involved with, innate immune activity. Amongst the proteins I studied, caspase recruitment domain 9 (CARD9) inhibited inflammasome-mediated IL-1β production. Multiple independent genome-wide association studies link this protein to inflammatory pathologies such as Crohn's disease, but its role in canonical inflammasomes was largely unexplored. To investigate how CARD9 inhibits inflammasome-mediated IL-1β production I have conducted assays in WT and Card9-/- BMDMs, including stimulation of specific NLRs with their purified ligands, infection with bacterial strains deficient in NLRC4 activation, and infection assays in presence of pharmacological inhibitors. By employing these approaches, I observed that CARD9 has a negative role on NLRP3-dependent IL-1β production. Specifically, in response to activation of the NLRP3 by Salmonella infection, CARD9 negatively regulates pro-IL-1β transcription, and decreases IL-1β processing by inhibiting spleen tyrosine kinase (SYK)-mediated NLRP3 activation and represses caspase-8 activity in the inflammasome. CARD9 expression is suppressed in the course of S. Typhimurium infection which may act as a mechanism to increase IL-1β production during the infection. In conclusion, I have established a connection between CARD9 and IL-1β production by the canonical NLRP3 inflammasome and elucidated some of the mechanisms involved in this process. I have also found evidence that other proteins are likely to be involved in inflammasome regulation and the elucidation of their roles will be addressed in future studies.
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The role of VEGF-induced PI3K/Akt signalling pathway in head and neck cancer cell migrationIslam, Mohammad Rafiqul January 2015 (has links)
The PI3K-Akt signalling pathway is a well-established driver of cancer progression. One key process promoted by Akt phosphorylation is tumour cell motility; however the mechanism of VEGF-induced Akt phosphorylation leading to motility remains poorly understood. Previously, it has been shown that Akt phosphorylation, induced by different factors, causes both stimulation and inhibition of motility in different cell types. However, differential phosphorylation of Akt at T308 and S473 residues by VEGF and its role in head and neck cancer cell motility and progression is unknown. The cell lines investigated in this study exhibited a change in phosphorylation of Akt in response to VEGF. However, in terms of motility, VEGF stimulated oral cancer and its associated cell lines, but not normal keratinocytes or oral mucosal fibroblasts. The addition of a PI3 kinase and mTOR inhibitor, inhibited the phosphorylation of Akt and also effectively blocked VEGF-induced oral cancer cell motility, whereas only the PI3 kinase inhibitor blocked oral cancer associated fibroblast cell motility. This study therefore discloses that two different mechanisms of Akt phosphorylation control the motility potential of different cell lines. Akt phosphorylated at both residues controls oral cancer cell motility. Tobacco, alcohol and HPV infection are associated with increased risk of HNSCC. However, little is known about the underlying signalling events influencing risk. It was also aimed to investigate the relationship between these risk factors and Akt phosphorylation, to determine prognostic value. VEGF-positive HNSCC biopsies, with known HPV status, were analysed by immunohistochemistry (IHC) for Akt, phosphorylated at residues S473 and T308. Comparisons between the tissues were carried out using a Mann-Whitney U test. Associations between the variables and continuous immunohistochemical parameters were evaluated with general linear models. Patient characteristics and pAkt IHC score were analysed for possible association with overall survival by Cox proportional hazard models. Immunohistochemistry revealed that cancer patients had significantly higher levels of pAkt T308 than S473 (P < 0.001). Smoking and alcohol were found to be independent risk factors for Akt phosphorylation at T308 (P = 0.022 and 0.027, respectively). Patients with tumours positive for HPV or pAkt S473 had a poorer prognosis (P = 0.005, and 0.004, respectively). Patients who were heavy drinkers were more likely to die than non-drinkers (P = 0.003). Patients with low pAkt T308 were more likely to be HPV positive (P = 0.028). Non-drinkers were also found to have lower levels of pAkt T308 and were more likely to have tumours positive for HPV than heavy drinkers (P = 0.044 and 0.007, respectively). This study suggests different mechanisms of carcinogenesis are initiated by smoking, alcohol and HPV. The resultant data propose higher phosphorylation of Akt at T308 as a reliable biomarker for smoking and alcohol induced HNSCC progression and higher phosphorylation of Akt at S473 as a prognostic factor for HNSCC.
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Etudes du dysfonctionnement mitochondrial dans le maintien de la biogenèse mitochondriale et de la réponse à l’apoptose induiteMERCY, Ludovic 17 March 2008 (has links)
<b>Français : </b>
La mitochondrie est un organite dont les fonctions dépassent largement le rôle bioénergétique. De ce fait, il apparaît de plus en plus clairement qu’un grand nombre de pathologies sont liées à un dysfonctionnement mitochondrial. Au cours de ces dernières années l’existence d’une communication moléculaire rétrograde entre la mitochondrie non fonctionnelle et le noyau a été mise en évidence dans les cellules eucaryotes de mammifères. Les voies de signalisation moléculaire menant à l’expression différentielle de gènes nucléaires en réponse à un dysfonctionnement mitochondrial sont néanmoins encore peu connues. Dans ce domaine, l’utilisation de lignées cellulaire totalement (r0) ou partiellement (r-) déplétées en ADN mitochondrial (ADNmt) s’est révélée essentielle dans l’étude de la réponse cellulaire induite par un dysfonctionnement mitochondrial.
L’objectif de ce travail était de mieux comprendre les mécanismes moléculaires impliqués dans la réponse cellulaire à un dysfonctionnement mitochondrial 1) en recherchant comment les cellules déplétées en ADNmt maintiennent un potentiel de membrane mitochondrial en étudiant les mécanismes impliqués dans le maintien de la biogenèse mitochondriale et 3) en caractérisant la sensibilité des cellules déplétées en ADNmt à l’apoptose.
Au cours de la première partie de ce travail, nous avons mis en évidence le rôle de la protéine mtCLIC dans le maintien du Dym des cellules déplétées en ADNmt. Nous avons ainsi démontré que le gène codant cette protéine est surexprimé dans les cellules présentant un dysfonctionnement mitochondrial, et que l’activité de canal à chlore pouvait rendre compte du maintien du Dym dans ces cellules.
Dans la deuxième partie de ce travail, nous avons caractérisé et comparé les populations mitochondriales des cellules parentales et déplétées en ADNmt (143B r0, ostéosarcome humain). L’activité de certains facteurs de transcription décrits pour jouer un rôle dans le processus de biogenèse mitochondriale a été recherchée ainsi que le niveau d’expression de certaines protéines marqueurs de la biogenèse mitochondriale. Le rôle de la voie calcium-CaMKIV-CREB dans le maintien de la biogenèse mitochondriale des cellules r0 a ainsi pu être mis en évidence. Nous avons également mis en évidence une diminution de l’activité d’importation de protéines chimériques matricielles dans les mitochondries des cellules déplétées en ADNmt. Cette diminution peut s’expliquer par la réduction du Dym et de la charge en ATP dans ces cellules mais n’est pas généralisable à l’ensemble des protéines mitochondriales. En effet, l’importation du cytochrome c est augmentée et celle de la sous-unité ß de la F1-ATPase est inchangée dans des cellules 143B r0.
La dernière partie de ce travail a été consacrée à la caractérisation et à la comparaison de la réponse des cellules 143B et 143B r0 à un stimulus pro-apoptotique. Après avoir clairement établi que les cellules r0 présentent une sensibilité accrue à la staurosporine, nous avons recherché les mécanismes moléculaires pouvant expliquer cette réponse différentielle. Nous proposons que la sensibilité accrue des cellules r0 peut s’expliquer par la sous-expression constitutive des protéines anti-apoptotiques Bcl-2 et Bcl-XL. De plus, nous montrons également que les mécanismes impliqués pourraient faire intervenir la cathepsine B, libérée du lysosome par un mécanisme non encore élucidé. Nous montrons également que l’activation spécifique de l’autophagie dans les cellules 143B r0 en réponse à la staurosporine pourrait également contribuer à la plus grande sensibilité à l’apoptose des cellules présentant un dysfonctionnement mitochondrial.
Les résultats obtenus au cours de ce travail ont permis d’identifier certains mécanismes d’adaptation mis en place dans des cellules de mammifères soumises à un stress énergétique chronique, et donc de mieux comprendre les implications d’un dysfonctionnement mitochondrial, une situation associée à ou responsable de nombreuses pathologies mitochondriales.
<b>English : </b>
Mitochondria are involved in numerous cell processes, such as ATP production, calcium homeostasis, fatty acid metabolism, heme synthesis, urea cycle, redox cell status, autophagy and apoptosis. Impairment of its bioenergetic activity is thus obviously associated with numerous pathologies. However, while various origins and symptoms have been described for mitochondrial diseases over the past 10 years, only very few retrograde signalling pathways (that could be defined as communication between impaired mitochondria and nucleus) have been identified. In addition, little is still known about the molecular mechanisms leading to differential gene expression in response to chronic or acute mitochondrial dysfunction. In that research field, the generation of cells totally (r0) or partially (r-) depleted in mtDNA has been very useful to study the response of cells to a chronic energetic stress.
The major aim of this work was to get a better understanding of the molecular mechanisms involved in the retrograde communication between impaired mitochondria and the nucleus that participate to the maintenance of 1) the mitochondrial membrane potential (Dym), 2) the mitochondrial biogenesis and 3) the apoptotic response to staurosporine, an alkaloïd that inhibits numerous kinases.
In the first part of this work, we highlighted the role of the protein mtCLIC/CLIC4 in the maintenance of the Dym in mtDNA-depleted cells. Using a “mRNA RT-PCR differential display” approach, we first identified that the gene was over-expressed in mtDNA-depleted cells. We also show that modifications of its abundance (over expresion and silencing by siRNA) were able to modify the Dym. Finally, we evidenced that mtCLIC allows the importation of chlorine into mitochondria of r-L929 (murine fibrosarcoma cells).
In the second part of this work, we characterized and compared mitochondrial populations between 143B (osteosarcoma cell line) and 143B r0 cells. We monitored the activity status of several key transcription factors known to be involved in the control of mitochondrial biogenesis and we determined the expression level of several mitochondrial proteins used as common markers of mitochondrial biogenesis. We also clearly demonstrated the role for calcium-CaMKIV-CREB pathway in the maintenance of mitochondrial biogenesis in mtDNA-depleted cells. Indeed, we show that the over-expression of cytochrome c and the higher mitochondrial NAO (Nonyl Acridine Orange) staining (two indicators for a higher abundance of mitochondrial mass) observed in mtDNA-depleted cells could be reduced in r0 cells that over-express either a dominant negative forms of CREB or CaMKIV. Moreover, we show that the importation of matrix-targeted proteins is reduced in mtDNAdepleted cells, a feature that can be explained by the lower Dym and reduced ATP content in these cells.
As several evidence were reported to link mitochondrial dysfunction and apoptosis in vivo, the last part of this work has been dedicated to the characterization of the apoptotic response of mtDNAdepleted cells to staurosporine. Indeed, the higher or lower sensitivity of mtDNA-depleted cells to apoptotic stimuli is still a debated question in the literature. We first show that r0 143B cells are hypersensitive to staurosporine-induced apoptosis, a phenomenon that could most likely be explained by the constitutive down-regulation of anti-apoptotic proteins such as Bcl-2 an Bcl-XL in r0 cells. Moreover, we show that the mechanisms of r0 cells response to staurosporine seems to be different from those triggered in parental cells. Indeed, we show that cathepsin B might play a role in staurosporine-induced mtDNA-depleted cell apoptosis, despite the activation of many caspases. Finally, we show that autopahgy is also triggered by staurosporine in r0 143B cells, an upstream event of caspase activation as 3-methyladenine (3-MA) strongly reduces caspase activation.
In conclusion, our results bring new information in the understanding of mechanisms and cell signalling activated in mammalian cells facing a chronic energetic stress, and thus bring new insights into the cellular consequences of mitochondrial impairment, a feature found in numerous mitochondrial diseases and pathologies associated with aging.
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OX1 Orexin Receptor Signalling to PhospholipasesEkholm, Marie January 2010 (has links)
The neuropeptides orexin-A and orexin-B were discovered in 1998 and were first described as regulators of feeding behaviour. Later research has shown that they have an important role in the regulation of sleep. Two G protein-coupled receptors, OX1 and OX2 orexin receptors, mediate the cellular responses to orexins. The overall aim of this thesis was to investigate the OX1 orexin receptors signalling to phospholipases. Previous investigations have determined that orexin receptors induce Ca2+ elevations through both receptor-operated Ca2+ channels (ROCs) and store-operated Ca2+ channels (SOCs). In this thesis we investigated the importance of these influxpathways on orexin-mediated phospholipase (PLC) activation. The results demonstrate that ROC influx is enough to fully support orexin-stimulated PLC activation but that SOC influx has a further amplifying role. We also investigated the metabolites generated after PLC activation, inositolphosphates and diacylglycerol (DAG). The results indicate involvement of two different PLC activities with different substrate specificities one of them leading to DAG production without co-occurring IP3 production at low orexin receptor stimulation. The results also suggest that at even lower orexin receptor stimulation DAG is produced via the activation of phospholipase D. In this thesis we also investigated if the ubiquitous phospholipase A2 (PLA2) signalling system is involved in orexin receptor signalling. The results demonstrate that stimulation of the OX1 orexin receptors leads to arachidonic acid (AA) release. This release is fully dependent on Ca2+ influx, probably through ROC, and at the same time the studies demonstrate that ROC influx is partly dependent on PLA2 activation. At low orexin receptor activation the AA release seemed to in part rely on extracellular signal-regulated kinase. We also devised two methods to aid in these investigations. The first method enabled studies of the receptor-operated Ca2+ influx without interference of the co-occurring store-operated Ca2+ influx. This was done by the expression of IP3-metabolising enzymes IP3-3-kinase-A and IP3-5-phosphatase-I. The second method enables quantification of DAG and IP3 signalling in fixed cells using GFP-fused indicators, leading to a semi-quantitative but easily applicable pharmacological assay.
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Molecular Mechanisms of Hepatitis C Virus- Associated SteatosisJackel-Cram, Candice Marie 18 August 2009
Hepatitis C virus (HCV) infects millions of people worldwide and is one of the leading causes of liver damage. Infection with HCV is strongly correlated with an increased risk of steatosis, or fatty liver disease, which is caused by a build-up of fat deposits in hepatocytes. All genotypes of HCV appear to cause some degree of steatosis in approximately 50% of infected individuals, especially in the presence of contributing host factors such as diabetes, obesity and alcoholism. However, approximately 70% of genotype 3a infections exhibit steatosis. Furthermore, successful clearance of the genotype 3a virus results in eradication of the steatosis, suggesting the genotype 3a virus may be able to directly cause steatosis.<p>
Research suggests a role for the core protein of HCV, which forms the capsid of the virus, in the alteration of lipid metabolism pathways during infection. As such, I hypothesized that: 1) HCV alters lipid metabolism pathways and causes the build up of lipid in hepatocytes and the development of steatosis; 2) HCV-3a core protein has a differential or increased effect on these pathways in comparison to 1b core protein; and 3) other HCV proteins could also play a role in the altering of lipid metabolism. My research characterized the subcellular localization on lipid droplets of the HCV-3a core protein in comparison to HCV-1b core protein. It was found that HCV-3a core causes increased transcriptional activity from the Fatty Acid Synthase (FAS) promoter, an important enzyme involved in the synthesis of triglycerides in hepatocytes. In addition, one specific amino acid of HCV-3a core was determined to be partially responsible for this effect. Further research determined that the effect of HCV-3a core on FAS was dependent on the transcription factor Sterol Response Element Binding Protein-1 (SREBP-1) and the presence of HCV-3a core increased the processing and activity of SREBP-1. HCV core was also able to increase activity of Akt 1 and Akt2; inhibition of Akt activity resulted in decreased SREBP-1 activity thereby indicating that HCV core partially mediates SREBP-1 via Akt. Further experiments examined the role of another HCV protein, NS2, in these same lipid metabolism pathways. NS2 was also able to increase transcription from the FAS promoter via SREBP-1, suggesting that this HCV protein may also be important in the development of steatosis during HCV infection.<p>
The evidence provided in these studies shows a very important role for HCV in altering lipid metabolism during infection that may lead to the development of steatosis. Current research suggests that the SREBP-1 pathway may be critical in the life cycle of the virus and these studies have provided important information on how lipid metabolism pathways are being changed by the virus. Hopefully this work can help identify potential treatment options for HCV that can slow down disease progression by preventing the development of steatosis or by decreasing viral replication.
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Molecular Mechanisms of Hepatitis C Virus- Associated SteatosisJackel-Cram, Candice Marie 18 August 2009 (has links)
Hepatitis C virus (HCV) infects millions of people worldwide and is one of the leading causes of liver damage. Infection with HCV is strongly correlated with an increased risk of steatosis, or fatty liver disease, which is caused by a build-up of fat deposits in hepatocytes. All genotypes of HCV appear to cause some degree of steatosis in approximately 50% of infected individuals, especially in the presence of contributing host factors such as diabetes, obesity and alcoholism. However, approximately 70% of genotype 3a infections exhibit steatosis. Furthermore, successful clearance of the genotype 3a virus results in eradication of the steatosis, suggesting the genotype 3a virus may be able to directly cause steatosis.<p>
Research suggests a role for the core protein of HCV, which forms the capsid of the virus, in the alteration of lipid metabolism pathways during infection. As such, I hypothesized that: 1) HCV alters lipid metabolism pathways and causes the build up of lipid in hepatocytes and the development of steatosis; 2) HCV-3a core protein has a differential or increased effect on these pathways in comparison to 1b core protein; and 3) other HCV proteins could also play a role in the altering of lipid metabolism. My research characterized the subcellular localization on lipid droplets of the HCV-3a core protein in comparison to HCV-1b core protein. It was found that HCV-3a core causes increased transcriptional activity from the Fatty Acid Synthase (FAS) promoter, an important enzyme involved in the synthesis of triglycerides in hepatocytes. In addition, one specific amino acid of HCV-3a core was determined to be partially responsible for this effect. Further research determined that the effect of HCV-3a core on FAS was dependent on the transcription factor Sterol Response Element Binding Protein-1 (SREBP-1) and the presence of HCV-3a core increased the processing and activity of SREBP-1. HCV core was also able to increase activity of Akt 1 and Akt2; inhibition of Akt activity resulted in decreased SREBP-1 activity thereby indicating that HCV core partially mediates SREBP-1 via Akt. Further experiments examined the role of another HCV protein, NS2, in these same lipid metabolism pathways. NS2 was also able to increase transcription from the FAS promoter via SREBP-1, suggesting that this HCV protein may also be important in the development of steatosis during HCV infection.<p>
The evidence provided in these studies shows a very important role for HCV in altering lipid metabolism during infection that may lead to the development of steatosis. Current research suggests that the SREBP-1 pathway may be critical in the life cycle of the virus and these studies have provided important information on how lipid metabolism pathways are being changed by the virus. Hopefully this work can help identify potential treatment options for HCV that can slow down disease progression by preventing the development of steatosis or by decreasing viral replication.
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Insulin Receptor Signaling is Necessary for the Maintenance of Epithelial Phenotype in MCF10A CellsDi Palma, Vanessa C. 11 July 2013 (has links)
Obesity is an adverse factor in the development and severity of breast cancer. Obesity is
often accompanied by an increase in circulating insulin, which is also associated with
poor BC prognosis. Although not expressed in normal breast tissue, the insulin receptor
(IR) is highly expressed in BC, therefore insulin signaling in BC cells may be responsible
for the negative prognostic effects associated with hyperinsulinemia.
This thesis describes the development of a cell-based system to study how insulin affects
BC. My work shows that MCF10A, untransformed human breast epithelial cells that
express the IR, require insulin for normal proliferation and morphology. Interestingly, I
discovered hyperactivation of ERK1/2 in MCF10A cells in response to insulin
withdrawal, resulting in a loss of epithelial phenotype. Unexpectedly, while losing
epithelial phenotype, MCF10A cells depleted of insulin failed to migrate. In conclusion,
breast cells that express IR require insulin for migration and maintenance of epithelial
characteristics.
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