Teses / dissertações sobre o tema "Iron Metabolism"
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SAITO, HIROSHI. "METABOLISM OF IRON STORES". Nagoya University School of Medicine, 2014. http://hdl.handle.net/2237/20543.
Texto completo da fonteAlvarez-Hernandez, J. "Iron metabolism in macrophages". Thesis, University of Glasgow, 1985. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.375442.
Texto completo da fonteXue, Yue 1978. "Iron metabolism in mammalian cells". Thesis, McGill University, 2003. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=79216.
Texto completo da fonteIron Regulatory Proteins (IRPs), which serve as main posttranscriptional regulators of cellular iron homeostasis, are the other interest of research. Iron regulatory proteins reversibly interact with iron regulatory elements (IREs) within ferritin and transferrin receptor (TfR) mRNAs. The binding ability of IRPs is under tight control so that they respond to the changes in the intracellular iron requirements in a coordinate manner by differentially regulating ferritin mRNA translational efficiency and TfR mRNA stability. Besides intracellular iron levels, some other stimuli, such as oxidative stress, are capable of regulating this RNA-protein interactions.
Whitnall, Megan. "Iron metabolism, chelation and disease". Thesis, The University of Sydney, 2011. https://hdl.handle.net/2123/28914.
Texto completo da fonteEkins, Andrew John. "Iron acquisition by Histophilus ovis". Thesis, McGill University, 2002. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=38481.
Texto completo da fonteSritharan, Manjula. "Studies in iron metabolism of mycobacteria". Thesis, University of Hull, 1988. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.278446.
Texto completo da fonteLopes, Tiago Jose da Silva. "Systems biology analysis of iron metabolism". Doctoral thesis, Humboldt-Universität zu Berlin, Mathematisch-Naturwissenschaftliche Fakultät I, 2011. http://dx.doi.org/10.18452/16417.
Texto completo da fonteEvery cell of the mammalian organism needs iron as trace element in numerous oxido-reductive processes as well as for transport and storage of oxygen. The mammalian organism maintains therefore a complex regulatory network of iron uptake, excretion and intra-body distribution. Here a mathematical model of iron metabolism of the adult mouse is presented. It formulates the iron flux balance of the most important cell types of the organism in the form of transmembraneous and intracellular kinetic equations and integrates these cell models with the central exchange compartment (blood plasma) of the body. The iron status is represented as content of labile iron and of ferritin-bound iron in every cell type, and the metabolism is formulated as a network of flux dynamics. The experimental input into the model stems from different sources. Radioactive tracer data measured in the intact animal (mouse strain C57BL6 - the most intensively studied animal model) under various physiological conditions provided the experimental background from which clearance parameters could be obtained by numerical parameter fitting. Future research should render more precise the quantitative representation of genetic reconstructions (global and cell-type-addressed knock-out and constitutive expression of relevant genes of the model mouse strain).
Bahrami, Fariborz. "Iron acquisition in Actinobacillus suis". Thesis, McGill University, 2005. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=85880.
Texto completo da fonteBae, Dong-Hun. "The Effects of Iron Levels on the Interaction between Polyamine Metabolism and Iron Metabolism in Neoplastic Cells". Thesis, The University of Sydney, 2018. http://hdl.handle.net/2123/18081.
Texto completo da fonteTremblay, Yannick. "Acquisition of haemoglobin-bound iron by Histophilus somni". Thesis, McGill University, 2005. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=82441.
Texto completo da fonteZetterström, Fernaeus Sandra. "Changed iron metabolism and iron toxicity in scrapie-infected neuroblastoma cells". Doctoral thesis, Stockholm University, Department of Neurochemistry, 2005. http://urn.kb.se/resolve?urn=urn:nbn:se:su:diva-661.
Texto completo da fonteReactions and interactions of iron and oxygen can be both beneficial and detrimental to cells and tissues. Iron is mainly found in our blood where it functions as a mediator in the transport of oxygen to the cells and is further vital for the cellular respiration reducing the oxygen to water. The flexible redox state of iron makes it ideal to contribute in single electron transfers, but may also catalyze reactions with oxygen resulting in cell damaging reactive oxygen species (ROS). Normally the cells are protected against iron toxicity by controlling iron uptake and storage. When the intracellular demand for iron increases; the iron uptake is promoted by increasing the expression of transferrin receptor (TfR) and by decreasing the expression of the iron storage protein ferritin. Ferritin has a central role in the cellular iron detoxification by keeping it in a non reactive but still bioavailable form. However, in neurodegenerative diseases like in Alzheimer’s and Parkinson’s disease the iron storage capacity is disturbed and iron induced oxidative stress adds to the pathology of the diseases. The role of iron and its possible contribution to the pathology of prion diseases, like Creutzfeldt-Jakob disease, is less explored. In the first three studies of this thesis, the iron metabolism and the mutual relation between iron and oxygen are studied in scrapie-infected mouse neuroblastoma cells (ScN2a) as compared to control cells (N2a). In the fourth study we have analyzed the expression of ferritin and TfR in response to inflammation by treating the cells with the bacterial endotoxin lipopolysaccharide (LPS). LPS promotes the expression of inducible nitric oxide synthase (iNOS), a producer of nitric oxide (NO), a well known regulator of the iron metabolism.
In the first study, the scrapie infection was found to reduce the iron levels, to reduce the mRNA and protein levels of ferritin and the TfR. In addition, reduced levels and activities of the iron regulatory proteins 1 and 2 were observed as compared to the uninfected N2a cells.
In the second study, the addition of iron to the cell medium strongly increased the level of ROS and decreased the cell viability of the ScN2a cells, whereas the N2a cells were unaffected. The ferritin expression in N2a cells in response to the iron treatment was strongly increased and the concomitant measurement of the labile iron pool (LIP) revealed the LIP to be normalized within four hours. In the ScN2a cells the induction of ferritin expression was lower resulting in elevations in LIP that lasted up to 16 h, indicating that the increased ROS levels were iron catalyzed.
In the third study, the cells were challenged with hydrogen peroxide (H2O2) to elevate the oxidative stress and to analyze the effects on the LIP and cell viability. The ScN2a cells were sensitive to the increased oxidative stress according to the cell viability test, and responded to the treatment with marked increase in the LIP levels, probably derived from an intra-cellular source. The cell viability could be reset by the co-addition of an iron chelator to the cell media. The N2a cells did not elevate the LIP and resisted higher concentrations of H2O2 than the ScN2a cells, according to the cell viability assay.
In the fourth study, the LPS treatment resulted in increased mRNA levels of the heavy chain of ferritin, increased the protein levels of ferritin light chain and decreased the protein levels of the TfR in N2a cells, but no effects were observed in the ScN2a cells. Co-treatment with LPS and the iNOS inhibitor aminoguanidine did not affect the LPS induced decrease of TfR in N2a cells, whereas the free radical scavenger N-acetyl-L-cysteine reversed the effect of LPS on TfR expression, indicating that the changes were mediated by an oxidative rather than a nitric oxide mechanism in the N2a cells.
Zetterström, Fernaeus Sandra. "Changed iron metabolism and iron toxicity in scrapie-infected neuroblastoma cells /". Stockholm : Dept. of neurochemistry, Stockholm university, 2005. http://urn.kb.se/resolve?urn=urn:nbn:se:su:diva-661.
Texto completo da fonteÅkesson, Agneta. "Cadmium exposure and iron status /". Stockholm, 2000. http://diss.kib.ki.se/2000/91-628-4290-0/.
Texto completo da fonteKobylarz, Marek John. "Siderophore-mediated iron metabolism in Staphylococcus aureus". Thesis, University of British Columbia, 2016. http://hdl.handle.net/2429/57023.
Texto completo da fonteScience, Faculty of
Microbiology and Immunology, Department of
Graduate
Kingsley, Robert Anthony. "Iron uptake and metabolism by Salmonella enterica". Thesis, University of Leicester, 1997. http://hdl.handle.net/2381/29735.
Texto completo da fonteNixon, Gavin James. "Studies in the iron metabolism of mycobacteria". Thesis, University of Hull, 1999. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.310267.
Texto completo da fonteHoque, Rukshana. "The effects of quercetin on iron metabolism". Thesis, King's College London (University of London), 2014. https://kclpure.kcl.ac.uk/portal/en/theses/the-effects-of-quercetin-on-iron-metabolism(c3f5d9ca-eeaf-4fa7-9878-5b04552e6367).html.
Texto completo da fonteMitchell, Simon. "A computational model of human iron metabolism". Thesis, University of Manchester, 2013. https://www.research.manchester.ac.uk/portal/en/theses/a-computational-model-of-human-iron-metabolism(c3afe167-4a40-42aa-8fd8-a65e47dfe7eb).html.
Texto completo da fonteXu, Xiangcong. "THE MOLECULAR MECHANISMS OF IRON AND FERRITIN METABOLISM IN". University of Sydney, 2008. http://hdl.handle.net/2123/3535.
Texto completo da fonteIron (Fe) is essential for cell growth and replication as many Fe-containing proteins catalyse key reactions involved in energy metabolism (cytochromes, mitochondrial aconitase and Fe-S proteins of the electron transport chain), respiration (hemoglobin and myoglobin) and DNA synthesis (ribonucleotide reductase). If not appropriately shielded, Fe could participate in one-electron transfer reactions that lead to the production of extremely toxic free radicals. The Fe storage protein, ferritin, is essential to protect cells against Fe-mediated oxidative stress by accommodating excess Fe into its protein shell (Xu et al., 2005). However, despite intensive research over the last few decades, many questions relating to intracellular Fe metabolism, e.g. Fe release from ferritin remain unanswered. Therefore, it is important to elucidate the molecular mechanisms of Fe trafficking in cells. At the beginning of my candidature, little was understood regarding the effect of anti-cancer agents, anthracyclines on the Fe-regulated genes, including transferrin receptor-1 (TfR1), N-myc downstream-regulated gene-1 (Ndrg1) and ferritin. Furthermore, the mechanisms of ferritin-Fe release and anthracycline-mediated ferritin-Fe accumulation are unclear. The work presented in Chapters 3 and 4 has addressed these issues. Apart from the studies examining the molecular interactions of anthracyclines with Fe, a mouse model with perturbed Fe metabolism was used and the marked alterations of protein expression in the heart of this knockout mouse model was discussed in Chapter 5. Chapter 3 Anthracyclines are effective anti-cancer agents. However, their use is limited by cardiotoxicity, an effect linked to their ability to chelate iron (Fe) and perturb Fe metabolism (Xu et al., 2005). These effects on Fe-trafficking remain poorly understood, but are important to decipher as treatment for anthracycline cardiotoxicity utilises the chelator, dexrazoxane. Incubation of cells with doxorubicin (DOX) up-regulated mRNA levels of the Fe-regulated genes, transferrin receptor-1 (TfR1) and N-myc downstream-regulated gene-1 (Ndrg1). This effect was mediated by Fe-depletion, as it was reversed by adding Fe and was prevented by saturating the anthracycline metal-binding site with Fe. However, DOX did not act like a typical chelator, as it did not induce cellular Fe mobilisation. In the presence of DOX and 59Fe-transferrin, Fe-trafficking studies demonstrated ferritin-59Fe accumulation and decreased cytosolic-59Fe incorporation. This could induce cytosolic Fe-deficiency and increase TfR1 and Ndrg1 mRNA. Up-regulation of TfR1 and Ndrg1 by DOX was independent of anthracycline-mediated radical generation and occurred via HIF-1α-independent mechanisms. Despite increased TfR1 and Ndrg1 mRNA after DOX treatment, this agent decreased TfR1 and Ndrg1 protein expression. Hence, the effects of DOX on Fe metabolism were complex due to its multiple effector mechanisms. Chapter 4 The Fe storage protein, ferritin, can accommodate up to 4500 atoms of Fe in its protein shell (Harrison and Arosio, 1996). However, the underlying mechanism of ferritin-Fe release remains unknown. Previous studies demonstrated that anti-cancer agents, anthracyclines, led to ferritin-59Fe accumulation (Kwok and Richardson, 2003). The increase in ferritin-59Fe was shown to be due to a decrease in the release of Fe from this protein. It could be speculated that DOX may impair the Fe release pathway by preventing the synthesis of essential ferritin partner proteins that induce Fe release. In this study, a native protein purification technique has been utilised to isolate ferritin-associated partners by combining ultra-centrifugation, anion-exchange chromatography, size exclusion chromatography and native gel electrophoresis. In addition to cells in culture (namely, SK-Mel-28 melanoma cells), liver taken from the mouse was used as a physiological in vivo model, as this organ is a major source of ferritin. Four potential partner proteins were identified along with ferritin, e.g. aldehyde dehydrogenase 1 family, member L1 (ALDH1L1). Future studies are required to clarify the relationship of these proteins with cellular Fe metabolism and ferritin-Fe release. Chapter 5 A frequent cause of death in Friedreich’s ataxia patients is cardiomyopathy, but the molecular alterations underlying this condition are unknown. We performed two dimensional electrophoresis to characterise the changes in protein expression of hearts using the muscle creatine kinase frataxin conditional knockout (KO) mouse. Pronounced changes in the protein expression profile were observed in 9-week-old KO mice with severe cardiomyopathy. In contrast, only a few proteins showed altered expression in asymptomatic 4-week-old KO mice. In hearts from frataxin KO mice, components of the iron-dependent complex-I and -II of the mitochondrial electron transport chain and enzymes involved in ATP homeostasis (creatine kinase, adenylate kinase) displayed decreased expression. Interestingly, the KO hearts exhibited increased expression of enzymes involved in the citric acid cycle, catabolism of branched-chain amino acids, ketone body utilisation and pyruvate decarboxylation. This constitutes evidence of metabolic compensation due to decreased expression of electron transport proteins. There was also pronounced up-regulation of proteins involved in stress protection, such as a variety of chaperones, as well as altered expression of proteins involved in cellular structure, motility and general metabolism. This is the first report of the molecular changes at the protein level which could be involved in the cardiomyopathy of the frataxin KO mouse.
Gelling, Cristy Lee Biotechnology & Biomolecular Sciences Faculty of Science UNSW. "Tetrahydrofolate and iron-sulfur metabolism in Saccharomyces cerevisiae". Publisher:University of New South Wales. Biotechnology & Biomolecular Sciences, 2008. http://handle.unsw.edu.au/1959.4/43270.
Texto completo da fonteDzikaitė, Vijolė. "Studies of proteins in heme and iron metabolism /". Stockholm, 2004. http://diss.kib.ki.se/2004/91-7349-762-2/.
Texto completo da fonteSun, Xuesong. "Iron metabolism mediated by MtsA, transferrin and desferrioxamine". View the Table of Contents & Abstract, 2006. http://sunzi.lib.hku.hk/hkuto/record/B37552995.
Texto completo da fonteSun, Xuesong, e 孫雪松. "Iron metabolism mediated by MtsA, transferrin and desferrioxamine". Thesis, The University of Hong Kong (Pokfulam, Hong Kong), 2006. http://hub.hku.hk/bib/B38722446.
Texto completo da fonteMoshtaghie, A. A. "Interrelationships between aluminium and iron metabolism in man". Thesis, University of Newcastle Upon Tyne, 1988. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.380213.
Texto completo da fonteFerreira, Patrícia Daniela Oliveira. "Regulation of iron metabolism in different bacterial infections". Master's thesis, Universidade de Aveiro, 2015. http://hdl.handle.net/10773/14598.
Texto completo da fonteIron is found in almost all living organisms, playing a central role in host-pathogen interactions and being crucial for both host and pathogens. In the host, iron is a crucial element, since it plays a key role in biological processes such as oxygen transport, biosynthesis of DNA, energy production and regulation of gene expression. However, high concentrations of iron can also be toxic to cells due to the ability to generate hydroxyl radicals. Thus, vertebrates developed proteins to transport and store iron: transferrin and ferritin, respectivetly. Hepcidin is a key protein of iron metabolism, since it binds to ferroportin, the iron exporter, regulating the release of iron to the serum. On the other hand, iron is also fundamental for pathogens that required it to its growth and proliferation, to the expression of virulence factors and to metabolic processes. Thereby, during infection, the host and the pathogen compete by this metal. Pathogens developed multiple strategies to acquire iron from the host during infection. Thus, making iron unavailable for microorganisms is a central mechanism in host defense. In this work, we investigated the regulation of iron metabolism in host during infection with Listeria monocytogenes, a gram-positive bacterium and Salmonella Typhimurium, a gram-negative bacterium in order to verify whether there are alterations in host iron metabolism depending of infection type and if hepcidin have a central role in these alterations. C57BL6 male mice were infected with 104 CFU of L. monocytogenes, S. Typhimurium, or an equivalent volume of vehicle and sacrificed at different time points. Bacterial load quantification, non-heme iron determination in liver, evaluation of iron distribution in tissue, histopathologic analyses and the expression of genes related with iron metabolism were analyzed. Our results show that in both infections with L. monocytogenes and S. Typhimurium the host immune system are not able to irradiate the infection and, thus, the bacterial load increases during the experiment. Regarding the hematological and serological parameters, a reduction of red blood cells and hematocrit is observed, as well as, of serum iron levels. The levels of interleukin-6 and hepcidin increase at different time points in each infection. Additionally, non-heme iron concentration increases in liver during infection with both pathogens. Histopathological alterations were also detected during infection with L monocytogenes and S. Typhimurium. Our data suggests that both infections induce alterations in host iron metabolism. However, the infection with S. Typhimurium appears to have earlier and more severe effects in the host than infection with L. monocytogenes.
O ferro é encontrado em quase todos os seres vivos, desempenhando um papel central nas interacções entre o hospedeiro e o patógeno e sendo essencial para ambos. Para o hospedeiro, o ferro é um elemento crucial, uma vez que desempenha um papel chave em processos biológicos como o transporte de oxigénio, a biossíntese de DNA, produção de energia e regulação da expressão génica. No entanto, elevadas concentrações de ferro também podem ser tóxicas para as células devido à capacidade de gerarem radicais hidroxilo. Assim, os vertebrados possuem proteínas para transportar e armazenar o ferro, a transferrina e a ferritina respetivamente. A hepcidina é uma proteína chave do metabolismo do ferro, uma vez que se liga à ferroportina, o exportador do ferro, regulando a libertação de ferro para o soro. Por outro lado, o ferro é também fundamental para os patógenos, que o requerem para o seu crescimento e proliferação, para a expressão de factores de virulência e para vários processos metabólicos. Assim, durante a infecção, o hospedeiro e o patógeno competem por este metal. Os patógenos desenvolveram múltiplas estratégias para adquirir o ferro a partir do hospedeiro durante a infeção. Deste modo, tornar o ferro indisponível para os microrganismos é um mecanismo central na defesa do hospedeiro. Neste trabalho, investigámos a regulação do metabolismo do ferro no hospedeiro durante a infecção com Listeria monocytogenes, uma bactéria gram-positiva e com Salmonella Typhimurium, uma bactéria gram-negativa, de modo a verificar se existem alterações no metabolismo do ferro do hospedeiro dependendo do tipo de infeção e se a hepcidina tem um papel preponderante nestas alterações. Murganhos machos C57BL6 foram infectados com 104 CFU de L. monocytogenes, S. Typhimurium, ou um volume equivalente de veículo e sacrificados a diferentes tempos experimentais. A quantificação da carga bacteriana, determinação do ferro não hémico no fígado, avaliação da distribuição de ferro no tecido, análise histopatológica e a expressão de genes relacionados com o metabolismo do ferro foram analisados. Os nossos resultados mostram que tanto na infeção com L. monocytogenes como na infeção com S. Typhimurium, o sistema imunitário do hospedeiro não é capaz de irradiar a infeção e, assim, a carga bacteriana aumenta durante a experiência. Em relação aos parâmetros hematológicos e serológicos, é observada a redução da quantidade de eritrócitos e do hematócrito, bem como dos níveis de ferro no soro. Os níveis de interleucina-6 e de hepcidina aumentam em diferentes tempos experimentais em cada infeção. Adicionalmente, a concentração de ferro não hémico aumenta no fígado durante a infeção com ambos os patógenos. Foram também detetadas alterações histopatológicas aquando da infeção com L monocytogenes e S. Typhimurium. Os nossos dados sugerem que ambas as infeções induzem alterações no metabolismo do ferro do hospedeiro. Contudo, a infeção com S. Typhimurium parece ter efeitos mais precoces e mais severos no hospedeiro do que a infeção com L. monocytogenes.
Govus, Andrew. "The regulation of human iron metabolism in hypoxia". Thesis, Edith Cowan University, Research Online, Perth, Western Australia, 2015. https://ro.ecu.edu.au/theses/1719.
Texto completo da fonteMaddocks, Sarah Elizabeth. "Iron metabolism in bacteria : examination of the Feo system (Ferrous iron transporter) and Dps-iron storage proteins". Thesis, University of Reading, 2006. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.434313.
Texto completo da fonteDanzeisen, Ruth. "Iron metabolism by BeWo cells : the role of copper and iron in the regulation of placental iron transfer". Thesis, University of Aberdeen, 2001. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.364703.
Texto completo da fonteWang, Jian 1966. "Molecular control of iron metabolism in mammalian cells : new insights into iron regulatory proteins". Thesis, McGill University, 2005. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=86063.
Texto completo da fonteStys, Agnieska. "Role of iron regulatory proteins in the regulation of iron metabolism by nitric oxide". Thesis, Paris 11, 2011. http://www.theses.fr/2011PA11T056.
Texto completo da fonteIron Regulatory Protein 1 (IRP1) and 2 (IRP2) are two cytosolic regulators of mammalian cellular iron homeostasis. IRPs post-transcriptionally modulate expression of iron-related genes by binding to specific sequences, called Iron Regulatory Elements (IREs), located in the untranslated regions (UTR) of mRNAs. Either of the two IRPs inhibits translation when bound to the single 5’UTR IRE in the mRNA encoding proteins of iron export (ferroportin - Fpn) and storage (ferritin - Ft) or prevents mRNA degradationwhen bound to the multiple IREs within the 3’UTR of the mRNA encoding the transferrinreceptor 1 (TfR1) - iron uptake molecule. The IRE-binding activity of both IRPs respondsto cellular iron levels, albeit via distinct mechanisms. IRP1 is a bifunctional protein, whichmostly exists in its non IRE-binding, [4Fe-4S] aconitase form and can be regulated by apost-translational incorporation or removal of the Fe-S cluster. In contrast to IRP1, IRP2 isnot able to ligate an Fe-S cluster, and its IRE-binding activity is determined by the rate ofits proteasomal degradation. Although both IRP1 and IRP2 can regulate cellular ironhomeostasis, only mice lacking IRP2 were shown to display iron mismanagement in mosttissues. This could be explained by the fact that IRP1 exists mostly in its non IRE−binding,aconitase form under physiological oxygen conditions (3-6%). Interestingly, nitric oxide(NO), an important signalling molecule involved in immune defence, targets the Fe-Scluster of IRP1 in both normoxia and hypoxia, and converts IRP1 from aconitase to anIRE-binding form. It has also been reported that IRP2 could sense NO, but the intrinsicfunction of IRP1 and IRP2 in NO−mediated regulation of cellular iron metabolism hasremained a matter of controversy. In this study, we took advantage of mouse models ofIRP deficiency to define the respective role of IRP1 and IRP2 in the regulation of cellulariron metabolism by NO and assess the contribution of oxygen tension on the regulation.Therefore, we exposed bone marrow-derived macrophages (BMMs) from Irp1-/-, Irp2-/- andmacrophage specific double knockout mosaic mice (Irp1/2-/-) to exogenous andendogenous NO under different oxygen conditions (21% O2 for normoxia and 3-5% forhypoxia experiments) and measured IRPs activities, iron-related genes expression andactivity of Fe-S cluster protein – mitochondrial aconitase. We showed that in normoxia, thegenerated apo-form of IRP1 by NO was entirely responsible for the post-transcriptionalregulation of TfR1, H-Ft, L-Ft and Fpn. Moreover, by increasing iron uptake and reducingiron sequestration and export, NO−dependent IRP1 activation served to maintainadequate levels of intracellular iron in order to fuel the Fe−S biosynthetic pathway, asdemonstrated by the efficient restoration of the mitochondrial Fe−S aconitase, which wasprevented under IRP1 deficiency. Furthermore, activated IRP1 was potent enough todown-regulate the abnormally increased L-Ft and H-Ft protein levels in Irp2-/-macrophages. Endogenous NO activated IRP1 IRE-binding activity and tended todecrease IRP2 IRE-binding activity. Nevertheless, IRP1 was the predominant regulator offerritin in those conditions. In hypoxia, in Irp1+/+ and Irp2+/+ macrophages exposed to NO,both stabilized IRP2 and NO-activated IRP1 seemed to cooperate to inhibit ferritinsynthesis. However, in Irp1-/- cells, IRP2 stabilized in hypoxia was sufficient to inhibit LandH-Ft synthesis despite the concomitant increase of corresponding mRNAs.Interestingly, TfR1 was shown to be predominantly regulated at the transcriptional level byNO in hypoxia, in which HIF-1 alpha may be the critical regulator. In conclusion, we revealin this study how the IRP regulon participates in the regulation of cellular iron metabolismin response to NO and its intimate interplay with the oxygen pathway. The findingsunderlie the importance to further explore the role of IRP1 in inflammation in vivo, in nonhypoxictissue microenvironments
Quisumbing, Teresita Lambo. "Studies of iron metabolism and metabolic rate in iron-deficient and cold-acclimatized rats". Hong Kong : University of Hong Kong, 1985. http://sunzi.lib.hku.hk/hkuto/record.jsp?B1231545X.
Texto completo da fonteSIGHINOLFI, SILVIA. "INTRACELLULAR IRON OVERLOAD AFFECTS HSC METABOLISM BY IMPAIRING MITOCHONDRIAL FITNESS IN β-THALASSEMIA". Doctoral thesis, Università Vita-Salute San Raffaele, 2023. https://hdl.handle.net/20.500.11768/137019.
Texto completo da fonteL'attività e il metabolismo mitocondriali controllano in modo significativo la funzione e il destino delle cellule staminali ematopoietiche (HSC). Le HSC modificano lo stato metabolico in risposta a segnali di stress, come le specie reattive dell'ossigeno (ROS), che guidano l'ingresso delle HSC nel ciclo cellulare accompagnato da un aumento della fosforilazione ossidativa mitocondriale (OXPHOS) e della glicolisi. Tuttavia, l'eccessivo accumulo di ROS provoca il danno ossidativo degli organelli cellulari, compresi i mitocondri. Il ferro è una delle fonti di ROS e le HSC possono assorbire il ferro, ma si sa poco sugli effetti del ferro sul metabolismo delle HSC. Recentemente, abbiamo dimostrato una funzione alterata delle HSC nella β-talassemia (BThal), una condizione di sovraccarico sistemico di ferro (IO). Abbiamo anche osservato che l'eccesso di ferro riduce la capacità di supporto ematopoietica delle cellule stromali mesenchimali talassemiche. Tuttavia, non ci sono prove dell'effetto diretto del sovraccarico di ferro sulle HSC in BThal. Abbiamo ipotizzato che il sovraccarico di ferro e il conseguente stress ossidativo alterino il metabolismo e la funzione delle HSC. Abbiamo trovato un arricchimento positivo dei geni dell'omeostasi del ferro nelle HSC dei topi talassemici th3, suggerendo un aumento dell'assorbimento e dell'immagazzinamento del ferro. Coerentemente, abbiamo rilevato alti livelli di ferro reattivo libero nel citoplasma e nei mitocondri di th3 HSC, che correlano con alti livelli di ROS. Di conseguenza, i mitocondri sono alterati, con ridotta massa e attività. I progenitori multipotenti th3 hanno ereditato mitocondri disfunzionali poiché la correzione dell'attività mitocondriale si è verificata nella transizione verso progenitori più differenziati. In linea con la disfunzione mitocondriale, le HSC th3 hanno una ridotta produzione di ATP mediante OXPHOS e dipendono dalla glicolisi. La riduzione in vivo dei ROS mitocondriali ha ripristinato l'attività e il metabolismo mitocondriali e ha aumentato la frequenza e la quiescenza delle HSC th3, dimostrando così che lo stress ossidativo è la causa della disfunzione mitocondriale e dei potenziali difetti delle HSC. È importante sottolineare che la somministrazione in vivo di ferro destrano a topi wt ha generato eccesso di ferro intracellulare e stress ossidativo mitocondriale e una ridotta attività mitocondriale nelle HSC, indicando che il sovraccarico di ferro da solo è sufficiente per compromettere i mitocondri. Il nostro studio rivela che il sovraccarico di ferro ha un impatto diretto sul metabolismo delle HSC inducendo stress ossidativo e disfunzione mitocondriale. Le alterazioni dell'attività mitocondriale e del profilo metabolico, in risposta al sovraccarico di ferro, potrebbero alterare la funzione delle HSC. Questa ricerca aggiungerà nuove informazioni sul ruolo del ferro nella regolazione del metabolismo delle HSC e fornirà nuove conoscenze utili per migliorare le condizioni cliniche caratterizzate da sovraccarico di ferro, come BThal.
Fosset, Cedric. "Iron and copper interactions in humans : models and mechanisms". Thesis, Robert Gordon University, 2002. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.268863.
Texto completo da fonteMorris, Patricia Ann. "EXAFS of non-heme iron containing proteins". Diss., Georgia Institute of Technology, 1986. http://hdl.handle.net/1853/27402.
Texto completo da fontePeers, Graham Stewart. "Increased metabolic requirements for manganese and copper in iron-limited marine diatoms". Thesis, McGill University, 2005. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=85950.
Texto completo da fonteConstante, Pereira Marco. "Development of synthetic biology devices for iron metabolism research". Doctoral thesis, Universitat Pompeu Fabra, 2011. http://hdl.handle.net/10803/53579.
Texto completo da fonteLa biología sintética es un campo recientemente desarrollado con el objectivo de implementar nuevas funciones en sistemas biológicos. De forma global, la biología sintética incluye el desarrollo de herramientas para facilitar la ingeniería de sistemas biológicos. En diversas publicaciones, investigadores en el campo de la biología sintética han implementado dispositivos que funcionan de forma similar a circuitos electrónicos y han demonstrado el potencial del campo para la producción de biocarburantes, farmaceuticos y biosensores. Para la presente tesis he creado una colección de plasmidos estandarizados (Biobricks) que pueden ser de interés para biólogos fuera del campo da la biología sintética. Además, utilizando estos Biobricks, he creado un sensor de la actividad de las proteínas reguladas por el hierro. Para demonstrar su aplicación, he utilizado el sensor para estudiar un nuevo sistema de co-cultura de dos tipos celulares (BNL CL.2 y RAW 264.7), substituto para la comunicación entre hepatocitos y macrófagos
Metzendorf, Christoph. "Mitochondrial Iron Metabolism : Study of mitoferrin in Drosophila melanogaster". Doctoral thesis, Uppsala universitet, Jämförande fysiologi, 2010. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-114201.
Texto completo da fonteProcter, Catherine M. "The roles of the FRO genes in iron metabolism". Thesis, University of Newcastle Upon Tyne, 1999. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.313219.
Texto completo da fonteSchiffhauer, Samuel Peter. "Crosstalk Signaling Between Circadian Clock Components and Iron Metabolism". Diss., Virginia Tech, 2017. http://hdl.handle.net/10919/85398.
Texto completo da fontePh. D.
Rhodes, Christopher James. "Iron metabolism and biomarkers in idiopathic pulmonary arterial hypertension". Thesis, Imperial College London, 2011. http://hdl.handle.net/10044/1/6915.
Texto completo da fonteMüller, Katrin [Verfasser]. "Regulation of iron metabolism during liver injury / Katrin Müller". Ulm : Universität Ulm. Fakultät für Naturwissenschaften, 2013. http://d-nb.info/1038734851/34.
Texto completo da fonteRicard, Michelle. "Iron acquisition from porcine proteins by Actinobacillus pleuropneumoniae biotype 1". Thesis, National Library of Canada = Bibliothèque nationale du Canada, 1999. http://www.collectionscanada.ca/obj/s4/f2/dsk1/tape2/PQDD_0034/MQ64438.pdf.
Texto completo da fonteHawula, Zachary John. "Identification and analysis of genetic and chemical modulators of iron metabolism". Thesis, Queensland University of Technology, 2021. https://eprints.qut.edu.au/225904/1/Zachary_Hawula_Thesis.pdf.
Texto completo da fonteSalmon, Timothy Peter Civil & Environmental Engineering Faculty of Engineering UNSW. "Physiological and genetic characterisation of iron acquisition by the coastal cyanobacterium Lyngbya majuscula (Oscillatoriales)". Publisher:University of New South Wales. Civil & Environmental Engineering, 2007. http://handle.unsw.edu.au/1959.4/40725.
Texto completo da fonteD'Silva, Colin Gerard. "Iron acquisition by Actinobacillus pleuropneumoniae". Thesis, McGill University, 1995. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=28720.
Texto completo da fonteMettrick, Karla Adelle, e n/a. "Iron signalling pathways of Pseudomonas aeruginosa". University of Otago. Department of Biochemistry, 2008. http://adt.otago.ac.nz./public/adt-NZDU20081128.143145.
Texto completo da fontePark, Thomas. "The Role of NfuA Protein in Acinetobacter baumannii Iron Metabolism". Miami University Honors Theses / OhioLINK, 2011. http://rave.ohiolink.edu/etdc/view?acc_num=muhonors1303498264.
Texto completo da fonteStrickland, Natalie Judith. "In silico and functional analyses of the iron metabolism pathway". Thesis, Stellenbosch : Stellenbosch University, 2013. http://hdl.handle.net/10019.1/79871.
Texto completo da fonteENGLISH ABSTRACT: Iron is an essential micronutrient that is an absolute requirement for correct cellular function in all eukaryotic organisms. However, ferrous iron has the ability to catalyze the formation of potentially toxic reactive oxygen species and regulation of iron metabolism is therefore of critical importance. Currently, there is little known about the co-ordinated regulation of the plethora of genes coding for proteins involved in this biochemical pathway, with the exception of the well characterized post-transcriptional IRE/IRP system. Regulation of gene expression in eukaryotic organisms is a highly intricate process. Transcriptional regulation is the first step and is controlled by the presence of specific cis-regulatory regions (cis-motifs), residing within the promoter region of genes, and the functional interactions between the products of specific regulatory genes (transcription factors) and these cismotifs. A combinatorial bioinformatic and functional approach was designed and utilized in this study for the analysis of the promoter architecture of genes of the iron metabolic pathway. The upstream non-coding region (~2 kb) of 18 genes (ACO1, CP, CYBRD1, FTH1, FTL, HAMP, HEPH, HFE, HFE2, HMOX1, IREB2, LTF, SLC11A2, SLC40A1, STEAP3, TF, TFRC, TFR2), known to be involved in the iron metabolism pathway, was subjected to computational analyses to identify regions of conserved nucleotide identity utilizing specific software tools. A subset of nine (CYBRD1, FTH1, HAMP, HFE, HFE2, HMOX1, IREB2, LTF, TFRC) of the genes were found to contain a genomic region that demonstrated over 75% sequence identity between the genes of interest. This conserved region (CR) is approximately 140 bp in size and was identified in each of the promoters of the nine genes. The CR was subjected to further detailed examination with comparative algorithms from different software for motif detection. Four specific cis-motifs were discovered within the CR, which were found to be in the same genomic position and orientation in each of the CR-containing genes. In silico prediction of putative transcription factor binding sites revealed the presence of numerous binding motifs of interest that could credibly be associated with a biological function in this pathway, including a novel MTF-1 binding site in five of the genes of interest. Validation of the bioinformatic predictions was performed in order to fully assess the relevance of the results in an in vitro setting. Luciferase reporter constructs for the nine CRcontaining genes were designed containing: 1) the 2 kb promoter, 2) a 1.86 kb promoter with the CR removed and 3) the 140 bp CR element. The expression levels of these three reporter gene constructs were monitored with a dual-luciferase reporter assay under standard culture conditions and simulated iron overload conditions in two different mammalian cell lines. Results of the luciferase assays indicate that the CR promoter constructs displayed statistically significant variation in expression values when compared to the untreated control constructs. Further, the CR appears to mediate transcriptional regulatory effects via an iron-independent mechanism. It is therefore apparent that the bioinformatic predictions were shown to be functionally relevant in this study and warrant further investigation. Results of these experiments represent a unique and comprehensive overview of novel transcriptional control elements of the iron metabolic pathway. The findings of this study strengthen the hypothesis that genes with similar promoter architecture, and involved in a common pathway, may be co-regulated. In addition, the combinatorial strategy employed in this study has applications in alternate pathways, and could serve as a refined approach for the prediction and study of regulatory targets in non-coding genomic DNA.
AFRIKAANSE OPSOMMING: Yster is ‘n noodsaaklike mikrovoedingstof wat ‘n vereiste is vir korrekte sellulêre funksie in alle eukariotiese organismes. Yster (II) of Fe2+ het egter die vermoë om die vorming van potensiële toksies reaktiewe suurstof spesies te kataliseer en dus is die regulasie van die yster metaboliese padweg van kardinale belang. Tans is daar beperkte inligting oor koördineerde regulasie van die gene, en dus proteïene waarvoor dit kodeer, in hierdie padweg. ‘n Uitsondering is die goed gekarakteriseerde na-transkripsionele “IRE/IRP” sisteem. Regulasie van geenuitdrukking in eukariotiese organismes is ‘n ingewikkelde proses. Transkripsionele regulasie is die eerste stap en word beheer deur die teenwoordigheid van spesefieke cis-regulatoriese elemente (cis-motiewe), geleë in die promotor area van gene, en die funksionele interaksies wat plaasvind tussen die produkte van spesifieke regulatoriese faktore (of transkripsie faktore) en hierdie cis-motiewe. ‘n Gekombineerde bioinformatiese en funksionele benadering was ontwerp en daarna gebruik in dié studie vir die analise van die promotor argitektuur van gene wat ‘n rol speel in die yster metaboliese padweg. Die stroomop nie-koderende streek (~2 kb) van 18 gene (ACO1, CP, CYBRD1, FTH1, FTL, HAMP, HEPH, HFE, HFE2, HMOX1, IREB2, LTF, SCL11A2, SLC40A1, STEAP3, TF, TFRC, TFR2), bekend vir hul betrokkenheid in die yster metabolisme padweg, was bloodgestel aan bioinformatiese analises om die streke van konservering te identifiseer met die hulp van spesifieke sagteware. Slegs nege (CYBRD1, FTH1, HAMP, HFE, HFE2, HMOX1, IREB2, LTF, TFRC) van die geanaliseerde gene het ‘n genomiese area bevat wat meer as 75% konservering getoon het. Hierdie gekonserveerde area (GA) is 140 bp in lengte en is geïdentifiseer in elk van die promotors van die nege gene. Die GA was verder bloodgestel aan analises, met die hulp van spesifieke sgateware, wat gebruik maak van vergelykende algoritmes vir motief karakterisering. Vier cis-motiewe is identifiseer en kom voor in dieselfde volgorde en oriëntasie in elk van die gene. In silico voorspelling van moontlike transkripsie faktor bindingsplekke het getoon dat daar talle bindingsmotiewe van belang teenwoordig is en dié motiewe kan gekoppel word aan biologiese funksies in hierdie padweg, insluitend ‘n nuwe MTF-1 bindingsplek in vyf van die gene van belang. Die bioinformatiese analises is verder gevalideer om die relevansie van die resultate in ‘n in vitro sisteem ten volle te assesseer. Luciferase rapporteerder konstrukte is vir die nege gene ontwerp wat die volgende bevat: 1) die 2 kb promotor, 2) ‘n 1.86 kb promotor met die GA verwyder en 3) die 140 bp GA element. Die vlakke van uitdrukking van hierdie drie rapporteerder konstrukte was genormaliseer met ‘n dubbele-luciferase rapporteerder assay onder standaard kultuur kondisies en gesimuleerde ysteroorlading kondisies in twee verskillende soogdier sellyne. Resultate van die luciferase assays dui aan dat die GA promotor konstrukte statisties betekenisvolle variasie toon in vergelyking met die onbehandelde kontrole konstrukte. Verder, die GA blyk om transkipsionele regulatoriese effekte te medieer via ‘n yster-onafhanklike meganisme. Dit blyk duidelik dat die bioinformatiese voorspellings ook funksioneel getoon kon word en was dus relevant in dié studie en regverdig verdere ondersoek. Hierdie eksperimentele ontwerp verteenwoordig ‘n unieke en omvattende oorsig van nuwe transkripsionele beheer elemente wat voorkom in die yster metaboliese padweg. Die resultate van dié studie versterk die hipotese dat gene met soortgelyke promotor argitektuur en wat betrokke is in ‘n gemene padweg saam gereguleer kan word. Daarbenewens, die gekombineerde strategie wat in hierdie studie gebruik is het toepassings in alternatiewe metaboliese paaie, en kan dien as ‘n verfynde benadering vir die voorspelling en studie van die regulerende teikens in nie-koderende genomiese DNS.
National Research Foundation (Thuthuka)
Stellenbosch University
Vazzola, V. "Frataxin, a protein involved in iron metabolism, in Arabidopsis thaliana". Doctoral thesis, Università degli Studi di Milano, 2009. http://hdl.handle.net/2434/61969.
Texto completo da fonteTilley, Gareth John. "Electrochemical investigations into iron-sulfur cluster containing proteins". Thesis, University of Oxford, 2001. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.365300.
Texto completo da fonte