Global ETD Search

31	Increased metabolic requirements for manganese and copper in iron-limited marine diatoms Peers, Graham Stewart January 2005 (has links) No description available. Copper -- Metabolism. Thalassiosira. Marine phytoplankton. Iron -- Metabolism. Diatoms. Manganese -- Metabolism.
32	Changed iron metabolism and iron toxicity in scrapie-infected neuroblastoma cells Zetterström Fernaeus, Sandra January 2005 (has links) <p>Reactions 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.</p><p>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.</p><p>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.</p><p>In the third study, the cells were challenged with hydrogen peroxide (H<sub>2</sub>O<sub>2</sub>) 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 H<sub>2</sub>O<sub>2</sub> than the ScN2a cells, according to the cell viability assay.</p><p>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.</p> prion disease oxidative stress iron metabolism Neurochemistry Neurokemi
33	Changed iron metabolism and iron toxicity in scrapie-infected neuroblastoma cells Zetterström Fernaeus, Sandra January 2005 (has links) Reactions 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. prion disease oxidative stress iron metabolism Neurochemistry Neurokemi
34	Studies of iron metabolism and metabolic rate in iron-deficient and cold-acclimatized rats Quisumbing, Teresita Lambo. January 1985 (has links) published_or_final_version / Medical Sciences / Master / Master of Medical Sciences Iron deficiency anemia. Cold adaptation. Iron - Metabolism. Rats - Physiology.
35	Iron acquisition by marine phytoplankton Maldonado-Pareja, Maria Teresa. January 1999 (has links) Thalassiosira oceanica, a marine centric diatom, possesses an extracellular reductase that reduces iron (Fe(III)) bound to organic complexes as part of a high-affinity Fe transport mechanism. A number of Fe(III) organic complexes are reduced, including siderophores---effective Fe chelates produced by microorganims in response to Fe stress. Reduction rates are inversely related to the relative stability constants of the oxidized and reduced Fe chelates (log Kox/Kred), and vary by a factor of 2.4 in accordance with theoretical predictions. Under Fe-limiting conditions, reduction rates increase and the ability of T. oceanica to transport Fe from siderophores is enhanced. Iron bound to the siderophore desferrioxamine B (DFB) is reduced 2 times faster than it is taken up, suggesting that the reductase is well coupled to the Fe transporter, and can provide all the inorganic Fe to account for the measured Fe uptake rates in the presence of excess DFB. The efficacy of the reductase in providing inorganic Fe for uptake and growth is ultimately dependent on the relative concentrations of excess ligands in solution and cell surface Fe transporters competing for inorganic Fe. The rates of Fe reduction and uptake are twice as fast in cells grown in NO3- compared to those grown in NH 4+, suggesting a link with cellular N metabolism and with NO3- utilization in particular. Enhanced Fe reductase activity in NO3--grown cells enables them to maintain a 1.6-fold higher cellular Fe concentration under low Fe conditions. / Experiments conducted in the subarctic Pacific, an Fe-limited oceanic region, demonstrated that even indigenous plankton (both prokaryotic and eukaryotic plankton) have the ability to acquire Fe bound to strong organic chelates. Large phytoplankton species (>3 mum) reduce Fe bound to siderophores extracellularly. Because the predominant form of dissolved Fe in the sea is bound to strong organic complexes, a reductive mechanism as described here may be a critical step in Fe acquisition by phytoplankton. Iron -- Physiological transport. Iron -- Metabolism. Marine phytoplankton. Thalassiosira. Biogeochemical cycles.
36	Iron acquisition by Histophilus ovis Ekins, Andrew John January 2002 (has links) Five strains (9L, 642A, 714, 5688T and 3384Y) of Histophilus ovis were investigated with respect to iron acquisition. All strains used ovine, bovine and goat, but not porcine or human, transferrins (Tfs) as iron sources for growth. In solid phase binding assays, total membranes from only two (9L and 642A) of the five strains, grown under iron-restricted conditions, were able to bind Tfs (ovine, bovine and goat, but not porcine or human). However, when the organisms were grown under iron-restricted conditions in the presence of bovine Tf, total membranes from all strains exhibited Tf binding (as above); competition experiments demonstrated that all three Tfs (ovine, bovine and goat) were bound by the same receptor(s). An affinity isolation procedure allowed the isolation of two putative Tf-binding polypeptides (78 and 66 kDa) from total membranes of strains 9L and 642A grown under iron-restricted conditions, and from membranes of all strains if the growth medium also contained Tf. A gene encoding a Pasteurella multocida TbpA homologue was shown to be present in each of two representative strains (9L and 3384Y); these genes were sequenced and determined to be the structural genes encoding the 78-kDa Tf-binding polypeptides. The identification of a fur homologue and a Fur box within the promoter region of tbpA in both strains indicated that Fur (and iron) is responsible for the iron-repressible nature of Tf-binding activity. Although tbpA transcripts were detected by reverse transcription (RT)-PCR with RNA isolated from strains 9L and 3384Y grown under iron-restricted conditions, with strain 3384Y, and depending on the primer pair, tbpA transcripts were detected by RT-PCR predominantly when the RNA was isolated from cells grown under conditions of iron-restriction in the presence of Tf. The presence of an additional G in the tbpA gene of strain 3384Y grown under iron-replete conditions, compared to organisms grown under iron-restricted conditions plus bovine Tf, is Gram-negative bacteria -- Metabolism. Microbial metabolism. Iron -- Metabolism.
37	Role of oxidative stress in the regulation of iron regulatory protein 2 Lee, Julie, 1983- January 2008 (has links) Iron homeostasis is regulated by iron regulatory proteins, IRP1 and IRP2, which bind to iron responsive elements (IRE) in the mRNA of proteins of iron metabolism such as ferritin (iron storage). IRP2 undergoes iron-mediated degradation, and this pathway shares notable similarities with that of hypoxia-inducible factor 1 (HIF-1). It has been reported that oxidative stress marked by increased reactive oxygen species (ROS) signal HIF-1 stabilization in hypoxia. The role of ROS in IRP2 regulation is not well-established. We show that the degree of hypoxia induces differential effects on iron-mediated degradation of IRP2, such that IRP2 levels are 3-fold higher when exposed to 0.1% O 2 compared to 3% O2 after 4 hours of iron treatment. Hydrogen peroxide (H2O2) affects IRP2 by inducing IRE-binding activity after 12 hours, which is accompanied by decreased ferritin levels. Furthermore, the ability of H2O2 to protect IRP2 against iron-dependent degradation is similar to that of hypoxia. Finally, both intracellular and extracellular sources of oxidative stress protect IRP2 from ascorbate-mediated degradation. Taken together, these results support a role of ROS in protecting IRP2 against iron-mediated degradation and indicate that oxidative stress modulates downstream effects of IRP2. Iron -- metabolism. Iron Regulatory Protein 2 -- chemistry. Oxidative Stress -- genetics.
38	Iron acquisition by heterotrophic marine bacteria Granger, Julie. January 1998 (has links) Recent studies demonstrate that the dissolved iron in seawater is bound to strong organic complexes that have stability constants comparable to those of microbial iron chelates (siderophores). We investigated iron acquisition by 7 strains of heterotrophic marine bacteria using siderophores as a model for the natural iron-binding ligands. Siderophores were detected in the supernatants of 4 strains. All strains utilized iron bound to siderophores regardless of whether they produced their own. The majority took up iron bound to the fungal siderophore desferrioxamine B (dfoB). Over half also utilized iron bound to strain Neptune's siderophore, nep-L, while iron bound to pwf-L was available solely to the producing strain, Pwf3. Uptake rates of Fe-siderophores were similar among iron-limited strains and among ligands. Transport of Fe-dfoB in Neptune was enhanced 20 times by iron limitation. The half-saturation constant of Fe-dfoB transport was 15 nM, the lowest reported for Fe-siderophore transport in microorganisms. In contrast, uptake of inorganic iron (Fe' ) by iron-limited Neptune did not saturate at the highest concentration tested and was not upregulated under iron stress. This suggests that Fe ' uptake occurs by simple diffusion through the outer membrane. / Strain Lmg1, the sole catechol producer, did not take up iron bound to exogenous siderophores (dfoB, pwf-L, or nep-L). However, it utilized iron bound to its own ligand and, possibly, iron bound to the synthetic chelator EDTA. Transport of Fe' by iron-limited Lmg1 was 10 times higher than in the other strains and was upregulated 46 times in low iron conditions. The results suggest iron transport in Lmg 1 may be mediated by surface-associated catechol siderophores that scavenge inorganic ferric species as well as iron bound to weaker complexes, such as EDTA. This study elucidates the importance of siderophores in iron transport by heterotrophic marine bacteria. (Abstract shortened by UMI.) Iron -- Physiological transport. Iron -- Metabolism. Bacteria, Heterotrophic. Marine bacteria.
39	Increased metabolic requirements for manganese and copper in iron-limited marine diatoms Peers, Graham Stewart January 2005 (has links) Productivity in large areas of the world's oceans is limited by low concentrations of dissolved iron in surface waters. Phytoplankton have adapted to persist in these environments by reducing their requirements for iron (Fe) in key metabolic pathways, in some cases by replacing Fe-containing catalysts with their iron-free functional equivalents. This thesis examines the requirements and biochemical roles for copper (Cu) and manganese (Mn) in Fe-limited centric marine diatoms. A major finding of my research is that diatoms have elevated requirements for Mn and Cu when grown in Fe-deficient seawater. Iron deficiency induces oxidative stress and increases the cellular concentrations of toxic oxygen radicals and damage products in Thalassiosira pseudonana. The increased Mn-requirement is used, in part, to activate Mn-containing isoforms of the antioxidant enzyme superoxide dismutase. Cultures co-limited by Fe and Mn exhibit high levels of oxidative stress and an inefficient detoxification pathway that further reduces cell growth. Diatoms isolated from the metal poor open ocean require more Cu to divide than related species from metal-rich coastal waters. This pattern is in stark contrast to all other known nutritive trace metals. One part of the diatom Cu requirement that is independent of provenance is for efficient Fe transport. The additional Cu requirement of oceanic species appears to be due to the constitutive expression of a Cu-containing electron transport protein, possibly plastocyanin. Coastal species, which have higher Fe-requirements for growth, retain the Fe-containing functional homologue cytochrome c6. By employing metals other than Fe within photosynthesis and antioxidant pathways, marine diatoms are able to increase their fitness in Fe-deficient environments. However, Mn and Cu also occur in low concentrations in the open ocean and thus may co-limit growth of natural populations of phytoplankton. Metal enrichment experiments i Manganese -- Metabolism. Copper -- Metabolism. Iron -- Metabolism. Marine phytoplankton. Diatoms. Thalassiosira.
40	The role of iron in the ecology and physiology of marine bacteria / Adly, Carol. January 2005 (has links) Despite being abundant in the earth's crust, the concentration of Fe in many oceanic regions is so low that it is limiting to the growth of photosynthetic plankton. Heterotrophic bacteria play key roles in the oceanic cycling of carbon and nutrients, but it is unclear whether they can be Fe-deficient in nature, or what possible effects Fe-deficiency might have on their ecology and physiology. In chapter 1, I investigated the response of a natural bacterial community to a mesoscale Fe-enrichment experiment in the northeast subarctic Pacific. The addition of Fe to surface waters caused a rapid stimulation of bacterial growth and production, and induced the organic Fe uptake systems of bacteria. These findings suggest that bacteria responded directly to increased Fe availability, and may be Fe-deficient in situ. In chapter 2, I examined the effects of Fe-deficiency on the coupled processes of carbon catabolism and adenosine triphosphate (ATP) production in cultures of the marine bacterium Pseudoalteromonas haloplanktis. In Fe-limited cells, Fe-dependent oxidative pathways of ATP production were downregulated, leading to an intracellular energy deficit. Thus, by altering carbon metabolism and energy acquisition of heterotrophic bacteria, Fe may affect the cycling of carbon in parts of the sea. Iron -- Physiological transport. Iron -- Metabolism. Heterotrophic bacteria. Marine bacteria.

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