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Iron as Therapeutic Targets in Human Diseases Volume 1

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ISBN: 9783039280827 9783039280834 Year: Pages: 472 DOI: 10.3390/books978-3-03928-083-4 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Science (General) --- Biology --- Biochemistry
Added to DOAB on : 2020-04-07 23:07:08
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Abstract

Iron is an essential element for almost all organisms, a cofactor playing a crucial role in a number of vital functions, including oxygen transport, DNA synthesis, and respiration. However, its ability to exchange electrons renders excess iron potentially toxic, since it is capable of catalyzing the formation of highly poisonous free radicals. As a consequence, iron homeostasis is tightly controlled by sophisticated mechanisms that have been partially elucidated. Because of its biological importance, numerous disorders have been recently linked to the deregulation of iron homeostasis, which include not only the typical disorders of iron overload and deficiency but also cancer and neurodegenerative diseases. This leads iron metabolism to become an interesting therapeutic target for novel pharmacological treatments against these diseases. Several therapies are currently under development for hematological disorders, while other are being considered for different pathologies. The therapeutic targeting under study includes the hepcidin/ferroportin axis for the regulation of systemic iron homeostasis, complex cytosolic machineries for the regulation of the intracellular iron status and its association with oxidative damage, and reagents exploiting proteins of iron metabolism such as ferritin and transferrin receptor. A promising potential target is a recently described form of programmed cell death named ferroptosis, in which the role of iron is essential but not completely clarified. This Special Issue has the aim to summarize the state-of-the-art, and the latest findings published in the iron field, as well as to elucidate future directions.

Keywords

cinnamic acid derivatives --- soybean seed ferritin --- iron release --- binding ability --- Fe2+-chelating activity --- reducibility --- adverse event profile --- anaemia --- bioengineering --- labile iron --- intravenous iron --- iron-carbohydrate complex --- iron processing --- iron metabolism --- infection --- innate immunity --- hepcidin --- ferritin --- anemia of inflammation --- pharmaceutical targets --- iron deficiency anemia --- nutrient iron --- oral iron therapy --- FeSO4 --- NaFeEDTA --- non-transferrin-bound iron (NTBI) --- developing countries --- Indonesia --- neurodegeneration --- mitochondria --- therapy --- heme --- haem --- Iron-sulfur --- Friedreich Ataxia --- Oxidative stress --- Iron chelators --- iron deficiency --- anemia --- cancer --- hepcidin --- patient blood management --- malaria --- iron deficiency --- hepcidin --- TNF --- children --- Africa --- Anemia --- iron deficiency --- oral iron salts --- intravenous iron --- Sucrosomial® iron --- M cells --- bioavailability --- tolerability --- efficacy --- iron --- gut microbiota --- iron supplementation --- iron transporters --- mucosal immunity --- SCFA --- intestinal inflammation --- inflammatory bowel disease (IBD) --- colorectal cancer --- oxidative stress --- anaemia --- cardiovascular disease --- chronic kidney disease --- IV iron therapy --- bone homeostasis --- iron overload --- iron deficiency --- osteoclast --- osteoblast --- osteoporosis --- neurodegeneration with brain iron accumulation --- iron chelation therapy --- multifunctional iron chelators --- fluorescent iron chelator --- 3-hydroxy-4-pyridinone --- fluorophore --- rhodamine --- membrane interactions --- bacteria --- antibacterial activity --- histidine --- iron --- anemia --- oxidative stress --- kidney --- chelation --- iron --- retina --- age-related macular degeneration (AMD) --- iron --- lipid --- obesity --- cancer --- neurodegeneration --- iron chelation --- phlebotomy --- NCOA4 --- ferritinophagy --- iron homeostasis --- erythropoiesis --- ferroptosis --- cancer --- Tfr2 --- iron metabolism --- hepcidin --- erythropoiesis --- SNC --- ferritin --- iron mobilization --- chaotropes --- flavin nucleotide --- electron transfer --- kinetics --- ferritin --- iron --- iron delivery --- nanotechnology --- nanocage --- drug delivery --- inflammation --- serum biomarker --- iron metabolism --- hepcidin --- ferroportin --- hemochromatosis --- anemia --- hepcidin --- iron deficiency anemia --- iron dextran --- neonatal period --- pig --- supplementation --- Alzheimer’s disease --- neuroinflammation --- neurodegeneration --- cytokines --- neuroimmune responses --- iron --- genetic hemochromatosis --- non transferrin bound iron --- hepcidin --- ferroportin --- venesections --- Anemia of chronic disease --- anemia of inflammation --- hepcidin --- anti-hepcidin therapy --- iron supplementation --- macrophage --- central nurse macrophage --- red pulp macrophage --- Kupffer cell --- iron metabolism --- erythropoiesis --- erythroblastic islands --- erythrophagocytosis --- inflammation --- iron homeostasis --- lung diseases --- oxygen sensing --- hypoxia --- ferritin --- hereditary hyperferritinemia --- hereditary hypoferritinemia --- iron metabolism --- cataracts syndrome --- neurodegenerative disease --- n/a --- iron --- neurodegeneration --- NBIA --- hepcidin --- iron --- lung --- acute lung injury --- COPD --- lung infection --- cystic fibrosis --- iron --- anaemia --- infection --- malaria --- immunity --- brain development --- growth --- microbiome --- hepcidin --- ferritin --- iron supplementation --- infants --- children --- low and middle income countries --- liver --- iron --- hepcidin --- Mek/Erk --- Hfe --- Bmp/Smad --- iron --- mycobacteria --- immunity --- Alzheimer’s disease --- iron homeostasis --- ferroptosis --- senescence --- chelators --- macrophages --- iron --- metabolism --- inflammation --- iron --- ferritin --- acute kidney injury --- chronic kidney disease --- vascular calcification --- iron --- hepcidin --- ferroportin --- Interleukin-6 --- infection --- rheumatoid arthritis --- iron homeostasis --- iron absorption --- non-haem iron --- flavonoids --- developmental --- iron deficiency anemia --- neonatal --- transferrin receptor --- treatment --- hemochromatosis --- HFE --- natural history --- T lymphocytes --- MHC --- CD8+ T cells --- prevention --- iron homeostasis --- hepcidin --- protein binding --- peritoneal dialysis --- iron --- hepcidin --- iron regulatory proteins --- cardiomyocyte --- chronic heart failure --- pulmonary arterial smooth muscle cells --- pulmonary arterial hypertension --- iron --- brain --- neurophysiology --- cognition --- social behavior --- didox --- iron chelators --- antitumor compound --- iron metabolism --- RRM2 --- SLC40A1 --- ferroportin --- iron overload --- non-HFE --- ferritin --- hemochromatosis --- iron --- chelation --- neurodegenerative diseases --- pituitary --- brain --- hemopexin --- heme homeostasis --- iron homeostasis --- hemolysis --- haptoglobin --- ferroptosis --- inflammation --- biomarker --- heme oxygenase --- liver --- microbiome --- trauma --- hemorrhage --- iron metabolism --- hepcidin --- iron homeostasis --- ferroportin --- n/a

Iron as Therapeutic Targets in Human Diseases Volume 2

Authors: --- ---
ISBN: 9783039281145 9783039281152 Year: Pages: 440 DOI: 10.3390/books978-3-03928-115-2 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Science (General) --- Biology --- Biochemistry
Added to DOAB on : 2020-04-07 23:07:08
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Abstract

Iron is an essential element for almost all organisms, a cofactor playing a crucial role in a number of vital functions, including oxygen transport, DNA synthesis, and respiration. However, its ability to exchange electrons renders excess iron potentially toxic, since it is capable of catalyzing the formation of highly poisonous free radicals. As a consequence, iron homeostasis is tightly controlled by sophisticated mechanisms that have been partially elucidated. Because of its biological importance, numerous disorders have been recently linked to the deregulation of iron homeostasis, which include not only the typical disorders of iron overload and deficiency but also cancer and neurodegenerative diseases. This leads iron metabolism to become an interesting therapeutic target for novel pharmacological treatments against these diseases. Several therapies are currently under development for hematological disorders, while other are being considered for different pathologies. The therapeutic targeting under study includes the hepcidin/ferroportin axis for the regulation of systemic iron homeostasis, complex cytosolic machineries for the regulation of the intracellular iron status and its association with oxidative damage, and reagents exploiting proteins of iron metabolism such as ferritin and transferrin receptor. A promising potential target is a recently described form of programmed cell death named ferroptosis, in which the role of iron is essential but not completely clarified. This Special Issue has the aim to summarize the state-of-the-art, and the latest findings published in the iron field, as well as to elucidate future directions.

Keywords

cinnamic acid derivatives --- soybean seed ferritin --- iron release --- binding ability --- Fe2+-chelating activity --- reducibility --- adverse event profile --- anaemia --- bioengineering --- labile iron --- intravenous iron --- iron-carbohydrate complex --- iron processing --- iron metabolism --- infection --- innate immunity --- hepcidin --- ferritin --- anemia of inflammation --- pharmaceutical targets --- iron deficiency anemia --- nutrient iron --- oral iron therapy --- FeSO4 --- NaFeEDTA --- non-transferrin-bound iron (NTBI) --- developing countries --- Indonesia --- neurodegeneration --- mitochondria --- therapy --- heme --- haem --- Iron-sulfur --- Friedreich Ataxia --- Oxidative stress --- Iron chelators --- iron deficiency --- anemia --- cancer --- hepcidin --- patient blood management --- malaria --- iron deficiency --- hepcidin --- TNF --- children --- Africa --- Anemia --- iron deficiency --- oral iron salts --- intravenous iron --- Sucrosomial® iron --- M cells --- bioavailability --- tolerability --- efficacy --- iron --- gut microbiota --- iron supplementation --- iron transporters --- mucosal immunity --- SCFA --- intestinal inflammation --- inflammatory bowel disease (IBD) --- colorectal cancer --- oxidative stress --- anaemia --- cardiovascular disease --- chronic kidney disease --- IV iron therapy --- bone homeostasis --- iron overload --- iron deficiency --- osteoclast --- osteoblast --- osteoporosis --- neurodegeneration with brain iron accumulation --- iron chelation therapy --- multifunctional iron chelators --- fluorescent iron chelator --- 3-hydroxy-4-pyridinone --- fluorophore --- rhodamine --- membrane interactions --- bacteria --- antibacterial activity --- histidine --- iron --- anemia --- oxidative stress --- kidney --- chelation --- iron --- retina --- age-related macular degeneration (AMD) --- iron --- lipid --- obesity --- cancer --- neurodegeneration --- iron chelation --- phlebotomy --- NCOA4 --- ferritinophagy --- iron homeostasis --- erythropoiesis --- ferroptosis --- cancer --- Tfr2 --- iron metabolism --- hepcidin --- erythropoiesis --- SNC --- ferritin --- iron mobilization --- chaotropes --- flavin nucleotide --- electron transfer --- kinetics --- ferritin --- iron --- iron delivery --- nanotechnology --- nanocage --- drug delivery --- inflammation --- serum biomarker --- iron metabolism --- hepcidin --- ferroportin --- hemochromatosis --- anemia --- hepcidin --- iron deficiency anemia --- iron dextran --- neonatal period --- pig --- supplementation --- Alzheimer’s disease --- neuroinflammation --- neurodegeneration --- cytokines --- neuroimmune responses --- iron --- genetic hemochromatosis --- non transferrin bound iron --- hepcidin --- ferroportin --- venesections --- Anemia of chronic disease --- anemia of inflammation --- hepcidin --- anti-hepcidin therapy --- iron supplementation --- macrophage --- central nurse macrophage --- red pulp macrophage --- Kupffer cell --- iron metabolism --- erythropoiesis --- erythroblastic islands --- erythrophagocytosis --- inflammation --- iron homeostasis --- lung diseases --- oxygen sensing --- hypoxia --- ferritin --- hereditary hyperferritinemia --- hereditary hypoferritinemia --- iron metabolism --- cataracts syndrome --- neurodegenerative disease --- n/a --- iron --- neurodegeneration --- NBIA --- hepcidin --- iron --- lung --- acute lung injury --- COPD --- lung infection --- cystic fibrosis --- iron --- anaemia --- infection --- malaria --- immunity --- brain development --- growth --- microbiome --- hepcidin --- ferritin --- iron supplementation --- infants --- children --- low and middle income countries --- liver --- iron --- hepcidin --- Mek/Erk --- Hfe --- Bmp/Smad --- iron --- mycobacteria --- immunity --- Alzheimer’s disease --- iron homeostasis --- ferroptosis --- senescence --- chelators --- macrophages --- iron --- metabolism --- inflammation --- iron --- ferritin --- acute kidney injury --- chronic kidney disease --- vascular calcification --- iron --- hepcidin --- ferroportin --- Interleukin-6 --- infection --- rheumatoid arthritis --- iron homeostasis --- iron absorption --- non-haem iron --- flavonoids --- developmental --- iron deficiency anemia --- neonatal --- transferrin receptor --- treatment --- hemochromatosis --- HFE --- natural history --- T lymphocytes --- MHC --- CD8+ T cells --- prevention --- iron homeostasis --- hepcidin --- protein binding --- peritoneal dialysis --- iron --- hepcidin --- iron regulatory proteins --- cardiomyocyte --- chronic heart failure --- pulmonary arterial smooth muscle cells --- pulmonary arterial hypertension --- iron --- brain --- neurophysiology --- cognition --- social behavior --- didox --- iron chelators --- antitumor compound --- iron metabolism --- RRM2 --- SLC40A1 --- ferroportin --- iron overload --- non-HFE --- ferritin --- hemochromatosis --- iron --- chelation --- neurodegenerative diseases --- pituitary --- brain --- hemopexin --- heme homeostasis --- iron homeostasis --- hemolysis --- haptoglobin --- ferroptosis --- inflammation --- biomarker --- heme oxygenase --- liver --- microbiome --- trauma --- hemorrhage --- iron metabolism --- hepcidin --- iron homeostasis --- ferroportin --- n/a

Genetic and Epigenetic Modulation of Cell Functions by Physical Exercise

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ISBN: 9783039284801 / 9783039284818 Year: Pages: 170 DOI: 10.3390/books978-3-03928-481-8 Language: eng
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Science (General) --- Biology --- Genetics
Added to DOAB on : 2020-06-09 16:38:57
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From an evolutionary perspective, our species has relied upon physical activity for most of its history to survive and has had to escape from predators, to scavenge for food, and to use physique to work or build necessary means for everyday life. Physical activity has been part of our evolution and progress since the very beginning and, consequently, our entire body has been programmed to be active physically. In the last 20 years, scientific research has increasingly shown that our ancient survival principle has beneficial effects not only on the cells and organs involved in physical activities but on the metabolism of the entire organism, influencing the homeostasis and integration of all bodily functions, likely stimulating the production of hormones and other regulatory molecules, with each affecting vital signalling pathways. Most of the web of factors involved in molecular signalling upon exercise are suspected to be centrally controlled by the brain, which has been reported to be deeply modified by physical activity. Such complexity requires a multifaceted approach to shed light on the molecular interactions that occur between physical activity and its outcome at a cellular level.

Dietary Trace Minerals

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ISBN: 9783039283248 9783039283255 Year: Pages: 208 DOI: 10.3390/books978-3-03928-325-5 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Science (General) --- Biology --- Nutrition and Food Sciences
Added to DOAB on : 2020-04-07 23:07:08
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Dietary trace minerals are pivotal and hold a key role in numerous metabolic processes. Trace mineral deficiencies (except for iodine, iron, and zinc) do not often develop spontaneously in adults on ordinary diets; infants are more vulnerable because their growth is rapid and their intake varies. Trace mineral imbalances can result from hereditary disorders (e.g., hemochromatosis, Wilson disease), kidney dialysis, parenteral nutrition, restrictive diets prescribed for people with inborn errors of metabolism, or various popular diet plans. The Special Issue “Dietary Trace Minerals” comprised 13 peer-reviewed papers on the most recent evidence regarding the dietary intake of trace minerals, as well as their effect on the prevention and treatment of non-communicable diseases. Original contributions and literature reviews further demonstrated the crucial and central part that dietary trace minerals play in human health and development. This editorial provides a brief and concise overview of the content of the Dietary Trace Minerals Special Issue.

Biological Crystallization

Authors: --- ---
ISBN: 9783039214037 9783039214044 Year: Pages: 184 DOI: 10.3390/books978-3-03921-404-4 Language: English
Publisher: MDPI - Multidisciplinary Digital Publishing Institute
Subject: Science (General) --- Biology
Added to DOAB on : 2019-12-09 11:49:15
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For at least six hundred million years, life has been a fascinating laboratory of crystallization, referred to as biomineralization. During this huge lapse of time, many organisms from diverse phyla have developed the capability to precipitate various types of minerals, exploring distinctive pathways for building sophisticated structural architectures for different purposes. The Darwinian exploration was performed by trial and error, but the success in terms of complexity and efficiency is evident. Understanding the strategies that those organisms employ for regulating the nucleation, growth, and assembly of nanocrystals to build these sophisticated devices is an intellectual challenge and a source of inspiration in fields as diverse as materials science, nanotechnology, and biomedicine. However, “Biological Crystallization” is a broader topic that includes biomineralization, but also the laboratory crystallization of biological compounds such as macromolecules, carbohydrates, or lipids, and the synthesis and fabrication of biomimetic materials by different routes. This Special Issue collects 15 contributions ranging from biological and biomimetic crystallization of calcium carbonate, calcium phosphate, and silica-carbonate self-assembled materials to the crystallization of biological macromolecules. Special attention has been paid to the fundamental phenomena of crystallization (nucleation and growth), and the applications of the crystals in biomedicine, environment, and materials science.

Keywords

polymyxin resistance --- colistin resistance --- MCR-1 --- protein crystal nucleation --- thermodynamic and energetic approach --- protein ‘affinity’ to water --- solubility --- balance between crystal bond energy and destructive surface energies --- supersaturation dependence of the crystal nucleus size --- ependymin (EPN) --- ependymin-related protein (EPDR) --- mammalian ependymin-related protein (MERP) --- Campylobacter consisus --- Crohn’s disease --- circular dichroism --- protein crystallization --- Csep1p --- protein crystallization --- biochemical aspects of the protein crystal nucleation --- classical and two-step crystal nucleation mechanisms --- bond selection during protein crystallization --- equilibration between crystal bond and destructive energies --- protein crystal nucleation in pores --- crystallization in solution flow --- crystallization --- microseed matrix screening --- seeding --- optimization --- human carbonic anhydrase IX --- neutron protein crystallography --- microbially induced calcite precipitation (MICP) --- heavy metals --- wastewater treatment --- bioprecipitation --- calcium carbonate --- drug discovery --- education --- crystallization --- crystallography --- nucleation --- micro-crystals --- agarose --- ferritin --- lysozyme --- proteinase k --- insulin --- calcium carbonate --- {00.1} calcite --- lithium ions --- ultrasonic irradiation --- vaterite transformation --- adsorption --- calcein --- crystal violet --- dyes --- diffusion --- H3O+ --- reductants --- color change --- gradients --- biomorphs --- barium carbonate --- silica --- PCDA --- pyrrole --- droplet array --- crystal growth --- calcium carbonate --- high-throughput --- biomimetic crystallization --- biomineralization --- polyacrylic acid --- Cry protein crystals --- metallothioneins --- bioremediation --- heavy metal contamination --- nanoapatites --- graphene --- crystallization --- nanocomposites --- lysozyme --- L-tryptophan --- N-acetyl-D-glucosamine --- chitosan --- MTT assay --- GTL-16 cells --- Haloalkane dehalogenase --- halide-binding site --- random microseeding --- biomineralization --- biomimetic materials --- biomorphs --- calcium carbonate --- nanoapatites --- nucleation --- growth --- crystallization of macromolecules --- bioremediation --- materials science --- biomedicine

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