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The iron element (Fe) is strictly required for the survival of most forms of life, including bacteria, plants and humans. Fine-tuned regulatory mechanisms for Fe absorption, mobilization and recycling operate to maintain Fe homeostasis, the disruption of which leads to Fe overload or Fe depletion. Whereas the deleterious effect of Fe deficiency relies on reduced oxygen transport and diminished activity of Fe-dependent enzymes, the cytotoxicity induced by Fe overload is due to the ability of this metal to act as a pro-oxidant and catalyze the formation of highly reactive hydroxyl radicals via the Fenton chemistry. This results in unfettered oxidative stress generation that, by inducing protein, lipid and DNA oxidation, leads to Fe-mediated programmed cell death and organ dysfunction. Major and systemic Fe overloads occurring in hemochromatosis and Fe-loading anemias have been extensively studied. However, localized tissue Fe overload was recently associated to a variety of pathologies, such as infection, inflammation, cancer, cardiovascular and neurodegenerative disorders. In keeping with the existence of cross-regulatory interactions between Fe homeostasis and the pathophysiology of these diseases, further investigations on the mechanisms that provide cellular and systemic adaptation to tissue Fe overload are instrumental for future therapeutic approaches. Thus, we encourage our colleagues to submit original research papers, reviews, perspectives, methods and technology reports to contribute their findings to a current state of the art on a comprehensive overview of the importance of iron metabolism in pathophysiologic conditions.

Iron --- Iron deficiency anemia. --- iron metabolism --- iron and genetic disorder --- iron and inflammation --- Heme --- iron and cardiotoxicity --- iron and neurodegeneration --- Iron deficiency and anemia --- Metabolism.

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The iron element (Fe) is strictly required for the survival of most forms of life, including bacteria, plants and humans. Fine-tuned regulatory mechanisms for Fe absorption, mobilization and recycling operate to maintain Fe homeostasis, the disruption of which leads to Fe overload or Fe depletion. Whereas the deleterious effect of Fe deficiency relies on reduced oxygen transport and diminished activity of Fe-dependent enzymes, the cytotoxicity induced by Fe overload is due to the ability of this metal to act as a pro-oxidant and catalyze the formation of highly reactive hydroxyl radicals via the Fenton chemistry. This results in unfettered oxidative stress generation that, by inducing protein, lipid and DNA oxidation, leads to Fe-mediated programmed cell death and organ dysfunction. Major and systemic Fe overloads occurring in hemochromatosis and Fe-loading anemias have been extensively studied. However, localized tissue Fe overload was recently associated to a variety of pathologies, such as infection, inflammation, cancer, cardiovascular and neurodegenerative disorders. In keeping with the existence of cross-regulatory interactions between Fe homeostasis and the pathophysiology of these diseases, further investigations on the mechanisms that provide cellular and systemic adaptation to tissue Fe overload are instrumental for future therapeutic approaches. Thus, we encourage our colleagues to submit original research papers, reviews, perspectives, methods and technology reports to contribute their findings to a current state of the art on a comprehensive overview of the importance of iron metabolism in pathophysiologic conditions.

Iron --- Iron deficiency anemia. --- Metabolism. --- iron metabolism --- iron and genetic disorder --- iron and inflammation --- Heme --- iron and cardiotoxicity --- iron and neurodegeneration --- Iron deficiency and anemia

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Genetics, Medical. --- Genetic Diseases, Inborn. --- Human Genetics --- Medical Genetics --- Genetics, Human --- Anthropology, Physical --- Chromosome Disorders --- Sex Chromosome Disorders --- Genetic Diseases, Inborn --- Molecular Medicine --- Genetic Diseases --- Genetic Disorders --- Hereditary Disease --- Inborn Genetic Diseases --- Single-Gene Defects --- Hereditary Diseases --- Defect, Single-Gene --- Defects, Single-Gene --- Disease, Genetic --- Disease, Hereditary --- Disease, Inborn Genetic --- Diseases, Genetic --- Diseases, Hereditary --- Diseases, Inborn Genetic --- Disorder, Genetic --- Disorders, Genetic --- Genetic Disease --- Genetic Disease, Inborn --- Genetic Disorder --- Inborn Genetic Disease --- Single Gene Defects --- Single-Gene Defect --- Genetics, Medical

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Genetics --- Hereditary diseases. --- human. --- Human. --- Genetics, Medical --- Genetic Diseases, Inborn --- Genetic Diseases --- Genetic Disorders --- Hereditary Disease --- Inborn Genetic Diseases --- Single-Gene Defects --- Hereditary Diseases --- Defect, Single-Gene --- Defects, Single-Gene --- Disease, Genetic --- Disease, Hereditary --- Disease, Inborn Genetic --- Diseases, Genetic --- Diseases, Hereditary --- Diseases, Inborn Genetic --- Disorder, Genetic --- Disorders, Genetic --- Genetic Disease --- Genetic Disease, Inborn --- Genetic Disorder --- Inborn Genetic Disease --- Single Gene Defects --- Single-Gene Defect --- Medical Genetics --- Anthropology, Physical --- Chromosome Disorders --- Sex Chromosome Disorders --- Molecular Medicine --- Genetics, Medical.

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In horticulture, plant propagation plays an important role, as the number of plants can be rapidly multiplied, retaining the desirable characteristics of the mother plants, and shortening the bearing age of plants. There are two primary forms of plant propagation: sexual and asexual. In nature, the propagation of plants most often involves sexual reproduction, and this form is still used in several species. Over the years, horticulturists have developed asexual propagation methods that use vegetative plant parts. Innovation in plant propagation has supported breeding programs and allowed the production of high quality nursery plants with the same genetic characteristics of the mother plant, free of diseases or pests.

Carya illinoinensis --- orchards --- seedlings production --- emergence rate --- Ericaceae --- Vaccinium virgatum --- micropropagation --- in vitro culture --- cytokinins --- zeatin --- 2iP --- BAP --- kinetin --- WPM --- clone aging --- foundation-stock --- genetic-disorder --- non-infectious --- epigenetic --- pepper --- propagation --- domestic --- wild --- protocorm-like bodies --- light-emitting diode --- trehalose --- maltose --- CCC --- correlation --- growth retardants --- rooting --- cutting --- forcing --- oleander --- shading --- acclimatization --- auxins --- Dracaena draco --- in vitro --- auxin --- rhizobacteria --- Vaccinium spp. --- bacterial wilt --- Solanum melongena --- susceptible --- tolerance --- exopolysaccharides --- cell wall degrading enzymes --- nursery plants --- plant multiplication --- seeds --- cuttings --- budding --- grafting --- biotechnology