Journal ArticleDOI
Mechanism of Iodine Uptake by Cabbage: Effects of Iodine Species and Where It is Stored
TLDR
Iodine uptake by Chinese cabbage was more effective than in the form of I− if the concentration was low, but the trend was opposite if iodine concentration was 0.5 mg L−1 or higher, which implies that the uptake mechanism transits from active to passive as the iodine concentration increases.Abstract:
Iodine-enhanced vegetable has been proven to be an effective way to reduce iodine deficiency disorders in many regions. However, the knowledge about what mechanisms control plant uptake of iodine and where iodine is stored in plants is still very limited. A series of controlled experiments, including solution culture, pot planting, and field experiments were carried out to investigate the uptake mechanism of iodine in different forms. A new methodology for observing the iodine distribution within the plant tissues, based on AgI precipitation reaction and transmission electron microscope techniques, has been developed and successfully applied to Chinese cabbage. Results show that iodine uptake by Chinese cabbage was more effective when iodine was in the form of IO(3) (-) than in the form of I(-) if the concentration was low (<0.5 mg L(-1)), but the trend was opposite if iodine concentration was 0.5 mg L(-1) or higher. The uptake was more sensitive to metabolism inhibitor in lower concentration of iodine, which implies that the uptake mechanism transits from active to passive as the iodine concentration increases, especially when the iodine is in the form of IO(3) (-). The inorganic iodine fertilizer provided a quicker supply for plant uptake, but the higher level of iodine was toxic to plant growth. The organic iodine fertilizer (seaweed composite) provided a more sustainable iodine supply for plants. Most of the iodine uptake by the cabbage is intercepted and stored in the fibrins in the root while the iodine that is transported to the above-ground portion (shoots and leaves) is selectively stored in the chloroplasts.read more
Citations
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Journal ArticleDOI
Hydroponic Solutions for Soilless Production Systems: Issues and Opportunities in a Smart Agriculture Perspective.
Paolo Sambo,Carlo Nicoletto,Andrea Giro,Youry Pii,Fabio Valentinuzzi,Tanja Mimmo,Paolo Lugli,Guido Orzes,Fabrizio Mazzetto,Stefania Astolfi,Roberto Terzano,Stefano Cesco +11 more
TL;DR: This review provides information on the processes and mechanisms occurring in the hydroponic solutions that ensure an adequate nutrient concentration and thus an optimal nutrient acquisition without leading to nutritional disorders influencing ultimately also crop quality.
Journal ArticleDOI
Iodine biofortification of crops: agronomic biofortification, metabolic engineering and iodine bioavailability.
TL;DR: This review describes the current knowledge regarding iodine physiology in higher plants, and provides updates on recent agronomic and metabolic engineering strategies of biofortification.
Journal ArticleDOI
Use of Iodine to Biofortify and Promote Growth and Stress Tolerance in Crops.
Julia Medrano-Macías,Paola Leija-Martínez,Susana González-Morales,Antonio Juárez-Maldonado,Adalberto Benavides-Mendoza +4 more
TL;DR: This review systematically presents the results published on the application of iodine in agriculture, considering different environmental conditions and farming systems in various species and varying concentrations of the element, its chemical forms, and its application method.
Journal ArticleDOI
Iodine biofortification in tomato
TL;DR: It is found that tomato plants can tolerate high levels of iodine, stored both in the vegetative tissues and fruits at concentrations that are more than sufficient for the human diet.
Journal ArticleDOI
Tomato fruits: a good target for iodine biofortification
Claudia Kiferle,Silvia Gonzali,Harmen Tjalling Holwerda,Rodrigo Real Ibaceta,Pierdomenico Perata +4 more
TL;DR: Results suggest that tomato is a particularly suitable crop for iodine biofortification programs, since 150 μg iodine per day is the recommended dietary allowance for adults.
References
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Journal ArticleDOI
Iodine deficiency disorders (idd) and their eradication
TL;DR: Use of the term iodine deficiency disorders, instead of "goitre", would help to bridge the serious gap between knowledge and its application, and the complete eradication of iodine deficiency is therefore feasible within 5-10 years.
Journal ArticleDOI
Subcellular Distribution and Chemical Form of Cadmium in Bean Plants
Hans J. Weigel,Hans J. Jäger +1 more
TL;DR: The subcellular distribution and chemical form of Cd in bean plants grown in nutrient solutions containing Cd were investigated, which resulted in the identification of nine amino acids which were identical in roots and leaves.
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Iodine uptake by spinach (Spinacia oleracea L.) plants grown in solution culture: effects of iodine species and solution concentrations
TL;DR: Results show that higher concentrations of I(-) (> or =10 microM) had some detrimental effect on plant growth, while IO(3)(-) had little effect on the biomass production of spinach plants.
Journal ArticleDOI
Iodine: an environmental trigger of thyroiditis.
TL;DR: It is shown that iodine enhances disease in a dose-dependent manner using a new animal model of autoimmune thyroiditis, the NOD.H2(h4) mouse, to show that iodine incorporation in the thyroglobulin may augment the antigenicity of this molecule.
Journal ArticleDOI
Volatilization of methyl iodide from the soil-plant system
TL;DR: Iodine volatilization from the soil-plant system has been studied by radiotracer experiments and gas chromatography as mentioned in this paper, and it was assumed that iodine in the flooded soil was methylated by the action of roots or microorganisms.