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1.
Plant Biol (Stuttg) ; 18(6): 1025-1030, 2016 Nov.
Article in English | MEDLINE | ID: mdl-27488096

ABSTRACT

Grasses accumulate high amounts of silica deposits in tissues of all their organs, especially at mature stage. However, when and under which conditions do grass seedlings begin to produce these silica deposits and their relation with anatomy and development is little known. Here we investigated the silicification process in the first leaves and roots of seedlings of Bothriochloa laguroides grown in different substrate and Si treatments. The distribution and content of silica deposits in the organs of the seedlings grown under different conditions were analyzed through staining techniques and SEM-EDAX analyses. Leaf silica deposits were accumulated 3-4 days after the first leaf emergence, also under low silica solution (0.17-0.2 mM). Their location was mainly restricted to short costal cells from basal sectors, and scarcely in trichomes and xylem at tips. Silica content in leaves increased with the age of the seedlings. Roots presented dome-shaped silica aggregates, between 4-12 µm of diameter, located in the inner tangential wall of endodermal cells and similar to those produced at maturity. Silicification begins early in the first photosynthetic leaf, and silica distribution is opposite to that found in mature plants, mainly restricted to basal sectors, probably acting as a reinforcing element. The fast incorporation of solid amorphous silica in leaves and roots, may be useful for farm applications in species that are Si-fertilized.


Subject(s)
Poaceae/metabolism , Silicon Dioxide/metabolism , Organ Specificity , Plant Leaves/chemistry , Plant Leaves/metabolism , Plant Leaves/ultrastructure , Plant Roots/chemistry , Plant Roots/metabolism , Plant Roots/ultrastructure , Poaceae/chemistry , Poaceae/ultrastructure , Seedlings/chemistry , Seedlings/metabolism , Seedlings/ultrastructure
2.
Mar Pollut Bull ; 79(1-2): 365-70, 2014 Feb 15.
Article in English | MEDLINE | ID: mdl-24308995

ABSTRACT

The degree of iron pyritization (DOP) and degree of trace metal pyritization (DTMP) were evaluated in mangrove soil profiles from an estuarine area located in Rio de Janeiro (SE Brazil). The soil pH was negatively correlated with redox potential (Eh) and positively correlated with DOP and DTMP of some elements (Mn, Cu and Pb), suggesting that pyrite oxidation generated acidity and can affect the importance of pyrite as a trace metal-binding phase, mainly in response to spatial variability in tidal flooding. Besides these aerobic oxidation effects, results from a sequential extraction analyses of reactive phases evidenced that Mn oxidized phase consumption in reaction with pyrite can be also important to determine the pyritization of trace elements. Cumulative effects of these aerobic and anaerobic oxidation processes were evidenced as factors affecting the capacity of mangrove soils to act as a sink for trace metals through pyritization processes.


Subject(s)
Environmental Monitoring , Metals/analysis , Soil Pollutants/analysis , Water Pollutants, Chemical/analysis , Wetlands , Anaerobiosis , Biodegradation, Environmental , Brazil , Geologic Sediments/chemistry , Iron/chemistry , Metals/chemistry , Oxidation-Reduction , Soil/chemistry , Soil Pollutants/chemistry , Sulfides/chemistry , Water Pollutants, Chemical/chemistry
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