Versatile Flow Injection System for Spectrophotometric Determination of Silicon in Agronomic Samples

Carneiro, Josiane Meire Toloti; Rossete, Alexssandra Luiza Rodrigues Molina; Oliveira, Gisele S.; Bendassolli, José Albertino

doi:10.1080/00103620701377245

Cited by 9 publications

(7 citation statements)

References 22 publications

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“…C and N concentrations were determined by elemental analysis (NA 1500 Series 2; Carlo-Erba, Stanford, CA, USA). Ca, P and K concentrations were determined by sulphuric acid/hydrogen peroxide digestion, followed by ammonium molybdate/ascorbic acid colorimetric determination using flow injection analysis (FIAstar spectrophotometer 5023; Tecator, H€ oganas, Sweden) for P, and flame atomic absorbance spectrometry (Atomic Absorption Spectrophotometer Analyst 100; Perkin Elmer, Waltham, MA, USA) for Ca and K. Silica concentrations were assessed using an alkaline sodium hydroxide/hydrogen peroxide digest followed by determination of concentrations using flow injection analysis (Carneiro et al, 2007). Root lignin and lignin-like substances were assessed using a sulphuric acid digestion method with the remaining oven-dried, acid-insoluble residue operationally defined as the root lignin and lignin-like fraction (Woodin et al, 2009).…”

Section: Root Trait Analysismentioning

confidence: 99%

Root traits predict decomposition across a landscape‐scale grazing experiment

et al. 2014

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Root litter is the dominant soil carbon and nutrient input in many ecosystems, yet few studies have considered how root decomposition is regulated at the landscape scale and how this is mediated by land-use management practices. Large herbivores can potentially influence below-ground decomposition through changes in soil microclimate (temperature and moisture) and changes in plant species composition (root traits).To investigate such herbivore-induced changes, we quantified annual root decomposition of upland grassland species in situ across a landscape-scale livestock grazing experiment, in a common-garden experiment and in laboratory microcosms evaluating the influence of key root traits on decomposition.Livestock grazing increased soil temperatures, but this did not affect root decomposition. Grazing had no effect on soil moisture, but wetter soils retarded root decomposition. Species-specific decomposition rates were similar across all grazing treatments, and species differences were maintained in the common-garden experiment, suggesting an overriding importance of litter type. Supporting this, in microcosms, roots with lower specific root area (m2 g−1) or those with higher phosphorus concentrations decomposed faster.Our results suggest that large herbivores alter below-ground carbon and nitrogen dynamics more through their effects on plant species composition and associated root traits than through effects on the soil microclimate.

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Section: Root Trait Analysismentioning

confidence: 99%

Root traits predict decomposition across a landscape‐scale grazing experiment

et al. 2014

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“…Leaf sample preparation for silicon analysis by FIA Samples were prepared for silicon (Si) analysis as described by Carneiro et al (2007). Briefly, dried ground leaf (0.02 g) was weighed into polyethylene centrifuge tubes and 0.6 ml of hydrogen peroxide and 1.5 ml of 50% sodium hydroxide were added.…”

Section: Plant Materialsmentioning

confidence: 99%

Genetic mapping of the rice ionome in leaves and grain: identification of QTLs for 17 elements including arsenic, cadmium, iron and selenium

et al. 2009

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Research into the composition of cereal grains is motivated by increased interest in food quality. Here multi-element analysis is conducted on leaves and grain of the Bala x Azucena rice mapping population grown in the field. Quantitative trait loci (QTLs) for the concentration of 17 elements were detected, revealing 36 QTLs for leaves and 41 for grains. Epistasis was detected for most elements. There was very little correlation between leaf and grain element concentrations. For selenium, lead, phosphorus and magnesium QTLs were detected in the same location for both tissues. In general, there were no major QTL clusters, suggesting separate regulation of each element. QTLs for grain iron, zinc, molybdenum and selenium are potential targets for marker assisted selection to improve seed nutritional quality. An epistatic interaction for grain arsenic also looks promising to decrease the concentration of this carcinogenic element.

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“…Plant material and certified reference material (CRM) were prepared for silicon analysis as described by Carneiro et al. (). A total of 1.5 g shoot material from each sample were sub‐sampled at random and powderised using a ball mill (Retsch, MM200, Germany).…”

Section: Methodsmentioning

confidence: 99%

“…Prior to analysis, samples were diluted 1 : 5 with Milli‐Q water. Silicon concentration was measured using an FIA spectrophotometer (Tecator FIAstar 5010) at a wavelength of 410 nm ( Carneiro et al., ; Norton et al., ; ).…”

Section: Methodsmentioning

confidence: 99%

Genotypic differences in shoot silicon concentration and the impact on grain arsenic concentration in rice

Talukdar

Hartley

Travis

et al. 2019

J. Plant Nutr. Soil Sci.

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Silicon in rice (Oryza sativa L.) has been demonstrated to be involved in resistance to lodging, drought, and salinity, and also enhances resistance to pests and diseases. The aim of this study was to determine the range of silicon concentration in a set of rice (Oryza sativa L.) accessions, and to determine if the natural variation of shoot silicon is linked to the previously identified silicon transporters (Lsi genes). Silicon concentration was determined in 50 field‐grown accessions, representing all sub‐populations of rice, with all accessions being genotyped with 700K SNPs. SNPs within 10 kb of the Lsi genes were examined to determine if any were significantly linked with the phenotypic variation. An XRF method of silicon determination compared favourably with digestion and colorimetric analysis. There were significant genotypic differences in shoot silicon ranging from 16.5 to 42.4 mg g−1 of plant dry weight, but there was no significant difference between the rice sub‐populations. Plants with different alleles for SNPs representing Lsi2 and Lsi3 were significantly different for shoot silicon concentration. Shoot silicon correlated negatively with grain arsenic in the tropical and temperate japonica sub‐population, suggesting that accessions with high shoot silicon have reduced grain arsenic. This study indicates that alleles for Lsi genes are excellent candidate genes for further study to explain the natural variation of shoot silicon in rice.

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Versatile Flow Injection System for Spectrophotometric Determination of Silicon in Agronomic Samples

Cited by 9 publications

References 22 publications

Root traits predict decomposition across a landscape‐scale grazing experiment

Root traits predict decomposition across a landscape‐scale grazing experiment

Genetic mapping of the rice ionome in leaves and grain: identification of QTLs for 17 elements including arsenic, cadmium, iron and selenium

Genotypic differences in shoot silicon concentration and the impact on grain arsenic concentration in rice

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