Your search keyword '"Muhammad, Sayyar"' showing total 6 results

1. Generation of Se-fortified broccoli as functional food: impact of Se fertilization on S metabolism.

Author

Hsu FC, Wirtz M, Heppel SC, Bogs J, Krämer U, Khan MS, Bub A, Hell R, and Rausch T

Subjects

Amino Acid Sequence, Anticarcinogenic Agents metabolism, Biological Transport, Brassica chemistry, Brassica drug effects, Brassica growth & development, Fertilizers, Functional Food, Glucosinolates biosynthesis, Glucosinolates metabolism, Imidoesters, Molecular Sequence Data, Oximes, Plant Leaves chemistry, Plant Leaves metabolism, Plant Proteins genetics, Plant Roots chemistry, Plant Roots metabolism, Selenic Acid, Selenium metabolism, Selenium Compounds chemistry, Selenium Compounds metabolism, Sulfates chemistry, Sulfates metabolism, Sulfoxides, Brassica metabolism, Glucosinolates analysis, Selenium pharmacology, Sulfur metabolism

Abstract

Selenium (Se)-fortified broccoli (Brassica oleracea var. italica) has been proposed as a functional food for cancer prevention, based on its high glucosinolate (GSL) content and capacity for Se accumulation. However, as selenate and sulphate share the initial assimilation route, Se fertilization could interfere with sulphur metabolism and plant growth. Consequently, GSL accumulation could be compromised. To evaluate these potentially adverse effects of Se fertilization, we performed a comprehensive study on sand-grown young broccoli plants (weekly selenate applications of 0.8 µmol plant(-1) via the root) and field-grown adult broccoli plants during head formation (single foliar selenate application: 25.3 or 253 µmol plant(-1) ). The results show that under these conditions, Se application does not affect plant growth, contents of cysteine, glutathione, total GSL, glucoraphanin (major aliphatic GSL) or the expression of BoMYB28 (encoding a functionally confirmed master regulator for aliphatic GSL biosynthesis). Conversely, due to the changed expression of sulphate transporters (BoSULTR1;1, 1;2, 2;1, and 2;2), sulphate and total S contents increased in the shoot of young plants while decreasing in the root. We conclude that broccoli can be fertilized with Se without reduction in GSL content, even with Se accumulation exceeding the level recommended for human consumption., (© 2010 Blackwell Publishing Ltd.)

Published

2011

2. Discriminative Long-Distance Transport of Selenate and Selenite Triggers Glutathione Oxidation in Specific Subcellular Compartments of Root and Shoot Cells in Arabidopsis

Author

Muhammad Sayyar Khan, Anna Soyk, Ingo Wolf, Miriam Peter, Andreas J. Meyer, Thomas Rausch, Markus Wirtz, and Rüdiger Hell

Subjects

selenium, toxicity, oxidation, compartmentation, roGFP2, Plant culture, SB1-1110

Abstract

Selenium is an essential trace element required for seleno-protein synthesis in many eukaryotic cells excluding higher plants. However, a substantial fraction of organically bound selenide in human nutrition is directly or indirectly derived from plants, which assimilate inorganic selenium into organic seleno-compounds. In humans, selenium deficiency is associated with several health disorders Despite its importance for human health, selenium assimilation and metabolism is barely understood in plants. Here, we analyzed the impact of the two dominant forms of soil-available selenium, selenite and selenate, on plant development and selenium partitioning in plants. We found that the reference plant Arabidopsis thaliana discriminated between selenate and selenite application. In contrast to selenite, selenate was predominantly deposited in leaves. This explicit deposition of selenate caused chlorosis and impaired plant morphology, which was not observed upon selenite application. However, only selenate triggered the accumulation of the macronutrient sulfur, the sister element of selenium in the oxygen group. To understand the oxidation state-specific toxicity mechanisms for selenium in plants, we quantified the impact of selenate and selenite on the redox environment in the plastids and the cytosol in a time-resolved manner. Surprisingly, we found that selenite first caused the oxidation of the plastid-localized glutathione pool and had a marginal impact on the redox state of the cytosolic glutathione pool, specifically in roots. In contrast, selenate application caused more vigorous oxidation of the cytosolic glutathione pool but also impaired the plastidic redox environment. In agreement with the predominant deposition in leaves, the selenate-induced oxidation of both glutathione pools was more pronounced in leaves than in roots. Our results demonstrate that Se-species dependent differences in Se partitioning substantially contribute to whole plant Se toxicity and that these Se species have subcellular compartment-specific impacts on the glutathione redox buffer that correlate with toxicity symptoms.

Published

2022

3. Discriminative Long-Distance Transport of Selenate and Selenite Triggers Glutathione Oxidation in Specific Subcellular Compartments of Root and Shoot Cells in Arabidopsis.

Author

Khan, Muhammad Sayyar, Soyk, Anna, Wolf, Ingo, Peter, Miriam, Meyer, Andreas J., Rausch, Thomas, Wirtz, Markus, and Hell, Rüdiger

Subjects

CHALCOGENS, GLUTATHIONE, PLANT shoots, CHLOROSIS (Plants), PLANT morphology, OXIDATION, LONG-distance running, PLANT nutrition

Abstract

Selenium is an essential trace element required for seleno-protein synthesis in many eukaryotic cells excluding higher plants. However, a substantial fraction of organically bound selenide in human nutrition is directly or indirectly derived from plants, which assimilate inorganic selenium into organic seleno-compounds. In humans, selenium deficiency is associated with several health disorders Despite its importance for human health, selenium assimilation and metabolism is barely understood in plants. Here, we analyzed the impact of the two dominant forms of soil-available selenium, selenite and selenate, on plant development and selenium partitioning in plants. We found that the reference plant Arabidopsis thaliana discriminated between selenate and selenite application. In contrast to selenite, selenate was predominantly deposited in leaves. This explicit deposition of selenate caused chlorosis and impaired plant morphology, which was not observed upon selenite application. However, only selenate triggered the accumulation of the macronutrient sulfur, the sister element of selenium in the oxygen group. To understand the oxidation state-specific toxicity mechanisms for selenium in plants, we quantified the impact of selenate and selenite on the redox environment in the plastids and the cytosol in a time-resolved manner. Surprisingly, we found that selenite first caused the oxidation of the plastid-localized glutathione pool and had a marginal impact on the redox state of the cytosolic glutathione pool, specifically in roots. In contrast, selenate application caused more vigorous oxidation of the cytosolic glutathione pool but also impaired the plastidic redox environment. In agreement with the predominant deposition in leaves, the selenate-induced oxidation of both glutathione pools was more pronounced in leaves than in roots. Our results demonstrate that Se-species dependent differences in Se partitioning substantially contribute to whole plant Se toxicity and that these Se species have subcellular compartment-specific impacts on the glutathione redox buffer that correlate with toxicity symptoms. [ABSTRACT FROM AUTHOR]

Published

2022

4. A Future Crop Biotechnology View of Sulfur and Selenium

Author

Muhammad Sayyar Khan and Rüdiger Hell

Subjects

Crop, chemistry, Agronomy, Crop yield, Plant composition, chemistry.chemical_element, Biology, Sulfur, Selenium

Published

2015

5. Generation of Se-fortified broccoli as functional food: impact of Se fertilization on S metabolism

Author

Fu-Chen, Hsu, Markus, Wirtz, Simon C, Heppel, Jochen, Bogs, Ute, Krämer, Muhammad Sayyar, Khan, Achim, Bub, Rüdiger, Hell, and Thomas, Rausch

Subjects

Sulfates, Glucosinolates, Molecular Sequence Data, Biological Transport, Brassica, Selenic Acid, Plant Roots, Plant Leaves, Selenium, Functional Food, Sulfoxides, Imidoesters, Oximes, Anticarcinogenic Agents, Amino Acid Sequence, Fertilizers, Selenium Compounds, Sulfur, Plant Proteins

Abstract

Selenium (Se)-fortified broccoli (Brassica oleracea var. italica) has been proposed as a functional food for cancer prevention, based on its high glucosinolate (GSL) content and capacity for Se accumulation. However, as selenate and sulphate share the initial assimilation route, Se fertilization could interfere with sulphur metabolism and plant growth. Consequently, GSL accumulation could be compromised. To evaluate these potentially adverse effects of Se fertilization, we performed a comprehensive study on sand-grown young broccoli plants (weekly selenate applications of 0.8 µmol plant(-1) via the root) and field-grown adult broccoli plants during head formation (single foliar selenate application: 25.3 or 253 µmol plant(-1) ). The results show that under these conditions, Se application does not affect plant growth, contents of cysteine, glutathione, total GSL, glucoraphanin (major aliphatic GSL) or the expression of BoMYB28 (encoding a functionally confirmed master regulator for aliphatic GSL biosynthesis). Conversely, due to the changed expression of sulphate transporters (BoSULTR1;1, 1;2, 2;1, and 2;2), sulphate and total S contents increased in the shoot of young plants while decreasing in the root. We conclude that broccoli can be fertilized with Se without reduction in GSL content, even with Se accumulation exceeding the level recommended for human consumption.

Published

2010

6. Exploring the importance of sulfate transporters and ATP sulphurylases for selenium hyperaccumulation--a comparison of Stanleya pinnata and Brassica juncea (Brassicaceae).

Author

Schiavon, Michela, Malagoli, Mario, Pilon, Marinus, Pilon-Smits, Elizabeth A. H., Schat, Henk, and Khan, Muhammad Sayyar

Subjects

SELENIUM, SULFATES, BRASSICA juncea, SULFUR, GENE expression

Abstract

Selenium (Se) hyperaccumulation, the capacity of some species to concentrate Se to levels upwards of 0.1% of dry weight, is an intriguing phenomenon that is only partially understood. Questions that remain to be answered are: do hyperaccumulators have one or more Se-specific transporters? How are these regulated by Se and sulfur (S)? In this study, hyperaccumulator Stanleya pinnata was compared with related non-hyperaccumulator Brassica juncea with respect to S-dependent selenate uptake and translocation, as well as for the expression levels of three sulfate/selenate transporters (Sultr) and three ATP sulphurylases (APS). Selenium accumulation went down ~10-fold with increasing sulfate supply in B. juncea, while S. pinnata only had a 2-3-fold difference in Se uptake between the highest (5mM) and lowest sulfate (0mM) treatments. The Se/S ratio was generally higher in the hyperaccumulator than the non-hyperaccumulator, and while tissue Se/S ratio in B. juncea largely reflected the ratio in the growth medium, S. pinnata enriched itself up to 5-fold with Se relative to S. The transcript levels of Sultr1;2 and 2;1 and APS1, 2, and 4 were generally much higher in S. pinnata than B. juncea, and the species showed differential transcript responses to S and Se supply. These results indicate that S. pinnata has at least one transporter with significant selenate specificity over sulfate. Also, the hyperaccumulator has elevated expression levels of several sulfate/selenate transporters and APS enzymes, which likely contribute to the Se hyperaccumulation and hypertolerance phenotype. [ABSTRACT FROM AUTHOR]

Published

2015