2020
DOI: 10.1016/j.plaphy.2020.03.014
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Paspalum urvillei and Setaria parviflora, two grasses naturally adapted to extreme iron-rich environments

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Cited by 24 publications
(15 citation statements)
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“…Most of the N absorbed by grass species is found in leaf mesophyll cells (up to 75%), which are mainly involved in photosynthetic processes [ 26 , 48 ]. The leaf N also affects the size and number of chloroplasts and is found mainly as Rubisco and other thylakoid compounds (chlorophylls) responsible for light absorption and energy transfer [ 22 , 26 , 49 ]. As is consistent with other grass species [ 30 , 40 , 50 ], the patterns of N concentrations in both studied species were followed by most of the measured variables; plants that are able to capture more of the supplied N ( P. cinerascens ) have the benefits of increased carbon fixation and biomass.…”
Section: Discussionmentioning
confidence: 99%
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“…Most of the N absorbed by grass species is found in leaf mesophyll cells (up to 75%), which are mainly involved in photosynthetic processes [ 26 , 48 ]. The leaf N also affects the size and number of chloroplasts and is found mainly as Rubisco and other thylakoid compounds (chlorophylls) responsible for light absorption and energy transfer [ 22 , 26 , 49 ]. As is consistent with other grass species [ 30 , 40 , 50 ], the patterns of N concentrations in both studied species were followed by most of the measured variables; plants that are able to capture more of the supplied N ( P. cinerascens ) have the benefits of increased carbon fixation and biomass.…”
Section: Discussionmentioning
confidence: 99%
“…In fact, to reduce the metabolic risk associated with excess iron, species that adapt to environments naturally rich in metals can store large quantities of such elements by carrying the elements to the shoot organs (hyperaccumulators) or can prevent the elements from being absorbed in high quantities (excluders). A sophisticated combination of transport and accumulation in structures such as Fe-ferritin complexes is required in the former strategy to prevent the production of chemically reactive species (hydroxyl radicals) through the Fenton reaction [ 66 ], while in the latter mechanism is commonly found the formation of iron plaques around the roots as a consequence of the precipitation of Fe-oxyhydroxide (ferrihydrite), the restriction of iron uptake by apoplastic barriers, and Fe deposits in the root tissues (epidermal and cortical cells) in plants exposed to high iron availability [ 22 , 67 ]. Although in this study we did not evaluate the root anatomical structures, these adaptations are frequently observed in grasses, including the Paspalum genus.…”
Section: Discussionmentioning
confidence: 99%
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“…In foxtail millet, it was found that Iso-potentials of PEG (used for drought treatment) and laundry detergent had a more adverse effect on seed germination and overall plant growth than PEG ( Heidari et al, 2019 ). In a recent study, iron plaque (IP) formation was observed in the less studied grass S. parviflora which helps plants adapt to an iron-rich environment ( Oliveira de Araujo et al, 2020 ). Transient expression in tobacco leaves revealed that foxtail millet PPLS1 , a bHLH transcription factor associated with SiMYB85 controlled the purple color of pulvinus and leaf sheath (PPLS) trait used as an indicative characteristic of the authentic hybrids ( Bai et al, 2020 ).…”
Section: Omics Resources In Setariamentioning
confidence: 99%
“…Our seeds were collected from a grassland dominated by A. capillaris that is regularly flooded, which suggests that this species and, in particular, this genotype could potentially be adapted to such conditions. Furthermore, other species of the family Poaceae have also been shown to develop iron plaque, such as Paspalum urvillei and Setaria parviflora, which grow in sand with excesses of iron and developed layers of Fe oxyhydroxide (ferrihydrite) in the cell walls and vacuoles, which were detected only by synchrotron µXANES analysis [54]. The evidence suggests that one of the mechanisms of A. capillaris to cope with nZVI could be the formation of iron plaque, however, further investigation is necessary to evaluate this concept.…”
Section: Physiological Parametersmentioning
confidence: 99%