Subcellular localization of silicon and germanium in grass root and leaf tissues by SIMS: evidence for differential and active transport

Sparks, Jed P.; Chandra, Subhash; Derry, Louis A.; Parthasarathy, M. V.; Daugherty, C. S.; Griffin, Rory

doi:10.1007/s10533-010-9498-2

Cited by 33 publications

(23 citation statements)

References 53 publications

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“…For the wild-type samples, Si can be transported across the endodermis by Lsi1 and Lsi2, and if the Si concentration is very high, strong proximal accumulation of Si in the endodermal cell walls could be caused if Si efflux from the endodermis is greater than Si loading into the xylem, as observed in the mature root zone (Fig. 5) and the previous studies of Parry and Soni (1972), Lux et al (1999), Gong et al (2006), and Sparks et al (2010). For the lsi2 mutant roots in this study, an accumulation on the distal side of the endodermis may not be observed due to the low concentration and short duration of Si supplied.…”

Section: Discussionsupporting

confidence: 52%

“…However, in these studies, with the exception of Parry and Soni (1972), Si appears to localize only to the proximal side of the endodermis rather than completely surrounding the cell, as observed in our studies. Similarly, Sparks et al (2010) mapped the Si distribution in the roots of two grass species (P. annua and D. glomerata) and found the same distribution, with the Si localized only to the proximal side of the endodermis. Gong et al (2006) stated that in their study, the Si was found to be a component of the root cell walls, and Parry and Soni (1972) concluded that more Si was localized on the inner tangential walls, which is consistent with our observations.…”

Section: Discussionmentioning

confidence: 87%

“…Recent examples of biological studies by nano-SIMS include high-resolution imaging of the nickel distribution in a nickel hyperaccumulator plant (Smart et al, 2010), localization of As and Se in cereal grains (Moore et al, 2010), lipid distributions in phaseseparated membranes (Kraft et al, 2006), and in situ mapping of nitrogen uptake in the rhizosphere (Clode et al, 2009). The SIMS technique has also recently been used to map, at subcellular resolution, Si and germanium in root and leaf tissues of annual blue grass (Poa annua) and orchard grass (Dactylis glomerata; Sparks et al, 2010).…”

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confidence: 99%

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High-Resolution Secondary Ion Mass Spectrometry Reveals the Contrasting Subcellular Distribution of Arsenic and Silicon in Rice Roots

et al. 2011

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Rice (Oryza sativa) takes up arsenite mainly through the silicic acid transport pathway. Understanding the uptake and sequestration of arsenic (As) into the rice plant is important for developing strategies to reduce As concentration in rice grain. In this study, the cellular and subcellular distributions of As and silicon (Si) in rice roots were investigated using high-pressure freezing, high-resolution secondary ion mass spectrometry, and transmission electron microscopy. Rice plants, both the lsi2 mutant lacking the Si/arsenite efflux transporter Lsi2 and its wild-type cultivar, with or without an iron plaque, were treated with arsenate or arsenite. The formation of iron plaque on the root surface resulted in strong accumulation of As and phosphorous on the epidermis. The lsi2 mutant showed stronger As accumulation in the endodermal vacuoles, where the Lsi2 transporter is located in the plasma membranes, than the wild-type line. As also accumulated in the vacuoles of some xylem parenchyma cells and in some pericycle cells, particularly in the wild-type mature root zone. Vacuolar accumulation of As is associated with sulfur, suggesting that As may be stored as arsenite-phytochelatin complexes. Si was localized in the cell walls of the endodermal cells with little apparent effect of the Lsi2 mutation on its distribution. This study reveals the vacuolar sequestration of As in rice roots and contrasting patterns of As and Si subcellular localization, despite both being transported across the plasma membranes by the same transporters.

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Section: Discussionsupporting

confidence: 52%

Section: Discussionmentioning

confidence: 87%

mentioning

confidence: 99%

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High-Resolution Secondary Ion Mass Spectrometry Reveals the Contrasting Subcellular Distribution of Arsenic and Silicon in Rice Roots

et al. 2011

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“…While dominated by wellformed phytoliths ( Fig. 3a and b), biogenic Si also occurs as coating along cell walls and in other fine-scale structures (Sparks et al, 2011) that may be selectively reacted during short-term experiments. Sesquioxides and organics may also become sorbed and precipitated on soil phytoliths, increasing their chemical resistance and slowing their weathering rates (Piperno, 2006).…”

Section: Biologic Si Cyclingmentioning

confidence: 99%

“…The mechanism and reaction rates associated with weathering, a focus of intensive research over the last several decades (see reviews in Brantley et al, 2007), have direct applications to buffering acid precipitation, long-term atmospheric CO 2 drawdown and climate change (Walker et al, 1981;White and Blum, 1995;Berner and Berner, 1997;Driscoll et al, 2005). Terrestrial biogenic silica is produced when soluble Si is extracted from soils by biopumping of plants and transformed into opaline silica principally as phytoliths (Epstein, 1999;Sparks et al, 2011). Mechanisms by which grasses accumulate Si may include passive uptake, enzyme polymerization and species-specific efflux transporters (Sangster and Hodson, 1986;Ma et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

Biogenic and pedogenic controls on Si distributions and cycling in grasslands of the Santa Cruz soil chronosequence, California

White

Vivit

Schulz

et al. 2012

Geochimica et Cosmochimica Acta

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Colloidal transport in the Gordon Gulch catchment of the Boulder Creek CZO and its effect on C‐Q relationships for silicon

Aguirre

Derry

Mills

et al. 2017

Water Resources Research

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The near‐constant Si concentration under varying discharge observed in Gordon Gulch of the Boulder Critical Zone Observatory (CZO) indicates that the silica fluxes are strongly controlled by discharge. To identify the mechanisms supplying increased Si at high discharge (Q), we examine Si‐Al‐Fe‐Ge in soils, streams, and groundwaters. We identify bedrock weathering in groundwater and colloidal transport as the two end‐members that supply Si to the system. During base flow, streamflow is derived from groundwater, and weathering of feldspar is the main source of Si with a Ge/Si ratio 0.2–0.5 µmol/mol and low dissolved Al and Fe. The groundwater data are consistent with incongruent weathering of feldspar as the main source of dissolved Si. As discharge increases, Si‐Al‐Fe‐bearing colloids are mobilized and the Ge/Si ratio of the stream rises to 3.0 µmol/mol. Mineralogical analysis using XRD identified Al‐Si phases including kaolinite, illite, and quartz in the colloidal size fraction (<0.45 µm). The Ge/Si ratio of stream and soil colloids is ≈3.8 µmol/mol. The mechanism of colloidal transport with increasing discharge can account for the concentration‐discharge (C‐Q) patterns of Si, Al, and Fe with near‐zero or positive power law slopes observed in the Gordon Gulch catchment. Anomalously high Ge/Si ratios also identified a third end‐member resulting from coal fly ash deposition during the winter and spring. Wind trajectories during 2012, correlation between Ge/Si and SO42−, and comparison to atmospheric deposition data imply contamination from nearby coal fired power plant operations.

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Subcellular localization of silicon and germanium in grass root and leaf tissues by SIMS: evidence for differential and active transport

Cited by 33 publications

References 53 publications

High-Resolution Secondary Ion Mass Spectrometry Reveals the Contrasting Subcellular Distribution of Arsenic and Silicon in Rice Roots

High-Resolution Secondary Ion Mass Spectrometry Reveals the Contrasting Subcellular Distribution of Arsenic and Silicon in Rice Roots

Biogenic and pedogenic controls on Si distributions and cycling in grasslands of the Santa Cruz soil chronosequence, California

Colloidal transport in the Gordon Gulch catchment of the Boulder Creek CZO and its effect on C‐Q relationships for silicon

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