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Synchrotron micro-X-ray fluorescence imaging of arsenic in frozen-hydrated sections of a root of <i>Pteris vittata</i>

Teruhiko Kashiwabara, Nobuyuki Kitajima, Ryoko Onuma, Naoki Fukuda, Satoshi Endo, Yasuko Terada, Tomoko Abe, Akiko Hokura, Izumi Nakai

2021Metallomics12 citationsDOIOpen Access PDF

Abstract

We performed micro-X-ray fluorescence imaging of frozen-hydrated sections of a root of Pteris vittata for the first time, to the best of our knowledge, to reveal the mechanism of arsenic (As) uptake. The As distribution was successfully visualized in cross sections of different parts of the root, which showed that (i) the major pathway of As uptake changes from symplastic to apoplastic transport in the direction of root growth, and (ii) As and K have different mobilities around the stele before xylem loading, despite their similar distributions outside the stele in the cross sections. These data can reasonably explain As reduction, axially observed around the root tip in the direction of root growth and radially observed in the endodermis in the cross sections, as a consequence of the incorporation of As into the cells or symplast of the root. In addition, previous observations of As species in the midrib can be reconciled by ascribing a reduction capacity to the root cells, which implies that As reduction mechanisms at the cellular level may be an important control on the peculiar root-to-shoot transport of As in P. vittata.

Topics & Concepts

SteleEndodermisSymplastPteris vittataApoplastXylemChemistryHyperaccumulatorMaltolFluorescenceArsenicBotanyBiologyEnvironmental chemistryHeavy metalsPhysicsCell wallBiochemistryQuantum mechanicsPhytoremediationOrganic chemistryArsenic contamination and mitigationAluminum toxicity and tolerance in plants and animalsClay minerals and soil interactions
Synchrotron micro-X-ray fluorescence imaging of arsenic in frozen-hydrated sections of a root of <i>Pteris vittata</i> | Litcius