Iron trafficking inside the brain

Moos, Torben; Nielsen, Thomas Rosengren; Skjørringe, Tina; Morgan, Evan H.

doi:10.1111/j.1471-4159.2007.04976.x

Cited by 379 publications

(393 citation statements)

References 92 publications

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“…From our data emerges a new paradigm in which iron chelation by citrate is a prerequisite step for iron nutrition in extracellular fluids. Recently, complexation of iron by citrate has been proposed as an important event in the blood-tobrain circulation of iron (Moos et al, 2007), thus supporting the view that our model might be generalized to extracellular traffic of iron in eukaryotes.…”

Section: Discussionsupporting

confidence: 69%

“…Citrate is likely an important ligand of iron in animals and plants, in particular, in the extracellular fluids. In the brain interstitium where citrate is released in large amount by astrocytes, part of the nontransferrin-bound iron pool that circulates might be complexed with citrate because neurons have been shown to take up Fe-citrate (reviewed in Moos et al, 2007). In the xylem sap of many plant species, iron has been thought to circulate as Fe-citrate.…”

Section: Introductionmentioning

confidence: 99%

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The FRD3 Citrate Effluxer Promotes Iron Nutrition between Symplastically Disconnected Tissues throughout Arabidopsis Development

et al. 2011

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We present data supporting a general role for FERRIC REDICTASE DEFECTIVE3 (FRD3), an efflux transporter of the efficient iron chelator citrate, in maintaining iron homeostasis throughout plant development. In addition to its well-known expression in root, we show that FRD3 is strongly expressed in Arabidopsis thaliana seed and flower. Consistently, frd3 lossof-function mutants are defective in early germination and are almost completely sterile, both defects being rescued by iron and/or citrate supply. The frd3 fertility defect is caused by pollen abortion and is associated with the male gametophytic expression of FRD3. Iron imaging shows the presence of important deposits of iron on the surface of aborted pollen grains. This points to a role for FRD3 and citrate in proper iron nutrition of embryo and pollen. Based on the findings that iron acquisition in embryo, leaf, and pollen depends on FRD3, we propose that FRD3 mediated-citrate release in the apoplastic space represents an important process by which efficient iron nutrition is achieved between adjacent tissues lacking symplastic connections. These results reveal a physiological role for citrate in the apoplastic transport of iron throughout development, and provide a general model for multicellular organisms in the cell-to-cell transport of iron involving extracellular circulation.

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Section: Discussionsupporting

confidence: 69%

Section: Introductionmentioning

confidence: 99%

The FRD3 Citrate Effluxer Promotes Iron Nutrition between Symplastically Disconnected Tissues throughout Arabidopsis Development

et al. 2011

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“…Blood iron crosses the capillary endothelial cell membrane via the transferrin, lactoferrin, or possibly ferritin receptors (Fisher et al, 2006;Moos et al, 2007). Interestingly, we observed Fe(II)-but not Fe(III)-deposits along the luminal surface of endothelial cells.…”

Section: ) Capillary Endothelial Cellsmentioning

confidence: 47%

Cellular and subcellular localizations of nonheme ferric and ferrous iron in the rat brain: a light and electron microscopic study by the perfusion-Perls and -Turnbull methods

Meguro

Asano

Odagiri

et al. 2008

Archives of Histology and Cytology

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“…pool is acknowledged in the literature 28 and required by our model. The studies on Belgrade rats showed that despite high circulating Tf levels, brain iron uptake was compromised.…”

Section: Discussionmentioning

confidence: 99%

A Novel Model for Brain Iron Uptake: Introducing the Concept of Regulation

Simpson

Ponnuru

Klinger

et al. 2014

J Cereb Blood Flow Metab

119

165

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Neurologic disorders such as Alzheimer's, Parkinson's disease, and Restless Legs Syndrome involve a loss of brain iron homeostasis. Moreover, iron deficiency is the most prevalent nutritional concern worldwide with many associated cognitive and neural ramifications. Therefore, understanding the mechanisms by which iron enters the brain and how those processes are regulated addresses significant global health issues. The existing paradigm assumes that the endothelial cells (ECs) forming the blood-brain barrier (BBB) serve as a simple conduit for transport of transferrin-bound iron. This concept is a significant oversimplification, at minimum failing to account for the iron needs of the ECs. Using an in vivo model of brain iron deficiency, the Belgrade rat, we show the distribution of transferrin receptors in brain microvasculature is altered in luminal, intracellular, and abluminal membranes dependent on brain iron status. We used a cell culture model of the BBB to show the presence of factors that influence iron release in non-human primate cerebrospinal fluid and conditioned media from astrocytes; specifically apo-transferrin and hepcidin were found to increase and decrease iron release, respectively. These data have been integrated into an interactive model where BBB ECs are central in the regulation of cerebral iron metabolism.

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Iron trafficking inside the brain

Cited by 379 publications

References 92 publications

The FRD3 Citrate Effluxer Promotes Iron Nutrition between Symplastically Disconnected Tissues throughout Arabidopsis Development

The FRD3 Citrate Effluxer Promotes Iron Nutrition between Symplastically Disconnected Tissues throughout Arabidopsis Development

Cellular and subcellular localizations of nonheme ferric and ferrous iron in the rat brain: a light and electron microscopic study by the perfusion-Perls and -Turnbull methods

A Novel Model for Brain Iron Uptake: Introducing the Concept of Regulation

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