Torben Moos scite author profile

Iron, an essential element for all cells of the body, including those of the brain, is transported bound to transferrin in the blood and the general extracellular fluid of the body. The demonstration of transferrin receptors on brain capillary endothelial cells (BCECs) more than 20 years ago provided the evidence for the now accepted view that the first step in blood to brain transport of iron is receptor-mediated endocytosis of transferrin. Subsequent steps are less clear. However, recent investigations which form the basis of this review have shed some light on them and also indicate possible fruitful avenues for future research. They provide new evidence on how iron is released from transferrin on the abluminal surface of BCECs, including the role of astrocytes in this process, how iron is transported in brain extracellular fluid, and how iron is taken up by neurons and glial cells. We propose that the divalent metal transporter 1 is not involved in iron transport through the BCECs. Instead, iron is probably released from transferrin on the abluminal surface of these cells by the action of citrate and ATP that are released by astrocytes, which form a very close relationship with BCECs. Complexes of iron with citrate and ATP can then circulate in brain extracellular fluid and may be taken up in these lowmolecular weight forms by all types of brain cells or be bound by transferrin and taken up by cells which express transferrin receptors. Some iron most likely also circulates bound to transferrin, as neurons contain both transferrin receptors and divalent metal transporter 1 and can take up transferrin-bound iron. The most likely source for transferrin in the brain interstitium derives from diffusion from the ventricles. Neurons express the iron exporting carrier, ferroportin, which probably allows them to excrete unneeded iron. Astrocytes lack transferrin receptors. Their source of iron is probably that released from transferrin on the abluminal surface of BCECs. They probably to export iron by a mechanism involving a membrane-bound form of the ferroxidase, ceruloplasmin. Oligodendrocytes also lack transferrin receptors. They probably take up non-transferrin bound iron that gets incorporated in newly synthesized transferrin, which may play an important role for intracellular iron transport. Keywords: astrocyte, blood-brain barrier, cerebrospinal fluid, citrate, divalent metal transporter 1, endosome, ferroportin, transferrin receptor. Iron is essential for a plethora of functions in all cells. In the brain these include neurotransmission, myelination and cell division. In the circulation, iron is bound to transferrin with a binding-capacity for iron that only reaches its limit in diseases like hemochromatosis in which non-transferrin bound iron present as a low-molecular weight form can be detected in plasma (Batey et al. 1980;Brissot et al. 1985). The hydrophilic nature of the iron-containing transferrin prevents its passage into the brain, but to circumvent this feature and simultaneously nourish neu...

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Proteasomal Inhibition by α-Synuclein Filaments and Oligomers

Lindersson

Beedholm

Højrup

et al. 2004

Journal of Biological Chemistry

371

310

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A unifying feature of many neurodegenerative disorders is the accumulation of polyubiquitinated protein inclusions in dystrophic neurons, e.g. containing ␣-synuclein, which is suggestive of an insufficient proteasomal activity. We demonstrate that ␣-synuclein and 20 S proteasome components co-localize in Lewy bodies and show that subunits from 20 S proteasome particles, in contrast to subunits of the 19 S regulatory complex, bind efficiently to aggregated filamentous but not monomeric ␣-synuclein. Proteasome binding to insoluble ␣-synuclein filaments and soluble ␣-synuclein oligomers results in marked inhibition of its chymotrypsin-like hydrolytic activity through a non-competitive mechanism that is mimicked by model amyloid-A␤ peptide aggregates. Endogenous ligands of aggregated ␣-synuclein like heat shock protein 70 and glyceraldehyde-6-phosphate dehydrogenase bind filaments and inhibit their anti-proteasomal activity. The inhibitory effect of amyloid aggregates may thus be amenable to modulation by endogenous chaperones and possibly accessible for therapeutic intervention.

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The vascular basement membrane in the healthy and pathological brain

Thomsen

Routhe

Moos

2017

J Cereb Blood Flow Metab

354

274

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The vascular basement membrane contributes to the integrity of the blood-brain barrier (BBB), which is formed by brain capillary endothelial cells (BCECs). The BCECs receive support from pericytes embedded in the vascular basement membrane and from astrocyte endfeet. The vascular basement membrane forms a three-dimensional protein network predominantly composed of laminin, collagen IV, nidogen, and heparan sulfate proteoglycans that mutually support interactions between BCECs, pericytes, and astrocytes. Major changes in the molecular composition of the vascular basement membrane are observed in acute and chronic neuropathological settings. In the present review, we cover the significance of the vascular basement membrane in the healthy and pathological brain. In stroke, loss of BBB integrity is accompanied by upregulation of proteolytic enzymes and degradation of vascular basement membrane proteins. There is yet no causal relationship between expression or activity of matrix proteases and the degradation of vascular matrix proteins in vivo. In Alzheimer's disease, changes in the vascular basement membrane include accumulation of Aβ, composite changes, and thickening. The physical properties of the vascular basement membrane carry the potential of obstructing drug delivery to the brain, e.g. thickening of the basement membrane can affect drug delivery to the brain, especially the delivery of nanoparticles.

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The absence of reactive astrocytosis is indicative of a unique inflammatory process in Parkinson's disease

et al. 1999

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Torben Moos

A comprehensive overview of exosomes as drug delivery vehicles — Endogenous nanocarriers for targeted cancer therapy

Iron trafficking inside the brain

Proteasomal Inhibition by α-Synuclein Filaments and Oligomers

The vascular basement membrane in the healthy and pathological brain

The absence of reactive astrocytosis is indicative of a unique inflammatory process in Parkinson's disease

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