Manganese transport in eukaryotes: The role of DMT1

Au, Catherine; Benedetto, Alexandre; Aschner, Michael

doi:10.1016/j.neuro.2008.04.022

Cited by 208 publications

(199 citation statements)

References 81 publications

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“…Manganese exposure by itself has been shown to result in a variety of detrimental effects in C. elegans [146][147][148]. One study demonstrates that even short exposures (30 min) to manganese result in production of ROS, as evidenced by a drastic increase in glutathione levels [143].…”

Section: Manganese-containing Dithiocarbamate Fungicidesmentioning

confidence: 99%

“…elegans studies have also confirmed that manganese exposure may have an additive effect on DAergic neurodegeneration in neurons containing α-synuclein protein aggregates. Various labs have concluded that the C. elegans SMF-1 transporter, an analogue of the divalent metal transporter (DMT-1) found in humans, is important in the degeneration of these neurons [146,147,149,150]. Results in C. elegans indicate that this transporter plays a significant role in neurotoxicity by transporting manganese into the cell where it can induce numerous intracellular changes.…”

Section: Manganese-containing Dithiocarbamate Fungicidesmentioning

confidence: 99%

See 1 more Smart Citation

Caenorhabditis elegans: An Emerging Model System for Pesticide Neurotoxicity

McVey

Mink²,

Snapp³

et al. 2012

J Environ Anal Toxicol

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Section: Manganese-containing Dithiocarbamate Fungicidesmentioning

confidence: 99%

Section: Manganese-containing Dithiocarbamate Fungicidesmentioning

confidence: 99%

Caenorhabditis elegans: An Emerging Model System for Pesticide Neurotoxicity

McVey

Mink²,

Snapp³

et al. 2012

J Environ Anal Toxicol

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“…Being a paramagnetic substance, it reduces the spin-lattice relaxation time (T1) of surrounding water protons and, therefore, acts as a contrast agent in T1-weighted magnetic resonance (MR) images (Pautler et al, 1998, Saleem et al, 2002. When administered to the neural tissue, Mn 2+ enters neurons via different types of ion channels, including voltagegated calcium channels (Drapeau and Nachshen, 1984, Narita et al, 1990, Crossgrove and Yokel, 2005, as well as metal transporters, including divalent metal transporter 1 (DMT1) (Garrick et al, 2003, Au et al, 2008. Most importantly for neuroscientific studies, Mn 2+ is further transported by neural cells and can cross synapses (Sloot and Gramsbergen, 1994, Pautler et al, 1998, Saleem et al, 2002, which is not the case for all divalent metal ions (Tjalve et al, 1996).…”

Section: Introductionmentioning

confidence: 99%

Imaging neuronal pathways with 52Mn PET: Toxicity evaluation in rats

et al. 2017

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Manganese in its divalent state (Mn 2+ ) has features that make it a unique tool for tracing neuronal pathways. It is taken up and transported by neurons in an activity dependent manner and it can cross synapses. It also acts as a contrast agent for magnetic resonance imaging (MRI) enabling visualization of neuronal tracts. However, due to the limited sensitivity of MRI systems relatively high Mn 2+ doses are required. This is undesirable, especially in long-term studies, because of the known toxicity of the metal.In order to overcome this limitation, we propose 52 Mn as a positron emission tomography (PET) neuronal tract tracer. We used 52 Mn for imaging dopaminergic pathways after a unilateral injection into the ventral tegmental area (VTA), as well as the striatonigral pathway after an injection into the dorsal striatum (STR) in rats. Furthermore, we tested potentially noxious effects of the radioactivity dose with a behavioral test and histological staining. 24 h after 52 Mn administration, the neuronal tracts were clearly visible in PET images and statistical analysis confirmed the observed distribution of the tracer. We noticed a behavioral impairment in some animals treated with 170 kBq of 52 Mn, most likely caused by dysfunction of dopaminergic cells. Moreover, there was a substantial DNA damage in the brain tissue after applying 150 kBq of the tracer. However, all those effects were completely eliminated by reducing the 52 Mn dose to 20-30 kBq. Crucially, the reduced dose was still sufficient for PET imaging.

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“…Mn can reach the central nerve system (CNS) through DMT1 and/or TfR1 -mediated endocytosis (Diagram 3) [16,186]. Other transporters that can facilitate Mn entry to the CNS are store-operated and voltage-gated calcium channels [187,188], the choline transporter [189,190], citrate transporter [191] and ionotropic glutamate receptor Ca 2+ channels [192].…”

Section: Brain Transportmentioning

confidence: 99%

“…Within the brain, Mn binds to brain Tf which can mediate the neuronal uptake of Mn through TfR1 uptake mechanism that requires DMT1 for the metal export from the endosomes into the cytoplasm [15,186,199]. Also, DMT1 can facilitate Mn accumulation in DA-rich areas [200].…”

Section: Brain Transportmentioning

confidence: 99%

Effect of hemochromatosis on manganese neurotoxicity

Alsulimani¹

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ABSTRACT:Manganese (Mn) is an essential element for normal brain function, but excess levels of Mn in the brain are associated with a number of behavioral problems, including motor dysfunction, memory loss and psychiatric disorders. While Mn is known to share iron transporters for cellular uptake, deficiency in the Hfe (hemochromatosis), a cellular iron regulatory protein, affects the activities of iron transporters and impairs iron metabolism. Previously it was shown that Mn uptake into the brain is increased after intranasal exposure to Mn in Hfe-deficient mice, a mouse model of iron overload hereditary hemochromatosis. However, there is limited information about the effect of Hfe deficiency on Mn toxicity after exposure by other routes. Mn exposure is common through ingestion and inhalation in both environmental and occupational settings. Because Hfe deficiency alters iron transporters, and since Mn shares iron transporters, I hypothesize that Hfe deficiency increases Mn toxicity by modulating Mn uptake from the absorption site and deposition into the target organ for Mn toxicity which is the brain after gastric exposure in drinking water and pulmonary exposure to Mn particles. Specific aims are focused on the effect of Hfe deficiency on 1) the expression levels of metal transporters in the brain, gut and lung including alveolar macrophages, 2) levels of Mn, 3) Mn-associated neurobehavioral impairments, and 4) mechanisms of Mn neurotoxicity. This research will enhance the knowledge of Mn exposure and uptake in Hfe-related hemochromatosis, a prevalent iron disorder in the world.

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Manganese transport in eukaryotes: The role of DMT1

Cited by 208 publications

References 81 publications

Caenorhabditis elegans: An Emerging Model System for Pesticide Neurotoxicity

Caenorhabditis elegans: An Emerging Model System for Pesticide Neurotoxicity

Imaging neuronal pathways with 52Mn PET: Toxicity evaluation in rats

Effect of hemochromatosis on manganese neurotoxicity

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