Cellular iron uptake, trafficking and metabolism: Key molecules and mechanisms and their roles in disease

Lane, Darius J.R.; Merlot, Angelica M.; Huang, Michael L.H.; Bae, Dong-Hun; Jansson, Patric J.; Sahni, Sumit; Kalinowski, Danuta S.; Richardson, Des R.

doi:10.1016/j.bbamcr.2015.01.021

Cited by 305 publications

(280 citation statements)

References 147 publications

(326 reference statements)

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“…In contrast, patients with underlying autoimmune disorders and/or hematologic malignancies demonstrate a loss of central tolerance and differentiation blocks 6 ; these patients have poor and short-lived responses to immune-directed therapy because additional cell types are involved in disease pathogenesis and the implicated lymphocyte repertoire is largely autoreactive and able to reconstitute rapidly after therapy (see figure). As demonstrated by this and other reports, 7,8 combination therapy directed at multiple arms of the immune response, along with TRAs, improves response rates. This is an important observation, though treatment of refractory ITP nevertheless remains reminiscent of the story of the "blind men and the elephant," in which a group of blind men touch different parts of an elephant, and when they compare notes find they are in complete disagreement.…”

mentioning

confidence: 78%

Unchanneling cardiac iron in humans

Coates

2016

Blood

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mentioning

confidence: 78%

Unchanneling cardiac iron in humans

Coates

2016

Blood

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“…Apo-Isu1 does not appear to bind iron at the active site with significant affinity (58), suggesting that iron may be actively delivered to the ISC complex. Yfh1 and its human homologue frataxin can bind ferrous iron via acidic residues on the N-terminal ␣-helix, but concrete in vivo evidence of Yfh1 supplying iron is still lacking (15,59). Interestingly, frataxin-independent cluster synthesis using an Isu1 mutant protein may rule against a specific iron delivery function of frataxin (60).…”

Section: De Novo Synthesis Of a [2fe-2s] Cluster On The Mitochondrialmentioning

confidence: 99%

“…Cells typically maintain a strict balance of iron and sulfide ion concentrations due to their damaging redox reactions when present in excess (14,15). The cell also uses a complex biosynthetic system to ensure that the sometimes redox-sensitive and labile Fe/S clusters are assembled correctly, trafficked to specific target apoproteins, and remain protected during these processes.…”

Section: Ubiquitous Iron-sulfur Clusters and Their Synthesis: An Overmentioning

confidence: 99%

Iron–sulfur cluster biogenesis and trafficking in mitochondria

Braymer

Lill

2017

Journal of Biological Chemistry

314

293

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The biogenesis of iron-sulfur (Fe/S) proteins in eukaryotes is a multistage, multicompartment process that is essential for a broad range of cellular functions, including genome maintenance, protein translation, energy conversion, and the antiviral response. Genetic and cell biological studies over almost 2 decades have revealed some 30 proteins involved in the synthesis of cellular [2Fe-2S] and [4Fe-4S] clusters and their incorporation into numerous apoproteins. Mechanistic aspects of Fe/S protein biogenesis continue to be elucidated by biochemical and ultrastructural investigations. Here, we review recent developments in the pursuit of constructing a comprehensive model of Fe/S protein assembly in the mitochondrion. Ubiquitous iron-sulfur clusters and their synthesis: an overviewIron-sulfur (Fe/S) 2 clusters are inorganic cofactors that are essential for the proper functioning of virtually all biological cells (1). The chemical versatility of these clusters is utilized in fundamental life processes such as energy production, metabolic conversions, DNA maintenance, gene expression regulation, protein translation, and the antiviral response ( Fig. 1) (2-4). In eukaryotes, Fe/S proteins are found in or associated with the mitochondrion, endoplasmic reticulum, cytosol, and the nucleus. These cofactors participate in electron transfer reactions, Lewis acid catalysis, transfer of sulfur atoms, or facilitating structural roles (5, 6). Although the activities of some Fe/S proteins are dispensable for cell survival under certain conditions, for example fungal Fe/S enzymes in the metabolism of amino acids, others such as Fe/S proteins involved in DNA maintenance or protein translation are essential for cell viability (Fig. 1). The growing number of diseases that implicate Fe/S proteins or their assembly factors illustrates the essentiality of the various functions of these protein cofactors (7-9). The phenotypes associated with these "Fe/S diseases" and the in vivo work in model systems such as Saccharomyces cerevisiae and human cell culture have led to a mechanistic model of eukaryotic Fe/S protein biogenesis, in which the sequence of events required for proper synthesis and trafficking of Fe/S clusters has been elucidated (2). This model has been invaluable to diagnosing new mitochondrial disorders, and its continued advancement will enhance the ability for early diagnosis (10 -13). The focus of this review will be on the latest developments of the functional and mechanistic aspects that have advanced the model of mitochondrial Fe/S protein biogenesis.Cells typically maintain a strict balance of iron and sulfide ion concentrations due to their damaging redox reactions when present in excess (14, 15). The cell also uses a complex biosynthetic system to ensure that the sometimes redox-sensitive and labile Fe/S clusters are assembled correctly, trafficked to specific target apoproteins, and remain protected during these processes. This cellular control is exemplified by the 18 known "Fe/S cluster assembly" (ISC) proteins...

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“…2 These concepts proved prescient as they have been supported by a number of recent findings which have shown that the macrophage-erythroblast interactions mediated by a large number of adhesion molecules are essential for the highly regulated process of erythroblast proliferation and survival which is necessary for the production of two million reticulocytes per second. [3][4][5][6] In this context the recent findings that in vivo depletion of erythroblastic island macrophages blocks erythroblast proliferation and maturation fully validates the central role of macrophages in regulating erythropoiesis. 7 Apart from playing an important role in the genesis of red blood cells within the bone marrow, macrophages of the reticulocyte endothelial system in general and spleen in particular play a critical role in quality control by removing senescent and damaged red cells from the circulation.…”

mentioning

confidence: 99%

“…The exact route of uptake of NTBI remains unclear, but it is well established that NTBI is responsible for parenchymal cell iron overload. 1,5 β-thalassemia is a congenital anemia characterized by ineffective erythropoiesis, increased Tf saturation and tissue iron overload. 6 It represents a paradigmatic disorder of erythropoiesis characterized by anemia and dysfunction of iron homeostasis.…”

mentioning

confidence: 99%

Increasing serum transferrin to reduce tissue iron overload due to ineffective erythropoiesis

Tolosano

2015

Haematologica

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Cellular iron uptake, trafficking and metabolism: Key molecules and mechanisms and their roles in disease

Cited by 305 publications

References 147 publications

Unchanneling cardiac iron in humans

Unchanneling cardiac iron in humans

Iron–sulfur cluster biogenesis and trafficking in mitochondria

Increasing serum transferrin to reduce tissue iron overload due to ineffective erythropoiesis

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