Iron in Friedreich Ataxia: A Central Role in the Pathophysiology or an Epiphenomenon?
<p>Structures of human frataxin (hFxn, pdb code 3s4m) and Yeast Frataxin Homologue 1 (Yfh1, pdb code 2fql). Top, ribbons representations showing the conserved alpha-beta-alpha structure. Structures are colored according to sequence, from dark blue (N-terminal) to red (C-terminal). In human frataxin the C-terminal region folds over the hydrophobic cavity formed between both alpha helices. Below, coulumbic surface coloring of the same structures. The red color indicates the presence of a marked acidic ridge, which may be involved in iron binding. Molecular graphics and analyses were performed with the UCSF Chimera package [<a href="#B11-pharmaceuticals-11-00089" class="html-bibr">11</a>].</p> "> Figure 2
<p>Potential contribution of frataxin to iron homeostasis and cellular consequences of its deficiency. (<b>A</b>), physiological: frataxin (FXN) binds Fe<sup>2+</sup> and contributes to its controlled oxidation to Fe<sup>3+</sup> and/or to incorporate it into Fe-containing proteins. These Fe-containing proteins (notably FeS proteins) keep the iron sensor inactive and genes involved in iron uptake are not expressed. Oxidized iron (Fe<sup>3+</sup>) is stored in the form of ferric-phosphate nanoparticles. (<b>B</b>), frataxin-deficient: loss of frataxin leads to decreased incorporation of iron into Fe-proteins and/or uncontrolled oxidation of Fe<sup>2+</sup> by O<sub>2</sub>. Such events lead to reactive oxygen species (ROS) generation, decreased phosphate availability, and mitochondrial dysfunction. Iron sensors and other cell signaling pathways are activated and regulate the expression of genes involved in iron uptake and/or other cell-specific pathways involved on metabolic remodeling, hypertrophy or neurodegeneration.</p> ">
Abstract
:1. The Disease
2. Frataxin, an Ancestral Conserved Protein
3. Frataxin Function
3.1. Frataxin, an Iron Binding and Storage Protein
3.2. Frataxin in the Biosynthesis of Iron Containing Proteins
3.2.1. Biosynthesis of Heme Groups
3.2.2. Biosynthesis of Iron-Sulfur Centers
3.3. Control of Oxidative Stress and the Generation of Ros
4. Evidences of Iron Accumulation and Its Relation to Pathophysiology in FRDA
5. Targeting Iron as a Therapeutic Approach in FRDA
6. Concluding Remarks
Funding
Acknowledgments
Conflicts of Interest
References
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Alsina, D.; Purroy, R.; Ros, J.; Tamarit, J. Iron in Friedreich Ataxia: A Central Role in the Pathophysiology or an Epiphenomenon? Pharmaceuticals 2018, 11, 89. https://doi.org/10.3390/ph11030089
Alsina D, Purroy R, Ros J, Tamarit J. Iron in Friedreich Ataxia: A Central Role in the Pathophysiology or an Epiphenomenon? Pharmaceuticals. 2018; 11(3):89. https://doi.org/10.3390/ph11030089
Chicago/Turabian StyleAlsina, David, Rosa Purroy, Joaquim Ros, and Jordi Tamarit. 2018. "Iron in Friedreich Ataxia: A Central Role in the Pathophysiology or an Epiphenomenon?" Pharmaceuticals 11, no. 3: 89. https://doi.org/10.3390/ph11030089
APA StyleAlsina, D., Purroy, R., Ros, J., & Tamarit, J. (2018). Iron in Friedreich Ataxia: A Central Role in the Pathophysiology or an Epiphenomenon? Pharmaceuticals, 11(3), 89. https://doi.org/10.3390/ph11030089