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Query: UMLS:C0016719 (
Friedreich's ataxia
)
2,098
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
With rare exceptions, virtually all studied organisms from Archaea to man are dependent on iron for survival. Despite the ubiquitous distribution and abundance of iron in the biosphere, iron-dependent life must contend with the paradoxical hazards of iron deficiency and iron overload, each with its serious or fatal consequences. Homeostatic mechanisms regulating the absorption, transport, storage and mobilization of cellular iron are therefore of critical importance in iron metabolism, and a rich biology and chemistry underlie all of these mechanisms. A coherent understanding of that biology and chemistry is now rapidly emerging. In this review we will emphasize discoveries of the past decade, which have brought a revolution to the understanding of the molecular events in iron metabolism. Of central importance has been the discovery of new proteins carrying out functions previously suspected but not understood or, more interestingly, unsuspected and surprising. Parallel discoveries have delineated regulatory mechanisms controlling the expression of proteins long known--the transferrin receptor and ferritin--as well as proteins new to the scene of iron metabolism and its homeostatic control. These proteins include the iron regulatory proteins (IRPs 1 and 2), a variety of ferrireductases in yeast an mammalian cells, membrane transporters (DMT1 and ferroportin 1), a multicopper
ferroxidase
involved in iron export from cells (hephaestin), and regulators of mitochondrial iron balance (frataxin and MFT). Experimental models, making use of organisms from yeast through the zebrafish to rodents have asserted their power in elucidating normal iron metabolism, as well as its genetic disorders and their underlying molecular defects. Iron absorption, previously poorly understood, is now a fruitful subject for research and well on its way to detailed elucidation. The long-sought hemochromatosis gene has been found, and active research is underway to determine how its aberrant functioning results in disease that is easily controlled but lethal when untreated. A surprising connection between iron metabolism and
Friedreich's ataxia
has been uncovered. It is no exaggeration to say that the new understanding of iron metabolism in health and disease has been explosive, and that what is past is likely to be prologue to what is ahead.
...
PMID:Chemistry and biology of eukaryotic iron metabolism. 1147 Feb 29
Iron is essential for oxidation-reduction catalysis and bioenergetics; however, unless appropriately shielded, this metal plays a crucial role in the formation of toxic oxygen radicals that can attack all biological molecules. Organisms are equipped with specific proteins designed for iron acquisition, export and transport, and storage, as well as with sophisticated mechanisms that maintain the intracellular labile iron pool at an appropriate level. Despite these homeostatic mechanisms, organisms often face the threat of either iron deficiency or iron overload. This review describes several hereditary iron-overloading conditions that are confined to the brain. Recently, a mutation in the L-subunit of ferritin has been described that causes the formation of aberrant L-ferritin with an altered C-terminus. Individuals with this mutation in one allele of L-ferritin have abnormal aggregates of ferritin and iron in the brain, primarily in the globus pallidus. Patients with this dominantly inherited late-onset disease present with symptoms of extrapyramidal dysfunction. Mice with a targeted disruption of a gene for iron regulatory protein 2 (IRP2), a translational repressor of ferritin, misregulate iron metabolism in the intestinal mucosa and the central nervous system. Significant amounts of ferritin and iron accumulate in white matter tracts and nuclei, and adult IRP2-deficient mice develop a movement disorder consisting of ataxia, bradykinesia, and tremor. Mutations in the frataxin gene are responsible for
Friedreich's ataxia
, the most common of the inherited ataxias. Frataxin appears to regulate mitochondrial iron-sulfur cluster formation, and the neurologic and cardiac manifestations of
Friedreich's ataxia
are due to iron-mediated mitochondrial toxicity. Patients with Hallervorden-Spatz syndrome, an autosomal recessive, progressive neurodegenerative disorder, have mutations in a novel pantothenate kinase gene (PANK2). The cardinal feature of this extrapyramidal disease is pathologic iron accumulation in the globus pallidus. The defect in PANK2 is predicted to cause the accumulation of cysteine, which binds iron and causes oxidative stress in the iron-rich globus pallidus. Finally, aceruloplasminemia is an autosomal recessive disorder of iron metabolism caused by loss-of-function mutations in
ceruloplasmin
gene that leads to misregulation of both systemic and central nervous system iron trafficking. Affected individuals suffer from extrapyramidal signs, cerebellar ataxia, progressive neurodegeneration of retina, and diabetes mellitus. Excessive iron depositions are found in the brain, liver, pancreas, and other parenchymal cells, but plasma iron concentrations are decreased. These conditions are not common, but awareness about them is important for differential diagnosis of various neurodegenerative disorders.
...
PMID:Hereditary causes of disturbed iron homeostasis in the central nervous system. 1510 72
Mitochondria generate adenosine triphosphate (ATP) but also dangerous reactive oxygen species (ROS). One-electron reduction of dioxygen in the early stages of the electron transport chain yields a superoxide radical that is detoxified by mitochondrial superoxide dismutase to give hydrogen peroxide. The hydroxyl radical is derived from decomposition of hydrogen peroxide via the Fenton reaction, catalyzed by Fe2+ ions. Mitochondria require a constant supply of Fe2+ for heme and iron-sulfur cluster biosyntheses and therefore are particularly susceptible to ROS attack. Two main antioxidant defenses are known in mitochondria: enzymes that catalytically remove ROS, e.g. superoxide dismutase and glutathione peroxidase, and low molecular weight agents that scavenge ROS, including coenzyme Q, glutathione, and vitamins E and C. An effective defensive system, however, should also involve means to control the availability of pro-oxidants such as Fe2+ ions. There is increasing evidence that this function may be carried out by the mitochondrial protein frataxin. Frataxin deficiency is the primary cause of
Friedreich's ataxia
(
FRDA
), an autosomal recessive degenerative disease. Frataxin is a highly conserved mitochondrial protein that plays a critical role in iron homeostasis. Respiratory deficits, abnormal cellular iron distribution and increased oxidative damage are associated with frataxin defects in yeast and mouse models of
FRDA
. The mechanism by which frataxin regulates iron metabolism is unknown. The yeast frataxin homologue (mYfh1p) is activated by Fe(II) in the presence of oxygen and assembles stepwise into a 48-subunit multimer (alpha48) that sequesters >2000 atoms of iron in a ferrihydrite mineral core. Assembly of mYfhlp is driven by two sequential iron oxidation reactions: a fast
ferroxidase
reaction catalyzed by mYfh1p induces the first assembly step (alpha --> alpha3), followed by a slower autoxidation reaction that promotes the assembly of higher order oligomers yielding alpha48. Depending on the ionic environment, stepwise assembly is associated with the sequestration of < or = 50-75 Fe(II)/subunit. This Fe(II) is initially loosely bound to mYfh1p and can be readily mobilized by chelators or made available to the mitochondrial enzyme ferrochelatase to synthesize heme. However, as iron oxidation and mineralization proceed, Fe(III) becomes progressively inaccessible and a stable iron-protein complex is produced. In conclusion, by coupling iron oxidation with stepwise assembly, frataxin can successively function as an iron chaperon or an iron store. Reduced iron availability and solubility and increased oxidative damage may therefore explain the pathogenesis of
FRDA
.
...
PMID:Functional studies of frataxin. 1517 25
We report a 60-year-old man with a 6-year history of tremor in his hands. He noted the onset of short of breath and gait disturbance in 1994; both of these symptoms were slowly progressive. Then recently he developed fever two months prior to the present admission. He was admitted to the rheumatology department of our hospital and neurological consultation was asked on December 13, 2000. On neurologic examination, he showed Gottron sign and fine crackle in both lungs. Pertinent neurological findings were bilateral dysmetria in finger-to-nose and heel-to-knee tests and a broad-based gait. In addition, he showed intention tremor in upper extremities more on the left. Romberg sign was positive. Deep tendon reflexes were decreased. Vibratory sensation was reduced at the wrists. The patient's hemoglobin was 11.1 g/dl, with a mean corpuscular volume of 92.0 fl. Vitamin B12 level was 190 (reference range, >230 pg/ml). Serum lactic acid, pyruvic acid and
ceruloplasmin
were slightly elevated. Chest X-ray showed interstitial pneumonia. Muscle biopsy showed grouping of small angular fiber. Brain MRI showed diffuse atrophy of the cerebral cortex and the cerebellum hemisphere. Thalamotomy did not improve his tremor. He was admitted again in November 2001. General worsening of his neurological findings was observed. IL2-receptor was markedly elevated. Serum anti-Hu, Yo and Ri antibodies were negative. An anaplastic carcinoma was found in his jejunum. He died from respiratory failure in February 2002. He was discussed in a neurological CPC and the chief discussant arrived at a conclusion that the patient had paraneoplastic syndrome. Other diagnosis entertained included MERRF, GSS, Ramsay Hunt syndrome, subacute combined degeneration, spinocerebellar degeneration. Majority of the participants thought that paraneoplastic syndrome was most likely. Post-mortem examination revealed poorly differentiated carcinoma in the small intestine. Myeline pallor was noted in the posterior and the lateral columns in the thoracic spine. Neuronal cell loss was observed in the Purkinje cell and granular cell layer in the cerebellum. Sural nerve demonstrated loss of myelinated fibers and grouping of small fibers. Neuropathological findings were consistent with
Friedreich ataxia
; nevertheless, no mutation was reported in frataxin in Japan. The neuropathologist concluded that neuropathological diagnosis was a spinocerebellar ataxia with neuropathological similarities to
Friedreich ataxia
.
...
PMID:[A 60-year-old man with intention tremor as an initial symptom followed by cerebellar ataxia, peripheral neuropathy and dementia]. 1614 16
Iron that is not specifically chaperoned through its essential functional pathways is damaging to biological systems, in major part by catalyzing the production of reactive oxygen species. Iron serves in several essential roles in the mitochondrion, as an essential cofactor for certain enzymes of electron transport, and through its involvement in the assembly of iron-sulfur clusters and iron-porphyrin (heme) complexes, both processes occurring in the mitochondrion. Therefore, there are mechanisms that deliver iron specifically to mitochondria, although these are not well understood. Under normal circumstances the mitochondrion has levels of stored iron that are higher than other organelles, though lower than in cytosol, while in some disorders of iron metabolism, mitochondrial iron levels exceed those in the cytosol. Under these circumstances of excess iron, protective mechanisms are overwhelmed and mitochondrial damage ensues. This may take the form of acute oxidative stress with structural damage and functional impairment, but also may result in long-term damage to the mitochondrial genome. This review discusses the evidence that mitochondria do indeed accumulate iron in several genetic disorders, and are a direct target for iron toxicity when it is present in excess. We then consider two classes of genetic disorders involving iron and the mitochondrion. The first include defects in genes directly regulating mitochondrial iron metabolism that lead to
Friedreich's ataxia
and the various sideroblastic anemias, with excessive mitochondrial iron accumulation. Under the second class, we discuss various primary hemochromatoses that lead to direct mitochondrial damage, with reference to mutations in genes encoding HFE, hepcidin, hemojuvelin, transferrin receptor-2, ferroportin, transferrin, and
ceruloplasmin
.
...
PMID:Mitochondrial involvement in genetically determined transition metal toxicity I. Iron toxicity. 1679 9
Iron is essential for many metabolic processes but can also cause damage. As a potent generator of hydroxyl radical, the most reactive of the free radicals, iron can cause considerable oxidative stress. Since iron is absorbed through diet but not excreted except through menstruation, total body iron levels buildup with age. Macular iron levels increase with age, in both men and women. This iron has the potential to contribute to retinal degeneration. Here we present an overview of the evidence suggesting that iron may contribute to retinal degenerations. Intraocular iron foreign bodies cause retinal degeneration. Retinal iron buildup resulting from hereditary iron homeostasis disorders aceruloplasminemia,
Friedreich's ataxia
, and panthothenate kinase-associated neurodegeneration cause retinal degeneration. Mice with targeted mutation of the iron exporter
ceruloplasmin
have age-dependent retinal iron overload and a resulting retinal degeneration with features of age-related macular degeneration (AMD). Post mortem retinas from patients with AMD have more iron and the iron carrier transferrin than age-matched controls. Over the past 10 years much has been learned about the intricate network of proteins involved in iron handling. Many of these, including transferrin, transferrin receptor, divalent metal transporter-1, ferritin, ferroportin,
ceruloplasmin
, hephaestin, iron-regulatory protein, and histocompatibility leukocyte antigen class I-like protein involved in iron homeostasis (HFE) have been found in the retina. Some of these proteins have been found in the cornea and lens as well. Levels of the iron carrier transferrin are high in the aqueous and vitreous humors. The functions of these proteins in other tissues, combined with studies on cultured ocular tissues, genetically engineered mice, and eye exams on patients with hereditary iron diseases provide clues regarding their ocular functions. Iron may play a role in a broad range of ocular diseases, including glaucoma, cataract, AMD, and conditions causing intraocular hemorrhage. While iron deficiency must be prevented, the therapeutic potential of limiting iron-induced ocular oxidative damage is high. Systemic, local, or topical iron chelation with an expanding repertoire of drugs has clinical potential.
...
PMID:Iron homeostasis and toxicity in retinal degeneration. 1792 Oct 41
Iron is essential for life, but excess iron can be toxic. As a potent free radical creator, iron generates hydroxyl radicals leading to significant oxidative stress. Since iron is not excreted from the body, it accumulates with age in tissues, including the retina, predisposing to age-related oxidative insult. Both hereditary and acquired retinal diseases are associated with increased iron levels. For example, retinal degenerations have been found in hereditary iron overload disorders, like aceruloplasminemia,
Friedreich's ataxia
, and pantothenate kinase-associated neurodegeneration. Similarly, mice with targeted mutation of the iron exporter
ceruloplasmin
and its homolog hephaestin showed age-related retinal iron accumulation and retinal degeneration with features resembling human age-related macular degeneration (AMD). Post mortem AMD eyes have increased levels of iron in retina compared to age-matched healthy donors. Iron accumulation in AMD is likely to result, in part, from inflammation, hypoxia, and oxidative stress, all of which can cause iron dysregulation. Fortunately, it has been demonstrated by in vitro and in vivo studies that iron in the retinal pigment epithelium (RPE) and retina is chelatable. Iron chelation protects photoreceptors and retinal pigment epithelial cells (RPE) in a variety of mouse models. This has therapeutic potential for diminishing iron-induced oxidative damage to prevent or treat AMD.
...
PMID:Retinal iron homeostasis in health and disease. 2382 57
