UMLS:C0016719 - FACTA Search

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Query: UMLS:C0016719 (Friedreich's ataxia)
2,098 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Friedreich's ataxia (FRDA) is an autosomal recessive disorder with a frequency of 1 in 50 000 live births. In 97% of patients it is caused by the abnormal expansion of a GAA repeat in intron 1 of the FRDA gene on chromosome 9, which encodes a 210 amino acid protein called frataxin. Frataxin is widely expressed and has been localized to mitochondria although its function is unknown. We have investigated mitochondrial function, mitochondrial DNA levels, aconitase activity and iron content in tissues from FRDA patients. There were significant reductions in the activities of complex I, complex II/III and aconitase in FRDA heart. Respiratory chain and aconitase activities were decreased although not significantly in skeletal muscle, but were normal in FRDA cerebellum and dorsal root ganglia, although there was a mild decrease in aconitase activity in the latter. Mitochondrial DNA levels were reduced in FRDA heart and skeletal muscle, although in skeletal muscle this was paralleled by a decline in citrate synthase activity. Increased iron deposition was seen in FRDA heart, liver and spleen in a pattern consistent with a mitochondrial location. The iron accumulation, mitochondrial respiratory chain and aconitase dysfunction and mitochondrial DNA depletion in FRDA heart samples largely paralleled those in the yeast YFH1 knockout model, suggesting that frataxin may be involved in mitochondrial iron regulation or iron sulphur centre synthesis. However, the severe deficiency in aconitase activity also suggests that oxidant stress may induce a self-amplifying cycle of oxidative damage and mitochondrial dysfunction, which may contribute to cellular toxicity.
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PMID:Clinical, biochemical and molecular genetic correlations in Friedreich's ataxia. 1060 38

Friedreich ataxia, an autosomal recessive neurodegenerative disease, is the most common of the inherited ataxias. The recent discovery of the gene that is mutated in this condition, FRDA, has led to rapid advances in the understanding of the pathogenesis of Friedreich ataxia. About 98% of mutant alleles have an expansion of a GAA trinucleotide repeat in intron 1 of the gene. This leads to reduced levels of the protein, frataxin. There is mounting evidence to suggest that Friedreich ataxia is the result of accumulation of iron in mitochondria leading to excess production of free radicals, which then results in cellular damage and death. Currently there is no known treatment that alters the natural course of the disease. The discovery of the FRDA gene and its possible function has raised hope that rational therapeutic strategies will be developed.
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PMID:Friedreich ataxia: an overview. 1063 28

Most cases of Friedreich ataxia (FRDA) are due to expansions of a GAA trinucleotide repeat sequence in the FRDA gene coding for frataxin, a protein of poorly understood function which may regulate mitochondrial iron transport. However, between 1% and 5% of mutations are single base changes in the sequence of the FRDA gene, causing missense, nonsense, or splicing mutations. We describe three new mutations, IVS4nt2 (T to G), R165C, and L182F, which occur in patients in association with GAA expansions. These cases, and a further five reported cases of point mutations causing FRDA, demonstrate that splicing, nonsense, or initiation codon mutations (which cause a complete absence of functional frataxin) are associated with a severe phenotype. Missense mutations, even in highly evolutionally conserved amino acids, may cause a mild or severe phenotype.
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PMID:The correlation of clinical phenotype in Friedreich ataxia with the site of point mutations in the FRDA gene. 1073 99

Friedreich ataxia, the most frequent cause of recessive ataxia, is due in most cases to a homozygous intronic expansion resulting in the loss of function of frataxin. Frataxin is a mitochondrial protein conserved through evolution. Yeast knock-out models and histological data from patient heart autopsies have shown that frataxin defect causes mitochondrial iron accumulation. Biochemical data from patient heart biopsies or autopsies have revealed a specific deficiency in the activities of aconitases and of mitochondrial iron-sulfur proteins. These results suggest that frataxin may play a role either in mitochondrial iron transport or in iron-sulfur cluster assembly or transport. Iron abnormalities suggest a pathogenic mechanism involving free radical production and oxidative stress, a process that might be sensitive to antioxidant therapies.
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PMID:Recent advances in the molecular pathogenesis of Friedreich ataxia. 1076 11

Friedreich ataxia (FRDA), the most common autosomal recessive ataxia, is caused in almost all cases by homozygous intronic expansions resulting in the loss of frataxin, a mitochondrial protein conserved through evolution, and involved in mitochondrial iron homeostasis. Yeast knockout models, and histological and biochemical data from patient heart biopsies or autopsies indicate that the frataxin defect causes a specific iron-sulfur protein deficiency and mitochondrial iron accumulation leading to the pathological changes. Affected human tissues are rarely available to further examine this hypothesis. To study the mechanism of the disease, we generated a mouse model by deletion of exon 4 leading to inactivation of the Frda gene product. We show that homozygous deletions cause embryonic lethality a few days after implantation, demonstrating an important role for frataxin during early development. These results suggest that the milder phenotype in humans is due to residual frataxin expression associated with the expansion mutations. Surprisingly, in the frataxin knockout mouse, no iron accumulation was observed during embryonic resorption, suggesting that cell death could be due to a mechanism independent of iron accumulation.
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PMID:Inactivation of the Friedreich ataxia mouse gene leads to early embryonic lethality without iron accumulation. 1076 47

Remarkable progress is being made in understanding the molecular basis of disorders of human iron metabolism. Recent work has uncovered unanticipated relationships with the immune and nervous systems, intricate interconnections with copper metabolism, and striking homologies between yeast and human genes involved in the transport of transition metals. This review examines the clinical consequences of new insights into the pathophysiology of genetic abnormalities affecting iron metabolism. The proteins recently found to be involved in the absorption, transport, utilization, and storage of iron are briefly described, and the clinical manifestations of genetic disorders that affect these proteins are discussed. This chapter considers the most common inherited disorder in individuals of European ancestry (hereditary hemochromatosis), a widespread disease in sub-Saharan populations for which the genetic basis is still uncertain (African dietary iron overload), and several less frequent or rare disorders (juvenile hemochromatosis, atransferrinemia, aceruloplasminemia, hyperferritinemia with autosomal dominant congenital cataract, Friedreich's ataxia, and X-linked sideroblastic anemia with ataxia).
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PMID:Genetic disorders affecting proteins of iron metabolism: clinical implications. 1077 76

We showed recently that the yeast mitochondrial intermediate peptidase (YMIP polypeptide; gene symbol, OCT1) promotes mitochondrial iron uptake by catalyzing the maturation of iron-utilizing proteins and exacerbates the mitochondrial iron accumulation that results from loss of yeast frataxin, a mitochondrial protein required for mitochondrial iron efflux. This suggests that the human MIP (HMIP polypeptide; gene symbol MIPEP) may be one of the loci predicted to influence the clinical manifestations of Friedreich's ataxia (FRDA), an autosomal recessive neurodegenerative disease caused by lack of human frataxin. To begin to test this hypothesis, we have characterized HMIP at the functional and genomic levels. We show that HMIP can complement a yeast knock-out mutant lacking YMIP, demonstrating that HMIP and YMIP are functional homologues. The MIPEP gene spans 57 kb and consists of 19 exons that correlate with the functional domains of HMIP. Primer extension analysis has identified a major transcript of the MIPEP gene expressed differentially and predominantly in tissues with high oxygen consumption, while sequence analysis of approximately 2 kb of 5'-flanking DNA has revealed putative Mt1/3/4, NF-kappaB, and AP-1 elements that may regulate MIPEP expression in these tissues. Using a new polymorphic (CA)(n) repeat in intron 4, MIPEP has been genetically mapped within a 7-cM interval between markers D13S283 and D13S217 on 13q12. This work provides the basis for molecular analysis of MIPEP in FRDA and possibly other neurodegenerative diseases.
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PMID:Functional and genomic analysis of the human mitochondrial intermediate peptidase, a putative protein partner of frataxin. 1078 57

Mitochondrial iron accumulation is thought to underlie the pathophysiology of Friedreich ataxia and may occur at the expense of cytosolic iron. Decreases in cytosolic iron induce expression of the transferrin receptor, some of which is released into the serum. Here, we demonstrate that serum transferrin receptor concentrations are increased in patients with Friedreich ataxia, which supports the hypothesis that it is a disease of abnormal intracellular iron distribution.
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PMID:Increased serum transferrin receptor concentrations in Friedreich ataxia. 1080 40

Friedreich's ataxia, an autosomal recessive neurodegenerative disorder characterized by progressive gait and limb ataxia, cardiomyopathy, and diabetes mellitus, is caused by decreased frataxin production or function. The structure of human frataxin, which we have determined at 1.8-A resolution, reveals a novel protein fold. A five-stranded, antiparallel beta sheet provides a flat platform, which supports a pair of parallel alpha helices, to form a compact alphabeta sandwich. A cluster of 12 acidic residues from the first helix and the first strand of the large sheet form a contiguous anionic surface on the protein. The overall protein structure and the anionic patch are conserved in eukaryotes, including animals, plants, and yeast, and in prokaryotes. Additional conserved residues create an extended 1008-A(2) patch on a distinct surface of the protein. Side chains of disease-associated mutations either contribute to the anionic patch, help create the second conserved surface, or point toward frataxin's hydrophobic core. These structural findings predict potential modes of protein-protein and protein-iron binding.
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PMID:Crystal structure of human frataxin. 1090 Jan 92

Frataxin deficiency is the primary cause of Friedreich ataxia (FRDA), an autosomal recessive cardiodegenerative and neurodegenerative disease. Frataxin is a nuclear-encoded mitochondrial protein that is widely conserved among eukaryotes. Genetic inactivation of the yeast frataxin homologue (Yfh1p) results in mitochondrial iron accumulation and hypersensitivity to oxidative stress. Increased iron deposition and evidence of oxidative damage have also been observed in cardiac tissue and cultured fibroblasts from patients with FRDA. These findings indicate that frataxin is essential for mitochondrial iron homeostasis and protection from iron-induced formation of free radicals. The functional mechanism of frataxin, however, is still unknown. We have expressed the mature form of Yfh1p (mYfh1p) in Escherichia coli and have analyzed its function in vitro. Isolated mYfh1p is a soluble monomer (13,783 Da) that contains no iron and shows no significant tendency to self-associate. Aerobic addition of ferrous iron to mYfh1p results in assembly of regular spherical multimers with a molecular mass of approximately 1. 1 MDa (megadaltons) and a diameter of 13+/-2 nm. Each multimer consists of approximately 60 subunits and can sequester >3,000 atoms of iron. Titration of mYfh1p with increasing iron concentrations supports a stepwise mechanism of multimer assembly. Sequential addition of an iron chelator and a reducing agent results in quantitative iron release with concomitant disassembly of the multimer, indicating that mYfh1p sequesters iron in an available form. In yeast mitochondria, native mYfh1p exists as monomer and a higher-order species with a molecular weight >600,000. After addition of (55)Fe to the medium, immunoprecipitates of this species contain >16 atoms of (55)Fe per molecule of mYfh1p. We propose that iron-dependent self-assembly of recombinant mYfh1p reflects a physiological role for frataxin in mitochondrial iron sequestration and bioavailability.
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PMID:Iron-dependent self-assembly of recombinant yeast frataxin: implications for Friedreich ataxia. 1093 Mar 61

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