UMLS:C0011849 - FACTA Search

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Query: UMLS:C0011849 (diabetes)
277,896 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The aim of this study was to determine phenotypie characteristics of patients with early onset cerebellar ataxia (EOCA) with preserved tendon reflexes. The series comprises 25 patients, representing 10% of all ataxic patients who have been genetically studied in our laboratory since 1990. There were 11 males and 14 females. Fourteen patients were homozygous for the GAA expansion on chromosome 9q13 (group 1) and therefore a diagnosis of Friedreich's ataxia with retained reflexes (FARR) was given. The remaining 11 patients had two normal non-expanded alleles (group 2) and a working diagnosis of EOCA with retained reflexes (EOCARR) was established. Mean ages of onset were 13.7 +/- 5.9 years (3-25) for group 1 and 10.3 +/- 7.3 for group 2; the difference was not significant. Frequencies of symptoms and signs were also comparable for both groups the only significant differences being the higher frequency of nystagmus, cardiomyopathy and sensory neuropathy in group 1 patients. There was a tendency for FARR patients to have higher frequencies of hypopallesthesia in the lower limbs and skeletal deformities. In none of the cases diabetes mellitus was observed. We conclude that differentiation of FARR and EOCARR may be suspected by classical clinical and electrophysiological data and confirmed by analysis of the GAA repeat.
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PMID:Early onset cerebellar ataxia and preservation of tendon reflexes: clinical phenotypes associated with GAA trinucleotide repeat expanded and non-expanded genotypes. 1019 66

Friedreich ataxia is an autosomal recessive disorder caused by mutations in the FRDA gene that encodes a 210-amino acid protein called frataxin. An expansion of a GAA trinucleotide repeat in intron 1 of the gene is present in more than 95% of mutant alleles. Of the 83 people we studied who have mutations in FRDA, 78 are homozygous for an expanded GAA repeat; the other five patients have an expansion in one allele and a point mutation in the other. Here we present a detailed clinical and genetic study of a subset of 51 patients homozygous for an expansion of the GAA repeat. We found a correlation between the size of the smaller of the two expanded alleles and age at onset, age into wheelchair, scoliosis, impaired vibration sense, and the presence of foot deformity. There was no significant correlation between the size of the smaller allele and cardiomyopathy, diabetes mellitus, loss of proprioception, or bladder symptoms. The larger allele size correlated with bladder symptoms and the presence of foot deformity. The duration of disease is correlated with wheelchair use and the presence of diabetes, scoliosis, bladder symptoms and impaired proprioception, and vibration sense but no other complications studied.
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PMID:Clinical and genetic study of Friedreich ataxia in an Australian population. 1053 31

We describe two sisters with early onset gait ataxia, rapid disease progression, absent or very mild dysarthria and upper limb dysmetria, retained knee jerks in one, slight to moderate peripheral nerve involvement, and diabetes. Molecular analysis showed that they are compound heterozygotes for GAA expansion and a novel exon 5a missense mutation (R165P). This mutation appears to be associated with an atypical but not milder Friedreich ataxia phenotype.
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PMID:Atypical Friedreich ataxia phenotype associated with a novel missense mutation in the X25 gene. 1066 23

We clinically assessed and performed polymerase chain reaction analysis for the GAA trinucleotide repeat expansion in 103 patients from 73 families in Ireland, with a prior clinical diagnosis of Friedreich's ataxia (FA) or an unclassified progressive ataxic syndrome. The patients were classified as "typical" or "atypical" FA according to Harding's mandatory clinical diagnostic criteria. All patients underwent blood glucose analysis, and electrocardiography and echocardiography was performed in 99 and 101 patients, respectively. Mutation screening for expanded CAG trinucleotide repeats, associated with spinocerebellar ataxia (SCA) 1, 2, 3 and 6 was performed in 86 patients overall, including all GAA negative patients. Forty-nine of 56 typical patients and 13 of 47 atypical patients were either homozygous or heterozygous for the GAA expansion. Seven patients with a typical FA phenotype were negative for the GAA expansion. Although one of these patients had vitamin E deficiency, and two had raised alpha-fetoprotein levels, three other GAA negative patients with a typical FA phenotype had no other identifiable cause for their ataxia, once again raising the possibility of locus heterogeneity in FA. It is also possible that these patients have two point mutations in the X25 gene, or that they have another ataxic syndrome mimicking the FA phenotype. Two families who were homozygous for the GAA expansion exhibited intrafamilial phenotypic variability. Only one GAA negative patient had the SCA 3 mutation, and this was the only patient in the study with a possible autosomal dominant inheritance pattern. In the homozygous GAA population typical patients had significantly more repeats on the smaller allele than atypical patients, and there was an inverse relationship between the number of repeats on the smaller allele and the age at presentation. There was also an inverse relationship between the repeat size on both the larger and the smaller of the two alleles and the age at becoming wheelchair bound. There was no significant relationship between repeat size and the other indices of disease severity, including the presence or absence of diabetes or cardiomyopathy. This is the first large study of an Irish population with progressive ataxia that has shown a similar phenotype/genotype relationship to studies of FA in other European and non-European populations. The relatively low sensitivity and specificity of Harding's clinical diagnostic criteria must be appreciated when clinically assessing patients with a progressive ataxic syndrome. Although molecular genetic analysis now plays an essential role in diagnosis and classification, patients with a typical FA phenotype without any identifiable cause for their ataxia exist.
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PMID:Typical Friedreich's ataxia without GAA expansions and GAA expansion without typical Friedreich's ataxia. 1089 66

Friedreich's ataxia (FA) is an autosomal recessive disease that has been attributed to a GAA triplet repeat expansion in the first intron of the X25/frataxin gene. Impaired glucose tolerance is present in up to 39% of FA patients, and clinically apparent diabetes is seen in approximately 18% of the affected individuals. Subjects carrying the X25/frataxin GAA repeat in a heterozygous state do not develop FA and, therefore, represent an ideal model to study the underlying metabolic defects that contribute to the diabetes associated with this disorder. In the present study, we have compared 11 first-degree relatives of FA patients (i.e., parents or heterozygous siblings of FA patients) with matched normal control subjects to study the parameters of glucose metabolism. An oral glucose tolerance test revealed diabetes in one of the heterozygous subjects who was excluded from further analyses. Using an octreotide-based quantification of insulin sensitivity, 8 of the remaining 10 study subjects showed pronounced insulin resistance, reflecting a significant difference from the control group (P = 0.001). In conclusion, a heterozygous expansion of the X25/frataxin GAA repeat in healthy individuals is associated with insulin resistance and might be considered a genetic co-factor in the pathogenesis of mitochondrial subtypes of diabetes.
Diabetes 2000 Sep
PMID:Heterozygous expansion of the GAA tract of the X25/frataxin gene is associated with insulin resistance in humans. 1096 48

The purpose of the current study was to develop and evaluate rapid assays for autoantibodies to GAD65 (GAA), ICA512bdc/IA-2 (ICA512AA), and insulin (microIAA, mIAA) as a potential tool for identification of cadaveric pancreas donors who were at high risk for developing diabetes. The study included 154 new onset diabetic, prediabetic, and healthy control subjects. Subjects were evaluated for all three autoantibodies in three separate assays: (1) standard (std) assay with a 24-h or 72-h incubation at 4 degrees C (combined GAA/ICA512AA or mIAA, respectively), (2) rapid assay with 1-h room temperature (RT) incubation, and (3) rapid assay with 2-h RT incubation. The serum samples from 777 organ donors were also evaluated for all three autoantibodies and all the positive samples from standard assay evaluated with the 1-h incubation assay. Simple linear regression analyses revealed excellent correlation between the standard assay and the rapid assays for all three autoantibodies, as follows: (1) GAA: std vs. 1 h (R2=0.85) and std vs. 2 h (R2=0.83), (2) ICA512AA: std vs. 1 h (R2=0.85) and std vs. 2 h (R2=0.84), and (3) mIAA: std vs. 1 h (R2=0.70) and std vs. 2 h (R2=0.64). Comparison of assay correlation rates between subject cohorts revealed no significant differences. Compared to their respective standard assays, the 1-h RT GAA assay missed 3.2% and identified an additional 1.3% of samples, the 1-h RT ICA512AA assay had no discordant samples, and the 1-h RT mIAA assay missed 7.1% and identified an additional 5.8% of samples. We analysed a series of 777 stored serum samples from cadaveric donors. Two of 777 (0.25%) were positive for two autoantibodies (both GAA and ICA512AA) and 23 of 777 (3.0%) one autoantibody (11 IAA; 12 GAA). The rapid analysis for all three autoantibodies could be completed in less than 3 h with comparable concordance rates to the more time-consuming standard assays, making these assays an attractive option for organ donor screening to identify potential pancreata for immunopathogenetic research.
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PMID:Rapid assays for detection of anti-islet autoantibodies: implications for organ donor screening. 1122 98

Friedreich's ataxia is an autosomal recessive neuro-degenerative disorder involving both central and peripheral nervous system. Patients also show a systemic clinical picture presenting heart disease and diabetes mellitus or glucose intolerance. The disease is caused by mutations in the FRDA gene mapped on chromosome 9q13. The product of the gene is frataxin, an 18 kDa soluble mitochondrial protein with 210 amino acids. Crystal structure suggests a new, not previously reported, protein fold. The most frequent mutation is the expansion of a GAA trinucleotide repeat located within the first intron of the gene, and represents 98% of the mutations. Point mutations are described in compound heterozygous subjects with one expanded allele. A two-step model of GAA normal alleles towards premutation alleles, which might generate further full expanded mutations in the population with Indo-European ancestry, has been postulated. Clinical phenotype is variable and an inverse correlation with the GAA expansion size has been observed. Analysis of the GAA triplet is a strong molecular tool for clinical diagnosis, genetic counselling and prenatal diagnosis. Friedreich's ataxia patho-genesis is not solved yet. Substantial data from organism models, such the S. cerevisae yeast and more recently conditioned knock-outs in mouse, and studies in heart biopsies and fibroblast cultures from patients suggest an important role of mitochondrial iron in the development of the disease. Iron is accumulated in the mitochondrial matrix of both the yeast frataxin deficient mutant and the patient fibroblasts. It has been postulated that iron-induced oxygen radical affects the oxidative phosphorylation in frataxin deficiency states favouring the disease pathology. A second hypothesis postulates a direct role of frataxin in the mitochondrial energy activation and oxidative phosphorylation. Iron chelator drugs and antioxidant drugs have been postulated for Friedreich's treatment. No results from clinical trials are available yet, but idebenone, a short-chain quinone, seems to reduce the size of hypertrophic cardiomyopathy and levels of oxidative stress molecules in patients.
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PMID:Friedreich's ataxia and frataxin: molecular genetics, evolution and pathogenesis (Review). 1135 Dec 69

Friedreich's ataxia, the most common autosomal recessive inherited ataxia, is characterized by progressive gait and limb ataxia. Friedreich's ataxia is known for its occurrence within the first or second decade of life and is associated with hypertrophic cardiomyopathy, and in some cases with diabetes. Genetically, it is identified by the expression of an unstable trinucleotide GAA repeat expansion located in the first intron of the X25 gene on chromosome 9. Two brothers with very late adult-onset ataxia, and their unaffected sister, were examined for the clinical presentation of FA and for the presence of the mutated FA gene. The relationship of the expanded gene sequence to the severity of disease and age of onset were evaluated. Clinical examination revealed that the two brothers had mild ataxia and proprioceptive loss, with age of onset between 60 and 70 years of age. DNA from peripheral blood nucleated cells demonstrated a small homozygous expansion, with approximately 120-130 GAA repeats in the X25 gene in both patients. The expanded repeats were interrupted either with GAAGAG, GAAGGA, or GAAGAAAA sequences. The unaffected sister carried a normal FA genotype with 8-uninterrupted GAA repeat, observed by sequence analysis. In addition, the levels of FA gene transcript in both brothers were relatively lower than that in the unaffected sister. No detectable cardiomyopathy or diabetes was observed. Phenotypic diversity of FA is increasingly expanding. The age of onset and the structure of GAA repeat expansion plays an important role in determining the clinical features and the differential diagnosis of FA. The confirmation of the FA gene mutation in the atypical case, broadens the clinical spectrum of FA, and supports the idea that patients with even a mild form of ataxia of late adult onset should be considered for molecular testing.
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PMID:Sequence variation in GAA repeat expansions may cause differential phenotype display in Friedreich's ataxia. 1174 52

Friedreich ataxia is an autosomal recessive disease causing degeneration in the central and peripheral nervous system, cardiomyopathy, skeletal abnormalities and increased risk of diabetes. It is caused by deficiency of frataxin, a highly conserved nuclear-encoded mitochondrial protein. The genetic mutation found in 98% of Friedreich ataxia chromosomes is the unstable hyperexpansion of a GAA triplet repeat in the first intron of the gene. The expanded GAA repeat, by adopting an abnormal triple helical structure, impairs frataxin transcription. Longer repeats cause a more profound frataxin deficiency and are associated with earlier onset and increased severity of the disease. Yeast cells deficient in the frataxin homologue (Deltayfh1) become unable to carry out oxidative phosphorylation, lose mitochondrial DNA, accumulate iron in mitochondria, show unregulated high expression of high affinity iron uptake, and have an increased sensitivity to oxidative stress. Loss of respiratory competence in Deltayfh1 is iron-dependent. Additional properties of these cells include a deficiency of iron-sulfur cluster containing proteins (ISPs) and impaired iron efflux out of mitochondria. Evidence of oxidative stress, mitochondrial dysfunction, deficiency of multiple ISPs and iron deposits are also found in the human disease and in mouse models. The primary function of frataxin is still unknown, however much recent evidence suggests that it enhances iron-sulfur cluster synthesis and protects iron from free radical-generating reactions. The search for frataxin function stimulated more investigations on the role of mitochondria in cellular iron homeostasis. Their results suggest that these organelles may play a central role in controlling iron homeostasis, which is not surprising considering that they are the major cellular site where this metal is utilized. I propose a model, valid in yeast as well as in higher eukaryotes, in which iron transport into mitochondria is directly coupled to its uptake at the cell membrane and iron transport out of mitochondria depends on adequate iron-sulfur cluster synthesis. Regulatory mechanisms in the cytosol would then sense a post-mitochondrial iron pool. Much circumstantial evidence from genetically manipulated yeast and from human diseases supports this model.
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PMID:Iron metabolism and mitochondrial abnormalities in Friedreich ataxia. 1254 48

A GAA-repeat in the X25 gene is causing Friedreich's ataxia (FRDA), a common neurodegenerative disease and >20% of FRDA patients develop type II diabetes (T2D). Linkage has previously been detected between T2D and chromosome 9p13-q21, the region that harbours the X25 gene, but association studies of this gene in T2D have been contradicting. Here, we examined whether genetic variation in the X25 gene is associated with risk for T2D. The GAA-repeat and 18 single nucleotide polymorphisms (SNPs) covering the X25 gene were genotyped in 220 trios in which the affected offspring had abnormal glucose tolerance. Any nominally significant findings were examined in an independent sample consisting of 523 individuals with T2D and 326 healthy controls. Previously reported results were analysed together with our data using a meta-analysis approach. There was no association between the GAA-repeat and T2D susceptibility in our study, which was supported by the meta-analysis including all previous publications. One SNP (rs2498429), 8.2 kb downstream of X25, was nominally associated with T2D in the trios (P=0.02) and showed a trend of association in the same direction in the case-controls (P=0.08; combined permuted P=0.01). Further analysis showed that the nine-marker haplotype containing the rare allele of rs2498429 was nominally associated with T2D in the trios (P<0.01) as well as in the case-controls (P=0.03). In conclusions, this study excludes a role of genetic variation within the X25 gene, but instead suggests that genetic variation downstream the X25 gene, may increase risk for T2D.
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PMID:Haplotype construction of the FRDA gene and evaluation of its role in type II diabetes. 1582 63

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