Association of moderate polyglutamine tract expansions in the slow calcium-activated potassium channel type 3 with ataxia

BACKGROUND: The small-conductance calcium-activated potassium channel gene (hSKCa3) contains 2 CAG repeats, 1 of which is highly polymorphic. Although this repeat is not pathologically expanded in patients with schizophrenia, some studies have suggested an allelic association with schizophrenia. CAG expansions in other genes such as the alpha1 subunit of a brain-specific P/Q-type calcium channel gene cause spinocerebellar ataxia type 6, whereas the length of the CAG repeat in the RAI1 gene modifies the age of onset of spinocerebellar ataxia type 2. OBJECTIVES: To evaluate expansions in the hSKCa3 polyglutamine domain as causative for ataxia, and to study the association between the length of the polyglutamine repeat and the presence of ataxia. METHODS: We analyzed this repeat in 122 patients with autosomal dominant cerebellar ataxia, or sporadic ataxia, and compared allele distribution with 750 alleles seen in 2 healthy control groups and 172 alleles in patients with Parkinson disease. RESULTS: The distribution of alleles in ataxia patients and controls was significantly different by Wilcoxon rank test (P <.001). Twenty-two or more polyglutamine tracts were more common in ataxia patients compared with controls by chi2 analysis (P<.001). CONCLUSION: Longer stretches of polyglutamines in a human potassium channel are not causative for ataxia, but they are associated with the presence of ataxia. There is no association with the presence of Parkinson disease.     

Trinucleotide repeat expansion in neurological disease

Expansion of trincleotide repeats is now recognized as a major cause of neurological disease. At least seven disorders result from trinucleotide repeat expansion: X-linked spinal and bulbar muscular atrophy (SBMA), two fragile×syndromes of mental retardation (FRAXA and FRAXE), myotonic dystrophy, Huntington's disease, spinocerebellar ataxia type 1 (SCA1), and dentatorubral-pallidoluysian atrophy (DRPLA). The expanded trinucleotide repeats are unstable, and the phenomenon of anticipation, i.e., worsening of disease phenotype over successive generations, correlates with increasing expansion size. In this review, we compare the clinical and molecular features of the trinucleotide repeat diseases, which may be classified into two types. Fragile×and myotonic dystrophy are multisystem disorders usually associated with large expansions of untranslated repeats, while the four neurodegenerative disorders, SBMA, Huntington's disease, SCA1, and DRPLA, are caused by smaller expansions of CAG repeats within the protein coding portion of the gene. CAG repeats encode polyglutamine tracts. Polyglutamine tract expansion thus appears to be a common mechanism of inherited neurodegenerative disease. Although polyglutamine tract lenghthening presumably has a toxic gain of function effect in the CAG trinucleotide repeat disorders, the basis of this neuronal toxicity remains unknown.     

Friedreich ataxia—update on pathogenesis and possible therapies

Friedreich ataxia is the most-common inherited ataxia. Since the causative genetic basis was described in 1996, much has been learnt about the pathogenesis from human, animal, and yeast studies. This has led to the development of rational therapeutic approaches. In this review, the current state of knowledge regarding the pathogenesis of Friedreich ataxia is presented and possible therapeutic strategies based on this knowledge are discussed.None of the authors has any conflicts of interest.     

The clinical diagnosis of autosomal dominant spinocerebellar ataxias

The spinocerebellar ataxias (SCAs) are a heterogeneous group of autosomal dominantly inherited progressive ataxia diseases. Up to now, almost 30 different gene loci have been found. In 14 of them, the underlying mutations have been identified. The more common SCAs, SCA1, 2, 3 and 6 are due to translated CAG repeat expansions that code for an elongated polyglutamine tract within the respective proteins. These diseases belong to a larger group of polyglutamine disorders that also includes Huntington’s disease. Epidemiological studies conducted in different European regions found prevalence rates of SCAs ranging from 0.9 to 3.0:100,000. In all SCAs, ataxia is the prominent symptom. However, the majority have a complex phenotype in which ataxia is accompanied by varying non-ataxia symptoms. In all ataxia patients with proven or suspected autosomal dominant mode of inheritance, the available molecular genetic tests for SCA mutations should be performed. Depending on the geographical origin of the family, these tests will lead to positive diagnostic results in at least half of the families.     

A review of friedreich ataxia clinical trial results

There are now 21 agents or classes of therapeutic agents in the Friedreich ataxia research pipeline (http://www.curefa.org/pipeline.html) that have been developed in the 15 years since the discovery of the frataxin gene, with the ongoing characterization of its mutations and the resulting molecular pathology. Twenty-four studies are currently posted on ClinicalTrials.gov. Twenty-seven works discussing the results of clinical trials in Friedreich ataxia have been published. In 2010, 42 public (National Institutes of Health) and private (Friedreich Ataxia Research Alliance, Muscular Dystrophy Association, and National Ataxia Foundation) grants were funded for translational and clinical research in Friedreich ataxia. Millions of dollars from public, private, and industry-based initiatives have been dedicated to research in Friedreich ataxia therapeutics. Despite this vigorous international effort, there is as yet no proven disease-modifying therapy for Friedreich ataxia.     

Milestones in ataxia

The past 25 years have seen enormous progress in the deciphering of the genetic and molecular basis of ataxias, resulting in improved understanding of their pathogenesis. The most significant milestones during this period were the cloning of the genes associated with the common spinocerebellar ataxias, ataxia telangiectasia, and Friedreich ataxia. To date, the causative mutations of more than 30 spinocerebellar ataxias and 20 recessive ataxias have been identified. In addition, there are numerous acquired ataxias with defined molecular causes, so that the entire number of distinct ataxia disorders exceeds 50 and possibly approaches 100. Despite this enormous heterogeneity, a few recurrent pathophysiological themes stand out. These include protein aggregation, failure of protein homeostasis, perturbations in ion channel function, defects in DNA repair, and mitochondrial dysfunction. The clinical phenotypes of the most common ataxia disorders have been firmly established, and their natural history is being studied in ongoing large observational trials. Effective therapies for ataxias are still lacking. However, novel drug targets are under investigation, and it is expected that there will be an increasing number of therapeutic trials in ataxia. © 2011 Movement Disorder Society     

An interrupted 34-CAG repeat SCA-2 allele in patients with sporadic spinocerebellar ataxia

In spinocerebellar ataxia type 2 (SCA-2), a difference of three CAG repeats distinguishes normal alleles (14 to 31 repeats) from pathogenic alleles (34 to 57 repeats). All sequenced pathogenic alleles have a pure CAG repeat structure, whereas interrupted repeats have been seen exclusively in normal alleles. The authors present two patients with sporadic SCA with an interrupted 34-CAG repeat allele, (CAG)24(CAA)(CAG)9, who showed a phenotype compatible with SCA-2. The interrupted allele coding for a 34 pure polyglutamine tract may cause the SCA phenotype.     

Very late-onset Friedreich ataxia despite large GAA triplet repeat expansions

BACKGROUND: Most patients with Friedreich ataxia (FRDA) have abnormal GAA triplet repeat expansions in both X25 genes. The size of the GAA expansion in the shorter of the 2 expanded alleles correlates significantly with parameters of clinical severity and is inversely related to the age at onset. OBJECTIVES: To describe the clinical and molecular genetic findings in a patient with very late-onset FRDA and to review the literature. PATIENT AND METHODS: A 58-year-old white woman with mild progressive gait disturbance of 15 years' duration whose examination revealed mild incoordination was analyzed for mutations in the X25 gene. A combination of long-range polymerase chain reaction and genomic Southern blot analyses were used to identify GAA expansions in intron 1 of the X25 gene. To uncover evidence of somatic variability in triplet repeat length, DNA isolated from several tissue samples was similarly analyzed. Single-strand conformational polymorphism analysis was used to screen for mutations spanning the entire coding sequence of frataxin and all intron-exon junctions of the X25 gene. RESULTS: DNA isolated from blood leukocytes revealed GAA triplet repeat expansions in both X25 genes, which were estimated to contain 835 and 1200 repeats. Similar expansions were detected in DNA isolated from lymphoblasts, fibroblasts, buccal cells, and sural nerve, with estimated mean (+/- SD) lengths of the shorter and longer expansions being 854 (+/-69) and 1283 (+/-72) triplets, respectively. A review of reported cases of late-onset Friedreich ataxia (25-39 years) and very late-onset Friedreich ataxia (> or =40 years) demonstrated that this is the first instance of a patient presenting with very late-onset FRDA despite carrying more than 800 GAA repeats in both expanded X25 alleles. CONCLUSIONS: This unique case of very late-onset FRDA highlights a limitation in our ability to accurately predict the phenotype in FRDA based solely on the size of the GAA expansion. Other genetic or environmental factors may significantly modify disease severity in FRDA.     

Huntington's disease-like and ataxia syndromes: Identification of a family with a de novo SCA17/TBP mutation

The autosomal dominant spinocerebellar ataxias, commonly referred to as SCAs, are clinically and genetically heterogeneous neurodegenerative disorders. Twenty-eight genetic subtypes have been identified, of which 7 are caused by expansion of a CAG trinucleotide repeat that encodes a polyglutamine tract in the respective proteins. SCA17 is caused by a CAG/CAA repeat expansion in the TATA box-binding protein-gene (TBP). In some cases the clinical phenotype of SCA17 overlaps that of Huntington's disease (HD), hence the use of the term Huntington's disease-like. We screened 89 patients with a Huntington's disease-like phenotype without the HD-gene mutation and 178 patients with genetically unclassified cerebellar ataxia for the mutation in TBP. A 33-year old woman presenting with an HD like phenotype with a de novo 54 CAG/CAA repeat expansion was identified. Her normal allele included 38 repeats. The patient's mother and father both carried normal range repeats, 38/38 and 33/39 respectively. Analysis of the repeat structures revealed that the expansion had occurred upon expansion of the longer paternal allele. We conclude that, however rare, SCA17 must be considered as a cause of Huntington's disease-like phenotypes and ataxia syndromes, also in isolated cases.     

Cardiac dysfunction exacerbated by endocrinopathies in friedreich ataxia: a case series

Friedreich ataxia is a neurodegenerative disease characterized by gait abnormalities, cardiomyopathy, and diabetes. Congestive heart failure was recently reported as the most frequent cause of Friedreich ataxia mortality. Cardiac dysfunction is suspected to result from a frataxin deficiency that leads to oxidative damage in cardiac tissues and possible metabolic syndrome characteristics. In this report, we describe 2 patient cases whose cardiac function worsened dramatically in the presence of underlying endocrinopathies. We report on one Friedreich ataxia teenager with previously undiagnosed diabetes that resulted in diabetic ketoacidosis and rapid progression to severe left ventricular dysfunction. We also describe a Friedreich ataxia teenager whose underlying Graves disease led to rapid worsening of known cardiomyopathy. Cardiac management and treatment for the endocrinopathies returned cardiac function to baseline. We conclude that screening for and awareness of underlying endocrinopathies in Friedreich ataxia may provide novel therapeutic targets for preventing Friedreich ataxia-associated cardiac dysfunction.     

Absence of aprataxin gene mutations in a Greek cohort with sporadic early onset ataxia and normal GAA triplets in frataxin gene

Phenotype of patients with the aprataxin gene mutation varies and according to previous studies, screening of aprataxin gene could be useful, once frataxin gene mutation is excluded in patients with normal GAA expansion in frataxin gene. In the present study, we sought to determine possible causative mutations in aprataxin gene (all exons and flanking intronic sequences) in 14 Greek patients with sporadic cerebellar ataxia all but one without GAA expansion in frataxin gene (1 patient was heterozygous). No detectable point mutation or deletion was found in the aprataxin gene of all the patients. Our results do not confirm the previous studies. This difference may be attributed to the different populations studied and possible different genetic background. It is still questionable whether the screening for aprataxin mutation in Greek patients’ Friedreich ataxia phenotype is of clinical importance; larger, multicenter studies are necessary to clarify this issue.     

Genotype‐phenotype correlations,dystonia and disease progression in spinocerebellar ataxia type 14

Background: Spinocerebellar ataxia type 14 is a rare form of autosomal dominant cerebellar ataxia caused by mutations in protein kinase Cγ gene. Clinically, it presents with a slowly progressive, mainly pure cerebellar ataxia. Methods: Using next generation sequencing, we screened 194 families with autosomal dominant cerebellar ataxia and normal polyglutamine repeats. In‐depth phenotyping was performed using validated clinical rating scales neuroimaging and electrophysiological investigations. Results: We identified 25 individuals from 13 families carrying pathogenic mutations in protein kinase Cγ gene. A total of 10 unique protein kinase Cγ gene mutations have been confirmed of which 5 are novel and 5 were previously described. Our data suggest that the age at onset is highly variable; disease course is slowly progressive and rarely associated with severe disability. However, one third of patients presented with a complex ataxia comprising severe focal and/or task‐induced dystonia, peripheral neuropathy, parkinsonism, myoclonus, and pyramidal syndrome. The most complex phenotype is related to a missense mutation in the catalytic domain in exon 11. Conclusion: We present one of the largest genetically confirmed spinocerebellar ataxia type 14 cohorts contributing novel variants and clinical characterisation. We show that although protein kinase Cγ gene mutations present mainly as slowly progressive pure ataxia, more than a third of cases had a complex phenotype. Overall, our case series extends the phenotype and suggests that protein kinase Cγ gene mutations should be considered in patients with slowly progressive autosomal dominant cerebellar ataxia, particularly when myoclonus, dystonia, or mild cognitive impairment are present in the absence of polyglutamine expansion. © 2018 The Authors. Movement Disorders published by Wiley Periodicals, Inc. on behalf of International Parkinson and Movement Disorder Society.     

Coexistence of tuberous sclerosis and Friedreich ataxia

Tuberous sclerosis (TS) is caused by point mutations in the TSC1 or TSC2 genes on chromosomes 9q33-34 or 16p13, respectively. Clinical manifestations can be quite variable but are primarily limited to cutaneous, neurologic, and cardiovascular abnormalities. Phenotypes range from neurologically devastated to those with silent lesions. A 34-year-old patient with genetically documented TSC1 developed progressive ataxia over a decade, without TS lesions to correlate with this finding. After evaluation of common causes including long-term antiepileptic regimens, DNA testing for hereditary ataxias was performed and revealed the presence of an additional mutation on chromosome 9. The patient was homozygous for the Friedreich ataxia (FA) mutation, with 500 and 700 GAA repeats in the FRDA gene on chromosome 9q13. There is no established relationship between these two disorders and the occurrence of two mutations on the same chromosome is probably coincidental but emphasizes the importance of searching for additional genetic causes when the phenotype does not fit with an established genetic diagnosis.     

Dentatorubral-pallidoluysian atrophy (DRPLA)

Dentatorubral-pallidoluysian atrophy (DRPLA) is an autosomal dominant neurodegenerative disorder caused by expansion of CAG repeats coding for a polyglutamine stretch. The prominent anticipation and broad spectrum in the clinical presentations of DRPLA have been demonstrated to be tightly correlated with the instability of CAG repeats in the DRPLA gene. Discovery of the causative gene for DRPLA has made it possible to investigate molecular mechanisms of neurodegeneration caused by expanded polyglutamine stretches. Recent investigations suggest that nuclear transport of mutant proteins containing expanded polyglutamine stretches and intranuclear aggregate formation play important roles in neuronal degeneration. We have recently demonstrated that the aggregate formation and apoptosis are partially suppressed by transglutaminase inhibitors, raising the possibility that transglutaminase is involved in the aggregate body. The results may open new prospects for developing therapeutic measures for the polyglutamine diseases.     

Childhood ataxia: clinical features, pathogenesis, key unanswered questions, and future directions

Childhood ataxia is characterized by impaired balance and coordination primarily because of cerebellar dysfunction. Friedreich ataxia, a form of childhood ataxia, is the most common multisystem autosomal recessive disease. Most of these patients are homozygous for the GAA repeat expansion located on the first intron of the frataxin gene on chromosome 9. Mutations in the frataxin gene impair mitochondrial function, increase reactive oxygen species, and trigger redistribution of iron in the mitochondria and cytosol. Targeted therapies for Friedreich ataxia are undergoing testing. In addition, a centralized database, patient registry, and natural history study have been launched to support clinical trials in Friedreich ataxia. The 2011 Neurobiology of Disease in Children symposium, held in conjunction with the 40th annual Child Neurology Society meeting, aimed to (1) describe clinical features surrounding Friedreich ataxia, including cardiomyopathy and genetics; (2) discuss recent advances in the understanding of the pathogenesis of Friedreich ataxia and developments of clinical trials; (3) review new investigations of characteristic symptoms; and (4) establish clinical and biochemical overlaps in neurodegenerative diseases and possible directions for future basic, translational, and clinical studies.     

FXN GAA repeat expansions in amyotrophic lateral sclerosis

Homozygous trinucleotide expansions in the frataxin (FXN) gene are responsible for Friedreich’s ataxia. However, heterozygous trinucleotide expansion in FXN results in a decreased expression of frataxin, a component of the mitochondrial respiratory chain, and is associated with a subclinical metabolic phenotype. In this study we thus investigated whether heterozygous FXN trinucleotide expansion is a risk factor or modifier for amyotrophic lateral sclerosis (ALS). Genomic DNA from familial and sporadic ALS patients and control individuals was tested for extended FXN trinucleotide repeats by polymerase chain reaction analysis. Screening of 652 ALS patients and 238 controls revealed a lower overall frequency of heterozygously extended FXN repeats than expected. A significant difference in the frequency of the FXN expansion or an associated modification of the disease phenotype in ALS was not detected. Our findings strengthen the view that different DNA repeat expansions are toxic on the basis of specific biological mechanisms.