Expression and functional analysis of the SCA7 disease protein ataxin-7 / Studier av uttrycket och funktionen av SCA7 sjukdomsproteinet ataxin-7

Ström, Anna-Lena

January 2004

<p>Spinocerebellar ataxia type 7 (SCA7) is a neurodegenerative disease characterized by cerebellar ataxia and visual problems due to a progressive and selective loss of neurons within the cerebellum, brainstem and retina. The disease is caused by the expansion of a CAG repeat in the first coding exon of the SCA7 gene, resulting in an expanded polyglutamine domain in the N-terminal part of ataxin-7, a protein of unknown function.</p><p>To expand our knowledge of the ataxin-7 protein and the mechanism by which mutant ataxin-7 causes disease, we have studied the expression and function of both the normal and the mutated ataxin-7 protein. </p><p>Ataxin-7 expression was examination in brain and non-CNS tissues from SCA7 patients and age-matched controls. Expression was predominantly nuclear in neurons throughout the brain of both healthy and SCA7 individuals. We also observed aggregation of mutant ataxin-7 in the nuclei of neurons. No obvious difference in the expression level of ataxin-7 or the formation of aggregates could be observed between affected and non-affected brain regions in SCA7 patients. Based on these findings, we could conclude that the cell type specific neurodegeneration in SCA7 is not due to differences in expression levels or to the formation of ataxin-7 aggregates.</p><p>To widen our studies on ataxin-7 expression, we isolated and characterized the mouse SCA7 gene homolog. Cloning of the mouse SCA7 gene revealed two SCA7 mRNA isoforms that were highly homologous to their human counterparts. Immunohistochemical analysis also revealed a conserved expression pattern of ataxin-7 in adult mouse brain. In addition, ataxin-7 expression was observed during embryonic development in brain as well as in several non-neuronal tissues such as heart, liver and lung. </p><p>Besides SCA7, eight neurodegenerative disorders are known to be caused by expanded polyglutamine repeats, including SCA 1-3, 6 and 17, DRPLA, SBMA and Huntington’s disease. The polyglutamine disorders have many features in common and a common pathological disease mechanism involving transcriptional dysregulation has been proposed. To investigate the possible involvement of transcriptional dysregulation in SCA7 pathology, we analyzed the effects of both wild-type and expanded ataxin-7 on transcription driven by the co-activator CBP, the Purkinje cell-expressed nuclear receptor RORα1 or a basic TATA promoter. As previously shown for other polyglutamine disease proteins, expansion of the polyglutamine domain in ataxin-7 leads to reduced transcription. Surprisingly, strong repression of CBP-mediated, RORα1-mediated and basal transcription was also observed with wild-type ataxin-7, suggesting that the normal ataxin-7 protein may have a role in transcriptional regulation. </p>

Molecular biology

Polyglutamine disease

CAG repeat

Spinocerebellar ataxia type 7

Molekylärbiologi

Molecular biology

Molekylärbiologi

Expression and functional analysis of the SCA7 disease protein ataxin-7 / Studier av uttrycket och funktionen av SCA7 sjukdomsproteinet ataxin-7

Ström, Anna-Lena

January 2004

Spinocerebellar ataxia type 7 (SCA7) is a neurodegenerative disease characterized by cerebellar ataxia and visual problems due to a progressive and selective loss of neurons within the cerebellum, brainstem and retina. The disease is caused by the expansion of a CAG repeat in the first coding exon of the SCA7 gene, resulting in an expanded polyglutamine domain in the N-terminal part of ataxin-7, a protein of unknown function. To expand our knowledge of the ataxin-7 protein and the mechanism by which mutant ataxin-7 causes disease, we have studied the expression and function of both the normal and the mutated ataxin-7 protein. Ataxin-7 expression was examination in brain and non-CNS tissues from SCA7 patients and age-matched controls. Expression was predominantly nuclear in neurons throughout the brain of both healthy and SCA7 individuals. We also observed aggregation of mutant ataxin-7 in the nuclei of neurons. No obvious difference in the expression level of ataxin-7 or the formation of aggregates could be observed between affected and non-affected brain regions in SCA7 patients. Based on these findings, we could conclude that the cell type specific neurodegeneration in SCA7 is not due to differences in expression levels or to the formation of ataxin-7 aggregates. To widen our studies on ataxin-7 expression, we isolated and characterized the mouse SCA7 gene homolog. Cloning of the mouse SCA7 gene revealed two SCA7 mRNA isoforms that were highly homologous to their human counterparts. Immunohistochemical analysis also revealed a conserved expression pattern of ataxin-7 in adult mouse brain. In addition, ataxin-7 expression was observed during embryonic development in brain as well as in several non-neuronal tissues such as heart, liver and lung. Besides SCA7, eight neurodegenerative disorders are known to be caused by expanded polyglutamine repeats, including SCA 1-3, 6 and 17, DRPLA, SBMA and Huntington’s disease. The polyglutamine disorders have many features in common and a common pathological disease mechanism involving transcriptional dysregulation has been proposed. To investigate the possible involvement of transcriptional dysregulation in SCA7 pathology, we analyzed the effects of both wild-type and expanded ataxin-7 on transcription driven by the co-activator CBP, the Purkinje cell-expressed nuclear receptor RORα1 or a basic TATA promoter. As previously shown for other polyglutamine disease proteins, expansion of the polyglutamine domain in ataxin-7 leads to reduced transcription. Surprisingly, strong repression of CBP-mediated, RORα1-mediated and basal transcription was also observed with wild-type ataxin-7, suggesting that the normal ataxin-7 protein may have a role in transcriptional regulation.

Molecular biology

Polyglutamine disease

CAG repeat

Spinocerebellar ataxia type 7

Molekylärbiologi

Molecular biology

Molekylärbiologi

CAG Repeat Length and Suicidality in Huntington's disease

Kutz, Christen

01 January 2015

Abstract: The purpose of this study was to determine if a correlation exists between suicide and CAG repeat length in Huntington’s disease. Methodology: A case-control study using the COHORT Study de-identified database was conducted. Responses were collected from 163 participants. Depression, substance abuse history and use of benzodiazepines were covariates. Responses to the UHDRS behavioral section pertaining to the frequency and severity of suicidal ideation (“feels life is not worth living”, “has suicidal thoughts”) were analyzed. Results: Despite taking depression, benzodiazepine use, and history of substance abuse into account, there was a predictive relationship between CAG repeat length and frequency of suicidal ideation (p = .010). When the effect of depression was taken into account, there was no significant relationship between CAG repeat length and the severity of suicidal ideation. Recommendations: The findings from this quantitative analysis supported using CAG length in a clinician’s risk factor assessment to determine the frequency of suicidality.

Health and environmental sciences

CAG repeat length

Huntington's disease

Suicidal ideation

Suicidality

Suicide

Medicine and Health Sciences

Genetic and Molecular analysis of the Spinocerebellar ataxia type 7 (SCA7) disease gene

Jonasson, Jenni

January 2000

Spinocerebellar ataxia type 7 (SCA7) is a hereditary neurodegenerative disorder affecting the cerebellum, pons and retina. SCA7 patients present with gait ataxia and visual impairment as the main symptoms. Anticipation, commonly observed in SCA7 families, is a phenomenon where an earlier age at onset and a more severe progression of disease is seen in successive generations. In order to identify the gene responsible for SCA7, we performed linkage analysis on a Swedish SCA7 kindred. Evidence for linkage of the SCA7 disease locus to a 32 cM region on chromosome 3p12-21.1, between markers D3S1547 and D3S1274, was established. A number of neurodegenerative disorders associated with anticipation are caused by expanded (CAG)n repeats in their respective disease genes. In order to isolate the SCA7 disease gene we, therefore, screened a human infant brain stem cDNA library for CAG repeat containing clones, mapping to chromosome 3. Four candidate clones were isolated and analysed, but could all be excluded as the SCA7 disease gene. In 1997, the SCA7 disease gene was identified and, as expected, shown to harbour a CAG repeat, expanded in SCA7 patients. Analysis of the SCA7 CAG repeat region in Swedish SCA7 patients demonstrated that CAG repeat size was negatively correlated to age at onset of disease. Furthermore, patients with larger repeats presented with visual impairment, whereas patients with smaller repeats presented with ataxia as the initial symptom. SCA7 is the most common autosomal dominant cerebellar ataxia in Sweden and Finland, but rare in other populations. In order to investigate if the relatively high frequency of SCA7 in these countries is the result of a founder effect in the region, a haplotype analysis was performed on all SCA7 families available. All 7 families shared a common haplotype of at least 1.9 cM surrounding the SCA7 locus. In addition, strong linkage disequilibrium was demonstrated for marker D3S1287 closely linked to the SCA7 gene, suggesting a founder effect for the SCA7 mutation in Sweden and Finland. The function of the SCA7 protein, ataxin-7, is not known and it does not show significant homologies to any previously known proteins. In order to gain insight into the function of ataxin-7 we analysed the expression of ataxin-7 in brain and peripheral tissue from SCA7 patients and controls. In brain, expression was found to be mainly neuronal with a nuclear subcellular localisation. Ataxin-7 expression was found throughout the CNS, not restricted to sites of pathology. We also confirmed previously reported findings of neuronal intranuclear inclusions (NIls) in the brains of SCA7 patients. Based on our findings, we conclude that the cell type specific neurodegeneration in SCA7 is not due to differences in expression pattern in affected and non-affected tissue or the distribution pattern of aggregated protein.

Spinocerebellar ataxia

human genetics

linkage analysis

anticipation

CAG repeat expansion

founder effect

protein expression

ATXN7

Medical genetics

Medicinsk genetik

Correlation Between Weight Loss and Select Motor Scores From a Chart Review of Huntington's Disease Patients

Yoder, Jennifer M.

25 June 2012

No description available.

Genetics

Nutrition

Huntington&8217