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

Neural Precursor Cells: Interaction with Blood]brain barrier and Neuroprotective effect in an animal model of Cerebellar degeneration

Chintawar, Satyan

26 November 2009

Adult neural precursor cells (NPCs) are a heterogeneous population of mitotically active, self-renewing multipotent cells of both adult and developing CNS. They can be expanded in vitro in the presence of mitogens. The B05 transgenic SCA1 mice, expressing human ataxin-1 with an expanded polyglutamine tract in cerebellar Purkinje cells (PCs), recapitulate many pathological and behavioral characteristics of the neurodegenerative disease spinocerebellar ataxia type 1 (SCA1), including progressive ataxia and PC loss. We transplanted neural precursor cells (NPCs) derived from the subventricular zone of GFP-expressing adult mice into the cerebellar white matter of SCA1 mice when they showed absent (5 weeks), initial (13 weeks) and significant PC loss (24 weeks). A stereological count demonstrates that mice with significant cell loss exhibit highest survival of grafted NPCs and migration to the vicinity of PCs as compared to wt and younger grafted animals. These animals showed improved motor skills as compared to sham animals. Confocal analysis and profiling shows that many of implanted cells present in the cerebellar cortex have formed gap junctions with host PCs and express connexin43. Grafted cells did not adopt characteristics of PCs, but stereological and morphometric analysis of the cerebellar cortex revealed that grafted animals had more surviving PCs and a better preserved morphology of these cells than the control groups. Perforated patch clamp recordings revealed a normalization of the PC basal membrane potential, which was abnormally depolarized in sham-treated animals. No significant increase in levels of several neurotrophic factors was observed, suggesting, along with morphological observation, that the neuroprotective effect of grafted NPCs was mediated by direct contact with the host PCs. In this study, evidence for a neuroprotective effect came, in addition to motor behavior improvement, from stereological and electrophysiological analyses and suggest that timing of stem cell delivery is important to determine its therapeutic effect. In a brain stem cell niche, NSCs reside in a complex cellular and extracellular microenvironment comprising their own progeny, ependymal cells, numerous blood vessels and various extracellular matrix molecules. Recently, it was reported that blood vessel ECs-NSCs crosstalk plays an important role in tissue homeostasis. Bloodstream offers a natural delivery vehicle especially in case of diffuse neurodegenerative diseases which require widespread distribution of exogenous cells. As NSCs are confronted with blood-brain barrier endothelial cells (BBB-ECs) before they can enter into brain parenchyma, we investigated their interaction using primary cultures in an in vitro BBB model. We isolated human fetal neural precursor cells (hfNPCs) from aborted fetal brain tissues and expanded in vitro. We showed that in an in vitro model, human BBB endothelium induces the rapid differentiation of hfNPCs and allows them to cross the endothelial monolayer, with the differentiated progeny remaining in close contact with endothelial cells. These results are not reproduced when using a non-BBB endothelium and are partly dependent on the cytokine MCP1. Our data suggest that, in the presence of attractive signals released by a damaged brain, intravascularly administered NPCs can move across an intact BBB endothelium and differentiate in its vicinity. Overall, our findings have implications for the development of cellular therapies for cerebellar degenerative diseases and understanding of the brain stem cell niche.

spinocerebellar ataxia

transplantation

brain endothelium

stem cell niche

neuroprotection

cerebellum

neural precursor cells

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

Experimental and Computational Analysis of Polyglutamine-Mediated Cytotoxicity

Tang, Matthew

05 March 2012

Expanded polyglutamine proteins are known to be the causative agents of a number of human neurodegenerative diseases but the molecular basis of their cytoxicity is still poorly understood. Polyglutamine tracts may impede the activity of the proteasome, and evidence from single cell imaging suggests that the sequestration of polyglutamine proteins into inclusion bodies can reduce the proteasomal burden and promote cell survival, at least in the short term. The presence of misfolded protein also leads to activation of stress kinases such as p38MAPK, which can be cytotoxic. The relationships of these systems are not well understood. We have used fluorescent reporter systems imaged in living cells, and stochastic computer modeling to explore the relationships of expanded polyglutamine proteins, p38MAPK activation, generation of reactive oxygen species (ROS), proteasome inhibition, and inclusion body formation. In cells expressing a polyglutamine protein, inclusion body formation was preceded by proteasome inhibition but cytotoxicity was greatly reduced by administration of a p38MAPK inhibitor. Computer simulations suggested that without the generation of ROS, the proteasome inhibition and activation of p38MAPK would have significantly reduced toxicity. Our data suggest a vicious cycle of stress kinase activation and proteasome inhibition that is ultimately lethal to cells. There was close agreement between experimental data and the predictions of a stochastic computer model, supporting a central role for proteasome inhibition and p38MAPK activation in inclusion body formation and ROS-mediated cell death.

Polyglutamine

Huntington's disease

Spinocerebellar ataxia

Neurodegeneration

ubiquitin

proteasome

p38MAPK

Time lapse imaging

Novel Synchrotron-Based Analyses of Metal Pathology in Friedreichs Ataxia

Popescu, Bogdan Florin GH.

05 August 2009

Friedreichs ataxia (FRDA) is a progressive spinocerebellar ataxia (SCA) inherited as an autosomal recessive trait. The neurodegeneration, cardiomyopathy, diabetes mellitus and skeletal deformities characteristic to FRDA result from a deficiency in the mitochondrial protein frataxin. Frataxin chaperones iron to heme and iron-sulfur clusters and its deficiency causes mitochondrial iron accumulation and oxidative stress.<p> To address the effect of frataxin deficiency on mitochondrial iron chemistry, mitochondria were isolated from FRDA and control fibroblasts. X-ray absorption spectroscopy showed that ferrihydrite was the predominant form of iron in both. Near edge analysis showed that the ferrihydrite in the FRDA mitochondria resembled the highly organized ferrihydrite of ferritin. Western blotting confirmed that FRDA mitochondria had 3-fold more holoferritin containing stainable iron. I conclude that mitochondria from FRDA fibroblasts mineralize excess iron as ferrihydrite within mitochondrial ferritin.<p> To address how cellular iron dysregulation affected metal distribution in brain and spinal cord, a new synchrotron imaging technique, rapid-scanning x-ray fluorescence (RS-XRF) was employed and validated. Brain structures were readily identified by their unique metal content and distribution. This showed that RS-XRF could be used to reveal metal pathologies associated with diseases of metal metabolism such as FRDA. Since human FRDA tissues were not available for a detailed study, RS-XRF was employed to study the distribution of metals in normal cerebellum, a major site of FRDA-associated neurodegeneration, and to localize and quantify metals in the brain and spinal cord from a patient with a SCA of unknown aetiology. The motivation for this work is the prospect of future systematic studies on metal pathology in neurodegenerative diseases with direct application to FRDA. Novel findings arising from this work were the metal segmentation of the dentate nucleus, the high copper content of the olivary region and the different metal content of lesions at different stages of neurodegeneration. My results suggest that not only iron, but also copper and zinc may play a role in the physiopathology of neurodegeneration. Therefore, all three metals should be investigated in FRDA and other SCA of both known and unknown aetiologies to identify possible new therapeutic targets.

Copper

Iron

Zinc

Synchrotron

Brain

Metals

Neurodegeneration

Friedreich's ataxia

Experimental and Computational Analysis of Polyglutamine-Mediated Cytotoxicity

Tang, Matthew

05 March 2012

Expanded polyglutamine proteins are known to be the causative agents of a number of human neurodegenerative diseases but the molecular basis of their cytoxicity is still poorly understood. Polyglutamine tracts may impede the activity of the proteasome, and evidence from single cell imaging suggests that the sequestration of polyglutamine proteins into inclusion bodies can reduce the proteasomal burden and promote cell survival, at least in the short term. The presence of misfolded protein also leads to activation of stress kinases such as p38MAPK, which can be cytotoxic. The relationships of these systems are not well understood. We have used fluorescent reporter systems imaged in living cells, and stochastic computer modeling to explore the relationships of expanded polyglutamine proteins, p38MAPK activation, generation of reactive oxygen species (ROS), proteasome inhibition, and inclusion body formation. In cells expressing a polyglutamine protein, inclusion body formation was preceded by proteasome inhibition but cytotoxicity was greatly reduced by administration of a p38MAPK inhibitor. Computer simulations suggested that without the generation of ROS, the proteasome inhibition and activation of p38MAPK would have significantly reduced toxicity. Our data suggest a vicious cycle of stress kinase activation and proteasome inhibition that is ultimately lethal to cells. There was close agreement between experimental data and the predictions of a stochastic computer model, supporting a central role for proteasome inhibition and p38MAPK activation in inclusion body formation and ROS-mediated cell death.

Polyglutamine

Huntington's disease

Spinocerebellar ataxia

Neurodegeneration

ubiquitin

proteasome

p38MAPK

Time lapse imaging

Novel Synchrotron-Based Analyses of Metal Pathology in Friedreichs Ataxia

Popescu, Bogdan Florin GH.

05 August 2009

Friedreichs ataxia (FRDA) is a progressive spinocerebellar ataxia (SCA) inherited as an autosomal recessive trait. The neurodegeneration, cardiomyopathy, diabetes mellitus and skeletal deformities characteristic to FRDA result from a deficiency in the mitochondrial protein frataxin. Frataxin chaperones iron to heme and iron-sulfur clusters and its deficiency causes mitochondrial iron accumulation and oxidative stress.<p> To address the effect of frataxin deficiency on mitochondrial iron chemistry, mitochondria were isolated from FRDA and control fibroblasts. X-ray absorption spectroscopy showed that ferrihydrite was the predominant form of iron in both. Near edge analysis showed that the ferrihydrite in the FRDA mitochondria resembled the highly organized ferrihydrite of ferritin. Western blotting confirmed that FRDA mitochondria had 3-fold more holoferritin containing stainable iron. I conclude that mitochondria from FRDA fibroblasts mineralize excess iron as ferrihydrite within mitochondrial ferritin.<p> To address how cellular iron dysregulation affected metal distribution in brain and spinal cord, a new synchrotron imaging technique, rapid-scanning x-ray fluorescence (RS-XRF) was employed and validated. Brain structures were readily identified by their unique metal content and distribution. This showed that RS-XRF could be used to reveal metal pathologies associated with diseases of metal metabolism such as FRDA. Since human FRDA tissues were not available for a detailed study, RS-XRF was employed to study the distribution of metals in normal cerebellum, a major site of FRDA-associated neurodegeneration, and to localize and quantify metals in the brain and spinal cord from a patient with a SCA of unknown aetiology. The motivation for this work is the prospect of future systematic studies on metal pathology in neurodegenerative diseases with direct application to FRDA. Novel findings arising from this work were the metal segmentation of the dentate nucleus, the high copper content of the olivary region and the different metal content of lesions at different stages of neurodegeneration. My results suggest that not only iron, but also copper and zinc may play a role in the physiopathology of neurodegeneration. Therefore, all three metals should be investigated in FRDA and other SCA of both known and unknown aetiologies to identify possible new therapeutic targets.

Copper

Iron

Zinc

Synchrotron

Brain

Metals

Neurodegeneration

Friedreich's ataxia

Effects of the mismatch repair system on instability of trinucleotide repeats

Bourn, Rebecka Lynn.

January 2009

Thesis (Ph. D.)--University of Oklahoma. / Includes bibliographical references.

Genotype and phenotype characterisation of Friedreich ataxia mouse models and cells

Anjomani Virmouni, Sara

January 2013

Friedreich ataxia (FRDA) is an autosomal recessive neurodegenerative disorder, caused by a GAA repeat expansion mutation within intron 1 of the FXN gene, resulting in reduced level of frataxin protein. Normal individuals have 5 to 40 GAA repeat sequences, whereas affected individuals have approximately 70 to more than 1000 GAA triplets. Frataxin is a mitochondrial protein involved in iron-sulphur cluster and heme biosynthesis. The reduction in frataxin expression leads to oxidative stress, mitochondrial iron accumulation and consequential cell death with the primary sites of neurons of the dorsal root ganglia and the dentate nucleus of the cerebellum. FRDA, which is the most common inherited ataxia, affecting 1:50,000 Caucasians, is characterised by neurodegeneration, cardiomyopathy, diabetes mellitus and skeletal deformities. To investigate FRDA molecular disease mechanisms and therapy, several human FXN YAC transgenic mouse models have been established: Y47R, containing normal-sized (GAA)9 repeats; YG8R and YG22R, which initially contained expanded GAA repeats of 90-190 units and 190 units, respectively, but which have subsequently been bred to now contain expanded GAA repeats of 120-220 units and 170-260 units, respectively, and YG8sR (YG8R with a small GAA band) that was recently generated from YG8R breeding. To determine the FXN transgene copy number in the enhanced GAA repeat expansion-based FRDA mouse lines, a TaqMan qPCR assay was developed. The results demonstrated that the YG22R and Y47R lines had a single copy of the FXN transgene while the YG8R line had two copies. The YG8s lines showed less than one copy of the target gene, suggesting potential deletion of the FXN gene. Single integration sites of all transgenes were confirmed by fluorescence in situ hybridisation (FISH) analysis of metaphase and interphase chromosomes. However, in the YG8s line, at least 25% of the YG8s cells had no signals, while the remaining cells showed one signal corresponding to the transgenic FXN gene. In addition, the analysis of FXN exons in YG8s rescue mice by PCR confirmed the presence of all FXN exons in these lines, suggesting the incidence of somatic mosaicism in these lines. Extended functional analysis was carried out on these mice from 4 to 12 months of age. Coordination ability of YG8R, YG8sR and YG22R ‘FRDA-like’ mice, together with Y47R and C57BL6/J wild-type control mice, was assessed using accelerating rotarod analysis. The results indicated a progressive decrease in the motor coordination of YG8R, YG22R and YG8sR mice compared to Y47R or C57BL6/J controls. Locomotor activity was also assessed using an open field beam-breaker apparatus followed by four additional functional analyses including beam-walk, hang wire, grip strength and foot print tests. The results indicated significant functional deficits in the FRDA mouse models. Glucose and insulin tolerance tests were also conducted in the FRDA mouse models, indicating glucose intolerance and insulin hypersensitivity in the aforementioned lines. To investigate the correlation between the FRDA-like pathological phenotype and frataxin deficiency in the FRDA mouse models, frataxin mRNA and protein levels as well as somatic GAA repeat instability were examined. The results indicated that somatic GAA repeats increased in the cerebellum and brain of YG22R, YG8R and YG8sR mice, together with significantly reduced levels of FXN mRNA and protein in the liver of YG8R and YG22R compared to Y47R. However, YG8sR lines showed a significant decrease in FXN mRNA in all of the examined tissues compared to Y47R human FXN and C57BL6/J mouse Fxn mRNA. Protein expression levels were also considerably reduced in all the tissues of YG8sR mice compared to Y47R. Subsequently, the telomere length of human and mouse FRDA and control fibroblasts was assessed using qPCR and Q-FISH. The results indicated that the FRDA cells had chromosomes with relatively longer telomeric repeats in comparison to the controls. FRDA cells were screened for expression of telomerase activity using the TRAP assay and a quantitative assay for hTERT mRNA expression using TaqMan qRT-PCR. The results indicated that telomerase activity was not present in the FRDA cells. To investigate whether FRDA cells maintained their telomeres by ALT associated PML bodies (APBs), co-localisation of PML bodies with telomeres was assessed in these cells using combined immunofluorescence to PML and Q-FISH for telomere detection. The results demonstrated that the FRDA cells had significantly higher co-localised PML foci with telomeric DNA compared to the normal cells. Moreover, telomere sister chromatid exchange (T-SCE) frequencies were analysed in the human FRDA cell lines using chromosome orientation FISH (CO-FISH). The results indicated a significant increase in T-SCE levels of the FRDA cell lines relative to the controls. Furthermore, growth curve and population doubling analysis of the human FRDA and control fibroblasts was carried out. The results showed that the FRDA fibroblast cell cultures underwent growth arrest with higher cumulative population doubling compared to the controls. Though, further analysis of telomere length at different passage numbers revealed that the FRDA cells lost telomeres faster than the controls. Finally, the telomere dysfunction-induced foci (TIF) assay was performed to detect DNA damage in the human FRDA fibroblast cells using an antibody against DNA damage marker γ-H2AX and a synthetic PNA probe for telomeres. The frequency of γ-H2AX foci was significantly higher in the FRDA cells compared to the controls. Similarly, the FRDA cells had greater frequencies of TIFs in comparison to the controls, suggesting induced telomere dysfunction in the FRDA cells.

610

A Regulatory Role for ATM in Suppression of Mre11-Dependent DNA Degradation and Microhomology-Mediated End Joining

Rahal, Elias Adel

January 2009

ATM is the defective kinase in the neurodegenerative disorder ataxia telangiectasia. This kinase is associated with DNA double-strand break (DSB) repair and cell cycle control. Our laboratory previously demonstrated elevated levels of deletions and error-prone double-strand break repair via microhomology-mediated end joining (MMEJ) in ATM-deficient (A-T) extracts when compared to controls (wtATM+). To assess the involvement of enhanced nuclease activities in A-T extracts we studied the stability of DNA duplex substrates in A-T and control nuclear extracts under DSB repair conditions. We observed a marked shift in detection from full-length products to shorter products in A-T extracts. Addition of purified ATM to A-T nuclear extracts restored full-length product detection. This repression of degradation by ATM was dependent on its kinase activities. These results demonstrated a role for ATM in suppressing the degradation of DNA ends possibly through inhibiting nucleases implicated in MMEJ such as Mre11. Therefore, we assessed DNA end-stability in Mre11-depleted nuclear extracts and in extracts treated with the Mre11 nuclease inhibitor, Mirin. This resulted in decreased DNA degradation in both control and A-T extracts. Knockdown of Mre11 levels also led to an enhancement of DNA end-stability in nuclear extracts. Examining MMEJ levels by employing an in vivo reporter assay system revealed a decline in this pathway in Mre11-knockdown cells and in those treated with Mirin. These results signify a role for the Mre11 nuclease in MMEJ in mammalian cells and indicate a regulatory function for ATM in the control of error-prone DSB repair and preservation of DNA end-stability at a break.

Ataxia Telangiectasia

ATM

DNA repair

Microhomology-Mediated End Joining

Mre11

MRN