Polyglutamine Tract In Ataxin-1 Research Articles

Dysregulation of alternative splicing in spinocerebellar ataxia type 1.

Spinocerebellar ataxia type 1 is caused by an expansion of the polyglutamine tract in ATAXIN-1. Ataxin-1 is broadly expressed throughout the brain and is involved in regulating gene expression. However, it is not yet known if mutant ataxin-1 can impact the regulation of alternative splicing events. We performed RNA sequencing in mouse models of spinocerebellar ataxia type 1 and identified that mutant ataxin-1 expression abnormally leads to diverse splicing events in the mouse cerebellum of spinocerebellar ataxia type 1. We found that the diverse splicing events occurred in a predominantly cell autonomous manner. A majority of the transcripts with misregulated alternative splicing events were previously unknown, thus allowing us to identify overall new biological pathways that are distinctive to those affected by differential gene expression in spinocerebellar ataxia type 1. We also provide evidence that the splicing factor Rbfox1 mediates the effect of mutant ataxin-1 on misregulated alternative splicing and that genetic manipulation of Rbfox1 expression modifies neurodegenerative phenotypes in a Drosophila model of spinocerebellar ataxia type 1 in vivo. Together, this study provides novel molecular mechanistic insight into the pathogenesis of spinocerebellar ataxia type 1 and identifies potential therapeutic strategies for spinocerebellar ataxia type 1.

Identification of the ataxin-1 interaction network and its impact on spinocerebellar ataxia type 1

BackgroundSpinocerebellar ataxia type 1 (SCA1) is a neurodegenerative disease caused by a polyglutamine expansion in the ataxin-1 protein. The pathogenic mechanism resulting in SCA1 is still unclear. Protein–protein interactions affect the function and stability of ataxin-1.MethodsWild-type and mutant ataxin-1 were expressed in HEK-293T cells. The levels of expression were assessed using real-time polymerase chain reaction (PCR) and Western blots. Co-immunoprecipitation was done in HEK-293T cells expressing exogenous wild-type and mutant ataxin-1 using anti-Flag antibody following by tandem affinity purification in order to study protein–protein interactions. The candidate interacting proteins were validated by immunoprecipitation. Chromatin immunoprecipitation and high-throughput sequencing and RNA immunoprecipitation and high-throughput sequencing were performed using HEK-293T cells expressing wild-type or mutant ataxin-1.ResultsIn this study using HEK-293T cells, we found that wild-type ataxin-1 interacted with MCM2, GNAS, and TMEM206, while mutant ataxin-1 lost its interaction with MCM2, GNAS, and TMEM206. Two ataxin-1 binding targets containing the core GGAG or AAAT were identified in HEK-293T cells using ChIP-seq. Gene Ontology analysis of the top ataxin-1 binding genes identified SLC6A15, NTF3, KCNC3, and DNAJC6 as functional genes in neurons in vitro. Ataxin-1 also was identified as an RNA-binding protein in HEK-293T cells using RIP-seq, but the polyglutamine expansion in the ataxin-1 had no direct effects on the RNA-binding activity of ataxin-1.ConclusionsAn expanded polyglutamine tract in ataxin-1 might interfere with protein–protein or protein–DNA interactions but had little effect on protein–RNA interactions. This study suggested that the dysfunction of protein–protein or protein–DNA interactions is involved in the pathogenesis of SCA1.

PAK1 regulates ATXN1 levels providing an opportunity to modify its toxicity in spinocerebellar ataxia type 1.

Spinocerebellar ataxia type 1 (SCA1) is caused by the expansion of a trinucleotide repeat that encodes a polyglutamine tract in ataxin-1 (ATXN1). The expanded polyglutamine in ATXN1 increases the protein's stability and results in its accumulation and toxicity. Previous studies have demonstrated that decreasing ATXN1 levels ameliorates SCA1 phenotypes and pathology in mouse models. We rationalized that reducing ATXN1 levels through pharmacological inhibition of its modulators could provide a therapeutic avenue for SCA1. Here, through a forward genetic screen in Drosophila we identified, p21-activated kinase 3 (Pak3) as a modulator of ATXN1 levels. Loss-of-function of fly Pak3 or Pak1, whose mammalian homologs belong to Group I of PAK proteins, reduces ATXN1 levels, and accordingly, improves disease pathology in a Drosophila model of SCA1. Knockdown of PAK1 potently reduces ATXN1 levels in mammalian cells independent of the well-characterized S776 phosphorylation site (known to stabilize ATXN1) thus revealing a novel molecular pathway that regulates ATXN1 levels. Furthermore, pharmacological inhibition of PAKs decreases ATXN1 levels in a mouse model of SCA1. To explore the potential of using PAK inhibitors in combination therapy, we combined the pharmacological inhibition of PAK with MSK1, a previously identified modulator of ATXN1, and examined their effects on ATXN1 levels. We found that inhibition of both pathways results in an additive decrease in ATXN1 levels. Together, this study identifies PAK signaling as a distinct molecular pathway that regulates ATXN1 levels and presents a promising opportunity to pursue for developing potential therapeutics for SCA1.

RNAi or overexpression: Alternative therapies for Spinocerebellar Ataxia Type 1

Spinocerebellar Ataxia Type 1 (SCA1) is an autosomal dominant late onset neurodegenerative disease caused by an expanded polyglutamine tract in ataxin-1. Here, we compared the protective effects of overexpressing ataxin-1-like using recombinant AAVs, or reducing expression of mutant ataxin-1 using virally delivered RNA interference (RNAi), in a transgenic mouse model of SCA1. For the latter, we used an artificial microRNA (miR) design that optimizes potency, efficacy and safety to suppress ataxin-1 expression (miS1). Delivery of either ataxin-1-like or miS1 viral vectors to SCA1 mice cerebella resulted in widespread cerebellar Purkinje cell transduction and improved behavioral and histological phenotypes. Our data indicate the utility of either approach as a possible therapy for SCA1 patients.

14-3-3 Binding to Ataxin-1(ATXN1) Regulates Its Dephosphorylation at Ser-776 and Transport to the Nucleus

Spinocerebellar ataxia type 1 (SCA1) is a lethal neurodegenerative disorder caused by expansion of a polyglutamine tract in ATXN1. A prominent site of pathology in SCA1 is cerebellar Purkinje neurons where mutant ATXN1 must enter the nucleus to cause disease. In SCA1, phosphorylation of ATXN1 at Ser-776 modulates disease. Interestingly, Ser-776 is located within a region of ATXN1 that harbors several functional motifs including binding sites for 14-3-3, and splicing factors RBM17 and U2AF65. The interaction of ATXN1 with these proteins is thought to be regulated by the phosphorylation status of Ser-776. In addition, Ser-776 is adjacent to the NLS in ATXN1. Although pS776-ATXN1 is enriched in nuclear extracts of cerebellar cells, the vast majority of 14-3-3 is in the cytoplasmic fraction. We found that dephosphorylation of cytoplasmic pS776-ATXN1 is blocked by virtue of it being in a complex with 14-3-3. In addition, data suggest that binding of 14-3-3 to cytoplasmic ATXN1 impeded its transport to the nucleus, suggesting that 14-3-3 must disassociate from ATXN1 for transport of ATXN1 to the nucleus. Consistent with this hypothesis is the observation that once in the nucleus pS776 is able to be dephosphorylated. Evidence is presented that PP2A is the pS776-ATXN1 phosphatase in the mammalian cerebellum. In the nucleus, we propose that dephosphorylation of pS776-ATXN1 by PP2A regulates the interaction of ATXN1 with the splicing factors RBM17 and U2AF65.

Regional rescue of spinocerebellar ataxia type 1 phenotypes by 14-3-3 ε haploinsufficiency in mice underscores complex pathogenicity in neurodegeneration

Spinocerebellar ataxia type 1 (SCA1) is a neurodegenerative disease caused by the expansion of a CAG repeat encoding a polyglutamine tract in Ataxin-1 (ATXN1). Both WT and mutant ATXN1 interact with 14-3-3 proteins, and 14-3-3 overexpression stabilizes ATXN1 levels in cells and increases ATXN1 toxicity in flies. To determine whether reducing 14-3-3 levels might mitigate SCA1 pathogenesis, we bred Sca1(154Q/+) mice to mice lacking one allele of 14-3-3ε. 14-3-3ε haploinsufficiency rescued cerebellar pathology and motor phenotypes but, surprisingly, not weight loss, respiratory dysfunction, or premature lethality. Biochemical studies revealed that reducing 14-3-3ε levels exerted different effects in two brain regions especially vulnerable in SCA1: Although diminishing levels of both WT and mutant ATXN1 in the cerebellum, 14-3-3ε haploinsufficiency did not alter ATXN1 levels in the brainstem. Furthermore, 14-3-3ε haploinsufficiency decreased the incorporation of expanded ATXN1 into its large toxic complexes in the cerebellum but not in the brainstem, and the distribution of ATXN1's small and large native complexes differed significantly between the two regions. These data suggest that distinct pathogenic mechanisms operate in different vulnerable brain regions, adding another level of complexity to SCA1 pathogenesis.

SUMO-1 interacts with mutant ataxin-1 and colocalizes to its aggregates in Purkinje cells of SCA1 transgenic mice

Spinocerebellar ataxia type 1 (SCA1) is one of several progressive neurodegenerative diseases caused by the expanded polyglutamine tract in ataxin-1, the SCA1 gene product. In SCA1 patients and transgenic mice, the affected neuronal cells contain a large ubiquitin-positive aggregate which is derived from the mutant ataxin-1. Small ubiquitin-like modifier-1 (SUMO-1) is one of the most intriguing ubiquitin-like modifiers being conjugated to target proteins and modulating a number of cellular pathways. Recent findings that the aggregates from several neurodegenerative diseases are SUMO-1-positive prompted us to examine the implication of SUMO-1 in SCA1 pathogenesis. In our yeast two-hybrid experiments using mutant ataxin-1 as bait, we identified a SUMO-1 protein that directly binds to ataxin-1 protein. Interestingly, we found that most of the mutant ataxin-1-derived aggregates were SUMO-1-positive both in Purkinje cells of SCA1 transgenic mice and in HeLa cells, but not wild-type ataxin-1 in HeLa cells. In addition, the aggregates in Purkinje cells of SCA1 transgenic mice were positive against both anti-SUMO-1 and anti-ubiquitin antibodies. These results show that the SUMO-1 protein interacts with mutant ataxin-1 and colocalizes with its aggregates which suggests the involvement of the SUMO-1 system in the pathogenesis of SCA1 disease.

Partial Loss of Ataxin-1 Function Contributes to Transcriptional Dysregulation in Spinocerebellar Ataxia Type 1 Pathogenesis

Spinocerebellar ataxia type 1 (SCA1) is a dominantly inherited neurodegenerative disease caused by expansion of a CAG repeat that encodes a polyglutamine tract in ATAXIN1 (ATXN1). Molecular and genetic data indicate that SCA1 is mainly caused by a gain-of-function mechanism. However, deletion of wild-type ATXN1 enhances SCA1 pathogenesis, whereas increased levels of an evolutionarily conserved paralog of ATXN1, Ataxin 1-Like, ameliorate it. These data suggest that a partial loss of ATXN1 function contributes to SCA1. To address this possibility, we set out to determine if the SCA1 disease model (Atxn1154Q/+ mice) and the loss of Atxn1 function model (Atxn1−/− mice) share molecular changes that could potentially contribute to SCA1 pathogenesis. To identify transcriptional changes that might result from loss of function of ATXN1 in SCA1, we performed gene expression microarray studies on cerebellar RNA from Atxn1−/− and Atxn1154Q/+ cerebella and uncovered shared gene expression changes. We further show that mild overexpression of Ataxin-1-Like rescues several of the molecular and behavioral defects in Atxn1 −/− mice. These results support a model in which Ataxin 1-Like overexpression represses SCA1 pathogenesis by compensating for a partial loss of function of Atxn1. Altogether, these data provide evidence that partial loss of Atxn1 function contributes to SCA1 pathogenesis and raise the possibility that loss-of-function mechanisms contribute to other dominantly inherited neurodegenerative diseases.

Molecular pathogenesis of spinocerebellar ataxia type 1 disease.

Spinocerebellar ataxia type 1 (SCA1) is an autosomal-dominant neurodegenerative disorder characterized by ataxia and progressive motor deterioration. SCA1 is associated with an elongated polyglutamine tract in ataxin-1, the SCA1 gene product. As summarized in this review, recent studies have clarified the molecular mechanisms of SCA1 pathogenesis and provided direction for future therapeutic approaches. The nucleus is the subcellular site where misfolded mutant ataxin-1 acts to cause SCA1 disease in the cerebellum. The role of these nuclear aggregates is the subject of intensive study. Additional proteins have been identified, whose conformational alterations occurring through interactions with the polyglutamine tract itself or non-polyglutamine regions in ataxin-1 are the cause of SCA-1 cytotoxicity. Therapeutic hope comes from the observations concerning the reduction of nuclear aggregation and alleviation of the pathogenic phenotype by the application of potent inhibitors and RNA interference.

Characterization of the Zebrafish atxn1/axh Gene Family

In mammals, ataxin-1 (ATXN1) is a member of a family of proteins in which each member contains an AXH domain. Expansion of the polyglutamine tract in ATXN1 causes the neurodegenerative disease, spinocerebellar ataxia type 1 (SCA1) with prominent cerebellar pathology. Toward a further characterization of the genetic diversification of the ATXN1/AXH gene family, we identified and characterized members of this gene family in zebrafish, a lower vertebrate with a cerebellum. The zebrafish genome encodes two ATXN1 homologs, atxn1a and atxn1b, and one ATXN1L homolog, atxn1l. Key biochemical features of the human ATXN1 protein not seen in the invertebrate homologs (a nuclear localization sequence and a site of phosphorylation at serine 776) are conserved in the zebrafish homologs, and all three zebrafish Atxn1/Axh proteins behave similarly to their human counterparts in tissue-culture cells. Importantly, each of the three homologs is expressed in the zebrafish cerebellum, which in humans, is a prominent site of SCA1 pathogenesis. In addition, atxn1a and atxn1b are expressed in the developing zebrafish cerebellum. These data show that in zebrafish, a lower vertebrate, the complexity of the atxn1/axh gene family is more similar to higher vertebrates than invertebrates with a simple central nervous system and suggests a relationship between the diversification of the ATXN1/AXH gene family and the development of a complex central nervous system, including a cerebellum.

The ubiquitin-conjugating enzyme UbcH6 regulates the transcriptional repression activity of the SCA1 gene product ataxin-1

Spinocerebellar ataxia type 1 (SCA1) is an autosomal-dominant neurodegenerative disorder characterized by ataxia and progressive motor deterioration. SCA1 is caused by expansion of the polyglutamine tract in the SCA1 gene product, ataxin-1. We previously reported that the E2 ubiquitin-conjugating enzyme UbcH6 interacts with and ubiquitinates the ataxin-1 proteins as an E2-substrate cognate pair in the ubiquitin-proteasome system. In the present study, we further investigated whether the function of ataxin-1 is associated with UbcH6 and found that UbcH6 regulates the transcriptional repression activity of ataxin-1. The overexpression of UbcH6 reduced the transcriptional repression activity of ataxin-1. Interestingly, ataxin-1(30Q) was more affected by the presence of UbcH6 than ataxin-1(82Q), implying that the length of the polyglutamine tract in ataxin-1 might be involved in determining the stability of ataxin-1. The half-life of ataxin-1(82Q) was longer than that of ataxin-1(30Q) in the presence of UbcH6. shRNAs targeting UbcH6 enhanced the transcriptional repression activity of ataxin-1. In addition, the overexpression of UbcH6 reduced the formation of ataxin-1 aggregates. Our studies demonstrate that UbcH6 modulates the transcriptional repression activity of ataxin-1 by modulating the degradation of ataxin-1, suggesting that UbcH6 may have some therapeutic potential in the treatment of SCA1.

717. RNAi Therapy for Dominant Neurodegenerative Diseases

In this study we investigated gene silencing by RNA interference (RNAi) as a potential therapy for Spinocerebellar ataxia type 1 (SCA1), a dominant neurodegenerative disease caused by expansion of a polyglutamine tract in ataxin-1. Therapies for SCA1 do not exist, and studies in mouse models of other polyglutamine repeat diseases support that silencing of the disease allele can improve disease manifestations. Short hairpin RNAs (shRNAs) specific to SCA1 were screened for effective silencing against a mutant human ataxin (Q = 82) in vitro prior to testing in a transgenic mouse model of SCA1. SCA1 trangenic mice express a mutant human ataxin-1 (Q = 82) from the Purkinje cell specific promoter, and recapitulate many aspects of human SCA1, including progressive ataxia, shrinkage of the molecular layer, Purkinje cell degeneration and nuclear inclusion formation. AAV1 vectors expressing the most effective shRNA and an hrGFP reporter (AAVshSCA1.hrGFP) were injected into the cerebellar lobules of 7-week old SCA1 or wildtype mice. Viruses expressing an irrelevant hairpin (AAVshlacZ.hrGFP), or saline, were included as hairpin and injection controls. Rotarod tests of motor coordination were done 2-week prior and every two weeks following injections, until sacrifice at 16 weeks of age. Beginning at 9 weeks of age and continuing until sacrifice, SCA1 mice treated with shSCA1-expressing viruses showed significantly improved performance on the rotarod relative to saline- or shlacZ-treated SCA1 mice. There was no effect of the therapy on the performance of wildtype mice. The efficiency of transduction, quantified by hrGFP expression, ranged from ~ 5–10% of all Purkinje cells. We took advantage of hrGFP reporter expression to directly compare transduced and untransduced lobules for ataxin-1 nuclear inclusions, Purkinje cell morphology, and the width of the cerebellar molecular layer. In shSCA-treated SCA1 mice, Purkinje cell dendritic arbors remained robust, and transduced lobules (hrGFP+) had molecular layer widths indistinguishable from those of wild-type mice. Moreover, ataxin-1 inclusions were notably absent from all hrGFP-positive Purkinje cells in shSCA1-treated SCA1 mice (0 inclusions in 400 cells). In contrast, 49% of Purkinje cells from shlacZ-treated mice had inclusions, similar to untreated 16-wk old SCA1 mice. These data provide the first in vivo demonstration of efficacy of RNAi for dominant neurodegenerative disease therapy.

P80 coilin, a coiled body-specific protein, interacts with ataxin-1, the SCA1 gene product

Spinocerebellar ataxia type 1 (SCA1) is an autosomal-dominant neurodegenerative disorder characterized by ataxia and progressive motor deterioration. SCA1 is associated with an elongated polyglutamine tract in ataxin-1, the SCA1 gene product. Using the yeast two-hybrid system and co-immunoprecipitation experiments, we have found that p80 coilin, coiled body-specific protein, binds to ataxin-1. In further experiments with deletion mutants, we found that the C-terminal regions of ataxin-1 and p80 coilin were essential for this interaction. In HeLa cells that have been co-transfected with ataxin-1 and p80 coilin, the p80 coilin protein co-localizes with ataxin-1 aggregates in the nucleoplasm. However, immunohistochemical analysis and immunofluorescence assays showed that mutant ataxin-1 aggregates do not redistribute p80 coilin's dot-like structures in the Purkinje cells of SCA1 transgenic mice. This feature of the interaction between ataxin-1 and p80 coilin suggests that p80 coilin might be implicated in altering the function of ataxin-1.

USP7, a Ubiquitin-Specific Protease, Interacts with Ataxin-1, the SCA1 Gene Product

Spinocerebellar ataxia type 1 (SCA1) is an autosomal-dominant neurodegenerative disorder characterized by ataxia and progressive motor deterioration. SCA1 has been known to associate with elongated polyglutamine tract in ataxin-1, the SCA1 gene product. Using the yeast two-hybrid system, we have found that USP7, a ubiquitin-specific protease, binds to ataxin-1. Further experiments with deletion mutants indicated that the C-terminal region of ataxin-1 was essential for the interaction. Liquid β-galactosidase assay and coimmunoprecipitation experiments revealed that the strength of the interaction between USP7 and ataxin-1 is influenced by the length of the polyglutamine tract in the ataxin-1; weaker interaction was observed in mutant ataxin-1 with longer polyglutamine tract and USP7 was not recruited to the mutant ataxin-1 aggregates in the Purkinje cells of SCA1 transgenic mice. Our results suggest that altered function of the ubiquitin system can be involved in the pathogenesis of spinocerebellar ataxia type 1.

Chaperone suppression of aggregation and altered subcellular proteasome localization imply protein misfolding in SCA1.

Spinocerebellar ataxia type 1 (SCA1) is an autosomal dominant neurodegenerative disorder caused by expansion of a polyglutamine tract in ataxin-1. In affected neurons of SCA1 patients and transgenic mice, mutant ataxin-1 accumulates in a single, ubiquitin-positive nuclear inclusion. In this study, we show that these inclusions stain positively for the 20S proteasome and the molecular chaperone HDJ-2/HSDJ. Similarly, HeLa cells transfected with mutant ataxin-1 develop nuclear aggregates which colocalize with the 20S proteasome and endogenous HDJ-2/HSDJ. Overexpression of wild-type HDJ-2/HSDJ in HeLa cells decreases the frequency of ataxin-1 aggregation. These data suggest that protein misfolding is responsible for the nuclear aggregates seen in SCA1, and that overexpression of a DnaJ chaperone promotes the recognition of a misfolded polyglutamine repeat protein, allowing its refolding and/or ubiquitin-dependent degradation.