The KRAB-containing zinc-finger transcriptional regulator ZBRK1 activates SCA2 gene transcription through direct interaction with its gene product, ataxin-2

Hallen, Linda; Klein, H.; Stoschek, Carola; Wehrmeyer, Silke; Nonhoff, Ute; Ralser, Markus; Wilde, Jeannine; Röhr, Christina; Schweiger, Michal-Ruth; Zatloukal, Kurt; Vingron, Martin; Lehrach, Hans; Konthur, Zoltán; Krobitsch, Sylvia

doi:10.1093/hmg/ddq436

Cited by 36 publications

(31 citation statements)

References 37 publications

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“…The CpG sites situated close to the transcription start are predominantly targeted by methylation suggesting that these regions might be important in epigenetic control of ATXN2 expression. Recent findings on transcriptional activation of atxn2 gene by ATXN2 protein (through an interaction with ZBRK1) (Hallen et al 2011) and our data showing hypermethylation in this gene suggest that the self-activating function of ATXN2 may be modified by the methylation state of its own promoter and may influence the feedback loop for ATXN2 regulation during cellular stress (Hallen et al 2011). In this light, the reduced or enhanced ATXN2 expression by hyper-or hypomethylation leading to reduced ATXN2 levels or increased cellular burden of expanded polyQ protein, respectively, may lead to an maladaptive stress response.…”

Section: Discussionmentioning

confidence: 99%

“…The differential methylation of atxn2 might also have modifying effects in other pathological conditions connected with C27 CAG repeat expansions in atxn2, such as ALS (Elden et al 2010;Lee et al 2011), neuropsychiatry disorders (Rottnek et al 2008;Goyal et al 2010), and cancer (Wiedemeyer et al 2003;Hallen et al 2011) or as the causative mutant gene in autosomal dominant parkinsonism (Charles et al 2007;Payami et al 2003). An intuitive relationship between the methylation pattern in atxn2 promoter and phenotypes resulting from CAG expansions in the atxn2 locus would be based on the balance of the methylation pattern and consecutive expression levels of ATXN2 at given condition and cell types.…”

Section: Discussionmentioning

confidence: 99%

“…Recently, an interaction between the KRAB-containing zinc-finger transcriptional regulator (ZBRK1) and ATXN2 was reported. The ZBRK1/ATXN2 complex activates the atxn2 transcription, where ATXN2 acts as co-activator of ZBRK1 (Hallen et al 2011). Other modulating mechanism regulating the atxn2 expression was not found highlighting that regulation of ATXN2 expression is poorly understood.…”

Section: Introductionmentioning

confidence: 95%

“…Gaining insights in this mechanism is crucial, because pathogenic CAG expansions in the atxn2 gene are directly and/or indirectly linked to the development of devastating neurodegenerative disorders such as SCA2, Parkinson disease, ALS and frontotemporal lobar degeneration (Neumann et al 2006;Socal et al 2008;Elden et al 2010). In addition, the expression levels of ATXN2 have been found to be important in the development of some malignancies (Wiedemeyer et al 2003;Hallen et al 2011), suggesting a tumor suppressing activity for this gene. Cellular concentrations of ATXN2 were reported to be important in mRNA processing and translation under stress conditions through interaction with DEAD/H-box RNA helicase DDX6 and poly (A)-binding protein and consequent interference with the assembly of cellular P-body structures and stress granules (Nonhoff et al 2007).…”

Section: Introductionmentioning

confidence: 99%

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Epigenetics DNA methylation in the core ataxin-2 gene promoter: novel physiological and pathological implications

Laffita-Mesa¹,

Bauer

Kourí

et al. 2011

Hum Genet

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Pathogenic CAG (cytosine-adenine-guanine) expansions beyond certain thresholds in the ataxin-2 (ATXN2) gene cause spinocerebellar ataxia type 2 (SCA2) and were shown to contribute to Parkinson disease, amyotrophic lateral sclerosis and frontotemporal lobar degeneration. Regulation of ATXN2 gene expression and the function of the protein product are not known. SCA2 exhibits an inverse correlation between the size of the CAG repeat and the age at disease onset. However, a wide range of age at onset are typically observed, with CAG repeat number alone explaining only partly this variability. In this study, we explored the hypothesis that ATXN2 levels could be controlled by DNA methylation and that the derangement of this control may lead to escalation of disease severity and influencing the age at onset. We found that CpG methylation in human ATXN2 gene promoter is associated with pathogenic CAG expansions in SCA2 patients. Different levels of methylation in a SCA2 pedigree without an intergenerational CAG repeat instability caused the disease anticipation in a SCA2 family. DNA methylation also influenced the disease onset in SCA2 homozygotes and SCA3 patients. In conclusion, our study points to a novel regulatory mechanism of ATXN2 expression involving an epigenetic event resulting in differential disease course in SCA2 patients.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Epigenetics DNA methylation in the core ataxin-2 gene promoter: novel physiological and pathological implications

Laffita-Mesa¹,

Bauer

Kourí

et al. 2011

Hum Genet

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“…15 In particular, the co-repressor complex ZNF350/BRCA1/CtIP (CtTB-interacting protein) is implicated in the repression of highmobility group AT-hook 2 (HMGA2) and angiopoietin-1 (ANG1) genes, which are involved in increased proliferation, mammary acini formation, anchorage-independent growth and vascular formation in breast tumors. 16,17 In addition, the ZNF350 gene overexpression led to an increase of ataxin-2 (ATXN2) mRNA levels (spinocerebellar ataxia type 2: SCA2 gene), 18 which is involved in RNA metabolism and endocytic processes. [19][20][21][22][23] In breast cancer cells, ZNF350 was also identified as a transcriptional repressor of p21 when associated with the KRAB domain-associated protein 1.…”

Section: Introductionmentioning

confidence: 99%

Analysis of ZNF350/ZBRK1 promoter variants and breast cancer susceptibility in non-BRCA1/2 French Canadian breast cancer families

et al. 2012

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ZNF350/ZBRK1 is a transcription factor, which associates with BRCA1 to co-repress GADD45A to regulate DNA damage repair, and the expression of ZNF350 is altered in different human carcinomas. In a previous study, we identified ZNF350 genomic variants potentially involved in breast cancer susceptibility in high-risk non-BRCA1/2 breast cancer individuals, which pointed toward a potential association for variants in the 5'-UTR and promoter regions. Therefore, direct sequencing was undertaken and identified 12 promoter variants, whereas haplotype analyses put in evidence four common haplotypes with a frequency>2%. However, based on their frequency observed in breast cancer and unrelated healthy individuals, these are not statistically associated with breast cancer risk. Luciferase promoter assays in two breast cancer cell lines identified two haplotypes (H11 and H12) stimulating significantly the expression of ZNF350 transcript compared with the common haplotype H8. The high expression of the H11 allele was associated with the variant c.-874A. Using MatInspector and Transcription Element Search softwares, in silico analyses predicted that the variant c.-874A created a binding site for the factors c-Myc and myogenin. This study represents the first characterization step of the ZNF350 promoter. Additional studies in larger cohorts and other populations will be needed to further evaluate whether common and/or rare ZNF350 promoter variants and haplotypes could be associated with a modest risk of breast cancer.

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Drosophila ataxin‐2 gene encodes two differentially expressed isoforms and its function in larval fat body is crucial for development of peripheral tissues

et al. 2016

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Different isoforms of ataxin‐2 are predicted in Drosophila and may underlie different cellular processes. Here, we validated the isoforms B and C of Drosophila ataxin‐2 locus (dAtx2), which we found to be expressed in various tissues and at different levels during development. dAtx2‐B mRNA was detected at low amounts during all developmental stages, whereas dAtx2‐C mRNA levels increase by eightfold from L3 to pupal–adult stages. Higher amounts of dAtx2‐B protein were detected in embryos, while dAtx2‐C protein was also expressed in higher levels in pupal–adult stages, indicating post‐transcriptional control for isoform B and transcription induction for isoform C, respectively. Moreover, in the fat body of L3 larvae dAtx2‐C, but not dAtx2‐B, accumulates in cytoplasmic foci that colocalize with sec23, a marker of endoplasmic reticulum exit sites (ERES). Interestingly, animals subjected to selective knockdown of dAtx2 in the larval fat body do not complete metamorphosis and die at the third larval stage or early puparium. Additionally, larvae knocked down for dAtx2, grown at 29 °C, are significantly smaller than control animals due to reduction in DNA replication and cell growth, which are consistent with the decreased levels of phosphorylated‐AKT observed in the fat body. Based on the localization of ataxin‐2 (dAtx2‐C) in ERESs, and on the phenotypes observed by dAtx2 knockdown in the larval fat body, we speculate a possible role for this protein in processes that regulate ERES formation. These data provide new insights into the biological function of ataxin‐2 with potential relevance to neurodegenerative diseases.

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The KRAB-containing zinc-finger transcriptional regulator ZBRK1 activates SCA2 gene transcription through direct interaction with its gene product, ataxin-2

Cited by 36 publications

References 37 publications

Epigenetics DNA methylation in the core ataxin-2 gene promoter: novel physiological and pathological implications

Epigenetics DNA methylation in the core ataxin-2 gene promoter: novel physiological and pathological implications

Analysis of ZNF350/ZBRK1 promoter variants and breast cancer susceptibility in non-BRCA1/2 French Canadian breast cancer families

Drosophila ataxin‐2 gene encodes two differentially expressed isoforms and its function in larval fat body is crucial for development of peripheral tissues

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