Project description:The molecular mechanisms that lead to the cognitive defects characteristic of Down syndrome (DS), the most frequent cause of mental retardation, have remained elusive. Here we use a transgenic DS mouse model to show that DYRK1A gene dosage imbalance deregulates chromosomal clusters of genes located near neuron-restrictive silencer factor (REST/NRSF) binding sites. We found that DYRK1A binds the SWI/SNF-complex known to interact with REST/NRSF. Mutation of a REST/NRSF binding site in the promoter of the REST/NRSF target gene L1cam modifies the transcriptional effect of Dyrk1A-dosage imbalance on L1cam. DyrkA dosage imbalance perturbs Rest/Nrsf levels with decreased Rest/Nrsf expression in embryonic neurons and increased expression in adult neurons. We identified a coordinated deregulation of multiple genes that are responsible for the cellular phenotypic traits present in DS such as dendritic growth impairment and microcephaly during prenatal cortex development. Dyrk1a overexpression in primary mouse cortical neurons reduced the neuritic complexity. In the postnatal hippocampus, DYRK1A overexpression suppresses a form of synaptic plasticity that may be sufficient to cause DS cognitive defects. We propose that DYRK1A overexpression-related neuronal gene deregulation generates the brain phenotypic changes that characterize DS, with an accessory role for the gene dosage imbalance of other chromosome 21 genes.

Project description:The molecular mechanisms that lead to the cognitive defects characteristic of Down syndrome (DS), the most frequent cause of mental retardation, have remained elusive. Here we use a transgenic DS mouse model to show that DYRK1A gene dosage imbalance deregulates chromosomal clusters of genes located near neuron-restrictive silencer factor (REST/NRSF) binding sites. We found that DYRK1A binds the SWI/SNF-complex known to interact with REST/NRSF. Mutation of a REST/NRSF binding site in the promoter of the REST/NRSF target gene L1cam modifies the transcriptional effect of Dyrk1A-dosage imbalance on L1cam. DyrkA dosage imbalance perturbs Rest/Nrsf levels with decreased Rest/Nrsf expression in embryonic neurons and increased expression in adult neurons. We identified a coordinated deregulation of multiple genes that are responsible for the cellular phenotypic traits present in DS such as dendritic growth impairment and microcephaly during prenatal cortex development. Dyrk1a overexpression in primary mouse cortical neurons reduced the neuritic complexity. In the postnatal hippocampus, DYRK1A overexpression suppresses a form of synaptic plasticity that may be sufficient to cause DS cognitive defects. We propose that DYRK1A overexpression-related neuronal gene deregulation generates the brain phenotypic changes that characterize DS, with an accessory role for the gene dosage imbalance of other chromosome 21 genes.

Project description:The molecular mechanisms that lead to the cognitive defects characteristic of Down syndrome (DS), the most frequent cause of mental retardation, have remained elusive. Here we use a transgenic DS mouse model to show that DYRK1A gene dosage imbalance deregulates chromosomal clusters of genes located near neuron-restrictive silencer factor (REST/NRSF) binding sites. We found that DYRK1A binds the SWI/SNF-complex known to interact with REST/NRSF. Mutation of a REST/NRSF binding site in the promoter of the REST/NRSF target gene L1cam modifies the transcriptional effect of Dyrk1A-dosage imbalance on L1cam. DyrkA dosage imbalance perturbs Rest/Nrsf levels with decreased Rest/Nrsf expression in embryonic neurons and increased expression in adult neurons. We identified a coordinated deregulation of multiple genes that are responsible for the cellular phenotypic traits present in DS such as dendritic growth impairment and microcephaly during prenatal cortex development. Dyrk1a overexpression in primary mouse cortical neurons reduced the neuritic complexity. In the postnatal hippocampus, DYRK1A overexpression suppresses a form of synaptic plasticity that may be sufficient to cause DS cognitive defects. We propose that DYRK1A overexpression-related neuronal gene deregulation generates the brain phenotypic changes that characterize DS, with an accessory role for the gene dosage imbalance of other chromosome 21 genes. Experiment Overall Design: Agilent Whole Mouse Genome oligomicroarrays (GEO accession no. GPL2872, Agilent Technologies, Palo Alto, CA) were used. They contain 60-mer DNA probes synthesized in situ in a 44k format. Of 44,290 spots, 2756 are controls. The remaining 41,534 spots represent 33,661 unique transcripts which correspond to 20,202 unique human genes. Five independent (Dyrk1A overexpression, five individual samples) measurements were carried out for each group of biological conditions using exchanged dye-labeled RNA targets (i.e., Cy3 and Cy5 dye-swapping experiments).

Project description:The molecular mechanisms that lead to the cognitive defects characteristic of Down syndrome (DS), the most frequent cause of mental retardation, have remained elusive. Here we use a transgenic DS mouse model to show that DYRK1A gene dosage imbalance deregulates chromosomal clusters of genes located near neuron-restrictive silencer factor (REST/NRSF) binding sites. We found that DYRK1A binds the SWI/SNF-complex known to interact with REST/NRSF. Mutation of a REST/NRSF binding site in the promoter of the REST/NRSF target gene L1cam modifies the transcriptional effect of Dyrk1A-dosage imbalance on L1cam. DyrkA dosage imbalance perturbs Rest/Nrsf levels with decreased Rest/Nrsf expression in embryonic neurons and increased expression in adult neurons. We identified a coordinated deregulation of multiple genes that are responsible for the cellular phenotypic traits present in DS such as dendritic growth impairment and microcephaly during prenatal cortex development. Dyrk1a overexpression in primary mouse cortical neurons reduced the neuritic complexity. In the postnatal hippocampus, DYRK1A overexpression suppresses a form of synaptic plasticity that may be sufficient to cause DS cognitive defects. We propose that DYRK1A overexpression-related neuronal gene deregulation generates the brain phenotypic changes that characterize DS, with an accessory role for the gene dosage imbalance of other chromosome 21 genes. Experiment Overall Design: Agilent Whole Mouse Genome oligomicroarrays (GEO accession no. GPL2872, Agilent Technologies, Palo Alto, CA) were used. They contain 60-mer DNA probes synthesized in situ in a 44k format. Of 44,290 spots, 2756 are controls. The remaining 41,534 spots represent 33,661 unique transcripts which correspond to 20,202 unique human genes. Four dependent (152F7, one series of pooled samples) measurements were carried out for each group of biological conditions using exchanged dye-labeled RNA targets (i.e., Cy3 and Cy5 dye-swapping experiments).

Project description:Transcription profiling of transgenic down syndrome mouse model to show the role of DYRK1A gene. The molecular mechanisms that lead to the cognitive defects characteristic of Down syndrome (DS), the most frequent cause of mental retardation, have remained elusive. Here we use a transgenic DS mouse model to show that DYRK1A gene dosage imbalance deregulates chromosomal clusters of genes located near neuron-restrictive silencer factor (REST/NRSF) binding sites. We found that DYRK1A binds the SWI/SNF-complex known to interact with REST/NRSF. Mutation of a REST/NRSF binding site in the promoter of the REST/NRSF target gene L1cam modifies the transcriptional effect of Dyrk1Adosage imbalance on L1cam. DyrkA dosage imbalance perturbs Rest/Nrsf levels with decreased Rest/Nrsf expression in embryonic neurons and increased expression in adult neurons. We identified a coordinated deregulation of multiple genes that are responsible for the cellular phenotypic traits present in DS such as dendritic growth impairment and microcephaly during prenatal cortex development. Dyrk1a overexpression in primary mouse cortical neurons reduced the neuritic complexity. In the postnatal hippocampus, DYRK1A overexpression suppresses a form of synaptic plasticity that may be sufficient to cause DS cognitive defects. We propose that DYRK1A overexpression-related neuronal gene deregulation generates the brain phenotypic changes that characterize DS, with an accessory role for the gene dosage imbalance of other chromosome 21 genes. Transgenic embrionic brain regions versus wild type mice were analysed. The log2 values represent Cy5/Cy3 ratio (transgenic Cy5/wild type Cy3). Each array was scanned under a green laser (543 nm for Cy3 labeling) or a red laser (633 nm for Cy5 labeling) using a ScanArray Lite scanning confocal fuorescent scanner with 10 u resolution (laser power: 85% for Cy5 and 90% for Cy3, gain: 75% for Cy5 and 70% for Cy3). Scanned output files were analyzed using the GenePix Pro 3.0 software. Each spot was defined by automatic positioning of a grid of circles over the image. The average and median pixel intensity ratios calculated from both channels and the local background of each spot were determined. Local background corrected intensity ratios was determined for each spot. The background-corrected expression data were filtered for flagged spots and weak signal. Normalization was performed by the global Lowess method. Student’s t-test was applied to determine the p value.

Project description:The goal of this study was to identify genomic binding sites of the NRSF/REST transcription factor under conditions of basal and increased SF-1 dosage in the H295R human adrenocortical tumor cell line. 4 samples: input DNA (2 replicates) - NRSF/REST ChIP basal SF-1 dosage - NRSF/REST ChIP increased SF-1 dosage

Project description:The inhibition of DYRK1A (Dual Specificity Tyrosine-Phosphorylation-Regulated Kinase 1A) activity, triplicated in trisomy 21 subjects, has been proved as a promising therapy for Down syndrome. Epigallocatechin-3-gallate (EGCG), a polyphenol of green tea, is an allosteric inhibitor of DYRK1A that showed beneficial pro-cognitive effects in clinical trials with DS individuals. However, EGCG induces several pharmacological effects, and there is no proof that the observed improvements result from DYRK1A inhibition. Besides, the direct consequences of Dyrk1A overexpression are not well defined. We therefore used quantitative proteomics to decipher the proteome and phosphoproteome alterations resulting from Dyrk1A overexpression and its inhibition to get insight into the mechanism of action of EGCG. Towards this aim, we used mice overexpressing Dyrk1A, and compared the hippocampal proteome and phosphoproteome with their wild type counterparts, in basal conditions, and after treatment with EGCG. Moreover, given that the human clinical trials found that the effects of EGCG potentiated the effects of cognitive stimulation, we also included in our study treatment with environmental enrichment and its combination with EGCG. We found that DYRK1A overexpression leads to alterations in protein and phosphoprotein levels of hundreds of proteins, and that the levels of proteins involved in key postsynaptic pathways are restored by the cognitive enhancer treatments, which could help conceiving new therapeutic strategies.

Project description:The vertebrate-specific transcription factor RE-1 silencing transcription factor or neuron-restrictive silencer factor (REST/NRSF) was first described as a negative regulator restricting expression of neuronal genes to neurons in a variety of genetic contexts. However, REST/NRSF has a more general role in the regulation of gene expression that involves chromatin remodelling via a SWI/SNF complex. We identified a 677 gene repertoire of potential REST/NRSF-dependent genes taking advantage of Rest/Nrsf gene silencing in a mouse cell line. Using Ka/Ks analysis, we found that REST/NRSF protein, REST/NRSF interactors and the products of REST/NRSF-dependent genes display significantly higher rates of protein evolution in primates than in rodents. The McDonald-Kreitman test indicated positive selection for human REST/NRSF and nuclear RNA-binding proteins encoded by REST/NRSFdependent genes. In these proteins, we demonstrated sites under positive selection within the primate’s clade. Importantly, the REST/NRSF-dependent gene repertoire is statistically enriched in genes disrupted in neuropsychiatric diseases such as schizophrenia. In addition, we found that Smarca2 (Brm), Smarcd3 (Baf60c), Smarce1 (Baf57), Hdac1, RcoR1, and Mecp2, which are part of the REST/NRSFSWI/SNF chromatin remodelling complex, are transcriptionally regulated by REST/NRSF. Changing their gene dosage in vitro induced abnormal dendritic and dendritic spine phenotypes that were previously observed in rodent models of neuropsychiatric diseases. Altogether, these results suggest that genes encoding proteins of the REST/NRSF-SWI/SNF pathway display primate-specific accelerated evolution. It may be hypothesized that the subset of genes involved in this pathway, which display a primate evolutionary signature in specific sites, may represent a novel gene candidate repertoire for neuropsychiatric diseases.

Project description:Analysis of HeLa cell with overexpression of an EGFP-tagged dominant-negative truncation (73- 563 a.a.) of human REST/NRSF. RNA polymerase II and DNA damage repair factor γ-H2AX binding data provide insight into the molecular bases of how REST/NRSF perturbation impairs genome stability.

Project description:Down syndrome (DS), the most common human chromosomal disorder, is caused by trisomy 21. Recent studies show that the trisomic genes Dyrk1a and Kcnj6 play critical causative roles in DS cognitive deficits. Interestingly, an unexpected lack of improvement of hippocampal-dependent learning and memory deficits was observed when both Dyrk1a and Kcnj6 were normalized to diploidy in the DS mouse model, Dp(16)1/Yey (Dp16). In this study, we explored the molecular mechanisms underlying this phenomenon by using whole genome-wide hippocampal transcriptome analysis. In total, 142, 142, and 112 genes were found significantly differentially expressed in the Dp16, Dp16/Dyrk1aKO (Dyrk1a normalized) and Dp16;Dyrk1aKO/Kcnj6KO (Both Dyrk1a and Kcnj6 normalized) hippocampus, respectively, compared with the WT hippocampus. The majority of the common significantly differentially expressed genes (DEGs) were trisomic genes. Dyrk1a and Kcnj6 normalization mainly altered the expression of diploid genes. Normalizing Dyrk1a in the Dp16 hippocampus caused an overall downregulation of genes, whereas further Kcnj6 normalization caused an overall upregulation of genes. Both further rescuing effects and neutralizing effects were observed in Kcnj6 and Dyrk1a double-normalized mice compared with mice with Dyrk1a normalization alone.