Project description:Mutations in the MECP2 gene cause the profound neurological disorder Rett syndrome. MeCP2 protein is an epigenetic reader that recruits the NCOR1/2 corepressor complexes to methylated cytosine in its canonical CG setting, but also to methylated CA motifs, which are abundant in neurons but rare in other cell types. In this study we set out to test the biological significance of this non-canonical mode of DNA binding. To achieve this, we replaced the endogenous MeCP2 DNA binding domain with that of MBD2, which only binds mCG. Knock-in mice expressing the hybrid “MM2” protein created by this domain-swap displayed severe Rett syndrome-like phenotypes. This indicates that binding to mCA, specifically the mCAC trinucleotide, is critical for normal brain function and it offers a plausible explanation for the delayed onset of Rett syndrome, due to the coincident late accumulation of mCAC and its cognate interpreter, MeCP2. We show that the small subset of genes aberrantly expressed in both Mecp2-null and MM2 mice is strikingly enriched for genes implicated in neurological disorders, highlighting targets with potential relevance to the Rett syndrome phenotype

Project description:Mutations in the MECP2 gene cause the profound neurological disorder Rett syndrome. MeCP2 protein is an epigenetic reader that recruits the NCOR1/2 corepressor complexes to methylated cytosine in its canonical CG setting, but also to methylated CA motifs, which are abundant in neurons but rare in other cell types. In this study we set out to test the biological significance of this non-canonical mode of DNA binding. To achieve this, we replaced the endogenous MeCP2 DNA binding domain with that of MBD2, which only binds mCG. Knock-in mice expressing the hybrid “MM2” protein created by this domain-swap displayed severe Rett syndrome-like phenotypes. This indicates that binding to mCA, specifically the mCAC trinucleotide, is critical for normal brain function and it offers a plausible explanation for the delayed onset of Rett syndrome, due to the coincident late accumulation of mCAC and its cognate interpreter, MeCP2. We show that the small subset of genes aberrantly expressed in both Mecp2-null and MM2 mice is strikingly enriched for genes implicated in neurological disorders, highlighting targets with potential relevance to the Rett syndrome phenotype

Project description:This SuperSeries is composed of the following subset Series: GSE24285: Genome-wide Analysis Reveals Mecp2-dependent Regulation of MicroRNAs in a Mouse Model of Rett Syndrome (mm8 chromosomal tiling arrays) GSE24286: Genome-wide Analysis Reveals Mecp2-dependent Regulation of MicroRNAs in a Mouse Model of Rett Syndrome (mm8 promoter tiling arrays) GSE24320: Genome-wide Analysis Reveals Mecp2-dependent Regulation of MicroRNAs in a Mouse Model of Rett Syndrome (high-throughput small RNA sequencing) Refer to individual Series

Project description:Mutations in MECP2 cause the autism-spectrum disorder Rett syndrome. MeCP2 is predicted to bind to methylated promoters and silence transcription. However, the first large-scale mapping of neuronal MeCP2-binding sites on 26.3 Mb of imprinted and nonimprinted loci revealed that 59% of MeCP2-binding sites are outside of genes and that only 6% are in CpG islands. Integrated genome-wide promoter analysis of MeCP2 binding, CpG methylation, and gene expression revealed that 63% of MeCP2-bound promoters are actively expressed and that only 6% are highly methylated. These results indicate that the primary function of MeCP2 is not the silencing of methylated promoters. Keywords: ChIP-chip analysis

Project description:Rett syndrome is a severe neurodevelopmental condition that rsults primarily from mutations in the MECP2 gene. MECP2 is known to function as both a transcriptional activator and transcriptional repressor. However, it remains unclear how transcriptional dysregulation resulting from MECP2 mutations lead to the Rett syndrome phenotype. Multiple mouse models have been generated to investigate the function of MECP2 in vivo. Remarkably, despite the neurodevelopmental phenotype characteristic of Rett syndrome, temporal conditional MECP2 knock-out mouse models with MECP2 deletion induced postnatally recapitulate the Rett-syndrome-like phenotype in mouse. Here we investigated gene expression changes in 22-weeks old mice following conditional MECP knock-out at 12 weeks by RNA-sequencing. Consistent with previous data, we identify mild gene expression changes following MECP2 knock-out. These data could prove valuable in future studies comparing conditional MECP2 knock-out at distinct time points and in additional brain regions, and can also serve for investigating alternative splicing changes resulting from MECP2 conditional deletion.

Project description:The postnatal neurodevelopmental disorder Rett syndrome (RTT) is caused by mutations in the gene encoding Methyl-CpG-binding Protein 2 (MeCP2). Despite decades of research, it remains unclear how MeCP2 actually regulates transcription or why RTT features appear only 6-18 months after birth. We examined MeCP2 binding to methylated cytosine in the CH context (mCH, where H = A, C, or T) in the adult mouse brain and found that MeCP2 binds these mCH sites, influencing nucleosome positioning and transcription. Strikingly, this pattern is unique to the mature nervous system, as it requires the increase in mCH after birth to reveal differences in MeCP2 binding to mCG, mCH, and non-methylated DNA elements. This study provides insight into the molecular mechanism governing MeCP2 targeting and how this targeting might contribute to the delayed onset of RTT symptoms. MeCP2 ChIP-Seq were conducted from ~ 7-week-old hypothalamus tissues from Mecp2-/y; MECP2-EGFP mice.

Project description:The postnatal neurodevelopmental disorder Rett syndrome (RTT) is caused by mutations in the gene encoding Methyl-CpG-binding Protein 2 (MeCP2). Despite decades of research, it remains unclear how MeCP2 actually regulates transcription or why RTT features appear only 6-18 months after birth. We examined MeCP2 binding to methylated cytosine in the CH context (mCH, where H = A, C, or T) in the adult mouse brain and found that MeCP2 binds these mCH sites, influencing nucleosome positioning and transcription. Strikingly, this pattern is unique to the mature nervous system, as it requires the increase in mCH after birth to reveal differences in MeCP2 binding to mCG, mCH, and non-methylated DNA elements. This study provides insight into the molecular mechanism governing MeCP2 targeting and how this targeting might contribute to the delayed onset of RTT symptoms. Mnase-Seq were conducted from 7-week-old hypothalamus from MeCP2 knockout mice and their age and genetic background matched wild types control mice.

Project description:Transcription profiling of cultured fibroblastic cell lines from Rett syndrome patients. Rett syndrome (symbolized RTT) is caused by mutations in the gene MECP2 located on the X chromosome. We compared cell lines mutated clones versus non mutated.

Project description:Human methyl-CpG-binding protein 2 (MeCP2) disruption causes Rett syndrome, an autistic disease prevalent in females. Previous microarray expression profiling studies using tissue homogenate samples from mouse model of the Rett syndrome revealed only modest changes in expression caused by the loss of Mecp2, making it difficult to identify etiology of the Rett syndrome. Here, we carried out cell type specific genome wide expression profiling of Mecp2 null mice in three neuronal cell types. We found a hot spot of Mecp2 affected genes in chromosome 11B3 syntenic to human chromosome 17p13 which has known associations to mental retardation. We also found Mecp2 affected genes are almost non-overlapping between cell types. Cell-adhesion category of genes, however, are commonly overrepresented, suggesting a possible etiology of Rett syndrome Keywords: cell type comparison, disease state analysis, genetic modification Transgenic mice lines which label subpopulations of neurons (G42: fast spiking Parvarbumin positive interneurons, YFPH: layer 5 thick tufted pyramidal neurons, TH: tyrosine hydroxylase positive locus coeruleus neurons) were used to obtain cell type specific expression profiles on Affymetrix microarrays. Females which carry Mecp2 null alleles (and one of the fluorescent alleles) were crossed with males (which may or may not carry one of the fluorescent alleles depending on whether the female has one or not). Male offsprings at around age P40 which carry fluorescent allele and Mecp2 null allele were used for experiments. Littermate males which carry fluorescent allele but not Mecp2 null allele were used for controls. 3 or 4 biological replicates were done for each condition.

Project description:Mutations in the methyl-DNA-binding repressor protein MeCP2 cause the devastating neurodevelopmental disorder Rett syndrome. It has been challenging to understand how MeCP2 regulates transcription because MeCP2 binds broadly across the genome, and MeCP2 mutations are associated with widespread small-magnitude changes in neuronal gene expression. We demonstrate here that MeCP2 represses nascent RNA transcription of highly methylated long genes in the brain through its interaction with the NCoR co-repressor complex. By measuring the rates of transcriptional initiation and elongation directly in the brain, we find that MeCP2 has no measurable effect on transcriptional elongation, but instead represses the rate at which Pol II initiates transcription of highly methylated long genes. These findings suggest a new model of MeCP2 function in which MeCP2 binds broadly across highly methylated regions of DNA, but acts at transcription start sites to attenuate transcriptional initiation.