Project description:Alzheimer’s disease (AD) and Frontotemporal dementia (FTD) are the two most common forms of dementia that occur during aging. Both AD and FTD are associated with the pathological aggregation of proteins. Nevertheless, it remains unclear how these protein aggregates lead to neuronal cell death in these dementias. Here we show that the histone demethylase LSD1 is mislocalized with cytoplasmic aggregates in human cases of AD and FTD. In addition, loss of LSD1 systemically in adult mice is sufficient to recapitulate many aspects of these diseases. From these data, we propose that the aggregation of Tau and TDP-43 lead to neuronal cell death in AD and FTD by interfering with the continuous requirement for LSD1 to repress inappropriate transcription. Furthermore, we observe the inappropriate reactivation of stem cell loci in the hippocampal neurons of LSD1 mutant mice. This suggests that LSD1 may function to maintain the fate of differentiated neurons by repressing stem cell transcription.

Project description:To understand how haploinsufficiency of progranulin (PGRN) protein causes frontotemporal dementia (FTD), we created induced pluripotent stem cells (iPSC) from patients carrying the GRNIVS1+5G>C mutation (FTD-iPSCs). FTD-iPSCs were fated to cortical neurons, the cells most affected in FTD and known to express PGRN. Although generation of neuroprogenitors was unaffected, their further differentiation into neurons, especially CTIP2-, FOXP2- or TBR1-TUJ1 double positive cortical neurons, was significantly decreased in FTD-neural progeny. Zinc finger nuclease-mediated introduction of PGRN cDNA into the AAVS1 locus corrected defects in cortical neurogenesis, demonstrating that PGRN haploinsufficiency causes inefficient cortical neuron generation. RNAseq analysis confirmed reversal of altered gene expression profile following genetic correction. Wnt signaling pathway, one of the top defective pathways in FTD-iPSC-derived neurons coupled with its reversal following genetic correction, makes it an important candidate. Therefore, we demonstrate for the first time that PGRN haploinsufficiency hampers corticogenesis in vitro.

Project description:Human genetic studies have identified the neuronal RNA binding protein, Rbfox1, as a candidate gene for autism spectrum disorders. While Rbfox1 functions as a splicing regulator in the nucleus, it is also alternatively spliced to produce cytoplasmic isoforms. To investigate cytoplasmic Rbfox1, we knocked down Rbfox proteins in mouse neurons and rescued with cytoplasmic or nuclear Rbfox1. Transcriptome profiling showed that nuclear Rbfox1 rescued splicing changes induced by knockdown, whereas cytoplasmic Rbfox1 rescued changes in mRNA levels. iCLIP-seq of subcellular fractions revealed that in nascent RNA Rbfox1 bound predominantly to introns, while cytoplasmic Rbox1 bound to 3' UTRs. Cytoplasmic Rbfox1 binding increased target mRNA stability and translation, and overlapped significantly with miRNA binding sites. Cytoplasmic Rbfox1 target mRNAs were enriched in genes involved in cortical development and autism. Our results uncover a new Rbfox1 regulatory network and highlight the importance of cytoplasmic RNA metabolism to cortical development and disease. In this data set, we included the data from microarray experiments. We performed microarray analysis to profile gene expression and splicing changes in mouse hippocampal cultures (14 DIV) with Rbfox1 and Rbfox3 double knockdown by siRNAs. Before the treatment of siRNAs, the hippocampal cultures were treated with AraC to eliminate glial cells and co-cultured with cortical cultures to support the growth of neurons. Six samples were analyzed.

Project description:Human genetic studies have identified the neuronal RNA binding protein, Rbfox1, as a candidate gene for autism spectrum disorders. While Rbfox1 functions as a splicing regulator in the nucleus, it is also alternatively spliced to produce cytoplasmic isoforms. To investigate cytoplasmic Rbfox1, we knocked down Rbfox proteins in mouse neurons and rescued with cytoplasmic or nuclear Rbfox1. Transcriptome profiling showed that nuclear Rbfox1 rescued splicing changes induced by knockdown, whereas cytoplasmic Rbfox1 rescued changes in mRNA levels. iCLIP-seq of subcellular fractions revealed that in nascent RNA Rbfox1 bound predominantly to introns, while cytoplasmic Rbox1 bound to 3' UTRs. Cytoplasmic Rbfox1 binding increased target mRNA stability and translation, and overlapped significantly with miRNA binding sites. Cytoplasmic Rbfox1 target mRNAs were enriched in genes involved in cortical development and autism. Our results uncover a new Rbfox1 regulatory network and highlight the importance of cytoplasmic RNA metabolism to cortical development and disease. In this data set, we included the data from iCLIP-seq experiments. We performed iCLIP procedures to identify Rbfox1 binding in the cytoplasm. Cultured mouse forebrain neurons were irradiated with UV and a cytoplasmic fraction was purified for immunoprecipitation. An anti-Rbfox1 antibody was used to immunoprecipitate Rbfox1 target RNAs and an anti-Flag antibody was used as control. Two samples were analyzed.

Project description:Human genetic studies have identified the neuronal RNA binding protein, Rbfox1, as a candidate gene for autism spectrum disorders. While Rbfox1 functions as a splicing regulator in the nucleus, it is also alternatively spliced to produce cytoplasmic isoforms. To investigate cytoplasmic Rbfox1, we knocked down Rbfox proteins in mouse neurons and rescued with cytoplasmic or nuclear Rbfox1. Transcriptome profiling showed that nuclear Rbfox1 rescued splicing changes induced by knockdown, whereas cytoplasmic Rbfox1 rescued changes in mRNA levels. iCLIP-seq of subcellular fractions revealed that in nascent RNA Rbfox1 bound predominantly to introns, while cytoplasmic Rbox1 bound to 3' UTRs. Cytoplasmic Rbfox1 binding increased target mRNA stability and translation, and overlapped significantly with miRNA binding sites. Cytoplasmic Rbfox1 target mRNAs were enriched in genes involved in cortical development and autism. Our results uncover a new Rbfox1 regulatory network and highlight the importance of cytoplasmic RNA metabolism to cortical development and disease. In this data set, we included the data from RNA-seq experiments. We performed RNA-seq to profile gene expression and splicing changes. The expression levels of Rbfox1 and Rbfox3 in cultured mouse hippocampal neurons were reduced by siRNAs. The reduction of Rbfox1 and 3 was rescued by expression of cytoplasmic or nuclear Rbfox1 splice isoform. The gene expression and splicing profiles were compared between different treatments. Eight samples were analyzed.

Project description:Mitochondria are arising as critical modulators of antiviral tolerance by releasing mtDNA/mtRNA fragments to cytoplasm upon infection, activating virus sensors and type-I interferon response. The relevance of these mechanisms for mitochondrial diseases remains understudied. Here, we investigated mitochondrial recessive ataxia syndrome (MIRAS), caused by a common European founder mutation in DNA polymerase gamma (POLG1). The patients homozygous for the MIRAS variant p.W748S show exceptionally variable ages-of-onset and symptoms, indicating unknown modifying factors contributing to disease manifestation. We report that the mitochondrial DNA (mtDNA) replicase POLG1 has a role in antiviral defence mechanisms to double-stranded DNA and positive-strand RNA virus infections (HSV-1, TBEV, SARS-CoV-2) and its p.W748S variant dampens innate immune responses. Our patient and knock-in mouse data show that p.W748S compromises mtDNA replisome stability, causing mtDNA depletion, aggravated by virus infection. Low mtDNA and mtRNA release to cytoplasm and slow interferon response in MIRAS allow an early replicative advantage for viruses, leading to augmented pro-inflammatory response, subacute loss of GABAergic neurons, liver inflammation and necrosis. A population databank of ~300,000 Finns demonstrates enrichment of immunodeficient traits in p.W748S carriers. Our evidence suggests that POLG1 defects compromise antiviral tolerance, triggering epilepsy and liver disease. The finding has important implications to mitochondrial disease spectrum, including epilepsy, ataxia, and parkinsonism.

Project description:INTRODUCTION: Frontotemporal dementia (FTD) is characterized by progressive atrophy of frontal and/or temporal cortices and considerable clinical, pathological, and genetic heterogeneity. METHODS: Frontal and temporal cortex tissues from FTD-GRN (n=9), FTD-MAPT (n=13), and non-demented controls (n=11) were analysed with quantitative proteomics (DIA). Expression-weighted cell type enrichment deduced the role of major brain cell types and gene ontology analysis identified distinct biological processes. FTD-MAPT data was also compared to an AD (n=10) protein signature. RESULTS: We identified brain region-specific FTD protein expression signatures. In frontal cortex of FTD-GRN, we observed immune processes in endothelial cells and mitochondrial dysregulation in neurons. In temporal cortex of FTD-MAPT, we observed dysregulated RNA processing, oligodendrocyte dysfunction, and axonal impairment. Comparison with AD indicated that alterations in RNA processing and oligodendrocyte function are distinct for FTD-MAPT. DISCUSSION: Our results indicate cell type-specific biological processes distinctive for genetic FTD subtypes. These findings may aid the development of FTD subtype-specific treatment strategies.

Project description:Although the pathological hallmark of amyotrophic lateral sclerosis (ALS) is the nucleocytoplasmic mislocalisation of RNA binding proteins (RBPs), such as TDP-43 and FUS, the nucleocytoplasmic distribution of mRNA remains uncharacterised. Here, we used subcellular fractionation with RNA sequencing to assess nucleocytoplasmic mRNA localisation in human induced pluripotent stem cell-derived motor neurons (iPSNs) from ALS patients with TARDBP mutations, VCP mutations, and controls with VCP mutations isogenically knocked in with CRISPR/Cas9. In each mutant group, we found substantial nucleocytoplasmic mRNA redistribution, particularly in transcripts involved in protein binding. Redistributed transcripts in ALS iPSNs were enriched in protein-coding biotypes, exhibited longer lengths, and had enhanced interactions with RBPs, including TDP-43 and FUS. Treatment with the VCP D2 ATPase domain inhibitor ML240 partially restored nucleocytoplasmic mRNA redistribution not only in VCP mutants but also in TARDBP mutant iPSNs.

Project description:Human genetic studies have identified the neuronal RNA binding protein, Rbfox1, as a candidate gene for autism spectrum disorders. While Rbfox1 functions as a splicing regulator in the nucleus, it is also alternatively spliced to produce cytoplasmic isoforms. To investigate cytoplasmic Rbfox1, we knocked down Rbfox proteins in mouse neurons and rescued with cytoplasmic or nuclear Rbfox1. Transcriptome profiling showed that nuclear Rbfox1 rescued splicing changes induced by knockdown, whereas cytoplasmic Rbfox1 rescued changes in mRNA levels. iCLIP-seq of subcellular fractions revealed that in nascent RNA Rbfox1 bound predominantly to introns, while cytoplasmic Rbox1 bound to 3' UTRs. Cytoplasmic Rbfox1 binding increased target mRNA stability and translation, and overlapped significantly with miRNA binding sites. Cytoplasmic Rbfox1 target mRNAs were enriched in genes involved in cortical development and autism. Our results uncover a new Rbfox1 regulatory network and highlight the importance of cytoplasmic RNA metabolism to cortical development and disease. In this data set, we included the data from iCLIP-seq experiments.

Project description:Human genetic studies have identified the neuronal RNA binding protein, Rbfox1, as a candidate gene for autism spectrum disorders. While Rbfox1 functions as a splicing regulator in the nucleus, it is also alternatively spliced to produce cytoplasmic isoforms. To investigate cytoplasmic Rbfox1, we knocked down Rbfox proteins in mouse neurons and rescued with cytoplasmic or nuclear Rbfox1. Transcriptome profiling showed that nuclear Rbfox1 rescued splicing changes induced by knockdown, whereas cytoplasmic Rbfox1 rescued changes in mRNA levels. iCLIP-seq of subcellular fractions revealed that in nascent RNA Rbfox1 bound predominantly to introns, while cytoplasmic Rbox1 bound to 3' UTRs. Cytoplasmic Rbfox1 binding increased target mRNA stability and translation, and overlapped significantly with miRNA binding sites. Cytoplasmic Rbfox1 target mRNAs were enriched in genes involved in cortical development and autism. Our results uncover a new Rbfox1 regulatory network and highlight the importance of cytoplasmic RNA metabolism to cortical development and disease. In this data set, we included the data from microarray experiments.