Project description:Shank3 is an abundant excitatory postsynaptic scaffolding proteins implicated in various neurodevelopmental and psychiatric disorders, including ASD, Phelan-McDermid syndrome, intellectual disability, and schizophrenia. Shank3-mutant mice with a homozygous deletion of exons 14-16 (Shank3-HM mice) show ASD-like behavioral deficits and altered synaptic and neuronal functions, but little is known about how different ages, brain regions, and gene dosages contribute to transcriptomic phenotypes in these mice. Here, we performed RNA-Seq-based transcriptomic analyses of the prefrontal cortex, hippocampus, and striatum in adult Shank3 heterozygous- and homozygous-mutant mice. In addition, juvenile and adult Shank3 homozygous-mutant forebrain transcriptomes were compared. Juvenile and adult forebrain transcriptomes from Shank3 homozygous-mutant mice showed the patterns that are opposite and similar to those observed in ASD: reverse-ASD and ASD-like patterns, respectively. Here, the juvenile reverse-ASD pattern involved synaptic gene upregulations and ribosomal and mitochondrial downregulations, whereas the adult ASD-like pattern involved opposite changes. Gene set enrichment analyses (GSEA) of brain regional transcripts in adult Shank3-HT and Shank3-HM mice revealed that the cortical, hippocampal, and striatal transcripts show distinctly altered biological functions and ASD-related/risk gene expressions. The cortex and striatum display ASD-like patterns whereas the hippocampus displays reverse-ASD patterns. The cortical ASD-like pattern more strongly involves ASD-risk genes whereas the striatal ASD-like pattern more strongly involves astrocyte/microglia genes. Shank3-HT and Shank3-HM transcripts in a given brain region display largely similar patterns in biological functions and ASD-related/risk gene expressions, suggestive of small gene dosage effects. These results suggest that heterozygous and homozygous Shank3 deletions in mice lead to age, brain region, and gene dosage-differential transcriptomic changes.

Project description:Shank3 is an abundant excitatory postsynaptic scaffolding proteins implicated in various neurodevelopmental and psychiatric disorders, including ASD, Phelan-McDermid syndrome, intellectual disability, and schizophrenia. Shank3-mutant mice with a homozygous deletion of exons 14-16 (Shank3-HM mice) show ASD-like behavioral deficits and altered synaptic and neuronal functions, but little is known about how different ages, brain regions, and gene dosages contribute to transcriptomic phenotypes in these mice. Here, we performed RNA-Seq-based transcriptomic analyses of the prefrontal cortex, hippocampus, and striatum in adult Shank3 heterozygous- and homozygous-mutant mice. In addition, juvenile and adult Shank3 homozygous-mutant forebrain transcriptomes were compared. Juvenile and adult forebrain transcriptomes from Shank3 homozygous-mutant mice showed the patterns that are opposite and similar to those observed in ASD: reverse-ASD and ASD-like patterns, respectively. Here, the juvenile reverse-ASD pattern involved synaptic gene upregulations and ribosomal and mitochondrial downregulations, whereas the adult ASD-like pattern involved opposite changes. Gene set enrichment analyses (GSEA) of brain regional transcripts in adult Shank3-HT and Shank3-HM mice revealed that the cortical, hippocampal, and striatal transcripts show distinctly altered biological functions and ASD-related/risk gene expressions. The cortex and striatum display ASD-like patterns whereas the hippocampus displays reverse-ASD patterns. The cortical ASD-like pattern more strongly involves ASD-risk genes whereas the striatal ASD-like pattern more strongly involves astrocyte/microglia genes. Shank3-HT and Shank3-HM transcripts in a given brain region display largely similar patterns in biological functions and ASD-related/risk gene expressions, suggestive of small gene dosage effects. These results suggest that heterozygous and homozygous Shank3 deletions in mice lead to age, brain region, and gene dosage-differential transcriptomic changes.

Project description:Shank2 is an abundant postsynaptic scaffolding protein known to regulate excitatory synaptic assembly and function and is implicated in autism spectrum disorders (ASD). Whereas patient Shank2 mutations in autistic individuals are heterozygous, Shank2 functions studied in mice have mainly relied on the results from homozygous mutant mice, largely because of relatively strong synaptic and behavioral phenotypes. Moreover, although synaptic changes at juvenile and adult Shank2-mutant mice seem to be largely similar, it remains unclear whether there are any age-dependent changes across these stages at the molecular level. To address these questions, we attempted RNA-Seq analyses of the transcriptomes in the prefrontal cortex of both heterozygous and homozygous Shank2-mutant mice lacking exons 6 and 7 at juvenile and adult stages. The results indicate that heterozygous, but not homozygous, juvenile Shank2-mutant mice show strong transcriptomic changes that promote excitatory synaptic transmission and suppress ASD-related gene expressions. In contrast, adult Shank2-mutant mice show largely similar and dosage-dependent transcriptomic changes.

Project description:Heterozygous loss-of-function mutations in the synaptic scaffolding gene SHANK2 are strongly associated with autism spectrum disorder (ASD). To investigate their effect on synaptic connectivity, we generated cortical neurons from induced pluripotent stem cells (iPSC) derived from neurotypic and ASD-affected donors. We developed Sparse coculture for Connectivity (SparCon) assays where SHANK2 and control neurons were differentially labeled and sparsely seeded together on a lawn of unlabeled control neurons. We observed striking increases in total synapse number and dendrite complexity. Dendrite length increases were exacerbated by IGF1 or BDNF treatment. Increased excitatory synapse function in haploinsufficient SHANK2 neurons was phenocopied in gene-edited knockout SHANK2 neurons. Gene correction of an ASD SHANK2 mutation rescued excitatory synapse function supporting a role for SHANK2 as a negative regulator of connectivity in developing human neurons. The transcriptome in these isogenic SHANK2 neurons was deeply perturbed in synaptic and plasticity gene sets and ASD gene modules, and activity dependent dendrite extension was defective. Our unexpected findings provide evidence for hyperconnectivity and profoundly altered transcriptome in SHANK2 neurons derived from ASD subjects.

Project description:Autism spectrum disorder (ASD) and mental retardation (MR) represent clinically distinct neurodevelopmental disorders with a complex genetic etiology. Using microarrays we identified de novo copy number variations in the SHANK2 synaptic scaffolding gene in two unrelated ASD and MR patients; DNA sequencing of SHANK2 revealed additional variants including a de novo nonsense mutation and 7 rare inherited changes. Our findings further link common genes between ASD and intellectual disability.

Project description:Arid1b is a chromatin remodeler implicated in neurodevelopmental disorders. Arid1b mutant mice with haploinsufficiency (Arid1b HT) displayed persistent excitatory synaptic dysfunction from juvenile to adult stage, decreased synaptic density and transmission. Moreover, they showed autistic-like behaviors in both of early and adult stages, decreased sociability in pup USV calling and adult social interaction, and adult repetitive grooming. To investigate early transcriptomic changes in Arid1b mutant mice, RNAseq analysis of whole brain from wild-type and Arid1b mutant mice at postnatal day 10 was done. Transcriptomic changes support these electrophysiological and behavioral deficits. Arid1b HT mice at postnatal day 10 showed alterations in genes implicated in synaptic functions and ASD. Next, we found that early chronic fluoxetine treatment could carry out long-lasting restoration in electrophysiological and behavioral deficits in Arid1b HT mice. Whole brain transcriptomic analysis with mice at postnatal day 120 which underwent chronic fluoxetine treatment from postnatal day 3 to postnatal day 21 via mammillary milk was done to figure out transcriptomic reprogramming which contributes to this restoration. Comparing fluoxetine treated Arid1b HT mice and vehicle group, fluoxetine treated mice showed upregulation of synapse-related genes and disease related gene sets with reverse-ASD directions.

Project description:Heterozygous loss-of-function mutations in the synaptic scaffolding gene SHANK2 are strongly associated with autism spectrum disorder (ASD). To investigate their effect on synaptic connectivity, we generated cortical neurons from induced pluripotent stem cells (iPSC) derived from neurotypic and ASD-affected donors. We developed Sparse coculture for Connectivity (SparCon) assays where SHANK2 and control neurons were differentially labeled and sparsely seeded together on a lawn of unlabeled control neurons. We observed striking increases in dendrite length, dendrite complexity, total synapse number, and frequency of spontaneous excitatory postsynaptic currents. These findings were phenocopied in gene-edited homozygous SHANK2 knockout cells and rescued by gene correction of an ASD SHANK2 muation, supporting a role for SHANK2 as a regulator of connectivity in developing human neurons. Dendrite length increases were exacerbated by IGF1, TG003, or BDNF, and suppressed by DHPG treatment. The transcriptome in these isogenic SHANK2 neurons was deeply perturbed in synapse, plasticity, and neuronal morphogenesis gene sets and ASD gene modules, and activity-dependent dendrite extension was impaired. Our unexpected findings provide evidence for hyperconnectivity and profoundly altered transcriptome in SHANK2 neurons derived from ASD subjects.

Project description:Background: Transcriptome analysis has been used in autism spectrum disorder (ASD) to unravel common pathogenic pathways based on the assumption that distinct rare genetic variants or epigenetic modifications affect common biological pathways dysregulated in ASD. To unravel recurrent ASD-related neuropathological mechanisms, we took advantage of the En2-/- mouse model and performed transcriptome profiling on cerebellar and hippocampal adult tissues. Methods: En2-/- and WT cerebellar and hippocampal tissue from littermate mice were assessed for differential gene expression using microarray hybridization followed by RankProd analysis. To identify functional categories overrepresented in the differentially expressed genes we used the BIOBASE ExPlain system and mouse phenotype ontology database. Furthermore, we performed direct enrichment analysis of ASD associated genes from the SFARI repository in our differentially expressed genes. Results: We found 842 differentially expressed genes in En2-/- cerebellum and 862 in the En2-/- hippocampus. Our functional analysis revealed that the molecular signature of En2-/- cerebellum and hippocampus shares convergent pathological pathways with ASD, including abnormal synaptic transmission, altered developmental processes and increased immune response. Furthermore, when directly compared to the repository of the SFARI database, our differentially expressed genes show enrichment of ASD-associated genes significantly higher than previously reported. Among the differentially expressed genes 20 were validated by quantitative PCR. Conclusions: Our results indicate the En2-/- mouse model of ASD as an appropriate tool to investigate molecular alterations related to ASD. En2-/- and WT cerebellar and hippocampal tissue from 3 littermates mice for each genotype was hybridized on three replicates microarrays.

Project description:Shank2 is an excitatory postsynaptic scaffolding protein strongly implicated in autism spectrum disorders (ASD). Shank2-mutant mice with a homozygous deletion of exons 6 and 7 show decreased NMDA receptor (NMDAR) functions and autistic-like behaviors in juvenile (~postnatal day or P21) and adult (> P56) stages that are rescued by NMDAR activation. These mice, however, show an opposite change increased NMDAR functions—at ~P14, and NMDAR suppression by early and chronic memantine treatment during P7–21 prevents NMDAR hypofunction and autistic-like behaviors at juvenile (~P21) and adult (~P56) stages. To explore molecular mechanisms underlying the long-lasting effects of early memantine treatment, we performed RNA-Seq analysis of forebrains from wild-type and Shank2-mutant mice early and chronically treated with vehicle or memantine. Memantine-treated Shank2-mutant mice showed upregulations of chromatin-related genes and downregulations of mitochondria- and ribosome-related genes. In addition, vehicle-treated Shank2-mutant mice showed transcriptomic patterns that are largely opposite to those observed in ASD, as supported by the expression patterns of ASD-risk/related genes and cell-type-specific genes. These patterns, likely representing compensatory changes, were weakened by early memantine treatment. These results suggest that early chronic memantine treatment in Shank2-mutant mice alters chromatin- and mitochondria/ribosome-related gene expressions and weakens anti-ASD transcriptomic patterns.

Project description:Arid1b is a chromatin remodeler implicated in neurodevelopmental disorders. Arid1b mutant mice with haploinsufficiency (Arid1b HT) displayed persistent excitatory synaptic dysfunction from juvenile to adult stage, decreased synaptic density and transmission. Moreover, they showed autistic-like behaviors in both of early and adult stages, decreased sociability in pup USV calling and adult social interaction, and adult repetitive grooming. To investigate early transcriptomic changes in Arid1b mutant mice, RNAseq analysis of prefrontal cortex from wild-type and Arid1b mutant mice at postnatal day 10 was done. Transcriptomic changes support these electrophysiological and behavioral deficits. Arid1b HT mice at postnatal day 10 showed alterations in genes implicated in synaptic functions and ASD.