Project description:NMDA (N-methyl-d-aspartate) receptor dysfunction is widely implicated in pathophysiology of autism spectrum disorder (ASD), a neurodevelopmental condition with a strong genetic basis. Here we investigated heterozygous mouse mutants carrying the ASD-linked C456Y mutation of Grin2b, a high-confidence ASD risk gene encoding the GluN2B subunit of the NMDA receptors. Comprehensive transcriptomic analyses across multiple brain regions and postnatal ages revealed large-scale gene expression changes, particularly in pathways related to oxidative phosphorylation and ribosome/translation, suggesting brain-wide alteration of energy metabolism and protein synthesis in Grin2b+/C456Y mice. Starting from transcriptomic evidence, we additionally discovered widespread splicing abnormalities, and impaired hippocampal neurogenesis in Grin2b mutants. Interestingly, the underlying genes and the spatial and temporal patterns of transcriptomic changes in Grin2b+/C456Y mice differed substantially from those observed in mutant mice lacking Grin2a, which encodes the GluN2A subunit of the NMDA receptor but is a schizophrenia risk gene. These findings underscore the distinct role of Grin2b in brain development and function and reveal potential mechanisms by which Grin2b loss of function may lead to neurodevelopmental disorders.

Project description:NMDA (N-methyl-d-aspartate) receptor dysfunction is widely implicated in pathophysiology of autism spectrum disorder (ASD), a neurodevelopmental condition with a strong genetic basis. Here we investigated heterozygous mouse mutants carrying the ASD-linked C456Y mutation of Grin2b, a high-confidence ASD risk gene encoding the GluN2B subunit of the NMDA receptors. Comprehensive transcriptomic analyses across multiple brain regions and postnatal ages revealed large-scale gene expression changes, particularly in pathways related to oxidative phosphorylation and ribosome/translation, suggesting brain-wide alteration of energy metabolism and protein synthesis in Grin2b+/C456Y mice. Starting from transcriptomic evidence, we additionally discovered widespread splicing abnormalities, and impaired hippocampal neurogenesis in Grin2b mutants. Interestingly, the underlying genes and the spatial and temporal patterns of transcriptomic changes in Grin2b+/C456Y mice differed substantially from those observed in mutant mice lacking Grin2a, which encodes the GluN2A subunit of the NMDA receptor but is a schizophrenia risk gene. These findings underscore the distinct role of Grin2b in brain development and function and reveal potential mechanisms by which Grin2b loss of function may lead to neurodevelopmental disorders.

Project description:To investigate the effect of Grin2a (a schizophrenia risk gene) and Grin2b (an autism spectrum disorder risk gene) loss of function on brain transcriptome. We performed unbiased transcriptomic profiling (bulk RNAseq analysis) in 5 brain regions and at four postnatal ages in Grin2a and Grin2b mutant mice.

Project description:Mutations in GRIN2B are associated with intellectual disability in humans. We generated iPSC derived mature cortical neurons with mutations in GRIN2B and compared them to isogenic control cells. We found that both loss of function (LOF) and reduced dosage (RD) mutations in GRIN2B lead to reduced expression of NMDAR genes and increased expression of marker of immaturity, including KI67 and MET.

Project description:Primary cortical neurons were isolated from E15 mice and after 5 days in vitro were untreated or treated for 24 h with mesenchymal stem cell conditioned medium and then untreated or treated for a further 24 h with NMDA. Neuron gene expression was profiled and compared between the four different conditions (neurons, neurons+MSC cm, neurons+NMDA, neurons+MSC cm+NMDA) to investigate the molecular mechanisms of MSC neuroprotection. Mesenchymal stem cells (MSC) promote functional recovery in experimental models of central nervous system (CNS) pathology and are currently being tested in clinical trials for stroke, multiple sclerosis and CNS injury. Their beneficial effects are attributed to activation of endogenous CNS repair processes and immune regulation but their mechanisms of action are poorly understood. Here we investigated the neuroprotective effects of MSC in simplified MSC-neuron co-culture systems and in mice using models of glutamate excitotoxicity. MSC protected primary cortical neurons against glutamate (NMDA) receptor-induced death and conditioned medium from MSC (MSC cm), but not control NIH3T3 cells, was sufficient for this effect. MSC cm neuroprotection in mouse cortical neurons was reduced by neutralizing antibodies to bFGF and associated with altered gene expression in neurons towards an immature phenotype as well as reduced neuronal Grin1, Grin2a and Grin2b mRNA levels in response to NMDA stimulation. Further, MSC cm neuroprotection in rat retinal ganglion cells was associated with absence of glutamate-induced calcium influx. Adoptive transfer of EGFP+MSC in a mouse kainic acid seizure model reduced CA3 neuron damage and hippocampal astrocytosis and resulted in the increased expression of neuronal genes that are upregulated by MSC cm, Bmi1, Ddx4, Ezh1, in the hippocampus. These results show that MSC mediate direct neuroprotection against glutamate excitotoxicity by secreting bFGF, reducing glutamate receptor expression and function and altering neuron gene expression towards an immature pattern, and provide evidence for a link between the therapeutic effects of MSC and the activation of endogenous repair processes following CNS injury. In vitro cultures primary cortical neurons from mice were protected from glutamate excitotoxicity when pre-treated with MSC cm. Global gene expression changes induced in neurons before and after treatment with MSC cm and/or NMDA were investigated using a cDNA spotted macroarray filter. Four samples were analysed in duplicate: neurons alone (untreated), neurons+MSC cm, neurons+NMDA, neurons+MSC cm+NMDA.

Project description:To identify which brain cell types are contributing to the bulk transcriptomic changes in Grin2a mutant mice, we performed single-nucleus RNAseq (snRNAseq) in Grin2a heterozygous and homozygous mutants and their wild-type littermates at 4 and 12 weeks of age.

Project description:SLC6A20A is a proline and glycine transporter known to regulate glycine homeostasis and NMDA receptor (NMDAR) function in the brain. A previous study on Slc6a20a-haploinsufficient mice reported increases in ambient glycine levels and NMDA receptor-mediated synaptic transmission in the brain, but whether Slc6a20a deficiency leads to disease-related behavioral deficits in mice remains unknown. Here, we report that Slc6a20a heterozygous and homozygous mutant mice display gene dosage-dependent behavioral phenotypes in locomotor, repetitive behavioral, and fear memory domains. In addition, Slc6a20a heterozygous and homozygous mutant brains showed transcriptomic changes in synapse, ribosome, and mitochondria-related genes as well as autism, epilepsy, and neuron-related genes. These results suggest that Slc6a20a deletion leads to gene dosage-dependent behavioral deficits in mice and transcriptomic changes in genes associated with synapse, ribosome, mitochondria, ASD, epilepsy, and neurons

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:Many autism spectrum disorder (ASD)-associated genes act as transcriptional regulators (TRs). ChIP-seq was used to identify the regulatory targets of ARID1B, BCL11A, FOXP1, TBR1, and TCF7L2, ASD-associated TRs in the developing human and mouse cortex. These TRs shared substantial overlap in the binding sites, especially within open chromatin. The overlap within a promoter region, 1-2,000bp upstream of transcription start site, was highly predictive of brain expressed genes. This signature was observed at 96 out of 102 ASD-associated genes. In vitro CRISPRi against ARID1B and TBR1 delineated downstream convergent biology in mouse cortical cultures. After eight days, NeuN+ and CALB+ cells were decreased, GFAP+ cells were increased, and transcriptomic signatures correlated with the postmortem brain samples from individuals with ASD. We suggest functional convergence across five ASD-associated TRs leads to shared neurodevelopmental outcomes of haploinsufficient disruption.