Project description:Autism spectrum disorder (ASD) is a neurodevelopmental disorder with diverse genetic and environmental origins, yet whether these factors converge on common molecular pathways remains unclear. This study identifies dysregulation of the Notch signaling pathway as a shared mechanism in both hereditary and nonhereditary ASD models. Aberrant histone deacetylase 3-mediated epigenetic regulation of Notch signaling during embryonic forebrain development disrupts the specification of caudal ganglionic eminence (CGE) progenitors into vasoactive intestinal peptide (VIP+) GABAergic interneuron subtypes (VIP-INs). CGE-specific ablation of Notch1/2 genes in ASD models restores the loss of VIP-INs, normalizes maladaptive excitatory and inhibitory balance, and selectively improves social behaviors. Remarkably, a single antenatal dose of a γ-secretase inhibitor ameliorates multiple ASD-associated neuronal, behavioral, and transcriptomic changes in adult models. The study indicates a strong convergence of ASD-related factors on Notch signaling dysregulation and establishes this pathway as a promising therapeutic target for developmental and behavioral deficits in ASD.

Project description:Autism spectrum disorder (ASD) is a neurodevelopmental disorder characterized by social deficits and repetitive behaviors, influenced by both genetic and environmental factors. However, the molecular mechanisms underlying this heterogeneity remain unclear. This study highlights dysregulation of the Notch signaling pathway as a shared molecular mechanism in inherited and non-hereditary ASD models in mice and humans. Aberrant HDAC3-mediated epigenetic activation of Notch signaling during embryonic forebrain development disrupts the specification of caudal ganglionic eminence (CGE) precursors into VIP+ GABAergic interneuron subtypes (VIP-INs). CGE-specific ablation of Notch1/2 genes in ASD models rescues the VIP-IN loss, E/I balance, and selectively improves social behaviors. Remarkably, a single antenatal dose of a γ-secretase inhibitor, previously used in the clinical trials for cancer treatment, effectively ameliorates multiple ASD-associated neuronal, behavioral, and transcriptomic levels in adult models. Thus, the study confers a critical convergence of ASD risk factors on Notch signaling dysregulation and establishes this pathway as a promising therapeutic target for developmental and behavioral deficits in ASD.

Project description:Autism spectrum disorders (ASDs) are a neurodevelopmental disorder characterized by impairments in social interactions and stereotyped behaviors. While ASD has a strong genetic background, environmental factors including toxins, pesticides, infection and drugs are also known to confer autism susceptibility, likely by inducing epigenetic changes. Exposure to Valproic acid (VPA), a drug for epilepsy and bipolar disorders, during pregnancy is highly associated with the risk of ASD children. In rodents, in utero VPA exposure can precipitate behavioral phenotypes related to ASD in the offspring. Since VPA is an inhibitor of histone deacethytransferase (HDAC) activity, it thought to cause ASD with epigenetic modification. However, the core mechanism by which prenatal VPA exposure causes onset of ASD is still not fully uncovered. Here we revealed that prenatal VPA exposure strongly influences development of vasoactive intestinal peptide (VIP) - positive neurons, a subtype of cortical GABAergic interneurons. The number of VIP+ interneurons was severely reduced in somatosensory area of VPA-exposed ASD animals. We then found that the reduction in VIP+ interneurons is caused by the inhibition of HDAC3 activity upon prenatal VPA exposure. Importantly, prenatal HDAC3 inhibition caused not only the selective reduction in VIP+ interneurons but also the ASD-like behaviors in mice. We then demonstrated that the HDAC3 inhibition aberrantly activates Notch signaling, which influences the cell fate determination of VIP+ interneuron progenitors in caudal ganglionic eminence. Thus, this study uncovers the mechanism by which specific HDAC inhibition during development influences a specific type of GABAergic interneurons in the ASD model. The findings provide a novel insight into the understanding of ASD pathophysiology.

Project description:Autism Spectrum Disorder (ASD) presents a wide, and often varied, behavioral phenotype. Impulsivity and improper assessment of risks has been widely reported among individuals diagnosed with ASD. However, there is little knowledge of the molecular underpinnings of the impaired risk-assessment phenotype. In this study, we have identified impaired risk-assessment activity in multiple male ASD mouse models. By performing network-based analysis of striatal whole transcriptome data from each of these ASD models, we have identified a cluster of glutamate receptor–associated genes that correlate with the risk-assessment phenotype. Furthermore, pharmacological inhibition of striatal glutamatergic receptors was able to mimic the dysregulation in risk-assessment. Therefore, this study has identified a molecular mechanism that may underlie impulsivity and risk-assessment dysregulation in ASD.

Project description:Developmental exposure to environmental pollutants is increasingly recognized as a significant risk factor for autism spectrum disorder (ASD), yet the specific mechanisms by which individual toxicants contribute to this neurodevelopmental disorder remain largely unknown. Methyl ester sulfonate (MES), a widely used anionic surfactant with widespread environmental detection, lacks comprehensive evaluation for developmental neurotoxicity. Here, we exposed pregnant mice to environmentally relevant MES doses (0.06–6 mg/L) from gestational day 8.5 (GD8.5) to postnatal day 21.5 (PND21.5) and assessed their offspring for neurodevelopmental changes. Results showed dose-dependent ASD-like behavioral deficits, including impaired social interactions, heightened anxiety-like behaviors, and increased repetitive/stereotypic patterns. These behavioral anomalies were accompanied by neuropathological alterations, including blood-brain barrier (BBB) disruption, neuronal loss, and reduced dendritic spine density, indicative of impaired synaptogenesis. Integrative transcriptomic analysis of hippocampal tissue revealed significant dysregulation of key pathways involved in neurodevelopment, prominently featuring the Notch/Hes signaling pathway. Molecular docking simulations suggested that MES could directly interactwith Notch receptors, potentially disrupting ligand-receptor interactions. Further in vitro experimental validation demonstrated that MES exposure suppressed neural stem cell differentiation. Collectively, these findings provided evidence that early-life MES exposure acts as a neurodevelopmental toxicant by disrupting Notch/Hes signaling, thereby impairing neuronal differentiation and synaptogenesis, which underlied the observed ASD-like behavioral deficits in mice. This study offers novel mechanistic insights into how environmental factors contribute to ASD pathogenesis and highlights the need for toxicological assessment of widely distributed surfactants.

Project description:Neocortical circuits consist of stereotypical motifs that must self-assemble during development. Recent evidence suggests the subtype identity of both excitatory projection neurons (PNs) and inhibitory interneurons (INs) is important for this process. We knocked out the transcription factor Satb2 in PNs to induce those of the intratelencephalic (IT)-type to adopt a pyramidal tract (PT)-type identity. Loss of IT-type PNs selectively disrupted the lamination and circuit integration of INs derived from the caudal ganglionic eminence (CGE). Strikingly, reprogrammed PNs demonstrated reduced synaptic targeting of CGE-derived INs relative to controls. In control mice, IT-type PNs targeted neighboring CGE INs while PT-type PNs did not in deep layers, confirming this lineage-dependent motif. Finally, single cell RNA-sequencing revealed that major CGE IN subtypes were conserved after loss of IT PNs, but with differential transcription of synaptic proteins and signaling molecules. Thus, IT-type PNs influence CGE-derived INs in a non-cell autonomous manner during cortical development.

Project description:Proper regulation of the proliferation and differentiation of radial glia (RG), the neural stem cells of the developing cortex, is fundamental for brain growth and organization. In humans, a specialized RG subtype, the outer radial glia (oRG), are abundant and give rise to diverse neuronal and glial progeny. However, the mechanisms regulating oRG development and differentiation are not fully understood. Here we investigated the regulation of oRG expansion and lineage potential by perturbing Leukemia Inhibitory Factor (LIF) signaling in the developing human cortex and in human pluripotent stem cell (PSC)-derived cortical organoids. LIF receptors are specifically expressed in oRG cells during neurogenesis, and, consistent with the previously described role of this cytokine as an activator of stem cell self-renewal, LIF treatment increased the number of oRG cells. Surprisingly, LIF treatment also increased the production of inhibitory interneurons (INs) in the cortex. Comparative transcriptomic analysis suggested that these INs resemble INs produced in the caudal ganglionic eminence (CGE). To test if oRG cells are the progenitors of these CGE-like INs, we isolated oRG cells from primary developing cortex and cultured them for several weeks with and without LIF treatment. We found that CGE-like INs were produced by oRG cells, and their abundance is increased by LIF treatment. Together, these observations suggest that LIF signaling regulates oRG lineage potential and capacity to generate CGE-like INs.

Project description:Synaptic dysfunction represents a key pathophysiology in neurodevelopmental disorders such as autism spectrum disorder (ASD). Rare mutation R451C in human Neuroligin 3 (NLGN3, encoded by X-linked gene NLGN3), a cell adhesion molecule essential for synapse formation, has been linked to ASD. Despite success in recapitulating the social interaction behavioral deficits and the underlying synaptic abnormalities in mouse model, the impact of NLGN3 R451C on the human neuronal system remains elusive. Here, we generated isogenic knock-in human pluripotent stem cell lines harboring NLGN3 R451C allele and examined its impact on synaptic transmission. Analysis of co-cultured excitatory and inhibitory induced neurons (iNs) with mutation revealed an augmentation in excitatory synaptic strength comparing to isogenic control, but not in inhibitory synaptic transmission. Consistently, the augmentation in excitatory transmission was confirmed in iNs transplanted into mouse forebrain. Using single-cell RNA seq on co-cultured excitatory and inhibitory iNs, we identified differential expression genes (DEGs) and found NLGN3 R451C alters gene networks associated with synaptic transmission. Gene ontology and enrichment analysis revealed convergent gene networks associated with ASD and other mental disorders. Our finding suggests that the NLGN3 R451C mutation could preferentially impact excitatory neurons, which causes overall network properties changes and excitation-inhibition imbalance related to mental disorders.

Project description:The screening of putative candidate genes downstream of IL7R-INS in vitro KSL/CLP and in vivo (depicted as B-neoplasm, Notch-T-ALL, or myeloid disorder) in comparison to WT. Five-condition experiment: WT-KSL vs. INS-KSL cells; WT-CLP vs.INS-CLP; WT/ICN vs. INS/ICN; WT-CMP vs. INS-CMP. Biological replicate: each 1, One replicate per array.

Project description:Whole-exome sequencing studies have implicated chromatin modifiers and transcriptional regulators in autism spectrum disorder (ASD) through the identification of de novo loss of function mutations in affected individuals. Many of these genes are co-expressed in mid-fetal human cortex, suggesting ASD risk genes converge in regulatory networks that are perturbed in ASD during neurodevelopment. To elucidate such networks we mapped promoters and enhancers bound by the chromodomain helicase CHD8, which is strongly enriched in ASD-associated de novo loss of function mutations, using ChIP-seq in mid-fetal human brain, human neural stem cells (hNSCs), and embryonic mouse cortex. We find that CHD8 targets are strongly enriched for ASD risk genes that converge in ASD-associated co-expression networks in human midfetal cortex. CHD8 knockdown in hNSCs results in significant dysregulation of ASD risk genes targeted by CHD8, as well as additional genes important for neurodevelopment, including members of the Wnt/M-NM-2-catenin signaling pathway. Integration of CHD8 binding data with genetic and gene co-expression data in ASD risk models provides support for additional ASD risk genes. Together, our results suggest that loss of CHD8 function contributes to ASD through regulatory perturbation of other ASD risk genes during human cortical development. Two biological replicates for each ChIP with appropriate Input control Four biological replicates for each condition in knockdown experiments (Ctrl construct, Chd8 target C, and Chd8 target G)