Project description:Individuals with disruptions in the Autism Susceptibility Candidate 2 (AUTS2) gene frequently exhibit symptoms like intellectual disability, microcephaly, growth retardation, and distinct skeletal and facial differences. The role of AUTS2 in neurodevelopment has been explored using animal models and in vitro embryonic stem cell models. However, the precise molecular mechanisms through which AUTS2 influences neurodevelopment, particularly in humans, are not thoroughly understood. To address this, our study employs a 3D human organoid culture system, in combination with genetic, genomic, cellular, and molecular approaches, to investigate how AUTS2 impacts neurodevelopment through cellular signaling pathways. We used CRISPR/Cas9 technology to create AUTS2-deficient human embryonic stem cells (hESCs), replicating a 190kb genetic deletion observed in a patient. These cells were then differentiated into cerebral organoids. Our single-cell RNA sequencing (scRNA-seq) analysis of these organoids indicates that the absence of AUTS2 results in a significant reduction in neuron-related cells and an increase in choroid plexus (ChP) epithelial cells. Notably, our research reveals that AUTS2 negatively regulates the Wnt/β-catenin signaling pathway, evidenced by the observed overactivation of this pathway in AUTS2-deficient organoids as well as in a luciferase reporter cell line with AUTS2 deletion. Importantly, treating the AUTS2-deficient cerebral organoids with a Wnt inhibitor ameliorated the abnormalities in neuronal differentiation. This study offers new insights into the role of AUTS2 in neurodevelopment and suggests new potential targeted therapies for NDDs.

Project description:Recent studies on Polycomb repressive complexes (PRC) reveal a surprising role in transcriptional activation, yet the underlying mechanism remains poorly understood. We previously identified a type 1 PRC (PRC1) that contains Autism Susceptibility Candidate 2 (AUTS2), which positively regulates transcription of neuronal genes. However, the mechanism by which the PRC1-AUTS2 complex influences neurodevelopment is unclear. Here we demonstrate that WDR68 is not only an integral component of the PRC1-AUTS2 complex, it is required for PRC1-AUTS2-mediated transcription activation. Furthermore, deletion of Wdr68 in mouse embryonic stem cells leads to defects in neuronal differentiation without affecting self-renewal. Through transcriptomic analysis, we found that many genes responsible for neuronal differentiation are down-regulated in Wdr68 deficient neural progenitors. These genes include several that are targeted by the PRC1-AUTS2 complex. In summary, our studies uncovered a previously unknown but essential component of the active PRC1 complex and evidence of its role in regulating the expression of genes that may be important for neuronal differentiation.

Project description:Naturally occurring variations of Polycomb Repressive Complex 1 (PRC1) comprise a core assembly of Polycomb group proteins and additional factors that include, surprisingly, Autism Susceptibility Candidate 2 (AUTS2). While AUTS2 is often disrupted in patients with neuronal disorders, the underlying mechanism is unclear. We investigated the role of AUTS2 as part of a previously identified PRC1 complex (PRC1-AUTS2), and in the context of neurodevelopment. In contrast to the canonical role of PRC1 in gene repression, PRC1-AUTS2 activates transcription. Biochemical studies demonstrate that the CK2 component of PRC1-AUTS2 thwarts PRC1 repressive activity and AUTS2-mediated recruitment of P300 leads to gene activation. ChIP-seq of AUTS2 shows that it regulates neuronal gene expression through promoter association. Conditional CNS targeting of Auts2 in a mouse model leads to various developmental defects. These findings reveal a natural means of subverting PRC1 activity, linking key epigenetic modulators with neuronal functions and diseases. mRNA profiles of P1 brain from wild type mice were generated by deep sequencing

Project description:Naturally occurring variations of Polycomb Repressive Complex 1 (PRC1) comprise a core assembly of Polycomb group proteins and additional factors that include, surprisingly, Autism Susceptibility Candidate 2 (AUTS2). While AUTS2 is often disrupted in patients with neuronal disorders, the underlying mechanism is unclear. We investigated the role of AUTS2 as part of a previously identified PRC1 complex (PRC1-AUTS2), and in the context of neurodevelopment. In contrast to the canonical role of PRC1 in gene repression, PRC1-AUTS2 activates transcription. Biochemical studies demonstrate that the CK2 component of PRC1-AUTS2 thwarts PRC1 repressive activity and AUTS2-mediated recruitment of P300 leads to gene activation. ChIP-seq of AUTS2 shows that it regulates neuronal gene expression through promoter association. Conditional CNS targeting of Auts2 in a mouse model leads to various developmental defects. These findings reveal a natural means of subverting PRC1 activity, linking key epigenetic modulators with neuronal functions and diseases. ChIP-seq experiments of PRC1 components, PolII as well as histone modifications were performed either in mouse whole brain or in human 293T-REx lines expressing FLAG/HA-tagged subunits. RNA-seq was performed to analyze the expression profile of mouse whole brain.

Project description:Naturally occurring variations of Polycomb Repressive Complex 1 (PRC1) comprise a core assembly of Polycomb group proteins and additional factors that include, surprisingly, Autism Susceptibility Candidate 2 (AUTS2). While AUTS2 is often disrupted in patients with neuronal disorders, the underlying mechanism is unclear. We investigated the role of AUTS2 as part of a previously identified PRC1 complex (PRC1-AUTS2), and in the context of neurodevelopment. In contrast to the canonical role of PRC1 in gene repression, PRC1-AUTS2 activates transcription. Biochemical studies demonstrate that the CK2 component of PRC1-AUTS2 thwarts PRC1 repressive activity and AUTS2-mediated recruitment of P300 leads to gene activation. ChIP-seq of AUTS2 shows that it regulates neuronal gene expression through promoter association. Conditional CNS targeting of Auts2 in a mouse model leads to various developmental defects. These findings reveal a natural means of subverting PRC1 activity, linking key epigenetic modulators with neuronal functions and diseases.

Project description:Naturally occurring variations of Polycomb Repressive Complex 1 (PRC1) comprise a core assembly of Polycomb group proteins and additional factors that include, surprisingly, Autism Susceptibility Candidate 2 (AUTS2). While AUTS2 is often disrupted in patients with neuronal disorders, the underlying mechanism is unclear. We investigated the role of AUTS2 as part of a previously identified PRC1 complex (PRC1-AUTS2), and in the context of neurodevelopment. In contrast to the canonical role of PRC1 in gene repression, PRC1-AUTS2 activates transcription. Biochemical studies demonstrate that the CK2 component of PRC1-AUTS2 thwarts PRC1 repressive activity and AUTS2-mediated recruitment of P300 leads to gene activation. ChIP-seq of AUTS2 shows that it regulates neuronal gene expression through promoter association. Conditional CNS targeting of Auts2 in a mouse model leads to various developmental defects. These findings reveal a natural means of subverting PRC1 activity, linking key epigenetic modulators with neuronal functions and diseases.

Project description:Polycomb group (PcG) proteins are evolutionarily conserved chromatin-modifying factors that regulate gene expression to control tissue development. We previously discovered an AUTS2?Polycomb complex activates gene expression by recruiting Casein kinase 2 (CK2) and P300. But the mechanisms underlying the recruitment of AUTS2-PRC1 to chromatin and the physiological relevance of AUTS2-P300 interaction during neurodevelopment remain unknown. Here, we report that the transcription factor Nuclear Respiratory Factor 1 (NRF1) physically interacts with AUTS2 and overlaps with AUTS2 on chromatin binding. In a functional study combined with the single cell RNA-seq approach, we demonstrate that NRF1 is required for AUTS2 recruitment to chromatin, ncPRC1 associated active transcription in motor neuron and thereby modulates multipotent progenitors to motor neuron differentiation. Moreover, we discover that mutations within AUTS2 HX repeat region, which associate with RSTS phenotype disrupt AUTS2-P300 interaction and AUTS2 mediated transcriptional activation. Together, these findings reveal the underlying mechanism by which the AUTS2-containing ncPRC1 complex is recruited and activates transcription and mutations in the AUTS2 HX repeat region exert a dominant negative effect on AUTS2-P300 mediated transcriptional activation in RSTS.

Project description:Molecular functions of the intellectual disability syndrome gene AUTS2 remain uncertain. Two mechanisms of Auts2 function have been proposed. One study found that Auts2 modifies Polycomb repressive complex 1 (PRC1) to activate transcription of target neurodevelopmental genes by recruiting EP300, a histone acetyltransferase. A second study found that cytoplasmic AUTS2 regulates cytoskeletal assembly through PREX1 to promote neurite outgrowth and migration. To further investigate Auts2 functions, we screened for AUTS2 interactors in cerebral cortex, and profiled changes of transcript expression in the developing cortex of Auts2 conditional mutant mice. AUTS2 immunoprecipitation experiments identified interactions with proteins involved in pre-mRNA processing, and mRNAs, including those encoding EP300 and PREX1, both bound by AUTS2-containing complexes and dysregulated in Auts2 mutant cortex. We propose that AUTS2 interacts with an RNA-binding complex that directly targets transcripts encoding Auts2 effectors. This mechanism provides a unifying model that accounts for previously disparate hypotheses of AUTS2 functions.

Project description:This SuperSeries is composed of the following subset Series: GSE36950: SNP array for CNV calling AUTS2 project [Affymetrix] GSE37141: Oligo array for CNV calling AUTS2 project [Agilent] GSE37142: SNP array for CNV calling AUTS2 project [Illumina] GSE37654: Oligo array for calling CNV's for AUTS2 project [NimbleGen] GSE37656: Oligo array for CNV calling AUTS2 project [Bluegnome] Refer to individual Series

Project description:AUTS2 was originally discovered as the gene disrupted by a translocation in human twins with Autism spectrum disorder (ASD), intellectual disability, and epilepsy. Since that initial finding, AUTS2-linked mutations and variants have been associated with a very broad array of neuropsychiatric disorders, suggesting that AUTS2 is required for fundamental steps of neurodevelopment. However, genotype-phenotype correlations in this region are complicated, because most mutations could also involve neighboring genes. Of particular interest in this regard is the nearest downstream neighbor of AUTS2, GALNT17, encoding a brain-expressed N-acetylgalactosaminyltransferase of unknown brain function. Here we describe a mouse (Mus musculus) mutation, T(5G2;8A1)GSO (abbreviated 16Gso), a reciprocal translocation that breaks between Auts2 and Galnt17 and dysregulates both genes. Despite this complex regulatory effect, 16Gso homozygotes model certain human AUTS2-linked phenotypes very well. In addition to abnormalities in growth, craniofacial structure, learning and memory, and behavior, 16Gso homozygotes display distinct pathologies of the cerebellum and hippocampus that are similar to those associated with ASD and other types of neurological disease associated with this genomic region. Analyzing the mutant cerebellar and hippocampal transcriptomes, we identified disturbances in pathways related to neurite and synapse maturation, neurotransmitter signaling, and cellular stress, suggesting possible cellular mechanisms for 16Gso phenotypes. These pathways, coupled with the translocation’s selective effects on Auts2 isoforms and coordinated dysregulation of Galnt17, suggest novel hypotheses regarding the etiology of the human “AUTS2 syndrome” and the wide array of neurodevelopmental disorders linked to variance in this genomic region.