Project description:The establishment of neural circuits depends on precise neuronal positioning in the cortex, a tightly coordinated process of neuronal differentiation, migration and terminal localization. Deficit in this process is implicated in several psychiatric disorders. Here, we show that the transcription factor Tcf4 controls neuronal positioning during brain development. Tcf4-deficient neurons become mispositioned in clusters when their migration to the cortical plate is complete. We reveal that Tcf4 regulates the expression of cell adhesion molecules to control neuronal positioning. Furthermore, through in vivo extracellular electrophysiology, we show that neuronal functions are disrupted after the loss of Tcf4. TCF4 mutations are strongly associated with schizophrenia and cause Pitt-Hopkins syndrome, which is characterized by severe intellectual disability. Thus, our results not only reveal the importance of neuronal positioning in brain development and but also provide new insights into the potential mechanisms underlying neurological defects linked to TCF4 mutations.

Project description:Haplo-insufficiency of TCF4 induced by mutations or microdeletion of TCF4 gene causes Pitt-Hopkins Diseases. Recent gene association studies revealed that mutations of TCF4 is significantly associated with schizophrenia. But the role of TCF4 in developing neocortex is not known. The goal of this study is to identify TCF4 itranscriptional regulatory pathways in developing neocortex by analyzing transcriptomes of dorsal telencephalons of TCF4knockout, TCF4Heterozygote and WT littermates and comparing differential expressed genes between these genotypes.

Project description:TCF4 is an important neurodevelopmental transcription factor associated with schizophrenia and Pitt-Hopkins syndrome. In this study, we used genome-wide expression profiling to determine the effects of acute TCF4 knockdown on gene expression in SH-SY5Y neuroblastoma cells. Pathway and enrichment analysis on the differentially expressed genes in TCF4-knockdown cells identified an over-representation of genes involved in TGF-β signaling, epithelial-to-mesenchymal transition (EMT) and apoptosis. Among the most significantly differentially expressed genes were the EMT regulators SNAI2 and DEC1 and the proneural genes NEUROG2 and ASCL1. Altered expression of several mental retardation genes such as UBE3A (AS), ZEB2 (MWS) and MEF2C was also found in TCF4-depleted cells. These data suggest that TCF4 regulates a number of convergent signaling pathways involved in cell differentiation and survival in addition to a subset of clinically important mental retardation genes.

Project description:The bHLH transcription factor TCF4 plays an important role in neurodevelopment highlighted by its association with schizophrenia and Pitt-Hopkins-Syndrome. Here we demonstrate that TCF4 function is essential for forebrain commissure formation in mice. Single-cell RNA sequencing of TCF4 knockout neocortices revealed dysregulation of multiple gene regulatory networks. We provide evidence that TCF4 controls the underlying regulons by interaction with the regulators, transcription factors surprisingly not belonging to the known canonical interactors of the bHLH family. In-depth analysis of the interplay between TCF4 and SOX11 showed a synergistic effect on commissural formation. Mice haploinsufficient for Sox11 or Tcf4 showed no commissural phenotype or only a mild callosal shortening, respectively, whereas Tcf4/Sox11 double haploinsufficient mice display aggravated corpus callosum dysgenesis and anterior commissure agenesis. Moreover, TCF4 and SOX11 synergistically induce the expression of common target genes. Collectively, these findings illuminate how TCF4 dysregulation influences brain development and contributes to neurodevelopmental diseases.

Project description:We evaluate cellular phenotypic abnormalities and alterations in molecular pathways due to mutations in the gene TCF4 in cells derived from Pitt-Hopkins patients, in comparison with respective controls (parents).

Project description:We evaluate cellular phenotypic abnormalities and alterations in molecular pathways due to mutations in the gene TCF4 in cells derived from Pitt-Hopkins patients, in comparison with respective controls (parents).

Project description:We evaluate cellular phenotypic abnormalities and alterations in molecular pathways due to mutations in the gene TCF4 in cells derived from Pitt-Hopkins patients, in comparison with respective controls (parents).

Project description:We evaluate cellular phenotypic abnormalities and alterations in molecular pathways due to mutations in the gene TCF4 in cells derived from Pitt-Hopkins patients, in comparison with respective controls (parents).

Project description:TCF4 is an important neurodevelopmental transcription factor associated with schizophrenia and Pitt-Hopkins syndrome. In this study, we used genome-wide expression profiling to determine the effects of acute TCF4 knockdown on gene expression in SH-SY5Y neuroblastoma cells. Pathway and enrichment analysis on the differentially expressed genes in TCF4-knockdown cells identified an over-representation of genes involved in TGF-β signaling, epithelial-to-mesenchymal transition (EMT) and apoptosis. Among the most significantly differentially expressed genes were the EMT regulators SNAI2 and DEC1 and the proneural genes NEUROG2 and ASCL1. Altered expression of several mental retardation genes such as UBE3A (AS), ZEB2 (MWS) and MEF2C was also found in TCF4-depleted cells. These data suggest that TCF4 regulates a number of convergent signaling pathways involved in cell differentiation and survival in addition to a subset of clinically important mental retardation genes. To identify TCF4-mediated gene expression changes in SH-SY5Y cells, experiments were conducted with two control (mock and GAPDH KD) and two TCF4 knockdown (KD1 and KD2) groups. Two non-overlapping siRNAs against TCF4 were designed and transfected over a 72h period to induce global knockdown of TCF4 transcripts. In parallel, cells were mock transfected (mock; transfection reagent only) and transfected with an unrelated siRNA against GAPDH (GAPDH KD) in order to control for background gene expression changes due to transfection, presence of dsRNA and activation of the cellular silencing machinery. After transfection, RNA was extracted from all cells, converted to cDNA and labelled for microarray hybridization. Each of the four treatment groups (mock, GAPDH KD, KD1 and KD2) contained three biological replicates which were processed at the same time using the Toray microarray platform.

Project description:Common genetic variants in and around the gene encoding transcription factor 4 (TCF4) are associated with an increased risk of schizophrenia whereas rare variants have been found in patients with intellectual disability (ID), developmental disorders and autism spectrum disorder (ASD). Haploinsufficiency of TCF4 also causes Pitt Hopkins syndrome (PTHS); a condition characterized by developmental delay, ID and autonomic dysfunction. To understand the role of TCF4 in these disorders, we have used chromatin immunoprecipitation and next generation sequencing (ChIP-seq) to identify the genomic binding sites for TCF4. In this study we identify 10,604 binding sites assigned to 5,437 genes. De novo motif enrichment found that approximately 77% of the TCF4 binding sites contained at least one E-box (5’-CAtcTG). Furthermore, the majority of TCF4 binding sites overlapped with H3K27ac histone mark for active enhancers. Enrichment analysis on the set of TCF4 targets identified numerous, highly significant functional clusters for pathways including nervous system development, ion transport and signal transduction and co-expression modules for genes associated with synaptic function and brain development. Importantly, we found that genes harboring de novo mutations in schizophrenia (P < 5.3 x 10-7), ASD (P < 2.5 x 10-4) and ID (P < 7.6 x 10-3) were also enriched among TCF4 targets. These data demonstrate that TCF4 binding sites are found in a large number of neuronal genes that include genetic risk factors for common neurodevelopmental disorders.