Project description:Govek et al. demonstrate conditional loss of Cdc42 in cerebellar granule cell progenitors (GCPs) perturbs GCP polarity and impairs axon patterning, glial-guided migration, and cerebellar foliation. Phospho-proteomic analysis identified polarity and cytoskeletal proteins as affected targets in Cdc42 deficient GCPs.

Project description:Regulation of chromatin plays fundamental roles in the normal development of the brain. Haploinsufficiency of the chromatin remodeling enzyme CHD7 causes CHARGE syndrome, a genetic disorder that prominently affects the development of the cerebellum. However, how CHD7 controls chromatin states in the cerebellum remains incompletely understood. Using conditional knockout of CHD7 in granule cell precursors in the mouse cerebellum, we find that CHD7 robustly promotes the accessibility and activity of enhancers in granule cell precursors. Remarkably, in vivo profiling of genome architecture reveals that CHD7 operates locally to stimulate enhancer activation, thereby driving the expression of topologically-interacting genes. Genome and gene ontology studies show that CHD7-regulated enhancers are associated prominently with genes that control brain tissue morphogenesis. Accordingly, conditional knockout of CHD7 triggers a striking phenotype of cerebellar polymicrogyria, which we have also found in a case of CHARGE syndrome. Finally, we uncover a CHD7-dependent switch in the preferred orientation of granule cell precursor division in the developing cerebellum, providing a cellular basis for the cerebellar polymicrogyria phenotype upon loss of CHD7. Collectively, our findings define CHD7 function in the regulation of the epigenome in granule cell precursors and identify a surprising link of CHD7 to the control of cerebellar cortical morphogenesis, with potential implications for our understanding of CHARGE syndrome.

Project description:During cerebellar development, maternal granule cell progenitors (GCPs) divide to produce not only postmitotic granule cells (GCs) but also sister GCPs. However, molecular machinery to proportionally produce distinct sister cell types from seemingly uniform GCPs is still elusive. Here we report Notch signaling makes a difference among GCPs, leading to their proportional differentiation.

Project description:Most human cancers arise from stem/progenitor cells by sequential accumulation of genetic/epigenetic alterations, while cancer modeling typically requires simultaneous multiple oncogenic events. Here we show that a single p53 mutation, despite causing no defect in mouse brain, promoted neural stem/progenitor cells to spontaneously accumulate oncogenic alterations, including loss of multiple chromosomal (chr) regions syntenic to human chr10 containing Pten, forming malignant gliomas/glioblastomas with PI3K/Akt activation. Rictor/mTORC2 loss inhibited Akt signaling, greatly delaying and reducing glioma formation by suppressing glioma precursors within the subventricular zone stem-cell niche. Unexpectedly, Rictor/mTORC2 loss delayed timely differentiation of granule cell precursors (GCPs) during cerebellar development, promoting sustained GCP proliferation and medulloblastoma formation, which recapitulated critical features of TP53-mutant Sonic Hedgehog (SHH) medulloblastomas with GLI2 and/or N-MYC amplification. Our study demonstrates that Rictor/mTORC2 has opposing functions in neural stem cells and GCPs in the adult and developing brain, promoting malignant gliomas/glioblastoma and suppressing SHH-medulloblastoma formation, respectively.

Project description:The main cell of origin of the Sonic hedgehog (SHH) subgroup of medulloblastoma (MB) is granule cell precursors (GCPs), a SHH-dependent transient amplifying population in the developing cerebellum. SHH-MBs can be further subdivided based on molecular and clinical parameters, as well as location since SHH-MBs occur preferentially in the lateral cerebellum (hemispheres). Our analysis of adult patient data suggests that tumors with Smoothened (SMO) mutations form more specifically in the hemispheres than those with Patched 1 (PTCH1) mutations. Using sporadic mouse models of SHH-MB with the two mutations commonly seen in adult MB, constitutive activation of Smo (SmoM2) or loss-of-Ptch1, we found that regardless of timing of induction or type of mutation, tumors developed primarily in the hemispheres with SmoM2-mutants indeed showing a stronger specificity. We further uncovered that GCPs in the hemispheres are more susceptible to high level SHH signaling compared to GCPs in the medial cerebellum (vermis), as more SmoM2 or Ptch1-mutant hemisphere cells remain undifferentiated and show increased tumorigenicity when transplanted. Finally, we identified location-specific GCP gene expression profiles, and found that deletion of the genes most highly expressed in the hemispheres (Nr2f2) or vermis (Engrailed1) showed opposing effects on GCP differentiation. Our studies thus provide new insights into intrinsic differences within GCPs that impact on SHH-MB progression.

Project description:To determine if changes in Protein Disulfide Isomerase (PDIA1) expression in mice with a null Reelin allele were caused by accumulation of intracellular Reelin or were an effect of reduced Reelin protein, we examined expression of PDIA1 and other stress markers in heterozygous RELN +/- null allele mice. The levels of PDIA1 as well as PERK, BIP, phospho-eIF2alpha and total eIF2alpha were unchanged between wild-type and RELN +/- null allele mice. This suggested that there are phenotypic differences in the cerebella between mice that carry a RELN allele that fails to produce a protein (null allele) and those that make a protein that fails to be secreted (Orl allele). Each of the three major ER stress pathways ultimately leads to changes in gene transcription. Thus, we compared wild-type and heterozygous RELN Orl +/- mice cerebellum by RNAseq. Analysis was performed on 3 heterozygous (HET) and 3 wild-type (WT) cerebella, obtained from 6-week old male mice.

Project description:Schizophrenia is a severe psychiatric disorder with a strong hereditary component that affects approximately 1% of the world’s population. The disease is most likely caused by the altered expression of a number of genes that function at the level of biological pathways or gene networks. Transcription factors (TF) are indispensable regulators of gene expression. EGR3 is a TF associated with schizophrenia. In the current study, DNA microarray and ingenuity pathway analyses (IPA) demonstrated that EGR3 regulates Reelin signaling pathway in SH-SY5Y cells. ChIP and luciferase reporter studies confirmed that EGR3 directly binds to the promoter region of RELN thereby activating RELN expression. Both the expression of EGR3 and RELN were decreased during neuronal differentiation induced by retinoic acid (RA) in SH-SY5Y cells, and EGR3 overexpression reduced neurite outgrowth which could be partially reversed by the knockdown of RELN. The expression levels of EGR3 and RELN in peripheral blood of patients with schizophrenia were found to be downregulated (compared to healthy controls), and were positively correlated. Furthermore, data mining from public databases revealed that the expression levels of EGR3 and RELN were presented a positive correlation in postmortem brain tissue of schizophrenic individuals. Taken together, the current study suggests that EGR3 is a novel TF of the RELN gene and regulates neurite outgrowth via Reelin signaling pathway. Our findings contribute to the understanding of the regulatory role of EGR3 in the pathophysiology and molecular mechanisms of schizophrenia, and potentially to the development of new therapies and diagnostic biomarkers for the disorder.

Project description:We mapped the binding sites of Chd7 in cerebellar granule cells, and compared with the pattern of H3K27ac. To examine the impact of Chd7 loss to Top2b binding, we mapped the binding sites of Top2b in control and Chd7 mutant cells

Project description:Gene expression data from mouse cerebellar tumors generated using CRISPR/Cas9 technology to disrupt Ptch1 and Chd7 in the embryonic cerebellum of Chd7 fl/+ mice by in utero electroporation.

Project description:Brain development is regulated by conserved transcriptional programs across species, but little is known about divergent mechanisms that create species-specific characteristics. Among brain regions, the cerebellum is now recognized to contribute to human cognitive evolution having a broad range of non-motor cognitive functions in addition to motor control. Emerging studies highlight the complexity of human cerebellar histogenesis, compared with non-human primates and rodents, making it important to develop methods to generate human cerebellar neurons that closely resemble those in the developing human cerebellum. Here we report a rapid and simple protocol for the directed derivation of the human ATOH1 lineage, the precursor of all excitatory cerebellar neurons, from human pluripotent stem cells (hPSC), and strategies to decrease culture variability; a common limitation in hPSC studies. Upon transplantation into juvenile mice, early postmitotic hPSC-derived cerebellar granule cells migrated along glial fibers and integrated into the cerebellar cortex. By Translational Ribosome Affinity Purification (TRAP)-seq, the ATOH1 lineage most closely resembled human cerebellar tissue in the second trimester. Unexpectedly, TRAP-seq identified a heterochronic shift in the expression of RBFOX3 (NeuN) and NEUROD1, which are classically associated with differentiated neurons, within granule cell progenitors (GCPs) in the human external granule layer. This molecular divergence may provide the mechanism by which the GCP pool persists into year two post birth in humans, but only lasts for two weeks in mice. Our approach provides a scalable in vitro model of the human ATOH1 lineage that yields cerebellar granule cells within 48 days as well as a strategy for identifying uniquely human cellular and molecular characteristics.