Project description:We report using a single-cell transcriptomic study of cerebral organiods (COs) developed from WA09 hESCs with gene editing-induced NGLY1 mutations and from NGLY1-deficient patient's hiPSCs at 40 or 80 days of development. WA09 hESC-derived COs with and without mutant NGLY1 and patient's hiPSC-derived COs with and without the ectopic expression NGLY1 were analyzed.

Project description:Thiele2013 - Cerebral cortex neuronal cells The model of cerebral cortex neuronal cells metabolism is derived from the community-driven global reconstruction of human metabolism (version 2.02, MODEL1109130000 ). This model is described in the article: A community-driven global reconstruction of human metabolism. Thiele I, et al . Nature Biotechnology Abstract: Multiple models of human metabolism have been reconstructed, but each represents only a subset of our knowledge. Here we describe Recon 2, a community-driven, consensus 'metabolic reconstruction', which is the most comprehensive representation of human metabolism that is applicable to computational modeling. Compared with its predecessors, the reconstruction has improved topological and functional features, including ~2x more reactions and ~1.7x more unique metabolites. Using Recon 2 we predicted changes in metabolite biomarkers for 49 inborn errors of metabolism with 77% accuracy when compared to experimental data. Mapping metabolomic data and drug information onto Recon 2 demonstrates its potential for integrating and analyzing diverse data types. Using protein expression data, we automatically generated a compendium of 65 cell type-specific models, providing a basis for manual curation or investigation of cell-specific metabolic properties. Recon 2 will facilitate many future biomedical studies and is freely available at http://humanmetabolism.org/. This model is hosted on BioModels Database and identified by: MODEL1310110033 . To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models . To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:Neuronal development in NEIL3-deficient mice (hippocampus)

Project description:Histone deacetylase 3 (HDAC3) is a unique epigenetic regulator forming stoichiometric complexes with several other proteins. Patients with mutations in genes encoding these proteins display intellectual disability, implying an important role of HDAC3 in this prevalent disease. Here we report that cerebrum-specific inactivation of the mouse gene causes striking developmental defects in the neocortex, hippocampus and corpus callosum; post-weaning lethality; and abnormal behaviors, including hyperactivity and anxiety. The developmental defects are due to rapid loss of neural stem and progenitor cells (NSPCs), starting at E14.5. Premature neurogenesis and abnormal neuronal migration in the mutant brain alter NSPC homeostasis. Mutant cerebral cortices display augmented DNA damage, apoptosis, and histone hyperacetylation. In agreement with these results, mutant NSPCs are impaired in forming neurospheres in vitro, and treatment of wild-type NSPCs with the HDAC3-specific inhibitor RGFP966 abolishes neurosphere formation. Transcriptomic analyses of neonatal cerebral cortices and cultured neurospheres support that HDAC3 regulates various transcriptional programs through interaction with multiple transcription factors, including NFIB. These findings establish HDAC3 as a major deacetylase critical for perinatal development of the mouse cerebrum and NSPCs, thereby suggesting a direct link of this enzymatic epigenetic regulator to human cerebral and intellectual development. To study the impact of cerebrum specific (Emx1-Cre) deletion of Hdac3 on embryonic neurospheres (cultured in vitro from E16.5 cerebrum) and neocortex from newborn pups (P0).

Project description:Neuronal development in NEIL3-deficient mice (hippocampus) [CA1]

Project description:neuronal development in NEIL3-deficient mice (hippocampus) [DG]

Project description:Neuronal development in NEIL3-deficient mice (hippocampus) [CA3]

Project description:Multiple sclerosis (MS) affects the cerebral cortex, inducing cortical atrophy and neuronal and synaptic pathology. Despite the fact that women are more susceptible to getting MS, men with MS have worse disability progression. Here, we address sex differences in neurodegenerative mechanisms focusing on the cerebral cortex using the MS model, chronic experimental autoimmune encephalomyelitis (EAE). RNA sequencing of neurons in cerebral cortex during EAE showed robust differential gene expression in male EAE mice compared to male healthy, age-matched, control mice. In contrast, there were few differences in female EAE mice compared to female controls. The most enriched differential gene expression pathways in male mice during EAE were mitochondrial dysfunction and oxidative phosphorylation. Mitochondrial morphology showed significant abnormalities in the cerebral cortex of EAE males, but not EAE females. Regarding function, synaptosomes isolated from cerebral cortex of male EAE mice demonstrated decreased oxygen consumption rates during respirometry assays. Together, cortical neuronal transcriptomics, mitochondrial morphology, and functional respirometry assays in synaptosomes revealed worse neurodegeneration in male EAE mice. This is consistent with worse neurodegeneration in MS men and reveals a model and a target to develop treatments to prevent cortical neurodegeneration and mitigate disability progression in MS men.

Project description:Malformations of the human cortex represent a major cause of disability. Mouse models with mutations in known causal genes only partially recapitulate the phenotypes and are therefore not unlimitedly suited for understanding the molecular and cellular mechanisms responsible for these conditions. Here we study periventricular heterotopia (PH) by analyzing cerebral organoids derived from induced pluripotent stem cells of patients with mutations in the cadherin receptor-ligand pair DCHS1 and FAT4 or from isogenic knock-out lines. Our results show that human cerebral organoids reproduce the cortical heterotopia associated with PH. Mutations in DCHS1 and FAT4 or knock-down of their expression cause changes in the morphology of neural progenitor cells and result in defective neuronal migration dynamics only in a subset of neurons. Single-cell RNA-sequencing data reveal a subpopulation of mutant neurons with dysregulated genes involved in axon guidance, neuronal migration and patterning. We suggest that defective neural progenitor cell (NPC) morphology and an altered navigation system in a subset of neurons underlie this form of periventricular heterotopia.

Project description:The neuronal ceroid lipofuscinoses (NCL) are a group of childhood inherited neurodegenerative disorders characterized by blindness, early dementia and pronounced cortical atrophy. The similar pathological and clinical profiles of different forms of NCL suggest that common disease mechanisms may be involved. Here, we have performed quantitative gene expression profiling of cortex from targeted knock out mice produced for Cln1 and Cln5 to explore NCL-associated molecular pathways. Combined microarray datasets from both mouse models exposed a common affected pathway: genes regulating cytoskeletal dynamics and neuronal growth cone stabilization display similar aberrations. We analyzed locus specific gene expression and showed regional clustering of Cln1 and three major genes of this pathway, further supporting a close functional relationship between the corresponding gene products, Cap1, Ptprf and Ptp4a2. The evidence from the gene expression data was substantiated by immunohistochemical staining data of Cln1-/- and Cln5-/- cortical neurons. These primary neurons displayed abnormalities in beta-tubulin and actin as well as abnormal intracellular distribution of growth cone associated proteins GAP-43, synapsin and Rab3. Our data provide the first evidence for a common molecular pathogenesis behind neuronal degeneration in CLN1 and CLN5. Since CLN1 and CLN5 code for proteins with distinct functional roles these data may have implications for other forms of NCL.