Project description:Basal radial glial cells (bRGs) are neural progenitors enriched in primates and humans and were proposed to contribute to the expansion of neurons during cortical development in gyrencephalic species. Shortly after their generation, bRGs delaminate towards the outer subventricular zone, where they divide multiple times before differentiation. Thus, the regulation of bRGs generation could be essential for the establishment of correct gyrification within the human cortex. Here, we study the role of LGALS3BP, a secreted protein whose RNA expression is enriched in bRGs. By using cerebral organoids, human fetal tissues and mice, we show that manipulation of LGALS3BP regulated bRG generation. Additionally, individuals with unique de novo variants in LGALS3BP demonstrate abnormal gyrification and thickness at multiple sites over their cortex. Single-cell-RNA-sequencing and proteomics reveal the extracellular matrix involvement in the LGALS3BP mediated mechanisms. We find that LGALS3BP is required for bRGs delamination and influences corticogenesis and gyrification in humans.

Project description:We set up a 3D model based on iPSCs derived from patients with familial forms of Alzheimer’s disease (AD) and healthy non-demented control. We created cerebral organoids (COs), verified their ability to mimic AD in vitro, and used it to explore early events and the progression of AD pathogenesis. Our data reveal that despite similar expression of cell-type-specific genes during CO maturation in vitro, AD-iPSCs derived COs show limited tissue patterning and altered cellular development. These findings complement unique single-cell sequencing data of AD-iPSCs derived COs confirming this observation and uncovering that a sub-set of neurons in AD-iPSCs likely differentiates prematurely while at the same time retaining the expression of progenitor marker PAX6.

Project description:Joint profiling of chromatin accessibility and gene expression from the same single cell provides critical information about cell types in a tissue and cell states during a dynamic process. These emerging multi-omics techniques help the investigation of cell-type resolved gene regulatory mechanisms. Here, we developed in situ SHERRY after ATAC-seq (ISSAAC-seq), a highly sensitive and flexible single cell multi-omics method to interrogate chromatin accessibility and gene expression from the same single cell. We demonstrated that ISSAAC-seq is sensitive and provides high quality data with orders of magnitude more features than existing methods. Using the joint profiles from thousands of nuclei from the mouse cerebral cortex, we uncovered major and rare cell types together with their cell-type specific regulatory elements and expression profiles. Finally, we revealed distinct dynamics and relationships of transcription and chromatin accessibility during an oligodendrocyte maturation trajectory.

Project description:The AMPylation is novel protein post-translation modification. In consist of attachment of the adenosine monophosphate onto the serine, threonine or tyrosine amino acid residues of the protein. This process is catalysed by bacterial effectors or in human by protein FICD (also called HYPE) which contain conserved fic domain. In our study we have focused on identification of the unknown AMPylated proteins and their function in human cells (HeLa, A549, SH-SY5Y, iPSCs, NPCs and neurons) and cerebral organoids (COs). For this purpose we designed and synthesized the small molecule N6-propargyl phosphoramidate adenosine (PAK-76) which was used for in situ labelling of the AMPylation in cells and COs. Subsequnetly the the propargyl tag was employed for preparation of chemical-proteomic samples which were measured by LC-MS/MS. This approach confirmed the known AMPylation of heat shock protein HSPA5 and found diverse group of novel AMPylation targets. Several cathepsins found as AMPylation targets were further characterized by identification of AMP binding site. Based on our chemical proteomic data we found out that neurons and neuronal like cells contain distinct AMPylatino pattern from other studied cell types. This also suggested the importance of the AMPylation in these cell types which were then studied in cerebral organoids by overexpressing the FICD wt and E234G highly active mutant. This led to the accelerated differentiation of progenitors into the neurons. Overall our approach is suitable for identification of the AMPylated proteins in living cells and led to characterization of FICD function.

Project description:The AMPylation is novel protein post-translation modification. In consist of attachment of the adenosine monophosphate onto the serine, threonine or tyrosine amino acid residues of the protein. This process is catalysed by bacterial effectors or in human by protein FICD (also called HYPE) which contain conserved fic domain. In our study we have focused on identification of the unknown AMPylated proteins and their function in human cells (HeLa, A549, SH-SY5Y, iPSCs, NPCs and neurons) and cerebral organoids (COs). For this purpose we designed and synthesized the small molecule N6-propargyl phosphoramidate adenosine (pro-N6pA) which was used for in situ labelling of the AMPylation in cells and COs. Subsequnetly the the propargyl tag was employed for preparation of chemical-proteomic samples which were measured by LC-MS/MS. This approach confirmed the known AMPylation of heat shock protein HSPA5 and found diverse group of novel AMPylation targets. Several cathepsins found as AMPylation targets were further characterized by identification of AMP binding site. Based on our chemical proteomic data we found out that neurons and neuronal like cells contain distinct AMPylatino pattern from other studied cell types. This also suggested the importance of the AMPylation in these cell types which were then studied in cerebral organoids by overexpressing the FICD wt and E234G highly active mutant. This led to the accelerated differentiation of progenitors into the neurons. Overall our approach is suitable for identification of the AMPylated proteins in living cells and led to characterization of FICD function.

Project description:Amyotrophic Lateral Sclerosis is clinically defined as the combined degeneration of the corticospinal and corticobulbar neurons (CSN) along with the bulbar and spinal motor neurons (SMN). While a growing body of evidence points to the motor cortex, where CSN are located, as the potential initiation site of ALS, little is known about how CSN degenerate. To gain insights into the molecular mechanisms behind CSN selective degeneration, we first developed an approach to purify this neuronal population from the cerebral cortex of adult wild-type and Sod1G86R mice, combining retrograde labelling and Fluorescence Activated Cell Sorting. In parallel, a second population of cortical neurons, the callosal projection neurons (CPN) located in the layers II/III of the cerebral cortex were also purified. CPN and CSN are both cortical excitatory projection neurons but as opposed to CSN, CPN do not degenerate in Sod1G86R mice, and served as control population. CSN and CPN were purified from same animals, at two presymptomatic ages (3 and 60 days) and two symptomatic ages, 90 and 105 days. A total of 57 samples were further processed and analysed (CSN: 30d: n=4 WT and 3 Sod1G86R; 60d: n=4 WT and 4 Sod1G86R; 90d: n=4 WT and 4 Sod1G86R; 105d: n=4 WT and 2 Sod1G86R; CPN: 30d: n=4 WT and 3 Sod1G86R; 60d: n=2 WT and 3 Sod1G86R; 90d: n=4 WT and 4 Sod1G86R; 105d: n=4 WT and 4 Sod1G86R).

Project description:Areas and layers of the cerebral cortex are specified by genetic programs that are initiated in progenitor cells and then, implemented in postmitotic neurons. Here, we report that Tbr1, a transcription factor expressed in postmitotic projection neurons, exerts positive and negative control over both regional (areal) and laminar identity. Tbr1 null mice exhibited profound defects of frontal cortex and layer 6 differentiation, as indicated by down-regulation of gene-expression markers such as Bcl6 and Cdh9. Conversely, genes that implement caudal cortex and layer 5 identity, such as Bhlhb5 and Fezf2, were up-regulated in Tbr1 mutants. Tbr1 implements frontal identity in part by direct promoter binding and activation of Auts2, a frontal cortex gene implicated in autism. Tbr1 regulates laminar identity in part by downstream activation or maintenance of Sox5, an important transcription factor controlling neuronal migration and corticofugal axon projections. Similar to Sox5 mutants, Tbr1 mutants exhibit ectopic axon projections to the hypothalamus and cerebral peduncle. Together, our findings show that Tbr1 coordinately regulates regional and laminar identity of postmitotic cortical neurons. Mouse E14.5 neocortices and Postnatal day (P) 0.5 brains: E14.5 neocortices KO, 3; E14.5 neocortices WT, 3; Postnatal day (P) 0.5 brains frontal WT, 4; Postnatal day (P) 0.5 brains frontal KO, 4; Postnatal day (P) 0.5 brains parietal WT, 4; Postnatal day (P) 0.5 brains parietal KO, 4; Postnatal day (P) 0.5 brains occipital WT, 4; Postnatal day (P) 0.5 brains occipital KO, 4.

Project description:We have applied a recently developed, highly accurate and sensitive single-cell RNA-seq method (STRT/C1) to perform a molecular census of two regions of the mouse cerebral cortex: the somatosensory cortex and hippocampus CA1. We isolated cells fresh from somatosensory cortex (S1) and hippocampus CA1 area of juvenile (P22 - P32) CD1 mice, 33 males and 34 females. Cells were collected without selection, except that 116 cells were obtained by FACS from 5HT3a-BACEGFP transgenic mice. A total of 76 Fluidigm C1 runs were performed, each attempting 96 cell captures and resulting in 3005 high-quality single-cell cDNAs, containing Unique Molecular Identifiers allowing counting of individual mRNA molecules, even after PCR amplification.

Project description:Molecular mechanisms controlling specification and differentiation of distinct neuron subtypes in the cerebral cortex are not well understood. Corticothalamic projection neurons (CThPN) are a diverse set of neurons, critical for function of the neocortex, but little is known about the molecular mechansims controlling their development. We used microarrays to detail CThPN gene expression at 3 developmental time points. We then compared CThPN gene expression, with the gene expression of other neuron subtypes in the cerebral cortex at the same stages (previously described in Arlotta et a., 2005) CThPN were retrogradely label with fluorescent microespheres injected into the thalamus, and were FACS purified at 3 developmental stages for RNA extraction and hybridization on Affymetrix microarrays.

Project description:Molecular mechanisms controlling specification and differentiation of distinct neuron subtypes in the cerebral cortex are not well understood. Corticothalamic projection neurons (CThPN) are a diverse set of neurons, critical for function of the neocortex, but little is known about the molecular mechansims controlling their development. We used microarrays to detail CThPN gene expression at 3 developmental time points. We then compared CThPN gene expression, with the gene expression of other neuron subtypes in the cerebral cortex at the same stages (previously described in Arlotta et a., 2005)