Project description:Rat Astrocyte-Neuron Co-cultures versus purified co-cultured Astrocytes versus Astrocyte alone

Project description:Growing evidence implicates the importance of glia, particularly astrocytes, in neurological and psychiatric diseases. Here, we describe a rapid and robust method for the differentiation of highly pure populations of astrocytes from human induced pluripotent stem cells (hiPSCs), via a neural progenitor cell (NPC) intermediate. Using this method, we generated hiPSC-derived astrocyte populations (hiPSC-astrocytes) from 42 NPC lines (derived from 30 individuals) with an average of ~90% S100β-positive cells. Transcriptomic analysis demonstrated that the hiPSC-astrocytes are highly similar to primary human fetal astrocytes and characteristic of a non-reactive state. hiPSC-astrocytes respond to inflammatory stimulants, display phagocytic capacity and enhance microglial phagocytosis. hiPSC-astrocytes also possess spontaneous calcium transient activity. Our novel protocol is a reproducible, straightforward (single media) and rapid (<30 days) method to generate homogenous populations of hiPSC-astrocytes that can be used for neuron-astrocyte and microglia-astrocyte co-cultures for the study of neuropsychiatric disorders.

Project description:Astrocytes, the most abundant cells in the central nervous system, promote synapse formation and help refine neural connectivity. Although they are allocated to spatially distinct regional domains during development, it is unknown whether region-restricted astrocytes are functionally heterogeneous. Here we show that postnatal spinal cord astrocytes express several region-specific genes, and that ventral astrocyte-encoded Semaphorin3a (Sema3a) is required for proper motor neuron and sensory neuron circuit organization. Loss of astrocyte-encoded Sema3a led to dysregulated α−motor neuron axon initial segment orientation, markedly abnormal synaptic inputs, and selective death of α−but not of adjacent γ−motor neurons. Additionally, a subset of TrkA+ sensory afferents projected to ectopic ventral positions. These findings demonstrate that stable maintenance of a positional cue by developing astrocytes influences multiple aspects of sensorimotor circuit formation. More generally, they suggest that regional astrocyte heterogeneity may help to coordinate postnatal neural circuit refinement. 12 total samples consisting of three biological replicates each of flow sorted postnatal day 7 dorsal spinal cord astrocytes, ventral spinal cord astrocytes, dorsal SC non astrocytes, and ventral SC non astrocytes

Project description:Aubert2005 - Interaction between astrocytes and neurons on energy metabolism Enocded non-curated model. Issues: - Confusing equations A.41 and A.42 - Missing values for parameters Vv,0 and dHb,0 This model is described in the article: Interaction between astrocytes and neurons studied using a mathematical model of compartmentalized energy metabolism. Aubert A, Costalat R. J. Cereb. Blood Flow Metab. 2005 Nov; 25(11): 1476-1490 Abstract: Understanding cerebral energy metabolism in neurons and astrocytes is necessary for the interpretation of functional brain imaging data. It has been suggested that astrocytes can provide lactate as an energy fuel to neurons, a process referred to as astrocyte-neuron lactate shuttle (ANLS). Some authors challenged this hypothesis, defending the classical view that glucose is the major energy substrate of neurons, at rest as well as in response to a stimulation. To test the ANLS hypothesis from a theoretical point of view, we developed a mathematical model of compartmentalized energy metabolism between neurons and astrocytes, adopting hypotheses highly unfavorable to ANLS. Simulation results can be divided between two groups, depending on the relative neuron versus astrocyte stimulation. If this ratio is low, ANLS is observed during all the stimulus and poststimulus periods (continuous ANLS), but a high ratio induces ANLS only at the beginning of the stimulus and during the poststimulus period (triphasic behavior). Finally, our results show that current experimental data on lactate kinetics are compatible with the ANLS hypothesis, and that it is essential to assess the neuronal and astrocytic NADH/NAD+ ratio changes to test the ANLS hypothesis. This model is hosted on BioModels Database and identified by: MODEL1411210000. 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:Neurons induce a dramatic transformation in developing astrocytes, causing them to develop a complex stellate morphology resembling their appearance in vivo. However, the transcriptional changes that accompany this transformation are not known, nor are the signalling mechanisms responsible. Similarly, whether synaptic activity controls astrocytic gene expression and whether this leads to altered astrocytic function is unclear. This experiment seeks to investigate this non-cell-autonomously regulated gene expression by co-culturing astrocytes and neurons derived from closely related species (mouse and rat), and separating RNA-seq reads derived from each cell type in silico, thus shedding light on the signalling mechanisms underlying neuron-to-astrocyte communication and the functional consequences for astrocytes.

Project description:Co-cultures of neurons and astrocytes derived from human iPS cells carrying a GFAP (R239C) mutation - an identified cause of Alexander disease (AxD) - were analyzed with single-cell RNA sequencing to assess cell population composition, differential gene expression, and cell-cell interaction differences in AxD co-cultures compared to controls. Oxygen-glucose deprivation (OGD) challenge was applied to identify differences in stress response. Our results suggested differentiation impairment especially in AxD astrocytes, represented by an enriched population of less differentiated cells and downregulation of mature astrocyte genes in AxD astrocytes-containing co-cultures. Furthermore, AxD co-cultures showed increased stress response represented by upregulation of metallothioneins and increased susceptibility to the OGD challenge.

Project description:Astrocytes and neurons coexist and interact in the CNS1,2. Given that many signaling and pathological events are protein-driven, identifying astrocyte and neuron proteomes is essential for elucidating the complex protein networks that dictate their respective contributions to physiology and disease. Here, we used cell- and subcompartment-specific proximity-dependent biotinylation3 to study the proteomes of striatal astrocytes and medium spiny neurons (MSNs) in vivo. We evaluated cytosolic and plasma membrane compartments for astrocytes and MSNs, revealing how these cells differ at the protein level and in their core signaling machinery. We assessed subcellular compartments of astrocytes including end feet and processes to reveal the molecular basis of essential astrocyte signaling and homeostatic functions. Unexpectedly, SAPAP3 proteins (gene; Dlgap3) associated with obsessive compulsive disorder (OCD) and repetitive behaviors4-11 were detected at equivalent levels in striatal astrocyte and MSN plasma membrane and cytosolic compartments. Astrocytic expression was confirmed by RNA-seq, fluorescence in situ hybridization and immunohistochemistry. Furthermore, genetic rescue experiments combined with behavioral analyses and proteomics in a mouse model4 of OCD lacking SAPAP3 revealed contributions of SAPAP3 in astrocytes and MSNs to repetitive and anxiety-related OCD behaviors. Our data define how astrocytes and neurons differ at the protein level and in their major signaling pathways, how astrocyte proteomes vary between physiological subcompartments, and how specific astrocyte and neuronal molecular mechanisms contribute to a psychiatric disease. Targeting both astrocytes and neurons together is likely to be therapeutically effective in complex CNS disorders.

Project description:Comparison of expression data of rat forebrain astrocytes from P1, P7 acutely isolated by immunopanning or cultured with astrocytes prepared by McCarthy and de Vellis' (1980) method. Elucidating the genes induced by serum in immunopannedrat astrocytes. Three biological replicates for each sample were done. MD-astrocytes were prepared as described in McCarthy and de Vellis 1980 and harvested for mRNA after 7DIV. IP-astrocytes were isolated from P1 or P7 Sprague Dawley rats and processed for RNA immediately (IP-astrocytes P1/P7), or cultured for 7 days in HBEGF before harvesting (Cult. IP-astrocytes P1/P7). For the serum studies, we plated IP-astrocytes P7 in MD-astrocyte media containing 10% fetal calf serum immediately after isolation and cultured them for 7 days. After 7 days, the cultures were either processed for total RNA or washed 3x with dPBS and astrocyte base media with HBEGF was added. The cells were cultured for an additional 7 days and then processed for RNA. We isolated total RNA with the QIAshredder and Qiagen RNeasy Mini Kit. We used the 3’IVT Express kit for preparation of the RNA and the Rat Genome 230 2.0 Array chip (Affymetrix, Santa Clara). RT-PCR was used to elucidate the level of contamination in each cell sample.

Project description:Astrocyte-to-neuron conversion has developed into a promising avenue for neuronal replacement therapy. Neurons depend critically on mitochondria function and often die by ferroptosis during the conversion process. Here we examined the extent of adequate mitochondrial reprogramming by morphology and proteome analysis. While mitochondria profoundly changed their morphology during Neurogenin2 (Neurog2) – or Achaete-scute homolog 1 (Ascl1)-mediated astrocyte-to-neuron reprogramming, we found neuron-specific mitochondrial proteins, here identified in a comprehensive proteome analysis of isolated mitochondria from primary neurons and astrocytes, to be only partially and at late stages regulated during the process. To improve this, we used dCas9 technology to induce neuron-specific mitochondrial proteins early during reprogramming. This resulted not only in increased conversion efficiency, but also in faster neuronal generation. Taken together, reprogramming mitochondria in a cell type-specific manner has powerful effects on astrocyte-to-neuron conversion, suggesting mitochondria to be a driving force in this process.

Project description:Mice of indicated ages and genotypes were perfused and their brains dissected and dissociated. Cells were fixed, immunolabeled and FACS sorted. RNA was extracted from neuron, astrocyte, and microglial cell populations. Typical RIN=4-5 for neurons, 6-8 for astrocytes, and 5-7 for microglia. Typical RNA yields ~100ng for neurons, ~20ng for microglia, and ~10ng for astrocytes. cDNA was generated from up to 25 ng of total RNA using Nugen'™s RNA-Seq method for low-input RNA samples, Ovation RNA-Seq System V2 (NuGEN). (Per manufacturers instructions, total RNA was neither depleted of rRNA nor polyA-selected.) 1 ug of sheared cDNA was taken into further processing, starting at end repair step, using Illumina'™s TruSeq RNA Sample Preparation Kit v2 (Illumina). The 'SAMPLE_ID'; sample characteristic is a sample identifier internal to Genentech. The ID of this project in Genentech's ExpressionPlot database is PRJ0006149 Astrocytes, microglia and neurons were sorted from 7- or 13-month old PS2APP or non-transgenic mice, 4 <= n <= 7 per group.