Project description:The sheer complexity of the brain has complicated our ability to understand its cellular mechanisms in health and disease. Genome-wide association studies have uncovered genetic variants associated with specific neurological phenotypes and diseases. In addition, single-cell transcriptomics have provided molecular descriptions of specific brain cell types and the changes they undergo during disease. Although these approaches provide a giant leap forward towards understanding how genetic variation can lead to functional changes in the brain, they do not establish molecular mechanisms. To address this need, we developed a 3D co-culture system termed iAssembloids (induced multi-lineage assembloids) that enables the rapid generation of homogenous neuron-glia spheroids. We characterize these iAssembloids with immunohistochemistry and single-cell transcriptomics and combine them with large-scale CRISPRi-based screens. In our first application, we ask how glial and neuronal cells interact to control neuronal death and survival. Our CRISPRi-based screens identified that GSK3β inhibits the protective NRF2-mediated oxidative stress response in the presence of reactive oxygen species elicited by high neuronal activity, which was not previously found in 2D monoculture neuron screens. We also apply the platform to investigate the role of APOE- 4, a risk variant for Alzheimer’s Disease, in its effect on neuronal survival. We find that APOE- 4 expressing astrocytes may promote more neuronal activity as compared to APOE- 3 expressing astrocytes. This platform expands the toolbox for the unbiased identification of mechanisms of cell-cell interactions in brain health and disease.

Project description:Apolipoprotein E (apoE) plays a pivotal role in the pathogenesis of Alzheimer’s disease (AD). In the brain, apoE is predominantly expressed and secreted by astrocytes, but is dramatically up-regulated in microglia under AD-associated conditions. Although the function of astrocytic apoE has been widely investigated, whether and how apoE particles derived from different types of glia differ in biological features and function remains elusive. Here, we show that apoE particles derived from astrocytes and microglia exhibit dissimilar sizes. Microglial apoE particles impaired neurite growth and synapses and promoted neuronal senescence, whereas GPNMB-deficient microglial apoE particles abolished these detrimental effects. These findings provide direct evidence supporting that microglia-derived apoE particles contribute to neuronal senescence and toxicity.

Project description:SORL1 is implicated in the pathogenesis of Alzheimer’s disease (AD) through genetic studies. To interrogate the role(s) of SORL1 in human brain cells, SORL1 null iPSCs are differentiated to neuron, astrocyte, microglial, and endothelial cell fates. Loss of SORL1 leads to alterations in both overlapping and distinct pathways across cell types, with the greatest effects in neurons and astrocytes. SORL1 loss induces a neuron-specific reduction in APOE and CLU and altered lipid profiles. Enhancement of retromer-mediated trafficking rescues tau phenotypes observed in SORL1 null neurons but does not rescue APOE levels. Pathway analyses implicate TGF-β/SMAD signaling in SORL1 function, and modulating SMAD signaling in neurons alters APOE RNA levels in a SORL1-dependent manner. Analyses of iPSCs derived from a large cohort reveal a neuron-specific association between SORL1, APOE, and CLU levels, a finding validated in post-mortem brain. These studies provide a mechanistic link between strong genetic risk factors for AD.

Project description:Human APOE genotype is intricately involved in the homeostasis of the central nervous system, which is particularly evident from its association with neurodegenerative disease. Compared to APOE3, APOE4 is associated with greater cognitive decline in aging, poorer outcomes following stroke and traumatic brain injury, and is a major genetic risk factor for Alzheimer’s disease. Human APOE genotypes can differentially modulate neuronal function via both direct and indirect pathways. Of the indirect pathways, increasing evidence supports that APOE4-associated neurovascular dysfunction plays a significant role in neurodegeneration. For example, deficits in cerebral blood flow, neuronal-vascular coupling and blood-brain barrier integrity are observed with APOE4 both during aging and in Alzheimer’s disease patients; data that has been recapitulated in mouse models. Therefore, the identification of cellular mechanistic pathways that contribute to APOE-modulated vascular function is important for fundamental and disease-focused research. Highly specialized brain endothelial cells (BECs) are essential for virtually all neurovascular functions and, therefore, the influence of apoE on the cerebrovasculature likely involves alterations in brain endothelial cells function, directly or via supporting cells. ApoE synthesis has been demonstrated in multiple cell types in both the brain (e.g. astrocytes, pericytes and neurons) and periphery (e.g. hepatocytes and macrophages). Current research has largely focused on the effects of apoE produced by supporting cell types, particularly astrocytes and pericytes, on BEC function. However, less explored is whether BECs produce apoE to modulate their function. Data from limited studies on apoE production by BECs and APOE genotype-specific functional differences are conflicting. Evaluation of whether the APOE genotype of BECs modulates their function is important, as this could represent a novel mechanisms that contributes to altered cerebrovascular function in aging and AD. The goal of this study was to evaluate the role of human APOE genotype in modulating the phenotype and/or function of brain endothelial cells in vitro. To this end, we utilized primary brain endothelial cells isolated from APOE-targeted replacement mice that express human APOE3 or APOE4 under the endogenous mouse APOE promoter. BECs are highly specialized and functionally complex to maintain homeostasis of the central nervous system and APOE genotype could theoretically alter levels of any number of molecules and associated functions. Thus, without a priori knowledge we initially evaluated the extent that APOE modulated the transcriptomic profile of brain endothelial cells.

Project description:Astrocyte dysfunction impacts their normal function, including neuronal support, thereby contributing to neurodegenerative pathologies including Alzheimer's disease (AD). Therefore to understand the role of astrocytes in the pathogenesis of age-related disorders we analysed the gene expression profile of astrocytes with respect to Alzheimer-type pathology. The aim of the present study was to combine immuno-LCM and microarray analysis to characterise the astrocyte transcriptome at different Braak stages, and with respect to ApoE genotype, in post-mortem human temporal cortex sampled dervied from the Medical Research Council Cognitive Function and Ageing Study (MRC-CFAS). GFAP-positive astrocytes were isolated from age, sex and brain pH-matched cases derived from the MRC-CFAS cohort, using immuno laser capture microdissection. The extracted RNA was amplified and applied to HGU133 Plus 2.0 Affymetrix gene arrays. Genes were considered differentially expressed if they showed a minimum 1.5 fold change at p<0.02 in all 6 individual cases in each stage of pathology [18 cases in total: 6 cases Braak stages I-II (3 cases carried at least one ApoE epsilon4 allele and 3 were ApoEe4 negative); 6 cases Braak stages III-IV (3 ApoEe4 positive and 3 ApoEe4 negative; 6 cases Braak stages V-VI (3 ApoEe4 positive and 3 ApoEe4 negative)]. keywords: human GFAP-positive astrocytes

Project description:To explore the mechanistic basis of ApoE Ɛ4 vs ApoE Ɛ3 protein expression on endocytic pathways responsible for tau uptake in neurons and astrocytes and the maturation of neuronal networks, we have developed genotype matched co-cultures of iPSC derived astrocytes and neurons derived from isogenic triads of iPSC lines generated by the ADAPTED consortium (Schmid et al., 2019, 2020) . We show that isogenic iPSC derived APOE-E4 expressing astrocytes take up less extracellular tau than APOE-E3 or APOE null astrocytes, while isogenic neurons in monoculture take up equivalent amounts of tau primarily through macropinocytosis. Co-culture of neurons with genotype matched astrocytes increases the general uptake capacity of neurons by increasing the dependence of neuronal endocytosis on dynamin mediated pathways. Co-culture also enhances the emergence of spontaneous neuronal activity; however, the emergence of synchronous network activity is impaired by the expression of APOE-E4 genotype. We performed RNA-Seq on the astrocytes, neurons and co-cultures to understand the molecular pathway changes associated with different ApoE genotypes.

Project description:The APOE gene is diversified by three alleles e2, e3, and e4 encoding corresponding apolipoprotein (apo) E isoforms. The e4 allele promotes age-related cognitive decline, risk of Alzheimer’s disease (AD), and the rate of AD dementia progression. ApoE is produced by astrocytes as high-density lipoprotein-like particles and these are internalized by neurons upon binding to neuron-expressed apoE receptors. ApoE isoforms differentially engage neuronal plasticity through poorly understood mechanisms. We examined here the effects of native apoE lipoproteins produced by immortalized astrocytes homozygous for e2, e3, and e4 alleles on the maturation and the transcriptomic profile of primary hippocampal neurons. Control neurons were grown in the presence of conditioned media from Apoe-/- astrocytes. ApoE2 and apoE3 significantly increase the dendritic arbor branching, the combined neurite length, and the total arbor surface of the hippocampal neurons, while apoE4 fails to produce similar effects and even significantly reduces the combined neurite length compared to the control. ApoE lipoproteins show no systemic effect on dendritic spine density, yet apoE2 and apoE3 increase the mature spines fraction, while apoE4 increases the immature spine fraction. This is associated with opposing effects of apoE2 or apoE3 and apoE4 on the expression of NR1 NMDA receptor subunit and PSD95. There are 1,062 genes differentially expressed across neurons cultured in the presence of apoE lipoproteins compared to the control. KEGG enrichment and gene ontology analyses show common for apoE2 and apoE3 activation of genes involved in neurite branching, and synaptic signaling. In contrast, apoE4 cultured neurons show upregulation of genes related to the glycolipid metabolism, which are involved in dendritic spine turnover and those which are usually silent in neurons and are related to cell cycle and DNA repair. In conclusion our work reveals that lipoprotein particles comprised of various apoE isoforms differentially regulate neuronal development through interaction with neuronal transcriptome. ApoE4 produces a functionally distinct transcriptomic profile, which is associated with attenuated neuronal development. Differential regulation of neuronal transcriptome by apoE isoforms is a newly identified biological mechanism, which has both implication in the development and aging of the CNS.

Project description:SORL1 is strongly implicated in the pathogenesis of Alzheimer’s disease (AD) through human genetic studies that point to an association of reduced SORL1 levels with higher risk for AD. To interrogate the role(s) of SORL1 in human brain cells, SORL1 null iPSCs were generated, followed by differentiation to neuron, astrocyte, microglial, and endothelial cell fates. Loss of SORL1 led to alterations in both overlapping and distinct pathways across cell types, with the greatest effects in neurons and astrocytes. Intriguingly, SORL1 loss led to a dramatic neuron-specific reduction in APOE and CLU levels, an increase in the accumulation of lipid droplets and altered lipid profiles. Pathway analysis implicated intracellular transport pathways and TGF-β/SMAD signaling in the function of SORL1 in neurons. Enhancement of retromer-mediated trafficking and autophagy rescued tau phenotypes observed in SORL1 null neurons but did not rescue APOE levels. However, stimulation and inhibition of SMAD signaling in neurons modulated APOE RNA levels in a SORL1-dependent manner. Further, analyses of iPSCs derived from a human aging cohort revealed a neuron-specific linear correlation between SORL1 and APOE RNA and protein levels, a finding validated in human post-mortem brain. These studies provide a mechanistic link between two of the strongest genetic risk factors for AD.

Project description:CRISPR/Cas9-based functional genomics have transformed our ability to elucidate mammalian cell biology. Most previous CRISPR-based screens were implemented in cancer cell lines, rather than healthy, differentiated cells. Here, we describe a CRISPR interference (CRISPRi)-based platform for genetic screens in human neurons derived from induced pluripotent stem cells (iPSCs). We demonstrate robust and durable knockdown of endogenous genes in such neurons, and present results from three complementary genetic screens. A survival-based screen revealed neuron-specific essential genes and a small number of genes that improved neuronal survival upon knockdown. A screen with a single-cell transcriptomic readout uncovered several examples for genes knockdown of which had dramatically different cell-type specific consequences. A longitudinal imaging screen detected distinct consequences of gene knockdown on neuronal morphology. Our results highlight the potential of interrogating cell biology in iPSC-derived differentiated cell types and provide a platform for the systematic dissection of normal and disease states of neurons.

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.