Project description:Using high resolution quantitative mass spectrometry, we have generated the most comprehensive human and mouse microglia proteomic datasets to date, consisting of over 11,000 proteins across all six microglia groups. Microglia from different sources share a core protein signature of over 5600 proteins, yet fundamental differences are observed between species and culture conditions, indicating limitations for human disease modelling in mouse or in in vitro cultures of microglia. Mouse ex vivo microglia show important differences at the proteome level such as differential expression of inflammation and Alzheimer’s Disease associated proteins. We identify a tenfold difference in protein content of ex vivo and in vitro cells and significant proteome differences associated with protein synthesis, metabolism, microglia marker expression and environmental sensors. Culturing microglia induces rapidly increased growth, protein content and inflammatory protein expression. These changes can be restored by engrafting in vitro cells into the brain, with xenografted hESC-derived microglia closely resembling microglia from human brain. This data provides an important resource for the field and highlights important considerations needed when using model systems to study human physiology and pathology of microglia.

Project description:Using high resolution quantitative mass spectrometry, we have generated the most comprehensive human and mouse microglia proteomic datasets to date, consisting of over 11,000 proteins across all six microglia groups. Microglia from different sources share a core protein signature of over 5600 proteins, yet fundamental differences are observed between species and culture conditions, indicating limitations for human disease modelling in mouse or in in vitro cultures of microglia. Mouse ex vivo microglia show important differences at the proteome level such as differential expression of inflammation and Alzheimer’s Disease associated proteins. We identify a tenfold difference in protein content of ex vivo and in vitro cells and significant proteome differences associated with protein synthesis, metabolism, microglia marker expression and environmental sensors. Culturing microglia induces rapidly increased growth, protein content and inflammatory protein expression. These changes can be restored by engrafting in vitro cells into the brain, with xenografted hESC-derived microglia closely resembling microglia from human brain. This data provides an important resource for the field and highlights important considerations needed when using model systems to study human physiology and pathology of microglia.

Project description:Type I interferons (IFN-I) are crucial for effective antimicrobial defence in the central nervous system (CNS) but also can cause severe neurological disease (termed cerebral interferonopathy) as exemplified by Aicardi-Goutières Syndrome and chronic viral infection. In the CNS, microglia and astrocytes have essential roles in host responses to infection and injury, with both cell types responding to IFN-I. However, the extent to which the IFN-I responses of these cells differ, if at all, is still unknown. Here we determined the global transcriptional responses of astrocytes and microglia to the IFN-I, IFN-alpha. MGCs were prepared from 2–4 day-old C57BL/6 mice. Purified primary astrocytes were obtained from the MGCs by magnetic activated cell sorting using anti-CD11b beads. Microglia were obtained from mixed glial cell cultures by mechanical shaking for 4 h. After treating astrocytes and microglia with IFN-alpha for 12 h, microarray using Affymetrix mouse genome array 430 2.0 array was performed on total RNA extracted from these cells. We found that under basal conditions, each cell type has a unique gene expression pattern reflective of its developmental origin and biological function. Following stimulation with IFN-alpha for 12 h, astrocytes and microglia also displayed a common core response that was characterized by the increased expression of genes required for pathogen detection and elimination. Microglia had a more extensive and diverse response to IFN-alpha with twice the number of genes upregulated (282 vs. 141 genes) when compared with astrocytes. Validation of the findings in vivo further suggested that astrocytes and microglia play important but distinct roles in the development of IFN-alpha-driven cerebral interferonopathies.

Project description:Microglia activation is a key modulator of brain vulnerability in response to intra-uterine growth restriction (IUGR). However, the consequences of IUGR on microglia development and on microglia proteome are still unknown. We used a model of IUGR induced by a gestational low-protein diet (LPD) in rat. Microglia were isolated from control and LPD animals at P1 and P4. The aim of this work was characterize the consequence of IUGR on microglia development and investigate the consequences of IUGR exposure on microglia proteome during the first postnatal days using a bioinformatics approach associated with functional assays.

Project description:γ-Secretase is involved in the regulated intramembrane proteolysis (RIP) of a variety of integral membrane proteins and generates the amyloid peptide (Aβ) in Alzheimer’s Disease (AD). Microglia are centrally involved in AD, but the substrates and function of γ-secretase in these cells remain largely unstudied. Using a novel γ-Secretase Substrate Identification (G-SECSI) method, we identified 85 substrates, of which 59 were previously unknown, in stem cell derived microglia-like cells. More than 60% of those are signalling receptors possibly involved in cell state regulation. Inhibition of γ-secretase using Semagacestat or selective genetic knockout alters the expression of homeostatic (HM) and disease-associated (DAM) genes, in particular when microglia are exposed to amyloid plaques in vivo. Thus, γ-secretase regulates tonic signaling via a spectrum of substrates in microglia in steady state, and its blockage results in the defective transition to the DAM response in AD.

Project description:The ubiquitin-proteasome system maintains the functional proteome of the cells by the clearance of damaged, misfolded, old and/or unneeded proteins. This is particularly important in the brain where protein accumulation has a hallmark of many neurodegenerative diseases that drives neuroinflammation. Microglia are the resident immune cells of the central nervous system and play a major role in the regulation of brain homeostasis via constitutive expression of standard proteasomes and immunoproteasomes (IP). Nevertheless, the impact of IP function on the innate immunity of CNS is not well described. Here, we analyzed ubiquitylated proteins in IP deficient microglia upon enrichment and under different conditions to identify the proteins preferentially degraded by the IP and to investigate the impact of the accumulation of these proteins on microglia function.

Project description:We performed bulk transcriptomic analyses to compare the expression profile of different brain myeloid leukocytes. We used both Tg(p2ry12::p2ry12-GFP; cd45:DsRed) and Tg(mhc2dab:GFP; cd45:DsRed) adult fish, allowing to FACS-sort microglia identified in these animals as GFP+; DsRed+ or GFP+; DsRedlow cells, respectively. Brain putative DC-like cells were obtained using the Tg(mhc2dab:GFP; cd45:DsRed) reporter, and isolated as GFP+; DsRedhigh. These analyses confirm that cd45:DsRedhigh; mhc2dab:GFP+ cells share a similar transcriptome distinct from microglia and are DC-like cells.

Project description:Explore the protein molecular mechanism of physiological changes in microglia treated with optogenetic technology under light treatment.

Project description:Loss-of-function mutations in CLN3 cause juvenile Batten disease, featuring neurodegeneration and early-stage neuroinflammation. How loss of CLN3 function leads to early neuroinflammation is not yet understood. Here, we have comprehensively studied microglia from Cln3∆ex7/8 mice, a genetically accurate disease model. Loss of CLN3 function in microglia leads to lysosomal storage material accumulation and abnormal morphology of subcellular organelles. We also discovered pathological proteomic signatures consistent with defects in lysosomal function and indicative of abnormal lipid metabolism. CLN3-deficient microglia were unable to efficiently turnover myelin and metabolize the associated lipids, showing defects in lipid droplet formation and cholesterol accumulation.

Project description:Niemann-Pick type C (NPC) disease is a rare neurodegenerative disorder mainly caused by autosomal recessive mutations in Npc1 which result in abnormal late endosomal/lysosomal lipid storage. Although microgliosis is one of the prominent pathological features, consequences of NPC1 loss on microglial function and disease outcome remain largely unknown. Here, we provide an in-depth characterization of microglial proteomic signatures and phenotypes in an NPC1-deficient (Npc1-/-) murine model. We demonstrate that microglial defects, including enhanced phagocytosis and impaired lipid trafficking, occur early in the NPC pathological cascade and precede neuronal death. Compromised microglial function during Npc1-/- mouse development is reflected by enhanced synaptic pruning and deficient turnover of myelin. Accumulation of the undigested myelin occurs mainly within multi-vesicular bodies (MVBs) of Npc1-/- microglia and not within lysosomes. This is in agreement with the impairments in recycling of myelin into lipid droplets. Macrophages of NPC patients displayed similar molecular and functional alterations as murine Npc1-/- microglia, strengthening the role of NPC1 in immune homeostasis. Generated ex vivo assays using patient macrophages are novel promising clinical tools to monitor the progression and therapeutic efficacy in NPC patients.