Project description:In this study, we aimed to identify 1) The relevant Itgb8 expressing cell types that mediate microglial TGFb activation; 2) The developmental timing of Itgb8-mediated TGFb signaling in microglia; 3) The cellular source and identity of the TGFb ligand relevant for microglial development and homeostasis; 4) The relationship between developmentally disrupted microglia and disease associated microglia; and 5) The role of canonical (Smad-mediated) versus non-canonical TGFb signaling in microglia.

Project description:In this study, we aimed to identify 1) The relevant Itgb8 expressing cell types that mediate microglial TGFb activation; 2) The developmental timing of Itgb8-mediated TGFb signaling in microglia; 3) The cellular source and identity of the TGFb ligand relevant for microglial development and homeostasis; 4) The relationship between developmentally disrupted microglia and disease associated microglia; and 5) The role of canonical (Smad-mediated) versus non-canonical TGFb signaling in microglia.

Project description:While TGF-β signaling is essential for microglial function, the cellular source of TGF-β ligand and its spatial regulation remains unclear in adult CNS. Our data supports that microglia but not astrocytes or neurons are the primary producers of TGF-β1 ligands needed for microglial homeostasis. Microglia-Tgfb1 KO leads to activation of microglia featuring a dyshomeostatic transcriptomic profile that resembles disease-associated microglia (DAMs), injury-associated microglia, and aged microglia, suggesting that microglial self-produced TGF-β1 ligands are important in the adult CNS. Interestingly, astrocytes in the MG-tgfb1 iKO mice show a transcriptome profile that is closely aligned with A1-like astrocytes. Additionally, using sparse mosaic single cell microglia KO of TGF-β1 ligand we established an autocrine mechanism for TGF-β signaling. Importantly MG-Tgfb1 inducible KO mice show cognitive deficits, supporting that precise spatial regulation of TGF-β1 ligand derived from microglia is critical for the maintenance of brain homeostasis and normal cognitive function in the adult brain.

Project description:Microglia colonize the brain parenchyma at early stages of development and accumulate in specific regions where they actively participate in cell death, angiogenesis, neurogenesis and synapse elimination. A recurring feature of embryonic microglial distribution is their association with developing axon tracts which, together with in vitro data, supports the idea of a physiological role for microglia in neurite development. Yet the demonstration of this role of microglia is still lacking. Here, we have studied the consequences of microglial dysfunction on the formation of the corpus callosum, the largest connective structure in the mammalian brain, which shows consistent microglial accumulation during development. We studied two models of microglial dysfunction: the loss-of-function of DAP12, a key microglial-specific signaling molecule, and a model of maternal inflammation by peritoneal injection of LPS at E15.5. We performed transcriptional profiling of maternally inflamed and Dap12-mutant microglia at E17.5. We found that both treatments principally down-regulated genes involved in nervous system development and function, particularly in neurite formation. We then analyzed the functional consequences of these microglial dysfunctions on the formation of the corpus callosum. We also took advantage of the Pu.1-/- mouse line, which is devoid of microglia. We now show that all three models of altered microglial activity resulted in the same defasciculation phenotype. Our study demonstrates that microglia are actively involved in the fasciculation of corpus callosum axons. To investigate possible roles for microglial during brain development, we challenged microglial function by two complementary approaches. First, we induced maternal inflammation by peritoneal injection of LPS into pregnant dams. Next, we analyzed the consequences of a loss of function of DAP12, a signaling molecule specifically expressed in microglia that is crucial for several aspects of microglia biology (references in Wakselman et al., 2008). We compared the gene expression profiles of microglia from control, maternally-inflamed by LPS (MI), and Dap12-mutated embryos. We isolated RNA from FACS sorted maternally inflamed (by LPS) and Dap12-mutant microglia at E17.5 pooled per pregnant dam; as a control we included PBS treated and untreated (UT) microglia. We compared gene expression between maternally inflamed microlgia (PBSvsLPS) and DAP12-mutant microglia (UTvsDAP12KO).

Project description:TGFB-signaling is important for the establishment of microglia homeostasis; however, it's role in aging has remained vague. We found that Tgfb1 and TGFB signaling is altered during hippocampal microglia aging. To investigate the effects that microglia-derived Tgfb1 has on microglia aging, we performed scRNA-Seq on Cd11b+ cells from the hippocampus of mature mice where Tgfb1 had been ablated from Cx3cr1 cells post-maturity.

Project description:Immunometabolism investigates the complex interplay between the immune system and cellular metabolism. This study highlights the effects of mitochondrial frataxin (FXN) depletion, which causes Friedreich's ataxia (FRDA), a neurodegenerative condition characterized by coordination and muscle control deficiencies. Using single-cell RNA sequencing, we identified specific cell groups in the cerebellum of a FRDA mouse model, emphasizing a notable inflammatory microglial response. These FXN-deficient microglia cells exhibited enhanced inflammatory reactions. Furthermore, our metabolomic analyses revealed increased glycolysis and itaconate production in these cells, possibly driving the inflammation. Remarkably, butyrate treatment counteracted these immunometabolic changes, triggered an antioxidant response via the itaconate-Nrf2-GSH pathways, and dampened inflammation. The study also pinpointed Hcar2 (GPR109A) as a potential agent for butyrate anti-inflammatory impact on microglia. Tests on FRDA mice highlighted the neuroprotective attributes of butyrate intake, bolstering neuromotor performance. In essence, our findings shed light on how cerebellar microglia activation contributes to FRDA and highlight butyrate potential to alleviate neuroinflammation, rectify metabolic imbalances, and boost neuromotor capabilities in FRDA and similar conditions.

Project description:Immunometabolism investigates the complex interplay between the immune system and cellular metabolism. This study highlights the effects of mitochondrial frataxin (FXN) depletion, which causes Friedreich's ataxia (FRDA), a neurodegenerative condition characterized by coordination and muscle control deficiencies. Using single-cell RNA sequencing, we identified specific cell groups in the cerebellum of a FRDA mouse model, emphasizing a notable inflammatory microglial response. These FXN-deficient microglia cells exhibited enhanced inflammatory reactions. Furthermore, our metabolomic analyses revealed increased glycolysis and itaconate production in these cells, possibly driving the inflammation. Remarkably, butyrate treatment counteracted these immunometabolic changes, triggered an antioxidant response via the itaconate-Nrf2-GSH pathways, and dampened inflammation. The study also pinpointed Hcar2 (GPR109A) as a potential agent for butyrate anti-inflammatory impact on microglia. Tests on FRDA mice highlighted the neuroprotective attributes of butyrate intake, bolstering neuromotor performance. In essence, our findings shed light on how cerebellar microglia activation contributes to FRDA and highlight butyrate potential to alleviate neuroinflammation, rectify metabolic imbalances, and boost neuromotor capabilities in FRDA and similar conditions.

Project description:Immunometabolism investigates the complex interplay between the immune system and cellular metabolism. This study highlights the effects of mitochondrial frataxin (FXN) depletion, which causes Friedreich's ataxia (FRDA), a neurodegenerative condition characterized by coordination and muscle control deficiencies. Using single-cell RNA sequencing, we identified specific cell groups in the cerebellum of a FRDA mouse model, emphasizing a notable inflammatory microglial response. These FXN-deficient microglia cells exhibited enhanced inflammatory reactions. Furthermore, our metabolomic analyses revealed increased glycolysis and itaconate production in these cells, possibly driving the inflammation. Remarkably, butyrate treatment counteracted these immunometabolic changes, triggered an antioxidant response via the itaconate-Nrf2-GSH pathways, and dampened inflammation. The study also pinpointed Hcar2 (GPR109A) as a potential agent for butyrate anti-inflammatory impact on microglia. Tests on FRDA mice highlighted the neuroprotective attributes of butyrate intake, bolstering neuromotor performance. In essence, our findings shed light on how cerebellar microglia activation contributes to FRDA and highlight butyrate potential to alleviate neuroinflammation, rectify metabolic imbalances, and boost neuromotor capabilities in FRDA and similar conditions.

Project description:Niemann-Pick type C (NPC) disease is an inherited lysosomal storage disorder mainly driven by mutations in NPC1 gene, causing lipid accumulation within late endosomes/lysosomes, and resulting in progressive neurodegeneration. Although microglial activation proceeds neuronal loss, it remains elusive whether loss of NPC1 in microglia actively contributes to NPC pathology. Here, we used a mouse model with depletion of NPC1 in myeloid cells to investigate the role of microglia in Niemann-Pick disease. In order to achieve the loss of NPC1 in myeloid cells, mice with floxed Npc1 alleles (Npc1 flox/flox) were crossed with mice expressing the constitutively active Cre recombinase under the myeloid-specific promotor of Cx3cr1. Hyperactive microglia initiated a pathological cascade resembling NPC-like phenotypes, including shortened lifespan, motor impairments, astrogliosis, neuroaxonal pathology and increased levels of neuronal injury biomarker NF-L. To study the differential vulnerability between the brain regions, we compared the cerebellar with the cerebral (brain without cerebellum) proteome in Cre- and Cre+ mice at late pathological stages. Our results suggest that microglial loss of NPC1 has profound effects on brain cell homeostasis especially in the cerebrum.

Project description:Radial glia promote microglial development through aVb8 -TGFb1 signaling