Project description:Neonatal microglia replacement in mice modulates seizure severity in adulthood

Project description:Genetic evidence indicates that microglial dysfunctions contribute to the development and progression of various neurologic diseases, emphasizing microglia replacement as a promising therapeutic strategy. However, traditional bone marrow transplantation (BMT) aimed at replenishing brain microglia faces challenges due to low efficiency and potential brain injury from preconditioning with irradiation or chemotherapy. Moreover, the BM-derived cells that migrate to the brain fail to replicate the characteristics of resident microglia. Here, we present a simple yet highly effective microglia transplantation strategy devoid of any conditioning, termed "Tri-Cyclic Microglial Depletion for Transplantation" (TCMDT). This approach leverages three cycles of microglial depletion using the CSF1R inhibitor PLX3397, creating a critical window for the efficient engraftment of exogenous microglia. Notably, transplanting primary cultured microglia via the TCMDT strategy achieves their full restoration to the identity and functions of native microglia. To evaluate the therapeutic potential, we applied our strategy to a Sandhoff disease mouse model, a form of neurodegenerative lysosomal storage disorder (LSD) caused by Hexb deficiency. The results revealed that our strategy facilitated the efficient replacement of deficient microglia, leading to a notable decrease in neurodegeneration and an enhancement in motor performance. Similarly, in an Alzheimer's disease (AD) mouse model carrying the Trem2 R47H mutation, our transplantation strategy corrected microglial dysfunction and alleviated AD-related pathology. Overall, our study presents a practical approach for microglia replacement that is simple, efficient, and safe, offering significant therapeutic potential for treating microglia-associated disorders.

Project description:Microglia are important immune cells in the central nervous system (CNS). Dysfunctions of gene-deficient microglia contribute to the development and progression of multiple CNS diseases. Microglia replacement by nonself cells has been proposed to treat microglia associated disorders. However, most of attempts are failed due to low replacement efficiencies, such as with the traditional bone marrow transplantation approach. In this study, we develop three efficient strategies for microglia replacement: microglia replacement by bone marrow transplantation (mrBMT), microglia replacement by peripheral blood (mrPB) and microglia replacement by microglia transplantation (mrMT). mrBMT and mrPB allow microglia-like cells to efficiently replace resident microglia in the whole CNS. On the other hand, mrMT achieves microglia replacement in brain regions of interest. In summary, the present study offers effective tactics for microglia replacement with diverse application scenarios, which potentially opens up a window on treating microglia-associated CNS disorders.

Project description:Microglia are important immune cells in the central nervous system (CNS). Dysfunctions of gene-deficient microglia contribute to the development and progression of multiple CNS diseases. Microglia replacement by nonself cells has been proposed to treat microglia associated disorders. However, most of attempts are failed due to low replacement efficiencies, such as with the traditional bone marrow transplantation approach. In this study, we develop three efficient strategies for microglia replacement: microglia replacement by bone marrow transplantation (mrBMT), microglia replacement by peripheral blood (mrPB) and microglia replacement by microglia transplantation (mrMT). mrBMT and mrPB allow microglia-like cells to efficiently replace resident microglia in the whole CNS. On the other hand, mrMT achieves microglia replacement in brain regions of interest. In summary, the present study offers effective tactics for microglia replacement with diverse application scenarios, which potentially opens up a window on treating microglia-associated CNS disorders.

Project description:Krabbe disease, also named Globoid Cell Leukodystrophy (GLD) for its distinct lipid- laden macrophages, is a severe leukodystrophy caused by galactosylceramidase (GALC) mutations. Hematopoietic stem cell transplant (HSCT) ameliorates disease and is associated with central nervous system (CNS) engraftment of GALC+ donor macrophages. Yet, the role of macrophages in GLD pathophysiology and HSCT remains unclear. Using single-cell sequencing we revealed early interferon response signatures which precede progressively severe macrophage dyshomeostasis, and identified a molecular signature of globoid cells, which we validated in human brain specimens. Genetic depletion and direct microglia replacement by CNS monocyte injection rapidly replaced >80% of endogenous microglia with healthy monocytes in the twitcher (GalcW355*) mouse, a faithful model of GLD. Perinatal microglia replacement completely normalized transcriptional signatures, rescued histopathology, and doubled average survival. Overall, we uncovered distinct forms of microglia dysfunction, and evidence that direct, CNS-limited microglia replacement improves a monogenic neurodegenerative disease, a promising therapeutic target.

Project description:Krabbe disease, also named Globoid Cell Leukodystrophy (GLD) for its distinct lipid- laden macrophages, is a severe leukodystrophy caused by galactosylceramidase (GALC) mutations. Hematopoietic stem cell transplant (HSCT) ameliorates disease and is associated with central nervous system (CNS) engraftment of GALC+ donor macrophages. Yet, the role of macrophages in GLD pathophysiology and HSCT remains unclear. Using single-cell sequencing we revealed early interferon response signatures which precede progressively severe macrophage dyshomeostasis, and identified a molecular signature of globoid cells, which we validated in human brain specimens. Genetic depletion and direct microglia replacement by CNS monocyte injection rapidly replaced >80% of endogenous microglia with healthy monocytes in the twitcher (GalcW355*) mouse, a faithful model of GLD. Perinatal microglia replacement completely normalized transcriptional signatures, rescued histopathology, and doubled average survival. Overall, we uncovered distinct forms of microglia dysfunction, and evidence that direct, CNS-limited microglia replacement improves a monogenic neurodegenerative disease, a promising therapeutic target.

Project description:Microglia and border-associated macrophages (BAMs) are critical for brain health and their dysfunction is closely linked to disease. Replacing brain macrophages holds significant therapeutic promise, but remains challenging. Here, we demonstrate that monocytes can efficienty replace all brain macrophages. Monocytes readily replaced embryonal BAMs upon their depletion and engrafted as monocyte-derived microglia (Mo-Microglia) upon more sustained niche availability. Mo-Microglia expanded comparably to their embryonic counterparts and showed similar longevity. However, monocytes were unable to replicate the unique identity of embryonically-derived BAMs and microglia. Using humanized models, we found that human monocytes exhibited similar behavior, enabling us to identify putative Mo-Microglia in Alzheimer’s disease patients. In mice and humans, the ontogeny of monocytes shaped their identity as brain macrophages. Importantly, mouse fetal liver monocytes exhibited a distinct epigenetic landscape and could develop a bonafide microglial identity. Our results illuminate brain macrophage development and highlight the potential of monocytes as an abundant progenitor source for brain macrophage replacement therapies.

Project description:We used snRNA-sequencing to analzye NeuN-Olig2- thalamic brain cells derived from Hexb-deficient mice upon microglia replacement

Project description:Microglia/macrophage_induced neuroinflammation plays a crucial role in the progression of traumatic brain injury (TBI). However, the involvement of N6_methyladenosine (m6A) RNA modifications in this process remains elusive. Single_cell RNA sequencing (scRNA_seq) and m6A RNA immunoprecipitation sequencing (MeRIP_seq) across multiple time points post_injury revealed a strong correlation between m6A modifications and genes enriched in microglia/macrophage. Furthermore, the m6A demethylase ALKBH5 was identified as a key regulator of dynamic m6A patterns at the injury site. ALKBH5 suppression in microglia/macrophage exacerbated neuroinflammation in vitro and worsened neurological deficits in controlled cortical impact (CCI) models. MeRIP_qPCR and RNA pull_down assays revealed SOCS3 was a downstream target of ALKBH5_mediated m6A demethylation. This demethylation stabilized Socs3 mRNA and enhanced its protein expression, which in turn suppressed neuroinflammation via inhibiting the JAK2_STAT3 pathway. Conversely, SOCS3 depletion impaired functional recovery after injury. These findings unveiled a critical ALKBH5_m6A_SOCS3 regulatory axis that mitigated microglia/macrophage_driven neuroinflammation after TBI, underscoring its potential as a therapeutic intervention target for TBI progression.

Project description:NKT10 adoptive transfer gut microbiota