Project description:MEF2C is a transcription factor with wide ranging roles and has specifically been implicated in restraining the microglial inflammatory response, participating in nervous system development, and contributing to aging and neurological disease. While MEF2C murine models have provided critical insights, the homeostatic and disease-associated functions of MEF2C in human microglia remain unclear. To examine this question, we profile microglia differentiated from isogenic, CRISPR-modified MEF2C haploinsufficient and knockout induced-pluripotent stem cell (iPSC) lines. A combination of transcriptomic, epigenetic and functional analyses revealed that loss of MEF2C leads to a hyperinflammatory microglial phenotype with broad impairment in phagocytosis, lipid accumulation, lysosomal dysfunction and elevated basal inflammatory cytokine and inflammasome activation. Transcriptomic and epigenetic approaches identified substantial overlap between reduced microglial MEF2C expression and primary brain idiopathic autism datasets, suggesting a broader role of microglial MEF2C dysregulation in idiopathic autism especially as relates to the transcription factors repressive functions. Reduced MEF2C expression has been associated with brain aging, and we find that reduction in MEF2C leads to a premature aging or senescence associated phenotype in microglia. These findings are extended to a murine xenotransplantation model wherein reductions in MEF2C expression in human microglia leads to an ameboid hyperinflammatory phenotype with lysosomal and lipid dysfunction. Taken together, these studies reveal novel aspects of microglial MEF2C function that contribute to homeostasis and development of neurological disease.

Project description:MEF2C is a transcription factor with wide ranging roles and has specifically been implicated in restraining the microglial inflammatory response, participating in nervous system development, and contributing to aging and neurological disease. While MEF2C murine models have provided critical insights, the homeostatic and disease-associated functions of MEF2C in human microglia remain unclear. To examine this question, we profile microglia differentiated from isogenic, CRISPR-modified MEF2C haploinsufficient and knockout induced-pluripotent stem cell (iPSC) lines. A combination of transcriptomic, epigenetic and functional analyses revealed that loss of MEF2C leads to a hyperinflammatory microglial phenotype with broad impairment in phagocytosis, lipid accumulation, lysosomal dysfunction and elevated basal inflammatory cytokine and inflammasome activation. Transcriptomic and epigenetic approaches identified substantial overlap between reduced microglial MEF2C expression and primary brain idiopathic autism datasets, suggesting a broader role of microglial MEF2C dysregulation in idiopathic autism especially as relates to the transcription factors repressive functions. Reduced MEF2C expression has been associated with brain aging, and we find that reduction in MEF2C leads to a premature aging or senescence associated phenotype in microglia. These findings are extended to a murine xenotransplantation model wherein reductions in MEF2C expression in human microglia leads to an ameboid hyperinflammatory phenotype with lysosomal and lipid dysfunction. Taken together, these studies reveal novel aspects of microglial MEF2C function that contribute to homeostasis and development of neurological disease.

Project description:MEF2C encodes a transcription factor that is critical in nervous system development. To examine disease-associated functions of MEF2C in human microglia, we profiled microglia differentiated from isogenic MEF2C-haploinsufficient and -knockout induced pluripotent stem cell lines. Complementary transcriptomic and functional analyses revealed that loss of MEF2C lead to a hyperinflammatory phenotype with broad phagocytic impairment, lipid accumulation, lysosomal dysfunction, and elevated basal inflammatory cytokine secretion. Genome-wide profiling of MEF2C-bound sites coupled with the active regulatory landscape enabled inference of its transcriptional functions and potential mechanisms for MEF2C-associated cellular functions. Transcriptomic and epigenetic approaches identified substantial overlap with idiopathic autism datasets, suggesting a broader role of human microglial MEF2C dysregulation in idiopathic autism. In a murine xenotransplantation model, loss of MEF2C led to morphological, lysosomal and lipid abnormalities in human microglia in vivo. Altogether, these studies reveal mechanisms by which reduced microglial MEF2C could contribute to the development of neurological diseases.

Project description:Intrinsic immune checkpoints in microglia are vital for maintaining homeostatic immune response and preventing overactivation. Neuroinflammation, frequently driven by microglial overactivation, significantly influences a wide range of neurological disorders. While MEF2C has been associated with a syndromic form of autism spectrum disorder (ASD) and various other neurological disorders in humans, its specific role as an immune checkpoint remains poorly defined. By harnessing MEF2C-knockout (KO) induced microglia-like cells (iMGLs) through differentiation from human pluripotent stem cells (hPSCs), here we observed that these cells, following LPS stimulation, exhibited overactivation similar to patterns seen in various neurological disorders. High-throughput screening identified BMS265246, a CDK2 inhibitor, as effective in specifically suppressing the overactivated phenotypes of MEF2C-KO iMGLs, and in restoring inflammatory response closer to normal levels. Mechanistically, we uncovered that MEF2C regulates p21 transcription, a critical step in preventing CDK2 activation in microglia. Loss of MEF2C results in CDK2-induced RB phosphorylation and degradation, leading to enhanced NF-κB p65 subunit nuclear translocation and exacerbated inflammatory responses. Remarkably, BMS265246 treatment rectified microglial overactivation and ASD-like behaviors in both global and microglia-specific Mef2C heterozygous knockout mice. Overall, our findings elucidated a previously unknown immune checkpoint mechanism governed by MEF2C, and highlighted CDK2 as a potential key factor driving neuroinflammation through microglial overactivation. These insights positions CDK2 as a promising therapeutic target for treating various neurological diseases influenced by overactivated microglia.

Project description:Neuroinflammation driven by microglial overactivation is a significant contributor across a diverse range of neurological disorders. While MEF2C mutations have been associated with a syndromic form of autism spectrum disorder (ASD) and various other neurological disorders in humans, the role of MEF2C as a key immune checkpoint to restrain microglial overactivation remains elusive. In this study, we established MEF2C-knockout (KO) induced microglia-like cells (iMGLs) via differentiation of corresponding human pluripotent stem cells, and subsequently treated with LPS, as a disease model of overactivated microglia. Through high-throughput screening, we identified BMS265246, a CDK2 inhibitor, which effectively normalized overactivated phenotypes in LPS-stimulated MEF2C-KO iMGLs, nearing levels seen in WT counterparts. Mechanistically, absence of MEF2C instigated a sequential cascade encompassing p21 downregulation, CDK2 activation, RB phosphorylation and degradation, and NF-κB p65 subunit nuclear translocation, thereby intensifying inflammatory responses. Remarkably, BMS265246 treatment significantly rectified microglial overactivation and ASD behavioral defects in both global and microglia-specific Mef2C heterozygous mice. Overall, our findings elucidate a novel protective mechanism governed by MEF2C, and unveil CDK2 as a promising therapeutic target for treating various diseases influenced by overactivated microglia with aberrant MEF2C expression and/or CDK2 activation.

Project description:Microglia repair injury and maintain homeostasis in the brain, but whether aberrant microglial activation can contribute to neurodegeneration remains unclear. Here, we use transcriptome profiling to demonstrate that deficiency in frontotemporal dementia (FTD) gene progranulin (Grn) leads to an age-dependent, progressive up-regulation of lysosomal and innate immunity genes, increased complement production, and synaptic pruning activity in microglia. During aging, Grn-/- mice show profound accumulation of microglia and preferential elimination of inhibitory synapses in the ventral thalamus, which contribute to hyperexcitability in the thalamocortical circuits and obsessive-compulsive disorder (OCD)-like grooming behaviors. Remarkably, blocking complement activation by deleting C1qa gene significantly reduces synaptic pruning by Grn-/- microglia, and mitigates neurodegeneration, behavioral phenotypes and premature mortality in Grn-/- mice. These results uncover a previously unrecognized role of progranulin in suppressing microglia activation during aging, and support the idea that blocking complement activation is a promising therapeutic target for neurodegeneration caused by progranulin deficiency. Gene expression study in multiple brain regions from a mouse model of progranulin deficiency Please note that 9 outlier samples were excluded from data analysis. Therefore, there are 326 raw data columns (i.e. 163 samples) in the non_normalized data matrix while 154 samples are represented here.

Project description:Microdeletions of the MEF2C gene are linked to a syndromic form of autism termed MEF2C haploinsufficiency syndrome (MCHS). Here, we show that MCHS-associated missense mutations cluster in the conserved DNA binding domain and disrupt MEF2C DNA binding. DNA binding-deficient global Mef2c heterozygous mice (Mef2c-Het) display numerous MCHS-like behaviors, including autism-related behaviors, as well as deficits in cortical excitatory synaptic transmission. We find that hundreds of genes are dysregulated in Mef2c-Het cortex, including significant enrichments of autism risk and excitatory neuron genes. In addition, we observe an enrichment of upregulated microglial genes, but not due to neuroinflammation in the Mef2c-Het cortex. Importantly, conditional Mef2c heterozygosity in forebrain excitatory neurons reproduces a subset of the Mef2c-Het phenotypes, while conditional Mef2c heterozygosity in microglia reproduces social deficits and repetitive behavior. Together our findings suggest that MEF2C regulates typical brain development and function through multiple cell types, including excitatory neuronal and neuroimmune populations.

Project description:Heterozygous loss-of-function mutations or deletions of the MEF2C gene cause a neurodevelopmental disorder, termed MEF2C Haploinsufficiency syndrome (MCHS), that is characterized by autism spectrum disorder, intellectual disability, seizures, and other neurological symptoms. In mice, global Mef2c heterozygosity produces numerous behavioral phenotypes reminiscent of MCHS. MEF2C is highly expressed in multiple cell populations in the developing brain, including GABAergic inhibitory neurons. While MEF2C hypofunction in excitatory neurons or microglia alter neurotypical behaviors and brain circuit function, the impact of MEF2C heterozygosity in GABAergic neurons remains unknown.

Project description:Aging is the predominant risk factor for neurodegenerative diseases. One key phenotype as brain ages is the aberrant innate immune response characterized by proinflammation. However, the molecular mechanisms underlying aging-associated proinflammation are poorly defined. Whether chronic inflammation plays a causal role in cognitive decline in aging and neurodegeneration has not been established. Here we established a mechanistic link between chronic inflammation and aging microglia, and demonstrated a causal role of aging microglia in neurodegenerative cognitive deficits. Expression of microglial SIRT1 reduces with the aging of microglia. Genetic reduction of microglial SIRT1 elevates IL-1β selectively, and exacerbates cognitive deficits in aging and in transgenic mouse models of frontotemporal dementia (FTD). Interestingly, the selective activation of IL-1β transcription by SIRT1 deficiency is likely mediated through hypomethylating the proximal promoter of IL-1β. Consistent with our findings in mice, selective hypomethylation of IL-1β at two CpG sites are found in normal aging humans and demented patients with tauopathy. Our findings reveal a novel epigenetic mechanism in aging microglia that contributes to cognitive deficits in neurodegenerative diseases. Study of changes related to alterations of SIRT1 levels in microglia of young and aged animals and in models of neurodegenerative dementia

Project description:Microglia play critical roles in maintaining brain development, homeostasis, and response to aging and diseases like Alzheimer's disease (AD). Genetic studies highlight microglia's role in AD susceptibility, but the mechanisms mediating protective responses remain largely unknown. Gpr56/Adgrg1, is one of the few genes specifically expressed in yolk-sac-derived microglia, as compared with other mononuclear phagocytes. This study reveals its role in AD pathology, particularly in modulating microglial protective responses to amyloid deposition. Utilizing constitutive and inducible microglial Adgrg1 knockouts in the 5xFAD mouse model, we demonstrate that Adgrg1 deficiency leads to increased amyloid deposition, exacerbated neuropathology, and accelerated cognitive impairment. Transcriptomic analyses reveal a distinct microglial state characterized by downregulated genes associated with homeostasis, phagocytosis, and lysosomal functions. Functional assays in mouse models and human iPSC-derived microglia support the requirement for microglial ADGRG1 in efficient Aβ phagocytosis. Collectively, these results uncover a GPCR-dependent mechanism that instructs beneficial microglial functions in response to Aβ, pointing towards potential therapeutic strategies designed to alleviate disease progression by enhancing microglial functional competence.