Project description:Microglia are versatile regulators in brain development and disorders. Emerging evidence links miRNA-mediated regulation to microglial function; however, the exact underlying mechanism remains largely unknown. Here, we discover that miR-137, a neuropsychiatric disorders-associated miRNA, is abundant in the microglial nucleus and exhibits unexpected epigenetic functions in maintaining the global transcriptomic state, core properties, and functions of microglia. Mechanistically, microglial Mir137 deletion increases the accessibility of chromatin, which harbors binding motifs of microglial master transcription factor Pu.1. Our biochemical and bioinformatics analyses suggest that miR-137 can interact with Pu.1, thus influencing Pu.1-mediated gene expression. Importantly, we find that increased Pu.1 binding upregulates the target gene Jdp2, and Jdp2 knockdown markedly suppresses the impaired cellular phenotypes in Mir137 knockout microglia. Collectively, our study provides evidence supporting a notion that miR-137 acts as an epigenetic regulator, and this microglia-specific function is essential to maintain normal adult brain function.

Project description:Microglia are versatile regulators in brain development and disorders. Emerging evidence links miRNA-mediated regulation to microglial function; however, the exact underlying mechanism remains largely unknown. Here, we discover that miR-137, a neuropsychiatric disorders-associated miRNA, is abundant in the microglial nucleus and exhibits unexpected epigenetic functions in maintaining the global transcriptomic state, core properties, and functions of microglia. Mechanistically, microglial Mir137 deletion increases the accessibility of chromatin, which harbors binding motifs of microglial master transcription factor Pu.1. Our biochemical and bioinformatics analyses suggest that miR-137 can interact with Pu.1, thus influencing Pu.1-mediated gene expression. Importantly, we find that increased Pu.1 binding upregulates the target gene Jdp2, and Jdp2 knockdown markedly suppresses the impaired cellular phenotypes in Mir137 knockout microglia. Collectively, our study provides evidence supporting a notion that miR-137 acts as an epigenetic regulator, and this microglia-specific function is essential to maintain normal adult brain function.

Project description:Microglia are versatile regulators in brain development and disorders. Emerging evidence links miRNA-mediated regulation to microglial function; however, the exact underlying mechanism remains largely unknown. Here, we discover that miR-137, a neuropsychiatric disorders-associated miRNA, is abundant in the microglial nucleus and exhibits unexpected epigenetic functions in maintaining the global transcriptomic state, core properties, and functions of microglia. Mechanistically, microglial Mir137 deletion increases the accessibility of chromatin, which harbors binding motifs of microglial master transcription factor Pu.1. Our biochemical and bioinformatics analyses suggest that miR-137 can interact with Pu.1, thus influencing Pu.1-mediated gene expression. Importantly, we find that increased Pu.1 binding upregulates the target gene Jdp2, and Jdp2 knockdown markedly suppresses the impaired cellular phenotypes in Mir137 knockout microglia. Collectively, our study provides evidence supporting a notion that miR-137 acts as an epigenetic regulator, and this microglia-specific function is essential to maintain normal adult brain function.

Project description:Microglia are versatile regulators in brain development and disorders. Emerging evidence links miRNA-mediated regulation to microglial function; however, the exact underlying mechanism remains largely unknown. Here, we discover that miR-137, a neuropsychiatric disorders-associated miRNA, is abundant in the microglial nucleus and exhibits unexpected epigenetic functions in maintaining the global transcriptomic state, core properties, and functions of microglia. Mechanistically, microglial Mir137 deletion increases the accessibility of chromatin, which harbors binding motifs of microglial master transcription factor Pu.1. Our biochemical and bioinformatics analyses suggest that miR-137 can interact with Pu.1, thus influencing Pu.1-mediated gene expression. Importantly, we find that increased Pu.1 binding upregulates the target gene Jdp2, and Jdp2 knockdown markedly suppresses the impaired cellular phenotypes in Mir137 knockout microglia. Collectively, our study provides evidence supporting a notion that miR-137 acts as an epigenetic regulator, and this microglia-specific function is essential to maintain normal adult brain function.

Project description:Microglia are versatile regulators in brain development and disorders. Emerging evidence links miRNA-mediated regulation to microglial function; however, the exact underlying mechanism remains largely unknown. Here, we discover that miR-137, a neuropsychiatric disorders-associated miRNA, is abundant in the microglial nucleus and exhibits unexpected epigenetic functions in maintaining the global transcriptomic state, core properties, and functions of microglia. Mechanistically, microglial Mir137 deletion increases the accessibility of chromatin, which harbors binding motifs of microglial master transcription factor Pu.1. Our biochemical and bioinformatics analyses suggest that miR-137 can interact with Pu.1, thus influencing Pu.1-mediated gene expression. Importantly, we find that increased Pu.1 binding upregulates the target gene Jdp2, and Jdp2 knockdown markedly suppresses the impaired cellular phenotypes in Mir137 knockout microglia. Collectively, our study provides evidence supporting a notion that miR-137 acts as an epigenetic regulator, and this microglia-specific function is essential to maintain normal adult brain function.

Project description:Microglia are versatile regulators in brain development and disorders. Emerging evidence links miRNA-mediated regulation to microglial function; however, the exact underlying mechanism remains largely unknown. Here, we discover that miR-137, a neuropsychiatric disorders-associated miRNA, is abundant in the microglial nucleus and exhibits unexpected epigenetic functions in maintaining the global transcriptomic state, core properties, and functions of microglia. Mechanistically, microglial Mir137 deletion increases the accessibility of chromatin, which harbors binding motifs of microglial master transcription factor Pu.1. Our biochemical and bioinformatics analyses suggest that miR-137 can interact with Pu.1, thus influencing Pu.1-mediated gene expression. Importantly, we find that increased Pu.1 binding upregulates the target gene Jdp2, and Jdp2 knockdown markedly suppresses the impaired cellular phenotypes in Mir137 knockout microglia. Collectively, our study provides evidence supporting a notion that miR-137 acts as an epigenetic regulator, and this microglia-specific function is essential to maintain normal adult brain function.

Project description:Microglia are versatile regulators in brain development and disorders. Emerging evidence links miRNA-mediated regulation to microglial function; however, the exact underlying mechanism remains largely unknown. Here, we discover that miR-137, a neuropsychiatric disorders-associated miRNA, is abundant in the microglial nucleus and exhibits unexpected epigenetic functions in maintaining the global transcriptomic state, core properties, and functions of microglia. Mechanistically, microglial Mir137 deletion increases the accessibility of chromatin, which harbors binding motifs of microglial master transcription factor Pu.1. Our biochemical and bioinformatics analyses suggest that miR-137 can interact with Pu.1, thus influencing Pu.1-mediated gene expression. Importantly, we find that increased Pu.1 binding upregulates the target gene Jdp2, and Jdp2 knockdown markedly suppresses the impaired cellular phenotypes in Mir137 knockout microglia. Collectively, our study provides evidence supporting a notion that miR-137 acts as an epigenetic regulator, and this microglia-specific function is essential to maintain normal adult brain function.

Project description:Recent genetic evidence has revealed microRNA-137 (miR-137) as a risk gene in schizophrenia and autism spectrum disorder (ASD), and the following cellular studies have demonstrated the importance of miR-137 in regulating neurogenesis. We have generated miR-137 knockout mice which display behaviors that resemble some symptoms of these two diseases. To investigate the underlying molecular mechanism, we performed comprehensive analyses of the entire RNA and protein molecules of the miR-137 mouse brains. The dataset uploaded here is the raw data of the mass spectrometry-based whole proteome analysis of the six miR-137 mouse brains: wild-type, heterozygous (miR-137+/–) and homozygous (miR-137–/–) from two different litters. The tandem mass tag (TMT) methodology was employed in this proteomics analysis for the quantitation. The sample channels are: 128C (miR-137+/+, litter 1), 129N (miR-137+/–, litter 1), 129C (miR-137–/–, litter 1), 130N (miR-137+/+, litter 2), 130C (miR-137+/–, litter 2), and 131N (miR-137–/–, litter 2).

Project description:miR-137 plays critical roles in the nervous system and tumor development. An increase in its expression is required for neuronal differentiation while its reduction is implicated in gliomagenesis. To evaluate the potential of miR-137 in glioblastoma therapy, we conducted genome-wide target mapping in glioblastoma cells by measuring levels of associations between PABP and mRNAs in cells transfected with miR-137 mimics vs. controls via RIPSeq. Impact on mRNA levels was also measured by RNASeq. By combining the results of both experimental approaches, 1468 genes were determined to be negatively impacted by miR-137; among them, 595 (40%) contain miR-137 predicted sites. The most relevant targets include oncogenic proteins and players in neurogenesis like c-KIT, YBX1, AKT2, CDC42, CDK6 and TGFβ2. Interestingly, we observed that several identified miR-137 targets are also predicted to be regulated by miR-124, miR-128 and miR-7, which are equally implicated in neuronal differentiation and gliomagenesis. We suggest that the concomitant increase of these four miRNAs in neuronal stem cells or their repression in tumor cells could produce a robust regulatory effect with major consequences to neuronal differentiation and tumorigenesis. Identification of genes affected by miR137 transfection via RIP-Seq and RNA-Seq in U251 and U343 cells

Project description:Currently, it is unclear if all monocyte subsets exhibit osteoclastogenic potential. Furthermore, the role of lineage determining TFs in regulating OC differentiation on a genome-wide scale remains poorly understood. In this study, we utilized a novel Irf8 conditional knockout (Irf8 cKO) mouse model to characterize the importance of IRF8 in OC progenitor development and epigenetic regulation of OC differentiation. We performed RNA-seq on Irf8 gWT, gKO, cWT and cKO BMMs, preosteoclasts (PreOCs), and OCs. Cells were analyzed prior to (BMMs) and 3 days (PreOCs) and 6 days (OCs) after RANKL stimulation. Here we show that greater a number of genes are significantly upregulated in Irf8 cKO OCs when compared to WT and Irf8 gKO OCs. Altogether, our data shows that Irf8 cKO mice provide more precise/reliable OC-specific transcriptomic results when compared to Irf8 gKO mice.