Project description:To quantitative analysis of transcriptome changes caused by lnc-OPC knockdown during OPC differentiation from NSC, lentivirus-based short hairpin RNAs were used to knockdown the lnc-OPC expression in a neural stem cell culture . Subsequently, puromycin-selected NSCs were differentiated to OPC in culture for three days.RNA-Seq was performed on the polyadenylated fraction of RNA isolated from cell samples. DEseq was used for differential gene expression analysis caused by lnc-OPC knockdown. GO functional term enrichment analysis of differential gene expression caused by lnc-OPC knockdown, revealed significant enrichment of ‘oligodendrocyte development’, ‘oligodendrocyte differentiation’, ‘glia cell development’, and ‘axon ensheathment’ terms that are associated with oligodendrogenesis. mRNA profiles of differentiiated NSC samples after lnc-OPC knockdown by RNA-sequencing.

Project description:Oligodendrocyte progenitor cells (OPC) were cultured in the presence of LPC 18:1-Cy5. Proteins interacting with LPC 18:1-Cy5 were UV crossed linked and cell lysates were separated via isoelectric focusing gel electrophoresis. Band was cut out from gel and processed for mass spectrometry. OPC lysates were also incubated with LPC 18:1-micelles and allowed to interact with OPC proteins. Samples were separated using sucrose gradient (Liposome floatation assay), top fraction was collected and processed for mass spectrometry.

Project description:To identify factors involved in OPC senescence, we compared gene expressions between OPC-CG4, OPC-FCS and OPC-Rev. We established OPC senescence model system, in which OPC become senescent in the presence of high concentration of FCS. This phenotypes were kept even when the medium was switched to their optimal serum-free medium.

Project description:To identify factors involved in OPC senescence, we compared gene expressions between OPC-CG4, OPC-FCS and OPC-Rev.

Project description:Endogenous oligodendrocyte progenitor cells (OPCs) are a promising target to improve functional recovery after spinal cord injury (SCI) by remyelinating denuded, and therefore vulnerable, axons. Demyelination is the result of a primary insult and secondary injury, leading to conduction blocks and long-term degeneration of the axons, which subsequently can lead to the loss of their neuron. In response to SCI, dormant OPCs can be activated and subsequently start to proliferate and differentiate into mature myelinating oligodendrocytes (OLs). Therefore, researchers strive to control OPC responses, and utilize small molecule screening approaches in order to identify mechanisms of OPC activation, proliferation, migration and differentiation.

Project description:Mfsd2a plays an important role in accretion of essential fatty acids such as docosahexaenoic acid (DHA) from the periphery into the brain. Loss of Mfsd2a in humans leads to microcephaly and hypomyelination. The precise impact of lipid species transported by Mfsd2a on myelination is not known. Using OPC specific deletion of Mfsd2a (2aOKO) in mice we found that OPC cell state, differentiation and oligodendrocytes maturation is disrupted resulting in hypomyelination. RNAsequencing and differential gene expression analysis was performed on OPC and O4 cells from postnatal mouse brain to understand the influence of Mfsd2a on oligodendrocyte development.

Project description:Like neurons, oligodendrocytes (OL) are cells with elaborate morphology that probably require asymmetrical spatial regulation of biological processes. Formation of membrane protrusions is critical for OL development and interaction with axons. We hypothesized that the enrichment of specific mRNAs in protrusions of oligodendrocyte precursor cells (OPC) is important for morphological differentiation, thus having an impact in myelination. To explore this hypothesis, we established a modified Boyden chamber system to physically separate soma from membrane protrusions of rat primary OPC cultured in vitro for 24h. We performed a whole transcriptome analysis (RNAseq) of primary rat OPC soma and membrane protrusion fractions and found a subcellular enrichment of mRNAs in these structures during initial protrusion formation. At the very initial stage of OPC protrusion extension, there is a significant subcellular enrichment of transcripts encoding proteins related to cellular component assembly and cytoskeleton organization, particularly of actin-related molecules. This suggests that the regulation of the cytoskeleton dynamics may be locally controlled in OPCs and probably relevant for their differentiation program.

Project description:Here, we have used single-cell RNA sequencing (scRNA-seq), single-cell ATAC sequencing (scATAC-seq) and spatial transcriptomics to characterize murine cortical OPCs throughout postnatal life. During development, we identify two differentially-localized PDGFRα-positive OPC populations that are transcriptionally and epigenetically distinct. One population (active or actOPCs) is metabolically active and is enriched in white matter. The second (homeostatic or hOPCs) is less active, enriched in grey matter, and predicted to derive from actOPCs. In adulthood, these two groups are transcriptionally but not epigenetically distinct, and relative to developing OPCs are less active metabolically with much less open chromatin. When adult oligodendrogenesis is enhanced following experimental demyelination, adult OPCs do not reacquire a developmental open chromatin state, and the oligodendrogenesis trajectory is distinct from that seen neonatally. These data support a model where two OPC populations subserve distinct postnatal functions, and where neonatal and adult OPC-mediated oligodendrogenesis are fundamentally different.

Project description:Here, we have used single-cell RNA sequencing (scRNA-seq), single-cell ATAC sequencing (scATAC-seq) and spatial transcriptomics to characterize murine cortical OPCs throughout postnatal life. During development, we identify two differentially-localized PDGFRα-positive OPC populations that are transcriptionally and epigenetically distinct. One population (active or actOPCs) is metabolically active and is enriched in white matter. The second (homeostatic or hOPCs) is less active, enriched in grey matter, and predicted to derive from actOPCs. In adulthood, these two groups are transcriptionally but not epigenetically distinct, and relative to developing OPCs are less active metabolically with much less open chromatin. When adult oligodendrogenesis is enhanced following experimental demyelination, adult OPCs do not reacquire a developmental open chromatin state, and the oligodendrogenesis trajectory is distinct from that seen neonatally. These data support a model where two OPC populations subserve distinct postnatal functions, and where neonatal and adult OPC-mediated oligodendrogenesis are fundamentally different.

Project description:Here, we have used single-cell RNA sequencing (scRNA-seq), single-cell ATAC sequencing (scATAC-seq) and spatial transcriptomics to characterize murine cortical OPCs throughout postnatal life. During development, we identify two differentially-localized PDGFRα-positive OPC populations that are transcriptionally and epigenetically distinct. One population (active or actOPCs) is metabolically active and is enriched in white matter. The second (homeostatic or hOPCs) is less active, enriched in grey matter, and predicted to derive from actOPCs. In adulthood, these two groups are transcriptionally but not epigenetically distinct, and relative to developing OPCs are less active metabolically with much less open chromatin. When adult oligodendrogenesis is enhanced following experimental demyelination, adult OPCs do not reacquire a developmental open chromatin state, and the oligodendrogenesis trajectory is distinct from that seen neonatally. These data support a model where two OPC populations subserve distinct postnatal functions, and where neonatal and adult OPC-mediated oligodendrogenesis are fundamentally different.