Project description:The transcriptional regulatory network governing the differentiation and functionality of oligodendrocytes is essential for the formation and maintenance of the myelin sheath, and hence for the proper function of the nervous system. Perturbations in the intricate interplay of transcriptional effectors within this network can lead to a variety of nervous system pathologies. In this study, we have identified Gtf2i-encoded general transcription factor II-I (Tfii-i), as a regulator of key myelination-related genes. Gtf2i deletion from myelinating glia cells in mice led to functional alterations in CNS myelin, including elevated mRNA and protein expression levels of the central myelin component Mbp, enhanced connectivity properties, and thicker myelin wrapping axons with increased diameters. These changes resulted in faster axonal conduction across the corpus callosum, and improved motor coordination. In the PNS, Gtf2i deletion from Schwann cells led to hypermyelination of the tibial branch of the sciatic nerve. Furthermore, we show that, in myelinating oligodendrocytes, Tfii-i directly binds to regulatory elements of Sox10 and Mbp. These findings add to our understanding of myelination regulation and specifically elucidate a cell-autonomous mechanism for Tfii-i in myelinating glia transcriptional network.

Project description:Chemokine-like factor-like MARVEL-transmembrane domain containing protein 5 (CMTM5) is a tetraspan-transmembrane protein highly enriched in oligodendrocytes and central nervous system (CNS) myelin. We analyzed the proteome of myelin biochemically purified from mouse brains upon genetic disruption of the Cmtm5-gene specifically in myelinating cells. An ion mobility-enhanced version of data-independent acquisition (DIA) workflow with alternating low and elevated energy (referred to as UDMSE) was used to compare protein abundance in Cmtm5 cKO and CTRL samples by label-free quantification. Specifically, dynamic range enhancement (DRE)-UDMSE was applied as a dedicated data acquisition mode recently introduced for routine differential myelin proteome profiling. We found that Cmtm5 cKO mice displayed a largely similar myelin proteome composition as control mice and, together with other data such as electron micrographs, concluded that CMTM5 is not essential for myelin biogenesis and composition. However, oligodendroglial Cmtm5-deficiency causes an early-onset progressive axonopathy, presumably following a Wallerian-like pathomechanism. These results indicate that CMTM5 is involved in the function of oligodendrocytes to maintain axonal integrity rather than myelin biogenesis.

Project description:We revisited the proteome of myelin biochemically purified from the brains of healthy c56Bl/6N-mice utilizing complementary proteomic approaches for deep qualitative and quantitative coverage. A data-independent acquisition (DIA) workflow with alternating low and elevated energy (MSE) provided the high dynamic range required for correct quantification of highest-abundance proteins. According to this analysis, the most abundant myelin proteins PLP, MBP, CNP and MOG constitute 38%, 30%, 5% and 1% of the total myelin protein, respectively. Combined with data from an ion mobility-enhanced version of the MSE mode (referred to as UDMSE) and from 1D-gel-based proteomic approaches, we provide the most comprehensive proteome resource of CNS myelin so far and correlate it with published datasets on mRNA and protein abundance profiles of myelin and oligodendrocytes. Using dynamic range enhancement (DRE)-UDMSE as a dedicated data acquisition mode for routine differential myelin proteome profiling, we also establish that the myelin proteome displays only minor changes if assessed after a post mortem-delay of six hours. Together, these data provide a basis for addressing proteomic heterogeneity of myelin in mouse models and human patients with white matter disorders.

Project description:To assess whether the CNS myelin proteome varies within the same species, we used quantitative mass spectrometry to compare myelin purified from mouse brains at three developmental timepoints (P18, P75, 6 months), brains of male and female mice, and four CNS regions (cortex, corpus callosum, optic nerve, spinal cord). We utilized a data-independent acquisition (DIA) workflow with alternating low and elevated energy (MSE) and an ion mobility-enhanced version thereof (referred to as UDMSE) to achieve both, a correct quantification of exceptionally abundant myelin proteins and a comprehensive coverage of the myelin proteome. Label-free protein quantification revealed that the myelin protein composition matures between P18 and P75, and remains largely similar up to 6 months. Proteins with decreasing abundance included cytoskeleton-associated proteins (regulating sheath growth and wrapping), whereas proteins with increasing abundance included all subunits of the septin filament (stabilizing mature myelin), and potentially protective proteins. Among the latter was quinoid dihydropteridine reductase (QDPR), which emerges as a highly specific marker for mature oligodendrocytes and myelin. Conversely, female and male mice display essentially similar myelin proteomes and the myelin-enriched fractions from the four CNS regions mainly differ by the abundance of HCN2-channels in spinal cord myelin as a requirement for particularly long sheaths, apart from the extent of contaminating mitochondrial and synaptic proteins.

Project description:Using the sciatic nerve as a model, we biochemically purified peripheral nervous system (PNS) myelin and systematically assessed its proteome by dedicated, partly ion mobility-enhanced data-independent acquisition (DIA) workflows with alternating low and elevated energy (MSE) modes. Specifically, we used MSE for correct quantification of highest-abundance proteins, UDMSE for deep quantitative proteome coverage, and dynamic range enhancement (DRE)-UDMSE for comparative analysis, the latter mode providing a good compromise between dynamic range, identification rate and instrument run time for routine differential myelin proteome profiling. We found that integration of the proteome data with the total nerve transcriptome is suited to determine comprehensive molecular profiles in healthy nerves and in myelin-related disorders. This work provides the most comprehensive proteome resource thus far to approach development, function and pathology of peripheral myelin, and a straightforward, accurate and sensitive workflow to address myelin diversity in health and disease.

Project description:Rapid nerve conduction in the CNS is facilitated by the insulation of axons with myelin, a specialized oligodendroglial compartment distant from the cell body. Myelin is turned over and adapted throughout life; however, the molecular and cellular basis of myelin dynamics is not well understood. Hypothesizing that only a fraction of all myelin-related mRNAs has been identified so far, we subjected myelin biochemically purified from mouse brains at various ages to RNA sequencing. We find a surprisingly large pool of transcripts abundant and/or enriched in myelin. Furthermore, a comprehensive analysis showed that the myelin transcriptome is closely related to the myelin proteome but clearly distinct from the transcriptomes of oligodendrocytes and brain tissues, suggesting that the incorporation of mRNAs into the myelin compartment is highly selective. The mRNA-pool in myelin displays maturation-dependent dynamic changes of composition, abundance, and functional associations; however ageing-dependent changes after 6 months of age were minor. We suggest that this transcript pool provides a basis for the local modulation of myelin turnover and adaptation, i.e. in the individual internode. A light-weight membrane fraction enriched for myelin was purified from mouse brains as described previously (Jahn et al., Neuromethods, 2013). For RNA-Seq, RNA was isolated from myelin of mice from indicated ages.

Project description:Oligodendrocytes are cells from the central nervous system that can be grouped into precursors, myelin-forming, and non-myelinating perineuronal. The function of perineuronal oligodendrocytes is unknown; it was suggested that they can ensheath denuded axons. We tested this hypothesis. Using cell-specific tags, microarray technology and bioinformatics tools to identify gene expression differences between these subpopulations allowed us to capture the genetic signature of perineuronal oligodendrocytes. Here we report that perineuronal oligodendrocytes are configured for a dual role. As perineuronal, they integrate a repertoire of transcripts designed to create a cell with its own physiological agenda. But they maintain a reservoir of untranslated transcripts encoding the major myelin proteins for – we speculate – a pathological eventuality. We posit that the signature molecules PDGFR-αβ, cytokine PDGF-CC, and the transcription factor Pea3 used – among others - to define the non-myelinating phenotype, may be critical for mounting a myelinating programme during demyelination. Harnessing this capability is of therapeutic value for diseases such as multiple sclerosis. This is the first molecular characterization of perineuronal oligodendrocytes. Experiment Overall Design: Flow Cytometry was used to isolate A2B5/OTMP+ oligodendrocytes from postnatal day 7 rat brain. 4 bioloical replicates were obtained. This data can be compared to the previously submitted oligodendrocyte expression data (GSE5940).

Project description:While myelin is commonly assessed in mice as a model for humans, it remained unclear to which extent their myelin protein composition is similar. We analyzed the proteome of myelin biochemically purified from human white matter by two steps of discontinuous sucrose density gradient centrifugation intermitted by osmotic shocks. We utilized a data-independent acquisition (DIA) workflow with alternating low and elevated energy (MSE) and an ion mobility-enhanced version thereof (referred to as UDMSE) to achieve both, a correct quantification of exceptionally abundant myelin proteins and a comprehensive coverage of the myelin proteome. Label-free protein quantification revealed that the relative abundance of the structural myelin proteins PLP, MBP, CNP and SEPTIN8 correlates well with that in c57Bl/6N-mice. Conversely, multiple other proteins were identified exclusively or predominantly in human or mouse myelin. Species-dependent diversity of myelin protein composition can be instructive when translating from mouse models to humans.

Project description:Background; During the development of the central nervous system, oligodendrocytes generate large amounts of myelin, a multilayered insulating membrane that ensheathes axons, thereby allowing the fast conduction of the action potential and maintaining axonal integrity. Differentiation of oligodendrocytes to myelin-forming cells requires the downregulation of RhoA GTPase activity. Results; To gain insights into the molecular mechanisms of oligodendrocyte differentiation, we performed microarray expression profiling of the oligodendroglial cell line, Oli-neu, treated with the Rho kinase (ROCK) inhibitor, Y-27632 or with conditioned neuronal medium. This resulted in the identification of the transmembrane protein 10 (Tmem10/Opalin), a novel type I transmembrane protein enriched in differentiating oligodendrocytes. In primary cultures, Tmem10 was abundantly expressed in O4-positive oligodendrocytes, but not in oligodendroglial precursor cells, astrocytes, microglia or neurons. In mature oligodendrocytes Tmem10 was enriched in the rims and processes of the cells and was only found to a lesser extent in the membrane sheets. Conclusions; Together, our results demonstrate that Tmem10 is a novel marker for in vitro generated oligodendrocytes. Experiment Overall Design: 2 Subexperiments: Experiment Overall Design: 1. olineu in absence of neurons (control) vs. olineu in presence of neurons Experiment Overall Design: including dye swap design with 6 technical replicates Experiment Overall Design: 2. olineu in presence of neurons (control) vs. Y27631 treated olineu in presence of neurons

Project description:Oligodendrocytes are cells from the central nervous system that can be grouped into precursors, myelin-forming, and non-myelinating perineuronal. The function of perineuronal oligodendrocytes is unknown; it was suggested that they can ensheath denuded axons. We tested this hypothesis. Using cell-specific tags, microarray technology and bioinformatics tools to identify gene expression differences between these subpopulations allowed us to capture the genetic signature of perineuronal oligodendrocytes. Here we report that perineuronal oligodendrocytes are configured for a dual role. As perineuronal, they integrate a repertoire of transcripts designed to create a cell with its own physiological agenda. But they maintain a reservoir of untranslated transcripts encoding the major myelin proteins for – we speculate – a pathological eventuality. We posit that the signature molecules PDGFR-αβ, cytokine PDGF-CC, and the transcription factor Pea3 used – among others - to define the non-myelinating phenotype, may be critical for mounting a myelinating programme during demyelination. Harnessing this capability is of therapeutic value for diseases such as multiple sclerosis. This is the first molecular characterization of perineuronal oligodendrocytes. Keywords: developmental