Project description:Cellular maturation is an adaptive process essential for tissue formation and function, yet distinct from the initial steps of differentiation and cell fate specification. Understanding the regulation of cell maturation may inform underlying mechanisms of disease or new approaches to regenerative medicine. In the central nervous system, failed generation of mature oligodendrocytes contributes to numerous diseases including multiple sclerosis. Here, we report a transcriptional mechanism that governs the timing of oligodendrocyte maturation. After differentiation, the transcription factor SOX6 redistributes from super enhancers in proliferating oligodendrocyte progenitor cells to cluster across specific gene bodies in immature oligodendrocytes. These sites exhibit extensive chromatin decondensation and transcription, which abruptly turns off upon maturation. Suppression of SOX6 deactivates these immaturity loci, resulting in rapid transition to mature myelinating oligodendrocytes. Cells harboring this immature oligodendrocyte SOX6 gene signature are specifically enriched in multiple sclerosis patient brains, suggesting that failed maturation contributes to disease pathology. Administration of a Sox6-targeting antisense oligonucleotide in postnatal mice drove precocious oligodendrocyte maturation. Our findings reveal that SOX6 governs oligodendrocyte maturation and that its targeting could inform therapeutic strategies for enhancing myelin regeneration in neurodevelopmental and neurodegenerative diseases.

Project description:Cellular maturation is an adaptive process essential for tissue formation and function, yet distinct from the initial steps of differentiation and cell fate specification. Understanding the regulation of cell maturation may inform underlying mechanisms of disease or new approaches to regenerative medicine. In the central nervous system, failed generation of mature oligodendrocytes contributes to numerous diseases including multiple sclerosis. Here, we report a transcriptional mechanism that governs the timing of oligodendrocyte maturation. After differentiation, the transcription factor SOX6 redistributes from super enhancers in proliferating oligodendrocyte progenitor cells to cluster across specific gene bodies in immature oligodendrocytes. These sites exhibit extensive chromatin decondensation and transcription, which abruptly turns off upon maturation. Suppression of SOX6 deactivates these immaturity loci, resulting in rapid transition to mature myelinating oligodendrocytes. Cells harboring this immature oligodendrocyte SOX6 gene signature are specifically enriched in multiple sclerosis patient brains, suggesting that failed maturation contributes to disease pathology. Administration of a Sox6-targeting antisense oligonucleotide in postnatal mice drove precocious oligodendrocyte maturation. Our findings reveal that SOX6 governs oligodendrocyte maturation and that its targeting could inform therapeutic strategies for enhancing myelin regeneration in neurodevelopmental and neurodegenerative diseases.

Project description:Cellular maturation is an adaptive process essential for tissue formation and function, yet distinct from the initial steps of differentiation and cell fate specification. Understanding the regulation of cell maturation may inform underlying mechanisms of disease or new approaches to regenerative medicine. In the central nervous system, failed generation of mature oligodendrocytes contributes to numerous diseases including multiple sclerosis. Here, we report a transcriptional mechanism that governs the timing of oligodendrocyte maturation. After differentiation, the transcription factor SOX6 redistributes from super enhancers in proliferating oligodendrocyte progenitor cells to cluster across specific gene bodies in immature oligodendrocytes. These sites exhibit extensive chromatin decondensation and transcription, which abruptly turns off upon maturation. Suppression of SOX6 deactivates these immaturity loci, resulting in rapid transition to mature myelinating oligodendrocytes. Cells harboring this immature oligodendrocyte SOX6 gene signature are specifically enriched in multiple sclerosis patient brains, suggesting that failed maturation contributes to disease pathology. Administration of a Sox6-targeting antisense oligonucleotide in postnatal mice drove precocious oligodendrocyte maturation. Our findings reveal that SOX6 governs oligodendrocyte maturation and that its targeting could inform therapeutic strategies for enhancing myelin regeneration in neurodevelopmental and neurodegenerative diseases.

Project description:Cellular maturation is an adaptive process essential for tissue formation and function, yet distinct from the initial steps of differentiation and cell fate specification. Understanding the regulation of cell maturation may inform underlying mechanisms of disease or new approaches to regenerative medicine. In the central nervous system, failed generation of mature oligodendrocytes contributes to numerous diseases including multiple sclerosis. Here, we report a transcriptional mechanism that governs the timing of oligodendrocyte maturation. After differentiation, the transcription factor SOX6 redistributes from super enhancers in proliferating oligodendrocyte progenitor cells to cluster across specific gene bodies in immature oligodendrocytes. These sites exhibit extensive chromatin decondensation and transcription, which abruptly turns off upon maturation. Suppression of SOX6 deactivates these immaturity loci, resulting in rapid transition to mature myelinating oligodendrocytes. Cells harboring this immature oligodendrocyte SOX6 gene signature are specifically enriched in multiple sclerosis patient brains, suggesting that failed maturation contributes to disease pathology. Administration of a Sox6-targeting antisense oligonucleotide in postnatal mice drove precocious oligodendrocyte maturation. Our findings reveal that SOX6 governs oligodendrocyte maturation and that its targeting could inform therapeutic strategies for enhancing myelin regeneration in neurodevelopmental and neurodegenerative diseases.

Project description:Cellular maturation is an adaptive process essential for tissue formation and function, yet distinct from the initial steps of differentiation and cell fate specification. Understanding the regulation of cell maturation may inform underlying mechanisms of disease or new approaches to regenerative medicine. In the central nervous system, failed generation of mature oligodendrocytes contributes to numerous diseases including multiple sclerosis. Here, we report a transcriptional mechanism that governs the timing of oligodendrocyte maturation. After differentiation, the transcription factor SOX6 redistributes from super enhancers in proliferating oligodendrocyte progenitor cells to cluster across specific gene bodies in immature oligodendrocytes. These sites exhibit extensive chromatin decondensation and transcription, which abruptly turns off upon maturation. Suppression of SOX6 deactivates these immaturity loci, resulting in rapid transition to mature myelinating oligodendrocytes. Cells harboring this immature oligodendrocyte SOX6 gene signature are specifically enriched in multiple sclerosis patient brains, suggesting that failed maturation contributes to disease pathology. Administration of a Sox6-targeting antisense oligonucleotide in postnatal mice drove precocious oligodendrocyte maturation. Our findings reveal that SOX6 governs oligodendrocyte maturation and that its targeting could inform therapeutic strategies for enhancing myelin regeneration in neurodevelopmental and neurodegenerative diseases.

Project description:Altered oligodendrocyte heterogeneity in Multiple sclerosis.

Project description:Three mouse models of human central nervous system pathologies were selected for analyzing gene expression changes compared to wild type normal brain. The selected models are: TgAPP23 for Alzheimerﾒs disease (see Sturchler-Pierrat, C., Abramowski, D., Duke, M., Wiederhold, K.H., Mistl, C., Rothacher, S., Ledermann, B., B?rki, K., Frey, P., Paganetti, P.A., Waridel, C., Calhoun, M.E., Jucker, M., Probst, A., Staufenbiel, M. and Sommer, B. (1997) Two amyloid precursor protein transgenic mouse models with Alzheimer disease-like pathology. PNAS 94, 13287-13292), Tg6074 for multiple sclerosis (see Akassoglou K, Bauer J, Kassiotis G, Pasparakis M, Lassmann H, Kollias G and Probert L. (1998). Oligodendrocyte apoptosis and primary demyelination induced by local TNF/p55TNF receptor signaling in the central nervous system of transgenic mice: models for multiple sclerosis with primary oligodendrogliopathy. Am J Pathol. 153, 801-813) and permanent mid-cerebral artery occlusion for stroke (see Welsh, F.A., Sakamoto, T., McKee, A.E. and Sims, R.E. (1987) Effect of lactacidosis on pyridine nucleotide stability during ischemia in mouse brain. J Neurochem. 49, 846-851). Trangenic mice were grown to appropriate age, so that they would manifest the symptoms of disease or disease was induced by a surgical procedure to adult mice. Mice were sacrificed and half brains were removed at selected time points after disease onset for RNA extraction and subsequent array hybridization.

Project description:Altered human oligodendrocyte heterogeneity in multiple sclerosis

Project description:This experiment was carried out in the context of a whole-genome sequencing study in 4 affected and 4 unaffected relatives of a consanguineous Italian family characterized by the high prevalence of multiple sclerosis. These data were used to evaluate differences in GRAMD1B gene expression in whole blood comparing healthy and affected subjects of the family. Functional experiments have been subsequently performed to evaluate the involvement of this gene in multiple sclerosis.

Project description:Multiple sclerosis involves an aberrant autoimmune response and progressive failure of remyelination in the central nervous system. Prevention of neural degeneration and subsequent disability requires remyelination through the generation of new oligodendrocytes, but current treatments exclusively target the immune system. Oligodendrocyte progenitor cells are stem cells in the central nervous system and the principal source of myelinating oligodendrocytes. These cells are abundant in demyelinated regions of patients with multiple sclerosis, yet fail to differentiate, thereby representing a cellular target for pharmacological intervention. To discover therapeutic compounds for enhancing myelination from endogenous oligodendrocyte progenitor cells, we screened a library of bioactive small molecules on mouse pluripotent epiblast stem-cell-derived oligodendrocyte progenitor cells. Here we show seven drugs function at nanomolar doses selectively to enhance the generation of mature oligodendrocytes from progenitor cells in vitro. Two drugs, miconazole and clobetasol, are effective in promoting precocious myelination in organotypic cerebellar slice cultures, and in vivo in early postnatal mouse pups. Systemic delivery of each of the two drugs significantly increases the number of new oligodendrocytes and enhances remyelination in a lysolecithin-induced mouse model of focal demyelination. Administering each of the two drugs at the peak of disease in an experimental autoimmune encephalomyelitis mouse model of chronic progressive multiple sclerosis results in striking reversal of disease severity. Immune response assays show that miconazole functions directly as a remyelinating drug with no effect on the immune system, whereas clobetasol is a potent immunosuppressant as well as a remyelinating agent. Mechanistic studies show that miconazole and clobetasol function in oligodendrocyte progenitor cells through mitogen-activated protein kinase and glucocorticoid receptor signalling, respectively. Furthermore, both drugs enhance the generation of human oligodendrocytes from human oligodendrocyte progenitor cells in vitro. Collectively, our results provide a rationale for testing miconazole and clobetasol, or structurally modified derivatives, to enhance remyelination in patients. RNA sequencing of oligodendrocyte progenitor cells treated with vehicle, miconazole or clobetasol for 0, 2, 6, or 12 hours. Cells were plated 1.5 hours prior to addition of drug.