Project description:Strategies for treating progressive multiple sclerosis (MS) remain limited. Here, we found that miR-145-5p is overabundant uniquely in chronic lesion tissues from secondary progressive MS patients. We induced both acute and chronic demyelination in miR-145 knockout mice to determine its contributions to remyelination failure. Following acute demyelination, no advantage to miR-145 loss could be detected. However, after chronic demyelination, animals with miR-145 loss demonstrated increased remyelination and functional recovery, coincident with altered presence of astrocytes and microglia within the corpus callosum relative to wild-type animals. This improved response in miR-145 knockout animals coincided with a pathological upregulation of miR-145-5p in wild-type animals with chronic cuprizone exposure, paralleling human chronic lesions. Furthermore, miR-145 overexpression specifically in oligodendrocytes (OLs) severely stunted differentiation and negatively impacted survival. RNAseq analysis showed altered transcriptome in these cells with downregulated major pathways involved in myelination. Our data suggest that pathological accumulation of miR-145-5p is a distinctive feature of chronic demyelination and is strongly implicated in the failure of remyelination, possibly due to the inhibition of OL differentiation together with alterations in other glial cells. This is mirrored in chronic MS lesions, and thus miR-145-5p serves as a potential relevant therapeutic target in progressive forms of MS.

Project description:Impairment of oligodendrocyte (OL) myelinogenic potential, rather than inability of oligodendrocyte precursors to differentiate, is implicated in remyelination failure in demyelinating diseases such as multiple sclerosis. However, the mechanisms underlying myelinogenesis and age-related decline in remyelination remain elusive. Here, we identify a mature-OL-active transcriptional regulator Dor as a critical mediator of CNS myelination and remyelination. Genomic occupancy and transcriptomic analyses revealed that Dor interacts with Sox10 and targets the enhancers of myelinogenesis-regulatory genes including a newly identified OL-enriched nuclear factor Prr18 required for OL maturation. Metabolomic profiling showed that Dor is critical for alpha-ketoglutarate (alpha-KG) production and lipid biosynthesis. Supplementation with alpha-KG enhanced lipid biosynthesis and restored OL maturation defects in Dor-mutant mice while reversing the age-associated decline in remyelination efficiency and memory deficits in aging mice. Thus, our findings connect the OL-active Dor regulatory activity to alpha-KG-mediated lipid metabolism in mature OLs to thereby facilitate myelin production and remyelination.

Project description:Impairment of oligodendrocyte (OL) myelinogenic potential, rather than inability of oligodendrocyte precursors to differentiate, is implicated in remyelination failure in demyelinating diseases such as multiple sclerosis. However, the mechanisms underlying myelinogenesis and age-related decline in remyelination remain elusive. Here, we identify a mature-OL-active transcriptional regulator Dor as a critical mediator of CNS myelination and remyelination. Genomic occupancy and transcriptomic analyses revealed that Dor interacts with Sox10 and targets the enhancers of myelinogenesis-regulatory genes including a newly identified OL-enriched nuclear factor Prr18 required for OL maturation. Metabolomic profiling showed that Dor is critical for alpha-ketoglutarate (alpha-KG) production and lipid biosynthesis. Supplementation with alpha-KG enhanced lipid biosynthesis and restored OL maturation defects in Dor-mutant mice while reversing the age-associated decline in remyelination efficiency and memory deficits in aging mice. Thus, our findings connect the OL-active Dor regulatory activity to alpha-KG-mediated lipid metabolism in mature OLs to thereby facilitate myelin production and remyelination.

Project description:Impairment of oligodendrocyte (OL) myelinogenic potential, rather than inability of oligodendrocyte precursors to differentiate, is implicated in remyelination failure in demyelinating diseases such as multiple sclerosis. However, the mechanisms underlying myelinogenesis and age-related decline in remyelination remain elusive. Here, we identify a mature-OL-active transcriptional regulator Dor as a critical mediator of CNS myelination and remyelination. Genomic occupancy and transcriptomic analyses revealed that Dor interacts with Sox10 and targets the enhancers of myelinogenesis-regulatory genes including a newly identified OL-enriched nuclear factor Prr18 required for OL maturation. Metabolomic profiling showed that Dor is critical for alpha-ketoglutarate (alpha-KG) production and lipid biosynthesis. Supplementation with alpha-KG enhanced lipid biosynthesis and restored OL maturation defects in Dor-mutant mice while reversing the age-associated decline in remyelination efficiency and memory deficits in aging mice. Thus, our findings connect the OL-active Dor regulatory activity to alpha-KG-mediated lipid metabolism in mature OLs to thereby facilitate myelin production and remyelination.

Project description:Demyelination is a hallmark of multiple sclerosis, leukoencephalopathies, cerebral vasculopathies and several neurodegenerative diseases. The cuprizone mouse model is widely used to simulate demyelination occurring in these diseases. Here, we present a high-resolution snRNA-seq analysis of gene expression changes across all brain cells in this model. We define signatures of prototypic responses to demyelination and remyelination for each cell type, including anti-stress, anti-oxidant-, metabolic-, hypoxia-, IFN-, and IL-33-driven responses, and validate them at the protein level and in IL-33R-deficient mice. We identify related transcription regulators underpinning these pathways, including STAT3, NF-κB, OLIG1 and MAFB. Furthermore, snRNA- seq data provide novel insights into how various brain cell types connect and interact, defining complex circuitries previously unknown to impact demyelination and remyelination. As an explicative example, perturbation of microglia caused by TREM2 deficiency impacts the oligodendrocyte responses to demyelination. Altogether, this study provides a rich resource for future studies investigating mechanisms underlying demyelination and remyelination.

Project description:Demyelination is a hallmark of multiple sclerosis, leukoencephalopathies, cerebral vasculopathies and several neurodegenerative diseases. The cuprizone mouse model is widely used to simulate demyelination occurring in these diseases. Here, we present a high-resolution snRNA-seq analysis of gene expression changes across all brain cells in this model. We define signatures of prototypic responses to demyelination and remyelination for each cell type, including anti-stress, anti-oxidant-, metabolic-, hypoxia-, IFN-, and IL-33-driven responses, and validate them at the protein level and in IL-33R-deficient mice. We identify related transcription regulators underpinning these pathways, including STAT3, NF-κB, OLIG1 and MAFB. Furthermore, snRNA- seq data provide novel insights into how various brain cell types connect and interact, defining complex circuitries previously unknown to impact demyelination and remyelination. As an explicative example, perturbation of microglia caused by TREM2 deficiency impacts the oligodendrocyte responses to demyelination. Altogether, this study provides a rich resource for future studies investigating mechanisms underlying demyelination and remyelination.

Project description:Arrest of oligodendrocyte (OL) differentiation and remyelination following myelin damage in Multiple Sclerosis (MS) are associated with disease progression but the underlying mechanism are elusive. We show that Glutathione S-transferase 4α (Gsta4) is highly expressed during adult OL differentiation and that its loss prevents differentiation into myelinating OLs. Also, Gsta4 appeared to be a novel target for Clemastine, in clinical trial for MS. Over-expression of Gsta4 reduced the expression of Fas and activity along the mitochondria-associated Casp8/Bid-axis in adult pre-OLs from the corpus callosum, together promoting enhanced pre-OL survival during differentiation. The Gsta4-mediated input on apoptosis during adult OL differentiation was further verified in the LPC and EAE model, where Casp8 were reduced in pre-OLs with high Gsta4 expression in an immune response-independent fashion. Our results place Gsta4 as a key regulator of intrinsic mechanisms beneficial for OL differentiation and remyelination, and as a possible target for future MS therapies.

Project description:Demyelination and dysregulated myelination in the CNS are hallmarks of many neurodegenerative diseases such as multiple sclerosis (MS) and leukodystrophies. Here, we studied GFAP+ astrocytes during de- and remyelination in the cuprizone mouse by exploiting the ribosomal tagging (RiboTag) technology. Analyses were performed 5 weeks after cuprizone feeding, at the peak of demyelination in the corpus callosum, and 0.5 and 2 weeks after cuprizone withdrawal, when remyelination and tissue repair is initiated. After 5 weeks of cuprizone feeding, reactive astrocytes showed inflammatory signatures with enhanced expression of genes that modulate leukocyte migration (Tlr2, Cd86, Parp14,Cxcl10). Furthermore, demyelination-induced reactive astrocytes expressed numerous ligands including Cx3cl1, Csf1, Il34, and Gas6 that act on homeostatic as well as activated microglia and thus potentially mediate activation and recruitment of microglia as well as enhancement of their phagocytosis. During early remyelination, region-specific astrocytes displayed reduced inflammatory response signatures as indicated by shut down of CXCL10 production. During late remyelination, the signatures of GFAP+ astrocytes shifted towards resolving inflammation by active suppression of lymphocyte activation and differentiation and support of glia cell differentiation. Astrocytes showed enhanced expression of osteopontin (SPP1) as well as of factors that are relevant for tissue remodelling (Timp1), regeneration and axonal repair. In conclusion, we detected highly dynamic astroglial transcriptomic signatures in the cuprizone model, which reflects excessive communication amongst glia cells and highlights different astrocyte functions during neurodegeneration and regeneration.

Project description:Demyelination and dysregulated myelination in the CNS are hallmarks of many neurodegenerative diseases such as multiple sclerosis (MS) and leukodystrophies. Here, we studied GFAP+ astrocytes during de- and remyelination in the cuprizone mouse by exploiting the ribosomal tagging (RiboTag) technology. Analyses were performed 5 weeks after cuprizone feeding, at the peak of demyelination in the corpus callosum, and 0.5 and 2 weeks after cuprizone withdrawal, when remyelination and tissue repair is initiated. After 5 weeks of cuprizone feeding, reactive astrocytes showed inflammatory signatures with enhanced expression of genes that modulate leukocyte migration (Tlr2, Cd86, Parp14,Cxcl10). Furthermore, demyelination-induced reactive astrocytes expressed numerous ligands including Cx3cl1, Csf1, Il34, and Gas6 that act on homeostatic as well as activated microglia and thus potentially mediate activation and recruitment of microglia as well as enhancement of their phagocytosis. During early remyelination, region-specific astrocytes displayed reduced inflammatory response signatures as indicated by shut down of CXCL10 production. During late remyelination, the signatures of GFAP+ astrocytes shifted towards resolving inflammation by active suppression of lymphocyte activation and differentiation and support of glia cell differentiation. Astrocytes showed enhanced expression of osteopontin (SPP1) as well as of factors that are relevant for tissue remodelling (Timp1), regeneration and axonal repair. In conclusion, we detected highly dynamic astroglial transcriptomic signatures in the cuprizone model, which reflects excessive communication amongst glia cells and highlights different astrocyte functions during neurodegeneration and regeneration.

Project description:Demyelination is characterized by the loss of the myelin sheath that surrounds nerve fibers and myelin-supporting cells in the nervous system. This leads to increased vulnerability of axons to damage, resulting in significant atrophy and neuro-axonal degeneration. Demyelination is a common pathological feature in a wide range of diseases of the central nervous system (CNS). Multiple pathomolecular processes contribute to brain damage, including demyelination, neuroinflammation, oligodendrocyte (OLs) cell death, and progressive neuronal dysfunction. In this study, we used the cuprizone (CPZ) mouse model to investigate long-term non-invasive gamma entrainment using sensory stimulation (GENUS) as a potential therapeutic intervention for promoting myelination and reducing neuroinflammation. Our results demonstrate that GENUS effectively mitigated demyelination, stimulated oligodendrogenesis in the corpus callosum (CC), and preserved functional integrity and synaptic plasticity. Additionally, GENUS attenuated OLs ferroptosis-induced cell death. Furthermore, chronic GENUS exhibited a marked reduction in brain inflammation, decreasing both microgliosis and astrogliosis and proinflammatory molecules, such as high mobility group box 1 (HMGB1), complement component 1q (C1q) and complement C3 (C3). Considering the pro-remyelination and anti-neuroinflammatory effects observed with GENUS, these findings suggest its potential as a therapeutic approach for demyelinating disorders.