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Oligodendroglial myelination requires astrocyte-derived lipids
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نویسنده
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camargo n. ,goudriaan a. ,van deijk a.-l.f. ,otte w.m. ,brouwers j.f. ,lodder h. ,gutmann d.h. ,nave k.-a. ,dijkhuizen r.m. ,mansvelder h.d. ,chrast r. ,smit a.b. ,verheijen m.h.g.
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منبع
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plos biology - 2017 - دوره : 15 - شماره : 5
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چکیده
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In the vertebrate nervous system,myelination of axons for rapid impulse propagation requires the synthesis of large amounts of lipids and proteins by oligodendrocytes and schwann cells. myelin membranes are thought to be cell-autonomously assembled by these axon-associated glial cells. here,we report the surprising finding that in normal brain development,a substantial fraction of the lipids incorporated into central nervous system (cns) myelin are contributed by astrocytes. the oligodendrocyte-specific inactivation of sterol regulatory element-binding protein (srebp) cleavage-activating protein (scap),an essential coactivator of the transcription factor srebp and thus of lipid biosynthesis,resulted in significantly retarded cns myelination; however,myelin appeared normal at 3 months of age. importantly,embryonic deletion of the same gene in astrocytes,or in astrocytes and oligodendrocytes,caused a persistent hypomyelination,as did deletion from astrocytes during postnatal development. moreover,when astroglial lipid synthesis was inhibited,oligodendrocytes began incorporating circulating lipids into myelin membranes. indeed,a lipid-enriched diet was sufficient to rescue hypomyelination in these conditional mouse mutants. we conclude that lipid synthesis by oligodendrocytes is heavily supplemented by astrocytes in vivo and that horizontal lipid flux is a major feature of normal brain development and myelination. © 2017 public library of science. all rights reserved.
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آدرس
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department of molecular and cellular neurobiology,center for neurogenomics and cognitive research,amsterdam neuroscience,vu university amsterdam,amsterdam, Netherlands, department of molecular and cellular neurobiology,center for neurogenomics and cognitive research,amsterdam neuroscience,vu university amsterdam,amsterdam, Netherlands, department of molecular and cellular neurobiology,center for neurogenomics and cognitive research,amsterdam neuroscience,vu university amsterdam,amsterdam, Netherlands, biomedical mr imaging and spectroscopy group,center for image sciences,university medical center utrecht,utrecht,netherlands,department of pediatric neurology,brain center rudolf magnus,university medical center utrecht,utrecht, Netherlands, department of biochemistry and cell biology,faculty of veterinary medicine,utrecht university, Netherlands, department of integrative neurophysiology,center for neurogenomics and cognitive research,amsterdam neuroscience,vu university amsterdam,amsterdam, Netherlands, department of neurology,washington university school of medicine,st. louis,mo, United States, max-planck-institute of experimental medicine,department of neurogenetics,goettingen, Germany, biomedical mr imaging and spectroscopy group,center for image sciences,university medical center utrecht,utrecht, Netherlands, department of integrative neurophysiology,center for neurogenomics and cognitive research,amsterdam neuroscience,vu university amsterdam,amsterdam, Netherlands, department of neuroscience and department of clinical neuroscience,karolinska institutet,stockholm, Sweden, department of molecular and cellular neurobiology,center for neurogenomics and cognitive research,amsterdam neuroscience,vu university amsterdam,amsterdam, Netherlands, department of molecular and cellular neurobiology,center for neurogenomics and cognitive research,amsterdam neuroscience,vu university amsterdam,amsterdam, Netherlands
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Authors
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