Sulfatide-mediated control of extracellular matrix-dependent oligodendrocyte maturation

In the central nervous system, the extracellular matrix (ECM) compound laminin‐2, present on developing axons, is essential in regulating oligodendrocyte (OLG) maturation. For example, laminin‐2 is involved in mediating interactions between integrins and growth factors, initially localizing in separ...

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Veröffentlicht in:	Glia 2014-06, Vol.62 (6), p.927-942
Hauptverfasser:	Baron, Wia, Bijlard, Marjolein, Nomden, Anita, de Jonge, Jenny C., Teunissen, Charlotte E., Hoekstra, Dick
Format:	Artikel
Sprache:	eng
Schlagworte:	Animals Cell Adhesion - drug effects Cell Adhesion - physiology Cell Enlargement - drug effects Cell Line Cell Proliferation - physiology Cholesterol Cytoskeleton Extracellular Matrix - drug effects Extracellular Matrix - physiology fibronectin integrin α6β1 laminin Laminin - physiology myelination Nerve Fibers, Myelinated - physiology oligodendrocyte Oligodendroglia Rats Rats, Wistar sulfatide Sulfoglycosphingolipids - pharmacology
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creator	Baron, Wia Bijlard, Marjolein Nomden, Anita de Jonge, Jenny C. Teunissen, Charlotte E. Hoekstra, Dick
description	In the central nervous system, the extracellular matrix (ECM) compound laminin‐2, present on developing axons, is essential in regulating oligodendrocyte (OLG) maturation. For example, laminin‐2 is involved in mediating interactions between integrins and growth factors, initially localizing in separate membrane microdomains. The galactosphingolipid sulfatide is an important constituent of these microdomains and may serve as a receptor for laminin‐2. Here, we investigated whether sulfatide interferes with ECM–integrin interactions and, in this manner, modulates OLG maturation. Our data reveal that disruption of laminin‐2–sulfatide interactions impeded OLG differentiation and myelin‐like membrane formation. On laminin‐2, but not on (re)myelination‐inhibiting fibronectin, sulfatide laterally associated with integrin α6 in membrane microdomains. Sulfatide was partly excluded from membrane microdomains on fibronectin, thereby likely precluding laminin‐2‐mediated myelination. Anti‐sulfatide antibodies disrupted integrin α6‐PDGFαR interactions on laminin‐2 and induced demyelination in myelinated spheroid cultures, but intriguingly stimulated myelin‐like membrane formation on fibronectin. Taken together, these findings highlight the importance of laminin–sulfatide interactions in the formation of functional membrane microdomains essential for myelination. Thus, laminin–sulfatide interactions might control the asynchronous localized differentiation of OLGs, thereby allowing myelination to be triggered by axonal demand. Given the accumulation of fibronectin in multiple sclerosis lesions, the findings also provide a molecular rationale for the potential of anti‐sulfatide antibodies to trigger quiescent endogenous OLG progenitor cells in axon remyelination. GLIA 2014;62:927–942 Main points Our data show that laminin‐2‐sulfatide interactions are essential for the formation of functional membrane microdomains important for myelination. Fibronectin excludes sulfatide from these domains, while anti‐sulfatide antibodies trigger myelination.
doi_str_mv	10.1002/glia.22650
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Anti‐sulfatide antibodies disrupted integrin α6‐PDGFαR interactions on laminin‐2 and induced demyelination in myelinated spheroid cultures, but intriguingly stimulated myelin‐like membrane formation on fibronectin. Taken together, these findings highlight the importance of laminin–sulfatide interactions in the formation of functional membrane microdomains essential for myelination. Thus, laminin–sulfatide interactions might control the asynchronous localized differentiation of OLGs, thereby allowing myelination to be triggered by axonal demand. Given the accumulation of fibronectin in multiple sclerosis lesions, the findings also provide a molecular rationale for the potential of anti‐sulfatide antibodies to trigger quiescent endogenous OLG progenitor cells in axon remyelination. GLIA 2014;62:927–942 Main points Our data show that laminin‐2‐sulfatide interactions are essential for the formation of functional membrane microdomains important for myelination. 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Anti‐sulfatide antibodies disrupted integrin α6‐PDGFαR interactions on laminin‐2 and induced demyelination in myelinated spheroid cultures, but intriguingly stimulated myelin‐like membrane formation on fibronectin. Taken together, these findings highlight the importance of laminin–sulfatide interactions in the formation of functional membrane microdomains essential for myelination. Thus, laminin–sulfatide interactions might control the asynchronous localized differentiation of OLGs, thereby allowing myelination to be triggered by axonal demand. Given the accumulation of fibronectin in multiple sclerosis lesions, the findings also provide a molecular rationale for the potential of anti‐sulfatide antibodies to trigger quiescent endogenous OLG progenitor cells in axon remyelination. GLIA 2014;62:927–942 Main points Our data show that laminin‐2‐sulfatide interactions are essential for the formation of functional membrane microdomains important for myelination. 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For example, laminin‐2 is involved in mediating interactions between integrins and growth factors, initially localizing in separate membrane microdomains. The galactosphingolipid sulfatide is an important constituent of these microdomains and may serve as a receptor for laminin‐2. Here, we investigated whether sulfatide interferes with ECM–integrin interactions and, in this manner, modulates OLG maturation. Our data reveal that disruption of laminin‐2–sulfatide interactions impeded OLG differentiation and myelin‐like membrane formation. On laminin‐2, but not on (re)myelination‐inhibiting fibronectin, sulfatide laterally associated with integrin α6 in membrane microdomains. Sulfatide was partly excluded from membrane microdomains on fibronectin, thereby likely precluding laminin‐2‐mediated myelination. Anti‐sulfatide antibodies disrupted integrin α6‐PDGFαR interactions on laminin‐2 and induced demyelination in myelinated spheroid cultures, but intriguingly stimulated myelin‐like membrane formation on fibronectin. Taken together, these findings highlight the importance of laminin–sulfatide interactions in the formation of functional membrane microdomains essential for myelination. Thus, laminin–sulfatide interactions might control the asynchronous localized differentiation of OLGs, thereby allowing myelination to be triggered by axonal demand. Given the accumulation of fibronectin in multiple sclerosis lesions, the findings also provide a molecular rationale for the potential of anti‐sulfatide antibodies to trigger quiescent endogenous OLG progenitor cells in axon remyelination. GLIA 2014;62:927–942 Main points Our data show that laminin‐2‐sulfatide interactions are essential for the formation of functional membrane microdomains important for myelination. 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subjects	Animals Cell Adhesion - drug effects Cell Adhesion - physiology Cell Enlargement - drug effects Cell Line Cell Proliferation - physiology Cholesterol Cytoskeleton Extracellular Matrix - drug effects Extracellular Matrix - physiology fibronectin integrin α6β1 laminin Laminin - physiology myelination Nerve Fibers, Myelinated - physiology oligodendrocyte Oligodendroglia Rats Rats, Wistar sulfatide Sulfoglycosphingolipids - pharmacology
title	Sulfatide-mediated control of extracellular matrix-dependent oligodendrocyte maturation
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