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RESEARCH PRODUCT
Wnt-Dependent Oligodendroglial-Endothelial Interactions Regulate White Matter Vascularization and Attenuate Injury
María José Ulloa-navasEric J. HuangPedro Pérez-borredáPatrick S. McquillenManideep ChavaliManideep ChavaliJosé Manuel García-verdugoDavid H. Rowitchsubject
0301 basic medicineGenetically modified mouseoligodendrocytesMice TransgenicBiologyArticleWhite matter03 medical and health sciencesParacrine signallingMice0302 clinical medicinetip cell angiogenesisAxin ProteinConditional gene knockoutmedicineAXIN2AnimalsHumanshypoxic-ischemic encephalopathyHypoxiaWnt Signaling PathwayGeneral NeuroscienceWnt signaling pathwayFerretsIntracellular Signaling Peptides and ProteinsEndothelial CellsMembrane ProteinsCell DifferentiationHypoxia (medical)Wnt signalingWhite Matter3. Good healthCell biologyEndothelial stem cellstomatognathic diseasesOligodendroglia030104 developmental biologymedicine.anatomical_structurenervous systemEndothelium Vascularmedicine.symptom030217 neurology & neurosurgerydescription
Recent studies have indicated oligodendroglial-vascular crosstalk during brain development, but the underlying mechanisms are incompletely understood. We report that oligodendrocyte precursor cells (OPCs) contact sprouting endothelial tip cells in mouse, ferret and human neonatal white matter. Using transgenic mice, we show that increased or decreased OPC density results in cognate changes in white matter vascular investment. Hypoxia promoted both increased OPC numbers and higher white matter vessel density, and endothelial cell expression of the Wnt pathway targets Apcdd1 and Axin2, suggesting paracrine OPC-endothelial signaling. Conditional knockout of OPC Wntless resulted in diminished white matter vascular growth in normoxia, while loss of Wnt7a/b function blunted the angiogenic response to hypoxia resulting in severe white matter damage. These findings indicate that OPC-endothelial cell interactions regulate neonatal white matter vascular development in a Wnt-dependent manner and further suggest this mechanism is important in attenuating hypoxic injury.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-02-10 | Neuron |