Simons Initiative for the Developing Brain, and.
Centre for Discovery Brain Sciences, Edinburgh Medical School: Biomedical Sciences, The University of Edinburgh, Edinburgh EH8 9XD, United Kingdom.
J Neurosci. 2019 Feb 20;39(8):1386-1404. doi: 10.1523/JNEUROSCI.1747-17.2018. Epub 2019 Jan 7.
Heparan sulfate (HS) is a cell surface and extracellular matrix carbohydrate extensively modified by differential sulfation. HS interacts physically with canonical fibroblast growth factor (FGF) proteins that signal through the extracellular signal regulated kinase (ERK)/mitogen activated protein kinase (MAPK) pathway. At the embryonic mouse telencephalic midline, FGF/ERK signaling drives astroglial precursor somal translocation from the ventricular zone of the corticoseptal boundary (CSB) to the induseum griseum (IG), producing a focus of -expressing astroglial guidepost cells essential for interhemispheric corpus callosum (CC) axon navigation. Here, we investigated the cell and molecular function of a specific form of HS sulfation, 2-O HS sulfation catalyzed by the enzyme Hs2st, in midline astroglial development and in regulating FGF protein levels and interaction with HS. embryos of either sex exhibit a grossly enlarged IG due to precocious astroglial translocation and conditional mutagenesis and culture experiments show that is not required cell autonomously by CC axons or by the IG astroglial cell lineage, but rather acts non-cell autonomously to suppress the transmission of translocation signals to astroglial precursors. Rescue of the astroglial translocation phenotype by pharmacologically inhibiting FGF signaling shows that the normal role of Hs2st is to suppress FGF-mediated astroglial translocation. We demonstrate a selective action of Hs2st on FGF protein by showing that (but not ) normally suppresses the levels of Fgf17 protein in the CSB region and use a biochemical assay to show that (but not ) facilitates a physical interaction between the Fgf17 protein and HS. We report a novel non-cell-autonomous mechanism regulating cell signaling in developing brain. Using the developing mouse telencephalic midline as an exemplar, we show that the specific sulfation modification of the cell surface and extracellular carbohydrate heparan sulfate (HS) performed by Hs2st suppresses the supply of translocation signals to astroglial precursors by a non-cell-autonomous mechanism. We further show that Hs2st modification selectively facilitates a physical interaction between Fgf17 and HS and suppresses Fgf17 protein levels , strongly suggesting that Hs2st acts selectively on Fgf17 signaling. HS interacts with many signaling proteins potentially encoding numerous selective interactions important in development and disease, so this class of mechanism may apply more broadly to other biological systems.
硫酸乙酰肝素 (HS) 是一种细胞表面和细胞外基质碳水化合物,通过差异硫酸化广泛修饰。HS 与经典成纤维细胞生长因子 (FGF) 蛋白物理相互作用,这些蛋白通过细胞外信号调节激酶 (ERK)/丝裂原激活蛋白激酶 (MAPK) 途径发出信号。在胚胎小鼠端脑正中线上,FGF/ERK 信号驱动星型胶质前体细胞从皮质隔边界 (CSB) 的室腔区迁移到灰结节 (IG),产生一个表达 - 的星型胶质引导细胞焦点,对于半球间胼胝体 (CC) 轴突导航至关重要。在这里,我们研究了特定形式的 HS 硫酸化,即由酶 Hs2st 催化的 2-O HS 硫酸化,在正中线上星形胶质细胞发育中的细胞和分子功能,以及调节 FGF 蛋白水平和与 HS 的相互作用。无论性别如何, 胚胎的 IG 都明显增大,这是由于星型胶质前体细胞的早熟迁移引起的,条件性 突变和 培养实验表明,CC 轴突或 IG 星形胶质细胞谱系本身并不需要 ,而是通过非细胞自主方式抑制向星型胶质前体细胞传递迁移信号。通过药理学抑制 FGF 信号转导来拯救 星形胶质细胞迁移表型表明,Hs2st 的正常作用是抑制 FGF 介导的星形胶质细胞迁移。我们通过显示 (但不是 )正常抑制 CSB 区域中 Fgf17 蛋白的水平,证明了 Hs2st 对 FGF 蛋白的选择性作用,并且使用生化测定显示 (但不是 )促进 Fgf17 蛋白与 HS 之间的物理相互作用。我们报告了一种调节发育中大脑细胞信号转导的新的非细胞自主机制。我们以发育中的小鼠端脑正中线为范例,表明由 Hs2st 进行的细胞表面和细胞外碳水化合物硫酸乙酰肝素 (HS) 的特定硫酸化修饰通过非细胞自主机制抑制向星型胶质前体细胞供应迁移信号。我们进一步表明,Hs2st 修饰选择性地促进 Fgf17 和 HS 之间的物理相互作用,并抑制 Fgf17 蛋白水平,强烈表明 Hs2st 对 Fgf17 信号具有选择性作用。HS 与许多信号蛋白相互作用,可能编码许多在发育和疾病中重要的选择性相互作用,因此这种机制类别可能更广泛地适用于其他生物系统。
