ABSTRACT
Wnt signalling regulates many aspects of cell biology. Wnt-pathway activation and its downstream effects have been extensively studied, but the dynamic analysis of Wnt-ligands on mammalian cellular membranes is obstructed by difficulties of visualization. We overcome this using microbead-tethered Wnts presented to single embryonic stem cells, which undergo Wnt-mediated asymmetric cell division (ACD). Through live imaging and genetic editing, we show that knockout of Wnt co-receptor Lrp5 promotes cytoneme formation and Wnt-recruitment, which requires Lrp6 and β-catenin. Lrp5 facilitates ligand-retention at the membrane, and alongside Lrp6 mediates Wnt-ligand stabilization and positioning. β-catenin or Wnt co-receptor knockout causes misorientation at mitosis, and all but Lrp5 are required for Wnt-orientated ACD. Surprisingly, ionotropic glutamate receptor (iGluR) activity enables initial Wnt-recruitment, positioning, and ultimately oriented ACD. Uniquely, we have scrutinized the early Wnt ligand-membrane interaction, linking roles of Wnt-pathway components and crosstalk with iGluRs in guiding cell fate determination by oriented ACD.