Abstract

The retina is an exquisitely patterned tissue, with neuronal somata positioned at regular intervals to completely sample the visual field. Cholinergic amacrine cells are spectacular exemplars of precision, distributing in two radial layers and tangentially, forming regular mosaics. Here, we investigated how the intracellular phosphatase Pten and the cell adhesion molecule Dscam cooperate to regulate amacrine cell patterning. Using double mutants to test epistasis, we found that Pten and Dscam function in parallel pathways to regulate amacrine cell positioning. Mechanistically, Pten regulates endocytic remodeling of cell adhesion molecules (Dscam, Megf10, Fat3), which are aberrantly redistributed in Pten conditional-knock-out (cKO) amacrine cells. Furthermore, extracellular vesicles derived from multivesicular endosomes have altered proteomes in PtencKO retinas. Consequently, Wnt signaling is elevated in PtencKO retinal amacrine cells, the pharmacological disruption of which phenocopies PtencKO patterning defects. Pten thus controls endocytic trafficking of critical cell adhesion/signaling molecules to control amacrine cell spacing. HIGHLIGHTSO_LIPten and Dscam act in parallel pathways to regulate amacrine cell spacing C_LIO_LIEndocytic remodeling of cell adhesion molecules is perturbed in PtencKO retinas C_LIO_LIExtracellular vesicle content is altered in PtencKO retinas C_LIO_LIPerturbation of Wnt signaling phenocopies defects in amacrine cell positioning C_LI eTOC BLURBPatterns in nature range from stereotyped distributions of colored patches on butterfly wings to precise neuronal spacing in the nervous system. Waddington proposed that built-in constraints canalize developmental patterns. Touahri et al. identified Pten-mediated endocytic trafficking of cell adhesion/signaling molecules as a novel constraint measure controlling retinal amacrine cell patterning.