Developmental transformations of Purkinje cells tracked by DNA electrokinetic mobility

Brain development relies on orchestrated placement and timing of neurogenesis in progenitor zones to produce the expansive cellular diversity of the brain. We took advantage of bioelectric interactions between DNA and embryonic tissue to perform “stereo-tracking”, a developmental targeting strategy that differentially labels cells positioned at different depths within intact progenitor zones. This three-dimensional labeling was achieved by delivery of plasmids with distinct electrokinetic mobilities into neural progenitor zones in utero . We applied stereo-tracking with light sheet imaging in the cerebellum and identified that Purkinje cells follow embryonically committed developmental trajectories linking distinct progenitor zone fields to the topography of the mature cerebellar cortex. In the process of stereo-tracking, we identified a previously unreported subcellular structure on the axon initial segment of Purkinje cells. These structures, we termed “axon bubbles”, are developmentally timed and differentially labeled by lipid-modified proteins. Our findings demonstrate key rules that orchestrate the stereotyped transformations from fetal progenitors into mature networks of neuronal circuits, and demonstrate the potential of progenitor zone stereo-tracking to reveal new biology within intact developing systems.