Josephine W. Mitchell scite author profile

Sensory neurons enable an organism to perceive external stimuli, which is essential for survival. The sensory capacity of a neuron depends on the elaboration of its dendritic arbor and the delivery of sensory ion channels to the dendritic membrane. However, it is not well understood how ion channels are trafficked to sensory dendrites and whether their delivery is coordinated with dendrite growth. We investigated the trafficking of the DEG/ENaC/ASIC ion channel Pickpocket (Ppk) in peripheral sensory neurons in fruit fly larvae. We used CRISPR-Cas9 genome engineering to tag endogenous Ppk1 and visualize it live, including monitoring Ppk1 membrane localization via a novel secreted split-GFP approach. Strikingly, Ppk1 is present throughout the membrane of actively growing dendrites, and Ppk1 density scales in proportion to the dendritic membrane, even when dynein-mediated transport to dendrites is disrupted. Our data suggest that Ppk1 is integral to the membrane of growing dendrites and implicate the recycling endosome GTPase Rab11 in the forward trafficking of Ppk1 to dendrites. Together, our results suggest that Ppk channel transport is coordinated with dendrite morphogenesis, thus ensuring proper ion channel levels and distribution in sensory dendrites.

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Live Imaging of Golgi Outposts in Drosophila Dendritic Arbors

Mitchell

Wildonger

2022

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Handling difficult cryo-ET samples: A study with primary neurons fromDrosophila melanogaster

Kim

Yang

Mitchell

et al. 2023

Preprint

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Cellular neurobiology has benefited from recent advances in the field of cryo-electron tomography (cryo-ET). Numerous structural and ultrastructural insights have been obtained from plunge-frozen primary neurons cultured on electron microscopy grids. With most primary neurons been derived from rodent sources, we sought to expand the breadth of sample availability by using primary neurons derived from 3rd instar Drosophila melanogaster larval brains. Ultrastructural abnormalities were encountered while establishing this model system for cryo-ET, which were exemplified by excessive membrane blebbing and cellular fragmentation. To optimize neuronal samples, we integrated substrate selection, micropatterning, montage data collection, and chemical fixation. Efforts to address difficulties in establishing Drosophila neurons for future cryo-ET studies in cellular neurobiology also provided insights that future practitioners can use when attempting to establish other cell-based model systems.

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