Long-distance signaling is a key feature of peripheral neurons. In the developing sympathetic nervous system, long-distance signals via the neurotrophin-receptor pair NGF-TrkA are transported in a signaling endosome (SE) from the distal axon back to the soma. Upon arrival in the soma, the SE signals for survival and, strikingly, traffics into the dendrite where it organizes post-synaptic densities. However, the trafficking mechanisms underlying SE transport into dendrites is unknown. There is thus a fundamental gap in the understanding of how trafficking and signaling of the SE are linked to create functional synaptic connections. The signaling cascades elicited by NGF-TrkA are well-understood. However, the trafficking events that it undergoes once it reaches the soma are severely understudied. The trafficking of the SE affects its signaling and vice versa. Therefore, uncovering how the SE is trafficked into dendrites using high resolution cell biological tools will move past the current barriers of mechanistically linking the physiology of signaling with the cell biology of endosome traffic and maturation. Our long-term goal is to understand how a retrograde signal is able to organize synapse formation. The rationale motivating this proposal is that retrogradely trafficked NGF-TrkA is able to transport into dendrites and initiate the clustering of post-synaptic densities. Additionally, inhibiting the MEK/MAPK pathway exclusively in the cell body prohibits SEs from entering dendrites, indicating a significant link between trafficking and signaling. Our lab recently showed that SEs undergo a novel trafficking event, signaling transcytosis, where the SE is externalized on the soma membrane and is subsequently re-internalized. The central concept of this proposal is that SEs regulate multiple downstream outcomes (survival vs PSD clustering) by undergoing distinct, regulated endosomal conversions in order to diversify their signaling capacity. Our preliminary data suggest the specific hypotheses that dendritic SEs are long-lived and non- degradative (Aims 1 and 2), and that the inhibition of the MEK/MAPK pathway prevents NGF-TrkA?s transition into this long-lived SE that can travel to dendrites (Aim 3). I will use innovative approaches including knockin mice, microfluidic devices, and quantitative single vesicle live imaging to address three specific aims:
Aim 1) Determine the identity of dendritic SEs. What trafficking proteins (Rabs) associate with dendritic SEs? Aim 2) Determine how dendritic SEs are generated. What trafficking route do SEs take to reach the dendrites? Aim 3) Determine how interference with the MEK/MAPK pathway disrupts SE trafficking into dendrites. How does TrkA signaling affect its trafficking properties in the soma? The proposed research is significant because it will uncover the mechanisms of long-distance NGF signaling for dendrite development. The mechanisms uncovered in this work will have relevance as well to other long- distance signaling cascades via other growth factors in neurodevelopment.

Public Health Relevance

The completion of this project will uncover novel cellular mechanisms for the regulation of synapse formation. Information in the form of the neurotrophin Nerve Growth Factor (NGF) signaling is initiated at the distal target and is propagated retrogradely into the dendrites to cluster post-synaptic densities. The goal of this proposal is to uncover the molecular mechanisms, trafficking molecules, and signaling cascades involved in long-distance synapse assembly by the neurotrophin-TrkA signaling endosome, a pathway recently discovered and not widely studied.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Predoctoral Individual National Research Service Award (F31)
Project #
5F31NS098621-02
Application #
9333108
Study Section
Special Emphasis Panel (ZRG1)
Program Officer
Mamounas, Laura
Project Start
2016-12-31
Project End
2018-12-30
Budget Start
2017-12-31
Budget End
2018-12-30
Support Year
2
Fiscal Year
2018
Total Cost
Indirect Cost
Name
University of Virginia
Department
Neurosciences
Type
Schools of Medicine
DUNS #
065391526
City
Charlottesville
State
VA
Country
United States
Zip Code
22904
Barford, Kelly; Keeler, Austin; McMahon, Lloyd et al. (2018) Transcytosis of TrkA leads to diversification of dendritic signaling endosomes. Sci Rep 8:4715
Barford, Kelly; Deppmann, Christopher; Winckler, Bettina (2017) The neurotrophin receptor signaling endosome: Where trafficking meets signaling. Dev Neurobiol 77:405-418
Barford, Kelly; Keeler, Austin; Deppmann, Christopher et al. (2017) TrkA Bumps into Its Future Self. Dev Cell 42:557-558
Barford, Kelly; Yap, Chan Choo; Dwyer, Noelle D et al. (2017) The related neuronal endosomal proteins NEEP21 (Nsg1) and P19 (Nsg2) have divergent expression profiles in vivo. J Comp Neurol 525:1861-1878