Endosomal trafficking of receptors plays fundamental roles in neuronal function and in neurodevelopment, as well as in disease states of the nervous system. The current understanding of endosome organization and function is based primarily on work in yeast and fibroblasts. However, our recent work showed that neurons employ neuronal-specific endocytic and endosomal machinery. There is thus presently a fundamental gap in the understanding of how endosomal function is adapted to cater to the specific physiological needs of neurons. Since the particular organization of the endosome determines postendocytic trafficking of receptors (i.e. signaling, processing, and/or degradation) and thereby specific functional outcomes, the field's ignorance of the neuronal adaptations of the endosomal system constitutes a significant barrier to progress in both basic and disease-oriented fields. Our long-term goals are to uncover the functional contributions of endosomes to neurodevelopment, and to the healthy and diseased brain. The rationale motivating this proposal is that vertebrate neurons express neuronal-specific proteins in their endosomes (in particular NEEP21/Nsg-1 and P19/Nsg-2) that control the endosomal trafficking of crucial neuronal membrane proteins, such as receptors important in development (the axonal adhesion molecule L1/NgCAM), synaptic function (GluA2), and disease (bAPP). Nsg-proteins are members of a gene family of transmembrane proteins found specifically in the neuronal Golgi and in poorly characterized somatodendritic endosomes (Nsg-endosomes). The central concept of this application is that crucial neuronal functions depend on Nsg-endosomes. Our preliminary data suggest the specific hypothesis that Nsg-proteins maintain a specific subset of endocytosed receptors in a distinct non-degradative compartment from where the cargo can recycle to multiple locations to regulate axon growth and synaptic function. We will use innovative approaches including quantitative single vesicle live imaging, super-resolution fluorescence microscopy, and electron microscopy in combination with functional interference approaches in primary neurons and in rodent cortex to address three specific aims:
Aim 1) How are Nsg-endosomes formed and how do they relate to other somatodendritic endosomes? With which other proteins does NEEP21/Nsg-1 interact and which rabs regulate Nsg-endosomal organization? Aim 2) How does loss of NEEP21/Nsg-1 and P19/Nsg-2 affect endosomal organization and cargo trafficking? Aim 3) Does loss of NEEP21/Nsg-1 and P19/Nsg-2 affect axon and dendrite development in the cortex? The proposed research is significant because it will discover the contribution of endosomes to neuronal function in health and disease. The new insights gained will not only lead to fundamental advances in understanding the regulation of neuronal membrane traffic, but also raise the possibility of new targets for tailoring translational strateges in the future.

Public Health Relevance

A large number of neurological pathologies result from disturbances of membrane traffic. An increasing number of diseases are found to be genetically associated with endocytic and endosomal regulators. For instance, NHE6 mutations implicate endosomal dysfunction in some forms of autism. Also, some familiar Alzheimer's mutations are genetically linked to endosomal trafficking, suggesting that improper trafficking through endosomes can cause Alzheimer's disease even without mutations in bAPP. The proposed project to unravel the function and regulation of neuronal endosomes therefore will lead to advances in the scientific knowledge that will enable development of specific targeted interventions of harmful membrane trafficking pathologies in the future.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS083378-15
Application #
9324369
Study Section
Synapses, Cytoskeleton and Trafficking Study Section (SYN)
Program Officer
Riddle, Robert D
Project Start
2013-09-15
Project End
2018-07-31
Budget Start
2017-08-01
Budget End
2018-07-31
Support Year
15
Fiscal Year
2017
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
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Yap, Chan Choo; Digilio, Laura; McMahon, Lloyd P et al. (2018) Degradation of dendritic cargos requires Rab7-dependent transport to somatic lysosomes. J Cell Biol 217:3141-3159
Winckler, Bettina; Faundez, Victor; Maday, Sandra et al. (2018) The Endolysosomal System and Proteostasis: From Development to Degeneration. J Neurosci 38:9364-9374
Barford, Kelly; Keeler, Austin; McMahon, Lloyd et al. (2018) Transcytosis of TrkA leads to diversification of dendritic signaling endosomes. Sci Rep 8:4715
Casanova, James E; Winckler, Bettina (2017) A new Rab7 effector controls phosphoinositide conversion in endosome maturation. J Cell Biol 216:2995-2997
Barford, Kelly; Deppmann, Christopher; Winckler, Bettina (2017) The neurotrophin receptor signaling endosome: Where trafficking meets signaling. Dev Neurobiol 77:405-418
Yap, Chan Choo; Digilio, Laura; McMahon, Lloyd et al. (2017) The endosomal neuronal proteins Nsg1/NEEP21 and Nsg2/P19 are itinerant, not resident proteins of dendritic endosomes. Sci Rep 7:10481
Barford, Kelly; Keeler, Austin; Deppmann, Christopher et al. (2017) TrkA Bumps into Its Future Self. Dev Cell 42:557-558
Martorella, M; Barford, K; Winkler, B et al. (2017) Emergent Role of Coronin-1a in Neuronal Signaling. Vitam Horm 104:113-131
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

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