This proposal outlines an integrated strategy to gain insights into 3 related processes that determine the levels of integral membrane cell surface. Many cellular activities are exquisitely dependent on the level and repertoire of a variety proteins at the plasma membrane, which reflects a balance of trafficking pathways that control their internalization into endosomes, their transit from endosomes back to the plasma membrane along recycling routes, and their packaging into endosomal intraluminal vesicles prior to delivery and degradation in lysosomes. One of the main determinants for sending membrane proteins for lysosomal degradation is their covalent attachment to ubiquitin, that is subsequently recognized by a series of ubiquitin- sorting receptors. Exactly, how ubiquitinated proteins are physically clustered on endosomal membranes prior to incorporation into intraluminal vesicles has been unclear. However, we have discovered a family of small 4-pass membrane proteins that establish endosomal subdomains that ubiquitinated proteins segregate into. Here we will study the properties of these proteins, the formation of the subdomains, and the types of cargo and sorting events that such subdomains control. Ubiquitin has also been shown to be a signal for internalization, however, the exact sorting receptor(s) that mediate its recognition by many multi-component internalization apparatus. We have discovered that the one family of cargo adaptors for clathrin coated vesicle internalization binds ubiquitin with relatively high affinity. We will now determine whether this family, perhaps in combination with other Ub-binding proteins, serves as a critical component for ubiquitin-dependent internalization of cell surface proteins. One of the critical sorting decisions between degrading a protein or allowing it to remain active takes place in early endosomes, where proteins are either packaged into tubulo-vesicular carriers along a recycling route to the plasma membrane, or packaged into intraluminal vesicles for subsequent delivery and degradation in lysosomes. We recently completed a genetic screen that identified a plethora of new protein machinery required for recycling from early endosomes. This process is under broad metabolic control via the Rag/Gtr GTPases through a process that is independent of TORC1. Here will pursue these observations with biochemical and genetic experiments to connect this metabolic regulation with the trafficking machinery that effects protein movement through the recycling system.

Public Health Relevance

Most cellular functions rely on the proper activity of integral membrane proteins at the cell surface. Whether these proteins are nutrient transporters, growth factor receptors, or ion channels, their activity is broadly controlled by their abundance in the plasma membrane, which determined by internalization, recycling from endosomes, and degradation in lysosomes. Here we propose to examine mechanistic aspects of these processes and how they are regulated.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
2R01GM058202-21
Application #
9593415
Study Section
Membrane Biology and Protein Processing Study Section (MBPP)
Program Officer
Maas, Stefan
Project Start
1998-08-05
Project End
2022-06-30
Budget Start
2018-09-01
Budget End
2019-06-30
Support Year
21
Fiscal Year
2018
Total Cost
Indirect Cost
Name
University of Iowa
Department
Physiology
Type
Schools of Medicine
DUNS #
062761671
City
Iowa City
State
IA
Country
United States
Zip Code
52242
Krishnamani, Venkatramanan; Peterson, Tabitha A; Piper, Robert C et al. (2018) Informatic Analysis of Sequence Data from Batch Yeast 2-Hybrid Screens. J Vis Exp :
Peterson, Tabitha A; Stamnes, Mark A; Piper, Robert C (2018) A Yeast 2-Hybrid Screen in Batch to Compare Protein Interactions. J Vis Exp :
Xu, Peng; Hankins, Hannah M; MacDonald, Chris et al. (2017) COPI mediates recycling of an exocytic SNARE by recognition of a ubiquitin sorting signal. Elife 6:
MacDonald, Chris; Piper, Robert C (2017) Genetic dissection of early endosomal recycling highlights a TORC1-independent role for Rag GTPases. J Cell Biol 216:3275-3290
MacDonald, Chris; Winistorfer, Stanley; Pope, Robert M et al. (2017) Enzyme reversal to explore the function of yeast E3 ubiquitin-ligases. Traffic 18:465-484
MacDonald, Chris; Piper, Robert C (2016) Cell surface recycling in yeast: mechanisms and machineries. Biochem Soc Trans 44:474-8
Pashkova, Natasha; Peterson, Tabitha A; Krishnamani, Venkatramanan et al. (2016) DEEPN as an Approach for Batch Processing of Yeast 2-Hybrid Interactions. Cell Rep 17:303-315
MacDonald, Chris; Stamnes, Mark A; Katzmann, David J et al. (2015) Tetraspan cargo adaptors usher GPI-anchored proteins into multivesicular bodies. Cell Cycle 14:3673-8
MacDonald, Chris; Payne, Johanna A; Aboian, Mariam et al. (2015) A family of tetraspans organizes cargo for sorting into multivesicular bodies. Dev Cell 33:328-42
Peterson, Tabitha A; Yu, Liping; Piper, Robert C (2015) Backbone and side-chain NMR assignments for the C-terminal domain of mammalian Vps28. Biomol NMR Assign 9:21-4

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