The Ubiquitin Proteasome System (UPS) regulates the degradation of the majority of proteins in the cell and, as such, it is involved in essentially every cellular process. Because of its central role, misregulation within the UPS can potentiate or cause diseases, such as neurodegeneration and cancer. It is now well understood that protein misfolding and accumulation, which are intimately associated with neurodegenerative disease, can impair the UPS, exacerbating the disease. In fact, there is great interest to find ways of activating proteasome function as possible treatments for neurodegenerative disorders. To the contrary, in neoplastic disease the UPS is often exploited and even upregulated; due to this, a first line treatment for multiple myeloma is proteasome inhibition. The UPS thus sits at a shared and critical position in these two major human diseases. The proteasome?the central degradative machinery of the UPS?is regulated by very different regulatory complexes (e.g. 19S, PA28??, PA28?, PA200, and putatively P97). The job of these complexes is to regulate the function of the core particle of the proteasome, the 20S, which isolates its protein degradation chamber from the cellular milieu. A commonality shared by these regulators is that they all function to induce opening of the 20S proteasome substrate gate, which exposes substrates to the interior degradation chamber. The proteasome, and its regulators, provide a rich regulatory landscape to develop therapies that could profoundly impact these two large fields of study. This will require a deep biochemical understanding of the involved molecular mechanisms. The recent barrage of proteasomal structures facilitate this effort, but structures without an understanding of the dynamic mechanisms that underlie their functions are limited. Therefore, this proposal is primarily focused on understanding the biochemical function of three of these diverse proteasomal complexes and defining how they regulate protein degradation. We will focus on three specific questions: 1) How do the N-terminal domains of the proteasomal ATPases affect proteasome function?, 2) How does the mammalian P97 function to stimulate protein degradation by the 20S proteasome?, and 3) How does PA28? regulate 20S function to catalyze nuclear protein degradation? We have chosen to focus on these three regulators because they each play unique roles in the types of substrates that they degrade, and they each play key roles in specific human diseases. We implement a variety of approaches and systems to address these questions including studying function of proteasomal regulators from archaea, yeast, nematodes, mammals, and humans. Furthermore, we are using C. elegans as an animal model system to test our biochemically derived models and genetically test therapeutic concepts. The successful completion of this study will produce a sustained impact in the field by defining the central mechanisms of these three different cellular strategies for regulating protein degradation, each of which play different but critical roles in biology and disease.

Public Health Relevance

The proposed research is relevant to public health because protein degradation affects nearly every process in the cell and the mis-regulation of protein degradation underlies many diseases including cancer and neurodegenerative diseases. Elucidating the molecular mechanism of proteasome regulation is crucial to understanding its biological roles, and is expected to provide new targets for the development of therapeutics that modulate protein degradation. Thus, the proposed research is relevant to the part of NIH?s mission that pertains to increasing our understanding of life processes that lays the foundation for advances in disease treatment.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
2R01GM107129-06
Application #
9887300
Study Section
Membrane Biology and Protein Processing Study Section (MBPP)
Program Officer
Phillips, Andre W
Project Start
2014-07-01
Project End
2023-08-31
Budget Start
2019-09-24
Budget End
2020-08-31
Support Year
6
Fiscal Year
2019
Total Cost
Indirect Cost
Name
West Virginia University
Department
Biochemistry
Type
Schools of Medicine
DUNS #
191510239
City
Morgantown
State
WV
Country
United States
Zip Code
26506
Thibaudeau, Tiffany A; Anderson, Raymond T; Smith, David M (2018) A common mechanism of proteasome impairment by neurodegenerative disease-associated oligomers. Nat Commun 9:1097
Snoberger, Aaron; Brettrager, Evan J; Smith, David M (2018) Conformational switching in the coiled-coil domains of a proteasomal ATPase regulates substrate processing. Nat Commun 9:2374
DeVallance, Evan; Branyan, Kayla W; Lemaster, Kent et al. (2018) Aortic dysfunction in metabolic syndrome mediated by perivascular adipose tissue TNF?- and NOX2-dependent pathway. Exp Physiol 103:590-603
Smith, David M (2018) Could a Common Mechanism of Protein Degradation Impairment Underlie Many Neurodegenerative Diseases? J Exp Neurosci 12:1179069518794675
Brooks, Celine; Snoberger, Aaron; Belcastro, Marycharmain et al. (2018) Archaeal Unfoldase Counteracts Protein Misfolding Retinopathy in Mice. J Neurosci 38:7248-7254
Snoberger, Aaron; Anderson, Raymond T; Smith, David M (2017) The Proteasomal ATPases Use a Slow but Highly Processive Strategy to Unfold Proteins. Front Mol Biosci 4:18
Pifer, Phillip M; Farris, Joshua C; Thomas, Alyssa L et al. (2016) Grainyhead-like 2 inhibits the coactivator p300, suppressing tubulogenesis and the epithelial-mesenchymal transition. Mol Biol Cell 27:2479-92
Kim, Young-Chan; Snoberger, Aaron; Schupp, Jane et al. (2015) ATP binding to neighbouring subunits and intersubunit allosteric coupling underlie proteasomal ATPase function. Nat Commun 6:8520