Abstract

Traumatic brain injury (TBI) is a degenerative process, with an initial primary injury which causes immediate mechanical cell death. This injury also induces biochemical and cellular changes that contribute to continuing neuronal damage and death over time. This continuing damage is known as secondary injury, and multiple apoptotic and inflammatory pathways are activated as part of this process. One of the neurotoxic elements produced following TBI is the Alzheimer's disease-related protein A?. A? deposits, similar to those in Alzheimer's disease, are seen within 24 hours after exposure to TBI. A? is produced following sequential cleavage of the amyloid precursor protein (APP) by ?- and ?-secretase. We have recently reported that A? and the APP secretases are elevated in non-transgenic mice following TBI, with protein levels peaking at 3 days post-trauma. We found that immediate treatment with a ?- secretase inhibitor (DAPT) can completely block the learning deficits following TBI, and reduce brain lesion volume by 70%. Thus, we conclude that ?- secretase is a promising target for treatment of TBI. In order to fully exploit this new target, a key set of experiments have been designed. Firstly, the therapeutic window for APP secretase inhibition will be calculated. By narrowing the treatment window (both the start and end points of treatment), we can determine the time at which APP secretases are initiating secondary injury, and determine how long treatment should be maintained. This data will help us identify where in the sequence of secondary injury that APP secretases are important, and help to establish a therapeutic strategy for this class of inhibitors. Secondly, it is unclear from our data what the downstream target of APP secretase inhibitors are.
Aim 2 of this application examines APP and A? as primary downstream targets of ?-secretase following trauma. While between them ?- and ?-secretase have multiple downstream targets, there are a limited set of proteins that are cleaved by both ?- and ?-secretase. Given the excess of data suggesting that A? can impair blood flow, induce inflammation and cause apoptosis - all hallmarks of secondary injury - APP/A? is the most apparent of these targets.
The specific aims are designed to enhance our understanding of ?- secretase inhibitors as a treatment for TBI, and to determine if the continuing cell death following TBI is mediated through APP processing.

Public Health Relevance

This application aims to establish the role of the Alzheimer's disease peptide A? after traumatic brain injury (TBI). A? levels rapidly increase after TBI in the days following injury. We have previously shown that blocking ?- and ?- secretase activity after TBI can reduce hippocampal cell death and prevent learning impairments after trauma. Both ?- and ?- secretase inhibitors are currently in clinical trials for Alzheimer's disease, making these drugs a novel therapeutic strategy for TBI. This application will enhance our understanding of APP-secretase inhibitors as a treatment for TBI, and determine if the continuing cell death following TBI is mediated through cleavage of APP or production of the A? peptide.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Small Research Grants (R03)
Project #
1R03NS067417-01A1
Application #
8044951
Study Section
Cellular and Molecular Biology of Neurodegeneration Study Section (CMND)
Program Officer
Hicks, Ramona R
Project Start
2010-08-15
Project End
2012-04-30
Budget Start
2010-08-15
Budget End
2011-04-30
Support Year
1
Fiscal Year
2010
Total Cost
$76,750
Indirect Cost

  Institution

Name
Georgetown University
Department
Neurosciences
Type
Schools of Medicine
DUNS #
049515844
City
Washington
State
DC
Country
United States
Zip Code
20057

  Publications

Main, Bevan S; Villapol, Sonia; Sloley, Stephanie S et al. (2018) Apolipoprotein E4 impairs spontaneous blood brain barrier repair following traumatic brain injury. Mol Neurodegener 13:17
Neustadtl, Aidan L; Winston, Charisse N; Parsadanian, Maia et al. (2017) Reduced cortical excitatory synapse number in APOE4 mice is associated with increased calcineurin activity. Neuroreport 28:618-624
Villapol, Sonia; Loane, David J; Burns, Mark P (2017) Sexual dimorphism in the inflammatory response to traumatic brain injury. Glia 65:1423-1438
Main, Bevan S; Sloley, Stephanie S; Villapol, Sonia et al. (2017) A Mouse Model of Single and Repetitive Mild Traumatic Brain Injury. J Vis Exp :
Fe Lanfranco, Maria; Loane, David J; Mocchetti, Italo et al. (2017) Combination of Fluorescent in situ Hybridization (FISH) and Immunofluorescence Imaging for Detection of Cytokine Expression in Microglia/Macrophage Cells. Bio Protoc 7:
Washington, Patricia M; Villapol, Sonia; Burns, Mark P (2016) Polypathology and dementia after brain trauma: Does brain injury trigger distinct neurodegenerative diseases, or should they be classified together as traumatic encephalopathy? Exp Neurol 275 Pt 3:381-388
Winston, Charisse N; Noël, Anastasia; Neustadtl, Aidan et al. (2016) Dendritic Spine Loss and Chronic White Matter Inflammation in a Mouse Model of Highly Repetitive Head Trauma. Am J Pathol 186:552-67
Washington, Patricia M; Morffy, Nicholas; Parsadanian, Maia et al. (2014) Experimental traumatic brain injury induces rapid aggregation and oligomerization of amyloid-beta in an Alzheimer's disease mouse model. J Neurotrauma 31:125-34
Winston, Charisse N; Chellappa, Deepa; Wilkins, Tiffany et al. (2013) Controlled cortical impact results in an extensive loss of dendritic spines that is not mediated by injury-induced amyloid-beta accumulation. J Neurotrauma 30:1966-72
Washington, Patricia M; Forcelli, Patrick A; Wilkins, Tiffany et al. (2012) The effect of injury severity on behavior: a phenotypic study of cognitive and emotional deficits after mild, moderate, and severe controlled cortical impact injury in mice. J Neurotrauma 29:2283-96

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