For this competing renewal project (R01HL63290-16), we propose to continue collaborative studies between the Zlokovic and Griffin labs aimed at advancing basic knowledge on protein C/activated protein C (APC) pathways in the central nervous system (CNS) with an overall goal of advancing from basic knowledge to translation to the clinic. Previous results funded by this R01 project led to discovery of direct vasculoprotective, blood-brain barrier (BBB)-stabilizing, neuroprotective and anti-inflammatory activities of APC and its cytoprotective-selective mutants using rodent models of stroke, brain trauma and chronic neuronal degeneration. This project identified APC receptors and downstream pathways in the CNS that mediate cytoprotective APC signaling in neurons, brain endothelium and at the BBB and showed that protease activated receptor-1 (PAR1) has a major role in protection. Our progress was translated in 2014 into clinical Phase II trial for ischemic stroke of 3K3A-APC, a 2nd generation cytoprotective APC. For extending this project, our goals include: 1) providing proof of concept for hypothesized mechanisms for neuroprotective activities of APC, 2) characterizing novel 3rd generation APC-mimetic agents, and 3) discovering improved biologics for ischemic stroke with potential for treating other neurologic diseases. Our exciting new findings and preliminary data show that activation of PAR1 by APC involves a novel cleavage of this receptor's N-terminal domain at Arg46 which reveals a novel tethered ligand ending at residue Asn47 that causes APC's biased, -arrestin-dependent cytoprotective signaling. In contrast, classical activation of PAR1 by thrombin involves cleavage at Arg41 resulting in G-protein signaling and cellular toxicity. APC can cleave PAR1 at both Arg41 and Arg46, and in vivo proof of concept is lacking for the attractive hypothesis that APC's neuroprotection is based on PAR1 cleavage at Arg46. We hypothesize that: i) APC cleavage of PAR1 at Arg46 protects CNS, BBB and neurons (AIM 1); ii) an APC-mimetic peptide with the sequence of PAR1 residues 47-66 (TR47) (i.e., the tethered agonist generated after Arg46 cleavage) elicits -arrestin 2-dependent cytoprotective signaling in brain endothelium and neurons in vitro and in vivo after ischemic stroke (AIM 2); and iii) APC mutants with enhanced ability to cleave PAR1 at Arg46 may provide 3rd generation neuroprotective biologics. PRELIMINARY DATA include: i) generation of new mouse lines carrying R41Q-PAR1 and R46Q-PAR1 to prevent cleavages at either Arg41 or Arg46; ii) proof for feasibility of studying the neuroprotective actions of the TR47 peptide; and iii) success at engineering novel APC variants with mutations that enhance PAR1 cleavage at Arg46. Neuroprotection will be assessed using in vitro models of BBB and neuronal injury, stroke models in mice and rats, magnetic resonance imaging, neuropathological analysis, confocal microscopy and behavioral testing. We expect that new knowledge generated from this project will likely have significant, direct impact for translation to the clinic for ischemic stroke and, by extension, implications for therapies for othr neurological disorders.

Public Health Relevance

Stroke remains a major public health concern and therapeutic challenge. Our progress on this RO1 was translated in 2014 into clinical Phase II trial for ischemic stroke of a 2nd generation cytoprotective APC. For extending this project our goals include: 1) providing proof of concept for hypothesized mechanisms for neuroprotective activities of APC, 2) characterizing novel 3rd generation APC-mimetic agents, and 3) discovering improved biologics for ischemic stroke with potential for treating other neurologic diseases.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS090904-17
Application #
8935980
Study Section
Special Emphasis Panel (ZRG1-BDCN-K (02))
Program Officer
Koenig, James I
Project Start
2014-09-30
Project End
2019-07-31
Budget Start
2015-08-01
Budget End
2016-07-31
Support Year
17
Fiscal Year
2015
Total Cost
$636,078
Indirect Cost
$174,574
Name
University of Southern California
Department
Physiology
Type
Schools of Medicine
DUNS #
072933393
City
Los Angeles
State
CA
Country
United States
Zip Code
90089
Griffin, John H; Zlokovic, Berislav V; Mosnier, Laurent O (2018) Activated protein C, protease activated receptor 1, and neuroprotection. Blood 132:159-169
Sinha, Ranjeet K; Wang, Yaoming; Zhao, Zhen et al. (2018) PAR1 biased signaling is required for activated protein C in vivo benefits in sepsis and stroke. Blood 131:1163-1171
Sweeney, Melanie D; Kisler, Kassandra; Montagne, Axel et al. (2018) The role of brain vasculature in neurodegenerative disorders. Nat Neurosci 21:1318-1331
Sweeney, Melanie D; Sagare, Abhay P; Zlokovic, Berislav V (2018) Blood-brain barrier breakdown in Alzheimer disease and other neurodegenerative disorders. Nat Rev Neurol 14:133-150
Amar, Arun Paul; Sagare, Abhay P; Zhao, Zhen et al. (2018) Can adjunctive therapies augment the efficacy of endovascular thrombolysis? A potential role for activated protein C. Neuropharmacology 134:293-301
Kisler, Kassandra; Nelson, Amy R; Montagne, Axel et al. (2017) Cerebral blood flow regulation and neurovascular dysfunction in Alzheimer disease. Nat Rev Neurosci 18:419-434
Montagne, Axel; Zhao, Zhen; Zlokovic, Berislav V (2017) Alzheimer's disease: A matter of blood-brain barrier dysfunction? J Exp Med 214:3151-3169
Nelson, Amy R; Sagare, Abhay P; Zlokovic, Berislav V (2017) Role of clusterin in the brain vascular clearance of amyloid-?. Proc Natl Acad Sci U S A 114:8681-8682
Ochocinska, Margaret J; Zlokovic, Berislav V; Searson, Peter C et al. (2017) NIH workshop report on the trans-agency blood-brain interface workshop 2016: exploring key challenges and opportunities associated with the blood, brain and their interface. Fluids Barriers CNS 14:12
Sweeney, Melanie D; Ayyadurai, Shiva; Zlokovic, Berislav V (2016) Pericytes of the neurovascular unit: key functions and signaling pathways. Nat Neurosci 19:771-83

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