This is the resubmission of a renewal application for a longstanding project on dysregulation of calcium (Ca2+)-related processes in hippocampal neurons during aging and the consequences for altered neuronal function/vulnerability. The project initially derived from the finding that the Ca2+-dependent slow afterhyperpolarization (sAHP), that follows a burst of action potentials in hippocampal pyramidal neurons, is larger in aged than in young-adult animals. Importantly, larger sAHPs are correlated with reduced neuronal excitability and impaired learning and memory. Conversely, smaller sAHPs are found in animals that learn a task. Since then, we and others have determined that Ca2+ action potentials, Ca2+ transients and L-type Ca2+ currents also are increased in aged neurons. These results led to a Ca2+ dysregulation hypothesis of brain aging, in which increased activity of L-channels plays a key initiating role and the resulting larger sAHP reduces neuronal excitability. It also has become apparent that enhanced Ca2+-induced Ca2+ release (CICR) from ryanodine receptors (RyRs) modulates the magnitude of aging-related Ca2+ transients and sAHPs in pyramidal neurons. The major objective of this project is to fundamentally advance our understanding of the underlying molecular mechanisms of Ca2+ dysregulation that lead to unhealthy brain aging. Based on our new intriguing results, we have formulated a novel working hypothesis of age-related Ca2+ dysregulation that suggests that downregulation of immunophilins, particularly FK-506 binding protein 1b and/or 1a (FKBP1b/1a), leads to a cascade of RyR destabilization, greater CICR and larger sAHPs. The resulting effect is impaired neuronal excitability and behavioral plasticity. These studies will manipulate hippocampal expression/function of FKBP1b/1a and other proteins in the FKBP- Ca2+ regulatory pathway in vivo using microinjection of viral vectors. Multiple outcomes will be assessed in the same animals using a multidisciplinary approach comprising extensive behavioral testing, state-of-the-art intracellular electrophysiology with concomitant Ca2+ imaging, immunohistochemistry, and gene microarray analysis. These studies should substantially elucidate aging changes that depend on Ca2+ dysregulation and should clearly test the role of FKBPs in Ca2+ dysregulation and hippocampal function during aging. Chronic intervention studies are proposed that could have direct translational relevance and lead directly to novel preventative and therapeutic treatments against aging-related decline of brain function. Given the dramatic increase in the aging population, it is becoming increasingly important to identify and develop such therapies to maintain cognitive function in the elderly.

Public Health Relevance

The aging population of the United States is projected to increase at a dramatic rate with numbers that will undoubtedly impact our healthcare system (20% of the population will be >65 years of age by the year 2030). Cognitive decline frequently accompanies aging and depending on the severity, can significantly affect quality of life. Our results indicate that a specific pathway (FKBP-Ca2+) that plays a major role in cardiac failure may also play a critical role in brain aging and cognitive decline;thus the goal of this project is to use gene therapy techniques to determine whether such interventions can prevent or slow the onset of age-related brain decline. The outcomes may have substantial therapeutic implications.

Agency
National Institute of Health (NIH)
Institute
National Institute on Aging (NIA)
Type
Method to Extend Research in Time (MERIT) Award (R37)
Project #
5R37AG004542-25
Application #
8657963
Study Section
Neurobiology of Learning and Memory Study Section (LAM)
Program Officer
Wise, Bradley C
Project Start
1998-01-01
Project End
2016-02-29
Budget Start
2014-04-01
Budget End
2015-03-31
Support Year
25
Fiscal Year
2014
Total Cost
$394,838
Indirect Cost
$128,954
Name
University of Kentucky
Department
Pharmacology
Type
Schools of Medicine
DUNS #
939017877
City
Lexington
State
KY
Country
United States
Zip Code
40506
Gant, John C; Blalock, Eric M; Chen, Kuey-Chu et al. (2018) FK506-Binding Protein 12.6/1b, a Negative Regulator of [Ca2+], Rescues Memory and Restores Genomic Regulation in the Hippocampus of Aging Rats. J Neurosci 38:1030-1041
Gant, John C; Kadish, Inga; Chen, Kuey-Chu et al. (2018) Aging-Related Calcium Dysregulation in Rat Entorhinal Neurons Homologous with the Human Entorhinal Neurons in which Alzheimer's Disease Neurofibrillary Tangles First Appear. J Alzheimers Dis 66:1371-1378
Frazier, Hilaree N; Maimaiti, Shaniya; Anderson, Katie L et al. (2017) Calcium's role as nuanced modulator of cellular physiology in the brain. Biochem Biophys Res Commun 483:981-987
Alzheimer's Association Calcium Hypothesis Workgroup (2017) Calcium Hypothesis of Alzheimer's disease and brain aging: A framework for integrating new evidence into a comprehensive theory of pathogenesis. Alzheimers Dement 13:178-182.e17
Gant, John C; Chen, Kuey-Chu; Kadish, Inga et al. (2015) Reversal of Aging-Related Neuronal Ca2+ Dysregulation and Cognitive Impairment by Delivery of a Transgene Encoding FK506-Binding Protein 12.6/1b to the Hippocampus. J Neurosci 35:10878-87
Latimer, Caitlin S; Brewer, Lawrence D; Searcy, James L et al. (2014) Vitamin D prevents cognitive decline and enhances hippocampal synaptic function in aging rats. Proc Natl Acad Sci U S A 111:E4359-66
Gant, J C; Blalock, E M; Chen, K-C et al. (2014) FK506-binding protein 1b/12.6: a key to aging-related hippocampal Ca2+ dysregulation? Eur J Pharmacol 739:74-82
Thibault, Olivier; Anderson, Katie L; DeMoll, Chris et al. (2013) Hippocampal calcium dysregulation at the nexus of diabetes and brain aging. Eur J Pharmacol 719:34-43
Pancani, Tristano; Anderson, Katie L; Brewer, Lawrence D et al. (2013) Effect of high-fat diet on metabolic indices, cognition, and neuronal physiology in aging F344 rats. Neurobiol Aging 34:1977-87
Thibault, Olivier; Pancani, Tristano; Landfield, Philip W et al. (2012) Reduction in neuronal L-type calcium channel activity in a double knock-in mouse model of Alzheimer's disease. Biochim Biophys Acta 1822:546-9

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