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Center for Cellular Metabolism Research in Oklahoma

$571,664P20FY2023GMNIH

Oklahoma Medical Research Foundation, Oklahoma City OK

Investigators

Linked publications & trials

Abstract

The goal of the parent COBRE award (P20GM139763) is to support research project leaders (RPL) to scientific independence in area of cellular metabolism by creating and unifying resources under the COBRE- supported Center of Cellular Metabolism Research in Oklahoma (CMRO). Dr. Chi Fung Lee has been supported by the CMRO-COBRE as a RPL. The Lee lab has created a research program that investigates how metabolism regulates heart disease progression. With the current COBRE support, the Lee lab is examining mechanisms by which mitochondrial dysfunction and NAD+ redox imbalance promotes diabetic cardiomyopathy. Patients with heart disease are associated with arrhythmias, which increase risks of patients to heart failure, stroke and sudden death. In this supplement award, the Lee lab seeks support to continue a collaboration with the Lam Lab at the University of Delaware on cardiac electrical/calcium signaling, and to together examine the mechanistic roles of mitochondrial dysfunction and metabolism in arrhythmogenesis. We aim to examine how mitochondrial metabolism regulates electrical/calcium signals to promote arrhythmias, a hypothesis that has not been rigorously and directly tested. Dr. Chi Keung Lam was well-trained in laboratories studying electrical/calcium signaling in mouse models and using induced pluripotent stem cell platforms to identify mechanisms of arrhythmias. Our pilot data using cardiac-specific mitochondrial dysfunction mice (Ndufs4-cKO) showed that mitochondrial dysfunction increases susceptibility of hearts to arrhythmias and promotes sudden death. We found that calcium signaling is altered in cardiomyocytes isolated from the arrhythmic Ndufs4-cKO hearts. In this supplement award, we plan to thoroughly characterize changes in mitochondrial function and metabolism, and electrical/calcium signaling in these arrhythmias hearts. To understand how mitochondrial dysfunction promotes atrial and ventricular arrhythmic events, we will dissect spatial-specific changes (atrial and ventricular) using state-of-the-art electrical mapping (eMapping) of the arrhythmic Ndufs4-cKO hearts available to the Lam lab. Spatial transcriptomic and metabolomic analyses targeting cellular and mitochondrial metabolism will be used, available to the Lee lab. By coupling the expertise of electrical/calcium signaling (Lam lab) and metabolism (Lee lab), this series of experiments will provide important mechanistic targets to be further explored linking mitochondrial dysfunction to arrhythmias. Our long-term goal is to apply for a multi-PIs R01 grant that dissects detailed molecular mechanisms how mitochondrial metabolism regulates electrical/calcium signaling in arrhythmias. Our pilot data already support one of the possible mechanisms in related to NAD+-dependent metabolic signaling altered by mitochondrial dysfunction to deregulate calcium handling proteins (e.g. CaMKII acetylation). The complementary expertise in the Lee and Lam labs will have synergistic effects in developing our young research programs and understanding novel mechanisms of arrhythmias.

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