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Your search keyword '"Nassal, Drew M."' showing total 27 results
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27 results on '"Nassal, Drew M."'

2. Hyperglycemic Oxoaldehyde (Glyoxal)-Induced Vascular Endothelial Cell Damage Through Oxidative Stress Is Protected by Thiol Iron Chelator, Dimercaptosuccinic Acid – Role of Iron in Diabetic Vascular Endothelial Dysfunction

Author

Gurney, Travis O., Oliver, Patrick J., Sliman, Sean M., Yenigalla, Anita, Eubank, Timothy D., Nassal, Drew M., Miao, Jiaxing, Zhao, Jing, Hund, Thomas J., Parinandi, Narasimham L., Parinandi, Narasimham L., editor, and Hund, Thomas J., editor

Published
2022
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6. Phosphorylation of cardiac sodium channel at Ser571 anticipates manifestations of the aging myopathy.

Author

Pizzo, Emanuele, Cervantes, Daniel O., Ketkar, Harshada, Ripa, Valentina, Nassal, Drew M., Buck, Benjamin, Parambath, Sreema P., Stefano, Valeria Di, Singh, Kanwardeep, Thompson, Carl I., Mohler, Peter J., Hund, Thomas J., Jacobson, Jason T., Jain, Sudhir, and Rota, Marcello

Subjects
SODIUM channels, AGING, PHOSPHORYLATION, TRANSIENTS (Dynamics), CELLULAR aging
Abstract

Diastolic dysfunction and delayed ventricular repolarization are typically observed in the elderly, but whether these defects are intimately associated with the progressive manifestation of the aging myopathy remains to be determined. In this regard, aging in experimental animals is coupled with increased late Na+ current (INa,L) in cardiomyocytes, raising the possibility that INa,L conditions the modality of electrical recovery and myocardial relaxation of the aged heart. For this purpose, aging male and female wild-type (WT) C57Bl/6 mice were studied together with genetically engineered mice with phosphomimetic (gain of function, GoF) or ablated (loss of function, LoF) mutations of the sodium channel Nav1.5 at Ser571 associated with, respectively, increased and stabilized INa,L. At ∼18 mo of age, WT mice developed prolonged duration of the QT interval of the electrocardiogram and impaired diastolic left ventricular (LV) filling, defects that were reversed by INa,L inhibition. Prolonged repolarization and impaired LV filling occurred prematurely in adult (∼5 mo) GoF mutant mice, whereas these alterations were largely attenuated in aging LoF mutant animals. Ca2+ transient decay and kinetics of myocyte shortening/relengthening were delayed in aged (∼24 mo) WT myocytes, with respect to adult cells. In contrast, delayed Ca2+ transients and contractile dynamics occurred at adult stage in GoF myocytes and further deteriorated in old age. Conversely, myocyte mechanics were minimally affected in aging LoF cells. Collectively, these results document that Nav1.5 phosphorylation at Ser571 and the late Na+ current modulate the modality of myocyte relaxation, constituting the mechanism linking delayed ventricular repolarization and diastolic dysfunction. NEW & NOTEWORTHY: We have investigated the impact of the late Na current (INa,L) on cardiac and myocyte function with aging by using genetically engineered animals with enhanced or stabilized INa,L, due to phosphomimetic or phosphoablated mutations of Nav1.5. Our findings support the notion that phosphorylation of Nav1.5 at Ser571 prolongs myocardial repolarization and impairs diastolic function, contributing to the manifestations of the aging myopathy. [ABSTRACT FROM AUTHOR]

Published
2024
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9. Nanoscale remodeling of sodium channels in the cardiac transverse tubules contributes to aberrant calcium release in a Scn1a haploinsufficient mouse

Author

King, David R., primary, Demirtas, Mustafa, additional, Tarasov, Mikhail, additional, Meng, Xiaolei, additional, Struckman, Heather, additional, Min, Dennison, additional, Nassal, Drew M., additional, Hund, Thomas J., additional, Veeraraghavan, Rengasayee, additional, and Radwanski, Przemyslaw, additional

Published
2023
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11. Emerging therapeutic targets for cardiac hypertrophy

Author

Winkle, Alexander J., primary, Nassal, Drew M., additional, Shaheen, Rebecca, additional, Thomas, Evelyn, additional, Mohta, Shivangi, additional, Gratz, Daniel, additional, Weinberg, Seth H., additional, and Hund, Thomas J., additional

Published
2022
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13. Ca2+/calmodulin kinase II-dependent regulation of ßIV-spectrin modulates cardiac fibroblast gene expression, proliferation, and contractility.

Author

Nassal, Drew M., Unudurthi, Sathya D., Shaheen, Rebecca, Jane Yu, Mohler, Peter J., and Hund, Thomas J.

Subjects
*KINASE regulation, *GENE expression, *FIBROBLASTS, *HEART failure, *GLUTAMIC acid, *CYTOSKELETAL proteins, *PROTEIN kinases, *ANGIOTENSIN II
Abstract

Fibrosis is a pronounced feature of heart disease and the result of dysregulated activation of resident cardiac fibroblasts (CFs). Recent work identified stress-induced degradation of the cytoskeletal protein ßIV-spectrin as an important step in CF activation and cardiac fibrosis. Furthermore, loss of ßIV-spectrin was found to depend on Ca2+/calmodulin-dependent kinase II (CaMKII). Therefore, we sought to determine the mechanism for CaMKIIdependent regulation of ßIV-spectrin and CF activity. Computational screening and MS revealed a critical serine residue (S2250 in mouse and S2254 in human) in ßIVspectrin phosphorylated by CaMKII. Disruption of ßIV-spectrin/CaMKII interaction or alanine substitution of ßIV-spectrin Ser2250 (ßIV-S2254A) prevented CaMKIIinduced degradation, whereas a phosphomimetic construct (ßIV-spectrin with glutamic acid substitution at serine 2254 [ßIV-S2254E]) showed accelerated degradation in the absence of CaMKII. To assess the physiological significance of this phosphorylation event, we expressed exogenous ßIVS2254A and ßIV-S2254E constructs in ßIV-spectrin-deficient CFs, which have increased proliferation and fibrotic gene expression compared with WT CFs. ßIV-S2254A but not ßIV-S2254E normalized CF proliferation, gene expression, and contractility. Pathophysiological targeting of ßIV-spectrin phosphorylation and subsequent degradation was identified in CFs activated with the profibrotic ligand angiotensin II, resulting in increased proliferation and signal transducer and activation of transcription 3 nuclear accumulation. While therapeutic delivery of exogenous WT ßIV-spectrin partially reversed these trends, ßIV-S2254A completely negated increased CF proliferation and signal transducer and activation of transcription 3 translocation. Moreover, we observed ßIV-spectrin phosphorylation and associated loss in total protein within human heart tissue following heart failure. Together, these data illustrate a considerable role for the ßIV-spectrin/CaMKII interaction in activating profibrotic signaling. [ABSTRACT FROM AUTHOR]

Published
2021
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14. βIV-Spectrin/STAT3 complex regulates fibroblast phenotype, fibrosis, and cardiac function

Author

Patel, Nehal J., primary, Nassal, Drew M., additional, Greer-Short, Amara D., additional, Unudurthi, Sathya D., additional, Scandling, Benjamin W., additional, Gratz, Daniel, additional, Xu, Xianyao, additional, Kalyanasundaram, Anuradha, additional, Fedorov, Vadim V., additional, Accornero, Federica, additional, Mohler, Peter J., additional, Gooch, Keith J., additional, and Hund, Thomas J., additional

Published
2019
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16. Emerging therapeutic targets for cardiac arrhythmias: role of STAT3 in regulating cardiac fibroblast function

Author

Patel, Nehal J., Nassal, Drew M., Gratz, Daniel, and Hund, Thomas J.

Abstract

ABSTRACTIntroduction: Cardiac fibrosis contributes to the development of cardiovascular disease (CVD) and arrhythmia. Cardiac fibroblasts (CFs) are collagen-producing cells that regulate extracellular matrix (ECM) homeostasis. A complex signaling network has been defined linking environmental stress to changes in CF function and fibrosis. Signal Transducer and Activator of Transcription 3 (STAT3) has emerged as a critical integrator of pro-fibrotic signals in CFs downstream of several established signaling networks.Areas covered: This article provides an overview of STAT3 function in CFs and its involvement in coordinating a vast web of intracellular pro-fibrotic signaling molecules and transcription factors. We highlight recent work elucidating a critical role for the fibroblast cytoskeleton in maintaining spatial and temporal control of STAT3-related signaling . Finally, we discuss potential opportunities and obstacles for therapeutic targeting of STAT3 to modulate cardiac fibrosis and arrhythmias. Relevant publications on the topic were identified through Pubmed.Expert opinion: Therapeutic targeting of STAT3 for CVD and arrhythmias presents unique challenges and opportunities. Thus, it is critical to consider the multimodal and dynamic nature of STAT3 signaling. Going forward, it will be beneficial to consider ways to maintain balanced STAT3 function, rather than large-scale perturbations in STAT3 function.

Published
2021
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24. Contribution of two-pore K+ channels to cardiac ventricular action potential revealed using human iPSC-derived cardiomyocytes.

Author

Sam Chai, Xiaoping Wan, Nassal, Drew M., Haiyan Liu, Moravec, Christine S., Ramirez-Navarro, Angelina, and Deschênes, Isabelle

Subjects
HEART physiology, POTASSIUM channels, HEART cells
Abstract

Two-pore K+ (K2p) channels have been described in modulating background conductance as leak channels in different physiological systems. In the heart, the expression of K2p channels is heterogeneous with equivocation regarding their functional role. Our objective was to determine the K2p expression profile and their physiological and pathophysiological contribution to cardiac electrophysiology. Induced pluripotent stem cells (iPSCs) generated from humans were differentiated into cardiomyocytes (iPSC-CMs). mRNA was isolated from these cells, commercial iPSC-CM (iCells), control human heart ventricular tissue (cHVT), and ischemic (iHF) and nonischemic heart failure tissues (niHF). We detected 10 K2p channels in the heart. Comparing quantitative PCR expression of K2p channels between human heart tissue and iPSC-CMs revealed K2p1.1, K2p2.1, K2p5.1, and K2p17.1 to be higher expressed in cHVT, whereas K2p3.1 and K2p13.1 were higher in iPSC-CMs. Notably, K2p17.1 was significantly lower in niHF tissues compared with cHVT. Action potential recordings in iCells after K2p small interfering RNA knockdown revealed prolongations in action potential depolarization at 90% repolarization for K2p2.1, K2p3.1, K2p6.1, and K2p17.1. Here, we report the expression level of 10 human K2p channels in iPSC-CMs and how they compared with cHVT. Importantly, our functional electrophysiological data in human iPSC-CMs revealed a prominent role in cardiac ventricular repolarization for four of these channels. Finally, we also identified K2p17.1 as significantly reduced in niHF tissues and K2p4.1 as reduced in niHF compared with iHF. Thus, we advance the notion that K2p channels are emerging as novel players in cardiac ventricular electrophysiology that could also be remodeled in cardiac pathology and therefore contribute to arrhythmias. [ABSTRACT FROM AUTHOR]

Published
2017
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25. KChIP2 regulates the cardiac Ca2+ transient and myocyte contractility by targeting ryanodine receptor activity.

Author

Nassal, Drew M., Wan, Xiaoping, Liu, Haiyan, Laurita, Kenneth R., and Deschênes, Isabelle

Subjects
*RYANODINE receptors, *HEART, *CALCIUM channels, *CARDIOPULMONARY system, *BIOSYNTHESIS
Abstract

Pathologic electrical remodeling and attenuated cardiac contractility are featured characteristics of heart failure. Coinciding with these remodeling events is a loss of the K+ channel interacting protein, KChIP2. While, KChIP2 enhances the expression and stability of the Kv4 family of potassium channels, leading to a more pronounced transient outward K+ current, Ito,f, the guinea pig myocardium is unique in that Kv4 expression is absent, while KChIP2 expression is preserved, suggesting alternative consequences to KChIP2 loss. Therefore, KChIP2 was acutely silenced in isolated guinea pig myocytes, which led to significant reductions in the Ca2+ transient amplitude and prolongation of the transient duration. This change was reinforced by a decline in sarcomeric shortening. Notably, these results were unexpected when considering previous observations showing enhanced ICa , L and prolonged action potential duration following KChIP2 loss, suggesting a disruption of fundamental Ca2+ handling proteins. Evaluation of SERCA2a, phospholamban, RyR, and sodium calcium exchanger identified no change in protein expression. However, assessment of Ca2+ spark activity showed reduced spark frequency and prolonged Ca2+ decay following KChIP2 loss, suggesting an altered state of RyR activity. These changes were associated with a delocalization of the ryanodine receptor activator, presenilin, away from sarcomeric banding to more diffuse distribution, suggesting that RyR open probability are a target of KChIP2 loss mediated by a dissociation of presenilin. Typically, prolonged action potential duration and enhanced Ca2+ entry would augment cardiac contractility, but here we see KChIP2 fundamentally disrupts Ca2+ release events and compromises myocyte contraction. This novel role targeting presenilin localization and RyR activity reveals a significance for KChIP2 loss that reflects adverse remodeling observed in cardiac disease settings. [ABSTRACT FROM AUTHOR]

Published
2017
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27. Contribution of two-pore K + channels to cardiac ventricular action potential revealed using human iPSC-derived cardiomyocytes.

Author

Chai S, Wan X, Nassal DM, Liu H, Moravec CS, Ramirez-Navarro A, and Deschênes I

Subjects
Arrhythmias, Cardiac etiology, Arrhythmias, Cardiac metabolism, Arrhythmias, Cardiac physiopathology, Case-Control Studies, Cell Line, Female, Gene Expression Profiling methods, Heart Failure etiology, Heart Failure metabolism, Heart Failure physiopathology, Heart Ventricles physiopathology, Humans, Male, Myocardial Ischemia complications, Myocardial Ischemia metabolism, Myocardial Ischemia physiopathology, Potassium Channels, Tandem Pore Domain genetics, RNA Interference, Real-Time Polymerase Chain Reaction, Signal Transduction, Transfection, Action Potentials, Cell Differentiation, Heart Ventricles metabolism, Induced Pluripotent Stem Cells metabolism, Myocytes, Cardiac metabolism, Potassium Channels, Tandem Pore Domain metabolism
Abstract

Two-pore K + (K 2p ) channels have been described in modulating background conductance as leak channels in different physiological systems. In the heart, the expression of K 2p channels is heterogeneous with equivocation regarding their functional role. Our objective was to determine the K 2p expression profile and their physiological and pathophysiological contribution to cardiac electrophysiology. Induced pluripotent stem cells (iPSCs) generated from humans were differentiated into cardiomyocytes (iPSC-CMs). mRNA was isolated from these cells, commercial iPSC-CM (iCells), control human heart ventricular tissue (cHVT), and ischemic (iHF) and nonischemic heart failure tissues (niHF). We detected 10 K 2p channels in the heart. Comparing quantitative PCR expression of K 2p channels between human heart tissue and iPSC-CMs revealed K 2p 1.1, K 2p 2.1, K 2p 5.1, and K 2p 17.1 to be higher expressed in cHVT, whereas K 2p 3.1 and K 2p 13.1 were higher in iPSC-CMs. Notably, K 2p 17.1 was significantly lower in niHF tissues compared with cHVT. Action potential recordings in iCells after K 2p small interfering RNA knockdown revealed prolongations in action potential depolarization at 90% repolarization for K 2p 2.1, K 2p 3.1, K 2p 6.1, and K 2p 17.1. Here, we report the expression level of 10 human K 2p channels in iPSC-CMs and how they compared with cHVT. Importantly, our functional electrophysiological data in human iPSC-CMs revealed a prominent role in cardiac ventricular repolarization for four of these channels. Finally, we also identified K 2p 17.1 as significantly reduced in niHF tissues and K 2p 4.1 as reduced in niHF compared with iHF. Thus, we advance the notion that K 2p channels are emerging as novel players in cardiac ventricular electrophysiology that could also be remodeled in cardiac pathology and therefore contribute to arrhythmias. NEW & NOTEWORTHY Two-pore K + (K 2p ) channels are traditionally regarded as merely background leak channels in myriad physiological systems. Here, we describe the expression profile of K 2p channels in human-induced pluripotent stem cell-derived cardiomyocytes and outline a salient role in cardiac repolarization and pathology for multiple K 2p channels., (Copyright © 2017 the American Physiological Society.)

Published
2017
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