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1. Tracking single hiPSC-derived cardiomyocyte contractile function using CONTRAX an efficient pipeline for traction force measurement.

Author

Pardon, Gaspard, Vander Roest, Alison, Chirikian, Orlando, Birnbaum, Foster, Lewis, Henry, Castillo, Erica, Wilson, Robin, Denisin, Aleksandra, Blair, Cheavar, Holbrook, Colin, Koleckar, Kassie, Chang, Alex, Blau, Helen, and Pruitt, Beth

Subjects
Induced Pluripotent Stem Cells, Humans, Myocytes, Cardiac, Myocardial Contraction, Software, Cell Differentiation, Single-Cell Analysis, Cells, Cultured
Abstract

Cardiomyocytes derived from human induced pluripotent stem cells (hiPSC-CMs) are powerful in vitro models to study the mechanisms underlying cardiomyopathies and cardiotoxicity. Quantification of the contractile function in single hiPSC-CMs at high-throughput and over time is essential to disentangle how cellular mechanisms affect heart function. Here, we present CONTRAX, an open-access, versatile, and streamlined pipeline for quantitative tracking of the contractile dynamics of single hiPSC-CMs over time. Three software modules enable: parameter-based identification of single hiPSC-CMs; automated video acquisition of >200 cells/hour; and contractility measurements via traction force microscopy. We analyze >4,500 hiPSC-CMs over time in the same cells under orthogonal conditions of culture media and substrate stiffnesses; +/- drug treatment; +/- cardiac mutations. Using undirected clustering, we reveal converging maturation patterns, quantifiable drug response to Mavacamten and significant deficiencies in hiPSC-CMs with disease mutations. CONTRAX empowers researchers with a potent quantitative approach to develop cardiac therapies.

Published
2024

2. Incomplete-penetrant hypertrophic cardiomyopathy MYH7 G256E mutation causes hypercontractility and elevated mitochondrial respiration.

Author

Lee, Soah, Vander Roest, Alison, Blair, Cheavar, Kao, Kerry, Bremner, Samantha, Childers, Matthew, Pathak, Divya, Heinrich, Paul, Lee, Daniel, Chirikian, Orlando, Mohran, Saffie, Roberts, Brock, Smith, Jacqueline, Jahng, James, Paik, David, Wu, Joseph, Gunawardane, Ruwanthi, Ruppel, Kathleen, Mack, David, Pruitt, Beth, Regnier, Michael, Wu, Sean, Spudich, James, and Bernstein, Daniel

Subjects
MYH7, biomechanics, hypertrophic cardiomyopathy, induced pluripotent stem cells, Humans, Myosin Heavy Chains, Cardiac Myosins, Cardiomyopathy, Hypertrophic, Induced Pluripotent Stem Cells, Myocytes, Cardiac, Myocardial Contraction, Mutation, Mitochondria, Myofibrils, Cell Respiration
Abstract

Determining the pathogenicity of hypertrophic cardiomyopathy-associated mutations in the β-myosin heavy chain (MYH7) can be challenging due to its variable penetrance and clinical severity. This study investigates the early pathogenic effects of the incomplete-penetrant MYH7 G256E mutation on myosin function that may trigger pathogenic adaptations and hypertrophy. We hypothesized that the G256E mutation would alter myosin biomechanical function, leading to changes in cellular functions. We developed a collaborative pipeline to characterize myosin function across protein, myofibril, cell, and tissue levels to determine the multiscale effects on structure-function of the contractile apparatus and its implications for gene regulation and metabolic state. The G256E mutation disrupts the transducer region of the S1 head and reduces the fraction of myosin in the folded-back state by 33%, resulting in more myosin heads available for contraction. Myofibrils from gene-edited MYH7WT/G256E human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) exhibited greater and faster tension development. This hypercontractile phenotype persisted in single-cell hiPSC-CMs and engineered heart tissues. We demonstrated consistent hypercontractile myosin function as a primary consequence of the MYH7 G256E mutation across scales, highlighting the pathogenicity of this gene variant. Single-cell transcriptomic and metabolic profiling demonstrated upregulated mitochondrial genes and increased mitochondrial respiration, indicating early bioenergetic alterations. This work highlights the benefit of our multiscale platform to systematically evaluate the pathogenicity of gene variants at the protein and contractile organelle level and their early consequences on cellular and tissue function. We believe this platform can help elucidate the genotype-phenotype relationships underlying other genetic cardiovascular diseases.

Published
2024

3. Mechanobiology Assays with Applications in Cardiomyocyte Biology and Cardiotoxicity.

Author

Blair, Cheavar A and Pruitt, Beth L

Subjects
cardiomyocytes, cardiotoxicity, heart failure, human induced pluripotent stem cells, mechanobiology, mechanotransduction, Medicinal and Biomolecular Chemistry, Biomedical Engineering, Medical Biotechnology
Abstract

Cardiomyocytes are the motor units that drive the contraction and relaxation of the heart. Traditionally, testing of drugs for cardiotoxic effects has relied on primary cardiomyocytes from animal models and focused on short-term, electrophysiological, and arrhythmogenic effects. However, primary cardiomyocytes present challenges arising from their limited viability in culture, and tissue from animal models suffers from a mismatch in their physiology to that of human heart muscle. Human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) can address these challenges. They also offer the potential to study not only electrophysiological effects but also changes in cardiomyocyte contractile and mechanical function in response to cardiotoxic drugs. With growing recognition of the long-term cardiotoxic effects of some drugs on subcellular structure and function, there is increasing interest in using hiPSC-CMs for in vitro cardiotoxicity studies. This review provides a brief overview of techniques that can be used to quantify changes in the active force that cardiomyocytes generate and variations in their inherent stiffness in response to cardiotoxic drugs. It concludes by discussing the application of these tools in understanding how cardiotoxic drugs directly impact the mechanobiology of cardiomyocytes and how cardiomyocytes sense and respond to mechanical load at the cellular level.

Published
2020

4. Engineering hiPSC cardiomyocyte in vitro model systems for functional and structural assessment

Author

Schroer, Alison, Pardon, Gaspard, Castillo, Erica, Blair, Cheavar, and Pruitt, Beth

Subjects
Biochemistry and Cell Biology, Biological Sciences, Stem Cell Research - Induced Pluripotent Stem Cell, Cardiovascular, Stem Cell Research, Bioengineering, Stem Cell Research - Embryonic - Human, Stem Cell Research - Induced Pluripotent Stem Cell - Human, Heart Disease, Regenerative Medicine, Clinical Research, Good Health and Well Being, Animals, Cell Engineering, Cellular Microenvironment, Humans, Induced Pluripotent Stem Cells, Myocytes, Cardiac, In vitro cardiac model, Human induced pluripotent stem cell derived cardiomyocytes, Microphysiological systems, Heart-on-a-chip, Cardiac mechanobiology, Drug discovery, In vitro cardiac model, Biophysics, Biochemistry and cell biology
Abstract

The study of human cardiomyopathies and the development and testing of new therapies has long been limited by the availability of appropriate in vitro model systems. Cardiomyocytes are highly specialized cells whose internal structure and contractile function are sensitive to the local microenvironment and the combination of mechanical and biochemical cues they receive. The complementary technologies of human induced pluripotent stem cell (hiPSC) derived cardiomyocytes (CMs) and microphysiological systems (MPS) allow for precise control of the genetics and microenvironment of human cells in in vitro contexts. These combined systems also enable quantitative measurement of mechanical function and intracellular organization. This review describes relevant factors in the myocardium microenvironment that affect CM structure and mechanical function and demonstrates the application of several engineered microphysiological systems for studying development, disease, and drug discovery.

Published
2019

7. Incomplete-penetrant hypertrophic cardiomyopathy MYH7 G256E mutation causes hypercontractility and elevated mitochondrial respiration.

Author

Soah Lee, Vander Roest, Alison S., Blair, Cheavar A., Kao, Kerry, Bremner, Samantha B., Childers, Matthew C., Pathak, Divya, Heinrich, Paul, Lee, Daniel, Chirikian, Orlando, Mohran, Saffie E., Roberts, Brock, Smith, Jacqueline E., Jahng, James W., Paik, David T., Wu, Joseph C., Gunawardane, Ruwanthi N., Ruppel, Kathleen M., Mack, David L., and Pruitt, Beth L.

Subjects
HYPERTROPHIC cardiomyopathy, CONTRACTILE proteins, GENETIC variation, RESPIRATION, GENETIC mutation
Abstract

Determining the pathogenicity of hypertrophic cardiomyopathy-associated mutations in the β-myosin heavy chain (MYH7) can be challenging due to its variable penetrance and clinical severity. This study investigates the early pathogenic effects of the incomplete-penetrant MYH7 G256E mutation on myosin function that may trigger pathogenic adaptations and hypertrophy. We hypothesized that the G256E mutation would alter myosin biomechanical function, leading to changes in cellular functions. We developed a collaborative pipeline to characterize myosin function across protein, myofibril, cell, and tissue levels to determine the multiscale effects on structure-function of the contractile apparatus and its implications for gene regulation and metabolic state. The G256E mutation disrupts the transducer region of the S1 head and reduces the fraction of myosin in the folded-back state by 33%, resulting in more myosin heads available for contraction. Myofibrils from gene-edited MYH7WT/G256E human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) exhibited greater and faster tension development. This hypercontractile phenotype persisted in single-cell hiPSC-CMs and engineered heart tissues. We demonstrated consistent hypercontractile myosin function as a primary consequence of the MYH7 G256E mutation across scales, highlighting the pathogenicity of this gene variant. Single-cell transcriptomic and metabolic profiling demonstrated upregulated mitochondrial genes and increased mitochondrial respiration, indicating early bioenergetic alterations. This work highlights the benefit of our multiscale platform to systematically evaluate the pathogenicity of gene variants at the protein and contractile organelle level and their early consequences on cellular and tissue function. We believe this platform can help elucidate the genotype-phenotype relationships underlying other genetic cardiovascular diseases. [ABSTRACT FROM AUTHOR]

Published
2024
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9. Multi-scale models reveal hypertrophic cardiomyopathy MYH7 G256E mutation drives hypercontractility and elevated mitochondrial respiration

Author

Lee, Soah, primary, Roest, Alison S. Vander, additional, Blair, Cheavar A., additional, Kao, Kerry, additional, Bremner, Samantha B., additional, Childers, Matthew C, additional, Pathak, Divya, additional, Heinrich, Paul, additional, Lee, Daniel, additional, Chirikian, Orlando, additional, Mohran, Saffie, additional, Roberts, Brock, additional, Smith, Jacqueline E., additional, Jahng, James W., additional, Paik, David T., additional, Wu, Joseph C., additional, Gunawardane, Ruwanthi N., additional, Spudich, James A., additional, Ruppel, Kathleen, additional, Mack, David, additional, Pruitt, Beth L., additional, Regnier, Michael, additional, Wu, Sean M., additional, and Bernstein, Daniel, additional

Published
2023
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10. Multi-scale models reveal hypertrophic cardiomyopathy MYH7 G256E mutation drives hypercontractility and elevated mitochondrial respiration

Author

Lee, Soah, Roest, Alison S. Vander, Blair, Cheavar A., Kao, Kerry, Bremner, Samantha B., Childers, Matthew C, Pathak, Divya, Heinrich, Paul, Lee, Daniel, Chirikian, Orlando, Mohran, Saffie, Roberts, Brock, Smith, Jacqueline E., Jahng, James W., Paik, David T., Wu, Joseph C., Gunawardane, Ruwanthi N., Spudich, James A., Ruppel, Kathleen, Mack, David, Pruitt, Beth L., Regnier, Michael, Wu, Sean M., and Bernstein, Daniel

Subjects
Article
Abstract

RATIONALE: Over 200 mutations in the sarcomeric protein β-myosin heavy chain (MYH7) have been linked to hypertrophic cardiomyopathy (HCM). However, different mutations in MYH7 lead to variable penetrance and clinical severity, and alter myosin function to varying degrees, making it difficult to determine genotype-phenotype relationships, especially when caused by rare gene variants such as the G256E mutation. OBJECTIVE: This study aims to determine the effects of low penetrant MYH7 G256E mutation on myosin function. We hypothesize that the G256E mutation would alter myosin function, precipitating compensatory responses in cellular functions. METHODS: We developed a collaborative pipeline to characterize myosin function at multiple scales (protein to myofibril to cell to tissue). We also used our previously published data on other mutations to compare the degree to which myosin function was altered. RESULTS: At the protein level, the G256E mutation disrupts the transducer region of the S1 head and reduces the fraction of myosin in the folded-back state by 50.9%, suggesting more myosins available for contraction. Myofibrils isolated from hiPSC-CMs CRISPR-edited with G256E (MYH7 (WT/G256E) ) generated greater tension, had faster tension development and slower early phase relaxation, suggesting altered myosin-actin crossbridge cycling kinetics. This hypercontractile phenotype persisted in single-cell hiPSC-CMs and engineered heart tissues. Single-cell transcriptomic and metabolic profiling demonstrated upregulation of mitochondrial genes and increased mitochondrial respiration, suggesting altered bioenergetics as an early feature of HCM. CONCLUSIONS: MYH7 G256E mutation causes structural instability in the transducer region, leading to hypercontractility across scales, perhaps from increased myosin recruitment and altered crossbridge cycling. Hypercontractile function of the mutant myosin was accompanied by increased mitochondrial respiration, while cellular hypertrophy was modest in the physiological stiffness environment. We believe that this multi-scale platform will be useful to elucidate genotype-phenotype relationships underlying other genetic cardiovascular diseases.

Published
2023

14. Author Correction: Abnormal contractility in human heart myofibrils from patients with dilated cardiomyopathy due to mutations in TTN and contractile protein genes

Author

Vikhorev, Petr G., Smoktunowicz, Natalia, Munster, Alex B., Copeland, O’ Neal, Kostin, Sawa, Montgiraud, Cecile, Messer, Andrew E., Toliat, Mohammad R., Li, Amy, dos Remedios, Cristobal G., Lal, Sean, Blair, Cheavar A., Campbell, Kenneth S., Guglin, Maya, Richter, Manfred, Knöll, Ralph, and Marston, Steven B.

Published
2018
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15. Abnormal contractility in human heart myofibrils from patients with dilated cardiomyopathy due to mutations in TTN and contractile protein genes

Author

Vikhorev, Petr G., Smoktunowicz, Natalia, Munster, Alex B., Copeland, O’Neal, Kostin, Sawa, Montgiraud, Cecile, Messer, Andrew E., Toliat, Mohammad R., Li, Amy, dos Remedios, Cristobal G., Lal, Sean, Blair, Cheavar A., Campbell, Kenneth S., Guglin, Maya, Richter, Manfred, Knöll, Ralph, and Marston, Steven B.

Published
2017
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16. Mechanobiology Assays with Applications in Cardiomyocyte Biology and Cardiotoxicity.

Author

Blair, Cheavar, Blair, Cheavar, Pruitt, Beth, Blair, Cheavar, Blair, Cheavar, and Pruitt, Beth

Abstract

Cardiomyocytes are the motor units that drive the contraction and relaxation of the heart. Traditionally, testing of drugs for cardiotoxic effects has relied on primary cardiomyocytes from animal models and focused on short-term, electrophysiological, and arrhythmogenic effects. However, primary cardiomyocytes present challenges arising from their limited viability in culture, and tissue from animal models suffers from a mismatch in their physiology to that of human heart muscle. Human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) can address these challenges. They also offer the potential to study not only electrophysiological effects but also changes in cardiomyocyte contractile and mechanical function in response to cardiotoxic drugs. With growing recognition of the long-term cardiotoxic effects of some drugs on subcellular structure and function, there is increasing interest in using hiPSC-CMs for in vitro cardiotoxicity studies. This review provides a brief overview of techniques that can be used to quantify changes in the active force that cardiomyocytes generate and variations in their inherent stiffness in response to cardiotoxic drugs. It concludes by discussing the application of these tools in understanding how cardiotoxic drugs directly impact the mechanobiology of cardiomyocytes and how cardiomyocytes sense and respond to mechanical load at the cellular level.

Published
2020

18. Insights into single hiPSC-derived cardiomyocyte phenotypes and maturation using ConTraX, an efficient pipeline for tracking contractile dynamics

Author

Pardon, Gaspard, primary, Lewis, Henry, additional, Vander Roest, Alison S., additional, Castillo, Erica A., additional, Wilson, Robin, additional, Denisin, Aleksandra K., additional, Blair, Cheavar A., additional, Birnbaum, Foster, additional, Holbrook, Colin, additional, Koleckar, Kassie, additional, Chang, Alex C-Y, additional, Blau, Helen M., additional, and Pruitt, Beth L., additional

Published
2021
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20. Titin-truncating mutations associated with dilated cardiomyopathy alter length-dependent activation and its modulation via phosphorylation

Author

Vikhorev, Petr G, primary, Vikhoreva, Natalia N, additional, Yeung, WaiChun, additional, Li, Amy, additional, Lal, Sean, additional, dos Remedios, Cristobal G, additional, Blair, Cheavar A, additional, Guglin, Maya, additional, Campbell, Kenneth S, additional, Yacoub, Magdi H, additional, de Tombe, Pieter, additional, and Marston, Steven B, additional

Published
2020
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21. Engineering the Microenvironment for Heart Muscle Cell Mechanobiology

Author

Castillo, Erica A., primary, Lane, Kerry, additional, Chirikian, Orlando, additional, Feinstein, Samuel, additional, Blair, Cheavar, additional, Schroer, Alison, additional, Pardon, Gaspard, additional, Grancharova, Tanya, additional, Gunawardane, Ru, additional, Heilshorn, Sarah, additional, and Pruitt, Beth L., additional

Published
2020
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22. Titin-truncating mutations associated with dilated cardiomyopathy alter length-dependent activation and its modulation via phosphorylation.

Author

Vikhorev, Petr G, Vikhoreva, Natalia N, Yeung, WaiChun, Li, Amy, Lal, Sean, Remedios, Cristobal G dos, Blair, Cheavar A, Guglin, Maya, Campbell, Kenneth S, Yacoub, Magdi H, Tombe, Pieter de, and Marston, Steven B

Subjects
DILATED cardiomyopathy, CYCLIC-AMP-dependent protein kinase, GENE expression profiling, ADENOSINE triphosphate, TROPONIN I, CARDIOMYOPATHIES
Abstract

Aims  Dilated cardiomyopathy (DCM) is associated with mutations in many genes encoding sarcomere proteins. Truncating mutations in the titin gene TTN are the most frequent. Proteomic and functional characterizations are required to elucidate the origin of the disease and the pathogenic mechanisms of TTN- truncating variants. Methods and results  We isolated myofibrils from DCM hearts carrying truncating TTN mutations and measured the Ca2+ sensitivity of force and its length dependence. Simultaneous measurement of force and adenosine triphosphate (ATP) consumption in skinned cardiomyocytes was also performed. Phosphorylation levels of troponin I (TnI) and myosin binding protein-C (MyBP-C) were manipulated using protein kinase A and λ phosphatase. mRNA sequencing was employed to overview gene expression profiles. We found that Ca2+ sensitivity of myofibrils carrying TTN mutations was significantly higher than in myofibrils from donor hearts. The length dependence of the Ca2+ sensitivity was absent in DCM myofibrils with TTN -truncating variants. No significant difference was found in the expression level of TTN mRNA between the DCM and donor groups. TTN exon usage and splicing were also similar. However, we identified down-regulation of genes encoding Z-disk proteins, while the atrial-specific regulatory myosin light chain gene, MYL7, was up-regulated in DCM patients with TTN -truncating variants. Conclusion  Titin - truncating mutations lead to decreased length-dependent activation and increased elasticity of myofibrils. Phosphorylation levels of TnI and MyBP-C seen in the left ventricles are essential for the length-dependent changes in Ca2+ sensitivity in healthy donors, but they are reduced in DCM patients with TTN -truncating variants. A decrease in expression of Z-disk proteins may explain the observed decrease in myofibril passive stiffness and length-dependent activation. [ABSTRACT FROM AUTHOR]

Published
2022
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24. Diabetes with Heart Failure Increases Methylglyoxal Modifications in the Sarcomere Which Inhibit Function

Author

Papadaki, Maria, primary, Holewisnki, Ronald, additional, Previs, Sammantha, additional, Martin, Thomas, additional, Stachowski, Marisa, additional, Li, Amy, additional, Blair, Cheavar, additional, Campbell, Kenneth, additional, Christine, Moravec, additional, Van Eyk, Jennifer, additional, Aubert, Virginie, additional, Warshaw, David, additional, and Kirk, Jonathan, additional

Published
2019
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25. Diabetes with heart failure increases methylglyoxal modifications in the sarcomere, which inhibit function

Author

Papadaki, Maria, primary, Holewinski, Ronald J., additional, Previs, Samantha Beck, additional, Martin, Thomas G., additional, Stachowski, Marisa J., additional, Li, Amy, additional, Blair, Cheavar A., additional, Moravec, Christine S., additional, Van Eyk, Jennifer E., additional, Campbell, Kenneth S., additional, Warshaw, David M., additional, and Kirk, Jonathan A., additional

Published
2018
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29. Abnormal contractility in human heart myofibrils from patients with dilated cardiomyopathy due to mutations in TTN and contractile protein genes (vol 7, 14829, 2017)

Author

Vikhorev, Petr G., Smoktunowicz, Natalia, Munster, Alex B., Copeland, Neal, Kostin, Sawa, Montgiraud, Cecile, Messer, Andrew E., Toliat, Mohammad R., Li, Amy, dos Remedios, Cristobal G., Lal, Sean, Blair, Cheavar A., Campbell, Kenneth S., Guglin, Maya, Richter, Manfred, Knoll, Ralph, Marston, Steven B., Vikhorev, Petr G., Smoktunowicz, Natalia, Munster, Alex B., Copeland, Neal, Kostin, Sawa, Montgiraud, Cecile, Messer, Andrew E., Toliat, Mohammad R., Li, Amy, dos Remedios, Cristobal G., Lal, Sean, Blair, Cheavar A., Campbell, Kenneth S., Guglin, Maya, Richter, Manfred, Knoll, Ralph, and Marston, Steven B.

Published
2018

30. A Protocol for Collecting Human Cardiac Tissue for Research

Author

Blair, Cheavar A., Haynes, Premi, Campbell, Stuart G., Chung, Charles, Mitov, Mihail I., Dennis, Donna, Bonnell, Mark R., Hoopes, Charles W., Guglin, Maya, and Campbell, Kenneth S.

Subjects
Cardiology, Ventricular assist device, Heart failure, Cardiac, Article, Human
Abstract

This manuscript describes a protocol at the University of Kentucky that allows a translational research team to collect human myocardium that can be used for biological research. We have gained a great deal of practical experience since we started this protocol in 2008, and we hope that other groups might be able to learn from our endeavors. To date, we have procured ~4000 samples from ~230 patients. The tissue that we collect comes from organ donors and from patients who are receiving a heart transplant or a ventricular assist device because they have heart failure. We begin our manuscript by describing the importance of human samples in cardiac research. Subsequently, we describe the process for obtaining consent from patients, the cost of running the protocol, and some of the issues and practical difficulties that we have encountered. We conclude with some suggestions for other researchers who may be considering starting a similar protocol.

Published
2017

31. The Mechanical Properties of Non-Failing and Failing Human Myocardium

Author

Blair, Cheavar A.

Subjects
Cellular and Molecular Physiology, Translational Medical Research
Abstract

Heart failure is a clinical syndrome that manifests when there are structural and functional impairments to the heart that reduces the ability of the ventricles to fill or eject blood. The syndrome affects ~6 million Americans and is responsible for nearly 300,000 deaths annually. At the core of the syndrome are dysfunctional sarcomeres, the machinery that drives cardiac contraction and relaxation. By assessing the mechanical properties of human cardiac tissue, the information provided in this dissertation will provide data that demonstrates how sarcomeric dysfunction contributes to heart failure in the left and right ventricles. Additionally, these data will supply information on how probable therapeutics impact the mechanical properties of the heart and the clinical implications. Thus, the overall objective of this project is to assess the mechanical properties of failing and non-failing human myocardium while concomitantly studying the molecular mechanisms contributing to heart failure and work towards therapy. Mechanical experiments were performed with human cardiac samples obtained from patients who were receiving heart transplants and from organ donors who did not have a history of heart failure. Cardiac samples were homogenized and chemically permeabilized (pores in the membrane). Multicellular preparations from failing and non-failing hearts were attached between a force transducer and a motor to determine the mechanical properties. In the first study, we compared the mechanical properties of cardiac samples from the right and left ventricles of non-failing and failing hearts, as well as determined the relative phosphorylation levels of specific sarcomeric proteins. The results show that in non-failing hearts, calcium sensitivity was higher in the left ventricle, and in failing hearts, calcium sensitivity was higher in the right ventricle. The shift in the pattern of the calcium sensitivity data from non-failing samples to failing samples underpin a statistical interaction between heart failure status and the ventricles of the heart for calcium sensitivity. This interaction suggests that heart failure is altering the sensitivity of the myofilament to Ca2+ differently in the right ventricle. The mechanical data also demonstrated that heart failure significantly reduced isometric force and maximum power in both ventricles. Biochemical assays suggest that the cause of the interaction observed in the calcium sensitivity data is driven by the phosphorylation profile of sarcomeric proteins. We then determined the effects of two small molecules (omecamtiv mecarbil and para-Nitroblebbistatin) on the mechanical properties of human myocardium. The results of those studies demonstrate that omecamtiv mecarbil increases calcium sensitivity and slows the rate of force development in a dose-dependent manner without altering maximum isometric force. Conversely, para-Nitroblebbistatin reduced isometric force, power, and calcium sensitivity without changing shortening velocity or the rate of force development. Lastly, we measured the effects of engineered troponins on the mechanical function of failing tissue. The results show that troponin C and troponin I designed to either increase or decrease calcium sensitivity can significantly increase or decrease calcium sensitivity without altering maximum force, shortening velocity or the rate of tension development. The findings reported in this dissertation have revealed novel mechanical data from non-failing and failing human cardiac tissue. These data present three significant results. First, the right vs. left ventricular comparison data shows that heart failure in humans reduces maximum force and power in both ventricles equally while altering myofilament calcium sensitivity of the left and right ventricles in different ways. The change in calcium sensitivity may reflect ventricle specific post-translational modifications of sarcomeric proteins. Second, the use of myosin modulators revealed that molecules like omecamtiv mecarbil and para-Nitroblebbistatin that directly target myosin function can modify calcium sensitivity and the rate of force development in human cardiac tissue. Third, the engineered troponin study showed that engineered troponins C and I can alter myofilament calcium sensitivity without affecting myosin kinetics. Clinically, the results of the small molecules and engineered protein studies suggest that small molecules and engineered proteins could potentially serve as therapy for patients suffering from heart disease.

Published
2017
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32. No Difference in Myosin Kinetics and Spatial Distribution of the Lever Arm in the Left and Right Ventricles of Human Hearts

Author

Duggal, Divya, primary, Requena, S., additional, Nagwekar, Janhavi, additional, Raut, Sangram, additional, Rich, Ryan, additional, Das, Hriday, additional, Patel, Vipul, additional, Gryczynski, Ignacy, additional, Fudala, Rafal, additional, Gryczynski, Zygmunt, additional, Blair, Cheavar, additional, Campbell, Kenneth S., additional, and Borejdo, Julian, additional

Published
2017
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38. A Protocol for Collecting Human Cardiac Tissue for Research

Author

Blair, Cheavar A., primary, Haynes, Premi, primary, Campbell, Stuart G., primary, Chung, Charles, primary, Mitov, Mihail I., primary, Dennis, Donna, primary, Bonnell, Mark R., primary, Hoopes, Charles W., primary, Guglin, Maya, primary, and Campbell, Kenneth S., primary

Published
2016
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45. Modulating Beta-Cardiac Myosin Function at the Molecular and Tissue Levels.

Author

Wanjian Tang, Blair, Cheavar A., Walton, Shane D., Málnási-Csizmadia, András, Campbell, Kenneth S., and Yengo, Christopher M.

Subjects
MYOSIN, CARDIOMYOPATHIES, MOLECULAR motor proteins, MUSCLE contraction, ADENOSINE triphosphatase
Abstract

Inherited cardiomyopathies are a common form of heart disease that are caused by mutations in sarcomeric proteins with beta cardiac myosin (MYH7) being one of the most frequently affected genes. Since the discovery of the first cardiomyopathy associated mutation in beta-cardiac myosin, a major goal has been to correlate the in vitro myosin motor properties with the contractile performance of cardiac muscle. There has been substantial progress in developing assays to measure the force and velocity properties of purified cardiac muscle myosin but it is still challenging to correlate results from molecular and tissue-level experiments. Mutations that cause hypertrophic cardiomyopathy are more common than mutations that lead to dilated cardiomyopathy and are also often associated with increased isometric force and hyper-contractility. Therefore, the development of drugs designed to decrease isometric force by reducing the duty ratio (the proportion of time myosin spends bound to actin during its ATPase cycle) has been proposed for the treatment of hypertrophic cardiomyopathy. Para-Nitroblebbistatin is a small molecule drug proposed to decrease the duty ratio of class II myosins. We examined the impact of this drug on human beta cardiac myosin using purified myosin motor assays and studies of permeabilized muscle fiber mechanics. We find that with purified human beta-cardiac myosin para-Nitroblebbistatin slows actin-activated ATPase and in vitro motility without altering the ADP release rate constant. In permeabilized human myocardium, para-Nitroblebbistatin reduces isometric force, power, and calcium sensitivity while not changing shortening velocity or the rate of force development (ktr). Therefore, designing a drug that reduces the myosin duty ratio by inhibiting strong attachment to actin while not changing detachment can cause a reduction in force without changing shortening velocity or relaxation. [ABSTRACT FROM AUTHOR]

Published
2017
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47. Sarcomere length affects Ca2+ sensitivity of contraction in ischemic but not non-ischemic myocardium.

Author

Tanner, Bertrand C. W., Awinda, Peter O., Agonias, Keinan B., Attili, Seetharamaiah, Blair, Cheavar A., Thompson, Mindy S., Walker, Lori A., Kampourakis, Thomas, and Campbell, Kenneth S.

Subjects
*MYOCARDIUM, *CARDIAC contraction, *SMOOTH muscle contraction, *HEART failure patients, *TROPONIN I, *HEART transplantation, *HEART failure
Abstract

In healthy hearts, myofilaments become more sensitive to Ca2+ as the myocardium is stretched. This effect is known as length-dependent activation and is an important cellular-level component of the Frank--Starling mechanism. Few studies have measured length-dependent activation in the myocardium from failing human hearts. We investigated whether ischemic and non-ischemic heart failure results in different length-dependent activation responses at physiological temperature (37°C). Myocardial strips from the left ventricular free wall were chemically permeabilized and Ca2+-activated at sarcomere lengths (SLs) of 1.9 and 2.3 µm. Data were acquired from 12 hearts that were explanted from patients receiving cardiac transplants; 6 had ischemic heart failure and 6 had non-ischemic heart failure. Another 6 hearts were obtained from organ donors. Maximal Ca2+-activated force increased at longer SL for all groups. Ca2+ sensitivity increased with SL in samples from donors (P < 0.001) and patients with ischemic heart failure (P = 0.003) but did not change with SL in samples from patients with non-ischemic heart failure. Compared with donors, troponin I phosphorylation decreased in ischemic samples and even more so in nonischemic samples; cardiac myosin binding protein-C (cMyBP-C) phosphorylation also decreased with heart failure. These findings support the idea that troponin I and cMyBP-C phosphorylation promote length-dependent activation and show that length-dependent activation of contraction is blunted, yet extant, in the myocardium from patients with ischemic heart failure and further reduced in the myocardium from patients with non-ischemic heart failure. Patients who have a non-ischemic disease may exhibit a diminished contractile response to increased ventricular filling. [ABSTRACT FROM AUTHOR]

Published
2023
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48. Multi-scale models reveal hypertrophic cardiomyopathy MYH7 G256E mutation drives hypercontractility and elevated mitochondrial respiration.

Author

Lee S, Roest ASV, Blair CA, Kao K, Bremner SB, Childers MC, Pathak D, Heinrich P, Lee D, Chirikian O, Mohran S, Roberts B, Smith JE, Jahng JW, Paik DT, Wu JC, Gunawardane RN, Spudich JA, Ruppel K, Mack D, Pruitt BL, Regnier M, Wu SM, and Bernstein D

Abstract

Rationale: Over 200 mutations in the sarcomeric protein β-myosin heavy chain (MYH7) have been linked to hypertrophic cardiomyopathy (HCM). However, different mutations in MYH7 lead to variable penetrance and clinical severity, and alter myosin function to varying degrees, making it difficult to determine genotype-phenotype relationships, especially when caused by rare gene variants such as the G256E mutation., Objective: This study aims to determine the effects of low penetrant MYH7 G256E mutation on myosin function. We hypothesize that the G256E mutation would alter myosin function, precipitating compensatory responses in cellular functions., Methods: We developed a collaborative pipeline to characterize myosin function at multiple scales (protein to myofibril to cell to tissue). We also used our previously published data on other mutations to compare the degree to which myosin function was altered., Results: At the protein level, the G256E mutation disrupts the transducer region of the S1 head and reduces the fraction of myosin in the folded-back state by 50.9%, suggesting more myosins available for contraction. Myofibrils isolated from hiPSC-CMs CRISPR-edited with G256E (MYH7 WT/G256E ) generated greater tension, had faster tension development and slower early phase relaxation, suggesting altered myosin-actin crossbridge cycling kinetics. This hypercontractile phenotype persisted in single-cell hiPSC-CMs and engineered heart tissues. Single-cell transcriptomic and metabolic profiling demonstrated upregulation of mitochondrial genes and increased mitochondrial respiration, suggesting altered bioenergetics as an early feature of HCM., Conclusions: MYH7 G256E mutation causes structural instability in the transducer region, leading to hypercontractility across scales, perhaps from increased myosin recruitment and altered crossbridge cycling. Hypercontractile function of the mutant myosin was accompanied by increased mitochondrial respiration, while cellular hypertrophy was modest in the physiological stiffness environment. We believe that this multi-scale platform will be useful to elucidate genotype-phenotype relationships underlying other genetic cardiovascular diseases.

Published
2023
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