Your search keyword '"Julian E Stelzer"' showing total 72 results

1. Mechanism-based myofilament manipulation to treat diastolic dysfunction in HFpEF

Author

Katherine L. Dominic, Alexandra V. Schmidt, Henk Granzier, Kenneth S. Campbell, and Julian E. Stelzer

Subjects

HFpEF, heart failure with preserved ejection fraction, cMyBP-C, cTnI, cardiac troponin I, titin, Physiology, QP1-981

Abstract

Heart failure with preserved ejection fraction (HFpEF) is a major public health challenge, affecting millions worldwide and placing a significant burden on healthcare systems due to high hospitalization rates and limited treatment options. HFpEF is characterized by impaired cardiac relaxation, or diastolic dysfunction. However, there are no therapies that directly treat the primary feature of the disease. This is due in part to the complexity of normal diastolic function, and the challenge of isolating the mechanisms responsible for dysfunction in HFpEF. Without a clear understanding of the mechanisms driving diastolic dysfunction, progress in treatment development has been slow. In this review, we highlight three key areas of molecular dysregulation directly underlying impaired cardiac relaxation in HFpEF: altered calcium sensitivity in the troponin complex, impaired phosphorylation of myosin-binding protein C (cMyBP-C), and reduced titin compliance. We explore how targeting these pathways can restore normal relaxation, improve diastolic function, and potentially provide new therapeutic strategies for HFpEF treatment. Developing effective HFpEF therapies requires precision targeting to balance systolic and diastolic function, avoiding both upstream non-specificity and downstream rigidity. This review highlights three rational molecular targets with a strong mechanistic basis and potential for therapeutic success.

Published

2024

2. Length-dependent changes in contractile dynamics are blunted due to cardiac myosin binding protein-C ablation

Author

Ranganath eMamidi, Kenneth S Gresham, and Julian E Stelzer

Subjects

cMyBP-C, sarcomere length, length-dependent activation, cross-bridge kinetics, myofilament function, Physiology, QP1-981

Abstract

Enhanced cardiac contractile function with increased sarcomere length (SL) is, in part, mediated by a decrease in the radial distance between myosin heads and actin. The radial disposition of myosin heads relative to actin is modulated by cardiac myosin binding protein-C (cMyBP-C), suggesting that cMyBP-C contributes to the length-dependent activation (LDA) in the myocardium. However, the precise roles of cMyBP-C in modulating cardiac LDA are unclear. To determine the impact of cMyBP-C on LDA, we measured isometric force, myofilament Ca2+-sensitivity (pCa50) and length-dependent changes in kinetic parameters of cross-bridge (XB) relaxation (krel), and recruitment (kdf) due to rapid stretch, as well as the rate of force redevelopment (ktr) in response to a large slack-restretch maneuver in skinned ventricular multicellular preparations isolated from the hearts of wild-type (WT) and cMyBP-C knockout (KO) mice, at SL’s 1.9µm or 2.1µm. Our results show that maximal force was not significantly different between KO and WT preparations but length-dependent increase in pCa50 was attenuated in the KO preparations. pCa50 was not significantly different between WT and KO preparations at long SL (5.82±0.02 in WT vs. 5.87±0.02 in KO), whereas pCa50 was significantly different between WT and KO preparations at short SL (5.71±0.02 in WT vs. 5.80±0.01 in KO; p

Published

2014

3. Bringing into focus the central domains C3-C6 of myosin binding protein C

Author

Chang Yoon Doh, Alexandra V. Schmidt, Krishna Chinthalapudi, and Julian E. Stelzer

Subjects

myosin binding protein C, central domains, hypertrophic cardiomyopathy (HCM), muscle regulation, protein dynamics and conformation, protein interactions, Physiology, QP1-981

Abstract

Myosin binding protein C (MyBPC) is a multi-domain protein with each region having a distinct functional role in muscle contraction. The central domains of MyBPC have often been overlooked due to their unclear roles. However, recent research shows promise in understanding their potential structural and regulatory functions. Understanding the central region of MyBPC is important because it may have specialized function that can be used as drug targets or for disease-specific therapies. In this review, we provide a brief overview of the evolution of our understanding of the central domains of MyBPC in regard to its domain structures, arrangement and dynamics, interaction partners, hypothesized functions, disease-causing mutations, and post-translational modifications. We highlight key research studies that have helped advance our understanding of the central region. Lastly, we discuss gaps in our current understanding and potential avenues to further research and discovery.

Published

2024

4. Effect of the Novel Myotrope Danicamtiv on Cross‐Bridge Behavior in Human Myocardium

Author

Joohee Choi, Joshua B. Holmes, Kenneth S. Campbell, and Julian E. Stelzer

Subjects

heart failure, myocardium, myosin modulators, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Background Omecamtiv mecarbil (OM) and danicamtiv both increase myocardial force output by selectively activating myosin within the cardiac sarcomere. Enhanced force generation is presumably due to an increase in the total number of myosin heads bound to the actin filament; however, detailed comparisons of the molecular mechanisms of OM and danicamtiv are lacking. Methods and Results The effect of OM and danicamtiv on Ca2+ sensitivity of force generation was analyzed by exposing chemically skinned myocardial samples to a series of increasing Ca2+ solutions. The results showed that OM significantly increased Ca2+ sensitivity of force generation, whereas danicamtiv showed similar Ca2+ sensitivity of force generation to untreated preparations. A direct comparison of OM and danicamtiv on dynamic cross‐bridge behavior was performed at a concentration that produced a similar force increase when normalized to predrug levels at submaximal force (pCa 6.1). Both OM and danicamtiv‐treated groups slowed the rates of cross‐bridge detachment from the strongly bound state and cross‐bridge recruitment into the force‐producing state. Notably, the significant OM‐induced prolongation in the time to reach force relaxation and subsequent commencement of force generation following rapid stretch was dramatically reduced in danicamtiv‐treated myocardium. Conclusions This is the first study to directly compare the effects of OM and danicamtiv on cross‐bridge kinetics. At a similar level of force enhancement, danicamtiv had a less pronounced effect on the slowing of cross‐bridge kinetics and, therefore, may provide a similar improvement in systolic function as OM without excessively prolonging systolic ejection time and slowing cardiac relaxation facilitating diastolic filling at the whole‐organ level.

Published

2023

5. Basic science methods for the characterization of variants of uncertain significance in hypertrophic cardiomyopathy

Author

Chang Yoon Doh, Thomas Kampourakis, Kenneth S. Campbell, and Julian E. Stelzer

Subjects

hypertrophic cardiomyopathy (HCM), dilated cardiomyopathy (DCM), variants of uncertain clinical significance (VUS), restrictive cardiomyopathy (RCM), high throughput screen (HTS), mathematical modeling & simulation, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

With the advent of next-generation whole genome sequencing, many variants of uncertain significance (VUS) have been identified in individuals suffering from inheritable hypertrophic cardiomyopathy (HCM). Unfortunately, this classification of a genetic variant results in ambiguity in interpretation, risk stratification, and clinical practice. Here, we aim to review some basic science methods to gain a more accurate characterization of VUS in HCM. Currently, many genomic data-based computational methods have been developed and validated against each other to provide a robust set of resources for researchers. With the continual improvement in computing speed and accuracy, in silico molecular dynamic simulations can also be applied in mutational studies and provide valuable mechanistic insights. In addition, high throughput in vitro screening can provide more biologically meaningful insights into the structural and functional effects of VUS. Lastly, multi-level mathematical modeling can predict how the mutations could cause clinically significant organ-level dysfunction. We discuss emerging technologies that will aid in better VUS characterization and offer a possible basic science workflow for exploring the pathogenicity of VUS in HCM. Although the focus of this mini review was on HCM, these basic science methods can be applied to research in dilated cardiomyopathy (DCM), restrictive cardiomyopathy (RCM), arrhythmogenic cardiomyopathy (ACM), or other genetic cardiomyopathies.

Published

2023

6. AAV9 gene transfer of cMyBPC N-terminal domains ameliorates cardiomyopathy in cMyBPC-deficient mice

Author

Jiayang Li, Ranganath Mamidi, Chang Yoon Doh, Joshua B. Holmes, Nikhil Bharambe, Rajesh Ramachandran, and Julian E. Stelzer

Subjects

Cardiology, Medicine

Abstract

Decreased cardiac myosin-binding protein C (cMyBPC) expression due to inheritable mutations is thought to contribute to the hypertrophic cardiomyopathy (HCM) phenotype, suggesting that increasing cMyBPC content is of therapeutic benefit. In vitro assays show that cMyBPC N-terminal domains (NTDs) contain structural elements necessary and sufficient to modulate actomyosin interactions, but it is unknown if they can regulate in vivo myocardial function. To test whether NTDs can recapitulate the effects of full-length (FL) cMyBPC in rescuing cardiac function in a cMyBPC-null mouse model of HCM, we assessed the efficacy of AAV9 gene transfer of a cMyBPC NTD that contained domains C0C2 and compared its therapeutic potential with AAV9-FL gene replacement. AAV9 vectors were administered systemically at neonatal day 1, when early-onset disease phenotypes begin to manifest. A comprehensive analysis of in vivo and in vitro function was performed following cMyBPC gene transfer. Our results show that a systemic injection of AAV9-C0C2 significantly improved cardiac function (e.g., 52.24 ± 1.69 ejection fraction in the C0C2-treated group compared with 40.07 ± 1.97 in the control cMyBPC–/– group, P < 0.05) and reduced the histopathologic signs of cardiomyopathy. Furthermore, C0C2 significantly slowed and normalized the accelerated cross-bridge kinetics found in cMyBPC–/– control myocardium, as evidenced by a 32.41% decrease in the rate of cross-bridge detachment (krel). Results indicate that C0C2 can rescue biomechanical defects of cMyBPC deficiency and that the NTD may be a target region for therapeutic myofilament kinetic manipulation.

Published

2020

7. The contribution of N-terminal truncated cMyBPC to in vivo cardiac function

Author

Katherine L. Dominic, Joohee Choi, Joshua B. Holmes, Mandeep Singh, Michael J. Majcher, and Julian E. Stelzer

Subjects

Physiology

Abstract

Cardiac myosin binding protein C (cMyBPC) is an 11-domain sarcomeric protein (C0–C10) integral to cardiac muscle regulation. In vitro studies have demonstrated potential functional roles for regions beyond the N-terminus. However, the in vivo contributions of these domains are mostly unknown. Therefore, we examined the in vivo consequences of expression of N-terminal truncated cMyBPC (C3C10). Neonatal cMyBPC−/− mice were injected with AAV9-full length (FL), C3C10 cMyBPC, or saline, and echocardiography was performed 6 wk after injection. We then isolated skinned myocardium from virus-treated hearts and performed mechanical experiments. Our results show that expression of C3C10 cMyBPC in cMyBPC−/− mice resulted in a 28% increase in systolic ejection fraction compared to saline-injected cMyBPC−/− mice and a 25% decrease in left ventricle mass-to-body weight ratio. However, unlike expression of FL cMyBPC, there was no prolongation of ejection time compared to saline-injected mice. In vitro mechanical experiments demonstrated that functional improvements in cMyBPC−/− mice expressing C3C10 were primarily due to a 35% reduction in the rate of cross-bridge recruitment at submaximal Ca2+ concentrations when compared to hearts from saline-injected cMyBPC−/− mice. However, unlike the expression of FL cMyBPC, there was no change in the rate of cross-bridge detachment when compared to saline-injected mice. Our data demonstrate that regions of cMyBPC beyond the N-terminus are important for in vivo cardiac function, and have divergent effects on cross-bridge behavior. Elucidating the molecular mechanisms of cMyBPC region-specific function could allow for development of targeted approaches to manipulate specific aspects of cardiac contractile function.

Published

2023

8. Identification of Phosphorylation and Other Post-Translational Modifications in the Central C4C5 Domains of Murine Cardiac Myosin Binding Protein C

Author

Chang Yoon Doh, Katherine L. Dominic, Caitlin E. Swanberg, Nikhil Bharambe, Belinda B. Willard, Ling Li, Rajesh Ramachandran, and Julian E. Stelzer

Subjects

General Chemical Engineering, General Chemistry

Abstract

Cardiac myosin binding protein C (cMyBPC) is a critical multidomain protein that modulates myosin cross bridge behavior and cardiac contractility. cMyBPC is principally regulated by phosphorylation of the residues within the M-domain of its N-terminus. However, not much is known about the phosphorylation or other post-translational modification (PTM) landscape of the central C4C5 domains. In this study, the presence of phosphorylation outside the M-domain was confirmed in vivo using mouse models expressing cMyBPC with nonphosphorylatable serine (S) to alanine substitutions. Purified recombinant mouse C4C5 domain constructs were incubated with 13 different kinases, and samples from the 6 strongest kinases were chosen for mass spectrometry analysis. A total of 26 unique phosphorylated peptides were found, representing 13 different phosphorylation sites including 10 novel sites. Parallel reaction monitoring and subsequent mutagenesis experiments revealed that the S690 site (UniProtKB O70468) was the predominant target of PKA and PKG1. We also report 6 acetylation and 7 ubiquitination sites not previously described in the literature. These PTMs demonstrate the possibility of additional layers of regulation and potential importance of the central domains of cMyBPC in cardiac health and disease. Data are available via ProteomeXchange with identifier PXD031262.

Published

2022

9. Impact of the Myosin Modulator Mavacamten on Force Generation and Cross‐Bridge Behavior in a Murine Model of Hypercontractility

Author

Ranganath Mamidi, Jiayang Li, Chang Yoon Doh, Sujeet Verma, and Julian E. Stelzer

Subjects

cardiac muscle, cardiomyopathy, contractile function, cross‐bridge behavior, Mavacamten, myocardium, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Background Recent studies suggest that mavacamten (Myk461), a small myosin‐binding molecule, decreases hypercontractility in myocardium expressing hypertrophic cardiomyopathy‐causing missense mutations in myosin heavy chain. However, the predominant feature of most mutations in cardiac myosin binding protein‐C (cMyBPC) that cause hypertrophic cardiomyopathy is reduced total cMyBPC expression, and the impact of Myk461 on cMyBPC‐deficient myocardium is currently unknown. Methods and Results We measured the impact of Myk461 on steady‐state and dynamic cross‐bridge (XB) behavior in detergent‐skinned mouse wild‐type myocardium and myocardium lacking cMyBPC (knockout (KO)). KO myocardium exhibited hypercontractile XB behavior as indicated by significant accelerations in rates of XB detachment (krel) and recruitment (kdf) at submaximal Ca2+ activations. Incubation of KO and wild‐type myocardium with Myk461 resulted in a dose‐dependent force depression, and this impact was more pronounced at low Ca2+ activations. Interestingly, Myk461‐induced force depressions were less pronounced in KO myocardium, especially at low Ca2+ activations, which may be because of increased acto‐myosin XB formation and potential disruption of super‐relaxed XBs in KO myocardium. Additionally, Myk461 slowed krel in KO myocardium but not in wild‐type myocardium, indicating increased XB “on” time. Furthermore, the greater degree of Myk461‐induced slowing in kdf and reduction in XB recruitment magnitude in KO myocardium normalized the XB behavior back to wild‐type levels. Conclusions This is the first study to demonstrate that Myk461‐induced force depressions are modulated by cMyBPC expression levels in the sarcomere, and emphasizes that clinical use of Myk461 may need to be optimized based on the molecular trigger that underlies the hypertrophic cardiomyopathy phenotype.

Published

2018

10. AAV9 gene transfer of N-terminal truncated cMyBPC ameliorates cardiac function in cMyBPC-deficient mice

Author

Katherine L. Dominic, Joshua B. Holmes, Mandeep Singh, Michael J. Majcher, and Julian E. Stelzer

Subjects

Biophysics

Published

2023

11. Myocardial-restricted ablation of the GTPase RAD results in a pro-adaptive heart response in mice

Author

Ming C. Gong, Douglas A. Andres, Mihir Shah, Nemat Ali, Brooke M. Ahern, Andrea Sebastian, Julian E. Stelzer, Jiayang Li, Jonathan Satin, Wen Su, Sudhakar Veeranki, and Bryana M. Levitan

Subjects

0301 basic medicine, Cardiac function curve, Inotrope, medicine.medical_specialty, Lusitropy, Calcium Channels, L-Type, chemistry.chemical_element, Cardiomegaly, Mice, Transgenic, Calcium, Biochemistry, GTP Phosphohydrolases, Sarcoplasmic Reticulum Calcium-Transporting ATPases, Mice, 03 medical and health sciences, Internal medicine, Receptors, Adrenergic, beta, medicine, Animals, Humans, Myocytes, Cardiac, Calcium Signaling, Receptor, Molecular Biology, Heart Failure, Mice, Knockout, 030102 biochemistry & molecular biology, business.industry, Myocardium, Calcium channel, Cell Biology, medicine.disease, Myocardial Contraction, Mice, Inbred C57BL, Calcium ATPase, Sarcoplasmic Reticulum, 030104 developmental biology, Endocrinology, chemistry, Heart failure, ras Proteins, business, Signal Transduction

Abstract

Existing therapies to improve heart function target β-adrenergic receptor (β-AR) signaling and Ca(2+) handling and often lead to adverse outcomes. This underscores an unmet need for positive inotropes that improve heart function without any adverse effects. The GTPase Ras associated with diabetes (RAD) regulates L-type Ca(2+) channel (LTCC) current (I(Ca,L)). Global RAD-knockout mice (gRAD(−/−)) have elevated Ca(2+) handling and increased cardiac hypertrophy, but RAD is expressed also in noncardiac tissues, suggesting the possibility that pathological remodeling is due also to noncardiac effects. Here, we engineered a myocardial-restricted inducible RAD-knockout mouse (RAD(Δ/Δ)). Using an array of methods and techniques, including single-cell electrophysiological and calcium transient recordings, echocardiography, and radiotelemetry monitoring, we found that RAD deficiency results in a sustained increase of inotropy without structural or functional remodeling of the heart. I(Ca,L) was significantly increased, with RAD loss conferring a β-AR–modulated phenotype on basal I(Ca,L). Cardiomyocytes from RAD(Δ/Δ) hearts exhibited enhanced cytosolic Ca(2+) handling, increased contractile function, elevated sarcoplasmic/endoplasmic reticulum calcium ATPase 2 (SERCA2a) expression, and faster lusitropy. These results argue that myocardial RAD ablation promotes a beneficial elevation in Ca(2+) dynamics, which would obviate a need for increased β-AR signaling to improve cardiac function.

Published

2019

12. The HCM-causing Y235S cMyBPC mutation accelerates contractile function by altering C1 domain structure

Author

Ranganath Mamidi, Chang Yoon Doh, Julian E. Stelzer, and Jiayang Li

Subjects

Male, Sarcomeres, 0301 basic medicine, Mice, 129 Strain, Biophysics, Mutation, Missense, 030204 cardiovascular system & hematology, medicine.disease_cause, Sarcomere, Article, Frameshift mutation, Mice, 03 medical and health sciences, 0302 clinical medicine, Protein Domains, Serine, medicine, Animals, Missense mutation, Amino Acid Sequence, Tyrosine, Molecular Biology, 030304 developmental biology, C1 domain, Mice, Knockout, 0303 health sciences, Mutation, Chemistry, Myocardium, Hypertrophic cardiomyopathy, Cardiac muscle, Cardiomyopathy, Hypertrophic, medicine.disease, Myocardial Contraction, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Amino Acid Substitution, Molecular Medicine, Mutant Proteins, Carrier Proteins, Haploinsufficiency, 030217 neurology & neurosurgery

Abstract

Mutations in cardiac myosin binding protein C (cMyBPC) are a major cause of hypertrophic cardiomyopathy (HCM). In particular, a single amino acid substitution of tyrosine to serine at residue 237 in humans (residue 235 in mice) has been linked to HCM with strong disease association. Although cMyBPC truncations, deletions and insertions, and frame shift mutations have been studied, relatively little is known about the functional consequences of missense mutations in cMyBPC. In this study, we characterized the functional and structural effects of the HCM-causing Y235S mutation by performing mechanical experiments and molecular dynamics simulations (MDS). cMyBPC null mouse myocardium was virally transfected with wild-type (WT) or Y235S cMyBPC (KO(Y235S)). We found that Y235S cMyBPC was properly expressed and incorporated into the cardiac sarcomere, suggesting that the mechanism of disease of the Y235S mutation is not haploinsufficiency or poison peptides. Mechanical experiments in detergent-skinned myocardium isolated from KO(Y235S) hearts revealed hypercontractile behavior compared to KO(WT) hearts, evidenced by accelerated cross-bridge kinetics and increased Ca(2+) sensitivity of force generation. In addition, MDS revealed that the Y235S mutation causes alterations in important intramolecular interactions, surface conformations, and electrostatic potential of the C1 domain of cMyBPC. Our combined in vitro and in silico data suggests that the Y235S mutation directly disrupts internal and surface properties of the C1 domain of cMyBPC, which potentially alters its ligand-binding interactions. These molecular changes may underlie the mechanism for hypercontractile cross-bridge behavior which ultimately may result in the development of cardiac hypertrophy and in vivo cardiac dysfunction.

Published

2019

13. cMyBPC phosphorylation modulates the effect of omecamtiv mecarbil on myocardial force generation

Author

Joshua B Holmes, Nikhil Madugula, Ranganath Mamidi, Katherine L Dominic, Chang Yoon Doh, and Julian E. Stelzer

Subjects

0301 basic medicine, Physiology, Biophysics, Stimulation, macromolecular substances, Myofilament Special Issue, 2020, 030204 cardiovascular system & hematology, Pharmacology, Sarcomere, Article, Research News, Mice, 03 medical and health sciences, 0302 clinical medicine, In vivo, Myosin, Animals, Humans, Urea, Phosphorylation, Protein kinase A, Molecular physiology, Chemistry, Activator (genetics), Myocardium, Myocardial Contraction, Omecamtiv mecarbil, 030104 developmental biology, Cellular physiology

Abstract

Mamidi et al. investigate the effect of cardiac myosin-binding protein C (cMyBPC) phosphorylation on the response to omecamtiv mecarbil (OM), a candidate heart failure therapy. They show that OM uncouples myocardial force dynamics from cMyBPC phosphorylation, suggesting important therapeutic constraints., Omecamtiv mecarbil (OM), a direct myosin motor activator, is currently being tested as a therapeutic replacement for conventional inotropes in heart failure (HF) patients. It is known that HF patients exhibit dysregulated β-adrenergic signaling and decreased cardiac myosin-binding protein C (cMyBPC) phosphorylation, a critical modulator of myocardial force generation. However, the functional effects of OM in conditions of altered cMyBPC phosphorylation have not been established. Here, we tested the effects of OM on force generation and cross-bridge (XB) kinetics using murine myocardial preparations isolated from wild-type (WT) hearts and from hearts expressing S273A, S282A, and S302A substitutions (SA) in the M domain, between the C1 and C2 domains of cMyBPC, which cannot be phosphorylated. At submaximal Ca2+ activations, OM-mediated force enhancements were less pronounced in SA than in WT myocardial preparations. Additionally, SA myocardial preparations lacked the dose-dependent increases in force that were observed in WT myocardial preparations. Following OM incubation, the basal differences in the rate of XB detachment (krel) between WT and SA myocardial preparations were abolished, suggesting that OM differentially affects the XB behavior when cMyBPC phosphorylation is reduced. Similarly, in myocardial preparations pretreated with protein kinase A to phosphorylate cMyBPC, incubation with OM significantly slowed krel in both the WT and SA myocardial preparations. Collectively, our data suggest there is a strong interplay between the effects of OM and XB behavior, such that it effectively uncouples the sarcomere from cMyBPC phosphorylation levels. Our findings imply that OM may significantly alter the in vivo cardiac response to β-adrenergic stimulation.

Published

2021

14. Molecular characterization of linker and loop-mediated structural modulation and hinge motion in the C4-C5 domains of cMyBPC

Author

Chang Yoon Doh, Nikhil Bharambe, Joshua B. Holmes, Katherine L. Dominic, Caitlin E. Swanberg, Ranganath Mamidi, Yinghua Chen, Smarajit Bandyopadhyay, Rajesh Ramachandran, and Julian E. Stelzer

Subjects

Actin Cytoskeleton, Protein Conformation, Structural Biology, Molecular Dynamics Simulation, Protein Structure, Secondary, Article

Abstract

INTRODUCTION: The central C4 and C5 domains (C4C5) of cardiac myosin binding protein C (cMyBPC) contain a flexible interdomain linker and a cardiac-isoform specific loop. However, their importance in the functional regulation of cMyBPC has not been extensively studied. METHODS AND RESULTS: We expressed recombinant C4C5 proteins with deleted linker and loop regions and performed biophysical experiments to determine each of their structural and dynamic roles. We show that the linker and C5 loop regions modulate the secondary structure and thermal stability of C4C5. Furthermore, we provide evidence through extended molecular dynamics simulations and principle component analyses that C4C5 can adopt a completely bent or latched conformation. The simulation trajectory and interaction network analyses reveal that the completely bent conformation of C4C5 exhibits a specific pattern of residue-level interactions. Therefore, we propose a “hinge-and-latch” mechanism where the linker allows a great degree of flexibility and bending, while the loop aids in achieving a completely bent and latched conformation. Although this may be one of many bent positions that C4C5 can adopt, we illustrate for the first time in molecular detail that this type of large scale conformational change can occur in the central domains of cMyBPC. CONCLUSIONS: Our hinge-and-latch mechanism demonstrates that the linker and loop regions participate in dynamic modulation of cMyBPC’s motion and global conformation. These structural and dynamic features may contribute to muscle isoform-specific regulation of actomyosin activity, and have potential implications regarding its ability to propagate or retract cMyBPC’s regulatory N-terminal domains.

Published

2022

15. AAV9 gene transfer of cMyBPC N-terminal domains ameliorates cardiomyopathy in cMyBPC-deficient mice

Author

Nikhil Bharambe, Joshua B Holmes, Ranganath Mamidi, Jiayang Li, Chang Yoon Doh, Rajesh Ramachandran, and Julian E. Stelzer

Subjects

0301 basic medicine, Cardiac function curve, Myofilament, Cardiomyopathy, Cardiology, Heart failure, Mice, 03 medical and health sciences, Gene therapy, 0302 clinical medicine, Protein Domains, In vivo, medicine, Animals, business.industry, Myocardium, Gene Transfer Techniques, Hypertrophic cardiomyopathy, Stroke Volume, Genetic Therapy, General Medicine, Dependovirus, medicine.disease, Phenotype, Cell biology, 030104 developmental biology, 030220 oncology & carcinogenesis, Medicine, Cardiomyopathies, Carrier Proteins, business, Protein C, Research Article, medicine.drug

Abstract

Decreased cardiac myosin-binding protein C (cMyBPC) expression due to inheritable mutations is thought to contribute to the hypertrophic cardiomyopathy (HCM) phenotype, suggesting that increasing cMyBPC content is of therapeutic benefit. In vitro assays show that cMyBPC N-terminal domains (NTDs) contain structural elements necessary and sufficient to modulate actomyosin interactions, but it is unknown if they can regulate in vivo myocardial function. To test whether NTDs can recapitulate the effects of full-length (FL) cMyBPC in rescuing cardiac function in a cMyBPC-null mouse model of HCM, we assessed the efficacy of AAV9 gene transfer of a cMyBPC NTD that contained domains C0C2 and compared its therapeutic potential with AAV9-FL gene replacement. AAV9 vectors were administered systemically at neonatal day 1, when early-onset disease phenotypes begin to manifest. A comprehensive analysis of in vivo and in vitro function was performed following cMyBPC gene transfer. Our results show that a systemic injection of AAV9-C0C2 significantly improved cardiac function (e.g., 52.24 ± 1.69 ejection fraction in the C0C2-treated group compared with 40.07 ± 1.97 in the control cMyBPC–/– group, P < 0.05) and reduced the histopathologic signs of cardiomyopathy. Furthermore, C0C2 significantly slowed and normalized the accelerated cross-bridge kinetics found in cMyBPC–/– control myocardium, as evidenced by a 32.41% decrease in the rate of cross-bridge detachment (krel). Results indicate that C0C2 can rescue biomechanical defects of cMyBPC deficiency and that the NTD may be a target region for therapeutic myofilament kinetic manipulation., Cardiac function improves following AAV9-mediated delivery of the C0C2 domains of cardiac myosin-binding protein C in a mouse model of hypertrophic cardiomyopathy.

Published

2020

16. Prof. Cristobal dos Remedios and the Sydney Heart Bank: enabling translatable heart failure research

Author

Joshua B Holmes and Julian E. Stelzer

Subjects

medicine.medical_specialty, Structural Biology, business.industry, Heart failure, Biophysics, MEDLINE, Medicine, business, Intensive care medicine, medicine.disease, Molecular Biology, Letter to the Editor

Published

2020

17. Strategies for targeting the cardiac sarcomere: avenues for novel drug discovery

Author

Jiayang Li, Ranganath Mamidi, Chang Yoon Doh, Julian E. Stelzer, and Joshua B Holmes

Subjects

Heart Failure, Sarcomeres, 0303 health sciences, Drug discovery, business.industry, Drug Evaluation, Preclinical, Cardiovascular Agents, medicine.disease, Sarcomere, Article, 03 medical and health sciences, 0302 clinical medicine, Drug Development, Cross bridge kinetics, 030220 oncology & carcinogenesis, Heart failure, Drug Discovery, medicine, Animals, Humans, business, Neuroscience, 030304 developmental biology

Abstract

INTRODUCTION: Heart failure remains one of the largest clinical challenges in the United States. Researchers have continually searched for more effective heart failure treatments that target the cardiac sarcomere but have found few successes despite numerous expensive cardiovascular clinical trials. Among many reasons, the high failure rate of cardiovascular clinical trials may be partly due to incomplete characterization of a drug candidate’s complex interaction with cardiac physiology. AREAS COVERED: In this review, the authors address the issue of preclinical cardiovascular studies. The authors consider inherent tradeoffs made between mechanistic transparency and physiological fidelity for several relevant preclinical techniques at the atomic, molecular, heart muscle fiber, whole heart, and whole-organism levels. Thus, the authors suggest a comprehensive, bottom-up approach to preclinical cardiovascular studies that fosters scientific rigor and hypothesis-driven drug discovery. EXPERT OPINION: In the authors’ opinion, the implementation of hypothesis-driven drug discovery practices, such as the bottom-up approach to preclinical cardiovascular studies, will be imperative for the successful development of novel heart failure treatments. However, additional changes to clinical definitions of heart failure and current drug discovery culture must accompany the bottom-up approach to maximize the effectiveness of hypothesis-driven drug discovery.

Published

2020

18. Evidence for novel phosphorylation sites in the central C4-C5 domains of murine cardiac myosin binding protein C

Author

Chang Yoon Doh, Katherine L. Dominic, Caitlin E. Swanberg, Nikhil Bharambe, Ling Li, Belinda Willard, Rajesh Ramachandran, and Julian E. Stelzer

Subjects

Biophysics

Published

2022

19. The Sydney Heart Bank: improving translational research while eliminating or reducing the use of animal models of human heart disease

Author

Roger Cooke, Fredrik Pontén, Amy Li, Ger J.M. Stienen, S.J. Van Dijk, Sean Lal, Wolfgang A. Linke, Henk Granzier, C.G. dos Remedios, Jacob Odeberg, J. van der Velden, James W. McNamara, F. De Man, Connie R. Bezzina, R. Knöll, Julian E. Stelzer, Peter S. Macdonald, Steven B. Marston, Elisabeth Ehler, and Anne Keogh

Subjects

0301 basic medicine, Information retrieval, Computer science, Published Erratum, Section (typography), Biophysics, MEDLINE, Human heart, Translational research, Disease, 03 medical and health sciences, 030104 developmental biology, Structural Biology, Correct name, Molecular Biology

Abstract

The Sydney Heart Bank (SHB) is one of the largest human heart tissue banks in existence. Its mission is to provide high-quality human heart tissue for research into the molecular basis of human heart failure by working collaboratively with experts in this field. We argue that, by comparing tissues from failing human hearts with age-matched non-failing healthy donor hearts, the results will be more relevant than research using animal models, particularly if their physiology is very different from humans. Tissue from heart surgery must generally be used soon after collection or it significantly deteriorates. Freezing is an option but it raises concerns that freezing causes substantial damage at the cellular and molecular level. The SHB contains failing samples from heart transplant patients and others who provided informed consent for the use of their tissue for research. All samples are cryopreserved in liquid nitrogen within 40 min of their removal from the patient, and in less than 5–10 min in the case of coronary arteries and left ventricle samples. To date, the SHB has collected tissue from about 450 failing hearts (>15,000 samples) from patients with a wide range of etiologies as well as increasing numbers of cardiomyectomy samples from patients with hypertrophic cardiomyopathy. The Bank also has hearts from over 120 healthy organ donors whose hearts, for a variety of reasons (mainly tissue-type incompatibility with waiting heart transplant recipients), could not be used for transplantation. Donor hearts were collected by the St Vincent’s Hospital Heart and Lung transplantation team from local hospitals or within a 4-h jet flight from Sydney. They were flushed with chilled cardioplegic solution and transported to Sydney where they were quickly cryopreserved in small samples. Failing and/or donor samples have been used by more than 60 research teams around the world, and have resulted in more than 100 research papers. The tissues most commonly requested are from donor left ventricles, but right ventricles, atria, interventricular system, and coronary arteries vessels have also been reported. All tissues are stored for long-term use in liquid N or vapor (170–180 °C), and are shipped under nitrogen vapor to avoid degradation of sensitive molecules such as RNAs and giant proteins. We present evidence that the availability of these human heart samples has contributed to a reduction in the use of animal models of human heart failure.

Published

2017

20. Abstract 807: Rad Ablation as a Treatment to Target Cardiac Inotropy via L-type Calcium Channel Function

Author

Jonathan Satin, Nemat Ali, Julian E. Stelzer, Doug Andres, Andrea Sebastian, Mihir Shah, Sudhakar Veeranki, Jiayang Li, Bryana M. Levitan, and Brooke M. Ahern

Subjects

medicine.medical_specialty, Physiology, Chemistry, medicine.medical_treatment, Internal medicine, Cardiac inotropy, Cardiology, medicine, Cardiology and Cardiovascular Medicine, Ablation, L-type calcium channel function

Abstract

The L-type Ca 2+ channel current (I Ca,L ) provides trigger Ca 2+ to contribute to cardiac contraction. Rad GTPase associates with the L-type Ca 2+ channel (LTCC) and serves as an endogenous inhibitor of LTCC activity. Overexpression of Rad blocks I Ca,L ; absence of Rad increases I Ca,L . Rad attenuates β-adrenergic receptor (β-AR) signaling. Chronic β-AR stimulation associates with Ca 2+ mishandling and can promote signaling that progresses towards heart failure. Early studies of global, constitutive Rad-knockout mice (gRadKO) suggested that elevated Ca 2+ dynamics leads to pathological cardiac hypertrophy; however, Rad is also expressed in non-cardiac tissues. Our objective is to test the hypothesis that increased myocardial I Ca,L via Rad deletion safely enhances cardiac function without driving pathological remodeling. We created a cardiac-restricted inducible Rad knockout mouse (Rad Δ/Δ ). In vivo function was measured with echocardiography. We examined I Ca,L through whole cell configuration of the patch clamp technique, assessed Ca 2+ handling, and sarcomere dynamics. Unlike gRadKO, Rad Δ/Δ showed no elevation of fetal gene program, nor fibrosis, and no change to aortic pressure. Rad Δ/Δ had a sustained increase of inotropy without structural or functional remodeling (EF: Rad Δ/Δ =76 ± 2%, n=16; Rad fl/fl =59 ± 4%, n=7; p=0.001.) I Ca,L was significantly increased, with Rad loss mirroring a β-AR modulated phenotype on basal I Ca,L (max. conductance: Rad Δ/Δ =254 ± 19 pS/pF, n=15; Rad fl/fl =144 ± 12 pS/pF, n=18; p-4 ). Contrary to models of chronic β-AR stimulation, Rad Δ/Δ retained β-AR signaling shown in vivo using isoproterenol, and by preserved phosphorylation of protein regulators of Ca 2+ reuptake and contractility. Rad Δ/Δ cardiomyocytes show enhanced cytosolic Ca 2+ handling (Decay of Ca 2+ transient: Rad Δ/Δ = 0.07 ± 0.003 (F 340 /F 380 )/s, n=67, Rad fl/fl = 0.10 ± 0.005, n=69; p-4 ), increased contractile function, and elevated SERCA2a expression. These new findings challenge the canonical assumption that increased myocardial Ca 2+ necessarily promotes pathology. We conclude that cardiac hypertrophy in gRadKO was caused by non-cardiac tissue effects, and myocardial Rad deletion is a promising cardiac inotropic therapeutic direction.

Published

2019

21. The contributions of cardiac myosin binding protein C and troponin I phosphorylation to β-adrenergic enhancement ofin vivocardiac function

Author

Julian E. Stelzer and Kenneth S. Gresham

Subjects

0301 basic medicine, Cardiac function curve, medicine.medical_specialty, Physiology, Chemistry, Adrenergic, 030204 cardiovascular system & hematology, Dephosphorylation, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Endocrinology, Internal medicine, Myosin binding, Troponin I, medicine, Phosphorylation, Dobutamine, Protein kinase A, medicine.drug

Abstract

β-adrenergic stimulation increases cardiac myosin binding protein C (MyBP-C) and troponin I phosphorylation to accelerate pressure development and relaxation in vivo, although their relative contributions remain unknown. Using a novel mouse model lacking protein kinase A-phosphorylatable troponin I (TnI) and MyBP-C, we examined in vivo haemodynamic function before and after infusion of the β-agonist dobutamine. Mice expressing phospho-ablated MyBP-C displayed cardiac hypertrophy and prevented full acceleration of pressure development and relaxation in response to dobutamine, whereas expression of phosphor-ablated TnI alone had little effect on the acceleration of contractile function in response to dobutamine. Our data demonstrate that MyBP-C phosphorylation is the principal mediator of the contractile response to increased β-agonist stimulation in vivo. These results help us understand why MyBP-C dephosphorylation in the failing heart contributes to contractile dysfunction and decreased adrenergic reserve in response to acute stress. β-adrenergic stimulation plays a critical role in accelerating ventricular contraction and speeding relaxation to match cardiac output to changing circulatory demands. Two key myofilaments proteins, troponin I (TnI) and myosin binding protein-C (MyBP-C), are phosphorylated following β-adrenergic stimulation; however, their relative contributions to the enhancement of in vivo cardiac contractility are unknown. To examine the roles of TnI and MyBP-C phosphorylation in β-adrenergic-mediated enhancement of cardiac function, transgenic (TG) mice expressing non-phosphorylatable TnI protein kinase A (PKA) residues (i.e. serine to alanine substitution at Ser23/24; TnI(PKA-)) were bred with mice expressing non-phosphorylatable MyBP-C PKA residues (i.e. serine to alanine substitution at Ser273, Ser282 and Ser302; MyBPC(PKA-)) to generate a novel mouse model expressing non-phosphorylatable PKA residues in TnI and MyBP-C (DBL(PKA-)). MyBP-C dephosphorylation produced cardiac hypertrophy and increased wall thickness in MyBPC(PKA-) and DBL(PKA-) mice, and in vivo echocardiography and pressure-volume catheterization studies revealed impaired systolic function and prolonged diastolic relaxation compared to wild-type and TnI(PKA-) mice. Infusion of the β-agonist dobutamine resulted in accelerated rates of pressure development and relaxation in all mice; however, MyBPC(PKA-) and DBL(PKA-) mice displayed a blunted contractile response compared to wild-type and TnI(PKA-) mice. Furthermore, unanaesthesized MyBPC(PKA-) and DBL(PKA-) mice displayed depressed maximum systolic pressure in response to dobutamine as measured using implantable telemetry devices. Taken together, our data show that MyBP-C phosphorylation is a critical modulator of the in vivo acceleration of pressure development and relaxation as a result of enhanced β-adrenergic stimulation, and reduced MyBP-C phosphorylation may underlie depressed adrenergic reserve in heart failure.

Published

2016

22. Impact of the Myosin Modulator Mavacamten on Force Generation and Cross-Bridge Behavior in a Murine Model of Hypercontractility

Author

Chang Yoon Doh, Julian E. Stelzer, Ranganath Mamidi, Sujeet Verma, and Jiayang Li

Subjects

0301 basic medicine, Force generation, Benzylamines, cardiac muscle, Cardiomyopathy, steady‐state force generation, Myosins, Cross bridge, 03 medical and health sciences, Mice, contractile function, Myosin, medicine, Mavacamten, Missense mutation, Animals, Uracil, Original Research, Mice, Knockout, Heart Failure, business.industry, Myocardium, Cardiac muscle, Heart, Cardiomyopathy, Hypertrophic, medicine.disease, Myocardial Contraction, Actins, Cell biology, Disease Models, Animal, 030104 developmental biology, medicine.anatomical_structure, Murine model, Calcium, Cardiology and Cardiovascular Medicine, business, Carrier Proteins, cardiomyopathy, cross‐bridge behavior

Abstract

Background Recent studies suggest that mavacamten (Myk461), a small myosin‐binding molecule, decreases hypercontractility in myocardium expressing hypertrophic cardiomyopathy‐causing missense mutations in myosin heavy chain. However, the predominant feature of most mutations in cardiac myosin binding protein‐C ( cMyBPC ) that cause hypertrophic cardiomyopathy is reduced total cMyBPC expression, and the impact of Myk461 on cMyBPC ‐deficient myocardium is currently unknown. Methods and Results We measured the impact of Myk461 on steady‐state and dynamic cross‐bridge ( XB ) behavior in detergent‐skinned mouse wild‐type myocardium and myocardium lacking cMyBPC (knockout (KO)). KO myocardium exhibited hypercontractile XB behavior as indicated by significant accelerations in rates of XB detachment (k rel ) and recruitment (k df ) at submaximal Ca 2+ activations. Incubation of KO and wild‐type myocardium with Myk461 resulted in a dose‐dependent force depression, and this impact was more pronounced at low Ca 2+ activations. Interestingly, Myk461‐induced force depressions were less pronounced in KO myocardium, especially at low Ca 2+ activations, which may be because of increased acto‐myosin XB formation and potential disruption of super‐relaxed XB s in KO myocardium. Additionally, Myk461 slowed k rel in KO myocardium but not in wild‐type myocardium, indicating increased XB “ on ” time. Furthermore, the greater degree of Myk461‐induced slowing in k df and reduction in XB recruitment magnitude in KO myocardium normalized the XB behavior back to wild‐type levels. Conclusions This is the first study to demonstrate that Myk461‐induced force depressions are modulated by cMyBPC expression levels in the sarcomere, and emphasizes that clinical use of Myk461 may need to be optimized based on the molecular trigger that underlies the hypertrophic cardiomyopathy phenotype.

Published

2018

23. Sarcomere-based genetic enhancement of systolic cardiac function in a murine model of dilated cardiomyopathy

Author

Ranganath Mamidi, Xiaoping Wan, Chang Yoon Doh, Julian E. Stelzer, Kenneth S. Gresham, Jiayang Li, and Isabelle Deschenes

Subjects

0301 basic medicine, Cardiac function curve, Cardiomyopathy, Dilated, Male, Sarcomeres, Cardiac output, medicine.medical_specialty, Mice, 129 Strain, Systole, Muscle Proteins, Mice, Transgenic, 030204 cardiovascular system & hematology, Sarcomere, Article, Muscle hypertrophy, Contractility, 03 medical and health sciences, Mice, 0302 clinical medicine, Internal medicine, Medicine, Animals, Myocytes, Cardiac, Mice, Knockout, Ejection fraction, business.industry, Dilated cardiomyopathy, LIM Domain Proteins, medicine.disease, Disease Models, Animal, 030104 developmental biology, Endocrinology, Heart failure, cardiovascular system, Female, Cardiology and Cardiovascular Medicine, business, Carrier Proteins

Abstract

Diminished cardiac contractile function is a characteristic feature of dilated cardiomyopathy (DCM) and many other heart failure (HF) causing etiologies. We tested the hypothesis that targeting the sarcomere to increase cardiac contractility can effectively prevent the DCM phenotype in muscle-LIM protein knockout (MLP(−/−)) mice. The ablation of cardiac myosin binding protein C (MYBPC3(−/−)) protected the MLP(−/−) mice from developing the DCM pheno-type. We examined the in vivo cardiac function and morphology of the resultant mouse model lacking both MLP and MYBPC3 (DKO) by echocardiography and pressure-volume catheterization and found a significant reduction in hypertrophy, as evidenced by normalized wall thickness and chamber dimensions, and improved systolic function, as evidenced by enhanced ejection fraction (~26% increase compared MLP(−/−) mice) and rate of pressure development (DKO 7851.0 ± 504.8 vs. MLP(−/−) 4496.4 ± 196.8 mmHg/s). To investigate the molecular basis for the improved DKO phenotype we performed mechanical experiments in skinned myocardium isolated from WT and the individual KO mice. Skinned myocardium isolated from DKO mice displayed increased Ca(2+) sensitivity of force generation, and significantly accelerated rate of cross-bridge detachment (+63% compared to MLP(−/−)) and rate of XB recruitment (+58% compared to MLP(−/−)) at submaximal Ca(2+) activations. The in vivo and in vitro functional enhancement of DKO mice demonstrates that enhancing the sarcomeric contractility can be cardioprotective in HF characterized by reduced cardiac output, such as in cases of DCM.

Published

2018

24. Lost in translation: Interpreting cardiac muscle mechanics data in clinical practice

Author

Ranganath Mamidi, Joshua B Holmes, Jiayang Li, Julian E. Stelzer, and Chang Yoon Doh

Subjects

0301 basic medicine, Inotrope, Sarcomeres, Cardiotonic Agents, Biophysics, Biochemistry, Sarcomere, Article, Contractility, Translational Research, Biomedical, 03 medical and health sciences, Myosin, medicine, Myocyte, Animals, Humans, Molecular Biology, Heart Failure, 030102 biochemistry & molecular biology, business.industry, Myocardium, Cardiac muscle, medicine.disease, Myocardial Contraction, 030104 developmental biology, medicine.anatomical_structure, Heart failure, business, Neuroscience, Intracellular

Abstract

Current inotropic therapies improve systolic function in heart failure patients but they also elicit undesirable side effects such as arrhythmias and increased intracellular Ca(2+) transients. In order to maintain myocyte Ca(2+) homeostasis, the increased cytosolic Ca(2+) needs to be actively transported back to sarcoplasmic reticulum leading to depleted ATP reserves. Thus, an emerging approach is to design sarcomere-based treatments to correct impaired contractility via a direct and allosteric modulation of myosin’s intrinsic force-generating behavior –a concept that potentially avoids the “off-target” effects. To achieve this goal, various biophysical approaches are utilized to investigate the mechanistic impact of sarcomeric modulators but information derived from diverse approaches is not fully integrated into therapeutic applications. This is in part due to the lack of information that provides a coherent connecting link between biophysical data to in vivo function. Hence, our ability to clearly discern the drug-mediated impact on whole-heart function is diminished. Reducing this translational barrier can significantly accelerate clinical progress related to sarcomere-based therapies by optimizing drug-dosing and treatment duration protocols based on information obtained from biophysical studies. Therefore, we attempt to link biophysical mechanical measurements obtained in isolated cardiac muscle and in vivo contractile function.

Published

2018

25. Dose-Dependent Effects of the Myosin Activator Omecamtiv Mecarbil on Cross-Bridge Behavior and Force Generation in Failing Human Myocardium

Author

Ranganath Mamidi, Julian E. Stelzer, Jiayang Li, Amy Li, Chang Yoon Doh, Kenneth S. Gresham, Sujeet Verma, Sean Lal, and Cristobal G. dos Remedios

Subjects

0301 basic medicine, Sarcomeres, Cardiotonic Agents, Time Factors, Diastole, 030204 cardiovascular system & hematology, In Vitro Techniques, Myosins, Sarcomere, Article, 03 medical and health sciences, 0302 clinical medicine, Troponin T, In vivo, Myosin, Medicine, Humans, Urea, Muscle Strength, Phosphorylation, Heart Failure, Dose-Response Relationship, Drug, Ventricular Remodeling, business.industry, Troponin I, medicine.disease, Myocardial Contraction, Omecamtiv mecarbil, 030104 developmental biology, medicine.anatomical_structure, Ventricle, Heart failure, Case-Control Studies, Biophysics, Steady state (chemistry), Cardiology and Cardiovascular Medicine, business, Carrier Proteins, Protein Binding, Signal Transduction

Abstract

Background: Omecamtiv mecarbil (OM) enhances systolic function in vivo by directly binding the myosin cross-bridges (XBs) in the sarcomere. However, the mechanistic details governing OM-induced modulation of XB behavior in failing human myocardium are unclear. Methods and Results: The effects of OM on steady state and dynamic XB behavior were measured in chemically skinned myocardial preparations isolated from human donor and heart failure (HF) left ventricle. HF myocardium exhibited impaired contractile function as evidenced by reduced maximal force, magnitude of XB recruitment ( P df ), and a slowed rate of XB detachment ( k rel ) at submaximal Ca 2+ activations. Ca 2+ sensitivity of force generation (pCa 50 ) was higher in HF myocardium when compared with donor myocardium, both prior to and after OM incubations. OM incubation (0.5 and 1.0 μmol/L) enhanced force generation at submaximal Ca 2+ activations in a dose-dependent manner. Notably, OM induced a slowing in k rel with 1.0 μmol/L OM but not with 0.5 μmol/L OM in HF myocardium. Additionally, OM exerted other differential effects on XB behavior in HF myocardium as evidenced by a greater enhancement in P df and slowing in the time course of cooperative XB recruitment ( T rec ), which collectively prolonged achievement of peak force development ( T pk ), compared with donor myocardium. Conclusions: Our findings demonstrate that OM augments force generation but also prolongs the time course of XB transitions to force-bearing states in remodeled HF myocardium, which may extend the systolic ejection time in vivo. Optimal OM dosing is critical for eliciting enhanced systolic function without excessive prolongation of systolic ejection time, which may compromise diastolic filling.

Published

2017

26. Cardiac myosin binding protein-C Ser 302 phosphorylation regulates cardiac β-adrenergic reserve

Author

Julian E. Stelzer, Kenneth S. Gresham, Ranganath Mamidi, and Jiayang Li

Subjects

0301 basic medicine, medicine.medical_specialty, Multidisciplinary, Binding protein, Transgene, Regulator, Biology, In vitro, 3. Good health, 03 medical and health sciences, 030104 developmental biology, Blood pressure, Endocrinology, In vivo, Internal medicine, medicine, Phosphorylation, Protein kinase A

Abstract

Phosphorylation of cardiac myosin binding protein-C (MyBP-C) modulates cardiac contractile function; however, the specific roles of individual serines (Ser) within the M-domain that are targets for β-adrenergic signaling are not known. Recently, we demonstrated that significant accelerations in in vivo pressure development following β-agonist infusion can occur in transgenic (TG) mouse hearts expressing phospho-ablated Ser282 (that is, TGS282A) but not in hearts expressing phospho-ablation of all three serines [that is, Ser273, Ser282, and Ser302 (TG3SA)], suggesting an important modulatory role for other Ser residues. In this regard, there is evidence that Ser302 phosphorylation may be a key contributor to the β-agonist-induced positive inotropic responses in the myocardium, but its precise functional role has not been established. Thus, to determine the in vivo and in vitro functional roles of Ser302 phosphorylation, we generated TG mice expressing nonphosphorylatable Ser302 (that is, TGS302A). Left ventricular pressure-volume measurements revealed that TGS302A mice displayed no accelerations in the rate of systolic pressure rise and an inability to maintain systolic pressure following dobutamine infusion similar to TG3SA mice, implicating Ser302 phosphorylation as a critical regulator of enhanced systolic performance during β-adrenergic stress. Dynamic strain-induced cross-bridge (XB) measurements in skinned myocardium isolated from TGS302A hearts showed that the molecular basis for impaired β-adrenergic-mediated enhancements in systolic function is due to the absence of protein kinase A-mediated accelerations in the rate of cooperative XB recruitment. These results demonstrate that Ser302 phosphorylation regulates cardiac contractile reserve by enhancing contractile responses during β-adrenergic stress.

Published

2017

27. The contribution of cardiac myosin binding protein-c Ser282 phosphorylation to the rate of force generation andin vivocardiac contractility

Author

Kenneth S. Gresham, Julian E. Stelzer, and Ranganath Mamidi

Subjects

Cardiac function curve, medicine.medical_specialty, Myofilament, Physiology, Cardiac muscle, Biology, Contractility, medicine.anatomical_structure, Endocrinology, Internal medicine, Ventricular pressure, medicine, Biophysics, Phosphorylation, Myofibril, PRKCE

Abstract

Cardiac myosin binding protein-C phosphorylation plays an important role in modulating cardiac muscle function and accelerating contraction. It has been proposed that Ser282 phosphorylation may serve as a critical molecular switch that regulates the phosphorylation of neighbouring Ser273 and Ser302 residues, and thereby govern myofilament contractile acceleration in response to protein kinase A (PKA). Therefore, to determine the regulatory roles of Ser282 we generated a transgenic (TG) mouse model expressing cardiac myosin binding protein-C with a non-phosphorylatable Ser282 (i.e. serine to alanine substitution, TG(S282A)). Myofibrils isolated from TG(S282A) hearts displayed robust PKA-mediated phosphorylation of Ser273 and Ser302, and the increase in phosphorylation was identical to TG wild-type (TG(WT)) controls. No signs of pathological cardiac hypertrophy were detected in TG(S282A) hearts by either histological examination of cardiac sections or echocardiography. Baseline fractional shortening, ejection fraction, isovolumic relaxation time, rate of pressure development and rate of relaxation (τ) were unaltered in TG(S282A) mice. However, the increase in cardiac contractility as well as the acceleration of pressure development observed in response to β-adrenergic stimulation was attenuated in TG(S282A) mice. In agreement with our in vivo data, in vitro force measurements revealed that PKA-mediated acceleration of cross-bridge kinetics in TG(S282A) myocardium was significantly attenuated compared to TG(WT) myocardium. Taken together, our data suggest that while Ser282 phosphorylation does not regulate the phosphorylation of neighbouring Ser residues and basal cardiac function, full acceleration of cross-bridge kinetics and left ventricular pressure development cannot be achieved in its absence.

Published

2014

28. Cardiac myosin binding protein-C: a novel sarcomeric target for gene therapy

Author

Jiayang Li, Ranganath Mamidi, Julian E. Stelzer, and Kenneth S. Gresham

Subjects

Sarcomeres, medicine.medical_specialty, Myofilament, Physiology, Clinical Biochemistry, Cardiomyopathy, Biology, Sarcomere, Article, Myofibrils, Physiology (medical), Internal medicine, medicine, Humans, Actin, Myocardium, Binding protein, Hypertrophic cardiomyopathy, Genetic Therapy, Cardiomyopathy, Hypertrophic, medicine.disease, Myocardial Contraction, Cell biology, Endocrinology, Carrier Proteins, Myofibril, Function (biology)

Abstract

Through its ability to interact with both the thick and thin filament proteins within the sarcomere, cardiac myosin binding protein-C (cMyBP-C) regulates the contractile properties of the myocardium. The central regulatory role of cMyBP-C in heart function is emphasized by the fact that a large proportion of inherited hypertrophic cardiomyopathy cases in humans are caused by mutations in cMyBP-C. The primary dysfunction in cMyBP-C-related cardiomyopathies is likely to be abnormal myofilament contractile function; however, currently, there are no effective therapies for ameliorating these contractile defects. Thus, there is a compelling need to design novel therapies to restore normal contractile function in cMyBP-C-related cardiomyopathies. To this end, concepts gleaned from various structural, functional, and biochemical studies can now be utilized to engineer cMyBP-C proteins that, when incorporated into the sarcomere, can significantly improve contractile function. In this review, we discuss the rationale for cMyBP-C-based gene therapies that can be utilized to treat contractile dysfunction in inherited and acquired cardiomyopathies.

Published

2013

29. Ionic bases for electrical remodeling of the canine cardiac ventricle

Author

Xiaoping Wan, Isabelle Deschenes, Yoram Rudy, Eckhard Ficker, Lance D. Wilson, Keith F. Decker, Haiyan Liu, Julian E. Stelzer, Mukesh K. Jain, David S. Rosenbaum, Tamer H. Said, and Darwin Jeyaraj

Subjects

Male, medicine.medical_specialty, Potassium Channels, Physiology, Heart Ventricles, Action Potentials, Ionic bonding, Sodium-Calcium Exchanger, Integrative Cardiovascular Physiology and Pathophysiology, Dogs, Sarcolemma, Heart Conduction System, Physiology (medical), Internal medicine, medicine, Animals, Electrical Remodeling, Computer Simulation, Calcium Signaling, Ion channel, Chemistry, Cardiac Pacing, Artificial, Models, Cardiovascular, Cardiac Ventricle, Calcium cycling, Kinetics, Endocrinology, Myocardial strain, Potassium, Biophysics, Calcium, Calcium Channels, Cardiology and Cardiovascular Medicine

Abstract

Emerging evidence suggests that ventricular electrical remodeling (VER) is triggered by regional myocardial strain via mechanoelectrical feedback mechanisms; however, the ionic mechanisms underlying strain-induced VER are poorly understood. To determine its ionic basis, VER induced by altered electrical activation in dogs undergoing left ventricular pacing ( n = 6) were compared with unpaced controls ( n = 4). Action potential (AP) durations (APDs), ionic currents, and Ca2+transients were measured from canine epicardial myocytes isolated from early-activated (low strain) and late-activated (high strain) left ventricular regions. VER in the early-activated region was characterized by minimal APD prolongation, but marked attenuation of the AP phase 1 notch attributed to reduced transient outward K+current. In contrast, VER in the late-activated region was characterized by significant APD prolongation. Despite marked APD prolongation, there was surprisingly minimal change in ion channel densities but a twofold increase in diastolic Ca2+. Computer simulations demonstrated that changes in sarcolemmal ion channel density could only account for attenuation of the AP notch observed in the early-activated region but failed to account for APD remodeling in the late-activated region. Furthermore, these simulations identified that cytosolic Ca2+accounted for APD prolongation in the late-activated region by enhancing forward-mode Na+/Ca2+exchanger activity, corroborated by increased Na+/Ca2+exchanger protein expression. Finally, assessment of skinned fibers after VER identified altered myofilament Ca2+sensitivity in late-activated regions to be associated with increased diastolic levels of Ca2+. In conclusion, we identified two distinct ionic mechanisms that underlie VER: 1) strain-independent changes in early-activated regions due to remodeling of sarcolemmal ion channels with no changes in Ca2+handling and 2) a novel and unexpected mechanism for strain-induced VER in late-activated regions in the canine arising from remodeling of sarcomeric Ca2+handling rather than sarcolemmal ion channels.

Published

2013

30. Impaired contractile function due to decreased cardiac myosin binding protein C content in the sarcomere

Author

Yuanna Cheng, Xiaoping Wan, Tracy A. McElfresh, Kenneth S. Gresham, Julian E. Stelzer, Xiaoqin Chen, David S. Rosenbaum, and Margaret P. Chandler

Subjects

Sarcomeres, Heterozygote, medicine.medical_specialty, Transcription, Genetic, Physiology, Heart Ventricles, Cardiomyopathy, Action Potentials, Biology, medicine.disease_cause, Sarcomere, Mice, Heart Rate, Physiology (medical), Internal medicine, medicine, Animals, Calcium Signaling, Phosphorylation, Calcium signaling, Mutation, Myocardium, Binding protein, Heart, Heterozygote advantage, medicine.disease, Endocrinology, Cardiology, Calcium, medicine.symptom, Carrier Proteins, Cardiology and Cardiovascular Medicine, Muscle Mechanics and Ventricular Function, Muscle Contraction, Muscle contraction

Abstract

Mutations in cardiac myosin binding protein C (MyBP-C) are a common cause of familial hypertrophic cardiomyopathy (FHC). The majority of MyBP-C mutations are expected to reduce MyBP-C expression; however, the consequences of MyBP-C deficiency on the regulation of myofilament function, Ca2+ homeostasis, and in vivo cardiac function are unknown. To elucidate the effects of decreased MyBP-C expression on cardiac function, we employed MyBP-C heterozygous null (MyBP-C+/−) mice presenting decreases in MyBP-C expression (32%) similar to those of FHC patients carrying MyBP-C mutations. The levels of MyBP-C phosphorylation were reduced 53% in MyBP-C+/− hearts compared with wild-type hearts. Skinned myocardium isolated from MyBP-C+/− hearts displayed decreased cross-bridge stiffness at half-maximal Ca2+ activations, increased steady-state force generation, and accelerated rates of cross-bridge recruitment at low Ca2+ activations (+/− and wild-type myocardium. Intact ventricular myocytes from MyBP-C+/− hearts displayed abnormal sarcomere shortening but unchanged Ca2+ transient kinetics. Despite a lack of left ventricular hypertrophy, MyBP-C+/− hearts exhibited elevated end-diastolic pressure and decreased peak rate of LV pressure rise, which was normalized following dobutamine infusion. Furthermore, electrocardiogram recordings in conscious MyBP-C+/− mice revealed prolonged QRS and QT intervals, which are known risk factors for cardiac arrhythmia. Collectively, our data show that reduced MyBP-C expression and phosphorylation in the sarcomere result in myofilament dysfunction, contributing to contractile dysfunction that precedes compensatory adaptations in Ca2+ handling, and chamber remodeling. Perturbations in mechanical and electrical activity in MyBP-C+/− mice could increase their susceptibility to cardiac dysfunction and arrhythmia.

Published

2013

31. Inducible re-expression of HEXIM1 causes physiological cardiac hypertrophy in the adult mouse

Author

Connie Wang, Candida L. Desjardins, Michiko Watanabe, Yanduan Hu, Yong Qui Doughman, Xin Yu, Margaret P. Chandler, Julian E. Stelzer, Thomas E. Dick, Monica M. Montano, Heather M. Bensinger, Brian D. Hoit, and Yee Hsee Hsieh

Subjects

Cardiac function curve, medicine.medical_specialty, Genotype, Physiology, Angiogenesis, Neovascularization, Physiologic, Peroxisome proliferator-activated receptor, Cardiomegaly, Mice, Transgenic, Biology, Transfection, Muscle hypertrophy, Proto-Oncogene Proteins c-myc, Mice, Physiology (medical), Internal medicine, medicine, Animals, Myocytes, Cardiac, PPAR alpha, Transcription factor, Cells, Cultured, PI3K/AKT/mTOR pathway, Regulation of gene expression, chemistry.chemical_classification, GATA4, RNA-Binding Proteins, Stroke Volume, Hypoxia-Inducible Factor 1, alpha Subunit, Magnetic Resonance Imaging, GATA4 Transcription Factor, Phenotype, Endocrinology, Gene Expression Regulation, chemistry, Echocardiography, Physical Endurance, Cardiology and Cardiovascular Medicine, Transcription Factors

Abstract

Aims The transcription factor hexamethylene-bis-acetamide-inducible protein 1 (HEXIM1) regulates myocardial vascularization and growth during cardiogenesis. Our aim was to determine whether HEXIM1 also has a beneficial role in modulating vascularization, myocardial growth, and function within the adult heart. Methods and results To achieve our objective, we created and investigated a mouse line wherein HEXIM1 was re-expressed in adult cardiomyocytes to levels found in the foetal heart. Our findings support a beneficial role for HEXIM1 through increased vascularization, myocardial growth, and increased ejection fraction within the adult heart. HEXIM1 re-expression induces angiogenesis, that is, essential for physiological hypertrophy and maintenance of cardiac function. The ability of HEXIM1 to co-ordinate processes associated with physiological hypertrophy may be attributed to HEXIM1 regulation of other transcription factors (HIF-1-α, c-Myc, GATA4, and PPAR-α) that, in turn, control many genes involved in myocardial vascularization, growth, and metabolism. Moreover, the mechanism for HEXIM1-induced physiological hypertrophy appears to be distinct from that involving the PI3K/AKT pathway. Conclusion HEXIM1 re-expression results in the induction of angiogenesis that allows for the co-ordination of tissue growth and angiogenesis during physiological hypertrophy.

Published

2013

32. Cardiac myosin binding protein-C Ser

Author

Ranganath, Mamidi, Kenneth S, Gresham, Jiayang, Li, and Julian E, Stelzer

Subjects

Heart Ventricles, Myocardium, SciAdv r-articles, Mice, Transgenic, Adrenergic beta-Agonists, cross-bridge kinetics, Myocardial Contraction, Ventricular Function, Left, hemodynamic function, Mice, contractile reserve, Animals, cardiac contractile function, Phosphorylation, Carrier Proteins, Cardiac Function, Research Articles, Research Article

Abstract

MyBP-C Ser302 phosphorylation regulates access to cardiac contractile reserve in response to increased β-adrenergic stimulation., Phosphorylation of cardiac myosin binding protein-C (MyBP-C) modulates cardiac contractile function; however, the specific roles of individual serines (Ser) within the M-domain that are targets for β-adrenergic signaling are not known. Recently, we demonstrated that significant accelerations in in vivo pressure development following β-agonist infusion can occur in transgenic (TG) mouse hearts expressing phospho-ablated Ser282 (that is, TGS282A) but not in hearts expressing phospho-ablation of all three serines [that is, Ser273, Ser282, and Ser302 (TG3SA)], suggesting an important modulatory role for other Ser residues. In this regard, there is evidence that Ser302 phosphorylation may be a key contributor to the β-agonist–induced positive inotropic responses in the myocardium, but its precise functional role has not been established. Thus, to determine the in vivo and in vitro functional roles of Ser302 phosphorylation, we generated TG mice expressing nonphosphorylatable Ser302 (that is, TGS302A). Left ventricular pressure-volume measurements revealed that TGS302A mice displayed no accelerations in the rate of systolic pressure rise and an inability to maintain systolic pressure following dobutamine infusion similar to TG3SA mice, implicating Ser302 phosphorylation as a critical regulator of enhanced systolic performance during β-adrenergic stress. Dynamic strain–induced cross-bridge (XB) measurements in skinned myocardium isolated from TGS302A hearts showed that the molecular basis for impaired β-adrenergic–mediated enhancements in systolic function is due to the absence of protein kinase A–mediated accelerations in the rate of cooperative XB recruitment. These results demonstrate that Ser302 phosphorylation regulates cardiac contractile reserve by enhancing contractile responses during β-adrenergic stress.

Published

2016

33. Sarcomeric protein modification during adrenergic stress enhances cross-bridge kinetics and cardiac output

Author

Kenneth S. Gresham, Hyerin Kwak, Jiayang Li, Ranganath Mamidi, and Julian E. Stelzer

Subjects

0301 basic medicine, Cardiac function curve, Male, Sarcomeres, medicine.medical_specialty, Cardiac output, Physiology, Adrenergic, 030204 cardiovascular system & hematology, Biology, Stress (mechanics), Contractility, 03 medical and health sciences, Mice, 0302 clinical medicine, Myofibrils, Stress, Physiological, Physiology (medical), Internal medicine, Troponin I, medicine, Animals, Cardiac Output, Mechanism (biology), Adaptation, Physiological, Myocardial Contraction, Cell biology, Actin Cytoskeleton, Kinetics, 030104 developmental biology, Endocrinology, Posttranslational modification, cardiovascular system, Carrier Proteins, Research Article

Abstract

Molecular adaptations to chronic neurohormonal stress, including sarcomeric protein cleavage and phosphorylation, provide a mechanism to increase ventricular contractility and enhance cardiac output, yet the link between sarcomeric protein modifications and changes in myocardial function remains unclear. To examine the effects of neurohormonal stress on posttranslational modifications of sarcomeric proteins, mice were administered combined α- and β-adrenergic receptor agonists (isoproterenol and phenylephrine, IPE) for 14 days using implantable osmotic pumps. In addition to significant cardiac hypertrophy and increased maximal ventricular pressure, IPE treatment accelerated pressure development and relaxation (74% increase in dP/d tmax and 14% decrease in τ), resulting in a 52% increase in cardiac output compared with saline (SAL)-treated mice. Accelerated pressure development was maintained when accounting for changes in heart rate and preload, suggesting that myocardial adaptations contribute to enhanced ventricular contractility. Ventricular myocardium isolated from IPE-treated mice displayed a significant reduction in troponin I (TnI) and myosin-binding protein C (MyBP-C) expression and a concomitant increase in the phosphorylation levels of the remaining TnI and MyBP-C protein compared with myocardium isolated from saline-treated control mice. Skinned myocardium isolated from IPE-treated mice displayed a significant acceleration in the rate of cross-bridge (XB) detachment (46% increase) and an enhanced magnitude of XB recruitment (43% increase) at submaximal Ca2+ activation compared with SAL-treated mice but unaltered myofilament Ca2+ sensitivity of force generation. These findings demonstrate that sarcomeric protein modifications during neurohormonal stress are molecular adaptations that enhance in vivo ventricular contractility through accelerated XB kinetics to increase cardiac output. NEW & NOTEWORTHY Posttranslational modifications to sarcomeric regulatory proteins provide a mechanism to modulate cardiac function in response to stress. In this study, we demonstrate that neurohormonal stress produces modifications to myosin-binding protein C and troponin I, including a reduction in protein expression within the sarcomere and increased phosphorylation of the remaining protein, which serve to enhance cross-bridge kinetics and increase cardiac output. These findings highlight the importance of sarcomeric regulatory protein modifications in modulating ventricular function during cardiac stress.

Published

2016

34. Cardiac Myosin Binding Protein C Insufficiency Leads to Early Onset of Mechanical Dysfunction

Author

Brian D. Hoit, Arthur T. Coulton, Candida L. Desjardins, Xin Yu, Yong Chen, and Julian E. Stelzer

Subjects

Male, medicine.medical_specialty, Heart Ventricles, Diastole, Cardiomyopathy, Article, Ventricular Function, Left, Muscle hypertrophy, Mice, In vivo, Internal medicine, medicine, Animals, Radiology, Nuclear Medicine and imaging, medicine.diagnostic_test, business.industry, Binding protein, Hypertrophic cardiomyopathy, Magnetic resonance imaging, Cardiomyopathy, Hypertrophic, medicine.disease, Magnetic Resonance Imaging, Myocardial Contraction, In vitro, Disease Models, Animal, Cardiology, Carrier Proteins, Cardiology and Cardiovascular Medicine, business

Abstract

Background— Decreased expression of cardiac myosin binding protein C (cMyBPC) as a result of genetic mutations may contribute to the development of hypertrophic cardiomyopathy (HCM); however, the mechanisms that link cMyBPC expression and HCM development, especially contractile dysfunction, remain unclear. Methods and Results— We evaluated cardiac mechanical function in vitro and in vivo in young mice (8–10 weeks of age) carrying no functional cMyBPC alleles (cMyBPC −/− ) or 1 functional cMyBPC allele (cMyBPC ± ). Skinned myocardium isolated from cMyBPC −/− hearts displayed significant accelerations in stretch activation cross-bridge kinetics. Cardiac MRI studies revealed severely depressed in vivo left ventricular (LV) magnitude and rates of LV wall strain and torsion compared with wild-type (WT) mice. Heterozygous cMyBPC ± hearts expressed 23±5% less cMyBPC than WT hearts but did not display overt hypertrophy. Skinned myocardium isolated from cMyBPC ± hearts displayed small accelerations in the rate of stretch induced cross-bridge recruitment. MRI measurements revealed reductions in LV torsion and circumferential strain, as well reduced circumferential strain rates in early systole and diastole. Conclusions— Modest decreases in cMyBPC expression in the mouse heart result in early-onset subtle changes in cross-bridge kinetics and in vivo LV mechanical function, which could contribute to the development of HCM later in life.

Published

2012

35. Altered in vivo left ventricular torsion and principal strains in hypothyroid rats

Author

Aleefia Somji, Yong Chen, Xin Yu, and Julian E. Stelzer

Subjects

Male, Cardiotonic Agents, Physiology, Heart Ventricles, Torsion, Mechanical, Diastole, Biology, Rats, Sprague-Dawley, Contractility, Hypothyroidism, In vivo, Dobutamine, Physiology (medical), medicine, Animals, Protein Isoforms, Systole, Myosin Heavy Chains, Heart, Articles, Anatomy, Myocardial Contraction, Rats, medicine.anatomical_structure, Ventricle, Models, Animal, Circulatory system, medicine.symptom, Cardiology and Cardiovascular Medicine, Muscle contraction, medicine.drug

Abstract

The twisting and untwisting motions of the left ventricle (LV) lead to efficient ejection of blood during systole and filling of the ventricle during diastole. Global LV mechanical performance is dependent on the contractile properties of cardiac myocytes; however, it is not known how changes in contractile protein expression affect the pattern and timing of LV rotation. At the myofilament level, contractile performance is largely dependent on the isoforms of myosin heavy chain (MHC) that are expressed. Therefore, in this study, we used MRI to examine the in vivo mechanical consequences of altered MHC isoform expression by comparing the contractile properties of hypothyroid rats, which expressed only the slow β-MHC isoform, and euthyroid rats, which predominantly expressed the fast α-MHC isoform. Unloaded shortening velocity ( Vo) and apparent rate constants of force development ( ktr) were measured in the skinned ventricular myocardium isolated from euthyroid and hypothyroid hearts. Increased expression of β-MHC reduced LV torsion and fiber strain and delayed the development of peak torsion and strain during systole. Depressed in vivo mechanical performance in hypothyroid rats was related to slowed cross-bridge performance, as indicated by significantly slower Vo and ktr, compared with euthyroid rats. Dobutamine infusion in hypothyroid hearts produced smaller increases in torsion and strain and aberrant transmural torsion patterns, suggesting that the myocardial response to β-adrenergic stress is compromised. Thus, increased expression of β-MHC alters the pattern and decreases the magnitude of LV rotation, contributing to reduced mechanical performance during systole, especially in conditions of increased workload.

Published

2010

36. Correction to: The Sydney Heart Bank: improving translational research while eliminating or reducing the use of animal models of human heart disease

Author

Roger Cooke, S. E. M. van Dijk, Connie R. Bezzina, Henk Granzier, Wolfgang A. Linke, Steve Marston, J. van der Velden, F. De Man, James W. McNamara, Anne Keogh, Sean Lal, Peter S. Macdonald, Amy Li, Fredrik Pontén, Jacob Odeberg, Ger J.M. Stienen, Elisabeth Ehler, C.G. dos Remedios, Julian E. Stelzer, and R. Knöll

Subjects

Computer science, business.industry, Section (typography), Biophysics, Correction, Human heart, Translational research, Review, Disease, computer.software_genre, Structural Biology, Correct name, Artificial intelligence, business, Molecular Biology, computer, Natural language processing

Abstract

The Sydney Heart Bank (SHB) is one of the largest human heart tissue banks in existence. Its mission is to provide high-quality human heart tissue for research into the molecular basis of human heart failure by working collaboratively with experts in this field. We argue that, by comparing tissues from failing human hearts with age-matched non-failing healthy donor hearts, the results will be more relevant than research using animal models, particularly if their physiology is very different from humans. Tissue from heart surgery must generally be used soon after collection or it significantly deteriorates. Freezing is an option but it raises concerns that freezing causes substantial damage at the cellular and molecular level. The SHB contains failing samples from heart transplant patients and others who provided informed consent for the use of their tissue for research. All samples are cryopreserved in liquid nitrogen within 40 min of their removal from the patient, and in less than 5–10 min in the case of coronary arteries and left ventricle samples. To date, the SHB has collected tissue from about 450 failing hearts (>15,000 samples) from patients with a wide range of etiologies as well as increasing numbers of cardiomyectomy samples from patients with hypertrophic cardiomyopathy. The Bank also has hearts from over 120 healthy organ donors whose hearts, for a variety of reasons (mainly tissue-type incompatibility with waiting heart transplant recipients), could not be used for transplantation. Donor hearts were collected by the St Vincent’s Hospital Heart and Lung transplantation team from local hospitals or within a 4-h jet flight from Sydney. They were flushed with chilled cardioplegic solution and transported to Sydney where they were quickly cryopreserved in small samples. Failing and/or donor samples have been used by more than 60 research teams around the world, and have resulted in more than 100 research papers. The tissues most commonly requested are from donor left ventricles, but right ventricles, atria, interventricular system, and coronary arteries vessels have also been reported. All tissues are stored for long-term use in liquid N or vapor (170–180 °C), and are shipped under nitrogen vapor to avoid degradation of sensitive molecules such as RNAs and giant proteins. We present evidence that the availability of these human heart samples has contributed to a reduction in the use of animal models of human heart failure.

Published

2018

37. Determination of rate constants for turnover of myosin isoforms in rat myocardium: implications for in vivo contractile kinetics

Author

Julian E. Stelzer, Matthew R. Locher, Maria V. Razumova, Jitandrakumar R. Patel, Holly S. Norman, and Richard L. Moss

Subjects

Gene isoform, Physiology, chemical and pharmacologic phenomena, Myosins, Biology, Rats, Sprague-Dawley, chemistry.chemical_compound, Adenosine Triphosphate, Isomerism, Myofibrils, In vivo, Isometric Contraction, Physiology (medical), Myosin, Animals, Myocyte, Myocytes, Cardiac, Calcium Signaling, Pyruvates, Calcium signaling, Adenosine Triphosphatases, Models, Statistical, Myosin Heavy Chains, Myocardium, Articles, Myocardial Contraction, Rats, Cell biology, Adenosine Diphosphate, Kinetics, Adenosine diphosphate, chemistry, Biochemistry, Thyroidectomy, Female, Cardiology and Cardiovascular Medicine, Myofibril, Adenosine triphosphate

Abstract

The ventricles of small mammals express mostly α-myosin heavy chain (α-MHC), a fast isoform, whereas the ventricles of large mammals, including humans, express ∼10% α-MHC on a predominately β-MHC (slow isoform) background. In failing human ventricles, the amount of α-MHC is dramatically reduced, leading to the hypothesis that even small amounts of α-MHC on a predominately β-MHC background confer significantly higher rates of force development in healthy ventricles. To test this hypothesis, it is necessary to determine the fundamental rate constants of cross-bridge attachment ( fapp) and detachment ( gapp) for myosins composed of 100% α-MHC or β-MHC, which can then be used to calculate twitch time courses for muscles expressing variable ratios of MHC isoforms. In the present study, rat skinned trabeculae expressing either 100% α-MHC or 100% β-MHC were used to measure ATPase activity, isometric force, and the rate constant of force redevelopment ( ktr) in solutions of varying Ca2+concentrations. The rate of ATP utilization was ∼2.5-fold higher in preparations expressing 100% α-MHC compared with those expressing only β-MHC, whereas ktrwas 2-fold faster in the α-MHC myocardium. From these variables, we calculated fappto be approximately threefold higher for α-MHC than β-MHC and gappto be twofold higher in α-MHC. Mathematical modeling of isometric twitches predicted that small increases in α-MHC significantly increased the rate of force development. These results suggest that low-level expression of α-MHC has significant effects on contraction kinetics.

Published

2009

38. Transmural variation in myosin heavy chain isoform expression modulates the timing of myocardial force generation in porcine left ventricle

Author

Holly S. Norman, Jitandrakumar R. Patel, Julian E. Stelzer, Richard L. Moss, and Peter P. Chen

Subjects

Gene isoform, Myofilament, medicine.medical_specialty, Cardiac cycle, Physiology, Chemistry, Variable Expression, medicine.anatomical_structure, Ventricle, Internal medicine, Myosin, medicine, Biophysics, Cardiology, Phosphorylation, Systole

Abstract

Recent studies have shown that the sequence and timing of mechanical activation of myocardium vary across the ventricular wall. However, the contributions of variable expression of myofilament protein isoforms in mediating the timing of myocardial activation in ventricular systole are not well understood. To assess the functional consequences of transmural differences in myofilament protein expression, we studied the dynamic mechanical properties of multicellular skinned preparations isolated from the sub-endocardial and sub-epicardial regions of the porcine ventricular midwall. Compared to endocardial fibres, epicardial fibres exhibited significantly faster rates of stretch activation and force redevelopment (ktr), although the amount of force produced at a given [Ca2+] was not significantly different. Consistent with these results, SDS-PAGE analysis revealed significantly elevated expression of α myosin heavy chain (MHC) isoform in epicardial fibres (13 ± 1%) versus endocardial fibres (3 ± 1%). Linear regression analysis revealed that the apparent rates of delayed force development and force decay following stretch correlated with MHC isoform expression (r2= 0.80 and r2= 0.73, respectively, P < 0.05). No differences in the relative abundance or phosphorylation status of other myofilament proteins were detected. These data show that transmural differences in MHC isoform expression contribute to regional differences in dynamic mechanical function of porcine left ventricles, which in turn modulate the timing of force generation across the ventricular wall and work production during systole.

Published

2008

39. Role of myosin heavy chain composition in the stretch activation response of rat myocardium

Author

Stacey Brickson, Matthew R. Locher, Julian E. Stelzer, and Richard L. Moss

Subjects

Gene isoform, Contraction (grammar), Physiology, Chemistry, Cardiac muscle, Anatomy, medicine.disease, Cell biology, medicine.anatomical_structure, Heart failure, Myosin, medicine, Myocyte, MYH7, MYH6

Abstract

The speed and force of myocardial contraction during systolic ejection is largely dependent on the intrinsic contractile properties of cardiac myocytes. As the myosin heavy chain (MHC) isoform of cardiac muscle is an important determinant of the contractile properties of individual myocytes, we studied the effects of altered MHC isoform expression in rat myocardium on the mechanical properties of skinned ventricular preparations. Skinned myocardium from thyroidectomized rats expressing only the β MHC isoform displayed rates of force redevelopment that were about 2.5-fold slower than in myocardium from hyperthyroid rats expressing only the α MHC isoform, but the amount of force generated at a given level of Ca2+ activation was not different. Because recent studies suggest that the stretch activation response in myocardium has an important role in systolic function, we also examined the effect of MHC isoform expression on the stretch activation response by applying a rapid stretch (1% of muscle length) to an otherwise isometrically contracting muscle fibre. Sudden stretch of myocardium resulted in a concomitant increase in force that quickly decayed to a minimum and was followed by a delayed redevelopment of force (i.e. stretch activation) to levels greater than prestretch force. β MHC expression dramatically slowed the overall rate of the stretch activation response compared to expression of α MHC isoform; specifically, the rate of force decay was ∼2-fold slower and the rate of delayed force development was ∼2.5-fold slower. In contrast, MHC isoform had no effect on the amplitude of the stretch activation response. Collectively, these data show that expression of β MHC in myocardium dramatically slows rates of cross-bridge recruitment and detachment which would be expected to decrease power output and contribute to depressed systolic function in end-stage heart failure.

Published

2007

40. Cardiac Myosin Binding Protein-C Phosphorylation Modulates Myofilament Length-Dependent Activation

Author

Julian E. Stelzer, Ranganath Mamidi, Kenneth S. Gresham, and Sujeet Verma

Subjects

0301 basic medicine, Force generation, medicine.medical_specialty, Myofilament, stretch activation, Physiology, Kinetics, cross-bridge kinetics, Sarcomere, lcsh:Physiology, 03 medical and health sciences, stretch-activation, Internal medicine, Physiology (medical), medicine, skinned myocardium, Protein kinase A, Original Research, cardiac myosin binding protein-C, lcsh:QP1-981, Chemistry, phosphorylation, Binding protein, Cardiac myosin, 030104 developmental biology, Endocrinology, Biophysics, Phosphorylation, phoshphorylation, protein kinase A

Abstract

Cardiac myosin binding protein-C (cMyBP-C) phosphorylation is an important regulator of contractile function, however, its contributions to length-dependent changes in cross-bridge (XB) kinetics is unknown. Therefore, we performed mechanical experiments to quantify contractile function in detergent-skinned ventricular preparations isolated from wild-type (WT) hearts, and hearts expressing non-phosphorylatable cMyBP-C [Ser to Ala substitutions at residues Ser273, Ser282, and Ser302 (i.e., 3SA)], at sarcomere length (SL) 1.9 μm or 2.1μm, prior and following protein kinase A (PKA) treatment. Steady-state force generation measurements revealed a blunting in the length-dependent increase in myofilament Ca(2+)-sensitivity of force generation (pCa50) following an increase in SL in 3SA skinned myocardium compared to WT skinned myocardium. Dynamic XB behavior was assessed at submaximal Ca(2+)-activations by imposing an acute rapid stretch of 2% of initial muscle length, and measuring both the magnitudes and rates of resultant phases of force decay due to strain-induced XB detachment and delayed force rise due to recruitment of additional XBs with increased SL (i.e., stretch activation). The magnitude (P2) and rate of XB detachment (k rel) following stretch was significantly reduced in 3SA skinned myocardium compared to WT skinned myocardium at short and long SL, and prior to and following PKA treatment. Furthermore, the length-dependent acceleration of k rel due to decreased SL that was observed in WT skinned myocardium was abolished in 3SA skinned myocardium. PKA treatment accelerated the rate of XB recruitment (k df) following stretch at both SL's in WT but not in 3SA skinned myocardium. The amplitude of the enhancement in force generation above initial pre-stretch steady-state levels (P3) was not different between WT and 3SA skinned myocardium at any condition measured. However, the magnitude of the entire delayed force phase which can dip below initial pre-stretch steady-state levels (Pdf) was significantly lower in 3SA skinned myocardium under all conditions, in part due to a reduced magnitude of XB detachment (P2) in 3SA skinned myocardium compared to WT skinned myocardium. These findings demonstrate that cMyBP-C phospho-ablation regulates SL- and PKA-mediated effects on XB kinetics in the myocardium, which would be expected to contribute to the regulation of the Frank-Starling mechanism.

Published

2015

41. The contributions of cardiac myosin binding protein C and troponin I phosphorylation to β-adrenergic enhancement of in vivo cardiac function

Author

Kenneth S, Gresham and Julian E, Stelzer

Subjects

Male, Journal Club, Myocardium, Troponin I, Blood Pressure, Cardiomegaly, Heart, Mice, Transgenic, Cyclic AMP-Dependent Protein Kinases, Myofibrils, Adrenergic beta-1 Receptor Agonists, Dobutamine, Receptors, Adrenergic, beta, Animals, Female, Phosphorylation, Carrier Proteins

Abstract

β-adrenergic stimulation increases cardiac myosin binding protein C (MyBP-C) and troponin I phosphorylation to accelerate pressure development and relaxation in vivo, although their relative contributions remain unknown. Using a novel mouse model lacking protein kinase A-phosphorylatable troponin I (TnI) and MyBP-C, we examined in vivo haemodynamic function before and after infusion of the β-agonist dobutamine. Mice expressing phospho-ablated MyBP-C displayed cardiac hypertrophy and prevented full acceleration of pressure development and relaxation in response to dobutamine, whereas expression of phosphor-ablated TnI alone had little effect on the acceleration of contractile function in response to dobutamine. Our data demonstrate that MyBP-C phosphorylation is the principal mediator of the contractile response to increased β-agonist stimulation in vivo. These results help us understand why MyBP-C dephosphorylation in the failing heart contributes to contractile dysfunction and decreased adrenergic reserve in response to acute stress. β-adrenergic stimulation plays a critical role in accelerating ventricular contraction and speeding relaxation to match cardiac output to changing circulatory demands. Two key myofilaments proteins, troponin I (TnI) and myosin binding protein-C (MyBP-C), are phosphorylated following β-adrenergic stimulation; however, their relative contributions to the enhancement of in vivo cardiac contractility are unknown. To examine the roles of TnI and MyBP-C phosphorylation in β-adrenergic-mediated enhancement of cardiac function, transgenic (TG) mice expressing non-phosphorylatable TnI protein kinase A (PKA) residues (i.e. serine to alanine substitution at Ser23/24; TnI(PKA-)) were bred with mice expressing non-phosphorylatable MyBP-C PKA residues (i.e. serine to alanine substitution at Ser273, Ser282 and Ser302; MyBPC(PKA-)) to generate a novel mouse model expressing non-phosphorylatable PKA residues in TnI and MyBP-C (DBL(PKA-)). MyBP-C dephosphorylation produced cardiac hypertrophy and increased wall thickness in MyBPC(PKA-) and DBL(PKA-) mice, and in vivo echocardiography and pressure-volume catheterization studies revealed impaired systolic function and prolonged diastolic relaxation compared to wild-type and TnI(PKA-) mice. Infusion of the β-agonist dobutamine resulted in accelerated rates of pressure development and relaxation in all mice; however, MyBPC(PKA-) and DBL(PKA-) mice displayed a blunted contractile response compared to wild-type and TnI(PKA-) mice. Furthermore, unanaesthesized MyBPC(PKA-) and DBL(PKA-) mice displayed depressed maximum systolic pressure in response to dobutamine as measured using implantable telemetry devices. Taken together, our data show that MyBP-C phosphorylation is a critical modulator of the in vivo acceleration of pressure development and relaxation as a result of enhanced β-adrenergic stimulation, and reduced MyBP-C phosphorylation may underlie depressed adrenergic reserve in heart failure.

Published

2015

42. The Contribution of Myosin Binding Protein-C and Troponin I Phosphorylation to the β-Adrenergic Acceleration of Left Ventricular Contraction and Relaxation

Author

Julian E. Stelzer and Kenneth S. Gresham

Subjects

medicine.medical_specialty, Cardiac output, Lusitropy, Cardiac cycle, Chemistry, Diastole, Biophysics, Endocrinology, Internal medicine, Myosin binding, Troponin I, medicine, cardiovascular system, Dobutamine, Systole, medicine.drug

Abstract

Activation of the β-adrenergic signaling pathway in the heart leads to an increased rate of pressure development in early systole and an acceleration of relaxation in diastole to increase cardiac output. These effects are mediated by protein kinase A (PKA), which primarily targets myosin binding protein-c (MyBP-C) and troponin I (TnI) in the sarcomere for phosphorylation. However, the relative contributions of MyBP-C and TnI phosphorylation to the β-adrenergic-mediated increases in ionotropy and lusitropy remains unclear. To investigate, we used mice expressing non-phosphorylatable TnI (TnIAla2), non-phosphorylatable MyBP-C (MyBP-C3SA), and mice expressing non-phosphorylatable TnI and MyBP-C (TnI Ala2/MyBP-C3SA), as well as control WT mice. Pressure-volume loop analysis was performed to measure early systolic pressure development and ventricular relaxation at baseline and in response to dobutamine (a β-agonist) administration. At baseline there was no difference in systolic pressure development between the groups, but the acceleration of dp/dtmax after dobutamine administration was blunted in MyBP-C3SA and TnI Ala2/MyBP-C3SA mice (mmHg/s; 14,414±1,016 in WT, 12,921±982 in TnIAla2, 7,830±899 in MyBP-C3SA, and 8,803±1,001 in TnI Ala2/MyBP-C3SA after dobutamine; p

Published

2015

43. Protein Kinase A–Mediated Acceleration of the Stretch Activation Response in Murine Skinned Myocardium Is Eliminated by Ablation of cMyBP-C

Author

Richard L. Moss, Jitandrakumar R. Patel, and Julian E. Stelzer

Subjects

Inotrope, medicine.medical_specialty, Myofilament, Time Factors, Physiology, Stimulation, Isometric exercise, In Vitro Techniques, Contractility, Mice, Internal medicine, Troponin I, medicine, Animals, Protein kinase A, Mice, Knockout, Chemistry, Myocardium, Histological Techniques, Heart, Cyclic AMP-Dependent Protein Kinases, Myocardial Contraction, Kinetics, Endocrinology, cardiovascular system, Biophysics, Phosphorylation, Stress, Mechanical, Carrier Proteins, Cardiology and Cardiovascular Medicine

Abstract

β-Adrenergic agonists induce protein kinase A (PKA) phosphorylation of the cardiac myofilament proteins myosin binding protein C (cMyBP-C) and troponin I (cTnI), resulting in enhanced systolic function, but the relative contributions of cMyBP-C and cTnI to augmented contractility are not known. To investigate possible roles of cMyBP-C in this response, we examined the effects of PKA treatment on the rate of force redevelopment and the stretch activation response in skinned ventricular myocardium from both wild-type (WT) and cMyBP-C null (cMyBP-C −/− ) myocardium. In WT myocardium, PKA treatment accelerated the rate of force redevelopment and the stretch activation response, resulting in a shorter time to the peak of delayed force development when the muscle was stretched to a new isometric length. Ablation of cMyBP-C accelerated the rate of force redevelopment and stretch activation response to a degree similar to that observed in PKA treatment of WT myocardium; however, PKA treatment had no effect on the rate of force development and the stretch activation response in null myocardium. These results indicate that ablation of cMyBP-C and PKA treatment of WT myocardium have similar effects on cross-bridge cycling kinetics and suggest that PKA phosphorylation of cMyBP-C accelerates the rate of force generation and thereby contributes to the accelerated twitch kinetics observed in living myocardium during β-adrenergic stimulation.

Published

2006

44. Ablation of Myosin-Binding Protein-C Accelerates Force Development in Mouse Myocardium

Author

Richard L. Moss, Julian E. Stelzer, and Daniel P. Fitzsimons

Subjects

Kinetics, Biophysics, chemistry.chemical_element, Isometric exercise, Plasma protein binding, In Vitro Techniques, Myosins, Calcium, Mice, Myosin-binding protein C, Myosin, Animals, Muscle and Contractility, Actin, Mice, Knockout, Chemistry, Myocardium, Cardiac Muscle Contraction, Myosin Subfragments, Myocardial Contraction, Actins, Biomechanical Phenomena, Biochemistry, Carrier Proteins, Protein Binding

Abstract

Myosin-binding protein-C (MyBP-C) is a thick filament-associated protein that binds tightly to myosin. Given that cMyBP-C may act to modulate cooperative activation of the thin filament by constraining the availability of myosin cross-bridges for binding to actin, we investigated the role of MyBP-C in the regulation of cardiac muscle contraction. We assessed the Ca(2+) sensitivity of force (pCa(50)) and the activation dependence of the rate of force redevelopment (k(tr)) in skinned myocardium isolated from wild-type (WT) and cMyBP-C null (cMyBP-C(-/-)) mice. Mechanical measurements were performed at 22 degrees C in the absence and presence of a strong-binding, nonforce-generating analog of myosin subfragment-1 (NEM-S1). In the absence of NEM-S1, maximal force and k(tr) and the pCa(50) of isometric force did not differ between WT and cMyBP-C(-/-) myocardium; however, ablation of cMyBP-C-accelerated k(tr) at each submaximal force. Treatment of WT and cMyBP-C(-/-) myocardium with 3 muM NEM-S1 elicited similar increases in pCa(50,) but the effects of NEM-S1 to increase k(tr) at submaximal forces and thereby markedly reduce the activation dependence of k(tr) occurred to a greater degree in cMyBP-C(-/-) myocardium. Together, these results support the idea that cMyBP-C normally acts to constrain the interaction between myosin and actin, which in turn limits steady-state force development and the kinetics of cross-bridge interaction.

Published

2006

45. Acceleration of Stretch Activation in Murine Myocardium due to Phosphorylation of Myosin Regulatory Light Chain

Author

Julian E. Stelzer, Jitandrakumar R. Patel, and Richard L. Moss

Subjects

Male, Myosin light-chain kinase, Myosin Light Chains, Time Factors, Physiology, chemistry.chemical_element, Mice, Transgenic, Isometric exercise, macromolecular substances, 030204 cardiovascular system & hematology, Calcium, Article, 03 medical and health sciences, Mice, 0302 clinical medicine, Myosin, medicine, Animals, Phosphorylation, P-Chloroamphetamine, Myosin-Light-Chain Kinase, 030304 developmental biology, 0303 health sciences, Myocardium, Cardiac muscle, Skeletal muscle, Articles, Myocardial Contraction, Kinetics, medicine.anatomical_structure, Biochemistry, chemistry, Biophysics, Female, Stress, Mechanical

Abstract

The regulatory light chains (RLCs) of vertebrate muscle myosins bind to the neck region of the heavy chain domain and are thought to play important structural roles in force transmission between the cross-bridge head and thick filament backbone. In vertebrate striated muscles, the RLCs are reversibly phosphorylated by a specific myosin light chain kinase (MLCK), and while phosphorylation has been shown to accelerate the kinetics of force development in skeletal muscle, the effects of RLC phosphorylation in cardiac muscle are not well understood. Here, we assessed the effects of RLC phosphorylation on force, and the kinetics of force development in myocardium was isolated in the presence of 2,3-butanedione monoxime (BDM) to dephosphorylate RLC, subsequently skinned, and then treated with MLCK to phosphorylate RLC. Since RLC phosphorylation may be an important determinant of stretch activation in myocardium, we recorded the force responses of skinned myocardium to sudden stretches of 1% of muscle length both before and after treatment with MLCK. MLCK increased RLC phosphorylation, increased the Ca2+ sensitivity of isometric force, reduced the steepness of the force–pCa relationship, and increased both Ca2+-activated and Ca2+-independent force. Sudden stretch of myocardium during an otherwise isometric contraction resulted in a concomitant increase in force that quickly decayed to a minimum and was followed by a delayed redevelopment of force, i.e., stretch activation, to levels greater than pre-stretch force. MLCK had profound effects on the stretch activation responses during maximal and submaximal activations: the amplitude and rate of force decay after stretch were significantly reduced, and the rate of delayed force recovery was accelerated and its amplitude reduced. These data show that RLC phosphorylation increases force and the rate of cross-bridge recruitment in murine myocardium, which would increase power generation in vivo and thereby enhance systolic function.

Published

2006

46. Contributions of Stretch Activation to Length-dependent Contraction in Murine Myocardium

Author

Richard L. Moss and Julian E. Stelzer

Subjects

Force generation, Contraction (grammar), Physiology, Heart Ventricles, chemistry.chemical_element, Mice, Inbred Strains, Isometric exercise, 030204 cardiovascular system & hematology, Calcium, In Vitro Techniques, Length dependence, Sarcomere, Article, 03 medical and health sciences, Mice, 0302 clinical medicine, Animals, Ventricular Function, 030304 developmental biology, Initial rate, 0303 health sciences, Chemistry, Anatomy, Articles, Myocardial Contraction, Biomechanical Phenomena, Kinetics, Biophysics, End-diastolic volume, Stress, Mechanical

Abstract

The steep relationship between systolic force production and end diastolic volume (Frank-Starling relationship) in myocardium is a potentially important mechanism by which the work capacity of the heart varies on a beat-to-beat basis, but the molecular basis for the effects of myocardial fiber length on cardiac work are still not well understood. Recent studies have suggested that an intrinsic property of myocardium, stretch activation, contributes to force generation during systolic ejection in myocardium. To examine the role of stretch activation in length dependence of activation we recorded the force responses of murine skinned myocardium to sudden stretches of 1% of muscle length at both short (1.90 μm) and long (2.25 μm) sarcomere lengths (SL). Maximal Ca2+-activated force and Ca2+ sensitivity of force were greater at longer SL, such that more force was produced at a given Ca2+ concentration. Sudden stretch of myocardium during an otherwise isometric contraction resulted in a concomitant increase in force that quickly decayed to a minimum and was followed by a delayed development of force, i.e., stretch activation, to levels greater than prestretch force. At both maximal and submaximal activations, increased SL significantly reduced the initial rate of force decay following stretch; at submaximal activations (but not at maximal) the rate of delayed force development was accelerated. This combination of mechanical effects of increased SL would be expected to increase force generation during systolic ejection in vivo and prolong the period of ejection. These results suggest that sarcomere length dependence of stretch activation contributes to the steepness of the Frank-Starling relationship in living myocardium.

Published

2006

47. Expression of cardiac troponin T with COOH-terminal truncation accelerates cross-bridge interaction kinetics in mouse myocardium

Author

Daniel P. Fitzsimons, Julian E. Stelzer, M. Charlotte Olsson, Richard L. Moss, Leslie A. Leinwand, and Jitandrakumar R. Patel

Subjects

Genetically modified mouse, medicine.medical_specialty, Physiology, Transgene, Diastole, Mice, Transgenic, In Vitro Techniques, Mice, Troponin T, Troponin complex, Physiology (medical), Internal medicine, Myosin, medicine, Animals, Actin, biology, Chemistry, Myocardium, Myosin Subfragments, Myocardial Contraction, Troponin, Protein Structure, Tertiary, Actin Cytoskeleton, Kinetics, Cross-Linking Reagents, Endocrinology, Mutagenesis, Circulatory system, biology.protein, Calcium, Cardiology and Cardiovascular Medicine

Abstract

Transgenic mice expressing an allele of cardiac troponin T (cTnT) with a COOH-terminal truncation (cTnTtrunc) exhibit severe diastolic and mild systolic dysfunction. We tested the hypothesis that contractile dysfunction in myocardium expressing low levels of cTnTtrunc (i.e., 2+ sensitivity of force development [pCa for half-maximal tension generation (pCa50)] and the rate constant of force redevelopment ( ktr) in cTnTtrunc and wild-type (WT) skinned myocardium both in the absence and in the presence of a strong-binding, non-force-generating derivative of myosin subfragment-1 (NEM-S1). Compared with WT mice, cTnTtrunc mice exhibited greater pCa50, reduced steepness of the force-pCa relationship [Hill coefficient ( nH)], and faster ktr at submaximal Ca2+ concentration ([Ca2+]), i.e., reduced activation dependence of ktr. Treatment with NEM-S1 elicited similar increases in pCa50 and similar reductions in nH in WT and cTnTtrunc myocardium but elicited greater increases in ktr at submaximal activation in cTnTtrunc myocardium. Contrary to our initial hypothesis, cTnTtrunc appears to enhance thin filament activation in myocardium, which is manifested as significant increases in Ca2+-activated force and the rate of cross-bridge attachment at submaximal [Ca2+]. Although these mechanisms would not be expected to depress systolic function per se in cTnTtrunc hearts, they would account for slowed rates of myocardial relaxation during early diastole.

Published

2004

48. cMyBP-C Phosphorylation Modulates Sarcomere Length-Dependent Changes in Cardiac Muscle Contractile Function

Author

Ranganath Mamidi, Julian E. Stelzer, and Kenneth S. Gresham

Subjects

medicine.medical_specialty, Myofilament, Cardiac muscle, Biophysics, Cardiac myosin, Isometric exercise, Biology, Sarcomere, Endocrinology, medicine.anatomical_structure, Biochemistry, Internal medicine, medicine, Phosphorylation, Protein kinase A, Function (biology)

Abstract

It is well-established that cardiac myosin binding protein-C (cMyBP-C) phosphorylation enhances acto-myosin interactions and also impacts cross-bridge (XB) cycling rates, mechanisms which are known to affect sarcomere length (SL)-dependent contractile function. However, the precise role of cMyBP-C phosphorylation in modulating SL-dependent changes is unknown. Therefore, we measured isometric force, myofilament Ca2+-sensitivity (pCa50), SL-dependent changes in the rates of XB detachment (krel), recruitment (kdf), and the amplitude of the delayed force development (Pdf) in detergent-skinned ventricular preparations isolated from hearts of wild-type (WT) mice and from mice expressing non-phosphorylatable cMyBP-C (Ser to Ala substitutions at residues Ser273, Ser282, and Ser302 (i.e., 3SA)), at SL 1.9µm or 2.1µm both at baseline and following protein kinase A (PKA) treatment. No significant differences in maximal force and pCa50 were noted between WT and 3SA at either SL, at baseline and following PKA treatment. Importantly, however, krel was significantly slower in the 3SA compared to WT at both long (∼40%) and short (∼53%) SL at baseline, and slowed krel in 3SA myocardium was even more pronounced following PKA treatment (krel was ∼135% and ∼67% slower in compared to WT at long and short SL, respectively). No differences in kdf were observed between the WT and 3SA at either SL at baseline, however, PKA treatment accelerated kdf by ∼26% and ∼38% at long and short SL in WT myocardium but not in 3SA myocardium. Moreover, at baseline, Pdf amplitude was significantly lower in 3SA myocardium compared to WT myocardium at either SL, and PKA treatment enhanced Pdf amplitude at both SL in WT but not in 3SA, demonstrating that cMyBP-C phosphorylation modulates the magnitude and rate of XB recruitment. Collectively, our data indicate that cMyBP-C phosphorylation is a key regulator of SL-dependent contractile function.

Published

2016

49. Effect of hindlimb suspension on the functional properties of slow and fast soleus fibers from three strains of mice

Author

Jeffrey J. Widrick and Julian E. Stelzer

Subjects

Physiology, chemistry.chemical_element, Hindlimb, Calcium, Mice, Species Specificity, Physiology (medical), Myosin, Transducers, Pressure, medicine, Animals, Fiber, Muscle, Skeletal, Suspension (vehicle), Mice, Inbred ICR, Specific force, Myosin Heavy Chains, Chemistry, Body Weight, Anatomy, Hindlimb Suspension, Adaptation, Physiological, Muscle atrophy, Biomechanical Phenomena, Mice, Inbred C57BL, Muscle Fibers, Slow-Twitch, Muscle Fibers, Fast-Twitch, Mice, Inbred CBA, Biophysics, Electrophoresis, Polyacrylamide Gel, medicine.symptom

Abstract

Cross-sectional area (CSA), peak Ca2+-activated force (Po), fiber specific force (Po/CSA), and unloaded shortening velocity ( Vo) were measured in slow-twitch [containing type I myosin heavy chain (MHC)] and fast-twitch (containing type II MHC) chemically skinned soleus muscle fiber segments obtained from three strains of weight-bearing and 7-day hindlimb-suspended (HS) mice. HS reduced soleus slow MHC content (from ∼50 to ∼33%) in CBA/J and ICR strains without affecting slow MHC content in C57BL/6 mice (∼20% of total MHC). Two-way ANOVA revealed HS-induced reductions in CSA, Po, and Po/CSA of slow and fast fibers from all strains. Fiber Vo was elevated post-HS, but not consistently across strains. No MHC × HS treatment interactions were observed for any variable for C57BL/6 and CBA/J mice, and the two significant interactions found for the ICR strain (CSA, Po) appeared related to inherent pre-HS differences in slow vs. fast fiber CSA. In the mouse HS models studied here, fiber atrophy and contractile dysfunction were partially dependent on animal strain and generally independent of fiber MHC isoform content.

Published

2003

50. Functional properties of human muscle fibers after short-term resistance exercise training

Author

Todd C. Shoepe, Dena P. Garner, Jeffrey J. Widrick, and Julian E. Stelzer

Subjects

Adult, Male, Protein isoform, medicine.medical_specialty, Physiology, Strength training, Biopsy, Physical exercise, In Vitro Techniques, Myosins, Muscle hypertrophy, Contractility, Physiology (medical), Internal medicine, Myosin, medicine, Humans, Protein Isoforms, Exercise physiology, Muscle, Skeletal, Exercise, business.industry, Anatomy, Adaptation, Physiological, Biomechanical Phenomena, Muscle Fibers, Slow-Twitch, Endocrinology, Muscle Fibers, Fast-Twitch, Body Composition, Calcium, Stress, Mechanical, medicine.symptom, business, Muscle Contraction, Muscle contraction

Abstract

The aim of this study was to assess the relationships between human muscle fiber hypertrophy, protein isoform content, and maximal Ca2+-activated contractile function following a short-term period of resistance exercise training. Six male subjects (age 27 ± 2 yr) participated in a 12-wk progressive resistance exercise training program that increased voluntary lower limb extension strength by >60%. Single chemically skinned fibers were prepared from pre- and posttraining vastus lateralis muscle biopsies. Training increased the cross-sectional area (CSA) and peak Ca2+-activated force (Po) of fibers containing type I, IIa, or IIa/IIx myosin heavy chain by 30–40% without affecting fiber-specific force (Po/CSA) or unloaded shortening velocity (Vo). Absolute fiber peak power rose as a result of the increase in Po, whereas power normalized to fiber volume was unchanged. At the level of the cross bridge, the effects of short-term resistance training were quantitative (fiber hypertrophy and proportional increases in fiber Poand absolute power) rather than qualitative (no change in Po/CSA, Vo, or power/fiber volume).

Published

2002