Single cardiac ventricular myosins are autonomous motors.

Myosin transduces ATP free energy into mechanical work in muscle. Cardiac muscle has dynamically wide-ranging power demands on the motor as the muscle changes modes in a heartbeat from relaxation, via auxotonic shortening, to isometric contraction. The cardiac power output modulation mechanism is explored in vitro by assessing single cardiac myosin step-size selection versus load. Transgenic mice express human ventricular essential light chain (ELC) in wild- type (WT), or hypertrophic cardiomyopathy-linked mutant forms, A57G or E143K, in a background of mouse α-cardiac myosin heavy chain. Ensemble motility and single myosin mechanical characteristics are consistent with an A57G that impairs ELC N-terminus actin binding and an E143K that impairs lever-arm stability, while both species down-shift average step-size with increasing load. Cardiac myosin in vivo down-shifts velocity/force ratio with increasing load by changed unitary step-size selections. Here, the loaded in vitro single myosin assay indicates quantitative complementarity with the in vivo mechanism. Both have two embedded regulatory transitions, one inhibiting ADP release and a second novel mechanism inhibiting actin detachment via strain on the actin-bound ELC N-terminus. Competing regulators filter unitary step-size selection to control force-velocity modulation without myosin integration into muscle. Cardiac myosin is muscle in a molecule.

Size and speed of the working stroke of cardiac myosin in situ.

The power in the myocardium sarcomere is generated by two bipolar arrays of the motor protein cardiac myosin II extending from the thick filament and pulling the thin, actin-containing filaments from the opposite sides of the sarcomere. Despite the interest in the definition of myosin-based cardiomyopathies, no study has yet been able to determine the mechanokinetic properties of this motor protein in situ. Sarcomere-level mechanics recorded by a striation follower is used in electrically stimulated intact ventricular trabeculae from the rat heart to determine the isotonic velocity transient following a stepwise reduction in force from the isometric peak force TP to a value T(0.8-0.2 TP). The size and the speed of the early rapid shortening (the isotonic working stroke) increase by reducing T from ∼3 nm per half-sarcomere (hs) and 1,000 s(-1) at high load to ∼8 nm⋅hs(-1) and 6,000 s(-1) at low load. Increases in sarcomere length (1.9-2.2 µm) and external [Ca(2+)]o (1-2.5 mM), which produce an increase of TP, do not affect the dependence on T, normalized for TP, of the size and speed of the working stroke. Thus, length- and Ca(2+)-dependent increase of TP and power in the heart can solely be explained by modulation of the number of myosin motors, an emergent property of their array arrangement. The motor working stroke is similar to that of skeletal muscle myosin, whereas its speed is about three times slower. A new powerful tool for investigations and therapies of myosin-based cardiomyopathies is now within our reach.

ß-Myosin heavy chain variant Val606Met causes very mild hypertrophic cardiomyopathy in mice, but exacerbates HCM phenotypes in mice carrying other HCM mutations.

RATIONALE: Approximately 40% of hypertrophic cardiomyopathy (HCM) is caused by heterozygous missense mutations in ß-cardiac myosin heavy chain (ß-MHC). Associating disease phenotype with mutation is confounded by extensive background genetic and lifestyle/environmental differences between subjects even from the same family. OBJECTIVE: To characterize disease caused by ß-cardiac myosin heavy chain Val606Met substitution (VM) that has been identified in several HCM families with wide variation of clinical outcomes, in mice. METHODS AND RESULTS: Unlike 2 mouse lines bearing the malignant myosin mutations Arg453Cys (RC/+) or Arg719Trp (RW/+), VM/+ mice with an identical inbred genetic background lacked hallmarks of HCM such as left ventricular hypertrophy, disarray of myofibers, and interstitial fibrosis. Even homozygous VM/VM mice were indistinguishable from wild-type animals, whereas RC/RC- and RW/RW-mutant mice died within 9 days after birth. However, hypertrophic effects of the VM mutation were observed both in mice treated with cyclosporine, a known stimulator of the HCM response, and compound VM/RC heterozygous mice, which developed a severe HCM phenotype. In contrast to all heterozygous mutants, both systolic and diastolic function of VM/RC hearts was severely impaired already before the onset of cardiac remodeling. CONCLUSIONS: The VM mutation per se causes mild HCM-related phenotypes; however, in combination with other HCM activators it exacerbates the HCM phenotype. Double-mutant mice are suitable for assessing the severity of benign mutations.

Effect of muscle length on cross-bridge kinetics in intact cardiac trabeculae at body temperature.

Dynamic force generation in cardiac muscle, which determines cardiac pumping activity, depends on both the number of sarcomeric cross-bridges and on their cycling kinetics. The Frank-Starling mechanism dictates that cardiac force development increases with increasing cardiac muscle length (corresponding to increased ventricular volume). It is, however, unclear to what extent this increase in cardiac muscle length affects the rate of cross-bridge cycling. Previous studies using permeabilized cardiac preparations, sub-physiological temperatures, or both have obtained conflicting results. Here, we developed a protocol that allowed us to reliably and reproducibly measure the rate of tension redevelopment (k(tr); which depends on the rate of cross-bridge cycling) in intact trabeculae at body temperature. Using K(+) contractures to induce a tonic level of force, we showed the k(tr) was slower in rabbit muscle (which contains predominantly ß myosin) than in rat muscle (which contains predominantly α myosin). Analyses of k(tr) in rat muscle at optimal length (L(opt)) and 90% of optimal length (L(90)) revealed that k(tr) was significantly slower at L(opt) (27.7 ± 3.3 and 27.8 ± 3.0 s(-1) in duplicate analyses) than at L(90) (45.1 ± 7.6 and 47.5 ± 9.2 s(-1)). We therefore show that k(tr) can be measured in intact rat and rabbit cardiac trabeculae, and that the k(tr) decreases when muscles are stretched to their optimal length under near-physiological conditions, indicating that the Frank-Starling mechanism not only increases force but also affects cross-bridge cycling kinetics.

Thyroid hormone and the cardiovascular system.

Thyroid hormone has profound effects on the heart and cardiovascular system. This article describes the cellular mechanisms by which thyroid hormone acts at the level of the cardiac myocyte and the vascular smooth muscle cell to alter phenotype and physiology. Because it is well established that thyroid hormone, specifically T(3), acts on almost every cell and organ in the body, studies on the regulation of thyroid hormone transport into cardiac and vascular tissue have added clinical significance. The characteristic changes in cardiovascular hemodynamics and metabolism that accompany thyroid disease states can then be best understood at the cellular level.

ß-myosin heavy chain is induced by pressure overload in a minor subpopulation of smaller mouse cardiac myocytes.

RATIONALE: Induction of the fetal hypertrophic marker gene ß-myosin heavy chain (ß-MyHC) is a signature feature of pressure overload hypertrophy in rodents. ß-MyHC is assumed present in all or most enlarged myocytes. OBJECTIVE: To quantify the number and size of myocytes expressing endogenous ß-MyHC by a flow cytometry approach. METHODS AND RESULTS: Myocytes were isolated from the left ventricle of male C57BL/6J mice after transverse aortic constriction (TAC), and the fraction of cells expressing endogenous ß-MyHC was quantified by flow cytometry on 10,000 to 20,000 myocytes with use of a validated ß-MyHC antibody. Side scatter by flow cytometry in the same cells was validated as an index of myocyte size. ß-MyHC-positive myocytes constituted 3 ± 1% of myocytes in control hearts (n=12), increasing to 25 ± 10% at 3 days to 6 weeks after TAC (n=24, P<0.01). ß-MyHC-positive myocytes did not enlarge with TAC and were smaller at all times than myocytes without ß-MyHC (≈70% as large, P<0.001). ß-MyHC-positive myocytes arose by addition of ß-MyHC to α-MyHC and had more total MyHC after TAC than did the hypertrophied myocytes that had α-MyHC only. Myocytes positive for ß-MyHC were found in discrete regions of the left ventricle in 3 patterns: perivascular, in areas with fibrosis, and in apparently normal myocardium. CONCLUSIONS: ß-MyHC protein is induced by pressure overload in a minor subpopulation of smaller cardiac myocytes. The hypertrophied myocytes after TAC have α-MyHC only. These data challenge the current paradigm of the fetal hypertrophic gene program and identify a new subpopulation of smaller working ventricular myocytes with more myosin.

Knockdown of alpha myosin heavy chain disrupts the cytoskeleton and leads to multiple defects during chick cardiogenesis.

Atrial septal defects are a common congenital heart defect in humans. Although mutations in different genes are now frequently being described, little is known about the processes and mechanisms behind the early stages of atrial septal development. By utilizing morpholino-induced knockdown in the chick we have analysed the role of alpha myosin heavy chain during early cardiogenesis in a temporal manner. Upon knockdown of alpha myosin heavy chain, three different phenotypes of the atrial septum were observed: (1) the atrial septum failed to initiate, (2) the septum was initiated but was growth restricted, or (3) incorrect specification occurred resulting in multiple septa forming. In addition, at a lower frequency, decreased alpha myosin heavy chain was found to give rise to an abnormally looped heart or an enlarged heart. Staining of the actin cytoskeleton indicated that many of the myofibrils in the knockdown hearts were not as mature as those observed in the controls, suggesting a mechanism for the defects seen. Therefore, these data suggest a role for alpha myosin heavy chain in modelling of the early heart and the range of defects to the atrial septum suggest roles in its initiation, specification and growth during development.

Modulation of cardiac performance by motor protein gene transfer.

Cardiac muscle performance can be determined by factors intrinsic to each cardiac muscle cell, such as protein isoform expression. One protein whose expression plays a major role in determining cardiac performance is myosin. Myosin is the heart's molecular motor which transduces the chemical energy from ATP hydrolysis into the mechanical energy of each heartbeat. Alterations of myosin isoform expression are routinely associated with acquired and inherited cases of cardiomyopathy. For example, human heart failure is consistently associated with increased expression of a slow myosin motor isoform and a concomitant decreased expression of the heart's fast myosin motor isoform. Further, mutations of the cardiac myosin gene are the most common cause of inherited hypertrophic cardiomyopathy. Transgenic animal studies have provided insight into cardiac functional effects caused by myosin isoform gene switching (fast-to-slow myosin or slow-to-fast myosin) or by expression of a disease-related mutant motor. More direct structure-function analysis using acute gene transfer of myosin motors provides evidence that the inotropic state of cardiac muscle can be affected by motor protein isoform shifting independent of intracellular calcium handling. Because most therapies for the diseased heart target intracellular calcium handling, acute gene transfer of cardiac molecular motors to modulate heart performance offers a novel therapeutic strategy for the compromised heart. Although the development of safe vectors for therapeutic myosin gene delivery are in their infancy, studies focused on acute genetic engineering of the heart's molecular motor will provide a foundation for therapeutic vector development and insight into mechanisms that contribute to cardiomyopathy.

Severe heart failure and early mortality in a double-mutation mouse model of familial hypertrophic cardiomyopathy.

BACKGROUND: Familial hypertrophic cardiomyopathy (FHC) is characterized by genetic and clinical heterogeneity. Five percent of FHC families have 2 FHC-causing mutations, which results in earlier disease onset, increased cardiac dysfunction, and a higher incidence of sudden death events. These observations suggest a relationship between the number of gene mutations and phenotype severity in FHC. METHODS AND RESULTS: We sought to develop, characterize, and investigate the pathogenic mechanisms in a double-mutant murine model of FHC. This model (designated TnI-203/MHC-403) was generated by crossbreeding mice with the Gly203Ser cardiac troponin I (TnI-203) and Arg403Gln alpha-myosin heavy chain (MHC-403) FHC-causing mutations. The mortality rate in TnI-203/MHC-403 mice was 100% by age 21 days. At age 14 days, TnI-203/MHC-403 mice developed a significantly increased ratio of heart weight to body weight, marked interstitial myocardial fibrosis, and increased expression of atrial natriuretic factor and brain natriuretic peptide compared with nontransgenic, TnI-203, and MHC-403 littermates. By age 16 to 18 days, TnI-203/MHC-403 mice rapidly developed a severe dilated cardiomyopathy and heart failure, with inducibility of ventricular arrhythmias, which led to death by 21 days. Downregulation of mRNA levels of key regulators of Ca(2+) homeostasis in TnI-203/MHC-403 mice was observed. Increased levels of phosphorylated STAT3 were observed in TnI-203/MHC-403 mice and corresponded with the onset of disease, which suggests a possible cardioprotective response. CONCLUSIONS: TnI-203/MHC-403 double-mutant mice develop a severe cardiac phenotype characterized by heart failure and early death. The presence of 2 disease-causing mutations may predispose individuals to a greater risk of developing severe heart failure than human FHC caused by a single gene mutation.

Calcium-independent negative inotropy by beta-myosin heavy chain gene transfer in cardiac myocytes.

Increased relative expression of the slow molecular motor of the heart (beta-myosin heavy chain [MyHC]) is well known to occur in many rodent models of cardiovascular disease and in human heart failure. The direct effect of increased relative beta-MyHC expression on intact cardiac myocyte contractility, however, is unclear. To determine the direct effects of increased relative beta-MyHC expression on cardiac contractility, we used acute genetic engineering with a recombinant adenoviral vector (AdMYH7) to genetically titrate beta-MyHC protein expression in isolated rodent ventricular cardiac myocytes that predominantly expressed alpha-MyHC (fast molecular motor). AdMYH7-directed beta-MyHC protein expression and sarcomeric incorporation was observed as soon as 1 day after gene transfer. Effects of beta-MyHC expression on myocyte contractility were determined in electrically paced single myocytes (0.2 Hz, 37 degrees C) by measuring sarcomere shortening and intracellular calcium cycling. Gene transfer-based replacement of alpha-MyHC with beta-MyHC attenuated contractility in a dose-dependent manner, whereas calcium transients were unaffected. For example, when beta-MyHC expression accounted for approximately 18% of the total sarcomeric myosin, the amplitude of sarcomere-length shortening (nanometers, nm) was depressed by 42% (151.0+/-10.7 [control] versus 87.0+/-5.4 nm [AdMYH7 transduced]); and genetic titration of beta-MyHC, leading to 38% beta-MyHC content, attenuated shortening by 57% (138.9+/-13.0 versus 59.7+/-7.1 nm). Maximal isometric cross-bridge cycling rate was also slower in AdMYH7-transduced myocytes. Results indicate that small increases of beta-MyHC expression (18%) have Ca2+ transient-independent physiologically relevant effects to decrease intact cardiac myocyte function. We conclude that beta-MyHC is a negative inotrope among the cardiac myofilament proteins.

Myosin from failing and non-failing human ventricles exhibit similar contractile properties.

In non-failing human myocardium, V1 myosin comprises a small amount (<10%) of the total myosin content, whereas end-stage failing hearts contain nearly 100% V3 myosin. It has been suggested that this shift in V1 myosin isoform content may contribute to the contractile deficit in human myocardial failure. To test this hypothesis, myosin was isolated from human failing and non-failing ventricles, and non-failing atria. Performance was assessed in in vitro motility and isometric force assays. Consistent with prior reports, a small amount of V1 myosin was present in both non-failing (6.2 +/- 1.0%) and failing (3.5 +/- 1.4%) ventricular tissues. No difference in isometric force or unloaded shortening velocity was observed for failing and non-failing ventricular myosin irrespective of myosin isoform content. Atrial tissue expressing predominantly V1 myosin (66.7 +/- 4.1%) generated half the force but greater velocity compared with ventricular tissue, expressing predominantly V3 myosin. In additional experiments, rabbit cardiac myosin was used in a calcium regulated assay system to determine if V1 and V3 isoforms differentially affect thin filament activation. Half-maximal calcium activation was similar for the two cardiac isoforms. A 1:9 mixture of V1/V3 myosin, simulating isoform composition in non-failing human myocardium, was indistinguishable from 100% V3 myosin (simulating the failing state) with regard to velocity of shortening and average force. These data suggest that the myosin isoform shift reported in human myocardial failure does not significantly contribute to the contractile deficit of this disease.

Developmentally modulated cardiac conduction failure in transgenic mice with fetal or postnatal overexpression of DNA nonbinding mutant Nkx2.5.

INTRODUCTION: Nkx2.5 is a conserved homeodomain (HD) containing transcription factor essential for early cardiac development. We generated a DNA nonbinding missense mutation, I183P in the HD, similar to the missense HD mutation found in patients. Transgenic mice expressing this mutation under beta-MHC promoter [beta-MHC(I183P)] showed a postnatal lethal phenotype with heart failure. In contrast, mice expressing the mutation under alpha-MHC promoter [alpha-MHC(I183P)] survive, with later onset heart failure. The aim of this study was to investigate the interrelationship between lethal cardiac failure and the electrophysiologic (EP) phenotypes using cardiac-specific promoters with mutant gene expression at different stages of development and maturation. METHODS AND RESULTS: In beta-MHC(I183P) and wild-type littermates, six-lead ECG and in vivo endocardial EP studies were performed at 2.5, 3, 4, and 5 weeks of age. In alpha-MHC(I183P) and their wild-type controls, ECGs were acquired at 3, 19, 31, and 64 weeks and in vivo EP studies assessed at 19 +/- 4 weeks of age. Beta-MHC(I183P) mice display AV nodal, atrial, and ventricular EP dysfunction by 3 weeks of age. Bradycardia and PR prolongation were evident on telemetered ambulatory ECG of beta-MHC(I183P) mice. In contrast, alpha-MHC(I183P) mice had no abnormalities on serial ECG through 31 weeks or EP findings at 19 weeks, except increased myocardial tissue refractoriness. However, by 64 weeks, PR intervals lengthened in alpha-MHC(I183P) mice. CONCLUSION: Both prenatal and postnatal overexpression of DNA nonbinding mutant Nkx2.5 are associated with AV conduction malfunction and heart failure; however, more profound progressive EP defects are seen when this mutation expresses during fetal and neonatal periods. These conduction abnormalities may contribute to the lethal heart failure and early mortality evident in DNA nonbinding mutant Nkx2.5 mice.